Green Energy
- Where Is Your State In The Solar Race?
Solar households now represent almost 1.7 GW of installed capacity says Professor Ray Wills, chief adviser to the Sustainable Energy Association (SEA). The impressive tally, gained from data up until the end of March sourced...
- 8mw Deal For Canadian Solar
Canadian Solar has supplied more than 8MW of solar modules to groSolar for three utility and commercial photovoltaic projects in the United States.All three projects use Canadian Solar’s CS6p module. The largest project is a 6MW plant currently...
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The small island of Palau, an island nation located 500 miles east of the Philippines and with a population of 21,000 people, has installed a 226.8kW solar energy array on its airport. The panels were supplied by Kyocera, one of the world’s...
- Lifespan Of A Solar Power System Is Far Longer Than The 20 Years
As indicated in a study Josh wrote on just a couple weeks ago, the lifespan of a solar power system is far longer than the 20 years most analysts use to calculate solar power costs. Last November, Susan featured one that was going strong at 30 years....
- Estimation Of Solar Pv System Output
Factors Affecting Output Standard Test Conditions Solar modules produce DC electricity. The dc output of solar modules is rated by manufacturers under Standard Test Conditions (STC). These conditions are easily recreated in a factory, and allow for consistent...
Green Energy
How do you calculate how many kWh a solar installation will produce in a year?
Remember your utility charges you by the kWh, but solar installations are sold by the watt or kilowatt.
But there’s a quick way to roughly convert kW into kWh. In our part of the country, when the solar installation is ideally located (facing perfectly south, no shading), each 1000 watt (1kW) section of installed panels produces 1,350 kWh/year. So simply multiply the kW size of the system you’d like to purchase by 1,350. For example: 6 kW system x 1,350 kWh = 8,100 kWh expected annual production. If you use 15,000 kWh annually, this is more than half your electric bill!
The federal government has a online calculator that’s available to the public called PV Watts . It can provide a more refined realistic estimate of what to expect. It can be a little tricky to use if your unfamiliar with it. Ask us and we can help you.
Where does the factor 1350 come from? Well to start, in our part of the country when a solar installation is ideally located (facing perfectly south, no shading, etc), it receives about 4.5 “peak hours” of sunlight on average every day. Multiply 4.5 hours times 365 days/year = ~1,640 hours of peak sunlight every year.
So to go from the system’s kW size (referred to as “Power” in scientific terminology) to kWh that that system will actually produce (referred to as “Energy” in scientific terminology) in one year, first just multiply ‘kW’ times ‘peak sunlight hours per year’. For example: 6 kW system (times) ~1640 hours = ~9,840kWh (DC) of energy produced per year.
BUT NOW we need to take into account some losses inherent in the installation’s operations (when power is converted from DC to AC by the inverter, the specific module’s slight variation from nameplate to actual wattage, losses as the electricity flows along the wires, etc). This is often referred to as the “derate” factor. Under ‘standard test conditions’ this typically amounts to about 18% of the total potential energy production.
So the real world estimate of how much energy a 6kW system would produce in one year is actually calculated like this: 9,840kWh (times) 82% = 8,069kWh (AC)/year. (Or using the shortcut for our part of the country that’s shown above: 6kW x 1350 = 8,100kWh (AC)/year.) Even still if you use 15,000 kWh annually, this is more than half your electric bill!
Now when a still-viable solar installation is not ideally situated in relation to the sun (orientation is off of direct south, and angle to the sun is less or greater than optimal), the solar installation does not get to take full advantage of those peak hours. Combine this with the derate factor, and there can be as much as 35% of the total possible energy production that’s lost: 9,840kWh (times) 65% = 6396 kWh (AC)/year. But even still, if you use 15,000 kWh annually, this is more than 1/3 of your electric bill.
Two other factors not explained here that also impact total energy production are: shading that the solar installation undergoes during different times of the day and year, and .5 – .8% expected annual decline in panels’ intrinsic production capacity. (Air temperatures also have impact a solar installation’s output, but this accounted for in the original “peak hours” estimate.)
- Where Is Your State In The Solar Race?
Solar households now represent almost 1.7 GW of installed capacity says Professor Ray Wills, chief adviser to the Sustainable Energy Association (SEA). The impressive tally, gained from data up until the end of March sourced...
- 8mw Deal For Canadian Solar
Canadian Solar has supplied more than 8MW of solar modules to groSolar for three utility and commercial photovoltaic projects in the United States.All three projects use Canadian Solar’s CS6p module. The largest project is a 6MW plant currently...
-
The small island of Palau, an island nation located 500 miles east of the Philippines and with a population of 21,000 people, has installed a 226.8kW solar energy array on its airport. The panels were supplied by Kyocera, one of the world’s...
- Lifespan Of A Solar Power System Is Far Longer Than The 20 Years
As indicated in a study Josh wrote on just a couple weeks ago, the lifespan of a solar power system is far longer than the 20 years most analysts use to calculate solar power costs. Last November, Susan featured one that was going strong at 30 years....
- Estimation Of Solar Pv System Output
Factors Affecting Output Standard Test Conditions Solar modules produce DC electricity. The dc output of solar modules is rated by manufacturers under Standard Test Conditions (STC). These conditions are easily recreated in a factory, and allow for consistent...