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LN168210R-440~460
LNE Solar
The architectural elegance of the anodized aluminum alloy black frame meets cutting-edge photovoltaic engineering in this premium solar module. When handling the panel, the robust weight of the 2.0mm anti-reflective coated semi-tempered front glass, paired with the equally resilient rear glass, conveys immediate structural confidence. The sleek, uniform dark aesthetic not only absorbs sunlight with remarkable efficiency but also blends seamlessly into modern commercial rooftops and expansive ground-mounted arrays. Every micro-detail, from the precision-sealed IP68 junction box to the meticulously aligned monocrystalline cells, speaks to an uncompromising standard of manufacturing excellence.
Operating silently while harnessing the sun's power from both the primary face and the reflective rear, this module redefines energy capture in demanding environments. The tactile smoothness of the glass surfaces repels dust and environmental debris, ensuring the N-type cells beneath remain unhindered. By mitigating internal resistance through an advanced half-cell design, the module maintains a cool operating temperature even under intense irradiance. This thermal stability translates into a consistent, predictable energy flow, empowering facility managers and project developers to achieve their sustainability targets with absolute certainty. The fusion of aesthetic sophistication and rugged durability makes it an indispensable asset for forward-thinking energy infrastructure.
Key Benefits
- High energy yield with low levelized cost of energy (LCOE).
- Excellent durability with double-glass design and strong frame.
- Reliable performance under harsh conditions like heavy snow and strong wind.
Mechanical Parameters
Cell Type | N Type Monocrystalline Cell |
Cell Orientation | 96 (6×16) |
Dimensions (L×W×H) | 1762±2 × 1134±2 × 30 mm |
Weight | 23.7 kg |
Front Glass | 2.0mm AR coating semi tempered glass |
Rear Glass | 2.0mm semi tempered glass |
Frame | Anodized aluminum alloy black frame |
Junction Box | IP68, 3 diodes |
Cable | 4.0mm² |
Cable Length | +300mm, -300mm (customizable) |
Wind Load / Snow Load | 2400Pa / 5400Pa |
Per Pallet | 36 pcs |
Packaging (40' HC) | 936 pcs |
Electrical Characteristics (STC) - LN168N210R-XXX Series
Maximum Power: Pmax (W) | 440 | 445 | 450 | 455 | 460 |
Open Circuit Voltage:Voc (V) | 35.35 | 35.55 | 35.75 | 35.95 | 36.15 |
Short Circuit Current: Isc (A) | 15.89 | 15.92 | 15.95 | 15.98 | 16.05 |
Voltage at Maximum Power: Vmp (V) | 29.67 | 29.93 | 30.19 | 30.44 | 30.69 |
Current at Maximum Power: Imp (A) | 14.83 | 14.87 | 14.91 | 14.95 | 14.99 |
Module Efficiency: η (%) | 22.0 | 22.3 | 22.5 | 22.8 | 23.0 |
STC: Irradiance 1000W/m², Cell temperature 25°C, AM=1.5
Power measurement tolerance: ±3%
Electrical Characteristics with Different Rear Side Power Gain
Maximum Power: Pmax [W] | 462 | 467 | 472 | 477 | 483 |
Module Efficiency: η [%] | 23.1 | 23.4 | 23.6 | 23.9 | 24.2 |
Maximum Power: Pmax [W] | 506 | 511 | 517 | 523 | 529 |
Module Efficiency: η [%] | 25.3 | 25.6 | 25.9 | 26.2 | 26.5 |
Maximum Power: Pmax [W] | 550 | 556 | 562 | 568 | 575 |
Module Efficiency: η [%] | 27.5 | 27.8 | 28.1 | 28.4 | 28.8 |
Note: The data demonstrates performance under varying levels of rear side power gain.
Usage Instructions
- Install on a stable structure, allowing rear-side light exposure.
- Ensure professional electrical connections following safety standards.
- Clean surfaces regularly and inspect for damage to maintain efficiency.
Application Scenarios
- Ideal for commercial and industrial solar projects.
- Suitable for large solar farms and utility-scale installations.
- Effective in reflective environments like snowy areas or near water.
At the heart of this module lies cutting-edge N-type monocrystalline cell technology paired with a sophisticated half-cell layout. This synergistic design significantly mitigates internal energy dissipation and light-induced degradation (LID). By maintaining an exceptional baseline efficiency of up to 23.0% under STC, the panel effectively drives down the levelized cost of energy (LCOE) for expansive utility and commercial installations, ensuring a highly competitive energy profile.
