A solid-state drive device includes a first module including a first region containing a volatile main memory device and a controller device and a second region containing a first nonvolatile memory device, a second module disposed on the first module and having a third region containing a second nonvolatile memory device, the second module being connected to the first module, and a heat dissipating member disposed on the second module as vertically juxtaposed with the first and second modules. The heat dissipating member has a protruding portion protruding toward the first module and in direct thermal contact with the first region, and a plate-shaped portion having a main surface in direct thermal contact with the third region.

A speaker apparatus is provided in order to both receive and dissipate heat and to provide acoustic absorption for sound waves propagating through a speaker cavity. The speaker apparatus includes a speaker and a speaker cavity configured to receive sound waves emitted by the speaker for propagation through the speaker cavity. The speaker apparatus also includes a heat dissipation structure disposed at least partially within the speaker cavity. The heat dissipation structure includes a heat pipe or a heat sink configured to receive heat from a component that generates heat. The heat dissipation structure is configured to provide acoustic absorption for the sound waves propagating through the speaker cavity.

Provided is a display apparatus including a display panel, a covering member, and an intermediate member. The intermediate member includes a base material including an insulating material and a heat transfer particle, and is disposed between the display panel and the covering member The display panel includes: a substrate; an encapsulation member which faces the substrate; and a display device which is arranged between the substrate and the encapsulation member and displays an image, the covering member is arranged to face the display panel, and the intermediate member is disposed in a gap between the covering member and an area of the substrate where the encapsulation member is not disposed.

An electronic circuitry module and a method of potting an electronic circuit are provided. The electronic circuit module includes at least one heat generating electronic component and is potted in a potting material. Additionally, a cooling circuit is potted in the potting material. The cooling circuit includes an inlet and an outlet for flow of cooling liquid therebetween.

The present application relates to a heat transfer structure, power electronics module, cooling element and methods of manufacturing a heat transfer structure and a power electronics component. A heat transfer structure is utilized in a power electronics module. The heat transfer structure includes a metallic body and a carbon based insert.

An electronic assembly for a transmission control module includes a printed circuit board and a heat sink. The circuit board includes a first side, a second side averted from the first side, and at least one heat-generating component arranged on the first side and covered with at least one flowable and curable protective compound. The heat sink has an inner face facing the second side and is, at least in sections, spaced apart from the circuit board by at least one gap. The gap is at least partially filled with the at least one flowable and curable protective compound such that the flowable and curable protective compound is in direct contact with the circuit board and the heat sink. The heat sink adheres to the protective compound in a cohesive manner when the flowable and curable protective compound is in the cured state.

A device can dissipate heat from an electrical component by using a phase change material. A horizontal circuitry layer can have opposing first and second sides. A vertical hole can extend through the horizontal circuitry layer. A vertical channel can include a phase change material positioned in the vertical hole and in thermal contact with the first and second sides of the horizontal circuitry layer. The phase change material can dissipate a first amount of heat from the first side by absorbing the first amount of heat and changing phase from a solid form to a liquid form. The phase change material, when in the liquid form, can dissipate a second amount of heat from the first side by transporting the second amount of heat via convection from the first side of the horizontal circuitry layer to the second side of the horizontal circuitry layer.

Disclosed is a circuit assembly having a novel structure capable of reducing thermal resistance in a heat-dissipating path and increasing heat dissipation while ensuring insulation between a heat-dissipating portion and a heat-dissipation target. A circuit assembly includes: heat-generating components that generate heat as a result of a current flowing therethrough; metal plates connected to connecting portions of the heat-generating components, and each having a heat-dissipating portion configured to come into thermal contact with an external heat-dissipation target; a case accommodating the heat-generating components and the metal plates, and having opening portions that expose the heat-dissipating portions of the metal plates to an outside; and an insulating film sealing the opening portions of the case and fixed to the case.

An imaging apparatus includes an object to be cooled, a heat dissipation member, a first heat conductive sheet including a first heat absorbing part that absorbs heat from the object to be cooled and a first heat dissipating part that dissipates heat to the heat dissipation member, a second heat conductive sheet including a second heat absorbing part that absorbs heat from the object to be cooled and a second heat dissipating part that dissipates heat to the heat dissipation member, and an elastic member that biases the first heat absorbing part and the second heat absorbing part and maintains connection between the first heat absorbing part and the object to be cooled and between the second heat absorbing part and the object to be cooled. The elastic member biases the first heat absorbing part and the second heat absorbing part overlapping each other toward the object to be cooled.

A heating-cooling module is disposed on an electronic component and includes a heat-dissipation element, a first thermal conductive layer, a heater, and a second thermal conductive layer. The heat-dissipation element is arranged over the electronic component. The first thermal conductive layer is arranged between the electronic component and the heat-dissipation element. The heater is arranged over the electronic component, in which the heater and the heat-dissipation element are located above the same side of the electronic component, and the heater and the heat-dissipation element are separated from each other. The second thermal conductive layer is arranged between the electronic component and the heater and is separated from the first thermal conductive layer.