An integrated handlebar for a bicycle includes a handlebar and at least one integrated control device, wherein the handlebar has at least two free ends and the integrated control device includes a base engaged with at least one of the free ends, a brake lever and an electronic controller. The brake lever has a front end pivotally connected with the base and a rear end. The brake lever has a mounting portion, being located at a distance not greater than length of the brake lever from the rear end and not on the rear end. The electronic controller includes an operation member disposed on the brake lever, which includes at least one operation part adapted to be triggered by fingers of a rider to control an action of the operation member so as to drive the electronic controller to output an electronic signal to an electronic component.

A handguard system for a handlebar of a bicycle is provided and includes a handguard article having a handguard first end communicated with a handguard second end via a handguard center portion, wherein the handguard second end is configured to associate with the handlebar. The handguard system also includes a handguard collar, wherein the handguard collar includes a handguard collar structure which defines a collar cavity configured to contain the handlebar and having a collar cavity diameter CCD which is configurable between a first collar cavity diameter CC.sub.D1 and a second collar cavity diameter CC.sub.D2. and Additionally, the handguard system further includes a handguard mounting device, wherein the handguard mounting device is configured to securingly associate with the handguard first end and the handlebar, wherein when the handguard article is securingly associated with the handlebar, the handguard center portion is configured to cover a portion of the handlebar.

A bicycle handlebar assembly comprises a base bar, a v-shaped stem selectively removable from the base bar, and a bicycle fork assembly. Control cables from the bicycle may be routed from the base bar into hollow diverging stem members of the v-shaped stem. The bicycle fork assembly comprises an external-steerer fork having a load-bearing member and a preload tensioning rod. The preload tensioning rod fits within a head tube of the bicycle, and a hollow space around the preload tensioning rod accommodates control cables passing from the v-shaped stem into a hollow portion of the bicycle frame. The v-shaped stem is secured against the base bar by a pair of nut plates. In some examples, an engagement portion of an accessory such as an aerobar extension assembly is configured to secure the v-shaped stem and an aerobar extension against the base bar.

A system and method for balancing a bicycle is disclosed. The system can comprise a frame, a tension system, and a steering system. The frame can be capable of mounting to a bicycle. The tension system can comprise a first steering cable and a second steering cable. The first steering cable can be capable of connecting with a left handlebar of handlebars of the bicycle and the second steering cable can be capable of connecting with a right handlebar of the handlebars. The steering system can be mounted to the frame. The steering system can be in communication with the tension system such that manually maneuvering the steering system can adjust tension within the tension system to steer the bicycle.

A simulated bicycle brake hood attachment may be attached to handlebars of a stationary bicycle, such as Echelon, Bowflex, Keiser, Schwinn or PELETON indoor stationary bicycles, and allow the user to mimic real road bike riding positions. The simulated bicycle brake hood attachment includes a base portion for attaching to the handlebars, a post portion extending from the base portion and a head portion a top of the post portion. The post portion and the head portion provide rounded surfaces to allow a comfortable grip and provide a more ergonomic riding position and improve riding comfort.

A bicycle handlebar assembly comprises a base bar, a v-shaped stem selectively removable from the base bar, and a bicycle fork assembly. Control cables from the bicycle may be routed from the base bar into hollow diverging stem members of the v-shaped stem. The bicycle fork assembly comprises an external-steerer fork having a load-bearing member and a preload tensioning rod. The preload tensioning rod fits within a head tube of the bicycle, and a hollow space around the preload tensioning rod accommodates control cables passing from the v-shaped stem into a hollow portion of the bicycle frame. The v-shaped stem is secured against the base bar by a pair of nut plates. In some examples, an engagement portion of an accessory such as an aerobar extension assembly is configured to secure the v-shaped stem and an aerobar extension against the base bar.

An integrated bicycle control device has a handlebar portion of a bicycle handlebar assembly. The handlebar portion has a body with a gripping portion adjacent a distal end of the body and a transition portion spaced from the gripping portion. A compartment may be formed in the transition portion and an opening in the body may permit access to the compartment. An actuator is disposed near the distal end of the gripping portion. A control element and/or other elements or circuitry may be disposed within the compartment. The control device may include integrated accessory attachment structure.

A dual powered propulsion system for use with a human powered vehicle is provided. The system includes a connecting rod with a front end operatively coupled to yoke-connected forearm bars. The system also includes a splitter coupled to a rear end of the connecting rod, wherein the splitter is coupled to a first rack and a second rack that operate with a first and second pinion gear to turn a crank axle. This system supplies rotational power to the crank axle in a single rotational direction as the connecting rod is oscillated up and down and back and forth. Even though a solid connecting rod is used to transfer power from the oscillating forearm bars to the crank axle, the vehicle is steerable to the right or left as a result of the use of a carriage, on rollers, and a turning track operatively connected to the forearm bars.

A bicycle component mounting device comprises a base member, a holding member, a movable member, and a guide structure. The base member includes a mounting portion. The holding member is movably mounted to the mounting portion. The movable member is movably mounted relative to the base member to push the holding member relative to the mounting portion. The guide structure is configured to guide the holding member relative to the mounting portion in a guide direction inclined relative to a longitudinal axis in response to a movement of the movable member. The guide structure includes a recess and a protrusion. The recess is provided at one of the mounting portion and the holding member. The protrusion is configured to be disposed in the recess and provided at the other of the mounting portion and the holding member.

An integrated handlebar for a bicycle includes a handlebar and at least one integrated control device, wherein the handlebar has at least two free ends and the integrated control device includes a base engaged with at least one of the free ends, a brake lever and an electronic controller. The brake lever has a front end pivotally connected with the base and a rear end. The brake lever has a mounting portion, being located at a distance not greater than length of the brake lever from the rear end and not on the rear end. The electronic controller includes an operation member disposed on the brake lever, which includes at least one operation part adapted to be triggered by fingers of a rider to control an action of the operation member so as to drive the electronic controller to output an electronic signal to an electronic component.