Solar Panel Efficiency: Everything You Need to Know

Solar Panel Efficiency: Everything You Need to Know

Welcome back. In our previous post we covered some of the basics of solar cells and solar panel efficiency. We covered why solar panel efficiency matters and how it’s calculated. In this post, we’ll take an in-depth look at what determines solar panel efficiency including design, components, materials and environmental factors such as shading and positioning,

Content Table

  • 1. Solar technology and materials  
  • 1.1 Solar cell types  
  • 1.2 Technologies of solar cells  
  • 2. Environmental and positioning factors  
  • 2.1 Irradiance  
  • 2.2 Climate  
  • 2.3 Shading  
  • 2.4 Orientation & tilt of solar panels  
  • 3. Takeaways  

Solar technology and materials

Solar cell types

Solar cells are the building blocks of solar panels. Solar cells convert sunlight to electricity through a process called the photovoltaic effect, where electric current is generated when the cells are exposed to sunlight. There are three broad categories of solar cell: monocrystalline, polycrystalline, and thin-film solar cells.

-Monocrystalline

A monocrystalline solar cell is made from a single silicon crystal structure, an extremely pure form of silicon. Monocrystalline solar cells are highly efficient, but the manufacturing process is complex and labor intensive. To produce them, a seed crystal is pulled from molten silicon to create a cylindrical ingot with a single, continuous, crystal lattice structure. This crystal is then sliced into wafers that power induvial solar cells. Monocrystalline cells are more efficient than polycrystalline or thin-film cells, with an efficiency rate typically above 19 percent. But
monocrystalline solar panels tend to be the more expensive option due to higher manufacturing costs. Monocrystalline cells can be identified by a consistent black or blackish-blue color.

We don’t specifically mention in this blog that our panels all feature moncrystalline cells

(Pic 1. Comparing a monocrystalline to a polycrystalline solar cell.)

-Polycrystalline

Polycrystalline solar cells contain many small fragments of blue silicon crystals as opposed to a single silicon structure. A blue flaky appearance makes them easy to distinguish from monocrystalline cells. Polycrystalline cells are less efficient but easier to produce than monocrystalline. Typically, they have 12 to 15 percent efficiency and are lower in cost compared to monocrystalline cells.

-Thin-film

Unlike conventional photovoltaic cells, thin-film solar cells are made by layering multiple photovoltaic materials on a glass substrate. There are four kinds of thin-film solar cells: Cadmium Telluride (CdTe), Amorphous Silicon (a-Si), Copper Indium Gallium Selenide (CIGS), and Gallium Arsenide (GaAs).

Cadmium Telluride (CdTe) offer higher efficiency than other thin-film cells. And because they use only 1 percent of the silicon needed for a crystalline cell, and a less energy intensive manufacturing process, they are a lower cost option. They’re flexible and durable making them excellent options for curved surfaces. However, they do need additional
solar panel maintenance and cleaning to deliver consistent performance outdoors. They also contain rare and toxic elements including cadmium which require extra precautions during manufacturing and recycling.

Technologies of solar cells

Solar technology is constantly evolving in the quest for solar cells and panels with more power and increased efficiency. There are now a number of technologies on the market that offer increased performance, and each uses different design, materials and components to meet your energy needs.

-Interdigitated back contact (IBC cells)

Interdigitated back contact cells are high performing with a sleek design. They use back contact technology that doesn’t require metal ribbons on the front of a panel’s cell. That means they can absorb more sunlight per cell because there is no shading caused by the metal ribbons. IBC cells can reach efficiency of up to
29.1%.

Structure of an IBC solar cell.

(Pic 2. Structure of an IBC solar cell.)

-Passivated emitter and rear contact (PERC cells)

Passivated emitter and rear contact cells, or PERC cells, add an additional layer to the back of traditional solar cells. The extra layer bounces the light into the cell a second time giving the panel a second chance to capture the energy of the sunlight. This additional layer also prevents the aluminum back sheet from absorbing light which can reduce efficiency by producing additional heat.
Research published in 2017, shows the efficiency of a PERC cell can achieve beyond 25 percent.

Comparison of a conventional solar cell with a PERC solar cell

(Pic 3. Comparison of a conventional solar cell with a PERC solar cell.)

-Half-cut cells

Combining half-cut cell technology with PERC cells is a growing trend in solar modules. Half-cut cells, as their name would imply, are standard size cells cut in half, doubling the number of cells that can fit on a panel. Traditional monocrystalline panels typically have 60 to 72 cells. Half-cut panels have 120-144 cells. By cutting the cells in half, energy loss from resistance is limited by reducing how far the energy travels within a cell. The panel itself is divided into two sections so each can operate as a separate panel, allowing one section to create energy even if the other section is shaded.

Modules utilizing half-cut cell technology are more tolerant to high temperatures than conventional modules. Risks of hot spots are also reduced through improved bypass-diode configuration. We will cover more on this in the section on shading.

 all-new Renogy 550W Monocrystalline Solar Panel

(Pic 4. The all-new Renogy 550W Monocrystalline Solar Panel uses a combination of PERC and half-cut cell technology with better performance in low-light situations)

We don’t mention on our product pages that Renogy products use half-cut cells.

