A heat sink component can include a body including a thermally conductive material that is electrically non-conductive. At least one first terminal can be formed over a first end of the body. At least one second terminal formed over a second end of the body. The second end of the body can be opposite the first end of the body in an X-direction. The heat sink component can have a length in the X-direction and a width in a Y-direction that is parallel with the top surface and perpendicular to the X-direction. A ratio of the width to the length can be greater than about 1.

A heat sink component can include a body including a thermally conductive material that is electrically non-conductive. The body can have a top surface, a bottom surface opposite the top surface, and a plurality of side surfaces. The heat sink component also can include a heat source terminal formed over the bottom surface of the body. The heat source terminal can be spaced apart from the plurality of side surfaces. The heat sink component further can include a heat sink terminal formed over the bottom surface of the body. The heat sink terminal can be spaced apart from the plurality of side surfaces.

A surface mount component can include a first substrate and a second substrate arranged adjacent the first substrate to form a monolithic body. At least one of the first substrate or the second substrate can include a thermally conductive material that is electrically insulating. A thin film component can be arranged between the first substrate and the second substrate. A first terminal can be formed over a first end of the monolithic body. A second terminal can be formed over a second end of the monolithic body that is opposite the first end. A heat sink terminal can contact the thermally conductive material of the at least one of the first substrate or the second substrate.

An electronic device includes a heat dissipation part, a plurality of electronic components, and a fixed potential part. The electronic component is fastened to the heat dissipation part, and an insulation pad is disposed between the electronic component and the heat dissipation part. The fixed potential part has a fixed potential, and the heat dissipation part is electrically connected to the fixed potential part. The heat dissipation part has the fixed potential, a potential difference between the electronic component and the heat dissipation part is reduced, and a requirement of a safety specification between the electronic component and the heat dissipation part is reduced. The electronic component can be relatively close to the heat dissipation part, and a surrounding energized component of the heat dissipation part can also be closer to the heat dissipation part.

A cooling plate for cooling high power density electronics has an internal cavity and an opening for fluid exchange with the cavity. A mounting structure is positioned within the opening. A coaxial port is attached to the mounting structure, the coaxial port having a center conduit and a ring conduit surrounding the central conduit such that rotational axis of the center conduit coincides with rotational axis of the ring conduit. A single coaxial port can serve to deliver cooling liquid to the cooling plate and return warmed fluid from the cooling plate. The coaxial port center conduit connected with a fluid distribution panel. Fluid distribution is regulated by the panel before it exits the port through the ring conduit.

A mechanical device for cooling an electronic component may include a surface including an aperture, and a first support protruding from the surface and a second support protruding from the surface. In some embodiments, the device may include disposed within the aperture a thermal interface material (TIM).

The electrical equipment battery includes: a circuit board mounted with a heat generating element; and an outer case having a heat radiation plate made of metal. A heat transfer space is defined between the circuit board and the heat radiation plate, and then an electrical-insulating and heat-conducting gel is filled in the heat transfer space. Heat energy of the heat generating element is radiated to the outside via the heat radiation plate of the outer case. The heat radiation plate is provided with a flow-out block partition on the outer side of the heat transfer space. The flow-out block partition suppresses the electrical-insulating and heat-conducting gel from flowing out from the heat transfer space.

An assembly comprising a substrate, a first integrated device coupled to the substrate, a second integrated device coupled to the substrate, a frame coupled to the substrate such that the frame at least partially surrounds the first integrated device and the second integrated device, and a step heat sink coupled to the frame, such that the step heat sink is located over the first integrated device and the second integrated device. The assembly may further include a shield coupled to the frame such that the shield is located between the frame and the step heat sink. The shield may include a step shield. The assembly may further include a heat pipe coupled to the step heat sink.

A method of manufacturing an augmented LED array assembly is described which comprises providing an LED array assembly configured for inclusion in an LED lighting circuit, the LED array assembly comprising a micro-LED array mounted onto a driver integrated circuit, the driver integrated circuit comprising contact pads configured for electrical connections to a circuit board assembly; providing an essentially planar carrier comprising a plurality of contact bridges, each contact bridge extending between a first contact pad and a second contact pad; and mounting the contact bridge carrier to the LED array assembly by forming solder bonds between the first contact pads of the contact bridge carrier and the contact pads of the driver integrated circuit.

There is provided a conductive adhesive with which the connection stability between objects that are conductive members is excellent, the connection stability is maintained even when the conductive adhesive is subjected to high temperature, and rising towards the back side of an object is less likely to occur. A conductive adhesive 1 includes a binder component 12, and metal particles (A) 11 having a 20% compressive strength of 25 MPa or less in a 170° C. environment. The metal particles 11 preferably include a metal having a melting point of 280° C. or less. The content of the metal having a melting point of 280° C. or less in the metal particles (A) 11 is preferably 80% by mass or more.