https://wiki.hevs.ch/gridlab/api.php5?action=feedcontributions&user=Pierreol.moix&feedformat=atomGridLab - User contributions [en]2024-03-29T05:04:31ZUser contributionsMediaWiki 1.18.1https://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLabLow Voltage GridLab2015-09-08T12:32:57Z<p>Pierreol.moix: /* Content */</p>
<hr />
<div>{{public}}<br />
{{TOC right}}<br />
The Low Voltage GridLab is the part of the GridLab which works on the low voltage grid of 400V. The installations are at a scale of 1:1, which means real producers and consumers are recreated at their actual scale.<br />
<br />
The main purpose of the Low Voltage GridLab is to provide an infrastructure to perform full scale simulations and tests in the low voltage grid. This infrastructure is primarily used for the practical classes of the degree programs Systems Engineering and Energy and Environmental Engineering. Furthermore the infrastructure will provide a versatile tool for research and development and educational projects of the whole School of Engineering. The use of the Low Voltage GridLab by external companies as a test environment is envisaged too.<br />
<br />
[[File:GridlabLV_low_res.jpg|400px|The Low Voltage GridLab]] <br />
<br />
<br />
As the following images show, the Low Voltage GridLab is still under construction.<br />
<br />
[[File:low_voltage_gridlab_under_construction_1.jpg|400px|The Low Voltage GridLab under construction]] [[File:low_voltage_gridlab_under_construction_2.jpg|400px|The Low Voltage GridLab under construction]]<br />
== Content ==<br />
This part of the GridLab wiki contains information about the following major parts of the the Low Voltage GridLab.<br />
* [[Low_Voltage_GridLab/Practical_Classes|Practical Classes]]<br />
* [[Low_Voltage_GridLab/District_Unit|District Unit]]<br />
* [[Low_Voltage_GridLab/Solar_Storage_Unit|Solar Storage Unit]]<br />
* [[Low_Voltage_GridLab/Photovoltaic_System|Photovoltaic System]]<br />
* DC-bus<br />
<br />
== Projects ==<br />
The following list shows projects that where executed with the Low Voltage GridLab infrastructure.<br />
* [[Projects/Research_And_Development/DG2_Automation|DG2 Automation]]<br />
* [[Projects/Research_And_Development/I2G_Inverter_Integration_to_Grid|I2G Inverter Integration to Grid]]<br />
<br />
== Education ==<br />
* [[Low_Voltage_GridLab/Student_Labs|Student Labs]]<br />
* [[Low_Voltage_GridLab/Student_Diploma_Thesis|Student Diploma Thesis]]<br />
<br />
== Other ==<br />
* [[Low_Voltage_GridLab/To-do|To-do]]<br />
<br />
[[Category:Low Voltage GridLab]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2015-08-03T09:09:43Z<p>Pierreol.moix: /* Behavior emulation */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
And the implementation:<br />
<br />
[[File:Eole_gridlab_principe_reali.png|300px|The Wind-Turbine Simulator Implementation]]<br />
<br />
<br />
<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
<br />
=== Behavior emulation ===<br />
<br />
The power production in function of the wind speed and the rotation speed is modelised very simply with a linear model.<br />
Documentation is found here: [[Media:Emulation_Eolienne.pdf|Emulation Eolienne ]]<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup to be in "Isle" mode===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
=== Hardware setup to be in "Injection" mode===<br />
<br />
*The connections to make the bridge between the Turbine and the Grid are back from the test bench (see below)<br />
<br />
[[File:Pt_injection_1.JPG|220px|The Injection point from Wind to Grid]]<br />
<br />
*Connect the supply cable Input Grid from the Turbine on Grid<br />
*Connect the cable Output Grid from the Turbine on Injection<br />
<br />
*Select Wind on the main panel and put on the twos buttons on the "Wind" panel<br />
<br />
[[File:Cmde_général.jpg|220px|The Injection point from Wind to Grid]]<br />
[[File:Cmde_wind.jpg|150px|The Injection point from Wind to Grid]]<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: C:\SVN_gridlab\implementation\highVoltageGridLab\BancDemoEolienne\Prog_Labview_Eolienne<br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original, then the fpga files must be compiled again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
<br />
== Student Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2015-08-03T09:09:17Z<p>Pierreol.moix: /* Documentation */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
And the implementation:<br />
<br />
[[File:Eole_gridlab_principe_reali.png|300px|The Wind-Turbine Simulator Implementation]]<br />
<br />
<br />
<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
<br />
=== Behavior emulation ===<br />
<br />
The power production in function of the wind speed and the rotation speed is modelised very simply with a linear model.<br />
Documentation is found here: *[[Media:Emulation_Eolienne.pdf|Emulation Eolienne ]]<br />
<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup to be in "Isle" mode===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
=== Hardware setup to be in "Injection" mode===<br />
<br />
*The connections to make the bridge between the Turbine and the Grid are back from the test bench (see below)<br />
<br />
