A patient transport apparatus for transporting a patient. A seat section is pivotably coupled to a support structure about a seat axis. A front wheel is operatively attached to a front strut of the support structure, and a carrier is arranged for movement relative to the support. The carrier includes a shaft defining a wheel axis, a rear wheel supported for rotation about the wheel axis, a track having a belt, and a hub supporting the shaft and the track for concurrent pivoting movement about a hub axis defined by a upright of the support structure. The hub axis extends through a plane intersecting the seat axis, fixed relative to the upright, and defining opposing first and second sides. Movement of the carrier from a chair configuration to a stair configuration simultaneously deploys the track and moves the wheel axis from the first side to the second side.

A patient transport apparatus for transporting a patient. A seat section is pivotably coupled to a support structure about a seat axis. A front wheel is operatively attached to a front strut of the support structure, and a carrier is arranged for movement relative to the support. The carrier includes a shaft defining a wheel axis, a rear wheel supported for rotation about the wheel axis, a track having a belt, and a hub supporting the shaft and the track for concurrent pivoting movement about a hub axis defined by a upright of the support structure. The hub axis extends through a plane intersecting the seat axis, fixed relative to the upright, and defining opposing first and second sides. Movement of the carrier from a chair configuration to a stair configuration simultaneously deploys the track and moves the wheel axis from the first side to the second side.

An auxiliary drive device for a wheelchair has at least one electrically driven drive wheel and a coupling mechanism for coupling the auxiliary drive device to the wheelchair. The coupling mechanism includes a movable locking element which is movably supported in the coupling mechanism. The movable locking element can be in a locking position in which it causes locking in a positive-locking manner so that the auxiliary drive device is coupled to the wheelchair and, by operation of a handle, the locking element can be moved in a release position in which uncoupling of the auxiliary drive device from the wheelchair is possible.

A device for autonomous drive of a wheel-equipped apparatus, the wheel-equipped apparatus including a drive component operationally connected to a control component adapted to control the drive component, the control component being adapted to be operated manually by a user, the device being adapted to be operationally connected to the drive component, the device having storage adapted to store at least one electric signal corresponding to at least one manual control operated by the user on the control component, and wherein the device is adapted to autonomously control the drive component, as an alternative to the control component, by way of the at least one electric signal stored in the storage.

A device for autonomous drive of a wheel-equipped apparatus, the wheel-equipped apparatus including a drive component operationally connected to a control component adapted to control the drive component, the control component being adapted to be operated manually by a user, the device being adapted to be operationally connected to the drive component, the device having storage adapted to store at least one electric signal corresponding to at least one manual control operated by the user on the control component, and wherein the device is adapted to autonomously control the drive component, as an alternative to the control component, by way of the at least one electric signal stored in the storage.

The present invention relates to a wheelchair that includes a base frame having robotic legs and a seat assembly. A pair of armrests include at least one control stick and an electronic display for operating the wheelchair. A motor receives power from rechargeable batteries and extends or retracts the robotic legs. The legs have big wheels and small wheels that assists in movement of the wheelchair, including ascending and descending a staircase. The small wheels can be raised or lowered as per requirements automatically by the motor using a sensor or manually using the control stick. The wheelchair can be operated remotely using a handheld remote-control device enabling a caretaker to remotely activate and maneuver the wheelchair. The wheelchair enables individuals who use wheelchairs to remain independent even in traditionally non-accessible spaces and offers a way for disabled, elderly, and sick individuals to retain their independence.

The present invention relates to a wheelchair that includes a base frame having robotic legs and a seat assembly. A pair of armrests include at least one control stick and an electronic display for operating the wheelchair. A motor receives power from rechargeable batteries and extends or retracts the robotic legs. The legs have big wheels and small wheels that assists in movement of the wheelchair, including ascending and descending a staircase. The small wheels can be raised or lowered as per requirements automatically by the motor using a sensor or manually using the control stick. The wheelchair can be operated remotely using a handheld remote-control device enabling a caretaker to remotely activate and maneuver the wheelchair. The wheelchair enables individuals who use wheelchairs to remain independent even in traditionally non-accessible spaces and offers a way for disabled, elderly, and sick individuals to retain their independence.

A mobility scooter control system includes a remote control console having a wireless transmitter and switches. A status detection circuit is integrated with the switches. The status detection circuit emits a pulse on a regular cycle. After the pulse passes the respective switch following a change in state of the switch, a wireless transmission is sent. A controller is electronically connected to a motor. The control system has a regular operation mode in which direction of movement and speed limit functions are responsive to instructions inputted to the controller, and, in the absence of user instruction, the controller does not instruct movement of the motor. The control system has a Sabbath operation mode in which the direction of movement and speed limit functions are responsive only to signals from the wireless transmitter, and, in the absence of user instruction, the controller instructs the motor to continuously cycle backward and forward.

A mobility cart system includes a first platform with a plurality of wheels extending therefrom and configured to engage with a ground surface; a first control console with a first support attached to and extending from the first platform; a first seat attached to and extending from the first platform; and a power source to provide traversing movement of the first platform via the plurality of wheels; the first platform is to support a first user.

A mobility cart system includes a first platform with a plurality of wheels extending therefrom and configured to engage with a ground surface; a first control console with a first support attached to and extending from the first platform; a first seat attached to and extending from the first platform; and a power source to provide traversing movement of the first platform via the plurality of wheels; the first platform is to support a first user.