Views: 13 Author: Site Editor Publish Time: 2020-12-07 Origin: Site
Shanghai, December 4th, 2020 – On December 4, ZNShine Solar delivered the first 182mm module order from its Jintan manufacturing site to Vietnam.
The product delivered is a Light-Weight Double Glass half-cell module based on 182mm bifacial cell with 10BB and a power output of 530W. This product adopts advanced non-destructive cutting and high-density interconnection technology in the industry, which greatly reduces the risk of micro-cracks and later reliability in the module manufacturing process and improves the power generation efficiency of the module.
ZNShine Solar PV modules technology and production team continue to innovate and improve in product design and development, product reliability verification, supply chain screening, and other key activities to meet the market and customers’ needs.
As a leader in MBB technology, ZNShine Solar has reached 12BB mass production technology and experience. MBB can greatly reduce the current collection path and improve the optical and electrical performance of the module.
The 530W module can significantly reduce the overall BOS cost. The module size is 2256x1133mm, which is perfectly compatible with 1p and 2P tracker.
The Double Glass with frame design ensures easier installation and an improved load performance (the static load test passed + 5400pa / – 2400pa).
ABOUT ZNSHINE SOLAR
Founded in 1988, ZNShine Solar is a BNEF Tier1 module manufacturer with over 32 years of manufacturing excellence and 5 GW module production capacity. Scored as a “Top Performer” in the DNV GL PV Module Reliability Scorecard, ZNSHINE SOLAR (NEEQ Stock Code: 838463) has developed as a PV plant partner and investor having delivered bespoke EPC solutions and O&M services.
In recent years, the rapid development of solar photovoltaic (PV) technology has been accompanied by the continuous iteration of solar cell sizes. From the early 156mm era to today’s widespread use of larger 182mm and 210mm cells, each technological advancement has driven improvements in module power and optimization of system costs.
Graphene is hailed as the most revolutionary material of the 21st century, earning the title of "king of new materials" due to its exceptional properties. Composed of a single layer of carbon atoms arranged in a honeycomb lattice, graphene exhibits a range of remarkable physical characteristics. It is 100 times stronger than steel and has excellent electrical conductivity, with its carrier mobility at room temperature being approximately 10 times that of silicon. Additionally, graphene boasts outstanding thermal conductivity, with a thermal conductivity coefficient of up to 5300 W/mK, far surpassing most materials. Graphene is also nearly transparent, with an absorption rate of just 2.3% in the optical range. It retains excellent flexibility, allowing it to bend and deform while maintaining its structural integrity. These unique properties make graphene a material of enormous potential across various fields and are widely believed to herald a materials revolution.
When purchasing solar modules, performance and price are the two key factors to consider. The performance of a solar module depends not only on its photovoltaic conversion efficiency but also on the strength and durability of its structure. As a crucial support and protective component, the frame material has a direct impact on the overall performance of the module. Additionally, solar module frames, being high-value auxiliary materials, play a significant role in the module’s total cost structure. For instance, *the commonly used aluminum frame, with its strong mechanical properties, accounts for around 13% of the total module cost—surpassing other auxiliary materials like EVA, glass, backsheets, and solder ribbons—second only to the 55% cost share of the solar cells themselves.
Installing a solar photovoltaic (PV) system on a roof is a crucial process that requires ensuring the system efficiently captures solar energy while maintaining its safety and stability. This article will describe how to use the SRS (Solar Racking System) to install PV modules more securely and efficiently.
Una célula fotovoltaica es algo relativamente sencillo. Un material semiconductor, en el que se ha creado un diodo (se le ha dado polaridad), al que se le pone una capa azul antirreflejante y se conectan unos conductores eléctricos para extraer la electricidad. Digamos que la arquitectura de la célu
The first bifacial photovoltaic cells were created in the laboratory several decades ago. The first company that commercialized them was the Spanish company Isofoton (1981), based on the studies of Antonio Luque at the Institute of Solar Energy in Madrid.Today’s bifacial solar modules are a simplifi
Double glass photovoltaic modules stand out with remarkable advantages in power generation, embodying authenticity in their performance. The transparency and robust UV resistance of glass seamlessly align with the characteristics of double-sided cells, establishing a flawless synergy. When it comes to the module backsheet, the industry widely acknowledges the superiority of glass backsheets. In 2018, Joshua S. Stein from Sandia National Laboratories and Dirk C. Jordan from the National Renewable Energy Laboratory (NREL) conducted an in-depth review of double glass photovoltaic modules, delving into various pertinent issues.
Recently, ZNSHINE SOLAR, through its Singapore subsidiary ZNSHINE ENERGY INVESTMENT PTE LTD, officially launched a 549.26 kW solar project in the Bandar Baru Bangi area of Malaysia. This project will provide commercial and industrial rooftop solar support for the Malaysian factory of Japan’s Okumura Metal. Situated near Kuala Lumpur, Malaysia’s capital, the project marks a significant step in ZNSHINE SOLAR's strategic development in Southeast Asia’s green energy market. It also serves the solar rooftop needs of multiple Japanese corporations with overseas factories, demonstrating ZNSHINE SOLAR’s unique advantage in supporting global enterprises in their green transformations.