[[File:Pt_injection_1.JPG|220px|The Injection point from Wind to Grid]]<br />
<br />
*Connect the supply cable Input Grid from the Turbine on Grid<br />
*Connect the cable Output Grid from the Turbine on Injection<br />
<br />
*Select Wind on the main panel and put on the twos buttons on the "Wind" panel<br />
<br />
[[File:Cmde_général.jpg|220px|The Injection point from Wind to Grid]]<br />
[[File:Cmde_wind.jpg|150px|The Injection point from Wind to Grid]]<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: C:\SVN_gridlab\implementation\highVoltageGridLab\BancDemoEolienne\Prog_Labview_Eolienne<br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original, then the fpga files must be compiled again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
<br />
== Student Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Emulation_Eolienne.pdfFile:Emulation Eolienne.pdf2015-08-03T09:08:11Z<p>Pierreol.moix: </p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2015-08-03T09:06:23Z<p>Pierreol.moix: /* Behavior emulation */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
And the implementation:<br />
<br />
[[File:Eole_gridlab_principe_reali.png|300px|The Wind-Turbine Simulator Implementation]]<br />
<br />
<br />
<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
<br />
=== Behavior emulation ===<br />
<br />
The power production in function of the wind speed and the rotation speed is modelised very simply with a linear model.<br />
Documentation is found here: [[File:document]]<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup to be in "Isle" mode===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
=== Hardware setup to be in "Injection" mode===<br />
<br />
*The connections to make the bridge between the Turbine and the Grid are back from the test bench (see below)<br />
<br />
[[File:Pt_injection_1.JPG|220px|The Injection point from Wind to Grid]]<br />
<br />
*Connect the supply cable Input Grid from the Turbine on Grid<br />
*Connect the cable Output Grid from the Turbine on Injection<br />
<br />
*Select Wind on the main panel and put on the twos buttons on the "Wind" panel<br />
<br />
[[File:Cmde_général.jpg|220px|The Injection point from Wind to Grid]]<br />
[[File:Cmde_wind.jpg|150px|The Injection point from Wind to Grid]]<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: C:\SVN_gridlab\implementation\highVoltageGridLab\BancDemoEolienne\Prog_Labview_Eolienne<br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original, then the fpga files must be compiled again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
<br />
== Student Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2015-08-03T09:05:58Z<p>Pierreol.moix: /* Documentation */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
And the implementation:<br />
<br />
[[File:Eole_gridlab_principe_reali.png|300px|The Wind-Turbine Simulator Implementation]]<br />
<br />
<br />
<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
<br />
=== Behavior emulation ===<br />
<br />
The power production in function of the wind speed and the rotation speed is modelised very simply with a linear model.<br />
Documentation is found here: document<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup to be in "Isle" mode===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
=== Hardware setup to be in "Injection" mode===<br />
<br />
*The connections to make the bridge between the Turbine and the Grid are back from the test bench (see below)<br />
<br />
[[File:Pt_injection_1.JPG|220px|The Injection point from Wind to Grid]]<br />
<br />
*Connect the supply cable Input Grid from the Turbine on Grid<br />
*Connect the cable Output Grid from the Turbine on Injection<br />
<br />
*Select Wind on the main panel and put on the twos buttons on the "Wind" panel<br />
<br />
[[File:Cmde_général.jpg|220px|The Injection point from Wind to Grid]]<br />
[[File:Cmde_wind.jpg|150px|The Injection point from Wind to Grid]]<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: C:\SVN_gridlab\implementation\highVoltageGridLab\BancDemoEolienne\Prog_Labview_Eolienne<br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original, then the fpga files must be compiled again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
<br />
== Student Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLabHigh Voltage GridLab2015-02-02T15:47:41Z<p>Pierreol.moix: </p>
<hr />
<div>{{public}}<br />
{{TOC right}}<br />
The High Voltage GridLab is the part of the GridLab which works on the high voltage grid. The installations are at a scale of 1:5000, which means real producers and consumers are recreated at a reduced scale to be able to simulate high voltage producers and consumers e.g. distribution grids.<br />
<br />
The main purpose of the High Voltage GridLab is to provide an infrastructure to perform reduced scale simulations and tests in the medium and high voltage grid. This infrastructure is primarily used for the practical classes of the degree programs Systems Engineering and Energy and Environmental Engineering. Furthermore the infrastructure will provide a versatile tool for research and development and educational projects of the whole School of Engineering. The use of the High Voltage GridLab by external companies as a test environment is envisaged too.<br />
