A Guide to Bifacial Solar Panels (2024)
Contents:
1. what is a bifacial solar panel?
2. What are the types of bifacial solar panels?
3. Why HJT solar panel is the best choice for bifacial solar panel?
4. What is advantages of bifacial solar panel?
5. What are the Applicable Installation Scenarios for Bifacial Solar Panels?
What is a bifacial solar panel?
A bifacial solar panel is a type of solar module that is designed to capture sunlight on both the front and rear sides. Unlike traditional monofacial solar panels that only have a single-sided photovoltaic surface, bifacial panels have photovoltaic cells on both the front and back sides, allowing them to generate electricity from sunlight striking either side.
Bifacial solar panels can capture sunlight that is directly hitting the front side as well as reflected sunlight from the ground or nearby surfaces. This feature increases their efficiency, as they can harness additional sunlight, especially in environments with reflective surfaces like snow, water, or light-colored ground.
What are the types of bifacial solar panels?
Bifacial panels come in three different forms:
1.Glass/glass:?Bifacial panels with double-sided glass surfaces are structurally stronger and can resist heavier loads than other bifacial or monofacial solar panels.?
2.Glass/transparent backsheet:?Has a front side encased with glass while the rear is protected by a transparent backsheet. Typically, more affordable than glass/glass panel.
3.Glass/backsheet:?Similar to its bifacial counterparts , it has a glass front-side and a non-transparent backsheet on the back.
Maysun's HJT is a glass-glass bifacial solar panel,weather, corrosion and abrasion resistant double sided glass. Utilizes POE encapsulation, giving the solar panel a 30 year product and performance warranty.
Why HJT solar panel is the best choice for bifacial solar panel?
1.High efficiency cells. With the high-efficiency HJT 210mm solar cell, the TCO film increases the photovoltaic conversion efficiency by 25% by effectively passivating the interfacial defects between crystalline silicon and doped amorphous silicon. This innovative technology has had a significant positive impact on cell performance, effectively improving the energy conversion efficiency of solar cells.
2.High Bifaciality. The HJT cell utilizes a symmetrical front and back side structure to enable a backside power generation efficiency of over 95%. Compared to the Perc and Topcon technologies, the HJT cell realizes a significant gain in backside power generation of more than 30%. This innovative design allows the HJT cell to more efficiently utilize the ambient light energy resources, providing a sizable increase in solar cell performance.
What are the advantages of bifacial solar panels?
1.Maximize Land Use & Enhanced Efficiency:?Bifacial solar panels are designed to maximize land use and enhance efficiency. These panels efficiently capture more sunlight within the same area, increasing the energy capacity significantly. Maysun Solar's HJT bifacial double-glass solar panels stand out with a 30% higher rear-side energy gain compared to PERC and TOPCon technologies, and the the rear-side electricity utilization rate of HJT solar panels exceeds 95%.?This combination of maximizing energy yield and efficiency is especially beneficial in space-limited solar projects.
2.Climate Adaptability:?Bifacial panels excel in various climatic conditions, adapting to both high and low temperatures and seasonal changes, making them reliable for power generation in diverse weather conditions.
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3.Longer Generation Window:?These panels extend the power generation window by capturing light from both the front and the back. This capability allows them to generate power continuously throughout the day and under different lighting conditions, including in low-light scenarios.
4.Increased System Capacity Factor:?By harnessing sunlight effectively at various times of the day, bifacial solar panels improve the system capacity factor. This leads to maximized overall efficiency of the power plant and contributes to a lower Levelized Cost of Energy (LCOE).
What are the Applicable Installation Scenarios for Bifacial Solar Panels?
1.Large-scale terrestrial photovoltaic power plants: In large-scale terrestrial photovoltaic power plants, bifacial solar panels show their excellent performance. By fully utilizing the sunlight reflected from the ground, especially in areas with high ground reflectivity, such as sand or white cover, bifacial panels are more effective. This allows large ground-mounted PV plants to capture sunlight more efficiently, increasing overall energy production.
2.Commercial Rooftop Systems:?Bifacial solar panels are an ideal choice for commercial buildings with sufficient roof space. They maximize the use of reflected sunlight from the roof, especially if the roofing material is highly reflective. Commercial roof systems can be deployed to effectively increase the energy collection efficiency of solar panels and provide renewable energy support for commercial buildings.
3. Parking Lot Awnings: Installing bifacial solar panels on parking lot awnings not only provides the necessary shade for the parking area, but also captures sunlight from both the top and bottom at the same time. This innovative design not only improves the environment of the parking lot, but also increases energy efficiency and enables a sustainable energy supply.
4.Agricultural photovoltaic:?The application of bifacial solar panels is not only limited to the energy industry, but can also be combined with agriculture to form an agro-photovoltaic system. By installing bifacial panels above farmland, the dual use of agriculture and photovoltaic power generation is realized. Crops under the solar panels can benefit from the sunlight that passes through the panels, while the panels capture the reflected sunlight, realizing the efficient use of resources.
5. Floating Solar System: Deploying a floating solar system on a body of water, i.e., installing double-sided solar panels on the water surface, can effectively enhance power generation efficiency. By utilizing the reflected light from the water surface, this system not only achieves double capture of sunlight, but also has a certain protective effect on the water body, providing an innovative solution for sustainable energy development.
6.Vertical Installations in Urban Areas: In dense urban spaces where area is limited, bifacial panels can be installed vertically on various structures to efficiently utilize space and capture sunlight from both sides. Examples include integrating panels into building facades, sound barriers along highways, structures of urban transit stations like bus and subway stations, pedestrian bridges and overpasses, as well as in parks and recreational areas.
7. High Latitude Regions: In regions with low sun angles, such as near the poles, bifacial panels can be more effective than traditional panels. They can capture direct sunlight on the front side and reflected sunlight from snow or other surfaces on the back side.
In all these scenarios, bifacial solar panels offer a distinct advantage by utilizing their dual-sided design to capture more sunlight and generate more energy than traditional single-sided panels. This makes them a versatile and efficient choice for a wide range of solar energy applications.
Since 2008, Maysun Solar has focused on manufacturing premium photovoltaic modules. Select from our extensive selection of half-cut, MBB, IBC, HJT and shingled solar panels, which are available in full black, black frame, silver, and glass-glass varieties. These panels complement any building with their elegant designs and exceptional performance. Maysun Solar has effectively set up offices, warehouses, and enduring partnerships with top installers across many nations! For the most recent solar panel quotes or any other PV-related questions, please get in touch with us. We can't wait to help you.
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7 个月Why are bifacial solar panels typically mounted in a traditional tilted fashion, making the downward-facing side of the panel somewhat useless? Why don't more installations use a vertical mounting methodology (even using a 3D tower formation), which also has the advantage of allowing either a more dense placement, or of allowing for example agricultural use between vertical rows, creating co-benefits?