Although the energy band structure of an amorphous silicon Battery is similar to that of crystalline silicon, due to the lack of a long sequence of atomic arrangement, there is no vertical or non-vertical transition for photo-excited electronic transitions, so its light absorption coefficient is higher than that of crystalline silicon. Increase a lot. For the visible light region of the main part of the solar spectrum, the absorption coefficient of amorphous silicon is about an order of magnitude higher than that of crystalline silicon. A 1 micron thick amorphous silicon film can absorb about 60% of solar energy. Amorphous silicon containing hydrogen: Hydrogen alloy thin films were once regarded as the most promising thin film materials for solar cells. The energy gap of the amorphous silicon film is close to the optimal forbidden band width, and because the density of defect states is low, it is easy to form effective p or n-type doping, and the barrier layer of the prepared pn junction is wider; the photo-generated carrier The life is relatively long, which is conducive to the preparation of high-performance solar cells. At the same time, the process of depositing the amorphous silicon film is not complicated, the power consumption and cost of the preparation process are low, and it is easy to realize large-scale and large-scale production. Therefore, the amorphous silicon thin film and its Solar Cell have received great attention. However, future research has found that solar cells made of amorphous silicon thin films will deteriorate the performance of the material after being exposed to light, and the performance of the battery will also deteriorate, especially the conversion efficiency will be reduced. Therefore, the conversion efficiency of amorphous silicon solar cells is generally less than 10%. In order to improve the energy conversion efficiency of amorphous silicon solar cells, a variety of multi-element alloy materials have been developed on the basis of amorphous silicon-hydrogen alloys. For example, amorphous silicon-carbon-hydrogen has a large energy gap. By adjusting the carbon content, the value of the energy gap can also be changed within the range of 116-218 electron volts. For the fabricated battery, open circuit voltage and short circuit current They are larger than the corresponding parameter values ​​of amorphous silicon-hydrogen alloy batteries. Another way to improve the conversion efficiency of amorphous silicon solar cells is to prepare multi-layer cells with variable band gaps. This type of battery is composed of multiple different pn junctions stacked into multiple layers. For solar cells, obtaining a high open-circuit voltage is exactly the opposite of the short-circuit current requirement for the band gap width of the material. When the energy gap is narrow, photons easily excite electron-hole pairs and form a large short-circuit current; but at the same time, because the potential barrier of the pn junction is small, the open circuit voltage is relatively low. One solution to this contradiction is to design a multi-layer battery made up of different pn structures composed of different band gap materials. Because when the photon energy and the band gap energy are equal, the probability of photon absorption is the largest, materials with different band gaps can absorb light with different wavelengths in the solar spectrum, and the rubber injection machine makes the incident sunlight fully utilized. The total voltage of multiple pn junctions in series increases the open circuit voltage of the battery. However, the batteries of each layer are connected in series, and their short-circuit currents are required to be equal, which becomes the main difficulty in preparing multilayer batteries. In this way, although amorphous silicon is simpler and easier to prepare a multilayer pn junction process than single crystal silicon, there are still many unresolved designs and processes to meet the two conditions of absorbing different wavelengths of sunlight and equal short-circuit current. The problem.
From the upgrade of the existing 158.75 and 166 production lines, the process span of 182 solar panels is smaller, and the existing equipment and processes are more mature. Therefore, the difficulty and cost of new or upgraded production lines are lower, and the product yield rate is currently normal. PV industry experts suggest that the advantage of 182mm is that the industrial ecology is more mature, and it is the optimal size silicon wafer that meets the current development level of upstream and downstream, and is the first choice at this stage.
Sunket 182mm Solar Panel use 182mm 10BB/11BB solar cell, increases the wafer size, optimizes the layout profoundly and decreases the invalid power generation area.
1.Half Cell Technology
The half-cut cell design can decrease the power loss by the shadow effectively. The optimized circuit design not only realizes the maximum power output but also assures the reliability of solar panels.
2.MBB Technology
Sunket 182mm Solar Panel adopts multi-busbar technology. More busbars of the cell decrease the current transverse propagation path by 50%, effectively reduce the internal loss, and improve power of solar panels.
182mm Solar Panel,Mono Solar Panel,182mm Mono Solar Panel,Solar PV Module,Solar Panel Wuxi Sunket New Energy Technology Co.,Ltd , https://www.sunketsolar.com
April 18, 2024