A transport apparatus has a mobile chassis, a lifting mechanism, two armpit supports structured and operated mirror-symmetrical to one another, and two seat assemblies. The lifting mechanism includes a lifting arm for assembling a chest rest and two lifting racks, and a linear actuator driving the lifting arm to pivot upward or downward. The armpit supports are assembled on the lifting racks and transversely extend toward a rear of the mobile chassis. The seat assemblies are assembled on the mobile chassis. Each of the seat assembly has a seat plate driven to rotate by a drive motor to form a seat. The weak person can be moved directly by the transport apparatus with voice command or with a remote control. Since the weak person is not moved by the care workers, the weak person can be moved in an easier and safer way.

A motorized mobile system includes a human machine interface (HMI) to provide control instructions to the system. A controller in the system receives the control instructions and generates a control signal, wherein the generated control signal causes one or more components of the motorized mobile system to respond. One or more sensors generate health data related to a user, wherein the health data is stored in a secure memory connected to the controller, and wherein the stored user health data is used to bias the control signal for the motorized mobile system.

Embodiments of the present disclosure include 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, and one or more pairs of arm assemblies. The arm assembly includes a wheel configured to move from a first spatial location when the wheel chair is operating on flat, level ground to a second spatial location that is different than the first spatial location. Arm limiters that can selectively engage the arm assembly dependent on the position of the arm assembly and surface conditions of ground and can limit the range of motion of the arm assembly and sometimes other operational aspects of the chair.

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 powered wheelchair is operated by sensor-based control pads that include force transducers to produce a variable output signal that is proportional to a varying force applied. The control pad provides an analog-type output that provides a variable speed signal to a controller to operate the wheelchair at a variable speed in both forward/reverse directions and in right or left turning directions.

A mobility device (1) comprising: a main frame (3), drive wheel swing arms (5) pivotally connected to the main frame (3), drive wheels (7) connected to a respective one of the drive wheel swing arms (5), wheel motors, each wheel motor being configured to drive a respective drive wheel (7), a rear wheel swing arm (9) pivotally connected to the main frame (3), a rear wheel (11) connected to the rear wheel swing arm (9), and an actuating device configured to control a rear wheel swing arm angle between the rear wheel swing arm (9) and the main frame (3) independently of control of the wheel motors.

A method includes receiving sensor data relating to an environment from a plurality of mobility deices, determining locations of one or more points of accessibility within the environment based on the sensor data, creating an environment map based on the sensor data, and transmitting the environment map to a mobility device. The environment map includes the one or more points of accessibility.

A chassis for a mobility aid, the mobility aid including at least one base two lateral walls, and at least one connecting element which connects the two lateral walls. The chassis includes a plurality of positioning aids for each lateral wall, a bracket that can be connected to one lateral wall in at least three different configurations, and a drive unit that is connected to each bracket, wherein a bracket configuration on the lateral walls determines the type of drive for the mobility aid.

A powered pedestrian apparatus is provided having two vertical panels, two rotatably connected articulating arms capable of rotating about a center point, a vertical lifting device located within said panels attached to said arms, and a foot platform wherein one or more of an electric motor, front tires and caster wheels enable movement of the powered pedestrian apparatus.

A moving device adapted to be actuated by a prime mover is disclosed. The moving device allows a caregiver to ride thereon. The moving device comprises a vehicle body and a plurality of rotors. The vehicle body includes a first frame portion and a second frame portion. The first frame portion allows the caregiver to ride thereon and the second frame portion allows a care receiver to ride thereon. The plurality of rotors are provided on the first frame portion and are rotatable in accordance with movement of the vehicle body. A wheel base defined by the plurality of rotors is constant. The second frame portion is provided on the first frame portion so as to be movable in accordance with a motion of the caregiver riding on and getting off the first frame portion.