A heat sink structure and a manufacturing method thereof. The heat sink includes a main body having multiple main body connection sections and multiple radiating fins each having a connection section. The main body has a first end and a second end. The first and second ends define a longitudinal direction. The multiple radiating fins are placed in a mold. A mechanical processing measure is used to high-speed impact the main body so as to thrust the main body into the mold. Accordingly, the connection sections of the radiating fins placed in the mold are high-speed thrust into the main body connection sections and moved in the longitudinal direction to the second end of the main body to tightly integrally connect with the main body.

An anchor (910) for mounting to a hollow wall (W) made of friable material comprises a proximal flanged end (918) adapted to be engaged by a rotatable tool (B) to rotate the anchor (910) about a longitudinal axis (A) thereof and to cause is to gradually engage the wall (W). The anchor (910) also includes a distal end (912) adapted to cut through the wall (W) as the anchor (910) is rotated, and a shank (920) extending between the proximal and distal ends (918, 912). The shank (920) includes at least one expandable leg (924) that is in a collapsed position thereof when the anchor (910) is rotated to mount it to the wall (W) and that is located distally beyond a non visible surface of the wall (W) once the anchor (910) has been mounted to the wall and is in a first position thereof. The wall anchor (910) includes an outer thread (922) that securely engages the wall (W). A threaded fastener (B), e.g. a screw, is adapted to be introduced in the anchor (910) and to threadably engage the same distally of the leg (924) such that sufficient rotation of the threaded fastener (B) retracts the distal end (912) towards the proximal end (918) thereby causing the leg (924) to displace to a laterally expanded position thereof and to engage the non visible surface of the wall (W).

The invention relates to a dispense interface for an ejection device comprising a first part and a second part, at least a first opening, a second opening and a third opening, a fluidic channel and a connection element for each of the openings, wherein the first part is joined to the second part to form at least a part of the fluidic channel connecting the openings with each other and wherein at least one connection element is configured to accept a needle assembly for a fluid tight connection with the corresponding opening and wherein at least one connection element is configured to provide a releasable push fit connection for a fluid tight connection with an ejection device in order to reduce the complexity and provide an easy usage of the dispense interface and at the same time overcome the problems of material compatibility and cross contamination. The invention also relates to a system with a dispense interface according to the invention. The invention further relates to a method for preparing a dispense interface according to the invention.

The invention relates to an actuating unit for a motor vehicle lock, comprising a motor element and a drive for moving the motor element, a Bowden cable connected to the motor element and a connecting element for the Bowden cable. The invention further relates to a method of production. The aim of the invention is to simplify production of an actuating unit having a Bowden cable. According to the invention, the connecting element for the Bowden cable is angular, especially L-shaped, and a leg thereof, in the case of an L shape preferably the long leg thereof, is connected to the remainder of the housing. The angular form or L shape and the connection of one leg of such a shape to the remainder of the housing of the motor element results in a large surface or a large peripheral edge of the connecting part which can be connected to the remainder of the housing. As a result, the connecting element can be firmly secured to the remainder of the housing such that the latter withstands the forces of a motor element even when the movement of the motor element is not limited with the aid of a microswitch but with the aid of the connecting element.

The shank (12) of a disposable rotary cutting tool (10) comprises a pipe section (16) cut from a drawn metal pipe. The tool head (14) is formed from a cut-out (18a, 18b) of a drawn metal sheet or a section of a metal tube by non-cutting machining. The pipe section (16) and the tool head (14) are advantageously attached by force fitting.

A heat sink mounting apparatus including: a heat sink; and a device housing, the housing having a slot in the wall of the housing configured to receive a heat sink, wherein the heat sink and the housing are configured such that the heat sink can be secured within the slot with an interference fit.

A tool for mounting a chisel on a chisel holder, having an actuating member, which has a push-off section, wherein the actuating member can be displaced along a displacement direction. It is possible to simplify changing the chisel if the actuating member can be shifted by an actuating unit. The actuating unit has a draw-in section, which is spaced apart from the push-off section and is arranged transversely with respect to the displacement direction of the actuating member. The actuating member can be power-operated bidirectionally in the displacement direction by the actuating unit.

A control element (16) for an air vent (10) in a vehicle has a bearing portion which serves for the air-vent-side bearing of the control element (16) and includes a receptacle (22), in particular for a slat (12) of an air vent (10), and a spring element (34) which protrudes into the receptacle (22) of the bearing portion, wherein the spring element (34) is integrally molded to the control element (16).

[Purpose] To provide is a method capable of producing a heat-dissipating unit easily and at low cost. [Solution] The method of producing a heat-dissipating unit 12 includes: inserting pins 17 punched out of a second plate member 22 for pins into a plurality of through-holes 16 formed in a first plate member 20 for a substrate. In the first plate member 20, a plurality of substrate forming portions 25 is provided side by side in the longitudinal direction of the first plate member 20. In the second plate member 22, a plurality of pin punch-out portions 26 is provided side by side in the longitudinal direction of the second plate member 22. The method includes: a step A of forming the through-holes 16 in the substrate forming portion 25 of the first plate member 20; a step B of subjecting the pin punch-out portion 26 of the second plate member 22 to a half-punch out process to form half-punched-out pin forming portions 27 protruding from one surface side of the second plate member 22; a step C of forming the pins 17 by punching out the pin forming portions 27 from the second plate member 22 and simultaneously inserting the pins 17 into the through-holes 16 in the first plate member 20; and a step D of forming a substrate by cutting the substrate forming portion 25 with the pins 17 inserted in the through-holes 16 from the first plate member 20.

An assembly apparatus includes backup jigs, a press-fitting and caulking part, and an expansion part. The backup jigs is configured to back up arms of a yoke of the cross shaft universal joint from inside in an axial direction. The press-fitting and caulking part is configured to press-fit cup bearings from outside in the axial direction between bearing holes of the arms and a shaft portion of a cross shaft, and configured to caulk the cup bearings. The expansion part is configured to push a wedge body between the backup jigs and to expand the arms outward via the backup jigs. The press-fitting and caulking part is configured to press-fit the cup bearings and to caulk the cup bearings in a state in which the arms are expanded. The expansion part is configured to release an expansion of the arms after the press-fitting and caulking of the cup bearings.