Examples of the present disclosure relate to a bicycle configured to easily and efficiently adapt for riders of different sizes while providing both balance bike and pedal bike functionality. An exemplary bicycle is a children's bicycle designed and developed to grow with a child. An exemplary bicycle is configured to enable utility adjustments to a front assembly, among other components, which creates a setup that comfortably accommodates either smaller riders or larger-sized riders. The bicycle is adjustable with minimal effort and without tools, enabling re-configuration on the fly. Further disclosed is an exemplary training wheel device that is attachable to an exemplary bicycle. An exemplary training wheel device extends functionality of the bicycle and assist with training a young child to ride the bicycle.

Examples of the present disclosure relate to a bicycle configured to easily and efficiently adapt for riders of different sizes while providing both balance bike and pedal bike functionality. An exemplary bicycle is a children's bicycle designed and developed to grow with a child. An exemplary bicycle is configured to enable utility adjustments to a front assembly, among other components, which creates a setup that comfortably accommodates either smaller riders or larger-sized riders. The bicycle is adjustable with minimal effort and without tools, enabling re-configuration on the fly. Further disclosed is an exemplary training wheel device that is attachable to an exemplary bicycle. An exemplary training wheel device extends functionality of the bicycle and assist with training a young child to ride the bicycle.

A folding scooter frame (100) includes a front vehicle frame (110), a rear vehicle frame (120) and a folding seat support frame (8). The front vehicle frame (110) and the rear vehicle frame (120) are pivotally connected. The folding seat support frame (8) includes a linkage rod (81) and a frame body, wherein a front end of the linkage rod (81) is connected with the front vehicle frame (110), a rear end of the linkage rod (81) is pivotally connected with the frame body, and the linkage rod (81) is able to swing as the front vehicle frame (110) is folded and thus drives the frame body to fold. The folding scooter frame (100) has the advantages of quick and convenient folding operations.

A folding scooter frame (100) includes a front vehicle frame (110), a rear vehicle frame (120) and a folding seat support frame (8). The front vehicle frame (110) and the rear vehicle frame (120) are pivotally connected. The folding seat support frame (8) includes a linkage rod (81) and a frame body, wherein a front end of the linkage rod (81) is connected with the front vehicle frame (110), a rear end of the linkage rod (81) is pivotally connected with the frame body, and the linkage rod (81) is able to swing as the front vehicle frame (110) is folded and thus drives the frame body to fold. The folding scooter frame (100) has the advantages of quick and convenient folding operations.

An armrest handlebar and a bicycle handlebar assembly having the armrest handlebar are disclosed. The bicycle handlebar assembly includes a steering handlebar, the armrest handlebar, and two armrest pads. The steering handlebar is pivotally engaged with a frame. The armrest handlebar includes two extending tubes which are engaged with the steering handlebar. Each of the extending tubes includes a combining segment, a lifting segment, a leaned segment, and a holding segment which are sequentially disposed. The lifting segment is raised above the combining segment at a first angle, and the leaned segment is raised above the combining segment at a second angle. A curved surface is formed by recessing from a top surface of each of the leaned segments. Each of the two armrest pads is engaged with the steering handlebar and has a concave surface for a rider to lean on.

An armrest handlebar and a bicycle handlebar assembly having the armrest handlebar are disclosed. The bicycle handlebar assembly includes a steering handlebar, the armrest handlebar, and two armrest pads. The steering handlebar is pivotally engaged with a frame. The armrest handlebar includes two extending tubes which are engaged with the steering handlebar. Each of the extending tubes includes a combining segment, a lifting segment, a leaned segment, and a holding segment which are sequentially disposed. The lifting segment is raised above the combining segment at a first angle, and the leaned segment is raised above the combining segment at a second angle. A curved surface is formed by recessing from a top surface of each of the leaned segments. Each of the two armrest pads is engaged with the steering handlebar and has a concave surface for a rider to lean on.

A motorcycle handlebar riser having upper and lower members. The upper member has a proximal end and a distal end. A first vertical plane laterally bisects the upper member. The upper member distal end has a bar bed to hold a handlebar. The upper member proximal end has a generally flat first attachment face oriented at a predetermined angle relative to the first vertical plane. The lower member has a proximal end and a distal end that releasably attaches to the motorcycle front fork. A second vertical plane laterally bisects the lower member. The lower member proximal end has a generally flat second attachment face oriented at a predetermined angle relative to the second vertical plane. The riser assembles in a first configuration when the attachment faces are axially aligned in one orientation and assembles in a second configuration when the attachment faces are axially aligned in a different orientation.

A motorcycle handlebar riser having upper and lower members. The upper member has a proximal end and a distal end. A first vertical plane laterally bisects the upper member. The upper member distal end has a bar bed to hold a handlebar. The upper member proximal end has a generally flat first attachment face oriented at a predetermined angle relative to the first vertical plane. The lower member has a proximal end and a distal end that releasably attaches to the motorcycle front fork. A second vertical plane laterally bisects the lower member. The lower member proximal end has a generally flat second attachment face oriented at a predetermined angle relative to the second vertical plane. The riser assembles in a first configuration when the attachment faces are axially aligned in one orientation and assembles in a second configuration when the attachment faces are axially aligned in a different orientation.

A headset assembly system for a bicycle is provided having a handlebar stem (1), radially fastenable by tightening to a fork tube (2), rotatable by headset bearings (7) with respect to a head tube (3) wherein the headset bearings are fastened (7); a retaining flange (4), radially fastenable by tightening to the fork tube (2); a thrust ring (5), axially movable along the fork tube (2); such that the retaining flange (4) and the thrust ring (5) are configured to contact each other by a ramp (6) which relates a rotation with a movement relative to each other; the thrust ring (5) is arranged such that, when the thrust ring (5) is rotated around the fork tube (2) with the retaining flange (4) fastened to the fork tube (2), the thrust ring (5) moves with respect to the retaining flange (4) pushing the stem (1) against the headset bearings (7).

A headset assembly system for a bicycle is provided having a handlebar stem (1), radially fastenable by tightening to a fork tube (2), rotatable by headset bearings (7) with respect to a head tube (3) wherein the headset bearings are fastened (7); a retaining flange (4), radially fastenable by tightening to the fork tube (2); a thrust ring (5), axially movable along the fork tube (2); such that the retaining flange (4) and the thrust ring (5) are configured to contact each other by a ramp (6) which relates a rotation with a movement relative to each other; the thrust ring (5) is arranged such that, when the thrust ring (5) is rotated around the fork tube (2) with the retaining flange (4) fastened to the fork tube (2), the thrust ring (5) moves with respect to the retaining flange (4) pushing the stem (1) against the headset bearings (7).