This specification describes an adaptive robotic nursing assistant for physical tasks and patient observation and feedback. In some examples, the adaptive robotic nursing assistant includes an omni-directional mobile platform; a footrest on the omni-directional mobile platform; a handlebar located above the footrest such that a user standing on the footrest can grasp the handlebar; a display above the handlebar and at least one user input device; a robot manipulator comprising a robotic arm and an end effector on the robotic arm; and a control system coupled to the omni-directional mobile platform, the control system comprising at least one processor and memory storing executable instructions for the at least one processor to control the omni-directional mobile platform.

A motorcycle stand to lift and support a tyre of a motorcycle or motor scooter off the ground includes: a frame having first and second posts to extend along each side of a motorcycle wheel, and an interconnecting member extending transversely relative to the first and second posts; first and second motorcycle stand wheels coupled to ends of the first and second arms respectively and arranged for placement on opposite sides of the motorcycle and coaxial and aligned with the major axis parallel with the axes of the motorcycle wheels; a third motorcycle stand wheel mounted to the interconnecting member, and a self-engaging latching arrangement coupled with a respective frame engaging bracket, where at least one of each bracket and latching arrangement is supported on each of the first and second posts to engage mounting members provided on a frame or suspension members of the motorcycle or motor scooter.

The invention relates to a wheel assembly for a patient support apparatus comprising a fixed portion, a pivoting portion attached to the fixed portion and a wheel operatively connected to the pivoting portion, the wheel, which can be motorized, being movable between a first deployed position and a second retracted position. The wheel assembly has a spring assembly for urging the wheel in the first deployed position and an actuator to raise the wheel in the second retracted position. The invention also relates to a control handle for a motorized bed comprising a handle member having an actuatable trigger for controlling propelling of the bed, the handle member further comprising a user interface configured for providing bed information to the operator.

A surgical robotic system includes a robotic arm cart for supporting a robotic arm, and a docking station configured to be secured to an operating room floor around a surgical table. The robotic arm cart has a plurality of legs having wheels for facilitating movement of the robotic arm cart along the floor of the operating room. The robotic arm cart is configured to transition from an enlarged footprint state to a reduced footprint state. When the robotic arm cart is in the reduced footprint state, the robotic arm cart may be connected to the docking station to provide stability to the robotic arm cart.

An electric walking assisting vehicle configured such that in accordance with operating amounts acting on an operation part, driving of driving motors is controlled and includes an inclination detector which detects inclination of a vehicle body in a forward-backward direction, and on flat land where inclination is less than a threshold, with an operation origin of the operation part as a center, the driving motors are controlled to generate torque in a forward direction by operation of pushing the operation part forward and to generate torque in a backward direction by operation of pulling the operation part backward, on an uphill road on which the inclination is the threshold value or more, the operation origin is shifted to an pulling operation side, and on a downhill road on which the inclination is the threshold value or more, the operation origin is shifted to a pushing operation side.

A robot is provided, the robot comprising a body carrying a first drive arrangement, a second drive arrangement and a stabiliser. The robot further comprises actuators operable to cause relative movement of the first drive arrangement, the second drive arrangement and the stabiliser, and to drive the first and the second drive arrangements. The robot is arrangeable in first, second and third configurations each having static stability. In the first configuration, the stabiliser and the first drive arrangement are arranged to contact the ground. In the second configuration, the stabiliser and the second drive arrangement are arranged to contact the ground. In the third configuration, the first and the second drive arrangements are arranged to contact the ground. No other ground contacting point is involved in conferring said static stability in said configurations.

A motorized apparatus includes an articulated body assembly, a plurality of wheels coupled to the articulated body assembly, and at least one maintenance device coupled to the articulated body assembly. The articulated body assembly includes a first body and a second body. The articulated body assembly includes a joint coupling the first body to the second body. The first body is pivotable relative to the second body about a pivot axis extending through the joint. At least one wheel is transitionable between a first position and a second position. The motorized apparatus also includes a motor drivingly coupled to the plurality of wheels and configured to move the articulated body assembly relative to a surface. The motorized apparatus further includes at least one magnet coupled to the at least one wheel.

An all-terrain load transport system including a cylindrical first base member and at least three pairs of arms is provided. A handle is removably attached to an attachment member disposed on the cylindrical first base member. The cylindrical first base member defines a space for receiving at least one piece of accessory equipment. Each pair of the three pairs of arms defines a wheel support assembly at an end of each pair distal from an outer periphery of the cylindrical first base member. The three pairs of arms are detachably attached to the outer periphery of the cylindrical first base member. The wheel support assembly includes a cylindrical second base member defining a space for receiving a spherical wheel. The spherical wheel moves omnidirectionally within the defined space. Roller bearings positioned along an inner periphery of the cylindrical second base member facilitate the omnidirectional movement of the spherical wheel.

The improved mobile robot utilizes a cooperative wheeled support arrangement having a unique axle design that preferably cooperates with a base support module. A tri-axle is preferably used to support at least one omni-wheel on each axle section. Multiple omni-wheels on each section can be used for higher load applications. The tri-axle is of a fixed design and each wheel pivots on the individual axle section. Preferably, the axle sections are welded to each other.

The invention relates to a driverless transport vehicle for moving a semi-trailer. The driverless transport vehicle comprises a coupling device for automatically coupling the driverless transport vehicle to a kingpin of the semi-trailer. The invention also relates to a method for moving a semi-trailer using a driverless transport vehicle.