Green power generation using Solar Photovoltaic (PV) systems integrated with Battery Energy Storage Systems (BESS) represents a transformative approach to sustainable energy production. This hybrid configuration enables efficient harnessing of solar energy while addressing its inherent intermittency through energy storage, thereby ensuring reliable and dispatchable power supply.
Solar PV modules convert sunlight directly into electricity, while BESS stores excess energy generated during peak solar hours for use during non-generation periods. Together, they form a resilient and flexible power generation system suitable for modern energy demands.
✔ Enhanced reliabillity & dispatchability for Grid stability and support.
✔ Solar Peak and Evening Peak Shifting / Renewable Firming / CUF & Revenue increase.
✔ Zero carbon footprint and supports decarbonization and sustainability goals.
✔ Increased Renewable Penetration and improved energy economics.
✔ Supports energy storage and grid stability.
✔ Electric Vehicle (EV) Charging Infrastructure.
✔ Reduces dependence on fossil fuels.
Performs detailed hourly Global Horizontal Irradiance (GHI) and Plane of Array (POA) Irrandiance calculation by evaluating actual factors like solar time, hour angle,
declination, Zenith Angle, Solar Azimuth and angle of Incidence using the inputs tilt angle, tracking, Direct Normal Irradiance (DNI) and
Direct Horizontal Irradiance (DHI). (DNI & DHI are obtained from site solar hourly data generated by module.)
Using this hourly GHI value & POA Irradiance, hourly PV electricity generation is worked-out.
Solar PV integrated with BESS is a cornerstone technology for the future of green energy systems. By combining clean energy generation with intelligent storage,
it overcomes the limitations of standalone solar systems and delivers reliable, efficient, and sustainable power. This solution is essential for achieving energy security, economic efficiency, and environmental sustainability in modern power systems.
Solution module intelligently balances charging and discharging sequence based on the power demand / delivery options namely Solar Peak and Evening Peak Shifting / Renewable Firming / CUF & Revenue increase and accordingly establishes the
annual charging cycles to evaluate the battery replacement life.
✔ Establishes project identity, client details, and base currency.
✔ Defines project location, geographic coordinates, and reference year for solar resource assessment.
✔ Specifies renewable energy capacity and the intended role of the BESS.
✔ Utilizes PV module library data, gets OEM data including technology type, efficiency, power rating, temperature coefficients, NOCT, and physical dimensions.
✔ Captures key system design and operational parameters such as tilt, tracking, inverter efficiency, system losses, layout ratios, and replacement assumptions.
✔ Details BESS configuration, including storage capacity, depth of discharge, autonomy, round-trip efficiency, degradation, replacement strategy, and cost.
✔ Incorporates operating assumptions such as auxiliary consumption, O&M costs, working capital, and water usage.
✔ Defines CAPEX components for solar, BESS, land, and region-specific labor factors.
✔ Establishes financial structure including equity mix, interest rates, taxation, depreciation, and discount rate.
✔ Accounts for incentives, subsidies, revenue mechanisms, and target power sale price.
✔ Includes degradation, curtailment, transmission losses, and escalation factors (WPI, CPI, CAPEX, tariff).
✔ Sets the carbon accounting framework, including emission factors, lifecycle intensity, standards, and carbon credit pricing.
✔ Highlights Site hourly ambient data and generation analytics results in readable tables and graphs.
✔ Summarises solar generation outputs, including gross and net renewable electricity delivered annually.
✔ Captures BESS behaviour such as charge/discharge cycles, usable energy, throughput and system losses.
✔ Quantifies total renewable power available as exportable green power.
✔ Estaimates total land requirement for the project and cost of the land including breackdown.
✔ Consolidates investment outcomes including total CAPEX, borrowing levels, IDC and installed cost per kW.
✔ Presents carbon performance results including lifecycle CO₂ intensity, per-kg emission reductions and total annual savings.
✔ Displays additional revenue generated from carbon credits due to avoided emissions.
✔ Highlights project profitability across power export and carbon revenue streams.
✔ Provides key techno-economic indicators such as cost of generation, levelized costs and annual revenue potential.
✔ Offers a clear view of overall project efficiency, financial viability and environmental benefit.
✔ Generates a comprehensive PDF Report and excel documents for hourly ambient data, data analytics results and financial model.
