A substrate transport apparatus including a frame, a drive section connected to the frame and including at least one independently controllable motor, at least two substrate transport arms connected to the frame and comprising arm links arranged for supporting and transporting substrates, and a mechanical motion switch coupled to the at least one independently controllable motor and the at least two substrate transport arms for effecting the extension and retraction of one of the at least two substrate transport arms while the other one of the at least two substrate transport arms remains in a substantially retracted configuration.

An operating device configured to operate in a work space, the operating device including: a robot arm, which includes a succession of arm elements mounted on one another in a rotatable way about respective axes of rotation and which carries an operating unit on its end; and at least one presence sensor prearranged for detecting the presence of an operator. The device includes a positioning system, including a support by which the at least one presence sensor is carried and which is mounted on an arm element of the robot arm, according to a pre-set orientation and in such a way as to be orientable with respect to the arm element, and wherein the positioning system further includes a positioning unit prearranged for rotating the support with respect to the arm element, as a result of a movement of the robot arm, so as to keep the pre-set orientation of the support unchanged.

A conveying device includes a first link that includes a first connecting part, a second connecting part, and a first holder part located opposite the second connecting part with respect to the first connecting part, a second link that includes a third connecting part rotatably connected with the first connecting part, and operates to rotate the third connecting part about a first reference point, a third link that includes a fourth connecting part rotatably connected with the second connecting part and operates to rotate the fourth connecting part about a second reference point, and a first drive that operates the links. The links move the first holder part between a first point and a second point opposite each other with respect to the first reference point so that the first holder part approaches the first reference point in association with operation of the second link.

A module robot includes a first link, a second link movably linked to the first link, and a fluid pressure cylinder configured to move the first link and the second link relative to each other, wherein the first link has a cylinder block in which a cylinder chamber of the fluid pressure cylinder is formed.

A parallel kinematic machine (PKM) includes a support platform and first, second, and third support linkages. The first, second, and third support linkages together include at least five support links. The PKM further includes a tool base having a shaft joint, a tool base shaft, and a tool platform. The tool base shaft is connected to the support platform via the shaft joint, rigidly connecting the tool platform and the tool base shaft. The PKM also includes one or more tool linkages, each including a tool link connected at one end, via a tool base joint, to the tool base, and at the other end connected, via a tool carriage joint, to a movable carriage. Each tool linkage is configured to rotate the tool base shaft around at least one axis relative to the support platform by transferring a movement of the respective tool linkage to the tool base shaft.

A robotic joint comprises a first link, a middle link, a torque generator, a second link, and a locking mechanism. Different ends of the middle link are rotatably coupled to the first link and the second link. The torque generator is coupled to the first link and the middle link and is configured to produce torque between these links. The locking mechanism is switchable between a locking state and an unlocking state. In the unlocking state, the locking mechanism allows free rotation of the second link relative to the middle link in the first and second rotation directions. In the locking state, the locking mechanism is configured to impede rotation of the second link relative to the middle link in the first rotation direction and to allow rotation of the second link relative to the middle link in the second rotation direction opposite of the first rotation direction.

An articulated robot arm comprises a plurality of skeleton links. Motorized joint units forming joints between adjacent ones of the skeleton links such that the skeleton links of the adjacent ones are rotatable relative to one another. One or more skin shells are provided for the skeleton links, the skin shell forming a non-structural skin around the at least one of the skeleton links.

A maintenance system is disclosed for assisting in maintaining an automated carrier system for moving objects to be processed. The maintenance system includes a plurality of automated carriers that are adapted to move on an array of discontinuous standard track sections, each said automated carrier including a carrier body that is no larger in either a length or width direction that a standard track section, and an automated maintenance carrier that is adapted to move on the array of discontinuous track sections, said automated maintenance system including a maintenance body that is larger in at least one of a length or width direction than the standard track section.

A powered user interface for a robotic surgical system having a manipulator and a surgical instrument mounted to the manipulator includes a base and a linkage assembly that includes two two-bar linkage mechanisms. The linkage assembly is rotatably mounted to the base at a base joint, and a handle mounted to each of the two-bar linkage mechanisms. Sensors and actuators are arranged to measure and actuate the position and orientation of the user interface.

A powered user interface for a robotic surgical system includes a base, a handle mounted to the base and moveable relative to the base in at least six degrees of freedom, and actuators. The interface operates in accordance with a first mode of operation in which the actuators are operated to constrain predetermined ones of the joints to permit motion of the handle in only 4DOF with respect to the base, and a second mode of operation in which the actuators permit motion of the handle in at least 6DOF with respect to the base.