The Monocrystalline Silicon Mono 54 Cell module is a high-performance, bifacial solar solution featuring N-Type TOPCon Dual Glass technology. Engineered for maximum energy yield, it combines monocrystalline silicon cells with a double-glass structure and bifacial design, allowing it to capture sunlight from both front and rear surfaces. This module is ideal for projects seeking high efficiency, durability, and versatility, catering to commercial, residential, and utility-scale applications.
The bifacial design enables the module to generate additional power from reflected sunlight on the rear surface, increasing overall energy yield by a significant margin. This feature makes it highly efficient in areas with reflective surfaces such as snow, concrete, or white rooftops.
Built with 2.0mm heat-strengthened glass on both front and rear, the module offers superior resistance to impacts, corrosion, and environmental wear. It has passed strict salt spray and ammonia corrosion tests, ensuring reliable performance in harsh environments for decades.
Powered by N-Type MBB Cell and optimized circuit design, the module delivers consistent high power output. It includes PID Protection to minimize performance attenuation, while its excellent low light performance ensures efficient energy generation even in low-irradiance conditions.
Ideal for large-scale solar farms aiming to maximize energy production per unit area. The bifacial design and high efficiency of the Mono 54 Cell module make it a cost-effective choice for utility projects, enabling higher energy yields and faster return on investment.
Suitable for commercial buildings with large rooftop spaces, such as warehouses, factories, and shopping malls. The module’s bifacial design leverages reflected sunlight from rooftop surfaces, enhancing energy generation to meet the high power demands of commercial operations.
Perfect for agrivoltaic systems, where solar modules are installed above farmland. The bifacial design allows sunlight to pass through to the crops below while generating power, supporting sustainable agricultural practices and dual land use.
Long-Term Quality Assurance
Quality assurance diagram
Mechanical Diagrams
 |  |  |
Mechanical Diagrams | Frame Cross Section A-A | Frame Cross Section B-B |
Specifications
Weight | 24kg |
Dimensions | 1722mm*1134mm*30mm |
Cell Dimensions | 182*182mm |
Cell Amount | 54*2 pcs |
Maximum System Voltage | 1500V |
Junction Box | IP68 |
Front Glass | 2.0mm, AntiReflection Coating |
Back Galss | 2.0mm, Heat Strengthened Glass |
Frame | Aluminum Alloy |
Cable | 4mm², N 1100mm/P 1100mm for Horizontal installation 4mm2, N 300mm/P 300mm for Vertical installation |
Connector | MC4 compatible |
Bifaciality | 80±5% |
Electrical Parameters At Stc
Power | 430W | 435W | 440W | 445W | 450W |
Open Circuit Voltage | 38.57V | 38.72V | 38.87V | 39.02V | 39.17V |
Short Circuit Current | 14.09A | 14.18A | 14.27A | 14.36A | 14.44A |
Maximun Power Voltage | 31.76V | 31.89V | 32.05V | 32.20V | 32.35V |
Maximum Power Current | 13.54A | 13.64A | 13.73A | 13.82A | 13.91A |
Module Eciency | 22.02% | 22.28% | 22.53% | 22.79% | 23.04% |
Under Standard Test Conditions(STC) of irradiance of 1000 W/m2, spectrum AM 1.5 and cell temperature of 25℃.
Electrical Parameters At Nmot
Power | 324W | 327W | 331W | 335W | 339W |
Open Circuit Voltage | 36.63V | 36.78V | 36.93V | 37.08V | 37.23V |
Short Circuit Current | 11.36A | 11.38A | 11.45A | 11.52A | 11.58A |
Maximun Power Voltage | 29.65V | 29.78V | 29.93V | 30.08V | 30.24V |
Maximum Power Current | 10.93A | 10.98A | 11.06A | 11.14A | 11.21A |
Under Nominal Module Operating Temperature(NMOT), irradiance of 800 W/m2, spectrum AM 1.5, ambient temperature 20℃, wind speed 1 m/s.
Temperature Characteristics
NMOT | 41±3°C | Temp Coeicient of ISC | +0.046%/°C |
Temp Coeicient of VOC | 0.25%/°C | Temp Coeicient of Pmax | -0.30%/°C |
Packing Configuration
Modules/Pallet | 37 Pieces | Modules/40'Container | 962 Pieces |
Packing Description | 26 Pallets, Total=(37+37)x13=962 Pieces | ||
Characteristics
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LC-54M-182*182-ND | LC-54M-182*182-ND |
Maximum Rating
Output Tolerance | 0~+5W |
Operating Temperature | -40°C~+85°C |
Wind Load/Snow Load | 2400pa/5400pa |
Fuse Current | 25A |
Features bifaciality with a high percentage, ensuring efficient energy capture from both front and rear surfaces.
Constructed with 2.0mm anti-reflection coating glass (front) and 2.0mm heat-strengthened glass (rear) for optimal light transmission and protection.
Equipped with a durable aluminum alloy frame that provides structural stability and supports easy installation on various mounting systems.
Incorporates an IP68-rated junction box for complete protection against water and dust, ensuring safe operation in all weather conditions.
Uses 4mm² high-quality cables and MC4 compatible connectors for secure, standardized electrical connections, simplifying system integration.
Designed with a maximum system voltage of 1500V, complying with international safety standards and enabling efficient energy transmission in large-scale systems.
The bifacial design allows the module to absorb sunlight not only from the front but also from the rear surface via reflected light. This increases the total amount of sunlight captured, resulting in higher energy output compared to traditional single-sided modules, especially in reflective environments.
Heat-strengthened glass on the rear enhances the module’s durability by providing resistance to thermal stress and physical impacts. It also improves heat dissipation, reducing the module’s operating temperature and maintaining higher efficiency during prolonged exposure to sunlight.
Yes, the module has undergone strict ammonia corrosion tests, making it resistant to ammonia-induced damage. Its robust dual-glass design and corrosion-resistant materials ensure reliable performance in agricultural areas or other environments with high ammonia concentrations.
While the module can be installed on standard mounting systems, using raised mounting structures is recommended to maximize rear-side light capture. This allows reflected sunlight to reach the rear surface, optimizing the bifacial advantage and ensuring maximum energy yield.
