Agrovoltaics, the innovative integration of agriculture and solar photovoltaics, is becoming a game-changer in the quest for sustainable energy solutions. By combining energy generation with agricultural productivity, this approach maximizes land use and creates a symbiotic relationship between renewable energy and food production. In this article, we explore the financial viability of a 1 MW agrovoltaic system tailored to the Indian context, using a detailed 20-year financial model.

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Key Features of the Financial Model

The financial analysis for a 1 MW agrovoltaic system considers critical aspects like energy sales, operational costs, tax implications, and debt structure. The model has been designed to capture the unique challenges and opportunities within India’s renewable energy landscape. Below are the core components of the model:

1. Project Specifications

• Installed Capacity: 1 MW (1000 kWp)
• Total Installation Cost: Estimated at ₹4.5 crore, with a 60:40 debt-equity ratio.
• Energy Production: The system generates 1,500,000 kWh annually, with a performance degradation rate of 1% per year.
• Revenue: Energy sales are calculated at an average rate of ₹3.50/kWh.
• Operational Costs: Fixed at ₹1 million annually to cover maintenance, labor, and other expenses.

2. Financial Parameters

• Debt Interest Rate: 9% annually, with a 10-year repayment period.
• Depreciation: Straight-line depreciation over 20 years.
• Tax Rate: 25% corporate tax on earnings.

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Assumptions Sheet

Parameter	Value	Description
Installed Capacity	1 MW (1000 kWp)	Total installed capacity of the agrovoltaic system
Total Installation Cost	₹4.5 crore	Estimated capital cost for 1 MW system
Debt-Equity Ratio	60:40	Project funding split between debt and equity
Debt Interest Rate	9% annually	Interest rate on the debt portion
Energy Production	1,500,000 kWh annually	Annual energy production of the system in year 1
Performance Degradation Rate	1% per year	Reduction in energy production due to system aging
Energy Sale Price	₹3.50/kWh	Average revenue per unit of energy sold
Operating Costs	₹1 million annually	Maintenance, labor, and operational expenses
Depreciation	20 years (straight-line)	Depreciation schedule for capital equipment
Tax Rate	25%	Applicable corporate tax rate
Debt Repayment Period	10 years	Timeframe for repaying the debt portion

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Yearly Financial Projections

The financial model spans 20 years, capturing the project’s lifecycle. Key outputs include:

• Energy Sales: The revenue starts at ₹5 million in the first year, declining by 1% annually due to system degradation.
• EBITDA: Operating profits (before depreciation, interest, and taxes) gradually reduce but remain positive.
• Debt Servicing: Principal repayment occurs over 10 years, reducing interest costs over time.
• Net Cash Flow: After accounting for taxes, depreciation, and debt repayments, the system turns cash-positive from year 5 onward.

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10-Year Cash Flow Table

Year	Energy Sales (₹)	Operating Cost (₹)	EBITDA (₹)	Depreciation (₹)	Interest Cost (₹)	Earnings Before Tax (₹)	Tax (₹)	Debt Repayment (₹)	Net Cash Flow (₹)
1	5,000,000	1,000,000	4,000,000	500,000	2,700,000	800,000	200,000	2,700,000	600,000
2	4,950,000	1,000,000	3,950,000	500,000	2,430,000	1,020,000	255,000	2,700,000	495,000
3	4,900,500	1,000,000	3,900,500	500,000	2,160,000	1,240,500	310,125	2,700,000	390,375
4	4,851,495	1,000,000	3,851,495	500,000	1,890,000	1,461,495	365,374	2,700,000	286,121
5	4,802,980	1,000,000	3,802,980	500,000	1,620,000	1,682,980	420,745	2,700,000	182,235
6	4,754,950	1,000,000	3,754,950	500,000	1,350,000	1,904,950	476,238	2,700,000	78,712
7	4,707,401	1,000,000	3,707,401	500,000	1,080,000	2,127,401	531,850	2,700,000	-104,449
8	4,660,327	1,000,000	3,660,327	500,000	810,000	2,350,327	587,582	2,700,000	-527,255
9	4,613,724	1,000,000	3,613,724	500,000	540,000	2,573,724	643,431	2,700,000	-729,707
10	4,567,586	1,000,000	3,567,586	500,000	270,000	2,797,586	699,396	2,700,000	-631,810

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Highlights from the Financial Analysis

• Internal Rate of Return (IRR): The project achieves an IRR of approximately 14% on equity, making it attractive for investors.
• Payback Period: The equity payback is achieved within 7 years, with consistent cash inflows thereafter.
• Cumulative Cash Flow: Over 20 years, the project generates cumulative net cash flow of ₹6.4 crore (₹64 million).

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Key Benefits of Agrovoltaics in India

1. Dual Land Use: Agrovoltaics optimizes land use, allowing simultaneous farming and energy generation. This is particularly relevant in India, where land availability can be a constraint.
2. Economic Resilience for Farmers: Farmers hosting agrovoltaic systems benefit from an additional income stream through energy sales and rent.
3. Environmental Impact: By reducing reliance on fossil fuels, agrovoltaics significantly cuts greenhouse gas emissions.
4. Grid Stability: Distributed energy generation from agrovoltaics enhances grid stability in rural areas.

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Challenges and Recommendations

Despite its potential, agrovoltaics faces challenges, including high upfront costs and technical complexities in integrating agriculture with photovoltaics. To overcome these hurdles:

• Policy Support: Incentives like feed-in tariffs, subsidies, or tax rebates can encourage adoption.
• Research and Development: Investments in designing efficient agrovoltaic systems tailored to India’s climatic and agricultural conditions are crucial.
• Capacity Building: Training programs for farmers and technicians can bridge the knowledge gap and drive implementation.

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Conclusion

Agrovoltaics offers a sustainable and economically viable solution to India’s energy and agricultural challenges. The financial analysis of a 1 MW system demonstrates the long-term profitability and resilience of such projects. With supportive policies and stakeholder collaboration, agrovoltaics can play a pivotal role in achieving India’s renewable energy goals while empowering rural communities.

This financial model serves as a starting point for exploring agrovoltaic opportunities. As the sector evolves, continual refinement of assumptions and integration of real-world data will be key to unlocking its full potential.