The New Energy industry, including solar power, energy storage, wind power, and HVDC transmission, requires reliable and efficient thermal management solutions. High-power modules in inverters, storage systems, and power electronics generate significant heat that can affect performance, efficiency, and safety. Liquid Cold Plates and heat sinks are essential for maintaining optimal operating temperatures and ensuring long-term system stability.

Photovoltaic / Solar Inverters

High-power string inverters and medium-to-large centralized inverters have high power densities and generate substantial heat in IGBTs and other power modules. Efficient cooling is crucial for stable operation in outdoor environments.

Liquid cold plates, including FSW Liquid Cold Plates, Tube Liquid Cold Plates, Brazed Liquid Cold Plates, and CPU Water Blocks, provide direct cooling for high-power components. Integrated water cooling plates, water cooled cold plates, and cold plate electronics cooling ensure precise temperature control and uniform heat dissipation. Small cold plates, standard cold plates, and tube cold plates provide flexible integration options for different inverter designs.

Energy Storage Systems

Large-scale energy storage systems, including battery modules and storage inverters, require precise thermal management. Water cooled electronics, liquid cold plates, and Heat Sinks remove heat efficiently from high-power cells and converters, improving charge/discharge efficiency, safety, and component lifespan.

Advanced cold plate design, cooling plates for electronics, and water cooling circuits allow accurate temperature control across all modules. Hybrid solutions combining heat sinks with water cooling and liquid cooled heat sinks provide additional flexibility and high thermal efficiency.

Wind Power

Wind inverters and converters operate under high loads and challenging environmental conditions. Liquid cold plates and water cooled heat sinks ensure reliable cooling for IGBTs and power electronics.

Aluminum heat sinks, copper heat sinks, extruded heat sinks, skived fin heat sinks, and finned heat sinks are applied for auxiliary cooling, while water cooled heat sinks, heat sink with water cooling, and heat sink cold plates optimize high-power heat removal. Heat sink design, thermal resistance, and heat sink fin efficiency are optimized for demanding wind power applications.

High-Voltage Direct Current (HVDC) Transmission

HVDC systems rely on high-power modules like IGBTs and thyristors, which require efficient thermal management. Liquid cooled heat sinks, cold plate cooling, and water heat pipes ensure uniform temperature distribution and protect critical components.

Heat sinks, including large aluminum heat sinks, copper pipe heat sinks, heat sink with heat pipe, and liquid heat sinks, provide reliable heat dissipation. Advanced heat sink design software, simulation, and thermal analysis ensure optimal performance and safe operation.

Advantages of Liquid Cold Plates and Heat Sinks in New Energy

1. High thermal efficiency – Rapid heat removal from high-power modules ensures safe and reliable operation.

2. Precision cooling – Cold plate electronics cooling and heat sink design provide uniform temperature control.

3. Flexible integration – Solutions such as small cold plates, tube cold plates, extruded heat sinks, and liquid cooled heat sinks fit compact designs.

4. Extended component life – Maintaining optimal temperatures reduces thermal stress and increases system reliability.

5. Hybrid cooling solutions – Combining liquid cold plates and heat sinks provides maximum cooling efficiency in high-power applications.

In the New Energy industry, reliable thermal management is critical for photovoltaic inverters, energy storage systems, wind power converters, and HVDC transmission units. Liquid Cold Plates and Heat Sinks, including FSW Liquid Cold Plates, Tube Liquid Cold Plates, Brazed Liquid Cold Plates, aluminum heat sinks, copper heat sinks, and water cooled heat sinks, deliver precise, efficient, and customizable cooling solutions.

By integrating water cooling technology, cold plate cooling, water cooling circuits, and optimized heat sink design, new energy systems achieve stable operation, enhanced performance, and extended component lifespan, ensuring safety and efficiency in renewable power applications.