The present disclosure provides a plate heat exchanger comprising: a plurality of heat transfer plates stacked in a first direction, wherein the heat transfer plate is configured to have a heat transfer plate edge on its side in a second direction perpendicular to the first direction; first and second fluid channels formed between adjacent heat transfer plates and fluidly isolated from each other; two first ports formed in the heat transfer plate on the side and an opposite other side of the heat transfer plate in the second direction, respectively, and fluidly communicated to the first fluid channel; and a hole formed in the heat transfer plate between one of the two first ports located on the side and the heat transfer plate edge in a second direction, which is fluidly communicated to the first fluid channel and fluidly isolated from the second fluid channel. By disposing the hole in a bottom area of the plate heat exchanger, excessive water remained in the plate heat exchanger when it is not in use is avoided, so as to prevent freezing in the plate heat exchanger.

This disclosure describes an improved heat transfer system for use in reaction vessels used in chemical and biological processes. In one embodiment, a heat transfer baffle comprising two sub-assemblies adjoined to one another is provided.

A heat exchanger includes a plurality of heat exchange modules. Each of the plurality of heat exchange modules includes a pair of headers, a plurality of flat heat-transfer tubes, and a plurality of corrugated fins. The plurality of corrugated fins each have a corrugated shape and are each placed between ones of the flat heat-transfer tubes that face each other. The corrugated shape has apices joined to the flat heat-transfer tubes. The plurality of corrugated fins each include fin modules between the a pieces. The fin modules are arranged in the up-down direction. One of the corrugated fins situated on a leeward side in the direction of flow of the air is higher in outside-tube heat transfer coefficient than is one of the corrugated fins situated on a windward side in the direction of flow of the air.

A fin structure applied to a microchannel heat exchanger is provided. The fin structure is configured for allowing a flat tube to penetrate. The fin structure includes a plurality of inclined sections, wherein each of the plurality of inclined sections extends from one end of the fin structure to the other end thereof. The plurality of inclined sections are sequentially connected end to end to form a wave shape, and two opposite sides of each of the inclined sections are both provided with an inclined surface.

A heat exchanger for a vehicular air conditioning system is disclosed. The heat changer includes a heat exchanger body, a water storage tank, and a condensate water circulating device. The heat exchanger body is provided with an air-inlet side and an air-outlet side. The air-inlet side is configured to enable an external air flow to enter the heat exchanger body, so that the air flow conducts heat exchange with a refrigerant in the heat exchanger body. The air-outlet side is configured to exhaust the air flow completing heat exchange with the refrigerant. The water storage tank is arranged below the heat exchanger body and is configured to store condensate water formed on the heat exchanger body. The condensate water circulating device is configured to transport cold water in the water storage tank to the air-inlet side of the heat exchanger body for heat exchange with the heat exchanger body.

This disclosure describes an improved heat transfer system for use in reaction vessels used in chemical and biological processes. In one embodiment, a heat transfer baffle comprising two sub-assemblies adjoined to one another is provided.

A liquid cooling heat dissipation system is disclosed, including: a primary side cooling unit, a secondary side cooling unit and a heat exchange unit, wherein an outlet of the primary side cooling unit is in communication with a primary side inlet of the heat exchange unit, and a primary side outlet of the heat exchange unit is in communication with an inlet of the primary side cooling unit.