Mono Crystalline Solar Panels Manufacturers

Solar Modules

GLASS TO TRANSPARENT BACKSHEET
PIX MBHTB 144

144 Cells

Maximum Power Output - 550 Wp

  •     Module Power Range: 510-550 Wp
  •     Efficiency upto 21.29 %
  •     Power Tolerance: +4.99Wp

Harnessing Bifacial Solar Power with Glass-to-Transparent Backsheet PV Modules - PIX MBHTB 144 Mono Perc Bifacial Half-Cut NDCR

Glass-to-Transparent Backsheet Photovoltaic (PV) modules, exemplified by the PIX MBHTB 144 Mono Perc Bifacial Half-Cut NDCR model, stand at the forefront of solar innovation, seamlessly blending efficiency with the versatility of bifacial technology. In this comprehensive guide, we explore the distinctive features, operational principles, advantages, and versatile applications of these cutting-edge modules, emphasizing their pivotal role in maximizing solar energy generation.

Understanding Glass-to-Transparent Backsheet PV Modules - PIX MBHTB 144 Mono Perc Bifacial Half-Cut NDCR:

Glass-to-Transparent Backsheet modules integrate mono perc bifacial half-cut cells between tempered glass and a transparent backsheet, embodying a design that excels in performance and adaptability. The PIX MBHTB 144 model showcases cutting-edge technology, providing exceptional efficiency in solar energy conversion.

Working Principle:

The operational principle involves harnessing sunlight through the tempered glass and initiating the photovoltaic process within the mono perc bifacial half-cut cells. This innovative design not only optimizes energy conversion from the front but also captures reflected sunlight from the rear, enhancing overall efficiency and power output.

Advantages of Glass-to-Transparent Backsheet PV Modules - PIX MBHTB 144 Mono Perc Bifacial Half-Cut NDCR:

(a). Bifacial Technology: Bifacial cells capture sunlight from both the front and rear sides, increasing energy yield and efficiency.

(b). High Energy Conversion Efficiency: The mono perc bifacial half-cut cells, coupled with the glass-to-transparent backsheet design, result in an impressive energy conversion efficiency of 21.29%, ensuring optimal power generation.

(c). Versatility in Applications: The PIX MBHTB 144 model is adaptable for various installations, including those where capturing reflected sunlight is advantageous.

Applications:

The PIX MBHTB 144 Mono Perc Bifacial Half-Cut NDCR model finds applications across different sectors:

(a). Ground-Mounted Solar Farms: Ideal for large-scale solar installations, where bifacial technology can capture additional sunlight reflected from the ground, boosting overall energy production.

(b). Commercial and Industrial Projects: Suited for installations where maximizing efficiency and energy yield is paramount, contributing to the energy needs of businesses and industries.

(c). Projects in Snowy Environments: Bifacial technology can enhance energy production in snowy conditions by capturing sunlight reflected off the snow.

Performance Specifications:

Power Output: 550 watts

Voltage Range: 510-550 volts

Efficiency: 21.29%

Current: 4.99 amperes

Maintenance and Care:

Regular maintenance, including cleaning the tempered glass and transparent backsheet, is essential to ensure sustained efficiency and longevity of Glass-to-Transparent Backsheet PV Modules - PIX MBHTB 144 Mono Perc Bifacial Half-Cut NDCR.

Conclusion:

Glass-to-Transparent Backsheet PV Modules, particularly the PIX MBHTB 144 Mono Perc Bifacial Half-Cut NDCR model, represent the cutting edge of solar efficiency and adaptability. Their incorporation of bifacial technology, high energy conversion efficiency, and versatile applications make them a preferred choice for solar projects seeking optimal performance. As the demand for cleaner energy sources grows, these modules play a crucial role in advancing the efficiency and sustainability of solar technology, contributing to a greener and more energy-efficient future.

Product Features

Cutting edge Cell Splitting Technology

Enhanced Absorption

Flexible Application

High Power Density

Low Light Performance

Sustainable Production Process