The dual-glass bifacial construction is meticulously engineered to capture scattered and reflected light from the rear side. Depending on the albedo of the installation surface—such as snow, water, or highly reflective commercial roofing—this architecture yields an additional 5% to 25% power surge. This remarkable amplification can elevate the comprehensive power output beyond 575W, accelerating the amortization period and maximizing the return on investment for large-scale energy portfolios.
Constructed to thrive in the most unforgiving climates, the module features a formidable 2.0mm front and 2.0mm rear semi-tempered glass envelope, encased in a high-strength anodized aluminum alloy black frame. This robust physical barrier offers unparalleled resistance against micro-cracking, UV aging, and severe weather patterns. Rigorously tested to withstand 5400Pa of snow load and 2400Pa of wind load, it guarantees unwavering operational stability across diverse geographical landscapes.
Versatility is engineered into every component, ensuring seamless integration across a multitude of project scales. The module is equipped with an IP68-rated waterproof junction box and customizable cable lengths (+300mm, -300mm), accommodating complex wiring schematics with ease. Whether deployed on expansive commercial and industrial (C&I) rooftops, sprawling ground-mounted solar farms, or utility-scale energy hubs, the system architecture ensures flawless electrical compatibility and straightforward installation.
Recognizing the critical importance of supply chain efficiency, the physical dimensions and packaging configurations have been strategically optimized for international transit. Packed at 36 pieces per pallet and accommodating 936 pieces within a standard 40-foot high cube container, the design maximizes spatial utilization. This meticulous logistical planning significantly curtails cross-border shipping, maritime freight, and warehousing expenditures on a per-watt basis, streamlining the procurement cycle.
The inherent low-degradation characteristics of N-type cells, combined with the impenetrable physical defense of the double-glass structure, secure a remarkably stable power output over a 25 to 30-year lifecycle. This stringent approach to quality control ensures an exceptionally low annual degradation rate, providing asset managers and project developers with highly predictable energy yields, superior warranty expectations, and long-term asset security.
Selecting the right manufacturing partner is as critical as the technology itself. We operate at the intersection of scale, precision, and reliability, delivering photovoltaic solutions that empower global energy transitions. Our commitment extends far beyond the factory floor, ensuring every shipment aligns with the rigorous demands of commercial procurement and utility-scale deployment.
Direct Manufacturer Access: Bypass intermediaries to secure premium solar technology directly from the source, ensuring transparent communication and optimized pricing structures.
Stringent Quality Assurance: Every module undergoes exhaustive electroluminescence (EL) testing and thermal imaging to guarantee zero micro-cracks and perfect cell alignment before packaging.
Scalable Production Capacity: Equipped to fulfill high-volume orders with consistent lead times, keeping your critical project timelines on track without compromise.
Dedicated Technical Support: Our engineering teams provide comprehensive guidance on system compatibility, optimal array configuration, and performance modeling to maximize your site's potential.
FAQs
N-type cells inherently possess a higher tolerance to impurities and suffer from significantly lower light-induced degradation (LID) compared to traditional P-type cells. This translates to a higher sustained efficiency and a much slower performance decline over the module's multi-decade lifespan, securing a more predictable energy yield for large installations.
By capturing albedo (reflected light) on the rear side of the panel, the bifacial design supplements the primary front-side generation. In standard conditions, this adds 5% to 15% more energy. However, when deployed over highly reflective surfaces such as bright white commercial roofing membranes or snow-covered ground, the rear-side gain can exceed 25%, drastically improving the project's overall economics.
The half-cell design physically halves the electrical current passing through the busbars, which exponentially reduces internal resistive losses. Furthermore, it creates independent upper and lower module sections. If one half is subjected to partial shading from parapets or adjacent rows, the other half continues to operate at peak capacity, ensuring reliable power output.
Replacing the traditional polymer backsheet with a 2.0mm semi-tempered rear glass creates a nearly impermeable barrier against moisture ingress, salt mist, and blowing sand. This symmetrical glass-glass sandwich minimizes mechanical stress on the silicon cells during wind or snow loading, drastically reducing the risk of micro-cracks and extending the operational life with minimal power loss.
Absolutely. The structural integrity is fortified by a heavy-duty anodized aluminum alloy frame and the dual-glass envelope. It is rigorously certified to withstand severe downward mechanical loads up to 5400Pa (heavy snow accumulations) and uplift forces up to 2400Pa (gale-force winds), making it an optimal choice for demanding geographical locations.
