A forced double-circuit air cooling system designed for using in a sealed cabinet structure. A first air circuit is formed by an air loop moved around each of local modules (3; 4) of a sealed compartment [2] with using a circulation fan (26) which is installed within a sealed air channel [28]. The first air circuit is formed within an internal air channel (18) of the sealed compartment [2]. Wherein the internal air channel is connected to a number of air heat exchangers [22]. A first pair [22.1] of said number of air heat exchangers is equipped with the circulation fan [26]. Wherein a second air circuit [25] contains straight air channels [23] arranged within the ventilated compartment [24] adjacent to the sealed compartment [2]. Each of said straight air channels [23] comprising a second pair [22.2] of air heat exchangers with a blast fan [27] between them.

A system for managing temperature, that can be adapted to an electrical enclosure, the electrical enclosure delimiting a first volume, the system comprising: a first chamber delimiting a closed second volume and a tank housed in the first chamber and delimiting a closed third volume inside the first chamber, first air transfer means arranged between a first air inlet/outlet connected to the second volume and a second air inlet/outlet intended to be connected to the first volume, second air transfer means arranged between a third air inlet/outlet connected to the third volume and a fourth air inlet/outlet intended to be connected to the first volume, and a control and processing unit intended to apply a mode of operation of the system.

A heat dissipating system and a power cabinet are provided. The heat dissipating system includes a cabinet, a first circulating fan and a heat exchanger. The cabinet has an outer circulating air duct and a sealed inner circulating air duct. The air inlet and the air outlet connected to the outside are arranged in the outer circulating air duct, and the heat exchanger is arranged in the cabinet and configured to exchange heat between the inner circulating air duct and the outer circulating duct. The first circulating fan is arranged outside the air inlet of the outer circulating air duct or arranged inside the outer circulating air duct, and configured to supply air to the outer circulating air duct. The heat dissipation efficiency of the inner circulating air duct is improved.

This application provides a composite cooling system. The composite cooling system includes an indoor air duct and an outdoor air duct that are independent of each other. The indoor air duct and the outdoor air duct intersect in a heat exchange area of the composite cooling system. A first-stage heat exchanger core, a second-stage heat exchanger core, and a first side air duct are disposed in the heat exchange area. The heat exchange area is constructed as a part of the outdoor air duct. The first-stage heat exchanger core, the first side air duct, and the second-stage heat exchanger core are sequentially arranged along a flow direction of the outdoor air duct. An inner cavity of the first-stage heat exchanger core and an inner cavity of the second-stage heat exchanger core each are further constructed as a part of the indoor air duct.

An air conditioner for an enclosure that can include a housing that partly defines an ambient air exchange cavity and a tub that further defines the ambient air exchange cavity and partly defines a cooling cavity. The tub can support a first heat exchanger within the ambient air exchange cavity, and a second heat exchanger and a fan within the cooling cavity. The second heat exchanger can be included in a coolant flow loop with the first heat exchanger and the fan can move air across the second heat exchanger and into the inlet of the enclosure. The second heat exchanger can be located above the fan. A fluid trap can be provided below the second heat exchanger and adjacent the fan to capture condensate from the second heat exchanger and can direct the condensate into the ambient air exchange cavity for disposal.

An air flow generating device includes an enclosing wall, a frame sheet, a cover film, and a vibrating part. The frame sheet is disposed inside an air flow passage formed by the enclosing wall and closely contacts the air flow passage by its periphery. The cover film includes a central connection portion fixed to a central portion of the frame sheet, and a plurality of movable cover portions connected to the central connection portion. The cover film is between the frame sheet and an outlet of the air flow passage. The movable cover portions selectively cover a plurality of through holes of the frame sheet. The vibrating part is fixed on the frame sheet. When the vibrating part vibrates, the central portion and the central connection portion move together with the vibrating part so that the movable cover portions seal the through holes or move relative to the through holes.

Apparatus, systems, and methods are disclosed for cooling an electronic device. An example electronic device includes a chassis, a first fan including a first outlet and a second outlet, and a second fan having a third outlet and a fourth outlet. In the example electronic device, the first fan is to exhaust air through the first outlet and the second fan is to exhaust air through the third outlet to create a positive pressure in the chassis. The first fan is to exhaust air through the second outlet to an exterior of the chassis, and the second fan is to exhaust air through the fourth outlet to an exterior of the chassis.

The heat exchange module is used in the cabinet that includes a cabinet body. The cabinet body has a first space and a second space. A temperature of the first space is higher than a temperature of the second space. The heat exchange module has a first air circulation system and a second air circulation system, and heat exchange may be performed between the first air circulation system and the second air circulation system. Both an air intake vent and an air exhaust vent of the first air circulation system are configured to be connected to the first space. An air exhaust vent of the second air circulation system is connected to an external space, and an air intake vent of the second air circulation system can be configured to be selectively connected to the external space and/or the second space.

A heat exchanger includes a chassis, and a mounting opening and an outer outlet formed at the bottom of the chassis. The cooling core is installed in the chassis and disposed above the mounting opening. The external circulation fan module is installed from the mounting opening into the chassis. The cover covers the mounting opening. External air flows through the cooling core and exchanges heat with the cooling core to simplify the method of mounting the external circulation fan module.

The present application discloses a power cabinet, which is designed as a form of cabinet. All devices in the power cabinet are categorized into two types, and the two types of devices can have their own heat-dissipation channels or share a same heat-dissipation channel, which has a compact overall structure and high heat-dissipation efficiency compared with an air duct layout solution in the conventional technology.