Solar power is certainly a great way to save on some electricity bills and move your home toward a greener, more sustainable future. That said, calculating your power needs and designing a solar system to match those needs can be confusing, and there are a handful of important factors to understand.

One of these is the KWp rating, or kilowatts peak. This is the rate at which your solar system generates energy at peak performance, such as at midday on a sunny day.

But how do you calculate your solar system’s kWp?

**It can be challenging to calculate your solar system’s kWp, as it’s difficult to predict the exact power output of your system due to factors like component efficiency, temperature, location, and weather.**

There are some methods, though, and in this article, we’ll be covering the following:

- The standard for determining kWp
- Calculating the kWp of your system
- Determining the kWp you need in your home

*Calculating the correct kWp of your solar system can be confusing, but we’re here to help! Read on below for our in-depth guide on calculating your solar needs and output.*

**Contents**hide

## What is kWp in a solar panel?

**Put simply, kWp is the peak power capability of a solar panel or solar system**. All solar panels are given a kWp rating by the manufacturer, and this rating indicates the *amount of energy a panel can produce at its peak performance*, such as in the afternoon of a clear, sunny day.

kWp, or kilowatt peak of your panel, is calculated with a standardized test that all solar panel manufacturers must adhere to, with standardized radiance, temperature, and size. These standards are as follows:

- Solar radiation of 1,000-watts/m
^{2} - Ambient temperature of 25-degrees C
- Clear skies

**This standardization makes it possible for you to accurately compare solar panels and their performance when choosing which to purchase for your needs.**

## kWh vs kWp?

kWh, or kilowatt-hours, refers to the energy an appliance uses in one hour. A kilowatt equals 1,000-watts, so if you use a 1,000-watt appliance for one hour, you’ll be consuming 1 kWh of energy.

If your solar system has a kWp of 1,000-watts, for example, your kWh to kWp ratio is 1:1. Of course, this is at peak performance, so the ratio is, in reality, a fair bit lower.

A 1 kWp system operating at peak performance would supply you with one kilowatt of power, but this depends on many factors like efficiency, temperature, and weather, and so these two metrics are certainly important, but somewhat unrelated.

## How do I calculate my solar panel output?

Calculating solar panel output is fairly simple, but depends on the efficiency of your panels, your location, and the amount of sunlight hitting the panels every day.

For example, people living in equatorial regions will have far more sunlight on average per day than those living closer to the poles.

The first metric to check is your solar panel’s wattage rating. If you’re using a 300-watt panel, your panel will be kicking out 300-watts (maximum kWp) under perfect conditions, but again, likely a bit less on average due to temperature, weather, and placement.

A simple formula for calculating solar panel output is:

**Average hours of sunlight x solar panel wattage x 75%(to account for dust, pollution, weather) = daily wattage output.**

So, if you’re getting 6 hours of sunlight per day — on average — with a 300-watt panel, you’ll be getting 1,350-watt-hours per day.

## How many units does 1kw of solar panels produce?

Typically, one “unit” of solar energy equates to 1kWh, which is what a 1kw system is capable of producing in the course of 1 hour of perfect conditions. This means you would again use a very simple formula, system capacity (1kw) x hours of sunlight.

**Going back to our example above, 6 hours of sunlight multiplied by your system capacity (1kw) would give you roughly 6 units, or 6 kWh of energy per day.**

## How many kWh does a house use per day?

On average, the daily kWh consumption for an average home in the United States is just under *29 kWh hours*. This accounts for using energy-heavy appliances like geysers and heating, both of which can be substantially reduced.

This energy usage is also dependent on the size of your home, the building materials of your home, and the number of residents. Also, people living in colder climates will naturally use a significantly higher amount of power to warm their homes.

## How do I calculate kWh?

Calculating the kWh usage of your home is simple: all you do is take the total kWh on your electricity bill and divide it by the days the bill covers. Again, this may fluctuate during the year, but it’s a good ballpark figure.

You can even calculate the amount of kWh your appliances use based on how long they are on for. If you use a 1kWh appliance for 3 hours, for example, that appliance will use 3 kWh per day.

## How do you calculate PV per kWh?

Now that you know how many kWh your home is consuming, you’ll naturally need to calculate how many panels you’ll need to generate sufficient power.

Let’s assume your home uses 10 kWh per day. You’ll need at least 10kWh hours of solar panel output to match this, but most likely a lot more.

This is because no solar panel — or solar setup for that matter — is 100% efficient, plus, this kWh rating is under perfect conditions, which are not guaranteed.

**If you use 10 kWh per day, you’ll need at least 12-15 kWh of solar power output to account for losses.**

As an example, a 200-watt solar panel will produce roughly 200-watt hours per hour under perfect conditions, or 1,200-watt-hours (1.2 kWh) per six hours of sunlight.

You’ll need at least ten of these panels to cover your daily energy usage completely with solar power.