<br />
As the following images show, the High Voltage GridLab is still under construction.<br />
<br />
[[File:high_voltage_gridlab_under_construction_1.jpg|400px|The High Voltage GridLab under construction]] [[File:high_voltage_gridlab_under_construction_2.jpg|400px|The High Voltage GridLab under construction]]<br />
<br />
== Content ==<br />
This part of the GridLab wiki contains information about the following major parts of the the High Voltage GridLab.<br />
* [[High_Voltage_GridLab/Practical_Classes|Practical Classes]]<br />
* [[High_Voltage_GridLab/Dispatching|Dispatching]]<br />
* [[High_Voltage_GridLab/La_Lienne_SA_Simulator|La Lienne SA Simulator]]<br />
* [[High_Voltage_GridLab/Protection_and_Automation_Test_Bench|Protection and Automation Test Bench]]<br />
* [[High_Voltage_GridLab/WindturbineStand|Windturbine]]<br />
<br />
== Projects ==<br />
The following list shows projects that where executed with the Low Voltage GridLab infrastructure.<br />
*Dimensionnement de lignes et transformateurs pour Mini-Réseau HT/MT, Noémie Epiney 2013<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014<br />
<br />
== Other ==<br />
* [[High_Voltage_GridLab/To-do|To-do]]<br />
<br />
[[Category:GridLab Dispatching]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Main_PageMain Page2015-02-02T15:42:40Z<p>Pierreol.moix: </p>
<hr />
<div>= Welcome to the HES-SO Valais/Wallis Wiki of the GridLab =<br />
{{TOC right}}<br />
[[File:hesso_logo.png|left|200px|HESSO Valais Wallis Logo|link=http://www.hevs.ch]] This is the knowledge database of the [http://www.hevs.ch HES-SO Valais Wallis] [http://isi.hevs.ch/ Institute of Systems Engineering] GridLab. It's the place for technical informations, to share experiences, findings, how-to's and everything else about the GridLab installation and related topics.<br />
The official page of the [http://www.hevs.ch/gridlab Gridlab] is here: <br />
<br />
[[File:Gridlab panorama.jpg|center|800px|GridLab Panorama]]<br />
<br />
Find more information about our technical and educational program in the [http://wiki.hevs.ch/uit UIT Wiki] or [http://wiki.hevs.ch/fsi FSI Wiki].<br />
<br />
[[File:Icontexto-inside-rss.png|link=Help:http://wiki.hevs.ch/gridlab/index.php?title=Special:RecentChanges&feed=rss|48px]] [http://wiki.hevs.ch/gridlab/index.php?title=Special:RecentChanges&feed=rss Get informed about all changes to this wiki by signing up to this RSS feed]<br />
<br />
= Getting started =<br />
Use the ''Navigation'' to the left to enter the different sections or follow any of the following links:<br />
* [[Help:Contents|Help]]<br />
* [//meta.wikimedia.org/wiki/Help:Contents Wikimedia's Help]<br />
* [//www.mediawiki.org/wiki/Manual:FAQ MediaWiki FAQ]<br />
* [[Sandbox|Sandbox for test purposes]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-20T12:56:58Z<p>Pierreol.moix: /* Warning */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give Studer-Innotec a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the Internet network, you have to set up an local area network.<br />
For the ethernet connection use a standard straigth cable as there is an switch (Netgear) on the Unit! see: [http://fr.wikipedia.org/wiki/RJ45#C.C3.A2blage_crois.C3.A9_complet câble RJ45]<br />
<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
<br />
[[File:set_local_network_step4.gif|100px|IPV4 settings]]<br />
<br />
====Warning====<br />
<br />
When using the local area network settings, there is a waiting delay of 2 min else the communications blocks, this is unexplained yet.<br />
<br />
To work in this configuration the IP address of the cRIO must be set to fixed (in Measurement & Automation Explorer)<br />
<br />
[[File:mettre_adresse_statique_cRi.gif|100px|IP fix]]<br />
<br />
The unit #1 that has IP setting:<br />
*153.109.14.71<br />
*153.109.14.72<br />
<br />
The unit #2 that has IP setting:<br />
*153.109.14.76<br />
*153.109.14.77<br />
<br />
Unit #1 is not working in local network, problem to fix<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-20T12:55:58Z<p>Pierreol.moix: /* Known Problems */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give Studer-Innotec a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the Internet network, you have to set up an local area network.<br />
For the ethernet connection use a standard straigth cable as there is an switch (Netgear) on the Unit! see: [http://fr.wikipedia.org/wiki/RJ45#C.C3.A2blage_crois.C3.A9_complet câble RJ45]<br />
<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
<br />
[[File:set_local_network_step4.gif|100px|IPV4 settings]]<br />
<br />
====Warning====<br />
<br />
When using the local area network settings, there is a waiting delay of 2 min else the communications blocks, this is unexplained yet.<br />
<br />
To work in this configuration the IP address of the cRIO must be fixed<br />
<br />
<br />
<br />
[[File:mettre_adresse_statique_cRi.gif|100px|IP fix]]<br />
<br />
The unit #1 that has IP setting:<br />
*153.109.14.71<br />
*153.109.14.72<br />
<br />
The unit #2 that has IP setting:<br />
*153.109.14.76<br />
*153.109.14.77<br />
