When an operation portion (38) provided at an axial end portion of a valve member (37) is pushed into a valve case (31) provided to a first block (3), a clamping apparatus transitions from a first state, in which communication between: each of a primary-side pressure fluid supply/discharge port (34) and a secondary-side pressure fluid supply/discharge port (35); and a pressure fluid discharge port (36) is open, to a second state, in which communication between: each of the primary-side pressure fluid supply/discharge port (34) and the secondary-side pressure fluid supply/discharge port (35); and the pressure fluid discharge port (36) is closed.

In order to respond flexibly to various processing modes, such as forming curved surface shapes, when cutting a workpiece using a wire saw, this wire saw device (1) is provided with: a single robot arm (2) that is capable of moving freely by means of multi-axis control; a wire saw unit (3) that is detachably connected to the robot arm (2) via a tool changer (7); a wire (8) that spans a plurality of pulleys supported within the wire saw unit (3); and a workpiece cutting zone (20) that is established between the pulleys. The workpiece is cut to a prescribed shape by moving the robot arm (2) in a preset direction while running the wire (8) of the wire saw unit (3) and pressing the wire (8) against the supported workpiece.

A connector (70) for mechanically connecting a device (2) to a robot (20), wherein the connector (70) comprises a first portion (74) configured to be attached to the robot (20) and a second portion (76) configured to be attached to a device (2) configured to be connected to the robot (20). The first portion (74) and the second portion (76) are detachably attached to each other by a first connection portion (1) constituting a rotational system comprising a pivot (116) about which the first portion (74) can rotate with respect to the second portion (76) and a second connection portion (1′) constituting a mechanical locking structure that prevents the first portion (74) and the second portion (76) from being detached from each other.

A separable robotic interface includes a carrier portion, configured to attach to a free end of a robotic arm, and a probe portion, configured to be attached to a toolhead. The carrier portion includes a spring-loaded plug, coaxial with and arranged to slide lengthwise within the carrier portion, one or more ball bearings, arranged within holes of the carrier portion, and an axial lock feature. The probe portion may include a probe, which includes one or more recesses on lateral exterior surfaces of the probe and configured to receive ball bearings in order to axially lock the carrier portion to the probe portion in response to the probe portion inserted a predetermined distance into the carrier portion and the axial lock feature is activated. The probe portion is further configured to radially align with the carrier portion in response to an alignment feature engages the carrier portion.

An automatic tool exchange coupler and an automatic tool exchange device are provided that achieve further improvement in the user-friendliness of the automatic tool exchange device. The coupler includes a coupler body, a first direction switching valve and a second direction switching valve that are provided to a first side surface of the coupler body. The coupler body has: in a first side surface, an uncoupling input port being connected to a pipe for introducing a gas for uncoupling; and in the second side surface opposite to the first side surface, an uncoupling output port being configured to connected to the uncoupling port. The uncoupling input port is located at a position where a center of the uncoupling input port is radially offset with respect to the uncoupling output port by at least an amount corresponding to a length of a diameter of the uncoupling input port.

An adapter system for connecting the last element of a kinematic chain of a handling device to same, wherein the last element has a computer-storage module, as well as at least one actuator and/or at least one sensor. At least three sequentially positioned system modules are arranged between the penultimate and the last element. A first system module is a mechanical module, via which electrical and/or pneumatic connection lines are guided. In a second system module, the connection lines are connected with transition points of a negative adapter geometry of a mechatronic combi-interface. At least one further system module is arranged in a couplable manner between the second system module and the last element. A third system module has an electronics assembly which adapts the predefined system architecture to the device interface of the last element.

A surgical instrument holder includes a carriage, a housing, and a drive assembly. The carriage is configured for engagement to a surgical robotic arm and for supporting an instrument drive unit. The housing extends from the carriage and defines a channel. The drive assembly includes a pulley, a belt, and an annular member. The pulley is rotatably disposed within the housing and in operable engagement with a motor of the carriage such that actuation of the motor rotates the pulley. The belt is rotatably disposed within the housing and in operable engagement with the pulley such that rotation of the pulley effects rotation of the belt. The annular member is disposed within the channel of the housing and configured for non-rotatable receipt of an instrument drive unit. The annular member is in operable engagement with the belt such that rotation of the belt effects rotation of the annular member.

An arm engageable with a mounting receiver of an automated tooling system. The arm comprises a wall defining a central bore extending the length of the arm, and at least pin engageable with the mounting receiver to engage the mounting receiver for aligning and receiving the mounting receiver. The pin may be a plasma ion nitrided pin. The arm may also include first and second ends, an electrical power supply connector positioned inside the bore adjacent the first end and wiring. The second end defines an opening. The wiring is connected to the electrical power supply connector, and extends unexposed within the bore from the electrical power supply connector through the opening to supply power to the gripper.

A robotic surgical tool includes a handle having a plurality of drive inputs rotatably mounted thereto, an elongate shaft extending through the handle and having an end effector arranged at a distal end thereof, and a plurality of drive members extending along the shaft to the end effector. A plurality of input stacks are arranged within the handle and operatively coupled to the plurality of drive inputs such that actuation of the plurality of drive inputs rotates the plurality of input stacks. Each input stack includes a drive member engagement device that locates and captures a corresponding one of the plurality of drive members at the handle upon rotation of the input stack.

An interface for a surgical system includes an instrument drive unit and a surgical instrument. The instrument drive unit includes a connection hub and at least one drive shaft rotatably supported in the connection hub. The at least one drive shaft extends between a first end and a second end having an oblique end surface. The surgical instrument is releasably connectable to the instrument drive unit and includes a connecting member and at least one driven shaft rotatably supported in the connecting member. The at least one driven shaft extends between a first end and a second end. The second end has an oblique end surface corresponding to the oblique end surface of the at least one drive shaft. The oblique end surfaces are configured such that the connecting member is connectible with the connection hub via a first connection pathway and a second connection pathway.