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How to understand and compare solar panel specifications

How to read solar panel specifications.

The reason for this is that most people do not understand what each of the terms in the specifications sheet for a solar panel mean.

Even if you do happen to know what the terms mean, it is another thing to know how much importance to place on a particular feature. Some of the solar panel specifications that sound really important, actually aren’t.

How to understand and compare solar panel specifications

Solar cells

A solar module is made up of a number of individual solar cells that are wired together in series. Most solar panels used for homes have 60 cells in series, although some higher output panels have 72 solar cells wired together in series inside them.

Pv cell vendor

In some cases, the solar panel brand you are buying doesn’t make their own solar cells. They simply buy cells from a manufacturer, and their expertise is in assembling these cells into modules.

However, in the case of most top-tier brands, they make most, or all, of their solar cells. It is something worth asking about, as a lot of solar panel specifications for solar panel brands do not say who makes their cells. I would tend to prefer a brand that makes their own cells as they can’t blame anyone else for faults.

Photovoltaic cell types

Over 95% of solar panels used in residential and small commercial solar installations contain crystalline silicon cells.

This is not to say there aren’t other semiconductor materials that can be used to create solar cells and modules – however, to date, it has been the crystalline silicon technology that has attracted the most investment and achieved the best balance of efficiency and cost.

Read more on the features and pros and cons of Differences monocrystalline vs polycrystalline solar panels.

Static snow load in the solar panel specifications

This refers to the amount of pressure that can be exerted on the solar panels from the weight of static snow without voiding the warranty of the solar panel specifications.

Most solar panels are rated to hold a pressure from a snow load of 5400pascals (Pa), which are units of pressure. What this equates to is between 2-4 feet of snow, depending on the type and density of the snow.

This is quite a lot of snow and this is just the warrantied amount – it does not mean that a snow dump of more than this would necessarily break the panel, it is just beyond the depth at which the manufacturer is prepared to guarantee that it won’t break the panel.

Static wind load

This refers to the amount of wind force that the solar panel can withstand without breaking.

The value for a typical solar panel of around 2,400 Pa/50 pounds per square foot (psf) equates to a wind speed of about 141 miles per hour.

Temperature coefficient

It is a matter of basic electrical physics that as temperature increases in a semiconductor such as a solar cell, the voltage of the cell drops.

The current may increase very slightly but overall, the power output falls for each degree that the temperature of the solar cell increases.

While I have read the physics behind why this happens, the truth is I don’t understand it. However, I do understand what each of the readings in the power tolerance section of solar panel specifications or data sheet mean:

Specific temperature coefficient measurements

Temperature coefficient (Pmpp)

This refers to the percentage that the peak rating of the solar panel reduces by for each degree in temperature increase above 25 degrees Celsius.

The very best solar panels claim a temperature coefficient around -0.30%/degrees Celsius and a standard polycrystalline panel usually has a temperature coefficient around -0.41%/degrees Celsius.

Given real-world cell temperature (NOCT conditions) are more likely to average 45 degrees Celsius, the real-world power output difference between the panel with the best temperature coefficient and solar panels with an average temperature coefficient is likely to be a difference between a 6% output degradation to an 8% average output degradation because of temperature.

Temperature coefficient open circuit voltage (Voc)

Temperature coefficient of short circuit current (Isc) is less important to know, as this refers to the voltage drop and current increase caused by every 1 degrees Celsius temperature increase, whereas most people want to know the amount of output power reduced overall and not the solar panel specifications of voltage drop and current increase.

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Module efficiency

The first thing on a specification sheet that the salesperson will often note is the efficiency of the solar panel.

The efficiency of a panel is expressed as a percentage of the solar irradiation that the panel can transform into usable electricity at standard test conditions.

So, all other things being equal, two solar panels both rated at 270 watts will each produce the same amount of power when you shine 1000 Watts/m² onto the panel at 25 degrees Celsius.

The only benefit of a more efficient panel is that it takes up slightly less space to produce the same amount of power. With the most efficient solar panels on the market having around 23% efficiency and the run-of-the-mill Tier 2 average polycrystalline solar panels having efficiency of around 18%, you may be able to produce up to 28% more power from any given space using the most efficient monocrystalline solar panel rather than the average efficiency panel.

However, if space is not a restrictive factor for you it may be hard to justify the extra price tag that comes with the most efficient panels.

Power tolerance in solar panel specifications

Power tolerance can either be expressed in watts or as a percentage of the rated power of the solar panel. In most cases it will be expressed as a percentage of the rated power output.

The negative power tolerance is the percentage by which the maximum power output at standard test conditions (Pmax at STC) in a particular module can be less than the rated Pmax at STC.

Most crystalline solar panels on the market now have zero negative power tolerance, meaning all of the manufacturers are stating that their panels may produce more than their rated Pmax at STC but not less.

Their Pmax warranties are expressed after power tolerance and so this is important.

Most solar panel brands on the market claim a positive power tolerance of between 3-5%, meaning their panels may be over their Pmax at STC.

Pmax

Pmax is the rated power output of a solar panel at standard test conditions (STC) with a cell temperature of 25 degrees Celsius and solar irradiation at 1000W/m2.

The PTC rating of a panel was once more difficult to calculate because many panels once had negative power tolerances. Most better brands of solar panels now have no negative power tolerance, and because the effect of wind speed on output is minimal, the PTC is now mainly just an adjustment of Pmax for real-world temperatures.

The PTC rating became widely used in output forecasting when the California government started testing solar panels before approving them. When they did this, they found on average, panel outputs were 6% lower than what solar manufacturers were claiming on their spec sheets.

However, this real world calibration of PTC no longer happens for new solar panel models and so we use a simple formula to calculate power output for real world conditions that adjusts for likely average cell temperatures during the operating hours of the panels over a year.

Remember, cell temperature is usually 20 degrees Celsius higher than average ambient daytime temperatures.

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