This disclosure relates generally to a mobile robotic manipulator with telepresence system which includes a chassis assembly, a tilting arm assembly, and a rotary gripper assembly. The chassis assembly includes a chassis plate which mounts plurality of drive motors coupled with plurality of omni wheels through plurality of L mounting brackets; plurality of anti-toppling arms includes a plurality of linear guides which is mounted on a C mount plate; and plurality of linear actuators is mounted to expand or retract the plurality of anti-toppling arms. The tilting arm assembly includes a bottom fixed end of a front long actuator is mounted to a large rotating plate through plurality of C clamps. The rotary gripper assembly includes a top plate of a gripper is mounted and separated by gap with a bottom plate of the gripper to place a gripper actuator on top surface of the bottom plate of the gripper.

A robotic end-effector to provide an anthropomorphic hand with a dorsal actuation system. The hand has a substantially planar palm and fingers extending from the palm and capable of flexion and extension relative to the palm. The dorsal actuation system is supported on the palm and fingers, with actuators positioned at a dorsal side of the palm and links positioned at a dorsal side of the fingers.

A remote center manipulator for use in minimally invasive robotic surgery includes a base link held stationary relative to a patient, an instrument holder, and a linkage coupling the instrument holder to the base link. First and second links of the linkage are coupled to limit motion of the second link to rotation about a first axis intersecting a remote center of manipulation. A parallelogram linkage portion of the linkage pitches the instrument holder around a second axis that intersects the remote center of manipulation. The second axis is angularly offset from the first axis by a non-zero angle other than 90 degrees.

A medical robot system, including a robot coupled to an effectuator element with the robot configured for controlled movement and positioning. The system may include a transmitter configured to emit one or more signals, and the transmitter is coupled to an instrument coupled to the effectuator element. The system may further include a motor assembly coupled to the robot and a plurality of receivers configured to receive the one or more signals emitted by the transmitter. A control unit is coupled to the motor assembly and the plurality of receivers, and the control unit is configured to supply one or more instruction signals to the motor assembly. The instruction signals can be configured to cause the motor assembly to selectively move the effectuator element and is further configured to (i) calculate a position of the at least one transmitter by analysis of the signals received by the plurality of receivers; (ii) display the position of the at least one transmitter with respect to the body of the patient; and (iii) selectively control actuation of the motor assembly in response to the signals received by the plurality of receivers.

A spatial parallel mechanism comprises a platform. Three or more legs configured for extending from a base or ground to the platform, each leg has a distal link, one or more distal joint providing one rotational degree of freedom (DOF) about a distal rotational axis, the distal joint connecting a distal end of the distal link to the platform. A proximal joint provides at least two rotational DOFs at the proximal end of the distal link. Assemblies of joints and links provide DOFs to each said leg between the proximal joint and the base or ground. The distal rotational axes of the three legs are parallel to one another.

An attachment for an industrial or farm vehicle is designed to engage, carry and unroll a round hay bale. The attachment can be adjusted to interact with hay bales of various lengths. The attachment includes a support structure with features to attach to the vehicle. A first end of a first arm is pivotably connected proximate a first end of the support structure. A first end of a second arm is pivotably connected proximate the first end of the support structure. A spacing link is pivotably connected to second ends of the first and second arms. A first hay bale spear is attached to the spacing link. A third arm has a first end pivotably connected proximate a second end of the support structure. A second hale bay spear is attached proximate to a second end of the third arm and faces toward the first hay bale spear.

A substrate transfer robot for transferring a substrate in a vacuum chamber, includes: a transfer arm platform having coupling holes, wherein link connecting members with blades are engaged at front and rear areas of the transfer arm platform and a support shaft of a lower support is inserted into the lower space of one of the coupling holes; and a first and a second transfer arm part each including an end effector for supporting the substrate, multiple transfer link arms, multiple subordinate link arms and a common link arm that are connected to each other or to the transfer arm platform, wherein, the transfer link arms include at least some of drive shafts, interlocked with transfer driving motors or speed reducers, and output shafts interlocked with the drive shafts, and wherein the end effectors are positioned at different heights from each other through using a bracket.

A parallel link mechanism includes three or more link mechanisms that couple a fixed base and an end-effector base. The end-effector base has a facing surface facing the fixed base. The link mechanisms each include a proximal-end joint, a proximal link, an intermediate joint, a distal link, and a distal-end joint. The proximal-end joint is rotatably coupled to the fixed base. The proximal link is coupled to the proximal-end joint. The intermediate joint is provided to the proximal link. The distal link is rotatably coupled to the proximal link via the intermediate joint. The distal-end joint rotatably couples the distal link to the end-effector base. The point of intersection at which the extensions of the axes of rotation of the proximal-end joints, the extensions of the axes of rotation of the intermediate joints, and the extensions of the axes of rotation of the distal-end joints intersect is the center of rotation of the end-effector base. The center of rotation of the end-effector base is positioned in a first direction with respect to the facing surface.

The present disclosure provides an exoskeleton-type wearable robot. The exoskeleton-type wearable robot includes a first fixing unit configured to be worn on the body of the wearer, a first connection unit rotatably connected to the first fixing unit, a second connection unit spaced apart from the first connection unit and connected to the first connection unit via a first link assembly, and a second fixing unit connected to the arm or the leg of the wearer and connected to the second connection unit via a second link assembly.

A joint bearing for a robot 1 which comprises a shaft 21 and at least one link element 24, 35, 36, 37, 38, 59, 60 mounted to be rotatable on shaft 21 between two axial bearings 22, 23, 43, 44, 45, 46, 54, 55, 63, 64, 69, where a resiliently compressible preloading element 33, 49, 52, 53, 56, 57, 65, 66 is provided which applies an axial preloading force to the axial bearings. A robot with at least one such joint bearing as well as a method for assembling a joint bearing for a robot are disclosed herein.