Provided is a control system of an industrial robot that enables a robot to be stopped safely while reducing a load on a mechanical unit and avoiding interference with the peripheral environment when a command for which an excessive load is applied to the mechanical unit of the robot is received. A control system of an industrial robot includes: a setting unit configured to set in advance a first threshold value, a second threshold value smaller than the first threshold value, and a grace time; a determination unit configured to determine whether a command signal for controlling a robot has exceeded the first threshold value or the second threshold value; and a control unit configured to, in a case in which the command signal is determined as exceeding the second threshold value by the determination unit, continues the control according to the command only during the period until a grace time elapses since exceeding the second threshold value, and stop the robot at a timing at which an operation speed of the robot becomes equal to or less than a predetermined operation speed that is determined in advance.

When a first condition that a time in which magnitude of a first detection force detected by a force detection unit is larger than a first force threshold value continued for a time longer than zero and shorter than a first time threshold value is satisfied in teaching, a movable unit is moved in a predetermined amount in a direction according to a direction of the first detection force. When a second condition that magnitude of a second detection force detected by the force detection unit is larger than a second force threshold value that is larger than the first force threshold value is satisfied during movement of an end effector, the movable unit is decelerated or stopped.

A robot system causing a robot to operate in response to a handling force, wherein a position of the robot can be adjusted with higher accuracy. In one aspect of the present disclosure, a robot system includes a robot having a handle, a force sensor configured to detect a handling force applied to the handle, and an inching motion execution section configured to execute an inching motion of causing the robot to move by a movement amount determined in response to the handling force detected by the force sensor.

A robot system causing a robot to operate in response to a handling force, wherein a position of the robot can be adjusted with higher accuracy. In one aspect of the present disclosure, a robot system includes a robot having a handle, a force sensor configured to detect a handling force applied to the handle, and an inching motion execution section configured to execute an inching motion of causing the robot to move by a movement amount determined in response to the handling force detected by the force sensor.

Provided is a control system of an industrial robot that enables a robot to be stopped safely while reducing a load on a mechanical unit and avoiding interference with the peripheral environment when a command for which an excessive load is applied to the mechanical unit of the robot is received. A control system of an industrial robot includes: a setting unit configured to set in advance a first threshold value, a second threshold value smaller than the first threshold value, and a grace time; a determination unit configured to determine whether a command signal for controlling a robot has exceeded the first threshold value or the second threshold value; and a control unit configured to, in a case in which the command signal is determined as exceeding the second threshold value by the determination unit, continues the control according to the command only during the period until a grace time elapses since exceeding the second threshold value, and stop the robot at a timing at which an operation speed of the robot becomes equal to or less than a predetermined operation speed that is determined in advance.

When a first condition that a time in which magnitude of a first detection force detected by a force detection unit is larger than a first force threshold value continued for a time longer than zero and shorter than a first time threshold value is satisfied in teaching, a movable unit is moved in a predetermined amount in a direction according to a direction of the first detection force. When a second condition that magnitude of a second detection force detected by the force detection unit is larger than a second force threshold value that is larger than the first force threshold value is satisfied during movement of an end effector, the movable unit is decelerated or stopped.

A robot learning system for trajectory learning of a robot (RB) having a robot arm between a base and a tool center point (TCP). A user interface allows the user to control the robot arm in order to follow a desired trajectory during a real-time. A probe sensor (PS) is mounted on the TCP during the learning session. The probe sensor (PS) measures a distance parameter (Z) indicative of distance from the TCP and a surface forming the trajectory to be followed, and an orientation parameter (X, Y) indicative of orientation of the TCP and the surface forming the trajectory to be followed. These distance and orientation data are provided as a feedback to the controller of the robot (CTL) during the real-time learning session, thereby allowing the robot controller software to assist the user in following a desired trajectory in a continuous manner. Especially, the probe sensor (PS) may have a displaceable tip (TP) to follow a surface and having a neutral or center position, and where the robot controller software controls the robot movements to seek the neutral or center position irrespective of the user's control inputs. Data (DT) is logged during the learning session, so as to allow later control of the robot (RB) in response to the data (DT) logged during the learning session.