A dropout assembly comprises a first dropout that includes a first through hole configured to receive an axle for a bicycle wheel. The dropout assembly also comprises a second dropout that includes a second through hole and a mounting surface. The second through hole is configured to receive the axle for the bicycle wheel. The dropout assembly also includes a rotational control mechanism that is configured to mount to the mounting surface of the second dropout. The rotational control mechanism includes a nut and a nut cover.

An air spring assembly is disclosed. The air spring assembly includes an upper fork tube having a base lug on one end, a lower fork tube having an opening to receive the upper fork tube in a first axial end, and a fork tube gas seal to form a gas seal between the upper fork tube and the lower fork tube. A partial cartridge tube within a portion of the upper fork tube, the partial cartridge tube including a partial cartridge tube gas seal between an outer diameter (OD) of the partial cartridge tube and an inner diameter (ID) of the upper fork tube. An annular volume formed between the ID of the upper fork tube, the OD of the partial cartridge tube, the partial cartridge tube gas seal, and the base lug of the upper fork tube.

An air spring assembly is disclosed. The air spring assembly includes an upper fork tube having a base lug on one end, a lower fork tube having an opening to receive the upper fork tube in a first axial end, and a fork tube gas seal to form a gas seal between the upper fork tube and the lower fork tube. A partial cartridge tube within a portion of the upper fork tube, the partial cartridge tube including a partial cartridge tube gas seal between an outer diameter (OD) of the partial cartridge tube and an inner diameter (ID) of the upper fork tube. An annular volume formed between the ID of the upper fork tube, the OD of the partial cartridge tube, the partial cartridge tube gas seal, and the base lug of the upper fork tube.

A shock absorber includes a cylinder which is a conductor; a rod inserted into the cylinder from one end side of the cylinder, a suspension spring arranged outside the cylinder, a spring receiver which receives a load of the suspension spring on the one end side of the rod, and a protective member arranged on the one end side of the rod and configured to protect the rod. The protective member has a coil configured to detect a relative position between the cylinder and the protective member, and an end portion formed on the one end side of the protective member is arranged so as not to receive a load from the spring receiver.

A bicycle with a suspension system for a wheel of the bicycle, the suspension system including a smart fluid damper for dampening a movement of the wheel relative to the frame. The smart fluid damper includes a flow control element disposed within a cavity of the damper and configured to apply a field to a smart fluid within a fluid passage extending through the flow control element. The flow control element includes field barriers proximate the fluid passage to locally block and/or divert the field such that the field cannot pass therethrough. The field barriers are arranged to cause the field to criss-cross the fluid passage at multiple axial intervals along the fluid passage, thereby focusing the field within the fluid passage.

A bicycle with a suspension system for a wheel of the bicycle, the suspension system including a smart fluid damper for dampening a movement of the wheel relative to the frame. The smart fluid damper includes a flow control element disposed within a cavity of the damper and configured to apply a field to a smart fluid within a fluid passage extending through the flow control element. The flow control element includes field barriers proximate the fluid passage to locally block and/or divert the field such that the field cannot pass therethrough. The field barriers are arranged to cause the field to criss-cross the fluid passage at multiple axial intervals along the fluid passage, thereby focusing the field within the fluid passage.

A shock device for an at least partially muscle-powered two-wheeled vehicle including a damping system having a damper cylinder and a moving piston disposed therein and connected with a piston rod extending from the damper cylinder, wherein the piston acts on a first damping chamber in the damper cylinder in the compression stage as the piston rod plunges in from a retracted base position into a plunged-in position. In the damping system, as the piston rod plunges in, damping fluid is transferred from the first damping chamber to an auxiliary chamber. A flow resistance for transferring the damping fluid into the auxiliary chamber is configured travel-dependent, depending on the piston position. The flow resistance for transferring the damping fluid into the auxiliary chamber over a first travel distance of the piston including the base position is smaller than over a second travel distance that is plunged in further.

A shock device for an at least partially muscle-powered two-wheeled vehicle including a damping system having a damper cylinder and a moving piston disposed therein and connected with a piston rod extending from the damper cylinder, wherein the piston acts on a first damping chamber in the damper cylinder in the compression stage as the piston rod plunges in from a retracted base position into a plunged-in position. In the damping system, as the piston rod plunges in, damping fluid is transferred from the first damping chamber to an auxiliary chamber. A flow resistance for transferring the damping fluid into the auxiliary chamber is configured travel-dependent, depending on the piston position. The flow resistance for transferring the damping fluid into the auxiliary chamber over a first travel distance of the piston including the base position is smaller than over a second travel distance that is plunged in further.

A self-adjusting suspension system according to the present disclosure may be incorporated into an electric vehicle design by way of an integrated air supply system. The integrated air supply system measures and adjusts amounts of pressurized air within pneumatic components of the electric vehicle to provide a predetermined desired amount of suspension. The integrated air supply system also may be used to provide air to pneumatic tires of the vehicle, without the need for an external pump.

A self-adjusting suspension system according to the present disclosure may be incorporated into an electric vehicle design by way of an integrated air supply system. The integrated air supply system measures and adjusts amounts of pressurized air within pneumatic components of the electric vehicle to provide a predetermined desired amount of suspension. The integrated air supply system also may be used to provide air to pneumatic tires of the vehicle, without the need for an external pump.