Disclosed is a two-turn-one-movement parallel mechanism with a large turning angle, comprising a machine frame, a movable platform, a first branch and two second branches, characterized in that the first branch comprises a machine frame turning pair, a first moving pair slider, a first moving pair guide rod and a first universal joint; each one of the second branches comprises a second moving pair guide rail, a second moving pair slider, a second universal joint, a connecting rod and a movable platform turning pair; in the two second branches, the axis of the first turning pair of each one of the second universal joints is superimposed with and parallel to the axis of the machine frame turning pair in the first branch, and the axis of each one of the movable platform turning pairs is parallel to the second turning axis of the first universal joint in the first branch.

Disclosed is a two-layer three-rail planar robot with a parallelogram, including a fixed platform, a moving platform, and three branched chains. Three planar curved rails I are provided on the fixed platform. Three planar curved rails II are fixedly connected to the moving platform. Each planar curved rail I is connected to a planar curved rail II corresponding to the planar curved rail I by one of the branched chains. Each of the branched chains includes a slider I, two connecting rods provided in parallel, a slider II. The slider I is slidably connected to the planar curved rail I. The slider I is rotatably connected to one end of each connecting rod by a revolute pair I, the other end of the connecting rod is rotatably connected to the slider II by a revolute pair II. The slider II is slidably connected to the planar curved rail II.

Devices, systems, and methods include a teleoperated system including a kinematic structure having a joint, a drive or brake system for controlling the joint, and a computing unit coupled with the drive or brake system. The computing unit is configured to detect that the joint is between a software defined range of motion limit for the joint and a physical range of motion limit for the joint, the software defined range of motion limit being spaced a distance apart from the physical range of motion limit and delay for a duration of time, in response to detecting the joint between the software defined range of motion limit and the physical range of motion limit, applying the drive or brake system to stop motion of the joint.

Robotic and/or surgical devices, systems, and methods include kinematic linkage structures and associated control systems configured to facilitate preparation of the system for use. In some embodiments, actively driven joints will move a platform structure that supports multiple manipulators in response to movement of one of the manipulators, facilitating and expediting the arrangement of the overall system by moving those multiple manipulators as a unit into alignment with the workspace. Systems and methods are also provided to keep one, some, or all joints of the kinematic chain off a hardstop or physical range of motion limit associated with the joint or to otherwise maintain a desired range of motion for one, some, or all joints of the kinematic chain when exiting a set-up mode.

A parallel kinematic manipulator system having three degrees of freedom and a method of controlling and visualizing work objects using force feedback and oscillation algorithms is provided. Three co-planar linear actuators operate symmetrically and parallel to an effector arm and are pivotally connected by three magnetic disc swivel joints to a base plate. The disc swivel joints each include a convex upper and lower swivel member having two dimensional gear patterns structured into their contacting and non-sliding surfaces. A pulsed illumination source consists of an annular LED array and is synchronized to the oscillation frequencies of the system to provide visual filtering capabilities. A control unit includes a method for keeping a work object balanced by force feedback and without the need for angle sensors at the end-effector, as well as methods for rotation of work objects and control of the pulsed illumination source. Sound trap ridges are included as part of the housing to reduce system noise.

Robotic and/or surgical devices, systems, and methods include kinematic linkage structures and associated control systems configured to facilitate preparation of the system for use. In some embodiments, actively driven joints will move a platform structure that supports multiple manipulators in response to movement of one of the manipulators, facilitating and expediting the arrangement of the overall system by moving those multiple manipulators as a unit into alignment with the workspace. Systems and methods are also provided to keep one, some, or all joints of the kinematic chain off a hardstop or physical range of motion limit associated with the joint or to otherwise maintain a desired range of motion for one, some, or all joints of the kinematic chain when exiting a set-up mode.

A system for automatically handling components to be assembled onto a product on an assembly line includes a carriage that is movable to and between a first, retracted position spaced from the assembly line, and a second position displaced from the retracted position in a direction toward the assembly line. A manipulator on the carriage supports a component mounting tool configured to receive and support at least one component for assembly to the product. The manipulator may be arranged in a first orientation when the carriage is in the first position, and may be pivoted to a second orientation when the carriage is in the second position, such that a component on the component mounting tool is supported in a pose for processing when the carriage is in the first position, and is supported in a pose for joining to the product when the carriage is in the second position.

A semi-automatic precision positioning robot apparatus and method for use of the same to hold, position, orient and/or move a workpiece are provided. The positioning apparatus utilizes an actuator system of a given configuration to manipulate a workpiece holding unit with multiple degrees of freedom to achieve various positions and orientations. An associated tool may further be provided to interact with the workpiece in various positions and orientations. The positioning apparatus enables an operator to obtain high degrees of maneuverability while maintaining precision and consistency in the manufacture and production of various products and components.

A medical device is provided. The medical device includes a shaft motor, a parallel manipulator, a receiving yoke, a runner and a transmission yoke. The shaft motor is configured to generate a mechanical force for manipulating a surgical tool. The parallel manipulator includes an end platform used to support the surgical tool, a base platform used to support the shaft motor and a plurality of limbs coupled between the end platform and the base platform. The limbs are configured to control movement of the end platform. The receiving yoke is coupled to the surgical tool. The runner is slidingly engaged to the shaft motor and configured to receive the mechanical force. The transmission yoke is coupled to the runner and the receiving yoke, and the transmission yoke is configured to transfer the mechanical force to the receiving yoke.

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.