Context:

International delegates, attending the International Solar Alliance Session, recently visited a farm site at Najafgarh where the practical implementation of ‘Agrivoltaic Farming Systems’ was showcased. 

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  • International Participation: Ministers, mission heads, and delegates from 120 Member and Signatory Countries attended the seventh (7th) session of the International Solar Alliance in New Delhi under India’s presidency and France’s co-presidency.
  • Strategic Focus: The three-day event emphasized initiatives to improve energy access, security, and transition toward sustainable energy solutions. 

Agrivoltaic Farming System

  • Agrivoltaic farming focuses on the simultaneous use of land for both agriculture and solar energy generation.
  • In 1981, this technique was first conceived by Adolf Goetzberger and Armin Zastrow, which marked a significant milestone in sustainable agriculture.
  • This system creates a microclimate in solar farms that protects crops from extreme weather conditions, reduces soil moisture evaporation and enhances solar panel efficiency by 2-6 degrees.
  • The agro-PV installations support both food and non-food crops. These installations also benefit for the  horticultural crops, such as leafy greens, root vegetables, legumes and herbs.

Mechanism and Design

Panel Configuration: Solar panels are typically elevated 2-3 meters above the ground at specific angles (usually 30 degrees) to provide optimal shade and weather protection for crops.

System Types: Three basic configurations exist:

  • Interleaved arrays and crops
  • Arrays elevated above crops/livestock
  • Arrays mounted on greenhouses

Light Management: The system requires careful consideration of panel spacing to ensure sufficient light transmission to ground crops.

Infrastructure Requirements: Supporting structures are designed to homogenize radiation distribution on the ground while allowing access to farm machinery.

Significance of the Agrivoltaic Farming System

  • This dual land-use system offers a sustainable and reliable solution to land scarcity and acquisition for solar energy, including localised transmission and distribution.
  • It improves land productivity by 35-73 per cent, by providing a sustainable solution to land scarcity and acquisition of solar energy.
  • It helps in the reduction of soil erosion and land degradation from enhanced soil moisture.
  • This system also decreased land-use intensity and reduced emissions from land-use change associated with agriculture.
  • It creates an additional source of revenue for the farmers by the sale of power.

Some Examples to boost Agrivoltaic Farming Systems

  • South Korea: Successful cultivation of broccoli under photovoltaic panels, resulting in deeper green colouration and maintained quality.
  • Kenya: Implementation of elevated solar panels with strategic spacing enables farmers to grow high-value crops in previously unviable land.
  • France: Pilot project in Amance featuring over 5,000 solar panels capable of producing 2.5 megawatts at peak times.
  • Japan and China: Leading commercial implementation of agrivoltaic systems with proven economic viability.
  • India: Various projects are under construction viz. Amrol Distributed Solar Power Project (Gujarat), CAZRI plant in Jodhpur (Rajasthan) under PM-KUSUM Scheme.

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