A thermal conduction sheet holder include, in the following order, an elongated carrier film, a plurality of thermal conduction sheets, and an elongated cover film covering the plurality of thermal conduction sheets, the shortest distance between adjacent thermal conduction sheets is 2 mm or more, the plurality of thermal conduction sheets are disposed at intervals in a longitudinal direction of the carrier film and the cover film, and the plurality of thermal conduction sheets are peelable from the cover film and the carrier film.

A display module includes: a substrate having a mounting surface, four side surfaces, and a rear surface opposite to the mounting surface, the substrate including a thin film transistor layer (TFT) provided on the mounting surface; a plurality of inorganic light-emitting diodes provided on the mounting surface of the substrate; a side wiring electrically connected to the TFT layer and extending along a first pair of side surfaces among the four side surfaces of the substrate; a front cover covering the TFT layer and the plurality of inorganic light emitting devices in a first direction; a metal plate provided on the rear surface of the substrate; a side cover covering the side wiring and the four side surfaces; and a side member provided on a side of the side cover and grounded to the metal plate, wherein the side member is provided on a first side surface of the first pair of side surfaces along which the side wiring extends among the four side surfaces.

A system comprises: an inverter configured to convert DC power from a battery to AC power to drive a motor, wherein the inverter includes: a power switch including a drain terminal, a source terminal, and a gate terminal; and a controller configured to detect a change in current at the source terminal of the power switch using a complex impedance of a metal trace connected to the source terminal of the power switch, and control a gate control signal to the gate terminal based on the detected change in current.

A semiconductor packaging device includes a packaging module, a heat dissipation cover and a thermal interface material layer. The package module includes a substrate, and a working chip mounted on the substrate. The heat dissipation cover includes a metal cover fixed on the substrate and covering the working chip, an accommodating recess located on the metal cover to accommodate the working chip, and a plurality of protrusive columns respectively formed on the metal cover and distributed within the accommodating recess at intervals. The depth of the accommodating recess is greater than the height of each protrusive column, and the accommodating recess is greater than the working chip. The thermal interface material layer is non-solid, and located within the accommodating recess between the protrusive columns to wrap the protrusive columns and contact with the working chip, the metal cover and the protrusive columns.

A method of manufacturing a semiconductor device is provided. The method includes forming a package leadframe including a die pad, a first ridge formed at a first outer edge of the die pad, a second ridge formed at a second outer edge of the die pad opposite of the first outer edge and separate from the first ridge, and a plurality of leads surrounding the die pad. A semiconductor die is attached to the die pad by way of a die attach material. The semiconductor die is located on the die pad between the first ridge and the second ridge. An encapsulant encapsulates the semiconductor die and at least a portion of the package leadframe.

A module arrangement for power semiconductor devices, includes two or more heat spreading layers with a first surface and a second surface being arranged opposite to the first surface. At least two or more power semiconductor devices are arranged on the first surface of the heat spreading layer and electrically connected thereto. An electrical isolation stack comprising an electrically insulating layer and electrically conductive layers is arranged in contact with the second surface of each heat spreading layer. The at least two or more power semiconductor devices, the heat spreading layers and a substantial part of each of the electrical isolation stacks are sealed from their surrounding environment by a molded enclosure. Accordingly, similar or better thermal characteristic of the module can be achieved instead of utilizing high cost electrically insulating layers, and double side cooling configurations can be easily implemented, without the use of a thick baseplate.

A semiconductor device includes: a baseplate; an insulating substrate on the baseplate; a semiconductor element on the insulating substrate; a case bonded to the baseplate by an adhesive, the case surrounding a space in which the semiconductor element is positioned; and an encapsulating material filling the space surrounded by the case, in which, the case includes a claw, the claw includes: a protrusion protruding from an inner wall surface of the case; and a hook inclined from the protrusion, a space being sandwiched between the hook and the inner wall surface of the case.

A packaged integrated circuit device includes a semiconductor die. The packaged integrated circuit device also includes a sealed two-phase cooling structure thermally coupled to the semiconductor die. The packaged integrated circuit device further includes a mold compound encapsulating the semiconductor die and the sealed two-phase cooling structure.

Various aspects of the present disclosure generally relate to an integrated circuit device, such as a packaged integrated circuit device. In some aspects, an integrated circuit device includes a semiconductor die and a lid thermally coupled to the semiconductor die. The lid includes a two-phase thermal management device. The integrated circuit device also includes an interface layer in contact with the semiconductor die and the lid.

A semiconductor package includes a redistribution substrate, a chip stack structure disposed on the redistribution substrate and including a plurality of semiconductor chips disposed in a stack, a vertical wiring portion connecting the chip stack structure to the redistribution substrate and including a plurality of vertical wires that extend in a direction perpendicular to an upper surface of the redistribution substrate, a sealing member configured to seal at least a portion the chip stack structure and the vertical wiring portion, and a heat dissipation metal member disposed on side surfaces and an upper surface of the sealing member.