The present invention relates to a straddle-type vehicle provided with: a front wheel; a rear wheel; an electrical component box that houses a battery; electrical components such as a relay connected to the battery; and electrical component attachment parts with which the electrical components are attached to the electrical component box, wherein the electrical component box is made of a resin, and at least a bank angle sensor is housed in the electrical component box.

An electric vehicle transmission mechanism which is applied to drive a chain wheel of an electric vehicle is provided. The electric vehicle transmission mechanism includes a transmission shaft, an output shaft, a lower bearing and an upper bearing. The transmission shaft is connected to the chain wheel and has a transmission axial direction, and the transmission shaft includes a transmission portion. The output shaft includes an output portion engaged with the transmission portion, and the output shaft has an output axial direction substantially perpendicular to the transmission axial direction. The lower bearing is sleeved on the output shaft. The upper bearing is sleeved on the output shaft and located between the lower bearing and the output portion.

Herein is disclosed a straddle-ridden vehicle frame stiffener comprising a support structure for stiffening the straddle-ridden vehicle frame, the support structure comprising a first side; and a second side, adjacent to the first side; a first mounting element for removably mounting the support structure to the straddle-ridden vehicle frame, the first mounting element being attached to the first side; a second mounting element for removably mounting the support structure to the straddle-ridden vehicle frame, the second mounting element being attached to the second side; and wherein the first side and the second side are rigidly connected to one another.

Herein is disclosed a straddle-ridden vehicle frame stiffener comprising a support structure for stiffening the straddle-ridden vehicle frame, the support structure comprising a first side; and a second side, adjacent to the first side; a first mounting element for removably mounting the support structure to the straddle-ridden vehicle frame, the first mounting element being attached to the first side; a second mounting element for removably mounting the support structure to the straddle-ridden vehicle frame, the second mounting element being attached to the second side; and wherein the first side and the second side are rigidly connected to one another.

An adjustable bottom bracket mechanism, comprising: a bottom bracket, an axial connection portion and a mounting portion. The bottom bracket includes at least one shaft through hole and is configured for connection of a seat tube. A lengthwise extension direction of the seat tube is defined as a first direction. The axial connection portion includes at least one axial through hole and axially corresponds to the at least one shaft through hole. The mounting portion is connected to the axial connection portion and adjustably fixedly connected to the bottom bracket in a first position or a second position. When the mounting portion is in either of the first and the second position, axes of the at least one shaft through hole and the at least one axial through hole are located on the first direction.

An adjustable bottom bracket mechanism, comprising: a bottom bracket, an axial connection portion and a mounting portion. The bottom bracket includes at least one shaft through hole and is configured for connection of a seat tube. A lengthwise extension direction of the seat tube is defined as a first direction. The axial connection portion includes at least one axial through hole and axially corresponds to the at least one shaft through hole. The mounting portion is connected to the axial connection portion and adjustably fixedly connected to the bottom bracket in a first position or a second position. When the mounting portion is in either of the first and the second position, axes of the at least one shaft through hole and the at least one axial through hole are located on the first direction.

A saddle-ride type vehicle in which a rear frame and a rear suspension can be attached to a vehicle body frame with a small number of parts and with a simple structure. The saddle-ride type vehicle includes a rear frame fastened to a frame portion of a rear portion of a vehicle body frame, and a rear suspension disposed at a rear portion of the vehicle body frame. The vehicle body frame includes a tubular member inserted into the frame portion in a vehicle width direction and fixed to the frame portion. The rear frame is fastened by a frame fastener to a frame fixation portion provided at an inner end portion of the tubular member in the vehicle width direction, and the rear suspension is connected to a suspension connecting portion provided at an outer end portion of the tubular member in the vehicle width direction.

A vehicle with a Geo-Fenced Ride Control System including: one or more battery modules including one or more battery cells; one or more processors operably connected to the one or more battery cells to control vehicle performance; and a Global Positioning System (GPS) or cellular network receiver configured to determine location of the vehicle; wherein the one or more processors communicates with a remote sever to determine a plurality of available vehicle performance settings for the vehicle based on the location of the vehicle. The vehicle further includes a user input interface configured to receive user input including selection of the vehicle performance setting form the plurality of available vehicle performance settings based on the geographic location of the vehicle.

A bicycle includes a front wheel, a rear wheel, a frame comprising a main frame section and an articulated frame section, the articulated frame section comprising: a lower arm rotatably supported on a first axis by the main frame section, an upper frame link, the rotatably supported on a second axis by the main frame section, an upper arm rotatably connected to the upper frame link on a third axis, an upper butt joint rotatably connected to the upper frame link and the upper arm on the third axis, and a lower butt joint rotatably connected to the main frame portion and the lower arm on the first axis, and a shock absorber having a first end rotatably supported on a fourth axis by the main frame portion and a second end connected to a fifth axis from the upper butt joint and the lower butt joint ndung is held rotatable.

Systems and methods for collecting electric scooters are described herein. In some embodiments, the systems and methods facilitate a “snaking” configuration of attaching, coupling, or fixing multiple electric scooters to one another. The snaking configuration enables multiple electric scooters to be collected together and moved to various locations, such as locations where the electric scooters can be rented, serviced, and so on. Further, the systems and methods enable any electric scooter to act as a collecting scooter, and thus a scooter share service or other fleet of scooters can manage the collection and provisioning of scooters in a location without special vehicles or equipment, among other benefits.