Nominal power (photovoltaic)
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The nominal power is the nameplate capacity of photovoltaic (PV) devices, such as solar cells, panels and systems, and is determined by measuring the electric current and voltage in a circuit, while varying the resistance under precisely defined conditions. These Standard Test Conditions (STC) are specified in standards such as IEC 61215, IEC 61646 and UL 1703; specifically the light intensity is 1000 W/m2, with a spectrum similar to sunlight hitting the earth's surface at latitude 35°N in the summer (airmass 1.5), the temperature of the cells being 25 °C. The power is measured while varying the resistive load on the module between an open and closed circuit (between maximum and minimum resistance). The highest power thus measured is the 'nominal' power of the module in watts. This nominal power divided by the light power that falls on a given area of a photovoltaic device (area × 1000 W/m2) defines its efficiency, the ratio of the device's electrical output to the incident energy.
The nominal power is important for designing an installation in order to correctly dimension its cabling and converters. If the available area is limited the solar cell efficiency and with it the nominal power per area (e.g. kW/m2) is also relevant. For comparing modules, the price per nominal power (e.g. $/W) is relevant. For a given installation's physical orientation and location the expected annual production (e.g. kWh) per annual production assuming nominal power i.e. the capacity factor is important. With a projected capacity factor the price per projected annual production (e.g. $/kWh) can be estimated for a given installation. Finally, with a projected value of the production, the amortization of the cost of an installation can be estimated.
The peak power is not the same as the power under actual radiation conditions. In practice, this will be approximately 15-20% lower due to the considerable heating of the solar cells. Moreover, in installations where electricity is converted to AC, such as solar power plants, the actual total electricity generation capacity is limited by the inverter, which is usually sized at a lower peak capacity than the solar system for economic reasons. Since the peak DC power is reached only for a few hours each year, using a smaller inverter allows to save money on the inverter while clipping (wasting) only a very small portion of the total energy production. The capacity of the power plant after DC-AC conversion is usually reported in WAC as opposed to Wp or WDC.
The International Bureau of Weights and Measures, which maintains the SI-standard, states that the physical unit and its symbol should not be used to provide specific information about a given physical quantity and that neither should be the sole source of information on a quantity. Nonetheless, colloquial English sometimes conflates the quantity power and its unit by using the non-SI unit watt-peak and the non-SI symbol Wp prefixed as within the SI, e.g. kilowatt-peak (kWp), megawatt-peak (MWp), etc. As such a photovoltaic installation may for example be described as having "one kilowatt-peak" in the meaning "one kilowatt of peak power". Similarly outside the SI, the peak power is sometimes written as "P = 1 kWp" as opposed to "Ppeak = 1 kW". In the context of domestic PV installations, the kilowatt (kW) is the most common unit for peak power, sometimes stated as kWp.
Power output in real conditionsEdit
The output of photovoltaic systems varies with the intensity of sunshine and other conditions. The more sun, the more power the PV module will generate. Losses, compared to performance in optimal conditions, will occur due to non-ideal alignment of the module in tilt and/or azimuth, higher temperature, module power mismatch (since panels in a system are connected in series the lowest performing module defines performance of the string it belongs to), soiling and DC to AC conversion. The power a module generates in real conditions can exceed the nominal power when the intensity of sunlight exceeds 1000 W/m2 (which corresponds roughly to midday in summer in, for example, Germany), or when sun irradiation close to 1000 W/m2 happens at lower temperatures.
Conversion from DC to ACEdit
Solar power need to be converted from direct current (DC, as it is generated from the panel) to alternate current (AC) to be injected into the power grid. Since solar panels generate peak power only for few hours each year, and DC to AC converters are expensive, the converters are usually sized to be smaller than the peak DC power of the panels. This means that for few hours each year the peaks are "clipped" and the extra energy is lost. This has very little impact on the total energy generated throughout a year, but saves considerable amount of balance of system (BOS) costs. Due to under-sizing of converters, AC ratings of solar plants are generally significantly lower than DC ratings, as much as 30%. This in turn increases the calculated yearly capacity factor of the plant. The downrating of peak power and the related clipping is different from the losses incurred in the conversion from DC to AC, which happen at any power level and are usually relatively small.
Most countries refer to installed nominal nameplate capacity of PV systems and panels by counting DC power in watt-peak, denoted as Wp, or sometimes WDC, as do most manufacturers and organizations of the photovoltaic industry, such as Solar Energy Industries Association (SEIA), the European Photovoltaic Industry Association (EPIA) or the International Energy Agency (IEA-PVPS). However, in some places of the world, a system's rated capacity is given after the power output has been converted to AC. These places include Canada, Japan (since 2012), Spain, and some parts of the United States. AC instead of DC is also given for most utility-scale PV power plants using CdTe-technology. Some grid regulations may limit the output of a PV system to as little as 70% of its nominal DC power (Germany). In such cases, the difference between nominal peak-power and converted AC output can therefore amount to as much as 30%. Because of these two different metrics, international organizations need to reconvert official domestic figures from the above-mentioned countries back to the raw DC output, in order to report coherent global PV-deployment in watt-peak.
In order to clarify whether the nominal power output ("watt-peak", Wp) is in fact DC or already converted into AC, it is sometimes explicitly denoted as, for example, MWDC and MWAC or kWDC and kWAC. The converted WAC is also often written as "MW (AC)", "MWac" or "MWAC". Just as for Wp, these units are non SI-compliant but widely used. In California, for example, where the rated capacity is given in MWAC, a downrating of 15 percent in the conversion from DC to AC is assumed. This can be extremely confusing not only to non-experts, as the conversion efficiency has been improving to nearly 98 percent, grid regulations may change, some manufactures may differ from the rest of the industry, and countries, such as Japan, may adopt a different metric from one year to the other.
Although watt-peak is a convenient measure, and is the standardized number in the photovoltaic industry on which prices, sales and growth numbers are based, it is arguably not the most important number for actual performance. Since a solar panel's job is to generate electric power at minimal cost, the amount of power that it generates under real-life conditions in relation to its cost should be the most important number to evaluate. This "cost-per-watt" measure is widely used in the industry.
It can happen that a panel from brand A and a panel of brand B give exactly the same watt-peak in laboratory test, but their power output is different in a real installation. This difference can be caused by different degradation rates at higher temperatures. At the same time, though brand A can be less productive than brand B it may as well cost less, thus it has a potential of becoming financially advantageous. An alternative scenario can also be true: a more expensive panel may produce so much more power that it will outperform a cheaper panel financially. An accurate analysis of long-term performance versus cost, both initial and on-going, is required to determine which panel may lead the owner to better financial results.
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