In a robotic medical system comprising a staging kinematic chain coupled to a plurality of independently articulable robotic arms capable of motion with one or more degrees of freedom, a first configuration of robotic arms may be determined based on a first inverse kinematic model including the robotic arms and assuming a static staging kinematic chain. The first configuration may effectuate desired poses of instruments coupled to the robotic arms. A set of control parameter values associated with the robotic arms may be determined based on the first configuration, and, when a determined control parameter value falls outside a corresponding control parameter range, a staging kinematic chain pose and a second configuration of the robotic arms to effectuate the desired poses of the instruments may be determined. The second configuration is determined using a second inverse kinematic model that includes the robotic arms and assumes a mobile staging kinematic chain.

The present disclosure discloses a five-degree-of-freedom hybrid robot with rotational supports. A first and a second fixed shaft seats are rotatably connected to a first and a second rotational support through a hinge, respectively. One end of a first length adjustment device runs through the first rotational support, and the other end is fixedly connected to a moving platform. One end of each of the second and third length adjustment devices runs through the first rotational support and is then connected to the moving platform, respectively. Middle portions of the first, second and third length adjustment devices are each hinged onto the first rotational support. One end of a fourth length adjustment device runs through the second rotational support and is connected to the moving platform. Middle portion of the fourth length adjustment device is hinged onto the second rotational support.

An exoskeleton mechanism according to the present disclosure includes: a fixed frame positioned to correspond to an upper physique; a rotatable frame positioned to correspond to a lower physique and coupled to the fixed frame by a hinge unit to be rotatable in the vertical direction; a support frame for supporting a terminal; a first motor mounted to the fixed frame and connected to the rotatable frame to drive the rotatable frame to rotate in the vertical direction; motors mounted to the rotatable frame and connected to the support frame to drive the support frame to rotate in the vertical direction and in the horizontal direction and rotate around an axis (roll axis) of the lower physique; links for connecting the first motor and the rotatable frame; and links for connecting the motors and the support frame.

A parallel kinematics robot includes a base and an end effector movable in relation to the base. A first actuator is attached to the base and connected to the end effector via a first kinematic chain including a first drive arm, a first rod, a first joint between the first drive arm and the first rod, and a second joint between the first rod and the end effector. A second actuator is attached to the base and connected to the end effector via a second kinematic chain including a second drive arm, a second rod, a third joint between the second drive arm and the second rod, and a fourth joint between the second rod and the end effector. A third actuator is attached to the base or to the first drive arm, and connected to the end effector via a third kinematic chain including a first gear wheel and a second gear wheel, the first and second gear wheels being journalled in bearings to the end effector and intermeshing with each other. One element of the third kinematic chain constitutes a kinematic pair with at least one element of the first kinematic chain. A kinematic chain responsible for a translational movement of the end effector is utilized as a support structure for a kinematic chain responsible for a rotational movement of the end effector.

A system for machining a workpiece. The system includes a rotatable frame mounted to a base and arms which can translate relative to the rotatable frame. The arms are attached directly or indirectly to a machining tool which can be moved to various points around the workpiece and include tools for various machining operations.

An industrial robot with parallel kinematics includes a robot base, an effector carrier receiving an effector, a first actuating arm, a second actuating arm, and a third actuating arm, wherein each actuating arm is driven at one end and is received on the robot base and is movably connected with its other end to the effector carrier. The actuating arms are adapted to move the effector carrier translationally in three dimensions in space relative to the robot base. The first actuating arm and the second actuating arm are connected to the effector carrier via lower arm joints. All lower arm joints of the first and second actuator arms lie in an effector carrier plane. The effector carrier is secured against rotation about a z-axis perpendicular to the effector carrier plane by the third actuating arm.