## How many solar panels do I need for 50 kWh per day?

As we’ve already discussed, solar panels are subject to efficiency issues, weather, sun hours, and location, and so it’s almost impossible to give an exact answer. However, there are some rough calculations we can do to get a fairly accurate answer.

Let’s assume you’re using 200-watt panels, with around 4-hours of sun per day(just to be safe), you’ll be getting roughly 800-watt hours (0.8 kWh) per day, per panel. This would mean you’ll need around 62, 200-watt panels to generate 50 kWh per day.

## How much power does 5kW solar produce?

On average, a 5kW solar system will produce around 20kWh per day, again depending on your location and hours per day of sunlight. You may find the system producing more in summer months, 25-30kWh, and less in winter, 15-20kWh.

## Is 1 kW enough to run a house?

Considering the average household in the United States uses roughly 29kWh per day, and 1kW of solar will give you 4-5kW of power with 5 hours of sunlight, this will not be enough for most homes.

*That being said, it can certainly help lower your dependence on mains power and save you money on electricity bills.*

It also helps to look at your energy requirements and usage, and see where you can save on power. For example, using a solar geyser to heat water, a gas fridge, and a stove, and heating your home with a fireplace or gas heater will save a ton of power overall.

In my home, a have a 1kW solar system that provides me with more power than I need, since I save on energy usage by using gas appliances and a solar geyser. This is more than enough to run lights, computers, a TV, and other small appliances.

## How much is a 30 kWh solar system?

For a 30 kWh solar system, the cost depends on several factors:

- The quality of the components you purchase
- Your location
- Installation

You can save quite a bit of money if you install the system yourself, but this is certainly tricky. Installation costs will vary widely depending on who does the installation for you, but for a system this large you can expect to pay around $10,000 for installation.

In general, solar panels cost around two or three dollars per watt. **Taking into consideration the quality of components you choose, installation, and your location, you can expect to pay anywhere from $60,000 to $80,000 for a 30 kWh solar setup.**

## How many solar panels do I need for 2000 kWh per month?

2000 kWh per month equates to roughly 66 kWh per day. Again, let’s go with 200-watt panels (as these are some of the most common), with around 4-hours of sun per day(just to be safe), you’ll again be getting roughly 800-watt hours (0.8 kWh) per day, per panel.

**In order to produce 66 kWh per day of power, you’d need 82, 200-watt solar panels.**

## How much should I pay for a 6kW solar system?

As mentioned earlier, the average cost per watt for solar setups is $2-$3 in the US. This works out to roughly $12,000, but you’ll also need to take installation into account, which will bring the cost up to roughly $14,000-$15,000.

## 1 kWp solar panel size

If you wanted to run a solar system with a panel output of 1 kWP, you’d need 1 kilowatt of power. 1 kilowatt would be the peak capability of your panels on a day with full sun, which is 1,000-watts. Most commonly, solar panels come in 200-350 watt units, although there are some higher power panels available too.

For 1 kWp, you’d need five 200-watt panels, four 250-watt panels, or three 350-watt panels. Remember, this is the *peak performance *rating of your solar array, and so your panels will only achieve this kind of output for a few hours a day if it is clear and sunny.

## How to calculate solar panel efficiency

Most solar panels have an efficiency rating of between 10% and 15%, which will usually be indicated by the manufacturer.

Efficiency also depends on the type of panel you’re using (monocrystalline vs polycrystalline), where your panel is facing, and much heat it is generating (solar panels should never be laid flat on a roof, as they lose efficiency exponentially when they overheat.)

**The efficiency rating of a solar panel refers to its ability to convert sunlight into usable energy.** So, if a panel has an efficiency rating of 15%, it will be able to harness 15% of the photons that hit it. Due to real-world conditions of weather and placement, a solar panel rarely produces its full wattage output rating.

To calculate the efficiency of your panel, you’ll need to look up the amount of sunlight that hits the earth in your particular area. Multiply this amount by the surface area of your panel, divide the maximum kWp of your panel by this number, and then multiply it by 100% to get an accurate efficiency rating.

*Let’s say 1,000-watts per square meter of sunlight is hitting your area, and you have a 1 square meter panel, you’ll end up with 1,000-watts exactly. If you have a 200 kWp panel, the efficiency will be roughly 20% (negating any other environmental factors, of course.)*

### Conclusion

The first step in designing a solar setup for your home is in calculating how many kWh or kWp you’ll need. Check your electricity bill for your monthly use, and then divide that number by 30 to calculate your daily needs.

Of course, you can always reduce your electricity usage, or simply use solar power to augment your mains power and reduce your electricity bills.

Once you’ve calculated your power requirements, you can then design a solar system that can provide you with all, or even just a portion of your power needs.

Hopefully, we’ve helped you with all the calculations you need so you can get started going off-grid, *today*!