<br />
Unit #1 is not working in local network, problem to fix<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Mettre_adresse_statique_cRi.gifFile:Mettre adresse statique cRi.gif2014-11-20T12:54:43Z<p>Pierreol.moix: </p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-20T12:53:55Z<p>Pierreol.moix: /* Warning */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give Studer-Innotec a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the Internet network, you have to set up an local area network.<br />
For the ethernet connection use a standard straigth cable as there is an switch (Netgear) on the Unit! see: [http://fr.wikipedia.org/wiki/RJ45#C.C3.A2blage_crois.C3.A9_complet câble RJ45]<br />
<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
<br />
[[File:set_local_network_step4.gif|100px|IPV4 settings]]<br />
<br />
====Warning====<br />
<br />
When using the local area network settings, there is a waiting delay of 2 min else the communications blocks, this is unexplained yet.<br />
<br />
To work in this configuration the IP address of the cRIO must be fixed<br />
<br />
[[File:Example.jpg]]<br />
<br />
The unit #1 that has IP setting:<br />
*153.109.14.71<br />
*153.109.14.72<br />
<br />
The unit #2 that has IP setting:<br />
*153.109.14.76<br />
*153.109.14.77<br />
<br />
Unit #1 is not working in local network, problem to fix<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-20T11:07:27Z<p>Pierreol.moix: /* Warning */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give Studer-Innotec a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the Internet network, you have to set up an local area network.<br />
For the ethernet connection use a standard straigth cable as there is an switch (Netgear) on the Unit! see: [http://fr.wikipedia.org/wiki/RJ45#C.C3.A2blage_crois.C3.A9_complet câble RJ45]<br />
<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
<br />
[[File:set_local_network_step4.gif|100px|IPV4 settings]]<br />
<br />
====Warning====<br />
<br />
When using the local area network settings, there is a waiting delay of 2 min else the communications blocks, this is unexplained yet.<br />
<br />
Use the unit #2 that has IP setting:<br />
*153.109.14.76<br />
*153.109.14.77<br />
<br />
Unit #1 is not working in local network, problem to fix<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-20T11:06:38Z<p>Pierreol.moix: /* Warning */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give Studer-Innotec a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the Internet network, you have to set up an local area network.<br />
For the ethernet connection use a standard straigth cable as there is an switch (Netgear) on the Unit! see: [http://fr.wikipedia.org/wiki/RJ45#C.C3.A2blage_crois.C3.A9_complet câble RJ45]<br />
<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
<br />
[[File:set_local_network_step4.gif|100px|IPV4 settings]]<br />
<br />
====Warning====<br />
<br />
When using the local area network settings, there is a waiting delay of 2 min else the communications blocks, this is unexplained yet.<br />
<br />
Use the unit #2 that has IP setting:<br />
*153.109.14.76<br />
*153.109.14.77<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-20T11:04:47Z<p>Pierreol.moix: /* Use in an independant Network */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give Studer-Innotec a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the Internet network, you have to set up an local area network.<br />
For the ethernet connection use a standard straigth cable as there is an switch (Netgear) on the Unit! see: [http://fr.wikipedia.org/wiki/RJ45#C.C3.A2blage_crois.C3.A9_complet câble RJ45]<br />
<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
<br />
[[File:set_local_network_step4.gif|100px|IPV4 settings]]<br />
<br />
====Warning====<br />
<br />
When using the local area network settings, there is a waiting delay of 2 min else the communications blocks, this is unexplained yet.<br />
Use the unit #2 that has IP setting:<br />
*153.<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-20T07:38:47Z<p>Pierreol.moix: /* Use in an independant Network */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give Studer-Innotec a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the Internet network, you have to set up an local area network.<br />
For the direct ethernet connection of two use device a crossed cable! see: [http://fr.wikipedia.org/wiki/RJ45#C.C3.A2blage_crois.C3.A9_complet câble RJ45]<br />
<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
<br />
[[File:set_local_network_step4.gif|100px|IPV4 settings]]<br />
<br />
When using the local area network settings, there is a waiting delay of 2 min else the communications blocks, this is unexplained yet.<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-19T15:24:18Z<p>Pierreol.moix: /* Programming Tricks */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give Studer-Innotec a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the School network, you have to set up an local area network.<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
<br />
[[File:set_local_network_step4.gif|100px|IPV4 settings]]<br />
<br />
