A robot controller includes an all-axes control part collectively calculating position command values for a plurality of axes based on a predetermined trajectory of the robot, and motor drive control parts for each axis. The motor drive control part includes a stopping position command calculation part which calculates a stopping position command value for each axis with a motor coordinate system as a reference. The motor drive control part switches the position command value transmitted from the all-axes control part to the stopping position command value for each axis when an emergency stop signal is inputted and, after that, returns from the stopping position command value for each axis to the position command value transmitted from the all-axes control part. The all-axes control part starts calculation for outputting an emergency stop position command value for stopping the robot on the predetermined trajectory when the emergency stop signal is inputted.

Provide is a robot and a control method thereof in which the motion of an arm 12 as a specified limb among a plurality of limbs 12 and 14 extended from a body 10 is controlled according to a specified trajectory. If a first interaction state, in which a hand 126, which is an end effector, interacts with a horizontal wood member L (j) of a ladder L in a first mode is implemented, then a control command is given to an actuator 41 that drives the hand 126 to cause the hand 126 to perform a grasping motion, thereby implementing a second interaction state, in which the hand 126 interacts with the horizontal wood member L (j) in a second manner. If the second interaction state is implemented, a control command is given to a brake 42 to maintain a motion halt state of the hand 126.

A control device configured to control operation of an electric motor of which a rotational shaft is rotatable by an external force which servo-controls the electric motor by an inverter circuit when a voltage value between power-supply input terminals of the inverter circuit is detected to be at or above a given voltage value required for the servo-control of the electric motor, and applies dynamic braking to the electric motor by forming a short circuit in the inverter circuit when the voltage value between the power-supply input terminals of the inverter circuit is detected to be below the given voltage value.

A method for decelerating a robot axis arrangement having at least one output link includes steps of applying a braking force on the output link with a brake and, in so doing, controlling a driving force of a drive that acts on the output link, and/or controlling the braking force on the basis of a dynamic variable of the output link, wherein the dynamic variable is a function of the braking force.

Provided is a robot and a control method thereof in which the motion of an arm 12 as a specified limb among a plurality of limbs 12 and 14 extended from a body 10 is controlled according to a specified trajectory. If a first interaction state, in which a hand 126, which is an end effector, interacts with a horizontal wood member L (j) of a ladder L in a first mode is implemented, then a control command is given to an actuator 41 that drives the hand 126 to cause the hand 126 to perform a grasping motion, thereby implementing a second interaction state, in which the hand 126 interacts with the horizontal wood member L (j) in a second manner. If the second interaction state is implemented, a control command is given to a brake 42 to maintain a motion halt state of the hand 126.

A robot system includes a motor, an inverter, a first control portion, and a second control portion. The motor includes stator windings for three phases. The inverter includes series-connection bodies of a high-side switch and a low-side switch for three phases. A connection point of the high-side switch and the low-side switch for each of the phases is connected with the corresponding stator winding. One of the high-side switch and the low-side switch for each of the phases works as a brake switch. The first control portion and the second control portion performs a driving control of the brake switches. Each of the first control portion and the second control portion has a function of monitoring the robot system, and turns on the brake switches for at least two phases when detecting that an abnormality occurs in the robot system.

A method for decelerating a robot axis arrangement having at least one output link includes steps of applying a braking force on the output link with a brake and, in so doing, controlling a driving force of a drive that acts on the output link, and/or controlling the braking force on the basis of a dynamic variable of the output link, wherein the dynamic variable is a function of the braking force.

A method for decelerating a robot axis arrangement having at least one output link includes steps of applying a braking force on the output link with a brake and, in so doing, controlling a driving force of a drive that acts on the output link, and/or controlling the braking force on the basis of a dynamic variable of the output link, wherein the dynamic variable is a function of the braking force.

A robot system includes a motor, an inverter, a first control portion, and a second control portion. The motor includes stator windings for three phases. The inverter includes series-connection bodies of a high-side switch and a low-side switch for three phases. A connection point of the high-side switch and the low-side switch for each of the phases is connected with the corresponding stator winding. One of the high-side switch and the low-side switch for each of the phases works as a brake switch. The first control portion and the second control portion performs a driving control of the brake switches. Each of the first control portion and the second control portion has a function of monitoring the robot system, and turns on the brake switches for at least two phases when detecting that an abnormality occurs in the robot system.

The invention relates to a method for commanding the brakes (F1, F2, F3) of the motors (M1, M2, M3) of a multi-axis robot (R1), comprising: a robot arm (B) comprising at least two degrees of freedom each associated with an electric motor (M1, M2, M3), a sensor (C1, C2, C3) for measuring movement information, and a brake (F1, F2, F3), an interfacing unit (4) of the brakes (F1-F3) able to control the supply of electricity to the brakes (F1-F3), a central processing unit (2), variable drives (V1, V2, V3) having a torque off function of the motors (M1-M3), a security system (4, 5),
the method comprising the following successive steps: 6a) selecting a motor (M1-M3), 6b) activating an electric braking function using the selected motor (M1-M3), 6c) opening the brake (F1-F3), 6d) comparing the movement information delivered by the sensor (C1-C3) to a threshold, 6e) closing the brake (F1-F3) when the movement information exceeds the threshold.