Jinko Solar modules with 445 Wp - efficiency in a compact space


The 445 Wp modules from Jinko Solar 's Tiger Neo series stand for high efficiency and modern cell technology in a compact design. With N-type half-cell technology, optimized efficiency and a robust mechanical design, they are particularly suitable for projects where limited roof space is to be used efficiently - for example in residential and commercial installations. The combination of performance, stability and long-term yield reliability makes them a reliable choice for demanding installations.

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Jinko Solar 445 Wp modules - High output in a compact space


The 445 Wp solar modules in the Tiger Neo series from Jinko Solar combine state-of-the-art N-type cell technology with a space-saving format consisting of 54 half cells. They offer a high output per square meter with a robust design - ideal for residential and commercial roofs where reliability and efficiency are paramount.

Technological highlights


The modules achieve an efficiency of up to 22.27 % and use N-Type HOT 2.0 technology, which ensures lower degradation and higher temperature tolerance. Thanks to SMBB (Super Multi Busbar) technology, the current flow is optimized and energy losses are reduced. The modules are also PID-resistant, which makes them particularly durable.

Mechanically, they impress with a load capacity of up to 6000 Pa snow load and 4000 Pa wind load, making them suitable for regions with demanding environmental conditions. The guaranteed linear performance over 30 years and the reduced annual degradation of just 0.4 % underline the long-term benefits.

Areas of application

  • Rooftop systems in the residential and commercial sector

  • Installations with limited space requirements

  • PV projects with a focus on efficiency and longevity

Discover more technologies from Jinko Solar


Jinko offers a wide range of technological options in addition to the 445 Wp modules:


Discover other watt classes such as 435 Wp or 475 Wp - ideal for adapting to different areas, system sizes and power requirements.