How does topology structure affect the performance of liquid cooling plates?

The performance of topology structure and simple structures is analyzed and compared its temperature, temperature difference, velocity, and pressure changes. The structural design of liquid cooling plates represents a significant area of research within battery thermal management systems.

What is a topological liquid cooling plate?

Geometrical model In the process of topology optimization, the liquid cooling plate is assumed to be a rectangular structure, as shown in Fig. 1, the inlet and outlet of the topological liquid cooling plate are located on the center line of the cold plate, where the dark domain is the design domain, and γ is the design variable.

What is topology optimization of cooling plates for battery thermal management?

Topology optimization of cooling plates for battery thermal management Optimal design and thermal modelling for liquid-cooled heat sink based on multi-objective topology optimization: an experimental and numerical study Topology optimization of heat conduction problem involving design-dependent heat load effect

What is liquid cooled data centre topology?

With reference to the high return water temperature (which exceeds 50 °C), the application of this liquid-cooled data centre topology enables the use of the waste heat of IT equipment for other applications such as domestic hot water, network heating, and industrial applications.

What is the cooling performance of liquid cooling plates with varying structures?

This study primarily investigates the cooling performance of liquid cooling plates with varying structures. Consequently, water is selected as the coolant in the model due to its efficient heat transfer characteristics, and aluminum is employed as the cold plate material due to its excellent thermal conductivity and cost-effectiveness.

Does liquid cooled heat dissipation structure optimization improve vehicle mounted energy storage batteries?

The research outcomes indicated that the heat dissipation efficiency, reliability, and optimization speed of the liquid cooled heat dissipation structure optimization method for vehicle mounted energy storage batteries based on NSGA-II were 0.78, 0.76, 0.82, 0.86, and 0.79, respectively, which were higher than those of other methods.