A pair of left and right vertical frame pieces 1b, 1b constituting a part of a vehicle body frame FR extend in a vertical direction. A pair of left and right swingarm brackets 9L, 9R are fixed to the left and right vertical frame pieces 1b, 1b, respectively. A pivot 16 is supported by the swingarm brackets 9L, 9R swingably supports a swingarm 12 outward of the swingarm brackets 9L, 9R in a vehicle widthwise direction. Each of the left and right swingarm brackets 9L, 9R includes left and right opposing portions 320, 340 disposed so as to be spaced apart in the vehicle widthwise direction. The pivot 16 is supported by the left and right opposing portions 320, 340 of each of the swingarm brackets 9L, 9R.

A chainring for a bicycle includes a body and a plurality. The plurality of teeth are disposed about a periphery of the body. The plurality of teeth have a tooth body formed of a first material and include a load flank. The plurality of teeth also include an insert formed of a second material. The insert is coupled to a tooth body of the plurality of teeth forming a load flank surface of the plurality of teeth.

A chainring for a bicycle includes a body and a plurality. The plurality of teeth are disposed about a periphery of the body. The plurality of teeth have a tooth body formed of a first material and include a load flank. The plurality of teeth also include an insert formed of a second material. The insert is coupled to a tooth body of the plurality of teeth forming a load flank surface of the plurality of teeth.

The present disclosure relates to a chain ring having teeth positioned in one of three lateral positions. At least one tooth may be placed in each lateral position. At least half the teeth may be positioned in a middle lateral position. The teeth in the first and third lateral positions may apply opposing lateral forces to a bicycle drive chain.

The present disclosure relates to a chain ring having teeth positioned in one of three lateral positions. At least one tooth may be placed in each lateral position. At least half the teeth may be positioned in a middle lateral position. The teeth in the first and third lateral positions may apply opposing lateral forces to a bicycle drive chain.

A mid-sprocket assembly is disclosed herein. The mid-sprocket assembly includes an input shaft to receive an input force, the input shaft having a plurality of input shaft gears coupled therewith. A countershaft having a plurality of countershaft gears coupled therewith, at least one of the plurality of countershaft gears selectively and axially engaged to receive the input force from at least one input shaft gears and provide the input force to a rear wheel to drive the rear wheel.

The teachings provided herein are generally directed to compact vehicle drive mechanisms that can be used in the design of a foldable, carry-on vehicle. The compact drive mechanisms presented herein, for example, have contributed to the advent of the compact, carry-on bicycles set-forth in the teachings which include drive-and-steering units and drive-and-chassis units.

A bicycle comprising a front wheel and a rear wheel supporting a frame. A bottom bracket of the frame defines a first axis, a second axis and a third axis. A pedal crank assembly is supported for rotation about the first axis and includes a first driven gear and a first drive gear. A second gear is supported for rotation about the second axis. A third driven gear and a third drive gear are supported for rotation about the third axis. An electric motor drives the first driven gear and the first drive gear rotates in response to rotation of the first driven gear. The first drive gear engages and rotates the second gear, which drives the third driven gear. The third drive gear rotates in response to rotation of the third driven gear. The third drive gear is rotationally coupled to the rear wheel.

A bicycle comprising a front wheel and a rear wheel supporting a frame. A bottom bracket of the frame defines a first axis, a second axis and a third axis. A pedal crank assembly is supported for rotation about the first axis and includes a first driven gear and a first drive gear. A second gear is supported for rotation about the second axis. A third driven gear and a third drive gear are supported for rotation about the third axis. An electric motor drives the first driven gear and the first drive gear rotates in response to rotation of the first driven gear. The first drive gear engages and rotates the second gear, which drives the third driven gear. The third drive gear rotates in response to rotation of the third driven gear. The third drive gear is rotationally coupled to the rear wheel.

An individual chain wheel for a bicycle front crank arrangement for engaging in a drive chain includes a plurality of teeth formed on a circumference of the chain wheel and having a first and a second group of teeth. The teeth of the second group of teeth are arranged in an alternating manner between the teeth of the first group of teeth. Each tooth has a load flank via which force is transmitted between an adjacent roller of the drive chain and the respective tooth. Each tooth of the first group may also have at least one profile with an opening in the vicinity of the flank, in which a portion of an inner link plate of the drive chain, which portion protrudes beyond the roller, engages.