The present invention is to provide a vehicular interior member in which three components can be strongly joined to each other and the weight can be reduced. A vehicular interior member is formed so that first and second components respectively made of thermoplastic resin, and a middle component arranged between the first component and the second component are joined to each other. The first component has a boss projecting to the second component side. The middle component has a through hole through which the boss is inserted. The second component has a through hole through which the boss is inserted, and a fitting portion projecting to the middle component side, the fitting portion being fitted to an edge portion of the through hole. The boss and the second component are welded to each other.

The present technology discloses methods for joining a first workpiece and a second workpiece through a heat stake, and products formed thereby. The first workpiece has an aperture configured to receive a stud positioned on a second workpiece. The system is formed by applying energy to the first workpiece using electrodes, which indirectly heats the stud, at least partially softening material of the stud. Pressure is then applied to the softened material of the stud, and causing the material to form according to a predetermined geometry. After pressure is released, the stud forms a stake forming an interlocked joint connecting the workpieces.

An adaptor for anchoring a second object with respect to a first object includes an anchoring part and an adjustment part. The anchoring part includes a distally facing anchoring surface and a proximally facing first control surface, and the adjustment part includes a distally facing second control surface positioned to abut against the first control surface. The anchoring part and the adjustment part define a common axis, and the first control surface or the second control surface or both is/are helical with respect to the axis, whereby a relative z position of the adjustment part with respect to the anchoring part is adjustable by rotating the adjustment part relative to the anchoring part around the axis while the second control surface abuts against the first control surface.

An adaptor is secured to a first object. The adaptor includes an anchoring part and an adjustment part. The anchoring part includes a distally facing anchoring surface and a proximally facing first control surface. The adjustment part has a distally facing second control surface positioned to abut against the first control surface. The first control surface or the second control surface or both is/are helical. Thereby a relative z position of the adjustment part with respect to the anchoring part is defined by the relative orientation of the adjustment part with respect to the common axis while the second control surface abuts against the first control surface. This is used to adjust the z position of the adjustment part relative to the first object, in connection with the orientation of the adjustment part being defined and possibly fixed by the function of the adaptor/the adjustment part

An adaptor for securing a second object includes an anchoring part and an adjustment part, wherein the anchoring part includes a distally facing anchoring surface and a proximally facing first control surface. The adjustment part has a distally facing second control surface positioned to abut against the first control surface. The anchoring part and the adjustment part define a common axis that is not perpendicular to the z direction, wherein the first control surface and possibly also the second control surface is/are helical with respect to the axis. Thereby a relative z position of the adjustment part with respect to the anchoring part is defined by the relative orientation of the adjustment part with respect to the common axis while the second control surface abuts against the first control surface.

A fastener element for attachment to a component, wherein the fastener element has a contact surface which contacts the component in the installed state. Furthermore, the fastener element has a mounting recess which faces the component in the dismantled state. The mounting recess is bounded by at least one sidewall and by a base section. The sidewall is, at least regionally, provided with at least one undercut which is effective in the axial direction of the fastener element. The base section is formed free of any aperture.

A connection assembly for a tower of a wind turbine is provided. The connection assembly includes a first tower section segment having an inner surface spaced apart from an outer surface. A second tower section segment is positioned adjacent to the first tower section segment and includes an inner surface spaced apart from an outer surface. The first tower section segment and the second tower section segment define a vertically extending gap therebetween. A connector plate includes a first connector plate portion, a second connector plate portion spaced apart from the first connector plate portion, and a third connector plate portion positioned between the first connector plate portion and the second connector plate portion. The first connector plate portion couples to the first tower section segment. The second connector plate portion couples to the second tower section segment. The third connector plate portion extends through the vertically extending gap.

A rivet connection has a hollow rivet composed of plastics material and connects a first component to a second component. The first component has a first surface and the second component has a second and third surface. The first surface and the second surface bear on one another. The second component has a first opening between the second and the third surface. The hollow rivet has a tubular component having a lateral wall, a cavity, a first end and a second end. Part of the tubular component is disposed in the first opening of the second component. The second end of the tubular component protrudes beyond the second component. The lateral wall of the tubular component adjacent the first opening of the second component is heated and compressed and configures an outwardly bulging region. Part of the outwardly bulging region contacts the third surface of the second component.

A mechanical coupling assembly that includes a primary substrate having at least one aperture formed therein. A secondary substrate includes at least one mechanical interlock monolithically formed with the secondary substrate. The at least one mechanical interlock extends through the aperture. The mechanical interlock includes a main body and a head portion with a transition portion connecting the main body and head portions. The main body includes a bore formed longitudinally therein about a centerline of the aperture. The mechanical interlock joins the primary substrate and secondary substrate mechanically.

A connection assembly for a tower of a wind turbine is provided. The connection assembly includes a first tower section segment having an inner surface spaced apart from an outer surface. A second tower section segment is positioned adjacent to the first tower section segment and includes an inner surface spaced apart from an outer surface. The first tower section segment and the second tower section segment define a vertically extending gap therebetween. A connector plate includes a first connector plate portion, a second connector plate portion spaced apart from the first connector plate portion, and a third connector plate portion positioned between the first connector plate portion and the second connector plate portion. The first connector plate portion couples to the first tower section segment. The second connector plate portion couples to the second tower section segment. The third connector plate portion extends through the vertically extending gap.