Systems and methods for providing solar-generated power to a display unit mounted to a vehicle are provided. One or more mounting supports connect a housing for an electronic display to the vehicle. A solar energy harvesting device is secured to an upper portion of the vehicle and is electrically connected to the electronic display.

A heat dissipating mechanism is for heat dissipation of a display module and a heat generating module of a display apparatus and includes a frame structure, a first airflow generating device, and a conductive cover structure having first, second, and third covers. The first cover is connected to the frame structure for containing the display module. The second cover has an air inlet and an air outlet and is connected to the first cover to form a channel. The third cover is connected to the second cover for containing the heat generating module. The first airflow generating device is disposed in the air inlet to guide air into the channel and out of the air outlet, so as to form an airflow for heat dissipation of the display module and the heat generating module.

An image capturing apparatus, including an image capturing element and having an optical axis, includes a control circuit to control the image capturing apparatus, a display panel arranged on a rear surface side of an exterior member, and a heat dissipation fan arranged on a bottom surface side of the exterior member. An image capturing element board, a control circuit board, and the display panel are arranged in a direction of the optical axis. A duct, extending from a first ventilation hole to a second ventilation hole formed to face the first ventilation hole across the optical axis, passes through an area among the image capturing element board, the control circuit board, and the bottom surface side of the exterior member. The heat dissipation fan is arranged inside the duct arranged in the area, the control circuit board, and the bottom surface side of the exterior member.

Embodiments of this application disclose a housing structure and a terminal device. The housing structure includes a bottom shell and a lifting shell. A first end of the bottom shell is connected to a first end of the lifting shell, a second end of the bottom shell and a second end of the lifting shell are spaced by a first distance, and space between the bottom shell and the lifting shell forms a heat dissipation channel. A heat dissipation panel is disposed on the bottom shell, a first surface of the heat dissipation panel is in contact with a heat emitting component, and a second surface of the heat dissipation panel is located in the heat dissipation channel. Therefore, the housing structure provided in the embodiments of this application can better dissipate heat for the heat emitting component in the bottom shell.

A display device includes a display panel; a chassis disposed at a rear side of the display panel; a control circuit board disposed on the chassis; a shield case disposed on the control circuit board; and a fan disposed on the chassis and adjacent to the shield case. The shield case includes a main portion spaced apart from the control circuit board in a third direction, and side portions extending toward the chassis from opposite sides of the main portion. Dimples are formed in an inner surface of the main portion facing toward the control circuit board.

This application relates to display devices and the layout/architecture of various internal components to enhance thermal energy management. A display device described herein may include one or more fan assemblies that drive ambient air into the display device to cool heat-generating components of the display device, and also to drive the ambient air, once heated through convectively cooling the heat-generating components, out of the display device. Further, the location of the heat-generating components is such that the heat-generating components upstream relative to the one or more fan assemblies. In this manner, the ambient air can pass over or through the heat-generating components prior to reaching the one or more fan assemblies. Additionally, heat-generating components, such as a backlit device and a power supply unit, are positioned relatively close to vent inlets in the display device. As a result, these heat-generating devices are immediately cooled with the ambient air.

A display assembly with divided interior space includes a first and second electronic display subassembly attached to a structural framework, where each of the subassemblies include an electronic display layer located behind a cover, an illumination device for providing illumination to the electronic display layer when powered, and a passageway for circulating gas. A common passageway for the circulating gas is located between the subassemblies and is in fluid communication with the passageways. A central septum extends within the common passageway between the subassemblies to divide the common passageway into a first portion and a second portion.

An electronic apparatus includes a housing with a power supply unit that receives external electrical power and supplies it to the apparatus using a power controller. The housing includes a heater; temperature and humidity sensors; and an electronic processor that receives power from the power supply unit and controls functions of the electronic apparatus. Upon startup, the power controller receives data from the temperature and humidity sensors; processes the received temperature and humidity data to indicate a current dew point within the housing; and compares the current dew point with a current location temperature at a location within the housing. If the current location temperature is at or below the current dew point, the heater is activated to raise the temperature within the housing. If the current location temperature is above the current dew point, electrical power supplied from the power supply unit to the electronic processor.

A projection type image display apparatus including a light source apparatus includes a light emitting element emitting blue light; a phosphor receiving the blue light to emit predetermined light; a heat sink provided with a bottom portion and a plurality of heat radiation fins extending from the bottom portion; and a cooling fan arranged to cool the plurality of heat radiation fins of the heat sink. The light emitting element is attached to the bottom portion of the heat sink. The phosphor is attached to the bottom portion of the heat sink at a predetermined interval from the light emitting element. Heat pipes conducting heat by repeating evaporation and liquefaction of working liquid are embedded in the bottom portion. The heat pipes are respectively provided with sections opposing the light emitting element in a thickness direction of the bottom portion.

A display assembly with loopback cooling includes a housing for an electronic display where a first airflow pathway extends within the housing. An equipment storage device for electronic equipment located at a storage area within the housing. A second airflow pathway fluidly connects the storage area with the first airflow pathway. One or more fans, when activated, cause a flow of air to travel through a portion of the first airflow pathway extending rearward of the electronic display in a first direction and a portion of the flow to leave the portion of the first airflow pathway and travel through the second airflow pathway, at least initially, in a second direction.