A self-piercing rivet element is provided with a body part having a thread cylinder and with a hollow rivet section to be pressed into an as yet unpierced component. In this arrangement, the rivet section is designed to be at least regionally dilatable by means of a die button and tapers in the direction of the central longitudinal axis and away from the body part. The hollow rivet section has, in the region of the transition to the body part, a diameter, which is larger than the outer diameter of the thread cylinder. Furthermore, the rivet section has a closed peripheral wall and an opening at its free end which corresponds at least substantially in diameter to the core diameter of the thread cylinder. Furthermore a component assembly, a method for the manufacture of the component assembly and the die button are claimed.

Two plates, corresponding to the diameter of a length of riveting material being used, act as gauges and are placed separately on the top and bottom of at least one components to be made into a jewelry item. The length of material, such as a wire or tubing, is passed through holes in all the components, and the holes of the plates. This allows the jewelry maker to cut the length of material flush with the exposed surface of the plate on the top of the stack. This automatically measures the optimal length of material needed to span the combined thickness of all the components to be riveted together, while providing the desired length exposed at the top and bottom of the stacked pieces, to fashion a properly formed and secure flattened rivet head on each end of the length of material.

The present invention relates to a fastening unit for fastening to a workpiece, said fastening unit comprising a rivet element and a reshaping element coupled to the rivet element and movable relative thereto, wherein the rivet element has a rivet section and the reshaping element has a reshaping section and a support section, which is arranged at a region of the reshaping element remote from the reshaping section, for axially supporting the fastening unit at an abutment. The rivet section and the reshaping section are designed such that, on an axial relative movement between the rivet element and the reshaping element that is produced by an introduction movement, the rivet section cooperates with the reshaping section and can be reshaped by it in a radial direction.

A clinch fastener with a single-element, unitary construction that does not require the preassembly of parts. The fastener provides a clamp load after installation and is fully formed by stamping the part from sheet metal. The fastener provides the necessary rigidity for a clinch attachment shank with the resilience of a head that will provide a residual clamp load to the attached panels. The fastener attaches two panels face-to-face by extending through aligned apertures in the panels. A shank undercut receives the cold flow of material from the second bottom panel while the panels are clamped against a resilient dome-shaped head of the fastener. The fastener may include a central axial well that receives the tip of a press punch during installation.

A self-piercing rivet element is provided with a body part having a thread cylinder and with a hollow rivet section to be pressed into an as yet unpierced component. In this arrangement, the rivet section is designed to be at least regionally dilatable by means of a die button and tapers in the direction of the central longitudinal axis and away from the body part. The hollow rivet section has, in the region of the transition to the body part, a diameter, which is larger than the outer diameter of the thread cylinder. Furthermore, the rivet section has a closed peripheral wall and an opening at its free end which corresponds at least substantially in diameter to the core diameter of the thread cylinder. Furthermore a component assembly, a method for the manufacture of the component assembly and the die button are claimed.

An overlapping part of a first member and a second member is joined using a tool for friction stir spot welding and a rivet. The first member is disposed on a side where the tool is press-fitted first, and the second member is disposed on a side where the tool is press-fitted last, so that the overlapping part is formed. The tool is press-fitted into the overlapping part to perform friction stirring, thereby forming a friction stirred part in the overlapping part. The rivet is press-fitted into the friction stirred part from the first member side.

A punch-riveting die for a punch-riveting tool for setting a semi-hollow punch rivet into a punch rivet joint. The die comprising a basic body with a sheet metal support surface and a recess for forming an underside of a punch-rivet joint. The recess is arranged rotationally symmetrically to the central axis of the punch-riveting die. The recess having a first annular base, a lower second annular base, and a lowest central cavity extending axially below the second base. A projection rises axially in the central part of the cavity. A first annular wall extends between the first annular base and the sheet metal support surface. A second annular wall extends between the first annular base and the second annular base. A third annular wall extends between the second annular base and the bottom of the cavity.

A clinch fastener with a single-element, unitary construction that does not require the preassembly of parts. The fastener provides a clamp load after installation and is fully formed by stamping the part from sheet metal. The fastener provides the necessary rigidity for a clinch attachment shank with the resilience of a head that will provide a residual clamp load to the attached panels. The fastener attaches two panels face-to-face by extending through aligned apertures in the panels. A shank undercut receives the cold flow of material from the second bottom panel while the panels are clamped against a resilient dome-shaped head of the fastener. The fastener may include a central axial well that receives the tip of a press punch during installation.