A link actuation apparatus includes: a parallel link mechanism including a proximal-side link hub, a distal-side link hub, and three or more link mechanisms each coupling the distal-side link hub to the proximal-side link hub such that a posture of the distal-side link hub can be changed relative to the proximal-side link hub; posture control drive sources; and a control device. The control device includes an abnormality detector including: a measurement section configured to measure a predetermined state value which is affected by abnormality in revolute pair parts of a link actuation apparatus body constituted by the parallel link mechanism and the posture control drive sources; and a determination section configured to determine if any of the revolute pair parts has abnormality in on the basis of a measurement result obtained by the measurement section. For example, the measurement section measures rigidity, or driving torque or the like.

A hip joint mechanism includes: a hip joint frame; an upper leg movably connected to the hip joint frame; a hip actuator configured to drive the hip joint frame to rotate; two upper leg actuators mounted on the hip joint frame; two transmission mechanisms configured to transmit motion from the two upper leg actuators to the upper leg, wherein each of the upper leg actuators comprises a casing connected to the hip joint frame, and an output shaft connected to one corresponding transmission mechanism, each of the two transmission mechanisms comprises an output end; and three connecting mechanisms, wherein the output ends and the hip joint frame are movably connected to the upper leg through the three connecting mechanisms, the three connecting mechanisms are arranged at three vertices of a triangle.

A head mechanism includes a base connectable to a body of a robot, a mounting member arranged above the base, a connecting member rotatably connected to the base and the mounting member. The connecting member, together with the mounting member, is rotatable relative to the base about a first axis, and the mounting member is rotatable relative to the connecting member about a second axis. The first axis and the second axis extend in different directions. The head mechanism further includes two first actuating mechanisms fixed to the base, and the two first actuating mechanisms are configured to drive the mounting member to rotate with respect to the base.

A multi-backhoe linkage mechanism, operable for rotating an output link around an output axis of rotation of an output joint at a base, includes a first closed kinematic chain, including the output link, a connecting link, and an input link. The output link is connected via the output joint to the base and via a connecting joint to the connecting link. The connecting link is connected via a bridging joint to the input link. The first closed kinematic chain additionally includes a base link connected to the base and to the input link. One or more additional closed kinematic chains are connected in a series after the first closed kinematic chain. Each additional closed kinematic chain is connected to the previous closed kinematic chain such that actuation of the additional closed kinematic chain amplifies the angle of rotation of the output link around the output axis of rotation.

A parallel link robot includes: a base part; a movable part including an accessory shaft; arms coupling the base and movable parts in parallel; and actuators that drive the respective arms, where each of the arms includes a driving link driven by each of the actuators, and two parallel passive links coupled to the driving link, between the passive links of at least one of the arms, an additional actuator having a rotating shaft disposed in parallel to the passive links is supported by a first link swingably coupled to each of the passive links, the accessory shaft, and the rotating shaft are coupled by a transmission shaft, and the transmission shaft is supported, at an intermediate position in a direction along a longitudinal axis thereof, on a second link rotatably around the longitudinal axis, the second link being swingably coupled to each of the passive links.

An apparatus for providing haptic guidance during manipulation of an end-effector includes a robotic arm. The robotic arm has at least one actuated joint, at least one other joint connected to the at least one actuated joint, and a physical constraint movable by actuation of the at least one actuated joint. The physical constraint limits the motion of the at least one other joint in at least one direction. The apparatus further includes an end-effector configured to be manipulated by an application of external forces and connected to the at least one other joint.

A parallel link robot includes a base having an axis, a movable portion movable along the axis so as to pick a workpiece in a first working region and place the workpiece in a second working region, and first, second and third arms arranged around the axis to form first, second, and third angles between the first, second and third arms. Each of the arms connects the base and the movable part to move the movable part along the axis. The third angle is less than 120 degrees. The first angle and the second angle are equal. The first and third arms are positioned on a side of the first working region with respect to the axis. The second arm is positioned on a side of the second working region with respect to the axis.

There is provided a spherical mechanism robot assembly for accessing a confined space in a vehicle, to perform confined space operation(s) in the vehicle. The assembly includes a base structure configured for attachment to the vehicle. The assembly includes a spherical mechanism structure having a first end attached to the base structure, and having a second end. The spherical mechanism structure includes a plurality of mechanical links, joints coupling the plurality of mechanical links together, and a plurality of actuators having one or more actuators coupled at each joint of the plurality of joints. The assembly includes an end effector attached to the second end of the spherical mechanism structure. The assembly is configured such that a majority portion remains outside of the confined space, while a remaining portion of the assembly accesses and occupies the confined space in the vehicle, to perform the confined space operation(s) in the vehicle.

The invention relates to a washing device for vehicles, which can clean the surface of a vehicle with high precision and with care. The claimed washing device comprises a delta robot (8, 32, 36, 48, 50) which supports a treatment element (6) on the operating-sided end.

A parallel link robot includes a base, a movable part, link mechanisms, and actuators. The movable part is movable along a center axis. The first, second and third link mechanisms are provided around the center axis with angular intervals in a circumferential direction around the center axis to project outwardly along a radial direction with respect to the center axis. Each of the first, second and third link mechanisms connects the base and the movable part to move the movable part along the center axis. The angular intervals have an acute angular interval with an acute angle. The first, second and third actuators are provided at the base to be connected to the first, second and third link mechanisms respectively so as to drive the first, second and third link mechanisms respectively.