An inverter power cabinet includes a cabinet body and power devices arranged in the cabinet body. The cabinet body includes a low-protection grade installation cavity and an airtight high-protection grade installation cavity hermetically isolated from each other; the power devices include high protection grade power devices arranged in the low-protection grade installation cavity and low-protection grade power devices arranged in the high-protection grade installation cavity; the low-protection grade installation cavity has an outer cold air inlet and an inner hot air outlet in communication with outside world, and a first fan is provided in the low-protection grade installation cavity; and the inverter power cabinet includes a heat exchanger configured to dissipate heat of the high-protection grade installation cavity. The inverter power cabinet can avoid direct contact of the low-protection grade power devices with a harsh environment, thereby preventing the contaminated cold air from damaging the low-protection grade power devices.

An equipment enclosure with temperature control components, an equipment enclosure temperature control unit, an equipment enclosure temperature control method, and various modular temperature control subassemblies are respectively disclosed for controlling the temperature of equipment in an equipment chamber. The temperature control components and unit may be implemented with a modular design wherein an air-conditioning unit is selectively mountable on an air handler assembly. The temperature control components and unit may support air-conditioning, free-air-cooling, free-air-cooling-with-return, and heating modes of operation. An emergency-free-air-cooling mode of operation may also be supported.

Aspects of the disclosure generally relate to at least one device for heat transfer or dissipation. The at least one device for heat transfer or dissipation can include an air-to-air heat exchanger. The air-to-air heat exchanger can include an air flow inlet and various slots to establish a flow-through air path.

An embodiment includes a cooling unit, including: a housing configured to attach to an enclosure opening in a sealed manner, where the enclosure houses heat generating electrical equipment; the housing including: a first ambient side area including a compressor, condensing coils, and an ambient air intake and outlet; a first enclosure side area situated above the first ambient side area and including an electrical box that includes one or more relays and a digital controller; a second enclosure side area extending along the rear side of the housing and communicating with the first enclosure side area, including an impeller, an enclosure air intake, an enclosure air return, and evaporator coils in fluid communication with the condenser coils; and a second ambient side area including an impeller and one or more hot air exhausts; where all components of the cooling unit are non-sparking and non-arcing; and where the first and second ambient side areas are sealed off from the first and second enclosure side areas. Other embodiments are described and claimed.

Heat exchanger assemblies and methods are provided for cooling the interior of an enclosure (e.g., electrical cabinets, computer server racks, chemical chambers, and animal cages). Heat is transferred via thermal conduction from a first plurality of surfaces positioned inside the enclosure to a second plurality of surfaces positioned outside the enclosure. The first and second plurality of surfaces remain in thermal contact with one another during use. Heat is dissipated from the second plurality of surfaces to the ambient air outside the isolated environment without the ambient outside air mixing together with the air inside the enclosure. This, in turn, inexpensively removes heat from the air inside the enclosure and prevents contaminants from entering the enclosure.

An inverter and an integrated platform having the same are provided. The inverter includes a cabinet having a cabinet door; an inverter body arranged in the cabinet; and a heat exchanger arranged on an outer side of the cabinet, where the inverter body has an alternating-current side, and the cabinet door is arranged on the alternating-current side or an opposite side of the alternating-current side of the inverter body.

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 invention relates to a heat exchanger for cooling a switch cabinet, with a first line system for a first coolant and with a second line system, separated fluidically from the first line system, for a second coolant, in which the first and the second line system are coupled thermally to one another, and to a corresponding switch cabinet.

An electric cabinet that includes a front part and a rear part, and designed to receive removable electric functional units, further including: a separating partition delineating a first thermal area formed by a first space located at the front part of the electric cabinet, the first thermal area being designed to receive first electric apparatuses of the removable electric functional units, and a second thermal area formed by a second space located at the rear part of the cabinet, the second thermal area being designed to receive second electric apparatuses of the removable electric functional units, and the second thermal area is hotter than the first thermal area, and the first electric apparatuses heat more than the second electric apparatuses, the electric cabinet further includes a cooling source; and an actuator allowing air to flow.

An embodiment includes a cooling unit, including: a housing configured to attach to an enclosure opening in a sealed manner, where the enclosure houses heat generating electrical equipment; the housing including: a first ambient side area including a compressor, condensing coils, and an ambient air intake and outlet; a first enclosure side area situated above the first ambient side area and including an electrical box that includes one or more relays and a digital controller; a second enclosure side area extending along the rear side of the housing and communicating with the first enclosure side area, including an impeller, an enclosure air intake, an enclosure air return, and evaporator coils in fluid communication with the condenser coils; and a second ambient side area including an impeller and one or more hot air exhausts; where all components of the cooling unit are non-sparking and non-arcing; and where the first and second ambient side areas are sealed off from the first and second enclosure side areas. Other embodiments are described and claimed.