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利用相变材料作为光谱分束滤光片的聚光光伏/热系统提升能量转换效率
Enhanced energy conversion in a concentrated photovoltaic/thermal system using phase change material as a spectral beam filter
语言:
中文摘要
摘要 聚光光伏/热系统的热稳定性和光谱吸收问题仍然制约着其效率的提升。本研究提出了一种新型聚光光伏/热系统,采用集成选择性液体滤光器与相变材料的混合光谱滤光装置。创新的数值方法被应用于实现三维多物理场建模,独特地考虑了相变材料在相变过程及不同波长下的光学行为变化。在完成模型验证后,性能分析探讨了运行条件和设计参数对产出、效率以及市场可行性的具体影响。研究结果表明,将相变材料与选择性液体滤光器相结合可有效增强热管理能力,稳定光伏组件温度,并改善光谱吸收特性,从而提高整体产出。所提出的系统设计实现了更优的效率表现,能量转换率达到49.15%,相较于传统聚光光伏系统提升了240%。
English Abstract
Abstract Thermal stability and spectral absorption challenges still limit concentrated PV/thermal efficiency. This study proposes a novel concentrated PV/thermal system with a hybrid spectral filter integrating a selective liquid filter and phase change material. Innovative numerical procedures are applied to perform 3D multiphysics modeling, uniquely accounting for variations in the optical behavior of phase change materials across phase transitions and wavelengths. Following model validation, performance analysis explores the effects of operating conditions and design parameters on yields, efficiencies, and market feasibility. The findings indicate that integrating phase change material with a selective liquid filter enhances thermal management, stabilizes PV temperatures, and improves spectral absorption, increasing overall yields. The proposed design achieves superior efficiency, with a 49.15 % energy conversion rate and a 240 % improvement over conventional concentrated PV systems.
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SunView 深度解读
该CPV/T混合光谱滤波技术对阳光电源SG系列光伏逆变器及储能系统具有重要启示。相变材料的光谱调控与热管理机制可优化我司1500V系统的温度稳定性,提升MPPT算法在高温工况下的追踪精度。研究中的多物理场耦合建模方法可应用于PowerTitan储能系统的热管理优化,特别是SiC器件在高功率密度场景下的散热设计。49.15%的能量转换效率为我司光储一体化方案提供了新的热电协同优化思路,可结合iSolarCloud平台实现温控预测性维护,提升系统全生命周期效率。