An electronic display assembly includes a display unit supported by a housing assembly. An upper portion is supported by said housing assembly above, and spaced apart from, the display unit. One or more fans associated with the upper portion move ambient air ingested through one or more intake/exhaust apertures in upper portion housing between an upper cavity and a transition area between the upper portion and the display unit. Ambient air is ingested through one or more intakes at the transition area by one or more fans associated with said display unit and forced though said at least one open loop airflow pathways within said display unit.

A display device including a carrying main body, a flexible display panel and at least one fan is provided. The flexible display panel is disposed on the carrying main body and adapted to be unfolded on the carrying main body. A gap is formed between the flexible display panel and the carrying main body. The fan is disposed on the carrying main body and adapted to generate an airflow, and a flow path of the airflow is located at the gap.

Systems and method for thermally managing display assemblies are provided. A closed loop pathway for circulating gas includes a channel located behind an electronic display located at a housing. A fan unit is positioned within the rear channel. A storage area for an equipment storage device is located within or adjacent to the channel and is partitioned by a barrier. A loopback channel accepts a flow of the circulating gas and forms a pathway about the equipment storage device. The fan unit generates an area of relatively high pressure circulating gas compared to circulating gas in the storage area, which causes a portion of the circulating gas to travel through the loopback channel to cool equipment stored at the equipment storage device.

A heat dissipation structure of a heat generating component includes a heat conductive plate that includes a heat receiving connecting part thermally connected to the heat generating component and a heat dissipation connecting part thermally connected to the chassis and an air cooling fan that generates cooling air for cooling the heat conductive plate. The heat conductive plate further includes a first heat dissipation area from which heat is dissipated by flowing the cooling air along a surface of the plate and a second heat dissipation area that is bent and extends from the first heat dissipation area so as to cross an advancing direction of the cooling air that flows along the surface of the plate at the first heat dissipation area, and from which heat is dissipated by receiving the cooling air that has flown along the surface of the plate at the first heat dissipation area.

The present invention relates to a display device with a heat exchange module and a heat exchange method thereof. The display device comprises a casing, a display unit and a heat exchange module, wherein a sealed space is formed inside the casing; the display unit is arranged in the sealed space; and the heat exchange module is arranged on the casing. The heat exchange module is provided with first heat exchange holes positioned inside the sealed space and second heat exchange holes positioned outside the sealed space; a first circulation airflow is formed between the first heat exchange holes and the sealed space; and the second heat exchange holes communicate with outside to form a second circulation airflow for performing heat exchange with the first circulation airflow. The present invention realizes heat exchange on the first circulation airflow by the second circulation airflow by using the second heat exchange holes and the first heat exchange holes formed in the heat exchange module of an integral structure. Compared with an existing heat dissipation fin, the present invention can improve the heat exchange efficiency to achieve a fast temperature lowering effect, so that a good heat dissipation effect is achieved on the display unit.

A head-mounted display device includes a casing, a control circuit board and a fan. The casing has a heat dissipation hole, and a face side and an external side opposite each other. The control circuit board is disposed in the casing. The fan is disposed in the casing and located between the control circuit board and the face side of the casing, and is configured to generate an air flow flowing from the face side toward the heat dissipation hole.

An electronic device is provided, which is for coupling to another electronic device in a side-by-side manner, and the electronic device includes a substrate, a first thermal dissipation sheet and a thermal dissipation element. The substrate includes a first surface and a second surface. The first thermal dissipation sheet is disposed on the first surface. The thermal dissipation element is disposed on the substrate. The first thermal dissipation sheet is disposed between the thermal dissipation element and the substrate, and the thermal dissipation element at least partially overlaps the first thermal dissipation sheet.

Provided is a display device. The display device includes a housing including a front glass and a rear cover, a display panel arranged within the housing, and an air circulator arranged behind the display panel for circulating air between the front glass and the front surface of the display panel, wherein the air circulator includes a circulation fan circulating air, a case receiving the circulation fan and having open top to discharge air in a direction of long edges of the display panel, a first connection part formed to be open at one end of the case in the direction of long edges, and a second connection part formed to be open at the other end of the case in the direction of long edges.

An outdoor display apparatus having a heat dissipation structure includes a first display module configured to display an image in a first direction, a second display module configured to display an image in a second direction opposite to the first direction, a housing configured to accommodate the first display module and the second display module, and having an inlet and an outlet, and a heat exchange device configured to receive heat from one of the first display module and the second display module and perform heat exchange, wherein the heat exchange device includes: a first heat exchange portion having at least one cooling passage to cool the first display module; a second heat exchange portion having at least one cooling passage to cool the second display module; and a heat exchanger configured to be selectively shared by the first heat exchange portion and the second heat exchange portion.

An electronic device includes an illumination optical system for outputting light to the projection lens, a blower for cooling a liquid crystal panel mounted on the illumination optical system, a first duct for guiding the air blown out from the blower to the liquid crystal panel, a second duct for guiding the air passing through the liquid crystal panel in the direction opposite to the direction of the air blown out from the blower and a heat sink for removing heat from the air passing through the second duct, and a holding member for holding the blower and guiding the air from which heat has been removed by the heat sink to the air inlet of the blower is provided in a dust-proof case