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2025 Vol.13, Issue 1 Preview Page
Optical Simulation for Agrivoltaic SystemUsing Raytracing Method

광선추적 기법을 사용한 영농형 태양광 시스템의 광학 시뮬레이션

Inku Kang1
,
Eunseok Jang1
,
Huijae Jang1
,
Bumsu Kim1
,
Myunghun Shin1*
,
Jungdae Kwon2**
강 인구1
,
장 은석1
,
장 희재1
,
김 범수1
,
신 명훈1*
,
권 정대2**
1School of Electronics and Information Engineering, Korea Aerospace University, Goyang-si, 10540, Korea
2Nano Materials Division, Korea Institute of Materials Science, Changwon, 51508, Korea
1항공전자정보공학부, 한국항공대학교, 고양시, 10540
2한국재료연구원, 창원, 51508
*Corresponding Author
**Corresponding Author
31 March 2025. pp. 31-36
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Abstract

Agrivoltaic systems, which integrate bifacial photovoltaic (PV) modules above agricultural fields, provide a sustainable solution to land scarcity by enabling the simultaneous cultivation of crops and generation of solar power on the same site. Optimizing these systems requires ensuring sufficient solar irradiance reaches the crops while maintaining uniform sunlight distribution to minimize shading variability. In this study, we evaluated two distinct agrivoltaic system layouts under identical area and shading conditions (30%) to assess the impact of module placement on solar irradiance distribution. Using ray tracing techniques, we modeled sunlight pathways beneath the PV modules and visualized the resulting irradiance distribution with heatmaps. The estimated annual energy yield per module was 1263 kWh/kWp and 1268 kWh/kWp (accounting for loss parameters), with average irradiance levels of 68.25% and 67.05% reaching the farmland, respectively. While the average irradiance levels were similar between the layouts, the standard deviation of irradiance differed significantly, measured at 4.16% and 1.58%. This finding demonstrates that the configuration without gaps between arrays provided more uniform irradiance, offering enhanced conditions for crop growth while sustaining efficient solar energy production.

Keywords
Agrivoltaic system
Ray tracing
Heatmap
Loss parameters
Energy yield
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Information
  • Publisher :Korea Photovoltaic Society
  • Publisher(Ko) :한국태양광발전학회
  • Journal Title :Current Photovoltaic Research
  • Volume : 13
  • No :1
  • Pages :31-36
  • Received Date : 2024-11-29
  • Revised Date : 2025-01-05
  • Accepted Date : 2025-01-15
  • DOI :https://doi.org/10.21218/CPR.2025.13.1.031
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