The present disclosure includes methods of operating a wheelchair configured to reposition an occupant between a lowered and a raised position. The wheelchair can include a frame, a seat moveable relative to the frame, a drive wheel, one or more pairs of arm assemblies, and one or more sensors. The arm assembly includes a wheel configured to move from a first spatial location when the wheelchair is operating on flat, level ground to a second spatial location that is different than the first spatial location. Arm limiters can selectively engage the arm assembly based on at least one of a seat position, position of the arm assembly, and surface conditions of ground surface. The arm limiters can limit the range of motion of the arm assembly and sometimes other operational aspects of the chair. The methods adjust the maximum operational speed of the wheelchair when the seat is in an elevated position based on sensor data relating to one or more of the arm limiter position and the position of the frame.

A configurable assistive device comprising: a platform; at least three wheels; and, at least three independent leg mechanisms, each respective leg mechanism coupled to the platform and a respective one of the at least three wheels, each respective leg mechanism configured to move the platform relative to the respective wheel for positioning the platform at an elevation and for inclining the platform to an inclination to configure the assistive device into one of a plurality of configurations.

An electric mobility vehicle including a mobility body, wheels provided at both sides in a vehicle width direction of the mobility body, and a sensor attached to the mobility body. An area which is located outside the wheel in the vehicle width direction, and at least one of a part of the wheel, and a part of the fender of the wheel are positioned within a detection area of the sensor.

A chair for individuals with mobility challenges and a method of using such a chair. The chair may be adjusted relative to a horizontal work surface disposed a distance above a floor by placing a base of the chair on the floor a first distance away from an edge of the work surface; rotating a seat of the chair relative to the base from a neutral position to a first angled position. The individual sits in the seat when in the first angled position and the seat is then rotated relative to the base and back to the neutral position. An actuator is then engaged to enable the seat to slide linearly relative to the base and toward the work surface. The seat is able to be rotated and moved linearly relative to the work surface adjusting the position of the base on the floor.

Several embodiments of wheeled vehicles, such as wheelchairs, that are adapted to traverse obstacles are disclosed. The wheeled vehicles include a frame, drive wheels, front anti-tip wheels positioned in front of the drive wheels, and rear anti-tip wheels positioned behind the drive wheels. One exemplary vehicle includes front anti-tip wheels supported by rigid arms that are fixed to the frame and drive assemblies that are independently suspended from the frame. Another exemplary vehicle includes a linkage that links the front and rear anti-tip wheels, such that movement of one of the front anti-tip wheel or the rear anti-tip wheel relative to the frame causes movement of the other wheel relative to the frame.

A wheelchair assembly including a control device, a power base, and a plurality of leg modules coupled to the power base is disclosed. Each of a first, a second, and a third leg module may include an upper leg assembly and a lower leg assembly. Each lower leg assembly may include a knee joint and a foot joint and each lower leg assembly may rotatably couple to each upper leg assembly at the knee joint. A knee wheel located at the knee joint of each lower leg assembly, may include an omni-directional wheel, and may be selectively drivable. A foot wheel located at the foot joint of each lower leg assembly may be selectively drivable. The control device, based on a selectable mode of operation, may selectively position at least one of the knee wheel or the foot wheel associated with each respective leg module relative to a surface.

Wheeled vehicles, such as wheelchairs, that are adapted to traverse obstacles are provided. The wheeled vehicles include a frame, drive wheels, front anti-tip wheels positioned in front of the drive wheels and rear anti-tip wheels positioned behind the drive wheels. One exemplary vehicle includes front anti-tip wheels supported by rigid arms that are fixed to the frame and drive assemblies that are independently suspended from the frame. Another exemplary vehicle includes a linkage that links the front and rear anti-tip wheels, such that movement of one of the front or rear anti-tip wheel relative to the frame causes movement of the other wheel relative to the frame.

A mobile device includes a body, a motor, a transmission assembly and two driven components. The motor and the transmission assembly are disposed at the body. The transmission assembly includes a differential, two shafts and two stoppers. The differential is coupled to the motor. The two shafts are respectively coupled to the two opposite sides of the differential. The two stoppers are respectively disposed corresponding to the two shafts. The two driven components are respectively connected to the two shafts. When one of the two shafts is locked by the corresponding stopper, the motor may still drive the other shaft and the driven component connected thereto to rotate relative to the body through the differential. A transmission assembly is also provided.

In one embodiment, a wheelchair includes a drive wheel, a motor coupled to the drive wheel, and a user input device. The motor, in one embodiment, is configured to rotate the drive wheel. The user input device may be configured to send a signal for controlling a motor parameter. The wheelchair, in one embodiment, includes a caster wheel and a castor sensor configured to sense a caster angle. In one embodiment, a controller is configured to receive the signal for controlling the motor parameter and a signal from the caster sensor and to determine a first turn rate parameter of the wheelchair based upon the received signal from each of the input device and the caster sensor.

Disclosed is a wheelchair power apparatus for electronic driving conversion. The wheelchair power apparatus for electronic driving conversion includes: an electronic module combined with a combining means of a manual wheelchair, wherein the electronic module includes: a driving wheel in which an in-wheel motor is mounted; an operation handle located directly above the driving wheel; a connector connected directly below the operation handle; a steering housing mounted directly below the connector in such a way that one side of the connector can be moved forwards or backwards inside the steering housing; a combining unit mounted directly below the steering housing and combined with a coupling means of a wheelchair; a battery mounted at the front of the combining unit; and strut supports and collapsible bars mounted at right and left sides of the driving wheel, so that the manual wheelchair is converted into an electronic wheelchair.