The power controller apparatus includes a plurality of parts including a heat member and a heat dissipation member. The power controller apparatus includes a housing for accommodating these plurality of parts. The power controller apparatus includes a snap fit and a thermal conductive member. The snap fit connects the heat member and the heat dissipation member. The thermal conductive member is arranged between the heat member and the heat dissipation member. The thermal conductive member includes a filler having anisotropy with respect to thermal conductivity. The filler is oriented so as to exhibit high thermal conductivity in a stacking direction between the heat member and the heat dissipation member.

A method is disclosed of mounting a heat sink through a printed circuit board to reach a component on the opposite side of a board. The heat sink is passed through a window in the board to contact a component at a predetermined pressure optimized for thermal performance at minimum stress. The heat sink is affixed in place on the printed circuit board using through-hole pins which can be soldered to maintain the heat sink's position and the predetermined pressure.

An electronic apparatus includes: a chassis; a heat generating element provided in the chassis; and a cooling device that has a cooling fin, a heat pipe connecting the cooling fin and the heat generating element, and a pressing assembly pressing the heat pipe against the heat generating element, and is provided in the chassis. The heat pipe has: a heat absorbing section that absorbs heat generated by the heat generating element; and a thin plate section having a thickness which is smaller than that of the heat absorbing section. The pressing assembly has: a base assembly relatively fixed to the chassis; and a bridge section that is provided integrally with the base assembly and placed on a surface of the thin plate section in such a manner as to extend over the heat pipe in a width direction.

The disclosure relates to an arrangement with a power module including power semiconductor components. The arrangement further includes a component having a curved surface. The power module is arranged on the curved surface of the component and is non-positively detachably connected to the component. The disclosure also relates to a power converter with the arrangement and to a vehicle with a power converter.

A mounting structure for a heater element includes a heater element having a surface to be cooled, a board on which the heater element is mounted, a cooling member that cools the surface to be cooled of the heater element mounted on the board, and a supporting member temporarily fixed to the board, the supporting member temporarily fixing the heater element.

The present utility model relates to the technical field of heat dissipation devices, and in particular to an adjustable heat exchanger. The adjustable heat exchanger includes a fan assembly, a heatsink assembly, a semiconductor chilling plate and a conduction cooling unit connected in sequence, the conduction cooling unit includes a main conduction cooling plate and a conduction cooling fin, and the conduction cooling fin includes at least one conduction cooling sub-fin. The main conduction cooling plate is connected to the semiconductor chilling plate, the conduction cooling fin is movably connected to an outer peripheral wall of the main conduction cooling plate, the conduction cooling fin extends outward along the center of the main conduction cooling plate, and the conduction cooling fin and the main conduction cooling plate jointly form a contact surface for adapting to a heat-dispersing surface. The heat exchanger of the present utility model can adapt to hot surfaces with different curved surface radians, and form a surrounded fixed structure with the hot surface, thereby making the conduction cooling unit well contact surfaces with different radians.

A desktop computing system having at least a central core surrounded by housing having a shape that defines a volume in which the central core resides is described. The housing includes a first opening and a second opening axially displaced from the first opening. The first opening having a size and shape in accordance with an amount of airflow used as a heat transfer medium for cooling internal components, the second opening defined by a lip that engages a portion of the airflow in such a way that at least some of the heat transferred to the air flow from the internal components is passed to the housing.

A chip module includes a circuit board (2), a slot (21) disposed on a surface of one side of the circuit board (2), a lidless packaged chip (5), a heat radiator (4), and a substrate fixing assembly (6). The lidless packaged chip (5) includes a substrate (51) and a die (52) packaged on the substrate (51). The slot (21) is electrically connected to the circuit board (2), the lidless packaged chip (5) has a connecting part on one side of the substrate (51) facing away from the die (52), and the connecting part is inserted into the slot (21). The heat radiator (4) is press-fitted on one side of the die (52) facing away from the circuit board (2). The substrate fixing assembly (6) is press-fitted at a periphery of one side of the substrate (51) facing away from the circuit board (2) and avoids the die (52).

A transistor heat dissipation module is adapted for at least one transistor. The transistor heat dissipation module includes a heat dissipation member and an elastic member. The heat dissipation member includes a first wall and a second wall opposite to each other and a first connecting member connected to the first wall and the second wall. An accommodating space is formed between the first wall and the second wall. The transistor is disposed in the accommodating space. The elastic member is disposed in the accommodating space and is located between the at least one transistor and the first wall to press the at least one transistor against the second wall. An assembly method of a transistor heat dissipation module is further provided.

A semiconductor package includes a lead frame that includes a die pad and a plurality of leads, a semiconductor die mounted on a die attach surface of the die pad, an encapsulant body of electrically insulating material that covers semiconductor die and portions of the lead frame, and a fastener receptacle that includes a blind hole in the encapsulant body or the die pad, wherein a rear surface of the die pad is exposed from a first main face of the encapsulant body.