-Heterojunction cells (HJT cells)

Heterojunction cells take efficiency to the next level by combining crystalline silicon solar cell technology with thin-film solar cells. In an HJT cell, a crystalline silicon solar cell is sandwiched between two amorphous silicon layers. Each of the three silicon layers of silicone combine to harvest more energy and yield usable power. HJT cells can reach efficiency of 25% or more.

Environmental and positioning factors

There are a few environmental and positioning factors that affect the efficiency of solar panels. These include irradiance, temperature, location, shading, tilt and others. All are important considerations when planning your solar project for on grid or
off grid solar.

Irradiance

Irradiance refers to the amount of solar energy that hits a square meter of a surface per second. Irradiance is measured using standard testing conditions and doesn’t consider any other factors that may affect efficiency.

Mohamed Amer Chaaban from Penn State University is an expert in the relationship between irradiance and power output in photovoltaic modules. The diagram below demonstrates shows how solar panels operating under irradiance of 1250W/m2 have a better power outcome than those under 750W/m2.

05 The Relationship Between Power & Voltage Under Different Irradiance

(Pic 5. The power output delivered by PV modules under different irradiance conditions. The higher the irradiance is, the more power a solar panel can generate. Data from e-education

Climate

Weather conditions play a significant role in performance and efficiency of solar panels. Lower temperatures tend to help your system deliver more voltage at high efficiency. However, if your system is in an area with lots of cloudy days you’ll produce less power, and snow accumulation on the panels will reduce power output as well.

It may seem counterintuitive, but high temperatures can also reduce solar efficiency. As temperatures climb, the voltage and the power output of solar panels decrease. When the temperature is above 77°F or 25°C, solar panels generate less power because of reduced efficiency. Solar panels are tested using standard temperature conditions of a constant 77°F or 25°C. Look for the “temperature coefficient”, on a panel’s spec sheet. It will tell you how much power a solar panel loses once the temperature goes over 77°F.

Shading

When planning your system, make sure your PV modules can operate free from shadows cast by trees or nearby buildings. Shade can prevent solar panels from absorbing enough light to complete power conversion even in peak daylight hours.

Hot spots, caused by partial shading, can greatly reduce the performance of PV modules. The hot spot effect is one of the most common reasons that solar panels fail. Partially shaded cells don’t produce energy, while other cells operate as usual to produce current. As a result, the current generated by non-shaded cells doesn’t pass through shaded cells and can lead to concentrated heat. Overheating can eventually develop into a hot spot and damage adjacent cells or even the whole module.

Bypass diode and half-cut cells deal with the effects of shading differently. The diagram below shows a full cell module (left) and half-cut cell module (both 6 strings). Each is shaded on half the module. For the module on the left, the bypass diode is at the top of the panel, and all 6 strings of cells stop working because the current is unable to pass through the shaded area.

However, the module on the right uses half-cut cell technology and can mitigate the effect of shading. The half-cut cell panel is split in half and consists of 6 groups of cell strings with the bypass diode in the middle. Half the solar panel is shaded and has stopped working. The other 3 cell strings still produce 50 percent more power than the traditional module on the left. The cells that are working are also distributing excessive heat to reduce the risk of hot spots.

Bypass diodes are configured at different locations on solar panels

(Pic 6. Bypass diodes are configured at different locations on solar panels: one at the top of the panel while the other is in the middle.)

Orientation & tilt of solar panels

The way solar panels are positioned on your rooftop can significantly impact their efficiency. This is referred to as orientation, meaning the compass direction your panels face most of the time. In the northern hemisphere, we advise you to orient your solar panels to the south or west to get the most sun exposure.

However, getting the right orientation for your solar panels is only one part of maximizing performance. Tilt plays an important role as well. If possible, always tilt panels at an angle toward the sun rather than lying flat. Solar panels should be mounted with a minimum 20 degree tilt toward the sun when possible. For example, the
ground mounted solar panels are always positioned with tilt brackets.

Takeaways

In this post, we’ve shown how solar technology, including silicon types and solar cells affect solar panel performance. You’ve also seen how irradiance, climate, shading, and other environmental factors affect performance.

Understanding solar panel efficiency is a good starting point for planning your solar project. But don’t forget that warranty and quality of other equipment such as the
solar panel battery and 12V inverter are just as important to ensure you get a high performing, long-lasting system.

Renogy has more than a decade of experience in the solar industry, and we’re dedicated to providing you with everything you need for your solar system. We provide up to 10-year material and workmanship warranties for solar panels with a 25-year 80% power output warranty. Buy solar panels on Renogy’s online store right now!

If you have any questions about solar, visit our
learning center or visit our forum for more information. Renny, our digital assistant at Renogy, is always ready to answer questions or provide guidance. Prefer to talk with a customer service specialist? You can contact us via phone or submit a case, and our support team will be happy to help. Get started on your sustainable, off-grid journey with Renogy today!

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