Influence of Cell Temperature on Theoretical Properties of InGaP/ InGaAs/Ge Triple-Junction Concentrated Solar Cells-Reference-Cited by-同舟云学术

Influence of Cell Temperature on Theoretical Properties of InGaP/ InGaAs/Ge Triple-Junction Concentrated Solar Cells

Published:2024-06 Issue:3 Volume:17 Page:159-170
ISSN:2212-7976
Container-title:Recent Patents on Mechanical Engineering
language:en
Short-container-title:MENG

Author:

Song Zhiqiang¹,Wang Zilong¹,Zhang Hua¹,Wu Weidong¹,Dou Binlin¹,Tian Ziao²,Hu Changqing³,Jin Qian⁴

Affiliation:

1. School of Energy and Power Engineering, University of Shanghai for Science and Technology, 200093, Shanghai, China

2. Shanghai Institute of Microsystems and Information Technology, Chinese Academy of Sciences, 200050, Shanghai, China

3. Shanghai Boshiguang Semiconductor Technology Company, 201715, Shanghai, China

4. Karamay Carbon Network Technology Company, 834000, Karamay, China

Abstract

Aims: This study aims to analyze the accuracy of single- and double-diode models in predicting the electrical parameters of InGaP/InGaAs/Ge triple-junction solar cells as described in relevant patents under various operating conditions. Methods: This study obtained and analyzed experimental and theoretical values of the relevant electrical parameters of solar cells through a combination of experimental research and theoretical model calculations. Results: The results indicated that the root mean square error of the short-circuit current decreased from 0.21 at 400 W/m² to 0.11 at 1000 W/m². The temperature of the two precision cut-off points for the open-circuit voltage in the single- and double-diode models increased from 34°C and 64°C at 400 W/m² to 39°C and 72°C at 1000 W/m². Additionally, for peak power and conversion efficiency, the precision cut-off temperatures of the single- and double-diode models were 56°C, 68°C, and 77°C at 400 W/m², 600 W/m², and 800 W/m², respectively. Conclusion: The theoretical values of the short-circuit current exceeded the corresponding experimental values. The single- and double-diode models for open-circuit voltage exhibited two accuracy cut-off points, with the single-diode model demonstrating greater accuracy within this temperature range. Similarly, the peak power and conversion efficiency models for single- and double-diodes have an accuracy cut-off point, with the double-diode model performing better at higher temperatures.

Funder

National Natural Science Foundation of China

Shanghai Municipal Natural Science Foundation

Special Project of Biomedical Science and Technology Support of Shanghai Science and Technology Innovation Action Plan

Publisher

Bentham Science Publishers Ltd.

Reference76 articles.

1. Gregoris P.P.; Soteris K.A.; Savvas T.A.; PEM fuel cells for energy production in solar hydrogen systems. Recent Pat Mech Eng 2011,3(3)

2. Kathirvel K.; Rajasekar R.; Shanmuharajan T.; Pal S.K.; Sathish Kumar P.; Saravana Kumar J.; Development of calcium titanium oxide coated silicon solar cells for enhanced voltage generation capacity. Mater Sci Pol 2017,35(1),181-187

3. Basel I.I.; Thermophotovoltaic energy conversion for direct generation of electricity as an alternative clean energy source technology. Recent Pat Mech Eng 2011,4(2)

4. Palaniappan S.K.; Chinnasamy M.; Rathanasamy R.; Pal S.K.; Recycling of solar panels. Materials for Solar Energy Conversion 2021

5. Kaliyannan G.V.; Gandhi U.; Rathanasamy R.; Effect of zinc oxide—aluminium oxide mechanical blends for boosting the polycrystalline silicon solar cell performance through antireflection properties 2023,1-12