An electronic apparatus including a box body, at least one heat generating element and an immersion cooling module are provided. The immersion cooling module includes a condensing structure and an airflow guiding device. The box body has a containing space, and the containing space is adapted to contain a heat dissipation medium. The heat generating element is disposed in the containing space to be immersed in the heat dissipation medium which is in the liquid state. The condensing structure is disposed in the containing space and includes a first condensing portion. The airflow guiding device is disposed in the box body and is adapted to guide the heat dissipation medium which is in the gaseous state toward the first condensing portion.

An electronic apparatus including a box body, at least one heat generating element and an immersion cooling module are provided. The immersion cooling module includes a condensing structure and an airflow guiding device. The box body has a containing space, and the containing space is adapted to contain a heat dissipation medium. The heat generating element is disposed in the containing space to be immersed in the heat dissipation medium which is in the liquid state. The condensing structure is disposed in the containing space and includes a first condensing portion. The airflow guiding device is disposed in the box body and is adapted to guide the heat dissipation medium which is in the gaseous state toward the first condensing portion.

A storage battery rack includes bottom frame portion, ceiling frame portion, long support posts, and side panels installed facing the support posts. Each support post has a plurality of attachment holes with a predetermined pitch along the longitudinal direction. Side panel has a plurality of female screw holes with a pitch corresponding to the predetermined pitch. Each side panel is attached to a pair of the support posts with screws fastened to attachment holes and the female screw holes. Side panel has a plurality of parallel support portions. A distance between support portions is set substantially equal to a total value of a predetermined height dimension of a refrigerant passage formed between a plurality of storage batteries and a predetermined height dimension of each storage battery.

A secure electronic equipment rack allows electronic equipment to be hung vertically to save space for deep components. This is done by providing a vertical rack apparatus with horizontal side panels on which components are mounted vertically. The side panels of the rack are shorter than the depth of the components to be mounted on, to, or within the panels, thus allowing space to be saved. The rack can be expanded based on user's equipment growth. The apparatus can be mounted on a wall or on a standard EIA relay rack. The apparatus has cable management for equipment that fits into wire channels and allows having a patch panel mounted without taking up a U space in the apparatus itself. The apparatus can include a built-in level for ease of mounting, and an integrated earth grounding stud. A secure version can include tamper resistance by adding baffling of ventilation areas, for example in both top and bottom vent patterns, and can be designed to be assembled in an overlapping fashion which allows no exposed hardware with the last piece to be assembled being the first to be removed in sequence.

Cooling systems for devices arranged in rows are disclosed. An example cooling system for a datacenter in a building includes a supply air duct to extend lengthwise along a first aisle within the building. The first aisle is defined between a first row of computers and a second row of computers. The first row of computers provides passage of a first current of air from the first aisle to a second aisle on an opposite side of the first row of computers. The supply air duct is to be positioned with an upper section that is higher than a top surface associated with the first and second rows of computers. The cooling system includes a first wing to extend from the supply air duct toward the first row of computers, and a second wing to extend from the supply air duct toward the second row of computers.

A method and apparatus for heat-dissipation utilizing a fin assembly including one or more fins organized on a wall or base surface. The fins can extend into a flow of fluid passing along the wall or base surface to convectively cool the fins, which can transfer heat from heat-producing components, such as electronics.

The invention concerns a helicopter ventilation architecture, said helicopter comprising at least two avionics bays (112a, 112b) comprising electronic equipment (116a, 116b) to be ventilated, said architecture comprising, for each avionics bay, an air inlet (120a, 120b) allowing outside air to enter the avionics bay in order to ventilate said avionics bay, and an air outlet (124a, 124b), allowing the air ventilating the avionics bay to exit the avionics bay, characterised in that the ventilation architecture further comprises a mixing chamber (134), connected to the air outlets, configured to receive the air originating from all the avionics bays, at least one air duct (138a, 138b), connected to the mixing chamber and to an outlet (130a, 130b) for discharging the air to the outside, and at least two fans (128a, 128b), arranged and distributed in the air duct or ducts.

An air baffle may include a body portion having a length and a height, as well as a plurality of folding lines arranged along the length of the air baffle. The folding lines may be substantially parallel to one another and directed along a direction of the height of the body portion. The air baffle may also include mounting features for mounting to a chassis of an information handling system. Based on a configuration of the plurality of folding lines, the air baffle may be mountable in a chassis of an information handling system to direct airflow within the chassis.

A method comprises performing an analysis of airflow and temperature distribution in an indoor environment utilizing a hybrid turbulence model including a Chen-Xu model used for analysis of bulk flow and a wall function used in first grid cells bounding solid objects in the indoor environment and adjusting physical layout and/or operating parameters of heat producing electrical equipment and/or a cooling system of the indoor environment responsive to results of the analysis to improve one of temperature distribution within the indoor environment and operating efficiency of the cooling system of the indoor environment.

A temperature-regulated cabinet (10) includes a cabinet body (1) and a temperature regulating module (2). The cabinet body (1) has a containing space (11) formed inside the cabinet body (1) and an opening (12) communicated with the containing space (11). The temperature regulating module (2) is detachably installed to the cabinet body (1) and covered onto the opening (12) and includes a temperature regulator (21), a first hood (22), a second hood (23) and an exhaust fan (24). The temperature regulator (21) has a casing (211). The first hood (22) is detachably installed to the top of the casing (211), and the second hood (23) is detachably installed to the bottom of the casing (211). The exhaust fan (24) is installed inside the first hood (22) or the second hood (23). The cabinet has the advantages of simplifying the production line and lowering the construction and operation costs.