When using the local area network settings, there is a waiting delay of 2 min else the communications blocks, this is unexplained yet.<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-19T15:22:59Z<p>Pierreol.moix: /* Use in an independant Network */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give them a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the School network, you have to set up an local area network.<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
<br />
[[File:set_local_network_step4.gif|100px|IPV4 settings]]<br />
<br />
When using the local area network settings, there is a waiting delay of 2 min else the communications blocks, this is unexplained yet.<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-19T15:22:11Z<p>Pierreol.moix: /* Use in an independant Network */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give them a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the School network, you have to set up an local area network.<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
<br />
[[File:set_local_network_step4.gif|100px|IPV4 settings]]<br />
<br />
When using the local area network settings, there is a delay to waoit of 2 min, this is unexplained yet.<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Set_local_network_step4.gifFile:Set local network step4.gif2014-11-19T13:43:49Z<p>Pierreol.moix: </p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-19T13:43:21Z<p>Pierreol.moix: /* Use in an independant Network */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give them a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the School network, you have to set up an local area network.<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
<br />
[[File:set_local_network_step4.gif|100px|IPV4 settings]]<br />
<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Set_local_network_step3.gifFile:Set local network step3.gif2014-11-19T13:40:36Z<p>Pierreol.moix: uploaded a new version of &quot;File:Set local network step3.gif&quot;</p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Set_local_network_step3.gifFile:Set local network step3.gif2014-11-19T13:35:06Z<p>Pierreol.moix: </p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-19T13:34:49Z<p>Pierreol.moix: /* Use in an independant Network */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give them a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the School network, you have to set up an local area network.<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
<br />
[[File:set_local_network_step3.gif|100px|connection status]]<br />
<br />
[[File:set_local_network_step4.gif|100px|Open network center]]<br />
<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Set_local_network_step2.gifFile:Set local network step2.gif2014-11-19T13:31:30Z<p>Pierreol.moix: uploaded a new version of &quot;File:Set local network step2.gif&quot;</p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Set_local_network_step2.gifFile:Set local network step2.gif2014-11-19T13:31:25Z<p>Pierreol.moix: </p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-19T13:30:27Z<p>Pierreol.moix: /* Use in an independant Network */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give them a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the School network, you have to set up an local area network.<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
<br />
[[File:set_local_network_step2.gif|100px|local area]]<br />
<br />
[[File:set_local_network_step3.gif|100px|Open network center]]<br />
<br />
[[File:set_local_network_step4.gif|100px|Open network center]]<br />
<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Set_local_network_step1.gifFile:Set local network step1.gif2014-11-19T13:27:25Z<p>Pierreol.moix: </p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-19T13:26:51Z<p>Pierreol.moix: </p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give them a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the School network, you have to set up an local area network.<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
<br />
[[File:set_local_network_step1.gif|100px|Open network center]]<br />
<br />
[[File:set_local_network_step2.gif|100px|Open network center]]<br />
<br />
[[File:set_local_network_step3.gif|100px|Open network center]]<br />
<br />
[[File:set_local_network_step4.gif|100px|Open network center]]<br />
<br />
<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/Low_Voltage_GridLab/Solar_Storage_UnitLow Voltage GridLab/Solar Storage Unit2014-11-19T13:25:28Z<p>Pierreol.moix: /* Use in an independant Network */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an integrated system with a battery inverter, an MPPT solar charger and a 24V battery. All device can be controled by Labview.<br />
<br />
<br />
[[File:GridLab_SolarStorageUnit.jpg|200px|The Solar-Storage Unit]]<br />
<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
* [[Media:gridlab_lv_solar_storage_unit_electrical_schematic.pdf|Electrical schematic of the solar storage unit]]<br /><br />
* [[Media:gridlab_lv_solar_storage_unit_communication_schematic.pdf|Communication schematic of the solar storage unit]]<br />
<br />
=== Control with Labview ===<br />
