An elastomer coupling for an electromechanical actuator, having a drive part and a driven part, wherein either the drive part or the driven part has multiple radially outwardly extending webs arranged so as to be distributed about an axis of rotation, and the respective other part has radially inwardly extending webs arranged on the inner side of a tubular body, wherein a radially inwardly and a radially outwardly extending web engage into one another and form a pocket in which there is received an elastic molded body produced from an elastomer, wherein, in at least one pocket, there is received a spring element which generates a pretensioning force, which spring element is attached either to an inwardly extending or to an outwardly extending web and is spring-loaded against an adjacent web.

An elastomer coupling for an electromechanical actuator, having a drive part and a driven part, wherein either the drive part or the driven part has multiple radially outwardly extending webs arranged so as to be distributed about an axis of rotation, and the respective other part has radially inwardly extending webs arranged on the inner side of a tubular body, wherein a radially inwardly and a radially outwardly extending web engage into one another and form a pocket in which there is received an elastic molded body produced from an elastomer, wherein, in at least one pocket, there is received a spring element which generates a pretensioning force, which spring element is attached either to an inwardly extending or to an outwardly extending web and is spring-loaded against an adjacent web.

An impact protection and shock absorbing device includes a support surface, and a plurality of flexible spines, configured of one or more sizes, each having a length defined from a base portion at the support surface to a distal portion thereof, and whereby each spine extends in one or more longitudinal directions outwardly from the support surface, at one or more angles less than 90 degrees. Sufficient deflecting of one or more spines by impact force causes impinging and deflecting of one or more other spines thereby dispersing and reducing impact forces.

An impact protection and shock absorbing device includes a support surface, and a plurality of flexible spines, configured of one or more sizes, each having a length defined from a base portion at the support surface to a distal portion thereof, and whereby each spine extends in one or more longitudinal directions outwardly from the support surface, at one or more angles less than 90 degrees. Sufficient deflecting of one or more spines by impact force causes impinging and deflecting of one or more other spines thereby dispersing and reducing impact forces.

The present invention is a vibration damping device (1, 2) that includes an external member (11, 21) attached to one of a vibration-generating portion and a vibration-receiving portion; a tubular member (40) attached to the other of the vibration-generating portion and the vibration-receiving portion; and an elastic body (30) which connects the external member (11, 21) and the tubular member (40). The external member (11, 21) includes a frame-like member (11, 21) having a rectangular shape when viewed from the top. In the elastic body (30), a long-side portion (32a) forming a long side of a rectangular shape when viewed from the top adheres to an inner circumferential surface of the long-side portion (12a, 12b) of the frame-like member (11, 21), and a short-side portion (32b) forming a short side of the rectangular shape when viewed from the top comes into contact with the external member (11, 21) in a long-side direction (X) in which the long-side portion (12a, 12b) extends when viewed from the top, in a non-adhering state.

Slide assemblies for motor vehicles are provided. In one example, a slide assembly for a motor vehicle includes a first member and a second member that is slidingly coupled with the first member. A first leaf spring device is disposed between the first and second members for facilitating relative sliding movement between the first and second members. The first leaf spring device includes a raised contact portion that slidingly interfaces with one of the first and second members during the relative sliding movement.

Slide assemblies for motor vehicles are provided. In one example, a slide assembly for a motor vehicle includes a first member and a second member that is slidingly coupled with the first member. A first leaf spring device is disposed between the first and second members for facilitating relative sliding movement between the first and second members. The first leaf spring device includes a raised contact portion that slidingly interfaces with one of the first and second members during the relative sliding movement.

An elastomer coupling for an electromechanical actuator, having a drive part and a driven part, wherein either the drive part or the driven part has multiple radially outwardly extending webs arranged so as to be distributed about an axis of rotation, and the respective other part has radially inwardly extending webs arranged on the inner side of a tubular body, wherein a radially inwardly and a radially outwardly extending web engage into one another and form a pocket in which there is received an elastic molded body produced from an elastomer, wherein, in at least one pocket, there is received a spring element which generates a pretensioning force, which spring element is attached either to an inwardly extending or to an outwardly extending web and is spring-loaded against an adjacent web.

A mounting assembly is provided. The mounting assembly includes a first assembly portion coupled to a first component and a second assembly portion coupled to a second component. The first assembly portion includes a first bracket and a locating pin. The first bracket has a first surface, a second surface, and defines a first bracket protrusion having a first bracket bore therein. The locating pin has a first end, a second end, and an exterior surface. The first end of the locating pin is fixedly mounted within the first bracket bore. The second assembly portion includes a base plate that has a base plate first surface and a base plate second surface and defines a base plate protrusion portion having a protrusion bore therein. The locating pin is configured to be inserted into the protrusion bore in order to position the first component with respect to the second component.

A mounting assembly is provided. The mounting assembly includes a first assembly portion coupled to a first component and a second assembly portion coupled to a second component. The first assembly portion includes a first bracket and a locating pin. The first bracket has a first surface, a second surface, and defines a first bracket protrusion having a first bracket bore therein. The locating pin has a first end, a second end, and an exterior surface. The first end of the locating pin is fixedly mounted within the first bracket bore. The second assembly portion includes a base plate that has a base plate first surface and a base plate second surface and defines a base plate protrusion portion having a protrusion bore therein. The locating pin is configured to be inserted into the protrusion bore in order to position the first component with respect to the second component.