Hi-MO3 with 320W Front-side Power: A Worthy Successor of Bifacial PERC

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LONGi Solar, a leading, vertically integrated monocrystalline manufacturer, showcased its third-generation product - the Hi-MO3 half-cut bifacial PERC module - at the SNEC (2018) International Photovoltaic Power Generation and Smart Energy Exhibition & Conference at the Shanghai New International Expo Center.

LONGi Solar’s Hi-MO series have led the industry in technology development of monocrystalline PERC with high power, high yield and low LID. Hi-MO3 combines advanced monocrystalline PERC cell technology and bifacial, half-cut module construction to provide energy producers with a brand new choice to reduce LCOE.

Hi MO 3产品主K英16 9 比例

May 2016. LONGi Solar released the first-generation Hi-MO1 products enabled with high-efficiency, low-LID PERC technology, setting off rapid growth in monocrystalline PERC. Empirical data showed that Hi-MO1 energy yield per watt was 3% higher than that of conventional modules;

April 2017. The 2nd generation Hi-MO2 bifacial PERC was released. Based on continuously developed PERC technologies, the front-side power of Hi-MO2 (60-cell) module exceeded 300W, with rear-side yield of 5-25% and a 30-year quality assurance that helps the industry significantly reduce LCOE and enhance project profitability;

May 2018. Based on Hi-MO2 integrated with advanced half-cut module construction and LONGi Solar’s continuous breakthroughs in monocrystalline PERC technology, the 3rd generation Hi-MO3 half-cut bifacial PERC module pushed front-side power up to 320W.

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Hi-MO3 inherits its predecessor’s low-LID and high rear-side yield, with more advantages:

  1.  Higher power. The power on the front-side reaches 320W (60-cell) / 380W (72-cell) in series production;
  2.  Lower hot spot effect. Under the same test conditions, the average hot spot temperature of half-cut module is 10-12 ℃ lower than that of full-sized cell modules;
  3. Higher yield. The yield under shaded conditions is significantly enhanced.
  4. Lower LCOE, with reductions of up to 11%.

In terms of power generation, Hi-MO3 with half-cut cells and bifacial construction has the efficient power of monocrystalline PERC, better performance in shade, enhanced energy yield, lower hot spot temperature and lower LCOE. In the high-irradiation regions and under shaded conditions, Hi-MO3 advantages help to sharply reduce LCOE and accelerate the progress of PV grid parity.

Development trends in Bifacial PERC

Among high-efficiency cell technologies, PERC is undoubtedly the most cost-effective. Compared with conventional cell, the production of PERC cell needs only to add rear passivation and laser slotting sections, coupled with metallization techniques. This will effectively enhance the conversion efficiency of the cells. In the past six months, the world record for PERC cell conversion efficiency has been constantly refreshed, demonstrating the strong potential upside of PERC.

Mature manufacturing techniques and reasonable capital investment can drive the expansion of PERC cell capacity. According to ASIACHEM statistics, as of May 2018, global PERC cell capacity reached 46.8 GW. Newly built or upgraded p-type monocrystalline silicon cell production lines will all adopt PERC technology. It is obvious that PERC solar cell technology is becoming a new-generation norm.

On this basis, bifacial PERC is also becoming an important route in the development of the technology. The commonly used manufacturing technology for bifacial PERC cell is to change the printing process of the PERC single-sided cell, and changing the rear surface from whole aluminum layer to a local aluminum layer. This allows incidental light on the rear surface to enter the cell from the exposed layer and create photoelectric conversion on both the front and rear sides.

In this process, with negligible increase in manufacturing cost, bifacial PERC can achieve power generation gain of 10%-25% at the system level, which will significantly reduce the LCOE of the PV system while greatly enhancing the competitiveness and development potential of PERC technology.

Bifacial PERC + half-cut technique further improve the cost performance of modules

To further realize the advantages of high power conversion of high efficiency cells, combining PERC cells with innovative module construction technique is an important upgrade route for manufacturers of PERC cells and modules. From a technology perspective to improve module output power, half-cut cell is undoubtedly a high performance and low cost product that is easy to implement in large scale production

Half-cut cell is the technique that cuts a conventional cell in half and then connecting the two halves together. Compared with conventional cell, the only operation required is to cut the whole cell into two parts by laser before string welding them. The cell splitting and transmission are fully automatic and the string welder needs only slight modification to achieve large-scale production.

Half-cut cell construction has the following characteristics:

1) As the cell is split in two, thermal resistance loss is reduced and output power of the half-cut-cell module is 5-10W higher compared to a full-cell module of the same type;

2) The hot spot temperature of the half-cut-cell module is about 25℃ lower than that of the full-cell module of the same type. This can effectively reduce the hot spot effect;

3) The half-cut-cell module can meet the 1500V system voltage design requirements and can reduce the cost of the system by about 10%.

Since half-cut module greatly enhances the output power without adding much additional cost, high-power half-cut cell module is being developed on a large scale. In 2018 SNEC, half-cut cell module was a must-have exhibit for PV module manufacturers.

At Intersolar Europe, LONGi Solar will present the new Hi-MO3 PERC Half-Cut Cell Bifacial module. The innovative combination of half-cut cell and bifacial module construction achieves front-side power up to 320W (60-cell), with bifaciality more than 75%. Under shady conditions, Hi-MO3 can deliver higher energy yield than whole-cell module array.