A headset includes a thermal frame disposed within a housing. A printed circuit board (PCB) is thermally coupled to the thermal frame. Heat generated by one or more electrical components on the PCB is transmitted to the thermal frame, which distributes the heat uniformly throughout the headset. A first heat pipe is disposed on a first side of the PCB in contact with at least a portion of the thermal frame, the PCB, and/or an electrical component disposed on the PCB to draw heat from the electrical component, and a second heat pipe is disposed proximate a second side of the PCB and is configured to draw heat from second side of the PCB.

A headset includes a thermal frame disposed within a housing. A printed circuit board is thermally coupled to the thermal frame. Heat generated by one or more electrical components on the PCB is transmitted to the thermal frame, which distributes the heat uniformly throughout the headset. The thermal frame provides a substantially rigid structural support to which components are coupled and is configured to transfer thermal energy away from the one or more electrical components of the headset and toward an environment located outside of the housing.

A heat dissipation module includes: a heat dissipation base material layer, provided with a first accommodating slot for accommodating a fingerprint sensor and a second accommodating slot for accommodating a flexible printed circuit, the fingerprint sensor being electrically connected to the flexible printed circuit, the first accommodating slot penetrating through the heat dissipation base material layer; and a light shielding buffer layer, on a side of the heat dissipation base material layer away from an opening of the second accommodating slot and provided with a hollowed-out area, an orthographic projection of the hollowed-out area on the heat dissipation base material layer being in the first accommodating slot, the hollowed-out area being configured to expose a photosensitive area of the fingerprint sensor, and the impedance of a surface of a side of the light shielding buffer layer away from the heat dissipation base material layer being 10.sup.6Ω-10.sup.10Ω.

A wearable display device includes a display element, a circuit board, an outer case including a first case member and a second case member, the first case member being configured to dissipate heat generated by the circuit board to outside, the second case member being disposed farther to a wearer side than the first case member is and configured to dissipate heat generated by the display element to the outside, and a heat insulating structure disposed in a region where the first case member and the second case member face each other.

Electronic equipment allowed to endure repetitive severe environmental change in a sterilizing treatment using an autoclave is provided. A tablet terminal (electronic equipment) 106 includes: an enclosure 10; a substrate 30 arranged in an internal space of the enclosure 10; an electronic circuit component 40 mounted on the substrate 30; a (first) heat insulating layer 50 formed along the enclosure 10; and a (first) heat release mechanism 70 allowed to discharge heat from an internal space of the heat insulating layer 50 to outside of the enclosure 10.

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.

A display device is disclosed. The display device includes a display panel; a material complexed plate located at a rear of the display panel; a side frame which is located between the display panel and the material complexed plate, is fixed to the material complexed plate, and to which the display panel is coupled, wherein the material complexed plate includes a front skin forming a front surface; a rear skin which forms a rear surface and faces the front skin; and a core which is located between the front skin and the rear skin, and includes fibers.

A projector, such as for eyewear, having a first and second shield that individually sink heat from a light source and provide electromagnetic (EM) shielding for the projector, and a processor controlling the projector. The shields sink heat evenly and efficiently, to different portions of the eyewear. In one example, the heat is directed in different directions. The shields encompass the light source and the processor, and they may be parallel to one another. The thickness of the shield coupled to the light source is thicker proximate the light source. The shields may be separated from each other by a thermal insulating material.

A display device includes a display panel, a data driver which transmits a data voltage to the display panel, a first flexible printed circuit board attached to the display panel and including an input side wiring electrically connected to the data driver, a first printed circuit board (PCB) electrically connected to the input side wiring to transmit a high-speed driving signal to the data driver, and a metal tape overlapping the input side wiring in a plan view and attached on the first flexible printed circuit board, where a part of the metal tape overlapping the input side wiring in the plan view defines an opening.

A display apparatus, comprising a first display panel, a first flexible circuit board, and a rigid membrane, wherein the first flexible circuit board is arranged on the back side of the first display panel; the first flexible circuit board comprises a first portion, a second portion, and a bending portion for connecting the first portion and the second portion; the first portion is electrically connected to the first display panel, and the second portion is located on the side of the first portion away from the first display panel; and the rigid membrane is located between the back side of the first display panel (101) and the bending portion, the rigid membrane supports the bending portion, the rigidity of the rigid membrane is greater than the rigidity of the first display panel (101), and the rigid membrane is used for dispersing a resilience force generated by the bending portion.