The present disclosure discloses a two-wheeled self-balancing robot which solves the technical problems in the prior art that the robot can only travel on a flat ground and its driving environments are limited by making improvements in its mechanical structure. The two-wheeled self-balancing robot comprises a vehicle body with wheels mounted on both sides thereof. The vehicle body comprises a parallelogram frame which can deform tiltedly. The vehicle body is provided with a stage, and the stage is hinged with the parallelogram frame. The parallelogram frame is provided with a first motor. The first motor drives the parallelogram frame to deform tiltedly according to road conditions so as to always keep the stage horizontal. The two-wheeled self-balancing robot according to the present disclosure can adapt to complicated road conditions, and its stage always keeps horizontal such that the object carried is not prone to fall off.

Various embodiments of an apparatus for changing the in-air pitch and/or roll of a land craft are described herein. The apparatus may include a steering input mechanism, a support structure, and an articulator. The apparatus may include one or more of a pitch-forward input mechanism, a pitch-back input mechanism, a roll-right input mechanism, and a roll-left input mechanism. The vehicle may include a set of wheels on which the vehicle travels over ground. The steering input mechanism may receive steering inputs from a driver of the vehicle. The steering input mechanism may receive pitch and roll control inputs from the driver. The support structure may connect the steering input mechanism to the vehicle, at least one of the wheels, or the vehicle and the at least one of the wheels. The articulator may rotatably connect the steering input mechanism to the support structure.

Various embodiments of an apparatus for changing the in-air pitch and/or roll of a land craft are described herein. The apparatus may include a steering input mechanism, a support structure, and an articulator. The apparatus may include one or more of a pitch-forward input mechanism, a pitch-back input mechanism, a roll-right input mechanism, and a roll-left input mechanism. The vehicle may include a set of wheels on which the vehicle travels over ground. The steering input mechanism may receive steering inputs from a driver of the vehicle. The steering input mechanism may receive pitch and roll control inputs from the driver. The support structure may connect the steering input mechanism to the vehicle, at least one of the wheels, or the vehicle and the at least one of the wheels. The articulator may rotatably connect the steering input mechanism to the support structure.

A tilting vehicle includes a frame and a front wheel coupled to the frame. A rear wheel is coupled to the frame and positioned rearward of the front wheel in a longitudinal direction. A seating area includes at least one seat positioned to support a rider between the front wheel and the rear wheel. A gyroscopic rider assist device is provided within an enclosure behind the seating area and above the rear wheel.

A tilting vehicle includes a frame and a front wheel coupled to the frame. A rear wheel is coupled to the frame and positioned rearward of the front wheel in a longitudinal direction. A seating area includes at least one seat positioned to support a rider between the front wheel and the rear wheel. A gyroscopic rider assist device is provided within an enclosure behind the seating area and above the rear wheel.

An energy storage apparatus including a spherical rotating member having permanent magnets and uniquely-identifiable location-defining elements, a plurality of coils, a controller operably coupled to the plurality of coils, a power source, and a location sensing apparatus operable to detect the plurality of location-defining elements. The controller may compare time-sequential information from the location sensing apparatus to determine a rotational axis and a rotational speed of the rotating member, operate the coils to change the rotational axis speed of the rotating member, increase energy stored by the rotating member by increasing the rotational speed by operating the coils to generate magnetic fields that interact with the permanent magnets, and withdraw energy by operating the coils to generate magnetic fields that interact with the magnetic fields of the permanent magnets to produce induced current in the coils and directing the induced current to a power delivery location.

An energy storage apparatus including a spherical rotating member having permanent magnets and uniquely-identifiable location-defining elements, a plurality of coils, a controller operably coupled to the plurality of coils, a power source, and a location sensing apparatus operable to detect the plurality of location-defining elements. The controller may compare time-sequential information from the location sensing apparatus to determine a rotational axis and a rotational speed of the rotating member, operate the coils to change the rotational axis speed of the rotating member, increase energy stored by the rotating member by increasing the rotational speed by operating the coils to generate magnetic fields that interact with the permanent magnets, and withdraw energy by operating the coils to generate magnetic fields that interact with the magnetic fields of the permanent magnets to produce induced current in the coils and directing the induced current to a power delivery location.

An augmented traction system for a two-wheeled vehicle comprising a CMG (control moment gyroscope) system including a plurality of CMGs to provide a first torque vector to decrease a roll angle of a turn of the vehicle and to increase force on one or more of the tires of the vehicle on a road surface, a steering system for the vehicle, the steering system to determine a steering control for the turn of the vehicle at a particular vehicle speed and roll angle, based on sensor data, and an aerodynamic control system to actuate one or more aerodynamic elements of the vehicle, the one or more aerodynamic elements to provide a second torque vector to decrease the roll angle of the vehicle.

An augmented traction system for a two-wheeled vehicle comprising a CMG (control moment gyroscope) system including a plurality of CMGs to provide a first torque vector to decrease a roll angle of a turn of the vehicle and to increase force on one or more of the tires of the vehicle on a road surface, a steering system for the vehicle, the steering system to determine a steering control for the turn of the vehicle at a particular vehicle speed and roll angle, based on sensor data, and an aerodynamic control system to actuate one or more aerodynamic elements of the vehicle, the one or more aerodynamic elements to provide a second torque vector to decrease the roll angle of the vehicle.

A self-balancing bicycle system is provided by the present disclosure. The system includes a bicycle, a sensor coupled to the bicycle, a steering control assembly comprising an actuator and being coupled to the bicycle and configured to adjust a steering angle of a front tire of the bicycle, and a controller coupled to the sensor and configured to receive a value from the sensor. The controller is further coupled to the steering control assembly and further configured to adjust the steering angle based on the value.