A throttle tube assembly including a throttle tube, a throttle body, a bearing, and a stop collar. The throttle tube extends along a central axis from a proximal most end to a distal most end, the throttle including a lumen extending through the throttle tube. The throttle body is connected to the throttle tube, at the proximal end of the throttle tube, the throttle body having a bearing seat aligned along the central axis with the throttle body. The bearing being disposed in the bearing seat and axially aligned with the throttle body and partially axially aligned with the throttle tube. The stop collar is fixed to the throttle body configured and arranged to actuate a throttle by wire system.

An assembly including an inner member; an outer member; and a bearing including a bearing sidewall including a flat portion, a first convex axial end, and a second convex axial end, where at least one of the inner member or the outer member is adapted to axially translate relative to the bearing, and where at least one of the first convex axial end or the second convex axial end is adapted to induce formation of a film on the bearing sidewall during the axial translation of at least one of the inner member or the outer member.

A throttle tube assembly including a throttle tube, a throttle body, a bearing, and a stop collar. The throttle tube extends along a central axis from a proximal most end to a distal most end, the throttle including a lumen extending through the throttle tube. The throttle body is connected to the throttle tube, at the proximal end of the throttle tube, the throttle body having a bearing seat aligned along the central axis with the throttle body. The bearing being disposed in the bearing seat and axially aligned with the throttle body and partially axially aligned with the throttle tube. The stop collar is fixed to the throttle body configured and arranged to actuate a throttle by wire system.

Skewer for tightening a cycle wheel to the cycle frame, such skewer including a first end having a threaded portion cooperable with a female thread of a first frame portion, and a second end having axial abutment mechanisms for contacting a second frame portion, as well as drive mechanisms to enable a user to alternately exert a tightening torque or a loosening torque. A torque limiting mechanism operational in the tightening direction is positioned between the drive mechanisms and the rod. The skewer further includes a braking device to increase the torque required to initiate the rotation of the drive mechanisms in the loosening direction. The braking device includes two mutually contacting friction surfaces when the axial abutment mechanisms are in contact with the second frame portion. When the torque limiting mechanism is operational, the braking device becomes non-operational because the friction surfaces are no longer in mutual contact.

An assembly comprising: a core in the form of a toroid; and at least one washer overlying the core, the washer comprising a polymer, wherein the washer has an arcuate cross-section so as to have a shape complementary to the core.

A bearing cup for a bicycle bottom bracket assembly is disclosed. The bearing cup comprises an annular body having a radially outer substantially cylindrical surface portion configured to be coupled with the frame of the bicycle and a radially inner substantially cylindrical surface portion defining a housing seat for a bearing. A plurality of ribs extend radially inwards from said radially inner substantially cylindrical surface portion. The plurality of ribs are configured to be coupled with interference with said bearing. In another embodiment, a bicycle bottom bracket assembly is disclosed that includes the aforementioned bearing cup and a bearing configured to be housed inside the bearing cup.

A linear motion assembly having a static coefficient of friction, S, as measured between an inner component and an outer component, and a dynamic coefficient of friction, .sub.D, as measured between the inner component and the outer component, wherein .sub.S/.sub.D is less than 2.0, such as less than 1.9, less than 1.8, less than 1.7, or even less than 1.6.

A bearing structure for a shaft includes a shaft on which a male thread section is formed and a concave section recessed inside in a radial direction is partially formed in a circumferential direction thereof, a cylindrical holder in which the shaft is disposed, a bearing attached between the shaft and the holder and configured to rotatably support the shaft at an opening side thereof at which the holder is open, a thread engagement member having a female thread section threadedly engaged with the male thread section and a flat surface section crossing the circumferential direction of the shaft and formed on an outer circumference thereof, and coaxially threadedly fastened to the shaft from the opening side, and a locking member having a convex section fitted into the concave section and an engaging section engaged with the flat surface section, and partially locked to the shaft and the thread engagement member.

Presented are multi-axis pivoting coupler joints for motorized vehicles, methods for making/using such coupler joints, and electric scooters with multi-axis pivoting coupler joints enabling multimodal scooter operation. A pivoting coupler joint includes first and second bearing assemblies each with a respective housing, respective inner and outer races concentric with each other and located in their respective housing, and a respective set of rolling elements rollably interposed between their respective inner and outer races. The first inner race of the first bearing assembly receives therethrough and circumscribes an axle shaft of a vehicle wheel. The second inner race attaches to a wheeled rider deck of the vehicle. The first and second bearing housings are joined together and angularly offset from each other. For some applications, the first bearing assembly includes a pair of longitudinally spaced needle roller bearings, and the second bearing assembly includes a pair of longitudinally spaced tapered bearings.

In one example, a structure for attaching a wheel to one of a frame of a motorcycle or a bicycle may include an axle having first and second opposing end portions and supporting a wheel, a left axle support collar structure configured to support the first opposing end portion of the axle, and a right axle support collar structure configured to support the second opposing end portion of the axle. A first bearing is positioned in the left axle support collar structure, and a second bearing is positioned in the left axle support collar structure. The axle rotates relative to the frame.