<br />
Documentation to do...<br />
<br />
<br />
*Set the correct IP address to communicate with the unit you want: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== To-do ==<br />
This list shows what has to be done for the different posts to finalize them.<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Number !! Part !! Work !! State<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery fixation || The battery have to be fixed in their frame. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Battery vapor protection || The battery vapor protection of the Delta Elektronika power supply has to be attached. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State signals of the front panel || The signals of the front panel selection which enters the NI controller have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || State LEDs of front panel || The state LEDs of the solar selection of the front panel have to be connected. || Waiting<br />
|-<br />
| 12.05.2014 || fud || 1 - 4 || Studer Xcom-232i || The communication module Xcom-232i is not mounted strong enough. Has to be glued better. || Waiting<br />
|-<br />
| 21.02.2014 || fud || 1 - 4 || Studer Xtender XTM 3200 || Correct the installation of the positive pole of the battery. (Increase size of the mounting hole to M10) || Waiting<br />
|-<br />
| 25.02.2014 || fud || 1 - 4 || Delta Elektronika power supply || The ventilation opening are blocked by the mounting profiles of the power supply. This has to be corrected by making some cut outs to the mounting profiles. || Done<br />
|-<br />
|}<br />
<br />
=== Software ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Software !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Instrument drivers || Communication with power supply || If the TCP connection is closed the user has to wait for about 1 minute to reconnect. This should not be the case. It seems, that the reason is the power supply. Check out what can be done. || Waiting<br />
|-<br />
|}<br />
<br />
=== Documentation ===<br />
{|class="wikitable sortable"<br />
! Date !! Autor !! Part !! Work !! State<br />
|-<br />
| 22.05.2014 || fud || Electrical schematic || The polarity of the inputs of the digital input module NI 9421 of the cRIO 9076 are inverted on the schematic. || Waiting<br />
|-<br />
|}<br />
<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
{|class="wikitable sortable"<br />
! Part !! Discovery !! Unit !! Remarks !! Corrected<br />
|-<br />
| 24VDC power supply and DC contactors || 23.05.2014 || 1 - 4 || The 24VDC voltage collapses down to 7VDC when one of the DC contactors is closed. This is because of the 200W of instantanious pick-up power which is driven from the 90W 24VDC power supply. So for the next version the dimensioning of the 24V DC power supply has to be adapted to this. || Not yet<br />
|-<br />
|}<br />
<br />
=== Programming Tricks===<br />
<br />
The latest version of Studer-Innnotec manuals can be downloaded here: [http://www.studer-inno.com/?cat=download_center |Studer-Innotec]<br />
<br />
There are different user levels availables for the programming units RCC:<br />
<br />
*The EXPERT user level code is 426468<br />
*The QSP user level code is 392855 for 2014, it changes every year, give them a phone call (of set back the clock time ;-) )<br />
<br />
<br />
The Xtender and the Variotrack receive parameters from Labview.<br />
These parameters are not saved permanently in the memory: if you switch off the system, when powering it back again, it returns to the default factory settings. There are parameters to control this behavior:<br />
* 1550 of the XT<br />
* 100?? for the VT<br />
<br />
<br />
If the VT is not performing what you want, check:<br />
<br />
10037 Synchronisation battery cycle with Xtender --> N0<br />
<br />
<br />
<br />
=== Use in an independant Network===<br />
<br />
To use the SolarStorage Unit directly with a computer, witout access to the School network, you have to set up an local area network.<br />
In Windows, in "network and sharing center", in "Local Area Connection"<br />
<br />
set_local_network_step1.gif<br />
<br />
Set IPV4 properties to fixed address: <br />
*IP adress 153.109.14.170<br />
*SubnetMask: 255.255.255.0<br />
<br />
[[Category:Low Voltage GridLab]]<br />
[[Category:Solar Storage Unit]]</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Principe_modelisation_eolienne.pngFile:Principe modelisation eolienne.png2014-11-18T15:29:04Z<p>Pierreol.moix: uploaded a new version of &quot;File:Principe modelisation eolienne.png&quot;</p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T15:25:27Z<p>Pierreol.moix: </p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
And the implementation:<br />
<br />
[[File:Eole_gridlab_principe_reali.png|300px|The Wind-Turbine Simulator Implementation]]<br />
<br />
<br />
<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: C:\SVN_gridlab\implementation\highVoltageGridLab\BancDemoEolienne\Prog_Labview_Eolienne<br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original, then the fpga files must be compiled again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
<br />
