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.

A self-piercing riveting (SPR) die includes a die body including an outer surface, a lower surface that is parallel to and offset from the outer surface, and a side surface that circumscribes the lower surface. A distance between the lower surface and the outer surface is less than or equal to approximately 1.2 mm. An angle between the side surface and the lower surface is within a range between approximately 45 and 90 degrees. An inner diameter of the outer surface is within a range between approximately 9 and 13 mm.

A self-piercing riveting (SPR) die includes a die body including an outer surface, a lower surface that is parallel to and offset from the outer surface, and a side surface that circumscribes the lower surface. A distance between the lower surface and the outer surface is less than or equal to approximately 1.2 mm. An angle between the side surface and the lower surface is within a range between approximately 45 and 90 degrees. An inner diameter of the outer surface is within a range between approximately 9 and 13 mm.

Tips of sections in a spreading state come into contact with vertical wall portions of a middle member at positions between a first plate-like member and center portions of the vertical wall portions in the thickness direction. Then, the sections break through the vertical wall portions, and are fastened to a hollow laminated board. Thus, a mounting bracket is attached to the hollow laminated board. This makes it possible to obtain a deck board with a small recessed portion formed in a top face.

Tips of sections in a spreading state come into contact with vertical wall portions of a middle member at positions between a first plate-like member and center portions of the vertical wall portions in the thickness direction. Then, the sections break through the vertical wall portions, and are fastened to a hollow laminated board. Thus, a mounting bracket is attached to the hollow laminated board. This makes it possible to obtain a deck board with a small recessed portion formed in a top face.

A fastener mounting assembly is configured to securely mount to at least one panel of a component. The fastener mounting assembly may include a base, a fastener mount extending from the base, and at least one panel-engaging member connected to one or both of the base and the fastener. The panel-engaging member(s) is configured to securely engage the panel(s) of the component to securely lock the fastener mounting assembly to the panel(s).

A fastener mounting assembly is configured to securely mount to at least one panel of a component. The fastener mounting assembly may include a base, a fastener mount extending from the base, and at least one panel-engaging member connected to one or both of the base and the fastener. The panel-engaging member(s) is configured to securely engage the panel(s) of the component to securely lock the fastener mounting assembly to the panel(s).

A method for joining at least two structural parts includes a fitting step in which a joining element is driven into the first structural part while a residual material thickness is maintained, and a joining step in which the joining element driven into the first structural part is connected to the second structural part. The joining element has a hollow element shaft, which is driven into the first structural part, and an element head, which is welded or adhesively bonded to the second structural part.

A method for joining at least two structural parts includes a fitting step in which a joining element is driven into the first structural part while a residual material thickness is maintained, and a joining step in which the joining element driven into the first structural part is connected to the second structural part. The joining element has a hollow element shaft, which is driven into the first structural part, and an element head, which is welded or adhesively bonded to the second structural part.

A module mount having at least one module that can be mounted on the module mount, wherein the module can be mounted on the module mount via at least one caulking element, such that the respective caulking element, which is composed of a thermoplastic, extends through a hole in a section of the respective module that can be mounted on the module mount made of a thermoplastic or thermoset, and is hot-caulked at an end projecting out of the hole, wherein at least one projection is formed on the section of the respective module that can be mounted on the module mount in the region of the respective hole of the section of the respective module that can be mounted on the module mount made of the thermoplastic or thermoset, which projection is engaged in a press fit with the hot-caulked end of the respective caulking element.