A robot arm (500) for positioning a tool (44) with controlled orientation. The robot arm (500) comprises an inner-arm linkage (15, 18, 29; 15, 18, 77); an outer-arm linkage (23; 81; 173; 228; 632; 384) and a first actuator (1; 249) configured to rotate the inner-arm linkage about a first axis of rotation (180). The inner-arm linkage includes a first inner link (15) that at an inner end is arranged to rotate around a fourth axis of rotation (185), and a second inner link (18) that at an inner end is arranged to rotate around a different, third axis of rotation (182, 185), wherein the axes of rotation (182, 185) are perpendicular to the first axis of rotation (180), and the rotations result in a geometric reconfiguration of the inner-arm linkage. The inner-arm linkage also includes a connection shaft (29; 77) mounted at an outer end of the first inner link and at an outer end of the second inner link by means of joints of at least one degree of freedom, is connected to the outer-arm linkage via the connection shaft, is connected to the tool and forms a first kinematic chain that gives a first degree of freedom for positioning the tool. A second actuator (2; 254) is configured to rotate the outer-arm linkage around the second axis of rotation, thereby forming a second kinematic chain giving a second degree of freedom for positioning the tool. A third actuator (3) is configured to move the outer-arm linkage by actuating the geometrically reconfigurable inner-arm linkage, resulting in a movement of the second axis of rotation around which the outer-arm linkage is arranged to rotate, thereby forming a third kinematic chain giving a third degree of freedom for positioning the tool. The robot arm also comprises one or more transmission mechanisms that in combination with the outer-arm linkage are arranged to accomplish the controlled orientation of the tool.

A mechanical translation apparatus includes a translation stage and a translation assembly operatively connected to the translation stage so as to impart linear motions to the translation stage substantially free of rotational motions. The translation assembly includes a plurality of at least three arms pivotably connected to the translation stage at a first end of each arm of the plurality of at least three arms. The mechanical translation apparatus also includes a base assembly in which each arm of the plurality of at least three arms is also rotationally connected to the base assembly at a second end of each arm. Each arm of the plurality of at least three arms includes three rigid elongate structures arranged substantially parallel and non-coplanar with respect to each other so as to act in cooperation to cancel torques so that substantially purely linear motion is imparted to the translation stage by the plurality of at least three arms, and the translation assembly constrains motion of the translation stage to be substantially purely translational motion free of rotational motion. A robot includes the mechanical translation apparatus.

A system for machining a workpiece. The system includes a rotatable frame mounted to a base and arms which can translate relative to the rotatable frame. The arms are attached directly or indirectly to a machining tool which can be moved to various points around the workpiece and include tools for various machining operations.

The present invention relates to a class of over-constrained two-rotation parallel mechanism with same kinematics, which comprises a base, a moving platform and four branches connecting the base and the moving platform, wherein the base and the moving platform are equilateral triangles, both ends of each of the first branch, the second branch and the third branch are respectively connected to end points of the base and the moving platform, both ends of the fourth branch are respectively connected to center points of the base and the moving platform, the first branch and the third branch both consist of a first rotating pair. The parallel mechanism of the present invention has a large rotation space and high rigidity, and can be used for positioning equipment such as missile launchers.

The present invention discloses an machining device based on a portable 5-DOF parallel module. The machining device based on a portable 5-DOF parallel module comprises: a table for moving a parallel module to increase the stroke of the machine tool such that the machine tool can machine large components and can also simultaneously conduct the mounting and the machining of workpieces at different stations; a CNC rotary table; and a portable 5-DOF parallel module. The portable parallel module has a large swing angle range, can conduct the conversion between vertical and horizontal machining modes and can achieve five-face machining in one setup in cooperation with the CNC rotary table. The parallel module can move flexibly, and can machine large and complex components after mounted on the sliding table. After the machining of the workpiece is completed, the parallel module can move to the position of a mounted component through the table to conduct the machining of the next component. Thus, the mounting and the machining of the workpiece are simultaneously conducted at different stations, and the utilization rate and the production efficiency of the portable parallel module are improved.

A robotic system includes a support structure, a platform, a center serial chain, outer serial chains, motors, a sensor, and a control module. The center serial chain connects a center of the platform to the support structure and includes first joints connected to a linear sliding shaft. The outer serial chains are disposed radially outward of the center serial chain. Each of the outer serial chains includes second joints connecting a bar to the platform and the supporting structure. The motors are connected to the outer serial chains. The sensor is connected to the platform and detects at least one of force or torque applied by a human operator on the platform and generates a signal indicative thereof. The control module controls the motors based on the signal to assist the human operator in at least one of moving or rotating the platform.

Embodiments of the present invention provide methods and systems to analyze wearable technology. A robot with snake assembly works in conjunction with a server in order to simulate the locomotive actions of appendages and to concomitantly determine the response of wearable technology devices, which are attached to the snake robot assembly, to the simulated locomotive actions.

The present invention provides a four-chain six-degree-of-freedom hybrid mechanism. The four-chain six-degree-of-freedom hybrid mechanism comprises a fixed platform, a sliding rail mounted on the fixed platform, two sliding blocks, a mobile platform and four linear actuator chains connecting the mobile platform with a first sliding block and a second sliding block. The mobile platform is square-shaped. In the four linear actuator chains, the first linear actuator chain and the third linear actuator chain have the same structure while the second linear actuator chain and the fourth linear actuator chain have the same structure. The mobile platform can achieve six degrees of freedom. The four linear actuator chains coordinate to drive so as to achieve two translational degrees of freedom and two rotational degrees of freedom; the first sliding block and the second sliding block coordinate to drive so as to achieve the other translational and rotational degrees of freedom.

A motion data generation system of a robot including an upper body, a waist, and a lower body is provided. The motion data generation system includes a subject motion data acquisition unit that acquires upper body motion data captured from motion of the upper body of a subject and captured waist motion data captured from motion of the waist of the subject, a manually generated motion data acquisition unit that acquires lower body motion data and manually generated waist motion data, the lower body motion data and the manually generated waist motion data being generated through manual input by a user, and a robot motion control unit. The robot motion control unit includes a leg state determination unit and a waist motion data generation unit.

A parallel-series connection walking robot and a construction method thereof. The parallel-series connection walking robot mainly comprises leg mechanisms A and B; one leg mechanism A is a parallel-series connection leg mechanism (3); the other leg mechanism B is a parallel-series connection leg mechanism (3) or a foot parallel-connection mechanism (1); and the parallel-series connection leg mechanism (3) is formed of a thigh mechanism (3.2) and a foot parallel-connection mechanism (3.1) through serial connection. The two leg mechanisms have a combination of a specific DOF; upper portions of the two leg mechanisms are fixedly connected together; all members are comprised by and intersected with each other, but have independent activity spaces, respectively; and projections of the triangles formed by toes of the two leg mechanisms on a horizontal plane overlap with each other. During an advancing process, the robot can stably walk in any direction without left-right gravity center adjustment; and the robot also has the advantages of less kinematic pairs, lower robot body height, strong bearing capacity, steering flexibility, strong obstacle crossing ability and climbing up and down ability.