Quick Summary: What Is an On-Grid Solar System and How Does It Work?
What is an on-grid solar system?
An on-grid solar system, also known as a grid-tied solar system, is directly connected to the public utility grid and generates electricity from solar panels.
How does it work?
Solar panels generate electricity, which is used to power your home or business. Any excess electricity generated by an on-grid solar system can be fed back into the grid, allowing homeowners to earn credits through net metering.
Main benefits:
Grid connection: Seamless integration with the utility grid ensures continuous power supply.
Net metering: Net metering allows homeowners to earn credits for excess electricity fed back to the grid, effectively reducing their electricity bills.
Cost savings: On-grid solar can cut your electricity bills by up to 90%.
Introduction — Maxira Solar and On-Grid Solar
An on-grid solar system is the most cost-effective choice for urban Indian homeowners with a reliable grid connection.. This guide is designed for Indian homeowners and businesses considering on-grid solar solutions. We cover system types, savings, installation, government incentives, and maintenance to help you make an informed decision.
Maxira Solar is an MNRE-empanelled solar installer, trusted for quality and compliance across India. For residential customers, on-grid solar is often the best solar system choice for sustainable living, as it reduces carbon footprint, supports eco-conscious lifestyles, and delivers fast financial returns through government incentives and net metering. Many governments encourage solar adoption by offering financial incentives such as subsidies, tax credits, or rebates for installing solar systems.
What Is an On-Grid Solar System and How Does It Work
An on-grid solar system, also known as a grid-tied solar system, is directly connected to the public utility grid and generates electricity from solar panels.Grid connected systems and grid systems enable seamless electricity flow and grid integration, allowing excess solar energy to be fed back into the grid through net metering. Excess electricity generated by an on-grid solar system can be fed back into the grid, allowing homeowners to earn credits through net metering.
The main difference between an on-grid solar system and an off grid solar system (or off grid systems) is how excess energy is managed: on-grid systems feed surplus power to the grid, while off-grid systems store energy in batteries for use during outages or at night. Hybrid systems combine grid connection with battery storage, offering both grid integration and backup power for enhanced reliability.
Key Components: Solar Panels, Grid-Tie Inverter, Net Metering
The major components of an on grid solar system include solar panels, a solar inverter (specifically a grid-tie inverter), a utility meter, and mounting systems. Solar panels capture sunlight and convert it into direct current (DC) electricity. The solar inverter then converts this DC electricity into alternating current (AC) electricity, which is suitable for household appliances and for feeding into the grid. The grid-tie inverter is essential for energy production and ensures compatibility with both your home and the utility grid.
A utility meter tracks the flow of electricity between your home and the grid, enabling net metering benefits—so you can earn credits for surplus energy sent back to the grid. Mounting systems securely fix the solar panels to your roof, whether RCC, tiled, or sheet types, ensuring safety and optimal energy production. Additional safety items such as surge protection devices, earthing kits, and AC/DC isolators are also included to protect your system and home.
With an understanding of the main components, let’s explore the different types of solar panels and how to size your system for optimal performance.
Solar Panels: Types, Performance, and kW On Grid Sizing
Monocrystalline, polycrystalline, and thin-film solar panels differ in efficiency, cost, and appearance. Monocrystalline panels offer the highest efficiency and are ideal for limited roof space, while polycrystalline panels are more affordable but slightly less efficient. Thin-film panels are lightweight and flexible but have lower efficiency and are best suited for large open areas.
Solar panels are typically installed on rooftops or open ground spaces to maximize sunlight exposure. These panels generate electricity by capturing sunlight and converting it into direct current (DC) electricity. An inverter then converts this DC electricity into alternating current (AC), which can be used to power your home or business and feed excess energy into the grid.
To calculate the required kW capacity for your on grid solar system, divide your average monthly electricity consumption (in kWh) by 120. For example, if your monthly load is 600 kWh, you need a 5 kW system (600 ÷ 120 = 5). This ensures your system is sized to meet your energy needs and maximize savings.
For optimal performance, the recommended panel tilt angle in Indian cities is close to the local latitude. In Delhi, a tilt of 28°–30° is ideal, while in Bangalore, 12°–15° works best. Proper tilt ensures maximum solar generation throughout the year.
With the right panels and system sizing, the next step is to understand the role of inverters and metering in your on-grid solar setup.
Inverters, Grid-Tie Inverter Types, and Metering Details
On-grid solar systems use different types of inverters to convert the direct current (DC) electricity generated by solar panels into alternating current (AC) electricity compatible with household appliances and the power grid. The most common inverter types include string inverters, microinverters, and hybrid inverters.
String inverters connect a series of solar panels in a string and convert their combined DC output into AC. They are widely used for residential and commercial systems due to their cost-effectiveness and reliability. However, their performance can be affected if one panel is shaded or underperforming, as it impacts the entire string.
Microinverters are installed on each individual solar panel, converting DC to AC at the panel level. This setup maximizes energy harvest from each panel independently, improving overall system efficiency, especially in installations with shading or complex roof orientations. Microinverters typically have higher upfront costs but offer better performance and easier scalability.
Hybrid inverters combine the functions of a grid-tie inverter with battery management capabilities. They enable integration of battery storage with the on-grid system, allowing for backup power during outages and greater energy self-consumption. Hybrid inverters are essential for systems that require battery storage or want flexibility between on-grid and off-grid operation.
