Asymmetric Fluid Flows Brazed Plate Heat Exchanger

Asymmetric Fluid Flows Type UFP20A Unequal Flow Path Brazed Plate Heat Exchanger

Product Introduce : 

Unequal Flow Path is the one kind of innovative , patent which incoming from Brazed Heat Exchanger , this kind of unequal flow path signify it is different on cold and heat for path volume . It is beneficial to take advantage of reasonable pressure drop on two flanks , If there is different flow or different fluid properties , for example oil and water , or different reasonable pressure drop needed on two flanks . Then ,  optimized heat transfer , so as to make the quantity of heat exchanger plate in unit reduce to the minimum , in some cases , the quantity of heat exchanger under the same load max reduce 25% . The path volume of primary side is 25% larger than secondary side .

Asymmetric Flow Path Design: The heat exchanger is designed with asymmetric flow paths. The channel structures and dimensions between each plate can be adjusted according to the heat conduction requirements of the fluids to achieve optimal heat transfer efficiency.

Brazing Technology: The heat exchanger plates are joined together using brazing techniques. During the brazing process, a filler material is melted and used to form a strong connection, ensuring the heat exchanger's sealing and durability.

Heat Conduction Performance: The asymmetric flow path brazed plate heat exchanger achieves efficient heat transfer through the high thermal conductivity of the metal plates. The corrugated structure of the plates increases the heat exchange surface area and promotes turbulence, enhancing heat conduction.

Wide Range of Applications: The asymmetric flow path brazed plate heat exchanger is suitable for various heat exchange applications involving different fluid combinations, such as liquid-to-gas, gas-to-gas, or liquid-to-liquid.

Customizable Design: The design of the asymmetric flow path brazed plate heat exchanger can be customized according to specific application requirements. By adjusting parameters such as the number of plates, channel shapes, and sizes, optimal heat conduction and heat transfer efficiency can be achieved.

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