== Student Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T15:25:15Z<p>Pierreol.moix: </p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
And the implementation.<br />
[[File:Eole_gridlab_principe_reali.png|300px|The Wind-Turbine Simulator Implementation]]<br />
<br />
<br />
<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: C:\SVN_gridlab\implementation\highVoltageGridLab\BancDemoEolienne\Prog_Labview_Eolienne<br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original, then the fpga files must be compiled again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
<br />
== Student Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Eole_gridlab_principe_reali.pngFile:Eole gridlab principe reali.png2014-11-18T15:24:54Z<p>Pierreol.moix: </p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T15:24:18Z<p>Pierreol.moix: </p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
And the implementation.<br />
[[File:Eole_gridlab_principe_realisation.png|300px|The Wind-Turbine Simulator Implementation]]<br />
<br />
<br />
<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: C:\SVN_gridlab\implementation\highVoltageGridLab\BancDemoEolienne\Prog_Labview_Eolienne<br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original, then the fpga files must be compiled again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
<br />
== Student Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T15:15:28Z<p>Pierreol.moix: /* Open and Start the programm */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: C:\SVN_gridlab\implementation\highVoltageGridLab\BancDemoEolienne\Prog_Labview_Eolienne<br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original, then the fpga files must be compiled again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
<br />
== Student Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T15:12:16Z<p>Pierreol.moix: /* Debug */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original, then the fpga files must be compiled again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
<br />
== Student Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T15:11:19Z<p>Pierreol.moix: </p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original the fpga files must be build again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
<br />
== Student Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T15:10:53Z<p>Pierreol.moix: /* Projects */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original the fpga files must be build again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
== Student Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T15:10:36Z<p>Pierreol.moix: </p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original the fpga files must be build again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...<br />
<br />
<br />
== Projects ==<br />
The following projects that where executed for the windturbine infrastructure:<br />
*Banc de simulation Eolienne, Shadya Gabathuler 2013 <br />
*Intégration d’éoliennes dans le Gridlab, Zacharie Lagger 2014</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T15:08:42Z<p>Pierreol.moix: /* Software */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original the fpga files must be build again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T15:08:31Z<p>Pierreol.moix: /* Software */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original the fpga files must be build again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
TODO:<br />
Filtrage des consigne des pots pour correspondre à la dynamique de montée en vitesse de l'éolienne<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T13:59:24Z<p>Pierreol.moix: /* Debug */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed from original the fpga files must be build again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T13:59:00Z<p>Pierreol.moix: /* Debug */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changed the fpga files must be build again. Else there is an error in Variables_transfer_FPGA.vi<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T13:58:00Z<p>Pierreol.moix: /* Debug */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changedm the fpga files must be build again<br />
<br />
[[File:Eole_fpga_aquisition.gif|100px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Eole_fpga_aquisition.gifFile:Eole fpga aquisition.gif2014-11-18T13:57:29Z<p>Pierreol.moix: </p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T13:57:00Z<p>Pierreol.moix: /* Open and Start the programm */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
==== Debug ====<br />
When the containing folder names (path) is changedm the fpga files must be build again<br />
[[File:Eole_fpga_aquisition.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T13:13:48Z<p>Pierreol.moix: /* Simulation */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T13:13:13Z<p>Pierreol.moix: /* Open and Start the programm */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
=== Simulation===<br />
<br />
<br />
<br />
*Give a torque reference for the motor in variable Motor_Torque_Ref (it’s in [%] of Mn)<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...</div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/File:Main_labview_eolienne.gifFile:Main labview eolienne.gif2014-11-18T13:12:55Z<p>Pierreol.moix: </p>