A bi-directional utility meter is a crucial component for net metering benefits. It accurately measures electricity flowing from the grid to the home and from the solar system back to the grid. This dual measurement allows homeowners to receive credits for surplus electricity fed into the grid, reducing their electricity bills.
When selecting an inverter, efficiency ratings and warranty terms are important considerations. High inverter efficiency ensures minimal energy loss during DC to AC conversion, maximizing solar power utilization. Warranties typically range from 5 to 12 years, reflecting the inverter’s expected lifespan and reliability. Choosing an inverter with a strong warranty and proven efficiency helps ensure long-term system performance and peace of mind.
With the core components and their roles clarified, let’s compare the main types of solar systems available for Indian homes and businesses.
Compare On-Grid Solar, Off Grid Solar Systems, and Hybrid Solar Systems
Feature
On-Grid Solar System
Off-Grid Solar System
Hybrid Solar System
Grid Connection
Yes
No
Yes
Battery Storage
Not required
Required
Optional (for backup)
Net Metering
Yes (earn credits for surplus power)
No
Yes (if grid-connected)
Power During Outage
No (unless hybrid with battery)
Yes (from batteries)
Yes (from batteries)
Initial Cost
Lowest
Highest (due to batteries)
Medium to High (depends on battery size)
Best For
Urban/connected areas seeking cost savings and easy installation
Remote/rural areas without grid access
Users needing backup power and grid interaction
Maintenance
Low
High (battery maintenance)
Medium (battery and inverter maintenance)
Government Incentives
Yes (subsidies, net metering)
Limited
Yes (for grid-connected portion)
On-grid solar systems connect directly to the utility grid, providing continuous access to grid power. This grid backup ensures your energy needs are always met, even during cloudy days or at night when solar generation is low. You never have to worry about running out of electricity, as the system automatically draws grid power when needed.
A key benefit of on-grid solar is net metering. When your solar panels generate extra energy—more than your immediate consumption—the excess power, also called surplus energy or excess electricity, is fed back into the grid. This excess energy fed to the utility can earn you credits or reduce your electricity bill, depending on how much energy your system produces versus how much you use. If you generate extra power, you can sell it to the grid or receive compensation from your utility provider.
On-grid solar systems are also relatively low-maintenance, as they lack the complex battery storage components required by off-grid or hybrid systems.
Off-grid solar systems, in contrast, are designed for locations without access to the utility grid. They require significant battery storage to supply power during periods of low sunlight, which increases both the initial cost and maintenance requirements. Off-grid systems are preferable in remote or rural areas where grid power is unavailable or unreliable.
Hybrid solar systems combine the benefits of both on-grid and off-grid setups. They use battery storage to provide backup power during outages, while still allowing for excess energy to be fed back to the grid when possible. This setup offers flexibility but comes with higher costs and more complex installation compared to a standard on-grid solar system.
Overall, an on-grid solar system offers the lowest cost and fastest payback for most Indian households.
Off-Grid Solar Systems: Use Cases and Battery Needs
Off-grid solar systems are recommended primarily for remote locations where access to the main power grid is unavailable or unreliable. These systems are ideal for rural homes, farms, cabins, and off-site facilities that require complete energy independence from the grid. Since they are not connected to the main power grid, off-grid solar systems rely heavily on battery storage to provide a consistent power supply during nighttime or periods of low sunlight. Battery sizing depends on the total energy consumption and desired backup duration, typically calculated to cover several days of autonomy. Proper battery management and maintenance are critical to ensure system reliability and longevity.
Hybrid Solar Systems and Battery Storage Options
Hybrid solar systems combine the benefits of on-grid solar with battery storage, offering a grid tied system that provides power during outages while allowing excess energy to be fed back to the grid. These systems are suitable for users seeking sustainable energy solutions with backup power capabilities, balancing grid dependency with energy independence. Common battery chemistries include lithium-ion, lead-acid, and flow batteries, each with different lifespans, efficiencies, and warranty norms. Hybrid inverters manage both grid interaction and battery charging, optimizing energy use and ensuring a greener future by reducing reliance on fossil fuels and enhancing energy resilience.
With system types and their applications clarified, let’s see how on-grid solar directly impacts your electricity bills and return on investment.
How On-Grid Solar Cuts Your Electricity Bill and Improves ROI
To estimate your monthly ₹ savings with an on grid solar system, start by calculating your average monthly electricity consumption in kWh. Multiply this by your current per-unit tariff to find your typical monthly bill. With an on-grid solar installation, you can offset a significant portion of this usage, leading to substantial cost savings by reducing your electricity bills and decreasing your dependency on the traditional utility grid. Over time, these savings add up to long-term financial benefits.
The payback period is the time it takes for your total savings from reduced electricity bills to equal your initial investment in the solar system. For most residential on-grid solar installations, the payback period can be as short as 4-5 years, depending on your location, system size, and local electricity tariffs. After this period, all further savings contribute directly to your return on investment (ROI), making on-grid solar a financially attractive option.
Net metering is a key benefit of on-grid solar systems. It allows homeowners to receive credits for any excess electricity their solar panels generate and feed back into the grid. These credits are applied to your electricity bill, effectively reducing your monthly charges. For example, if your system produces more electricity than you consume during the day, the surplus is exported to the grid and credited to your account, further increasing your cost savings and improving your overall ROI.
Understanding your potential savings and ROI is crucial, but accurate system sizing is equally important for maximizing benefits.