A heat exchanger for receiving an airflow having an uneven intensity distribution across the heat exchanger and for flowing refrigerant within the heat exchanger. The heat exchanger includes sections of microchannel tubes for flowing refrigerant through at least one pass through the heat exchanger, wherein the sections are configured according to the airflow across the heat exchanger. The heat exchanger may be used in an HVAC system. A method may also be performed to manufacture the heat exchanger.

An HVAC system for use with a first refrigerant and a second refrigerant. The HVAC system may include a first refrigerant circuit for use with the first refrigerant, a second refrigerant circuit for use with the second refrigerant, and a heat exchanger. The first refrigerant circuit and the second refrigerant circuit may each include may include a compressor, an expansion device, and an evaporator. The compressor may include a first upper section, a first lower section, a second upper section in fluid communication with the first lower section, and a second lower section in fluid communication with the first upper section. The first upper section, the first lower section, the second upper section, and the second lower section may be arranged such that the first refrigerant and the second refrigerant both flow through a majority of a face area of condenser while remaining in two different circuits.

A multi-channel high-efficiency heat dissipation water-cooling radiator includes a water distribution box, a water collection box, a first radiating pipe, a second radiating pipe, a third radiating pipe, and a fourth radiating pipe. Multiple chambers are formed by arranging partitions in both the water distribution box and the water collection box, and each radiating pipe is in communication with the corresponding chambers, so that the channels in the water-cooling radiator are connected in sequence to form a circuitous configuration. This allows the water to travel a longer distance in the water-cooling radiator, so that the water-cooling radiator can effectively cool the water and dissipate heat.

A water-cooling radiator includes a first water collection box, a second water collection box and a plurality of radiating pipes. A water pump chamber is disposed in a box body, and is in cooperation with a water pump, an impeller and a water pump cover to form. a water pump structure with good airtightness, so that the water pump and the first water collection box are effectively combined. The flow speed of water in the water-cooling radiator is effectively accelerated, which improves the heat dissipation efficiency. The overall heat dissipation effect of the product is very good.

A water-cooling radiator structure with pump includes a pump having a water outlet and a water inlet; and a water-cooling radiator including a first chamber that has a water-receiving room and a plurality of mutually communicable water passages therein. The water-receiving room is filled with a working fluid that reaches a level. The first chamber is externally provided with an outlet and an inlet as well as a pump mounting recess for mounting the pump therein. The water outlet and the water inlet are located corresponding to the outlet and the inlet, respectively, to be communicable with the water-receiving room and located lower than or flush with the level of the working fluid in the water-receiving room. And, the pump is detachably integrated into the water-cooling radiator. With these arrangements, it is able to overcome the problem of failed operation of the pump when the water-cooling radiator is laid horizontally.

A collector assembly includes a first collector and a pipe. The first collector includes an outlet pipe. A pipe chamber of the outlet pipe is in communication with an inner chamber of the first collector. The pipe includes an inlet end portion and an outlet end portion. The inlet end portion is located in the first collector. The outlet end portion is at least partially located in the outlet pipe. An inner chamber of the pipe is in communication with the pipe chamber of the outlet pipe and the inner chamber of the first collector. At least part of the outlet end portion is located in the pipe chamber of the outlet pipe. A heat exchanger having the collector assembly is also disclosed.

The present disclosure provides materials and methods related to passive cooling systems. In particular, the present disclosure provides a condensorator heat exchanger with a single microchannel coil that integrates the evaporator and condenser into one assembly. The passive heat exchanger systems of the present disclosure provide enhanced cooling capacity and airflow in environments ranging from outdoor electronic enclosures to commercial and residential buildings.

A heat exchanger for receiving an airflow having an uneven intensity distribution across the heat exchanger and for flowing refrigerant within the heat exchanger. The heat exchanger includes sections of microchannel tubes for flowing refrigerant through at least one pass through the heat exchanger, wherein the sections are configured according to the airflow across the heat exchanger. The heat exchanger may be used in an HVAC system. A method may also be performed to manufacture the heat exchanger.

A vapor/liquid condensation system includes a condensation unit and an evaporation unit. The condensation unit is connected with the evaporation unit via conduits. The evaporation unit has a liquid inlet, a vapor outlet and an evaporation chamber in communication with each other. The evaporation unit converts liquid-phase working fluid into vapor-phase working fluid, which spreads to the condensation unit. The condensation unit cools and condenses the vapor-phase working fluid into liquid-phase working fluid, which goes back the evaporation unit. After the vapor-phase working fluid enters the condensation unit, the vapor-phase working fluid is distributed and condensed into liquid-phase working fluid. Then the liquid-phase working fluid is collected and then goes back to the evaporation unit. The length of the pipeline is shortened and the pipeline pressure is lowered to avoid interruption of heat dissipation circulation and failure in heat dissipation.

A heat exchanger is provided, including a heat exchanger core. The heat exchanger core at least includes a first core part, a second core part and a third core part which are stacked. The first core part, the second core part and the third core part are formed by stacking plates. The third core part is located between the first core part and the second core part. The first core part is in the form of unilateral flow. The second core part is in the form of diagonal flow. The third core part can realize transformation of flow channel forms of the first core part and the second core part, and is stacked with the first core part and the second core part, and thus the heat exchange efficiency is good.