Disclosed is a vehicle having a breakaway tie rod. The tie rod has a longitudinal axis oriented substantially orthogonal to the longitudinal axis of the vehicle, and includes a rod portion and a receiver portion. The rod portion includes a proximal ball joint disposed at the proximal end and a male coupling section disposed at the distal end. The receiver portion includes a female coupling section disposed at the proximal end, a distal ball joint disposed at the distal end, and a narrowing feature disposed between the proximal end and distal end. The male coupling section of the rod portion is received into the female coupling section of the receiver portion, forming a connection, and the distal end of the rod portion is disposed proximate to the narrowing feature. The narrowing feature is configured to fracture when subjected to a threshold force substantially parallel to the longitudinal axis of the vehicle.

A bushing assembly for a vehicle including a first bushing with an inner diameter, an outer diameter, and interlocking teeth extending from it and a second bushing with an inner diameter, an outer diameter, and interlocking teeth extending from it. The first bushing and the second bushing are joined by their respective interlocking teeth. An inner sleeve with a first end and a second end is enclosed within the inner diameter of the first bushing and the inner diameter of the second bushing. A first compression cap on the first bushing is threadedly fastened to the inner sleeve, and a second compression cap on the second bushing is threadedly fasten to the inner sleeve.

A bushing assembly for a vehicle including a first bushing with an inner diameter, an outer diameter, and interlocking teeth extending from it and a second bushing with an inner diameter, an outer diameter, and interlocking teeth extending from it. The first bushing and the second bushing are joined by their respective interlocking teeth. An inner sleeve with a first end and a second end is enclosed within the inner diameter of the first bushing and the inner diameter of the second bushing. A first compression cap on the first bushing is threadedly fastened to the inner sleeve, and a second compression cap on the second bushing is threadedly fasten to the inner sleeve.

Provided is a torque-transmission joint 15a that is able to reduce the thrust force that is transmitted between the output shaft 12a of an electric motor 8 and a worm shaft 6a without generating noise. A shock-absorbing member 18a that is made using an elastic material is assembled between a driving-side transmission member 16a that is supported by the output shaft 12a and a driven-side member 17a that is supported by the worm shaft 6a. Held sections 33a, 33b of the shock-absorbing member 18a are located between the side surfaces in the circumferential direction of driving-side arm sections 21a of the driving-side transmission member 16a and side surfaces in the circumferential direction of driven-side arm sections 23a of the driven-side transmission member 17a. A damper section 26 is integrally provided with the shock-absorbing member 18a, and that damper section 26 is elastically held between the tip-end surface of the output shaft 12a and the base-end surface of the worm shaft 16a.

Provided is a rack bush capable of reducing an effect on the feeling of a steering operation. A rack bush (1) comprises: a rack bush 1 housed in a cylindrical housing (4), which supports a load applied to a rack bar (5) while allowing movement of the rack bar (5) in the direction of the axis (O) and can be freely expanded and contracted in the radial direction; and elastic rings (3) mounted on the bush body (2). The bush body (2) has mounting grooves (28), which are formed in the circumferential direction on an outer peripheral surface (22) for mounting the elastic ring (3). An axis (P) of the mounting groove (28) are shifted from the axis (O) of the bush body (2). By this arrangement, there are formed an elastic ring protruding part (10), where the elastic rings (3) protrude greatly from the outer peripheral surface (22) of the bush body (2), and an elastic ring embedded part (11), where the elastic rings (3) are embedded in the outer peripheral surface (22) of the bush body (2).

The present invention relates to a mounting assembly for a vehicle for coupling, to a chassis, a housing in which a steering device is mounted, the mounting assembly including: a first bush that is configured to be coupled to a mounting hole that is formed in the housing, and is configured to have a coupling groove formed therein; a second bush that is configured to be provided between the housing and the chassis, and is configured to have a through hole formed to lead to the coupling groove; and a bolt that is configured to fix the housing to the chassis, wherein the second bush is inserted into the bottom of the first bush to then be coupled, and the bolt is engaged with the coupling groove by passing through an assembly hole that is formed in the chassis and by passing the through hole.

The present invention relates to a new hydraulic stabilizing unit that can be mounted onto any self-steering axle assembly that utilises a pneumatic stabilizing system. The hydraulic stabilizer works in conjunction with the pneumatic stabilizer to eliminate a “dead zone” of the pneumatic system to avoid wheel shimmy and hop conditions associated with out of specification caster angles on the axle.

A turning device includes: a motor configured to generate a drive force for independently steering a steered wheel; a speed reducer connected to a rotary shaft body of the motor; and a brake configured to suppress transfer of torque between the motor and the speed reducer.

A shock-absorbing member comprises held sections located at a plurality of locations in a circumferential direction and comprising paired held sections and non-paired held sections, and is constructed to have a non-circular cylindrical shape in cross-section. Portions where outer-diameter side end sections of held sections that are adjacent to each other in the circumferential direction are made continuous by way of outer-diameter side cover sections, and portions where inner-diameter side end sections of held sections that are adjacent to each other in the circumferential direction are made continuous directly or by way of inner-diameter side cover sections, in an alternating sequence in the circumferential direction. Drive-side arm sections are placed between the non-paired held sections, driven-side arm sections are placed between the paired held sections, and the outer circumferential surfaces of the drive-side arm sections are covered by the outer-diameter side cover sections.

A damper apparatus includes a shock-absorbing member configured to absorb a shock while restricting movement of a shaft relative to a housing. The shock-absorbing member includes a shock-receiving member configured to come into contact with one member, which is one of a large-diameter portion of the shaft and a restriction portion of the housing, and a pre-compression spring disposed between the other member, which is the other of the large-diameter portion and the restriction portion, and the shock-receiving member in a state where the pre-compression spring is compressed in advance in an axial direction. The pre-compression spring is configured to urge the one member in the axial direction via the shock-receiving member when the large-diameter portion is relatively moved toward the restriction portion beyond a prescribed position.