An inductor and a power module are respectively provided. The inductor includes an insulating body and a conductive body. The insulating body has a top surface and a bottom surface. The conductive body includes two pin parts and a heat dissipation part. A portion of each of the pin parts is exposed outside the bottom surface. The portions of the two pin parts exposed outside the insulating body are configured to fix to a circuit board. The heat dissipation part is connected to the two pin parts, the heat dissipation part is exposed outside the top surface, and the heat dissipation part is configured to connect to an external heat dissipation member. When the inductor is fixed to the circuit board through the two pin parts exposed outside the bottom surface, the two pin parts and the bottom surface jointly define an accommodating space for accommodating a chip.

An illumination assembly includes a polymeric substrate, an electrical circuit including two conductors supported by the polymeric substrate, an LED electrically coupled to the two conductors, and a heat spreader thermally coupled to the LED. The two conductors can be printed on the polymeric substrate, embedded within the polymeric substrate, or lie atop the polymeric substrate. The illumination assembly may be fabricated in three-dimensional form factors.

A circuit board includes a substrate, a first inner circuit layer, a second inner circuit layer, a first insulating layer, a first optical fiber extending along a first direction, an optical component, an electrical component, a transparent insulating layer, a first inclined surface, a first reflective layer, a second inclined surface, a second reflective layer, and a second optical fiber extending along a second direction.

A power module is disclosed. The power module includes a carrier board, two switches, at least one metal block, a clamping component and a metal conductive component. The carrier board includes an upper surface and a lower surface. The two switches are disposed on the upper surface and connected in series to form a bridge arm electrically connected between a positive terminal and a negative terminal. The metal block is electrically connected to the two switches. The clamping component is disposed on the upper surface and electrically connected in parallel with the bridge arm through the carrier board. The metal conductive component is connected from a common node of the two switches to an output terminal. The metal conductive component is located at a side of the two switches facing away from the upper surface.

A circuit assembly includes: a substrate formed with a ground pattern and a through-hole; a metal member that is inserted into the through-hole and electrically connected to the ground pattern; a heat dissipation member made of metal, that is overlaid on the substrate and can be connected to an external ground potential; and conductive paste that connects the metal member and the heat dissipation member.

A carrier board and a power module using the same are disclosed. The carrier board includes a main body, two metal-wiring layers and at least one metal block. The main body includes at least two terminals and a surface. The two terminals are disposed on the surface. The two metal-wiring layers are disposed on the main body to form two parts of metal traces connected to the two terminals, respectively. The at least one metal block is embedded in the main body and connected to one of the two terminals. A thickness of the two parts of metal traces is less than that of the metal block. The two terminals connected by the two parts of metal traces have a loop inductance less than or equal to 1.4 nH calculated at a frequency greater than 1 MHz.

A module board of an embodiment includes a printed board having a through-hole, a semiconductor device mounted on the printed board so as to cover the through-hole, and a heat conductive polygonal column included in the through-hole. The semiconductor device includes a ground terminal or a power supply terminal, the polygonal column is supported by the through-hole at the corners of the polygonal column, and the polygonal column is connected to the ground terminal or the power supply terminal.

An electronic device includes a first component carrier with a first stack having at least one first electrically conductive layer structure forming an antenna structure and at least one first electrically insulating layer structure; at least one electronic component, and a second component carrier having at least one second electrically conductive layer structure and/or at least one second electrically insulating layer structure. The second component carrier further includes a heat removal structure. The first component carrier and the second component carrier are connected so that the antenna structure is positioned at one side of the electronic device for emitting and/or receiving electromagnetic radiation and the heat removal structure is positioned at an opposing other side of the electronic device.

Embedded cooling systems and methods of forming the same are disclosed. A system includes a PCB stack comprising a first major substrate opposite a second major substrate, a pre-preg layer disposed between the first and second major substrates, a power device stack embedded within the PCB stack and comprising a substrate, a power device coupled to the substrate of each power device stack, and a flat heat pipe having a first end embedded in the PCB stack and a second end extending outside the PCB stack, the power device stack being coupled to the flat heat pipe.

A circuit board, a preparation method thereof, and an electronic device are provided. The circuit board includes: a substrate, defining a first through-hole; a metal block, embedded in the first through-hole and fixedly connected to the substrate; a conductive line layer, arranged on at least one side surface of the substrate; wherein the conductive line layer partially covers an opening of the first through-hole on a corresponding side surface of the substrate; and a conductive channel, penetrating the conductive line layer and the metal block in turn. The conductive channel comprises a second through-hole and a conductive medium plated on a wall of the second through-hole; an end of the conductive medium is connected to the conductive line layer, and another end of the conductive medium is connected to the metal block.