Thermomechanical Design Rules for the Development of Photovoltaic Modules
Seiten
A set of 15 thermomechanical design rules is derrived to support and accelerate PV module developments.Three methods are developed and applied:
1. Thermomechanical FEM-simulations of PV module designs.
2. µ-Raman spectroscopy of laminated solar cells.
3. Solar cell integrated stress sensors (SenSoCell®).
The concept of specific thermal expansion stiffness E _ is introduced as a measure of how much thermal strain one material induces in another.
Stress in solar cells plays a crucial role in the reliability of photovoltaic (PV) modules. The influences on stress are as diverse as the number of different materials in a PV module and become more and more complex with the growing variety of PV modules for different applications. Within this dissertation, a set of 15 thermomechanical design rules is derrived to support and accelerate future PV module developments.
Three methods are developed and applied:
1. Thermomechanical finite element method simulations of PV module designs (FEM).
2. µ-Raman spectroscopy of laminated solar cells (µ-Raman).
3. Solar cell integrated stress sensors (SenSoCell®).
Furthermore, the concept of specific thermal expansion stiffness: E ^_a=E·a·A_j·h is introduced as a measure of how much thermal strain one material can induce in another.
1. Thermomechanical FEM-simulations of PV module designs.
2. µ-Raman spectroscopy of laminated solar cells.
3. Solar cell integrated stress sensors (SenSoCell®).
The concept of specific thermal expansion stiffness E _ is introduced as a measure of how much thermal strain one material induces in another.
Stress in solar cells plays a crucial role in the reliability of photovoltaic (PV) modules. The influences on stress are as diverse as the number of different materials in a PV module and become more and more complex with the growing variety of PV modules for different applications. Within this dissertation, a set of 15 thermomechanical design rules is derrived to support and accelerate future PV module developments.
Three methods are developed and applied:
1. Thermomechanical finite element method simulations of PV module designs (FEM).
2. µ-Raman spectroscopy of laminated solar cells (µ-Raman).
3. Solar cell integrated stress sensors (SenSoCell®).
Furthermore, the concept of specific thermal expansion stiffness: E ^_a=E·a·A_j·h is introduced as a measure of how much thermal strain one material can induce in another.
| Erscheinungsdatum | 29.04.2022 |
|---|---|
| Reihe/Serie | Solare Energie- und Systemforschung / Solar Energy and Systems Research |
| Zusatzinfo | num., col. illus. and tab. |
| Verlagsort | Stuttgart |
| Sprache | englisch |
| Maße | 148 x 210 mm |
| Themenwelt | Technik ► Elektrotechnik / Energietechnik |
| Schlagworte | B • Bauplanung • Berechnungsingenieure • Elektrizität • Energiesparend Bauen • Finite Element Method • mechanical engineering • Photovoltaics • PV-Modulhersteller • Renewable Energies • StressM Photovoltaic Module Design • StressM Photovoltaic Module Design • StressMPhotovoltaic Module Design • Versorgung |
| ISBN-10 | 3-8396-1808-8 / 3839618088 |
| ISBN-13 | 978-3-8396-1808-0 / 9783839618080 |
| Zustand | Neuware |
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