A thermal conductive device and thermal conductive device manufacturing method, an electrical connector, and an electronic device. The thermal conductive device comprises first housing, a second housing, a capillary mesh component, and a coolant. The second housing is disposed on the first housing. An airtight and vacuumed accommodating space is provided between the first housing and the second housing. The capillary mesh component is disposed in the accommodating space. The capillary mesh component comprises a plurality of capillary pores. The plurality of capillary pores and the accommodating space form a plurality of interconnected circulation channels. The coolant is filled in the accommodating space. Inside the thermal conductive device, the conventional copper powder sintered configuration is replaced with capillary mesh component, so that the thermal conductive device could be thinned and could present a better thermal conductivity.

A photovoltaic junction box comprising a diode module and a circuit board disposed in a box body, and a heat sink mounted on the outer surface of the box body. The diode module is attached to the back side of the heat sink and is electrically connected to cooper conductor. The heat sink is made of aluminum material and a heat-absorbing layer is provided inside the heat sink. The heat-absorbing layer is close to the diode module. The aluminum heat sink provides great thermal conductivity, therefore, can greatly increase the cooling capacity of the junction box. In addition, because metal material for higher temperature resistance is used instead of lower temperature resistance plastic material, the box body would not deform as easy, greatly increase the safety and reliability of the junction box.

Passive radiative cooling structures and apparatus manufactured with such cooling structures conserve energy needs. A flexible film transparent to visible light incorporates particles at a volume percentage larger than 25% so as to absorb and emit infrared radiation at wavelengths where Earth's atmosphere is transparent. Another film transparent to visible light is thin and flexible and configured to absorb and emit infrared radiation at wavelengths where Earth's atmosphere is transparent, wherein etchings or depositions are present on one or both surfaces. A high efficiency cooling structure has an emissive layer sandwiched between a waveguide layer and a thermal conductive layer. A solar cell panel is covered by a transparent passive radiative cooling film. A container housing an active cooling unit incorporates passive radiative cooling structures on one or more exterior surfaces.

Passive radiative cooling structures and apparatus manufactured with such cooling structures conserve energy needs. A flexible film transparent to visible light incorporates particles at a volume percentage larger than 25% so as to absorb and emit infrared radiation at wavelengths where Earth's atmosphere is transparent. Another film transparent to visible light is thin and flexible and configured to absorb and emit infrared radiation at wavelengths where Earth's atmosphere is transparent, wherein etchings or depositions are present on one or both surfaces. A high efficiency cooling structure has an emissive layer sandwiched between a waveguide layer and a thermal conductive layer. A solar cell panel is covered by a transparent passive radiative cooling film. A container housing an active cooling unit incorporates passive radiative cooling structures on one or more exterior surfaces.

Thermal management systems are described herein. A thermal management system includes components of a computing device. The computing device includes a housing. The housing includes an inner surface. A portion of the inner surface of the housing has a first emissivity. The computing device also includes a thermal management device positioned within the housing, at a distance from the portion of the inner surface of the housing. The thermal management device includes an outer surface. The outer surface of the thermal management device includes a first portion and a second portion. The first portion of the outer surface of the thermal management device has a second emissivity, and the second portion of the outer surface of the thermal management device has a third emissivity. The second emissivity is greater than the third emissivity, and the first emissivity is substantially the same as the second emissivity.

A curable thermal interface material and a cooling device, and a cooling device manufacturing method thereof are provided. The curable thermal interface material includes thermal conductive material and polymeric material, which is formed from the mixture of thermal conductive material and polymeric material. The curable thermal interface material is disposed on the heat sink, so as to properly conduct heat from the heat source to the heat sink to achieve heat dissipation.

This document describes a reinforced graphite heat-spreader for a surface of a housing component of an electronic device. The reinforced graphite heat-spreader includes a heat-spreader material stack having a layer of graphite material to spread heat. The reinforced graphite heat-spreader also includes an interface material stack that joins the heat-spreader material stack to the housing surface of an electronic device. The interface material stack, which may be formed using embossing techniques, includes protuberances that may be formed from an adhesive material.

This document describes a reinforced graphite heat-spreader for a surface of a housing component of an electronic device. The reinforced graphite heat-spreader includes a heat-spreader material stack having a layer of graphite material to spread heat. The reinforced graphite heat-spreader also includes an interface material stack that joins the heat-spreader material stack to the housing surface of an electronic device. The interface material stack, which may be formed using embossing techniques, includes protuberances that may be formed from an adhesive material.

A device which includes a heat generator, a resinous housing covering the heat generator, and a heat radiation material disposed on at least some of the surfaces of the heat generator, wherein the heat radiation material includes metal particles and a resin and has a region where the metal particles arranged along the surface direction are present at a relatively high density.

This document describes a reinforced graphite heat-spreader for a surface of a housing component of an electronic device. The reinforced graphite heat-spreader includes a heat-spreader material stack having a layer of graphite material to spread heat. The reinforced graphite heat-spreader also includes an interface material stack that joins the heat-spreader material stack to the housing surface of an electronic device. The interface material stack, which may be formed using embossing techniques, includes protuberances that may be formed from an adhesive material.