Structural Analysis of a Modular High-Concentration PV System Operating at ~1200 Suns

Structural Analysis of a Modular High-Concentration PV System Operating at ~1200 Suns

The progression of research in concentration photovoltaic systems parallels the advancement of high-efficiency multi-junction solar cells. To translate the theoretical optical framework into practical experimentation, a modular and structurally validated mechanical configuration for a high-concentra...

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Bibliographic Details
Main Authors: Taher Maatallah, Mussad Alzahrani, William Cameron, Katie Shanks, Souheil El Alimi, Tapas K. Mallick, Sajid Ali
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Machines
Subjects:
high-concentration photovoltaic
optics
sun tracker
counterbalance
simulation
Online Access:https://www.mdpi.com/2075-1702/13/6/468
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Summary:The progression of research in concentration photovoltaic systems parallels the advancement of high-efficiency multi-junction solar cells. To translate the theoretical optical framework into practical experimentation, a modular and structurally validated mechanical configuration for a high-concentration photovoltaic (HCPV) system was developed, incorporating boundary conditions and ensuring full system integration. The system incorporates a modular mechanical architecture, allowing flexible integration and interchangeability of optical components for experimental configurations. The architecture offers a high degree of mechanical flexibility, providing each optical stage with multiple linear and angular adjustment capabilities to support precision alignment. To ensure tracking precision, the system was coupled with a three-dimensional sun tracker capable of withstanding torques up to 60 Nm and supporting a combined payload of 80 kg, including counterbalance. The integration necessitated implementation of a counterbalance mechanism along with comprehensive static load analysis to ensure alignment stability and mechanical resilience. A reinforced triangular support structure, fabricated from stainless steel, was validated through simulation to maintain deformation below 0.1 mm under stress levels reaching 5 MN/m<sup>2</sup>, confirming its mechanical robustness and reliability. Windage analysis confirmed that the tracker could safely operate at 15 m/s wind speed for tilt angles of 35° (counter-clockwise) and −5° (clockwise), while operation at a 80° (counter-clockwise) tilt is safe up to 12 m/s, ensuring compliance with local environmental conditions. Overall, the validated system demonstrates structural resilience and modularity, supporting experimental deployment and future scalability.
ISSN:2075-1702

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