Flow Channel Design: The design of the flow channels is crucial to the performance of the heat exchanger. Optimizing the cross-sectional shape, arrangement, and width of the flow channels can improve fluid turbulence and reduce fluid resistance within the heat exchanger, thereby increasing heat transfer efficiency.
Heat Transfer Surface Treatment: To enhance the heat transfer performance of the plates, various surface treatments can be applied, such as spraying, electroplating, and electroless plating. These treatments increase the surface area of the plates, improving their thermal conductivity.
Sealing Structure Design: To ensure a tight seal between the plates, the shape and material of the sealing gaskets need to be rationally designed. Simultaneously, the distribution and number of fixing bolts also need to be optimized based on actual conditions to ensure the stability and reliability of the plates.
Material Selection: The selection of materials for the heat exchanger is also very important. For special operating conditions such as high temperature, high pressure, and corrosive fluids, materials with excellent corrosion resistance, high-temperature strength, and stability must be selected.

