Solar Simulator: Difference between revisions
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'''Specifications:''' Solar Simulator: WXS-90S-L2 by WACOM, Saitama, Japan / IV-Setup and Software: Sun Simulator SUS V2.0 / Oerlikon |
'''Specifications:''' Solar Simulator: WXS-90S-L2 by WACOM, Saitama, Japan / IV-Setup and Software: Sun Simulator SUS V2.0 / Oerlikon |
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'''Tool Responsibles:''' Malte Langenhorst, Ulrich Paetzold, Efthymios Klampaftis |
'''Tool Responsibles:''' [[User:Malte.Langenhorst|Malte Langenhorst]], [[User:Ulrich.Paetzold|Ulrich Paetzold]], [[User:Efthymios.Klampaftis|Efthymios Klampaftis]] |
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'''Location:''' Solar Lab (R203, B301) at the Institute of Microstructure Technology |
'''Location:''' Solar Lab (R203, B301) at the Institute of Microstructure Technology |
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== Short Description == |
== Short Description == |
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The solar simulator provides illumination approximating natural sunlight. It is a controllable indoor test facility to determine the power conversion efficiency and material stability under standardized conditions mimicking the international solar irradiation standard AM1.5G. It is a commercial solar simulator certified to highest accuracy class named AAA (WXS-90S-L2 by WACOM, Saitama, Japan). The illumination is homogeneous up to areas of 4”, enabling to perform tests on single solar cells as well as thin-film solar modules up to these dimensions. The tool is most in our lab for the testing of solar cells, solar harvesting devices and luminescent materials. |
The solar simulator provides illumination approximating natural sunlight. It is a controllable indoor test facility to determine the power conversion efficiency and material stability under standardized conditions mimicking the international solar irradiation standard AM1.5G. It is a commercial solar simulator certified to highest accuracy class named AAA (WXS-90S-L2 by WACOM, Saitama, Japan). The illumination is homogeneous up to areas of 4”, enabling to perform tests on single solar cells as well as thin-film solar modules up to these dimensions. The tool is most in our lab for the testing of solar cells, solar harvesting devices and luminescent materials. |
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== Manual == |
== Manual == |
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The solar simulator is certified to highest accuracy class named AAA (see also [[File:Spectrum.pdf]]) |
The solar simulator is certified to highest accuracy class named AAA (see also [[File:Spectrum.pdf]]) |
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== Important Rules == |
== Important Rules == |
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# After switching of the lamps you need to keep the cooling fan running for at least 20 min! Otherwise you will damage the lamps. |
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== Manual == |
== Manual == |
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Manual is stored in the labeled cupboard of the Solar Lab 203. |
Manual is stored in the labeled cupboard of the Solar Lab 203. |
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== How to Start the System == |
== How to Start the System == |
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Short description on how to start and ingnitiate correctly the lamps: [[File:Startup.pdf]] |
Short description on how to start and ingnitiate correctly the lamps: [[File:Startup.pdf]] |
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== Tool Responsibles == |
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[[User:Malte.Langenhorst|Malte Langenhorst]] |
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[[User:Ulrich.Paetzold|Ulrich Paetzold]] |
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[[User:Efthymios.Klampaftis|Efthymios Klampaftis]] |
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Revision as of 12:55, 15 September 2017
Device: Sun Simulator Setup
Specifications: Solar Simulator: WXS-90S-L2 by WACOM, Saitama, Japan / IV-Setup and Software: Sun Simulator SUS V2.0 / Oerlikon
Tool Responsibles: Malte Langenhorst, Ulrich Paetzold, Efthymios Klampaftis
Location: Solar Lab (R203, B301) at the Institute of Microstructure Technology
Short Description
The solar simulator provides illumination approximating natural sunlight. It is a controllable indoor test facility to determine the power conversion efficiency and material stability under standardized conditions mimicking the international solar irradiation standard AM1.5G. It is a commercial solar simulator certified to highest accuracy class named AAA (WXS-90S-L2 by WACOM, Saitama, Japan). The illumination is homogeneous up to areas of 4”, enabling to perform tests on single solar cells as well as thin-film solar modules up to these dimensions. The tool is most in our lab for the testing of solar cells, solar harvesting devices and luminescent materials.
Manual
The solar simulator is certified to highest accuracy class named AAA (see also File:Spectrum.pdf)
Important Rules
- After switching of the lamps you need to keep the cooling fan running for at least 20 min! Otherwise you will damage the lamps.
- Lamps can only be exchanged by tool responsibles! Do not touch the optics or inner parts of the solar simulator!
- Be aware that the lamps operate at high voltages!
- Always wear personal protection equipment (1) safety goggles (2) clothing w. long sleves (3) gloves
Manual
Manual is stored in the labeled cupboard of the Solar Lab 203.
How to Start the System
Short description on how to start and ingnitiate correctly the lamps: File:Startup.pdf
