Solar Panel System Calculator
Size a solar panel system from daily energy usage, sun hours, and panel wattage. Enter values for instant results with step-by-step formulas.
Formula
System kW = Daily kWh / (Sun Hours * (1 - Loss%)), Panels = System W / Panel W
The system size in kilowatts is calculated by dividing the adjusted daily energy requirement by peak sun hours. The number of panels is determined by dividing the total system wattage by individual panel wattage, rounded up to the nearest whole panel.
Worked Examples
Example 1: Average US Home Solar System Sizing
Problem: A home uses 30 kWh per day. The location gets 5 peak sun hours. Using 400W panels with 20% system losses, how many panels are needed?
Solution: Adjusted daily need = 30 / (1 - 0.20) = 37.5 kWh\nRequired system size = 37.5 / 5 = 7.5 kW\nNumber of panels = ceil(7500 / 400) = 19 panels\nActual system = 19 * 400 = 7600W = 7.6 kW\nDaily production = 7.6 * 5 * 0.80 = 30.4 kWh\nAnnual production = 30.4 * 365 = 11,096 kWh
Result: 19 panels (7.6 kW system) | 30.4 kWh/day | 11,096 kWh/year
Example 2: Small Cabin Off-Grid System
Problem: An off-grid cabin uses 8 kWh per day. The location gets 4 peak sun hours. Using 300W panels with 25% losses. Calculate system requirements and savings vs generator.
Solution: Adjusted daily need = 8 / (1 - 0.25) = 10.67 kWh\nRequired system size = 10.67 / 4 = 2.67 kW\nNumber of panels = ceil(2670 / 300) = 9 panels\nActual system = 9 * 300 = 2700W = 2.7 kW\nDaily production = 2.7 * 4 * 0.75 = 8.1 kWh\nAnnual production = 8.1 * 365 = 2,957 kWh\nGenerator fuel savings at $0.30/kWh = $887/year
Result: 9 panels (2.7 kW) | 8.1 kWh/day | Saves ~$887/year vs generator
Frequently Asked Questions
What system losses should I account for in solar panel calculations?
Total system losses typically range from 15 to 25 percent and come from multiple sources throughout the system. Inverter conversion losses account for 3 to 5 percent as DC power from panels is converted to AC. Wiring and connection losses add 1 to 3 percent. Temperature derating reduces output by 5 to 15 percent because solar panels lose efficiency in hot weather at about 0.3 to 0.5 percent per degree Celsius above 25 degrees. Soiling from dust, pollen, and bird droppings causes 2 to 5 percent loss. Shading from trees or neighboring structures can cause 0 to 20 percent loss depending on the site. Module mismatch and degradation over time add another 2 to 3 percent. A 20 percent total loss factor is a reasonable default for well-designed systems.
How many solar panels do I need for my home?
The number of panels depends on your energy consumption, local sun hours, panel wattage, and system losses. Using the formula: Number of Panels = Daily Usage kWh / (Sun Hours * Panel Wattage/1000 * (1 - Loss Factor)). For a typical US home using 30 kWh per day with 5 peak sun hours, 400W panels, and 20 percent losses, you need about 30 / (5 * 0.4 * 0.8) = 18.75, rounded up to 19 panels. This gives a system size of 7.6 kW. Most residential systems range from 5 to 12 kW. Higher efficiency panels reduce the number needed but cost more per watt. Consider future energy needs like electric vehicles when sizing your system.
How long does it take for a solar panel system to pay for itself?
The payback period depends on system cost, electricity rates, solar production, and available incentives. At the national average electricity rate of about $0.12 per kWh, a typical 8 kW residential system costing $22,400 before incentives saves about $1,050 per year, giving a 21-year payback. However, the 30 percent federal investment tax credit reduces the cost to $15,680, cutting payback to about 15 years. In states with high electricity rates like California or Hawaii at $0.25 to $0.40 per kWh, payback can be 6 to 10 years. Net metering policies, state rebates, SRECs, and rising electricity costs all accelerate payback. Most solar panels have 25 to 30 year warranties, so they generate free electricity for years after paying for themselves.
Do solar panels work on cloudy days or in winter?
Solar panels do produce electricity on cloudy days, though at reduced output. Light overcast conditions typically reduce production to 50 to 80 percent of clear-sky output, while heavy overcast drops production to 10 to 30 percent. In winter, production decreases due to shorter days and lower sun angle, not because of cold temperature. In fact, solar panels are more efficient in cold weather because silicon photovoltaic cells perform better at lower temperatures. A system in the northern US might produce only 30 to 40 percent of its summer output during December and January. Annual production calculations using peak sun hours already account for seasonal and weather variations. Snow coverage temporarily blocks production but panels usually clear quickly due to their angle and dark surface.
How much roof space do I need for a solar panel system?
A standard residential solar panel is approximately 5.4 feet by 3.25 feet, occupying about 17.5 square feet. A typical 8 kW system with 400W panels needs 20 panels, requiring about 350 square feet of usable roof space. However, not all roof area is usable because you need to account for setbacks from roof edges (typically 3 feet), obstruction clearances around vents and skylights, and optimal orientation. South-facing roof sections in the northern hemisphere receive the most sun, though east and west-facing installations typically produce 80 to 85 percent as much. Flat roofs require tilted mounting systems that add spacing between rows to avoid self-shading. Ground-mounted systems are an alternative when roof space or orientation is inadequate.
Should I add battery storage to my solar panel system?
Battery storage makes sense in certain situations but is not always cost-effective. Batteries are most valuable when your utility does not offer net metering or offers unfavorable rates for exported solar energy, when you experience frequent power outages and want backup, when time-of-use rates create a large price difference between peak and off-peak electricity, or when you want energy independence. A typical 10 kWh home battery system costs $8,000 to $15,000 installed. At current prices, batteries alone rarely pay for themselves through energy arbitrage. However, the value of backup power during outages is subjective and can be significant for homes with medical equipment or in areas with unreliable grids. Battery prices continue to decline and may become more economical in the coming years.