A working unit includes a tool rotation mechanism, a first turning mechanism turning the tool rotation mechanism about a first axis, and a second turning mechanism turning the tool rotation mechanism and the first turning mechanism about a second axis perpendicular to the first axis. The first turning mechanism includes a motor having a stator connected to the second turning mechanism and a hollow shaft-shaped rotor arranged inside the stator in such a manner that the rotor is capable of rotating about the first axis, and a second rotating body including one arm portion coupled to one end portion of the rotor, the other arm portion coupled to the other end portion of the rotor, and an arm coupling portion that couples the arm portions to each other. The tool rotation mechanism is provided on the second rotating body.

A machine tool comprising: a first body; a first leg, a second leg, and a third leg coupled to the first body via first joints and configured to support at least the first body; a second body including a tool holder; a fourth leg, a fifth leg, and a sixth leg coupled to the second body via second joints and configured to support at least the second body; and a first actuator coupled to the first body and to the second body, the first actuator being configured to cause rotational motion between the first body and the second body to enable a change in walking direction of the machine tool and/or to enable a change in machining stiffness and a change in work volume of the machine tool.

A non-Cartesian coordinate positioning machine is provided that comprises an extendable leg assembly for positioning a component such as a measurement probe within a working volume of the machine, and a constraint member associated with the extendable leg assembly for providing a predetermined part of the extendable leg assembly with substantially a same orientation relative to gravity for a same position of the component within the working volume. In a preferred embodiment, the orientation relative to gravity is maintained substantially constant, so that a plane defined by the predetermined part is substantially aligned with gravity, as the component is moved around the working volume.

A transfer device for self-propelling workpiece trolleys of a transport system allows ends of one or more route sections to be continuously or intermittently connected. The ends of the route sections are either connected via transfer sections that are rigid and bent at least in sections, or a transfer sectionwhich can be moved along a straight or curved track curve and supporting one or more workpiece trolleyscan be temporarily arranged before the ends of the route sections, which transfer section can be moved back and forth between the ends via a driveable gear unit. At least one transfer device for a transport and/or processing system is developed, with which the workpiece trolleys are transferred from one route section to another.

A parallel-type micro robot capable of precise control while minimizing size thereof and a surgical robot system having the same are disclosed. The parallel-type micro robot includes a base plate, a work plate, a main fixing shaft module, a horizontal movement module and at least one angle-controlling module. The base plate includes a base body portion and at least one base connecting portion connected to the base body portion. The work plate includes a work body portion corresponding to the base body portion and at least one work connecting portion connecting to the work body portion to correspond to the base connecting portion. The main fixing shaft module is disposed between the base body portion and the work body portion, and coupled to the work body portion such that the work body portion is rotatable. The horizontal movement module is disposed between the main fixing shaft module and the base body portion, and moves the main fixing shaft module along first and second directions intersecting each other. The angle-controlling module is coupled to the base connecting portion such that the base connecting portion is rotatable, is coupled to the work connecting portion such that the work connecting portion is rotatable, and allows translational motion between the base connecting portion and the work connecting portion. Thus, a size of a robot may be minimized while improving the structural stability and precise control.

The present disclosure relates to a method and to an apparatus for chamfering and deburring gear cut workpieces, especially of large-volume gear cut workpieces, using a deburring apparatus which is arranged on or at the cutting head of a gear cutting machine and which at least partially utilizes the machine axes of the gear cutting machine to chamfer and to deburr gear teeth along a tooth contour.

The present application provides a multi-motion-platform parallel robot and a method of constructing the same. The parallel robot comprises a symmetrical basic parallel mechanism and one or more symmetrical branch parallel mechanism. The basic parallel mechanism comprises a symmetrical basic foundation platform, a symmetrical basic motion platform, and symmetrical main branched-chains. The branch parallel mechanism comprises a symmetrical branch foundation platform, a symmetrical branch motion platform, and symmetrical branch branched-chains. The basic parallel mechanism and the branch parallel mechanism are connected by means of a multiple-output motion pair having symmetrical output ends, and share one set of driving pairs and drive and control devices. The multi-motion-platform parallel robot and it's method of construction can be used for various industrial robots, three-dimensional profile modeling and scaling robots and walking robots, and have the advantages of having a simple structure, being easy to standardize, having a high production efficiency, and the like.

A 6-axis positioning system features a base, a movable unit, and six variable-length actuators divided into two groups of three actuators each. The actuators of the first group are positioned within a region bounded by the second group on both the base and the movable unit. Each end of the actuators is connected via pivot fastening systems, allowing precise movement. Specifically, the first group's actuators can move within an angular range of 30 relative to a virtual line running perpendicular from the base, while the second group's actuators can move within an angular range of 0 to 45 relative to a plane spanned by the base. This arrangement ensures a compact, precise, and flexible positioning system, ideal for applications requiring high accuracy and load-bearing capacity.

A precision tripod motion system is provided. The tripod motion system in one example includes a bottom plate including three spaced-apart bottom single-degree-of-freedom hinges, a top plate including three spaced-apart top three-degrees-of-freedom (TDOF) joints, wherein the top plate is configured to receive a workpiece. Each linear actuator of three linear actuators is coupled to an associated SDOF hinge of the bottom plate and coupled to an associated TDOF joint of the top plate. Each linear actuator is configured to change length over a linear actuation span and configured to return the top plate to a predetermined set position after the top plate is displaced by an external force Each linear actuator includes a ball coupled to the associated three TDOF joint and a positioning actuator configured to move the ball to the predetermined set position prior to the return of the top plate to the predetermined set position.

A precision tripod motion system is provided. The tripod motion system in one example includes a bottom plate including three spaced-apart bottom single-degree-of-freedom (SDOF) hinge portions, a top plate including three spaced-apart top three-degrees-of-freedom (TDOF) joint portions, with the top plate configured to receive a workpiece, three linear actuators pivotally coupled to the three bottom SDOF hinge portions of the bottom plate and coupled to the three top TDOF joint portions of the top plate, with each linear actuator of the three linear actuators configured to change length over a linear actuation span, and a rotator component and/or a positioning table affixed to the top plate and the bottom plate. The tripod motion system is additionally coupled to a rotator component and a positioning table to provide six degrees of freedom of motion.