A motor according to the present invention includes an output axis, a brake for holding the output axis, a sensor for detecting an external torque applied to the output axis from outside, and a controller for decreasing or increasing the torque of the brake during operation of the brake in accordance with an increase or decrease in the external torque detected by the sensor.

The invention relates to a drive (1; 101) of a machine (2) comprising a drive motor (3) for driving a rotatable shaft (5) of the machine (2) around a shaft axis of rotation (4), and comprising a clutch unit (10) in operative connection with the drive motor (3) and the shaft (5) for compensating for a relative movement (11) between the shaft (5) and the drive motor (3). The drive motor (3) has a rotor part (35) surrounding the shaft (5) on which a clutch rotation part (18A) of the clutch system (10) is mounted to be rotatable around the shaft axis of rotation (4), wherein the rotor part (35) is arranged at least partially engaging in the clutch rotation part (18A) in such a way that the clutch rotation part (18A) is mounted radially movably on the rotor part (35).

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.

A device for gripping an object that includes a main body having a first and a second endplate, a baseplate, at least one guide rail, and a first jaw and a second jaw, each receiving the at least one guide rail. The device also includes a first pulley assembly and a second pulley assembly respectively attached to the baseplate and a chain loop respectively attached to the first pulley assembly and the second pulley assembly. The chain loop includes a first chain length and a second chain length and a first link and a second link that attaches the first chain length and the second chain length. Each of the first link and second link include at least one dowel pin. The chain loop is attached to the first jaw and the second jaw by the at least one dowel pin of each of the first link and second link.

A robot system includes a robot having a base, a robot arm coupled to the base, a motor that drives the robot arm, a supply unit that supplies electric power to the motor, and a switch mechanism that switches between a conduction state in which the motor and the supply unit are conducting and a non-conduction state in which the motor and the supply unit are not conducting, and a vehicle having a movement mechanism that transports the robot and an operation portion that operates the switch mechanism and turns the conduction state to the non-conduction state, and being configured to take a coupled state in which the vehicle is coupled to the base and a decoupled state in which the vehicle is decoupled from the base, wherein the operation portion operates the switch mechanism in the coupled state.

A purpose is to reduce the risk of an arm section dropping off an ejection section in a robot arm mechanism having a linear motion joint. A robot arm mechanism including a linear extension and retraction joint includes a linear motion joint including an arm section and a mechanism for linearly extending and retracting the arm section; a stepping motor configured to generate power for linearly extending and retracting the arm section; a motor driver configured to drive the stepping motor; an encoder configured to output an encoder pulse every time a drive shaft of the stepping motor rotates by a predetermined angle; and a control section configured to control the driver unit to generate a static torque when a length of the arm section corresponding to a count of the encoder pulse reaches a threshold value set for preventing a drop of the arm section.

A securing device for a rotatably mounted object with at least one receiving unit, which is fixed against rotation on a first component of the object with at least one clamping unit which is fixed against rotation to a second component of the object, which manually or by means of a rotary drive is moveable relative to the first component via a rotatably mounted joint about a rotational and/or swivel axis, and with at least one drive unit through which the clamping unit can be transferred from a release position, in which the first component and the second component are released for rotation relative to each other to a clamping position, in which the clamping unit frictionally and/or non-positively engages in the receiving unit, and the first component and the second component are fixed relative to each other against rotation about the rotary and/or swivel axis.

A redundant parallel mechanism with less actuation and multi-degree-of-freedom outputs and a control method thereof are provided, which relate to the field of robot mechanisms. The redundant parallel mechanism includes: a fixed platform, a moving platform, multiple moving branch chains, and one or more redundant branch chains. Two ends of each moving branch chain are respectively connected to the fixed platform and the moving platform, and a brake is arranged on each moving branch chain. Two ends of each redundant branch chain are respectively connected to the fixed platform and the moving platform, and an actuating part is arranged on each redundant branch chain. There are n redundant branch chains arranged. During control, the number of follow-up moving branch chains is set to n, and the n moving branch chains move to expected positions and postures under the control of the n redundant branch chains.

Provided is an actuator including: a motor; a brake; a motor casing that accommodates a constituent member of the motor; and a brake casing that accommodates a constituent member of the brake. The motor casing and the brake casing are connected to each other, the brake includes a stator having a coil and a coil case, and a friction plate, a minimum outer diameter of the coil case is 70 mm or less, and a value obtained by dividing a distance from a first end surface of the friction plate on a side farthest in an axial direction from the coil case to a second end surface of the coil case on a side opposite to the first end surface by the minimum outer diameter is 0.2 or less.

A motorized arm for a robotic medical system can include a shoulder coupled to a column of a table by a translational joint that allows translation of the shoulder along the column, a first link rotationally coupled to the column, a second link rotational coupled to the first link, and an arm support coupled to a distal end of the second link. The arm support can be configured to support one or more robotic arms usable during a robotic medical procedures. The motorized arm can include actuators for driving rotation of the links and arbors that can be engaged to increase the torsional stiffness of the motorized arm. The motorized arm can move the arm support between a stowed position below the table to a deployed position.