<hr />
<div></div>Pierreol.moixhttps://wiki.hevs.ch/gridlab/index.php5/High_Voltage_GridLab/WindturbineStandHigh Voltage GridLab/WindturbineStand2014-11-18T13:12:25Z<p>Pierreol.moix: /* How To Start a Demo */</p>
<hr />
<div>{{private}}<br />
{{TOC right}}<br />
<br />
This is an hardware simulation system of a windturbine.<br />
<br />
[[File:EolienneGridlab.jpg|300px|The Wind-Turbine Simulator]]<br />
<br />
The principle is to have a motor that gives torque on another motor controlled in speed<br />
<br />
[[File:Principe_modelisation_eolienne.png|300px|The Wind-Turbine Simulator concept]]<br />
<br />
For general information about windturbines, see: [http://en.wikipedia.org/wiki/Windturbine Wikipedia Windturbine]<br />
<br />
== Documentation ==<br />
=== Schematic ===<br />
<br />
<br />
*[[Media:Eole_P01.pdf|Electrical schematic of the Windturbine: P01]]<br />
*[[Media:Eole_P02.pdf|Electrical schematic of the Windturbine: P02]]<br />
*[[Media:Eole_P03.pdf|Electrical schematic of the Windturbine: P03]]<br />
*[[Media:Eole_P04.pdf|Electrical schematic of the Windturbine: P04]]<br />
*[[Media:Eole_TableauElectrique.pdf|Implementation]]<br />
<br />
Original files saved under: I:\Admin\SI-ET\Institut\Infrastructure\Labos\CR01\GridLab\Gridlab dispatching\TD_Bachelor<br />
<br />
FILES ORGANISATION TO DISCUSS<br />
<br />
=== Labview files repository ===<br />
<br />
<br />
<br />
All the Labview files are versionned, Checkout on SVN (https://repos.hevs.ch/svn/gridlab/) <br />
<br />
In subfolder: \implementation\highVoltageGridLab\BancDemoEolienne<br />
<br />
Always work on versionned files and commit when modifications are definitiv and must be saved for all.<br />
<br />
On the windturbine laptop, the files are in: C:\SVN_gridlab<br />
<br />
=== Communication ===<br />
*The correct IP address to communicate with the unit are given here: [[http://wiki.hevs.ch/gridlab/index.php5/Infrastructure/Communication_Networks/Local_Area_Network/Internet_Protocol/Fixed_Address_Device_List]]<br />
<br />
== How To Start a Demo ==<br />
Follow this procedure:<br />
<br />
=== PC login ===<br />
On the laptop dedicated to the WT, login local:<br />
*User: uadmin<br />
*pwd: laboae04<br />
<br />
<br />
<br />
=== Hardware setup ===<br />
<br />
*Connect the supply cable to Input Grid<br />
*Connect the cable bridge from Output Grid to Input Grid<br />
*Turn on the power switch<br />
*Check the emergency stop<br />
<br />
<br />
[[File:Eole_onoff_power.jpg|180px|The Wind-Turbine Simulator frontpannel]]<br />
[[File:Eole_power_connection.jpg|160px|The Wind-Turbine Simulator power connection]]<br />
<br />
The PC plug is powered only if Power Switch is ON<br />
<br />
<br />
<br />
=== Open and Start the programm ===<br />
<br />
*On desktop open shortcut to folder Prog_LabView_Eolienne<br />
**or access files in: <br />
<br />
*Open project file Eolienne.Ivproj<br />
*Open Main.vi and execute <br />
<br />
*Open the Graph.vi in projetwindow or in schematics<br />
<br />
The Main.vi has following structure:<br />
[[File:main_labview_eolienne.gif|160px|Programm structure of Wind-Turbine Simulator Labview Main.vi]]<br />
<br />
<br />
<br />
A first step is done and Lamp PC Online must be on.<br />
Then:<br />
*Push button Default on the front pannel<br />
** →You hear the relay closing<br />
** →Lights are seen on the Emerson Inverters<br />
*Push button Simulation<br />
*Push button Injection <br />
**→ The turbine can now be controlled with the ''Turbine Speed'' button<br />
<br />
Now the blade are rotating... to see the variables of the simulator, see the Global_Variables.vi<br />
<br />
[[File:Eole_front_pannel.jpg|200px|The Wind-Turbine Simulator frontpannel]]<br />
<br />
<br />
<br />
=== Simulation===<br />
<br />
<br />
<br />
*Give a torque reference for the motor in variable Motor_Torque_Ref (it’s in [%] of Mn)<br />
<br />
=== Interface ===<br />
<br />
Turn the wind speed and the turbine speed buttons.<br />
The effect can be seen on the graphical interface (Graph.vi)<br />
<br />
[[File:graph_windturbine_control.gif|200px|The Wind-Turbine Simulator]]<br />
<br />
<br />
The following characteristic is implemented:<br />
<br />
[[File:Eole_P_characteristic.png|200px|The Wind-Turbine Simulator characteristic]]<br />
<br />
You can play with the two buttons and find the optimal turbine speed in function of the wind speed.<br />
<br />
== Known Problems ==<br />
=== Hardware ===<br />
TODO:<br />
Ajouter un condo sur les pots ou un fitrage-moyennage soft: bruit observé<br />
=== Software===<br />
TODO:<br />
La vitesse de mise à jour avec les mesures des drives est lentes (~2sec), il serait agréable à l'utilisation de l'accélérer<br />
Je n'ai pas trouvé si c'est une limitation de la vitesse de communication, à creuser plus...<br />
<br />
== Students Lab ==<br />
<br />
TODO<br />
<br />
Ideas for Lab:<br />
*find optimal point of operation<br />
**manually<br />
**automatically with wind speed information<br />
**MPPT algorithm<br />
*...<br />
<br />
Ideas for project:<br />
*finish communication with Orsière<br />
*...</div>Pierreol.moix