A microprocessor heat sink fastener assembly, comprising a base to couple to a heat sink a retention nut to be received by a cavity of the base, and a retention clip to be attached to the base and to be cantilevered therefrom. The retention clip is to engage with a latching structure extending from a latching structure of a retention plate.

A touchpad module includes a bracket, a touch member and a supporting plate. The supporting plate is arranged between the bracket and the touch member. When an end of the touch member is pressed down, the end of the touch member is swung relative to the bracket through the supporting plate. The supporting plate includes a plate body, at least one supporting part and a swingable part. The plate body, the at least one supporting part and the swingable part are integrally formed as a one-piece structure. The present invention further provides a computing device with the touchpad module.

A container type variable-frequency drive skid includes a container body, wherein a containing space is provided in the container body, a wiring unit, a voltage transformation unit and a frequency conversion unit are arranged in the containing space, a first cooling unit and a second cooling unit are further arranged in the containing space, the first cooling unit comprises an air duct and a first heat dissipation fan arranged in the air duct, the voltage transformation unit is located in the air duct, air flows through the air duct under the action of the first heat dissipation fan to cool the voltage transformation unit, the second cooling unit comprises a cold guide assembly and a second heat dissipation fan, and the cold guide assembly abuts against the frequency conversion unit. The first cooling unit cools the voltage transformation unit in an air-cooling manner, and the second cooling unit cools the frequency conversion unit in an air cooling and water-cooling combined manner, such that the situation that the voltage transformation unit and the frequency conversion unit cannot operate normally due to too high a temperature is avoided, and the operation efficiency and reliability of the whole machine are improved.

The invention relates to a car module (10) comprising a tamper detecting electronic control unit (1), wherein the electronic control unit (1) is configured to control at least one electrically controllable function of a vehicle, for instance a light function such as low beam or high beam of a vehicle headlight, said electronic control unit (1) comprising—at least one carrier (2), in particular a printed circuit board, comprising an electric circuit (2a) for performing the controlling by the electronic control unit (1),—a housing (3) enclosing the at least one carrier (2), wherein the housing (3) comprises at least two parts (3a, 3b), wherein a first part (3a) of the housing (3) is holding the carrier (2), and wherein a second part (3b) of the housing (3) is attached to the first part (3a) in order to close the housing (3) and as such enclose the carrier (2) within the housing (3), and—a system (4) for detecting opening of the housing (3).

An inverter device (1), comprising a first printed circuit board (2) on which a transformer (3) is arranged; a second printed circuit board (4) which is arranged parallel to the first printed circuit board (2) at a distance from the sides of the transformer (3); and a cover element (5) which is arranged between the printed circuit boards (2, 4) for the purpose of electromagnetic shielding and has a through opening (6) through which the transformer (3) passes;
wherein the cover element (5) comprises a shielding unit (7) which surrounds the through opening (6) peripherally at least in some places and extends in the direction of the second printed circuit board (4).

Network rack systems for physically supporting modules of a network element and cable management structures for maintaining network cables in an organized manner are provided. An auxiliary side cabinet, according to one implementation, includes a frame configured for physical attachment to a side portion of a main rack structure, where the main rack structure is configured to support a plurality of modules of a Network Element (NE). The auxiliary side cabinet further includes a front plane connected to a front portion of the frame. Also, the auxiliary side cabinet includes one or more connector panels supported on the front plane. Each of the one or more connector panels is configured to support a plurality of connectors. The plurality of connectors are configured for communication with associated connectors of the modules of the NE via cables. Also, the plurality of connectors are configured as high pin count connectors.

An electronic switch module includes a circuit board having conductive pads coupled to a power source and a sense pad coupled to an output signal; and a variable-speed actuator assembly having an actuator positioned adjacent a side edge of the circuit board and moveable along a movement axis, a plunger coupled to the actuator, and a conductive wiper secured to the plunger in contact with the circuit board. The wiper includes a first leg arranged to slidably engage the sense pad and a second leg arranged to slidably engage at least one of the conductive pads. The sense pad is longitudinally aligned with the conductive pads. The first leg of the wiper is located between the actuator and the second leg, and the sense pad is located between the side edge of the circuit board and the conductive pads.

Examples described herein relate to an interface and a network interface device coupled to the interface and comprising circuitry to: control power utilization by a first set of one or more devices based on power available to a system that includes the first set of one or more devices, wherein the system is communicatively coupled to the network interface and control cooling applied to the first set of one or more devices.

A vibration isolator and method of assembly utilize “flex circuits” to provide both vibration/shock isolation and integrated electrically isolated conductive paths to support lightweight devices (<100 grams) such as crystal oscillators, IC chips, MEMs devices and the like. Each flex circuit includes a least one polymer layer and at least one of the flex circuits includes at least one patterned conductive layer. The isolator may be integrally formed from a stack of polymer layers and patterned conductive layers to provide the plurality of flex circuits, platform and connectors. Most typically, flex circuits are Type 4 in which the multiple polymer layers have a loose leaf or bonded configuration. Flex circuits are easy to produce in large quantities at low cost with standardized and repeatable performance characteristics.

DIN rail installation kit including main body, spring hook, latch fastener and elastic element and combined with electronic device. When latch fastener is pulled down first to move to second position, buckle of latch fastener pushes down on hook body of spring hook, and after passing under hook body, hook end of hook body can be temporarily positioned on side wall of latch fastener. When user releases latch fastener, elastic element returns latch fastener, buckle is then buckled on buckle portion of hook body, and second buckle means of latch fastener is kept away from first buckle means of main body to present a removable state. When latch fastener is pulled down secondarily to return to first position, buckle is separated from buckle portion of hook body, and second buckle means and first buckle means are relatively buckled on DIN rail to exhibit a state of tight coupling.