A bicycle capable of measuring power is disclosed. The bicycle comprises a spider including a torque input section and at least one torque output section; a crank assembly coupled with the spider through the torque input section and applying an input torque to the spider; a chainring mounted to the spider through the at least one torque output section and receiving an output torque from the spider; a gauge disposed and oriented generally along a tangential direction or a quasi-tangential direction with respect to the torque input section and the at least one torque output section; and a circuitry coupled to the gauge and receiving a signal from the gauge.

A bicycle capable of measuring power is disclosed. The bicycle comprises a spider including a torque input section and at least one torque output section; a crank assembly coupled with the spider through the torque input section and applying an input torque to the spider; a chainring mounted to the spider through the at least one torque output section and receiving an output torque from the spider; a gauge disposed and oriented generally along a tangential direction or a quasi-tangential direction with respect to the torque input section and the at least one torque output section; and a circuitry coupled to the gauge and receiving a signal from the gauge.

An electronic device is related to a human-powered vehicle operating device that includes an operating mechanism, which is for operating at least one of a human-powered vehicle transmission device and a human-powered vehicle braking device, and at least one operating member. The electronic device comprises a storage, an electronic controller, and a communication unit. The storage stores setting information related to an operation of the at least one operating member and to an output destination device. The electronic controller is configured to generate an output signal corresponding to the operation of the at least one operating member based on the setting information. The communication unit transmits the output signal to the output destination device that includes at least one of a game device, a training device, an audio device, and a video device.

An electronic device is related to a human-powered vehicle operating device that includes an operating mechanism, which is for operating at least one of a human-powered vehicle transmission device and a human-powered vehicle braking device, and at least one operating member. The electronic device comprises a storage, an electronic controller, and a communication unit. The storage stores setting information related to an operation of the at least one operating member and to an output destination device. The electronic controller is configured to generate an output signal corresponding to the operation of the at least one operating member based on the setting information. The communication unit transmits the output signal to the output destination device that includes at least one of a game device, a training device, an audio device, and a video device.

A bottom bracket is connected to a spindle and a frame of a bicycle. The bottom bracket comprises a housing and an adapter. The housing is connected to the frame and comprises a substantially circular disc, one or more pins, and an actuating mechanism. The disc comprises a plurality of disc openings arranged proximate to a circumferential edge of the disc and is adapted to rotate with the spindle. The pins selectively engage with the disc openings, wherein the engagement of the pins with the disc openings prevents further rotation of the disc. The actuating mechanism selectively engages the pins with the disc openings. The adapter removably is attached to the housing and connected to the frame.

A bottom bracket is connected to a spindle and a frame of a bicycle. The bottom bracket comprises a housing and an adapter. The housing is connected to the frame and comprises a substantially circular disc, one or more pins, and an actuating mechanism. The disc comprises a plurality of disc openings arranged proximate to a circumferential edge of the disc and is adapted to rotate with the spindle. The pins selectively engage with the disc openings, wherein the engagement of the pins with the disc openings prevents further rotation of the disc. The actuating mechanism selectively engages the pins with the disc openings. The adapter removably is attached to the housing and connected to the frame.

A foldable electric scooter and a manufacture method of the same. The foldable electric scooter includes a main body assembly, a front fork assembly located at the front end of the main body assembly, a rear fork assembly located at the rear end of the main body assembly, a telescoping plate assembly located on top of the front fork assembly and a handlebar assembly located on top of the telescoping plate assembly. The foldable electric scooter has a double headset design that increases a rake angle for more steering stability while still keeping the steering upright for an upright holding of the handlebars. The foldable electric scooter is manufactured by stamping of flat plate material.

A foldable electric scooter and a manufacture method of the same. The foldable electric scooter includes a main body assembly, a front fork assembly located at the front end of the main body assembly, a rear fork assembly located at the rear end of the main body assembly, a telescoping plate assembly located on top of the front fork assembly and a handlebar assembly located on top of the telescoping plate assembly. The foldable electric scooter has a double headset design that increases a rake angle for more steering stability while still keeping the steering upright for an upright holding of the handlebars. The foldable electric scooter is manufactured by stamping of flat plate material.

Each plate (10) includes a plate throughbore (64) secured to an end of a drive axle (52) of a bicycle (16). A pedal arm (72) is secured to an attachment post (68) that extends from the leverage plate (10) between the drive axle (52) and a perimeter edge (70) of the plate (10). Moving a pedal (82) on the pedal arm (72) downward to move the bicycle (16) in a forward, desired direction of motion (56), causes the pedal arm (72) to contact the drive axle (52). An inner end (74) of the pedal arm (72) moves the pedal arm attachment post (68) and leverage plate (10) around the plate throughbore (64). The drive axle (52) therefore becomes a fulcrum (52) of a first-class lever (88) as the pedal arm (72) is moved downward. The leverage plates (10) may retro-fit to any bicycle (16).

Each plate (10) includes a plate throughbore (64) secured to an end of a drive axle (52) of a bicycle (16). A pedal arm (72) is secured to an attachment post (68) that extends from the leverage plate (10) between the drive axle (52) and a perimeter edge (70) of the plate (10). Moving a pedal (82) on the pedal arm (72) downward to move the bicycle (16) in a forward, desired direction of motion (56), causes the pedal arm (72) to contact the drive axle (52). An inner end (74) of the pedal arm (72) moves the pedal arm attachment post (68) and leverage plate (10) around the plate throughbore (64). The drive axle (52) therefore becomes a fulcrum (52) of a first-class lever (88) as the pedal arm (72) is moved downward. The leverage plates (10) may retro-fit to any bicycle (16).