Solar Modules operate based on the Photovoltaic effect, where semiconductor materials (typically silicon) within the cells absorb photons from sunlight and release electrons, generating a direct current (DC) of electricity. This DC power is then managed and converted into usable alternating current (AC) by an inverter for powering homes and businesses.
Technical Specifications
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Features
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Mono PERC(P-type)
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TOPCon (N-type)
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HJT (N-type)
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Efficiency
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20%-21.5%
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22%-24%
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24%-26%
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Temp. Coefficient
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-0.34%/°C
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-0.30%/°C
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-0.25%/°C
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Bifaciality
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60%-70%
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70%-80%
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85%-95%
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Standard
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UL/ IEC-61215/IEC-61730
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UL/ IEC-61215/IEC-61730
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UL / IEC-61215/IEC-61730
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Certifications
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ALMM & BIS
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ALMM & BIS
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ALMM & BIS
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Category
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P-Type
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N-type
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N-type
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Applications
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Budget-Focused
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Mainstream High Performance
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Space Constrained
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Benefits & Modular Design
§ Scalability & Flexibility:
Systems can start small and be expanded later by adding more modules as energy needs or budgets change.
§ Easier Installation:
Smaller, individual modules are lighter and easier to transport and install, especially in tight or irregularly shaped rooftop spaces.
§ Efficient Maintenance:
If one module malfunctions, only that specific unit needs replacement or repair, rather than the entire system, which reduces downtime and costs.
§ Improved Performance under Shade:
In systems with micro inverters or optimizers, if one module is shaded, the other independent modules continue to operate at full potential, minimizing overall power loss.
Common Applications
§ Urban & Building | Agrivoltaics & Agriculture | Industry & Utility | Commercial