How many solar panels do I need?

Divide your annual electricity use by the yearly output of one panel. Each panel produces roughly its kW rating times your daily peak sun hours times a performance ratio, times 365. A 430 W panel at 3.8 sun hours and 80% performance makes about 477 kWh a year, so a 4,200 kWh home needs about 9 panels. The calculator does this for you and rounds up.

What are peak sun hours?

Peak sun hours are the number of hours per day that sunlight averages 1,000 watts per square metre — the standard test intensity. It bundles a whole day of varying sun into one equivalent figure. The UK averages about 2.5 to 3.5, southern Spain 4.5 to 5.5 and desert regions 6 or more. It is not the same as daylight hours.

What is a performance ratio and why is it below 100%?

The performance ratio captures real-world losses that the panel nameplate ignores: inverter conversion, heat, wiring resistance, dust and soiling, and module mismatch. A well-designed roof system runs at about 75 to 85%. Lowering this value reduces estimated output proportionally, so it is worth setting honestly.

How is system size in kWp calculated?

kWp (kilowatts peak) is simply the total panel wattage divided by 1,000. Twelve 430 W panels give 5,160 W, or 5.16 kWp. It is the nameplate capacity under standard test conditions and is the figure installers quote and grids use for connection limits.

How accurate is the savings and payback estimate?

It is a planning estimate, not a quote. Annual benefit combines bill savings on the share you use on-site plus income from exported units. Payback divides install cost by annual benefit. It ignores panel degradation, future price changes, battery storage and finance interest, so treat it as a starting point and confirm with an installer.

Does roof orientation and shading matter?

Yes, a great deal. A south-facing, unshaded roof in the northern hemisphere yields the most; east or west roofs lose roughly 10 to 20%, and any shading from chimneys or trees cuts output sharply. This calculator assumes a reasonable installation — reflect a poorer roof by lowering the peak sun hours or performance ratio.

Solar Panel Calculator

A solar panel calculator that turns a few real numbers into a complete picture of a rooftop solar array: how many panels you need, the system size in kWp, the annual energy produced, and a realistic estimate of the money it saves each year. You can work in two directions. Start from your energy need — type the monthly kWh from a recent electricity bill and the tool tells you how many panels cover it. Or start from your roof area in m² or ft² and see how many panels physically fit and what fraction of your usage they would offset. It is built for homeowners comparing quotes, renters weighing a move to solar, and anyone who wants to sanity-check an installer’s sizing before signing.

How it works

The engine rests on one core relationship. A single panel’s daily output is its rating in kilowatts multiplied by your local peak sun hours and a performance ratio that accounts for real losses. Multiply by 365 for the annual figure:

Annual kWh per panel = (Wattage / 1000) × peak sun hours × performance ratio × 365

In energy mode the calculator takes your yearly demand (monthly kWh times twelve) and divides by that per-panel output, rounding up to whole panels. In roof mode it converts your roof area to square metres, applies a usable-fraction allowance for setbacks, vents and shading, then divides by the area of one panel to count how many fit. Either way it then sums the array: total panels give the system size in kWp (total watts divided by 1,000), the daily, monthly and annual output, and the economics. Savings split the generation into a self-used share — valued at your retail electricity price — and an exported share valued at your export tariff. Dividing the install cost (per-watt times system watts) by that annual benefit yields a simple payback in years. Everything recomputes instantly as you type and auto-saves in your browser; no figures are ever uploaded.

Worked example

A home using 350 kWh per month needs 4,200 kWh a year. With 430 W panels at 3.8 peak sun hours and an 80% performance ratio, each panel makes about 477 kWh a year. Dividing 4,200 by 477 and rounding up gives 9 panels — a 3.87 kWp system that produces roughly 4,300 kWh annually.

If you self-consume 50% at an electricity price of 0.28 per kWh and export the rest at 0.07 per kWh, the array saves about 602 on bills and earns about 150 in export income — an annual benefit near 750. At an install cost of 1.90 per watt the system costs around 7,350, giving a simple payback of roughly 9.8 years and a 25-year benefit well above 18,000 before any price rises.

Monthly use	Sun hours	Panel	Panels	System	Annual output
250 kWh	3.5	400 W	8	3.20 kWp	3,270 kWh
350 kWh	3.8	430 W	9	3.87 kWp	4,295 kWh
500 kWh	4.5	450 W	11	4.95 kWp	6,504 kWh
700 kWh	5.0	450 W	13	5.85 kWp	8,541 kWh

Every figure is calculated in your browser. Treat the savings as planning estimates, not a quote — orientation, shading, weather and tariffs all move the real numbers.