Disclosed is a support device (100) and method for supplying supportive forces to a set of links in a main assembly (1). These links (1.A.1, 1.A.2, 1.A.3, 1.A.4) are connected to an assistive assembly (3), which is designed to be a representation of the main assembly (1), and the connection is used to maintain the representation, so that displacements and forces in the main assembly (1) result in displacements and forces in the assistive assembly (3), and the other way around. There are further force regulator units (3.E.1, 3.E.2) included in the assistive assembly (3), that apply forces on the assistive assembly (3) and through the connection thus also on the main assembly (1), but whose weight is not felt by the main assembly (1). These forces can be used to provide supportive or compensation forces to the main assembly (1), so the main assembly (1) can be a wearable exoskeleton that provides forces to support human wearers, or it can be an industrial robotic manipulator that appears weightless and whose payload is compensated.

A robot system and a method for driving a robot capable of moving the position of the center of gravity of the robot while minimizing the increase in the footprint thereof are provided. A robot system according to an aspect of the present disclosure includes a robot. The robot includes a movable moving part, an upper body part disposed above the moving part, and a driving mechanism for tilting the upper body part and moving a lower end of the upper body part in a direction in which the upper body part is tilted.

A remote center joint 1 is configured to rotate segment 7 relative to segment 2 along axis 15. Remote center joint 1 comprises a segment 3 coupled to base segment 2 along axis 16. Segment 4 is coupled to segment 3 about axis 17 intersecting axis 16 at first point 22. Segment 4 is coupled to segment 7 about axis 18 intersecting first point 22. Segment 5 is coupled to segment 2 about axis 19 parallel to axis 16. Segment 5 is geared to segment 3. Segment 6 is coupled to segment 5 about axis 20 intersecting axis 19 at second point 23. Segment 6 is coupled to segment 7 along axis 21 intersecting second point 23. Segment 6 is geared to segment 4. Axis 15 of rotation of terminal segment 7 relative to segment 2 connects first point 22 and second point 23.

A work device is configured to perform a work with use of an end effector and have six degrees of freedom. The work device including: a linear motion unit obtained by combining three linear motion actuators, to have three degrees of freedom; and a rotation unit obtained by combining a plurality of rotation mechanisms each having one or more degrees of rotational freedom, to have three degrees of freedom. A base portion of the linear motion unit is fixed to a mount. A base portion of the rotation unit is fixed to an output portion of the linear motion unit. The end effector is mounted to an output portion of the rotation unit.

Devices, systems and methods of controlling movement of a host mechanical system using inertial forces imparted by an augmentable or morphable appendage. Such appendages are attached to the host mechanical system such that augmentation or morphing of the appendage to move a mass of the appendage from an extended to a retracted configuration imparts inertial forces to the supporting structure. Augmentation/morphing is controlled and coordinated such that imparted inertial forces facilitate a desired movement of the mechanical system. The imparted forces can include translation forces and/or rotational forces along one or more axes. The augmentation or morphing of the appendage can be performed concurrently with separately controlled coordinated movement of the appendage to facilitate a desired movement of the mechanical system. Such appendages can include, but are not limited to, telescoping and/or folding designs.

In a parallel link mechanism, a distal end side link hub is coupled to a proximal end side link hub via three link mechanisms such that a posture of the distal end side link hub can be changed. Each link mechanism includes a proximal side end link member, a distal side end link member, and a center link member, and forms a quadric chain link mechanism composed of four revolute pairs. A singular point occurs when a central axis of the proximal or distal end side link hub and a central axis which is a rotation axis of a revolute pair section of the proximal or distal side end link member and the center link member coincide with each other. An axis angle of the center link member is specified such that a posture in which the singular point occurs is avoided.

A distal end side link hub is coupled to a proximal end side link hub via three or more link mechanisms. Each link mechanism has a proximal side end link member, a distal side end link member, and an intermediate link member. The proximal side end link member has a bent portion and rotation shaft mounting portions. A rotation shaft is mounted to the rotation shaft mounting portion. A bevel gear, forming a part of a gear mechanism for transmitting rotary motion of a posture control actuator to the proximal side end link member, is mounted on the rotation shaft mounting portion and disposed in a space between two virtual planes obtained by extending a radially inner edge and a radially outer edge of one end of the bent portion in a longitudinal direction of the rotation shaft mounting portion.

A center-of-gravity-of-load position calculator is provided which determines the position of the center of gravity of a physical load held by a horizontal four-axis robot arm. The center-of-gravity-of-load position calculator moves horizontally move the physical load a plurality of times in conditions where positions of a fourth axis are different from each other and measures degrees of torque acting on the fourth axis during such movement to calculate given first and second parameters. The center-of-gravity-of-load position calculator calculates the position of the center of gravity of the physical load as a function of the first and second parameters. This achieves fast and easy calculation of the position of the center of gravity of the physical load.

A method for controlling a servomotor with a converter includes monitoring a circuit of a direct-voltage DC link that is connected to an input circuit for flow of an electric current; switching off a first switching device to end the supply of the direct-voltage DC link from an electrical grid if a stop signal occurs; braking the servomotor by control of power semiconductor switches of an inverter circuit in a regenerative braking operation, to reduce the rotation speed of the servomotor, if the monitoring detects that an electric current is not flowing after the first switching device has been switched off; and switching off a second switching device to prevent feeding electrical energy from the direct-voltage DC link into the servomotor if the monitoring detects a flow of electric current after the first switching device has been switched off.

A carrier device includes a work part having a loading surface configured to have an object placed thereon, a base being movable, a support part supporting the work part movably with respect to the base, a detector provided at one of the work part and the base, and a controller, the detector is configured to detect a gravitational acceleration and a linear acceleration applied thereto. The controller is configured to control the support part so as to tilt the work part and linearly move the work part with respect to the base based on the gravitational acceleration and the linear acceleration. This carrier device prevents the object from falling down on the loading surface even while moving.