One of the biggest challenges that a disabled wheelchair user faces when using a wheelchair is getting in and out of the wheelchair. The method most commonly used for getting in or out of a wheelchair is a method using a sliding board. In this method, a user lays the sliding board across a wheelchair seat and a bed and moves across by pushing his or her buttocks. However, the biggest challenge of this method is that the large size of the wheelchair wheels makes it difficult to mount the sliding board on a side surface of the wheelchair, and there is also a high risk of falling while moving. The present invention enables a wheelchair user to easily move large wheelchair wheels rearward without outside assistance by using an armrest of the wheelchair as a lever. Through the present invention, which is lightweight and enables wheelchair users to easily move a wheel rearward by themselves, disabled wheelchair users can easily get in and out of wheelchairs by themselves without outside assistance.

Embodiments described herein are directed to a wheelchair system that includes a wheelchair and an exoskeleton. The wheelchair includes a frame, a pair of armrests coupled to the frame, and a control unit. The pair of armrests movable between an attached position and a detached position. When in the attached position, each one of the pair of armrests are coupled to the frame and when in the detached position, each one of the pair of armrests is removed from the frame. The exoskeleton is communicatively coupled to the control unit via a cable extending between the exoskeleton and the control unit. The exoskeleton being releasably coupled to at least a portion of the frame of the wheelchair. The wheelchair system is translatable between a wheelchair mode and an exoskeleton mode such that, when in the exoskeleton mode, the control unit provides electrical power and control signals to the exoskeleton.

Provided is a wheel (6a) in which a disk (62) includes a ring-shaped rim (60) on which a tire (6b) is fitted, and a disk (62) having a flat circular shape and disposed on an inner circumference of the rim (60). The disk (62) includes a first rib (62a) and a second rib (62b) which extend in a radial direction of the disk (62). A width of each of the first rib (62a) and the second rib (62b) in a circumferential direction of the disk (62) increases toward an outer circumferential side of the disk (62).

A transmission apparatus for a leveraged wheelchair may include a wheelchair, a driving mechanism, a driving wheels set, and a transmission wheels set. The driving mechanism has a first tube and a second tube which are pivotally connected, and with the relative movements between the first tube and the second tube, the driving wheels set can have forward or rearward rotation so as to achieve bi-direction driving effect of the wheelchair. Also, the relative movement between the first tube and the second tube is cooperated with a flexible connecting head such that a handle of the wheelchair is adapted to be forward and rearward pulled or rotated axially so to achieve the moving and turning actions of the wheelchair with one hand.

A lift assist device preferably includes a pair of lift units and a battery. Each lift unit preferably includes a linear actuator, a lift projection, a top bracket and a bottom bracket. A screw sled extends from one side of the linear actuator. An end of a lift projection is secured to the screw sled. One end of the top bracket is attached to a top of the linear actuator. One end of a bottom bracket is attached to a bottom of the linear actuator. The top and bottom brackets will be different depending on whether they are attached to rollators, wheelchairs, motorized wheelchairs and motorized scooters. The lift assist device may be used to help lift a user from a chair adjacent the rollator, wheelchair, motorized wheelchair or motorized scooter, or when the user is seated in rollator, wheelchair, motorized wheelchair or motorized scooter.

Systems and methods of wheelchair systems enabling fine manual motion control are disclosed. In one embodiment, a wheelchair system includes a wheelchair. The wheelchair includes one or more wheels, at least one actuator coupled to the one or more wheels, a processing device, and a non-transitory, processor-readable storage medium in communication with the processing device. The non-transitory, processor-readable storage medium includes one or more programming instructions that, when executed, cause the processing device to determine a wheel torque on the one or more wheels, determine a compensation value, and actuate the at least one actuator applying the compensation value to the one or more wheels to remove at least a portion of the wheel torque such that less external force is required to physically move the powered wheelchair than when the compensation value is not applied.

Provided is a wheelchair that can be easily operated with either a right or left hand. The wheelchair according to the present invention is provided with: a right-left pair of first handrims connected to handrim spokes; a right-left pair of second handrims connected to spokes; a first rotary shaft for transmitting a first rotational force generated by rotation of the left first handrim to a right wheel; and a second rotary shaft for transmitting a second rotational force generated by rotation of the right first handrim to a left wheel, wherein a first power transmission device on a right inner shaft of a right drive mechanism meshes with a second power transmission device on the second rotary shaft, and a third power transmission device on a right outer shaft of the right drive mechanism meshes with a fourth power transmission device on the first rotary shaft.

A wheelchair configured to impart motion on one or more lower extremities of a user to inhibit inelasticity in joints of one or more lower extremities as a result of extended immobility, and to promote a more natural alignment of one or more upper extremities of the user during manipulation of the wheelchair. The wheelchair includes a seat and a backrest, at least two ground-engaging wheels, a hand mechanism assembly including a hand grip on each side of the wheelchair, and a foot mechanism assembly including a footrest on each of the wheelchair. When a force is applied to one of the hand grips, the wheels rotate for locomotion, and the foot mechanism assembly is actuated, causing the foot rest on the opposite side from the hand grip to move in an arced path, and vice versa, thereby imparting contralateral locomotion.

A rack driven human powered vehicle utilizes a rack and pinion system to provide a more efficient method of propulsion. The rack and pinion system may take the linear momentum of at least one driving rack and may transfer it to rotational momentum for at least one freewheel sprocket which may turn the wheel providing momentum for the vehicle.

A wheelchair adornment system includes a wheelchair has a pair of wheels, a pair of arm rests, a pair of leg supports, a chair and a backrest. A plurality of guards is provided and each of the guards is removably coupled to a selected point on the wheelchair. Thus, each of the guards may conceal associated parts of a user's body. A pair of fenders is provided and each of the fenders is coupled to the wheelchair. Each of the fenders is positioned over an associated one of the wheels. A canopy is removably coupled to the wheelchair configured to shade the user.