| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
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ANYSOLAR |
MONOCRYSTL SOLAR CELL 18MW 1.89V |
0 |
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ANYSOLAR |
MONOCRYST SOLAR CELL 157MW 7.56V |
0 |
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ANYSOLAR |
MONOCRYSTL SOLAR CELL 56MW 630MV |
0 |
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ANYSOLAR |
MONOCRYSTL SOLAR CELL 20MW 630MV |
0 |
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ANYSOLAR |
MONOCRYST SOLAR CELL 540MW 5.67V |
0 |
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ANYSOLAR |
MONOCRYSTALN SOLR CELL 6MW 630MV |
0 |
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ANYSOLAR |
MONOCRYSTL SOLAR CELL 20MW 630MV |
0 |
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ANYSOLAR |
MONOCRYSTALN SOLAR CELL 136MW 4V |
0 |
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ANYSOLAR |
MONOCRYSTL SOLAR CELL 18MW 1.89V |
0 |
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ANYSOLAR |
MONOCRYSTALN SOLR CELL 6MW 630MV |
0 |
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ANYSOLAR |
MONOCRYST SOLAR CELL 182MW 7.56V |
0 |
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ANYSOLAR |
MONOCRYST SOLAR CELL 112MW 630MV |
0 |
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ANYSOLAR |
MONOCRYSTL SOLAR CELL 20MW 630MV |
0 |
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ANYSOLAR |
MONOCRYSTLN SOLAR CELL 67MW 6.3V |
0 |
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ANYSOLAR |
MONOCRYST SOLAR CELL 112MW 630MV |
0 |
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ANYSOLAR |
MONOCRYSTL SOLAR CELL 20MW 630MV |
0 |
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ANYSOLAR |
SOLAR CELL MONO |
0 |
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Solar cells (photovoltaic cells) are semiconductor devices that convert sunlight directly into electricity through the photovoltaic effect. They serve as core components in renewable energy systems, enabling sustainable power generation. Modern advancements have expanded their applications from large-scale power plants to portable electronics, making them critical for reducing fossil fuel dependence.
| Type | Functional Characteristics | Application Examples |
|---|---|---|
| Monocrystalline Silicon | High efficiency (18-22%), long lifespan (>25 years), high cost | Residential rooftop systems, utility-scale farms |
| Polycrystalline Silicon | Moderate efficiency (15-18%), lower cost, blue reflective appearance | Commercial buildings, off-grid systems |
| Thin-Film (a-Si) | Lightweight, flexible, lower efficiency (10-12%), temperature-resistant | Building-integrated PV, portable chargers |
| CIGS (Copper Indium Gallium Selenide) | 12-14% efficiency, better low-light performance | Flexible solar panels, EV charging |
| Organic PV | Low cost, transparent/colored options, shorter lifespan | Smart windows, wearable devices |
| Perovskite | High theoretical efficiency (33.7% in tandem), low production cost | Next-gen solar farms, BIPV |
Typical crystalline silicon solar cell structure includes: - Anti-reflective coating (silicon nitride) - N-type silicon layer (emitter) - P-type silicon layer (base) - Front electrode grid (silver paste) - Back surface field (aluminum layer) - Encapsulation (EVA film, tempered glass, )
| Parameter | Description | Importance |
|---|---|---|
| Conversion Efficiency | Percentage of sunlight converted to electricity | Directly affects energy output and ROI |
| Open-Circuit Voltage (Voc) | Maximum voltage at zero current | Determines system voltage compatibility |
| Short-Circuit Current (Isc) | Maximum current at zero voltage | Impacts wire sizing and inverter selection |
| Temperature Coefficient | Performance change per C temperature rise | Affects reliability in hot climates |
| Lifetime | Years until 80% performance retention | Key economic factor |
| Manufacturer | Key Product | Key Features |
|---|---|---|
| First Solar | Series 6 Thin-Film | 18% efficiency, cadmium-telluride technology |
| SunPower | Maxeon 3 | 22.8% efficiency, no degradation warranty |
| LONGi Solar | Hi-MO 4 | Monocrystalline PERC cells, 410W output |
| Hanwha Q CELLS | Q.PEAK DUO | 19.8% efficiency, bifacial generation capability |
| Tesla | Solar Roof V3 | Building-integrated solar tiles |
Key developments include: - Tandem cells combining perovskite and silicon layers (potential 40% efficiency) - Bifacial modules capturing rear-side irradiance - AI-driven manufacturing for defect reduction - Transparent solar glass integration in skyscrapers - Recycling infrastructure development for end-of-life panels - Quantum dot solar cells for tunable bandgap properties