HALO
Between square inch,
Create infinite
green energy
The HALO series high-efficiency heterojunction modules use N-type high-efficiency heterojunction cells, made by combining with SMBB technology and Double-sided μc-Si technology, natural symmetrical bifacial structure to bring higher power generation on the backside. The modules are suitable for various scenarios such as residential roofs, industrial and commercial roofs, and ground power stations.
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HALO
Between square inch,
Create infinite green energy
The HALO series high-efficiency heterojunction modules use N-type high-efficiency heterojunction cells, made by combining with SMBB technology and Double-sided μc-Si technology, natural symmetrical bifacial structure to bring higher power generation on the backside. The modules are suitable for various scenarios such as residential roofs, industrial and commercial roofs, and ground power stations.
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H
JT
A
UGMENT
L
OWER
O
CARBON
Efficient HJT Cell
Augment Efficiency
Lower LCOE
0 Carbon Future
HJT
AUGMENT
LOWER
OCARBON
Efficient HJT Cell
Augment Efficiency
Lower LCOE
0 Carbon Future
cover
Efficient HJT Cell
Modules adopt double-sided μc-Si technology, which improves significantly and power output, significantly reduce the LCOE
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Higher Bifacial Ratio
Modules have natural symmetrical bifacial structure, more than 90%+ bifaciality to bring higher power generation on the backside
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Ultra-low Temperature Coefficient
-0.26%/℃ Pmax temperature coefficient to ensure lower power loss in high temperature environments
Better Power Generation Performance
Zero LID and PID for lower power loss
Higher Reliability
Industry-leading technology and performance warranty to ensure modules’ outstanding and stable performance
Efficient HJT Cell
Modules adopt double-sided μc-Si technology, which improves significantly and power output, significantly reduce the LCOE
cover
Higher Bifacial Ratio
Modules have natural symmetrical bifacial structure, more than 90%+ bifaciality to bring higher power generation on the backside
cover
Ultra-low Temperature Coefficient
-0.26%/℃ Pmax temperature coefficient to ensure lower power loss in high temperature environments
Better Power Generation Performance
Zero LID and PID for lower power loss
Higher Reliability
Industry-leading technology and performance warranty to ensure modules’ outstanding and stable performance
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High conversion efficiency
Modules efficiency up to 23.04%
High reliability
PID Resistance, Polyisobutylene (PIB) Sealant, Industry leading warranty
High power generation
Excellent low-light performance, Low temperature coefficient, High bifacial ratio, low degradation rate
High conversion efficiency
Modules efficiency up to 23.04%
High reliability
PID Resistance, Polyisobutylene (PIB) Sealant, Industry leading warranty
High power generation
Excellent low-light performance, Low temperature coefficient, High bifacial ratio, low degradation rate

HALO Series Recommend

720W

720W

Bifacial Dual Glass HJT Module
Double-sided μc-Si technology to ensure higher cell efficiency and module power, effectively reducing LCOE
-0.26%/℃ Pmax temperature coefficient to ensure lower power loss in high temperature environments
645W

645W

Bifacial Dual Glass HJT Module
Double-sided μc-Si technology to ensure higher cell efficiency and module power, effectively reducing LCOE
-0.26%/℃ Pmax temperature coefficient to ensure lower power loss in high temperature environments
Solutions
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Commercial and Industry Solutions
Floating Photovoltaics Plants
EV Charging Station Solutions
Large-Scale Utility Applications
Mountain PV Power Plants
Commercial and Industry Solutions
Floating Photovoltaics Plants
EV Charging Station Solutions
Large-Scale Utility Applications
Mountain PV Power Plants

CONTACT US

CONTACT US

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