TY - JOUR
T1 - Extended Failure Mode and Effects Analysis for Development of Hot Desert Test Cycle Proposal
AU - Adothu, Baloji
AU - Mathiak, Gerhard
AU - Aly, Shahzada Pamir
AU - Alheloo, Ahmad
AU - Almheiri, Ali
AU - Alberts, Vivian
AU - Jäckel, Bengt
AU - Gottschalg, Ralph
AU - Shiradkar, Narendra S
AU - Abdallah, Amir A
AU - Garcia, Juan Lopez
AU - Salvador, Michael
AU - Hoex, Bram
AU - John, Jim Joseph
AU - Kazem, Hussein A
AU - Alam, Muhammad Ashraful
N1 - Publisher Copyright:
© 2024 John Wiley & Sons Ltd.
PY - 2024/11/12
Y1 - 2024/11/12
N2 - A growing number of gigawatt-scale photovoltaic (PV) power plants are being established in hot desert regions worldwide, which are favored for their vast available land, high solar irradiance, long sunshine hours, and relatively low maintenance needs. This study combines insights from global PV experts on degradation rates, failure mode and effects analysis (FMEA), and desert weather conditions to develop a hot desert test cycle (HDTC). The average degradation rate for PV modules installed in hot desert regions over the past 10 years is estimated to be around 1.63% per year. Eighteen failure modes were identified and analyzed using FMEA. According to the results, the main degradation mechanisms include UV light-induced degradation (UVLID), thermomechanical failures in interconnects and fingers, light-elevated temperature-induced degradation (LeTID), and abrasion of the glass and antireflection coatings. A radar map comparison shows that desert environments experience UV exposure, ambient, and module temperatures that are more than twice as high as those in moderate climates. The HDTC protocol was developed based on FMEA results and desert-specific weather conditions. It includes tests for desert UV exposure, temperature cycles, mechanical loads, and sand/brush abrasions. To ensure consistency across countries, there is a plan to establish an internationally recognized standard that complements existing IEC standards. As the industry grows, desert regions are expected to place greater emphasis on adopting desert-specific testing standards for the qualification and evaluation of PV modules.
AB - A growing number of gigawatt-scale photovoltaic (PV) power plants are being established in hot desert regions worldwide, which are favored for their vast available land, high solar irradiance, long sunshine hours, and relatively low maintenance needs. This study combines insights from global PV experts on degradation rates, failure mode and effects analysis (FMEA), and desert weather conditions to develop a hot desert test cycle (HDTC). The average degradation rate for PV modules installed in hot desert regions over the past 10 years is estimated to be around 1.63% per year. Eighteen failure modes were identified and analyzed using FMEA. According to the results, the main degradation mechanisms include UV light-induced degradation (UVLID), thermomechanical failures in interconnects and fingers, light-elevated temperature-induced degradation (LeTID), and abrasion of the glass and antireflection coatings. A radar map comparison shows that desert environments experience UV exposure, ambient, and module temperatures that are more than twice as high as those in moderate climates. The HDTC protocol was developed based on FMEA results and desert-specific weather conditions. It includes tests for desert UV exposure, temperature cycles, mechanical loads, and sand/brush abrasions. To ensure consistency across countries, there is a plan to establish an internationally recognized standard that complements existing IEC standards. As the industry grows, desert regions are expected to place greater emphasis on adopting desert-specific testing standards for the qualification and evaluation of PV modules.
KW - Degradation rate
KW - Desert climate
KW - Failure mode and effects analysis
KW - Hot desert test cycle
KW - Photovoltaic modules
KW - Risk priority number
UR - http://www.scopus.com/inward/record.url?scp=85208781061&partnerID=8YFLogxK
U2 - 10.1002/pip.3862
DO - 10.1002/pip.3862
M3 - Article
AN - SCOPUS:85208781061
SN - 1062-7995
JO - Progress in Photovoltaics: Research and Applications
JF - Progress in Photovoltaics: Research and Applications
ER -