An apparatus includes a drive; a movable arm connected to the drive, the movable arm comprising a first link connected to the drive at a shoulder, a second link connected to the first link at an elbow, a third link connected to the second link at a wrist, and a fourth link connected to the second link at the wrist; at least one first actuator located in the second link configured to cause a rotation of the third link about the wrist; and at least one second actuator located in the second link configured to cause a rotation of the fourth link about the wrist. One or more of a thermal management, a power distribution, or a communication is effected through the second link.

The invention relates to a modular exoskeleton structure that provides force assistance to a user, comprising a base module (1) comprising a lumbar belt (11) capable of surrounding the lower trunk of the user, two hip modules capable of being attached to two respective thighs of the user, and a backpack support module (14) for an exoskeleton structure, comprising: a hoop (141) designed to be anchored to the hip modules, at the hips of a user, a support rod (142) designed to extend along the back of the user and capable of being engaged in a pouch of a backpack to suspend the backpack to the backpack support module (14), wherein the rod (142) comprises a first rod element (1421) connected to the hoop (141), a second rod element (1422) capable of sliding with respect to the first rod element (1421) so as to vary a length of the rod (142), and a damper for cushioning the movement of the second rod element (1421) with respect to the first rod element (1422) caused by the walking of the user.

The invention relates to a method for designing grippers and fixtures for handling objects in robotic manufacturing and pick-and-place tasks. To achieve this a method for determining a shape of the holding or support surface of the gripper or fixture is presented. This method includes steps of determining an initial shape of the support surface based on an outer shape of the object, applying a shaping function to different locations of the initial shape, determining modified shape points at locations of the initial shape by comparing the applied shaping function with the initial shape. If the application of the shaping function results in an extension of the initial shape G(xi,yj) at the neighbour location (xi, yj) this extension forms part of a modified support surface for the gripper or fixture. A method for determining an optimum shape of the support surface with respect to optimization conditions is also presented.

A method for supporting designing and operation of a robotic system includes operating a computer-based Inventory configured to operate in a robotic system having Hardware Modules to perform a task, the Inventory including Hardware Module Descriptions including a unique identifier, a description of physical characteristics, a current status and historical data the Hardware Module. The method including the steps of collecting status data of the Hardware Module; collecting operating data representing usage of the Hardware Module and updating the historical data accordingly;
and at least one of the steps of scheduling maintenance actions to be performed on the Hardware Module (3); deriving or modifying, based on the operating data, historical data that is associated with a type of the Hardware Module.

A robotic grasping system can include a three-dimensional (3D) printed joint, a stiff portion coupled with the 3D-printed joint, internal tubes within the 3D-printed joint, a bellows coupled with the 3D-printed joint and at least one of the internal tubes, and a pressure source configured to cause the internal tubes to pressurize or depressurize the bellows.

The present disclosure provides a soft poly-limb system, comprising a first actuator segment, a second actuator segment, and a third actuator segment forming the soft poly-limb. Each of the first actuator segment, the second actuator segment, and the third actuator segment may comprise a plurality of ring reinforced actuators. The soft poly-limb system may further comprise a control system whereby a user may control the soft poly-limb.

An information processing method includes an output step in which a control device outputs a wire model having a length and a fixed position that satisfy a predetermined condition based on an initial value of at least one fixed position where a wire wired outside of a movable unit is fixed, an initial value of the length of the wire, and search conditions including physical constraints imposed on the wire associated with a move of the movable unit.

A robot casing includes, in a hollow resin body portion, two attachment openings and one work opening that communicate between an inside and an outside of the body portion. The two attachment openings are respectively provided in both end portions of the body portion; a metal member constituting an attachment surface is embedded in a resin constituting the body portion at a periphery of the attachment opening; the metal member is provided with attachment holes that allow attachment screws, which are used for attachment to the attachment surface, to penetrate therethrough or to be fastened thereinto, and is also embedded in the resin in a state in which the attachment surface is exposed; and components can be respectively attached to the two attachment openings by utilizing the work opening.

Disclosed is a method of providing performance indicators of a robot hand and a method of optimizing a structure of the robot hand, and more particularly to a method of providing performance indicators of a robot hand, in which the performance indicators are to objectively compare a plurality of robot hands with respect to performance, and a method of optimizing a structure of the robot hand, in which engineering design criteria are provided to determine essential factors in developing the structure of the robot hand.

A device capable of simulating a limb of a humanoid robot includes a vertically arranged guiding rail, a lower block fixed to the lower end of die guiding rail, an upper block slidably connected to rail, a lower linkage bar rotatably coupled to the lower block, an upper linkage bar rotatably coupled to the upper block, a joint module located between and rotatably coupled to the lower linkage bar and the upper linkage bar, a sensor configured to measure a force exerted on the joint; and a data processing module electrically connected to the sensor and configured to receive data from the sensor to determine a value of the force.