Abstract: A safety monitoring device monitoring a robot includes a workpiece parameter switching unit switching a workpiece parameter, an external force estimation unit estimating, as an external force estimation value, a force acting on the robot from an external environment by using the workpiece parameter, an external force monitoring unit stopping the robot when the external force estimation value satisfies an external force determination condition, an operation monitoring unit stopping the robot, based on conditions such as a position of the robot being included within a predetermined region, an operation monitoring state switching unit switching between a disabling command and an enabling command for the operation monitoring unit, and an external force determination condition setting unit switching the external force determination condition to an operation monitoring disabling time external force determination condition at the disabling command and to an operation monitoring enabling time external force determina

Abstract: A safety monitoring device for a robot includes a position detecting unit for detecting the position of a robot, a force detecting unit for detecting an external force applied to the position detecting unit, an external force determination condition setting unit, which sets, as an external force determination condition, an intra-region external force determination condition when the present position of the robot detected by the position detecting unit remains within a predetermined region and which sets, as an external force determination condition, an out-of-region external force determination condition when the present position of the robot is outside of the predetermined region, and a robot stopping unit for stopping the robot when the external force detected by the force detecting unit satisfies the external force determination condition.

Abstract: There is provided a robot control device enabling a robot to carry various types of objects without exceeding an allowable weight thereof. The robot control device for controlling the robot for carrying an object in cooperation with a person includes a force acquisition part configured to acquire force applied from the object to the robot when the object is lifted, a comparison part configured to compare a force component in a gravity direction of the force acquired by the force acquisition part with a first threshold value predetermined with respect to the force component, and a stop command part configured to stop the robot when the force component is greater than the first threshold value.

Abstract: A human-collaborative robot system includes a detection unit that directly or indirectly detects a physical quantity which is changed in response to contact force applied to a robot when the robot comes in contact with an external environment, and a stop command unit that compares the physical quantity detected by the detection unit with a first threshold value and a second threshold value greater than the first threshold value, stops the robot according to a predetermined stop method when the physical quantity is equal to or greater than the first threshold value and is smaller than the second threshold value, and stops the robot in a shorter period of time as compared with the predetermined stop method when the physical quantity is equal to or greater than the second threshold value.

Abstract: A robot control apparatus comprises a contact detection unit which judges whether or not a robot is in contact with an object other than the robot, and an operation direction monitor unit which detects an operation direction of the robot after the robot comes in contact with the object and monitors operation of the robot. After the robot comes in contact with the object, the operation direction monitor unit permits operation of the robot being within a permissible range and inhibits operation of the robot falling outside the permissible range.

Abstract: A human cooperation robot system includes: an external force detecting unit that detects an external force acting on a robot; a retreat operation commanding unit that commands a retreat operation for causing the robot to be moved in a direction such that the external force is decreased when the external force detected by the external force detecting unit is greater than a first threshold value; and an external force variation monitoring unit that stops the retreat operation when a variation width of the external force at a predetermined time after the retreat operation is commanded by the retreat operation commanding unit is smaller than a second threshold value.

Abstract: A human cooperation robot system includes: an external force detecting unit that detects an external force acting on a robot; a retreat operation commanding unit that commands a retreat operation for causing the robot to be moved in a direction such that the external force is decreased when the external force detected by the external force detecting unit is larger than a first threshold value; a position acquiring unit that a current position of the robot; and a retreat operation stopping unit that stops the retreat operation when the current position of the robot acquired by the position acquiring unit departs from a retreat area.

Abstract: A robot control device includes: an internal force estimating unit; a storage unit in which, in each small region of a rotational operation region of a plurality of joints of a robot arm, an internal force estimated by the internal force estimating unit is subtracted from an output of the force sensor in a state in which the robot arm is not in contact with an external environment, thereby storing a force correction amount; a force correction amount determining unit in which a force correction amount corresponding to each of the current angles of the plurality of joints of the robot arm is determined; and a contact force calculating unit in which a contact force when the robot arm is in contact with an external environment is calculated by subtracting an internal force and the force correction amount from a current output of the force sensor.

Abstract: A human-collaborative robot system includes a detection unit that directly or indirectly detects a physical quantity which is changed in response to contact force applied to a robot when the robot comes in contact with an external environment, and a stop command unit that compares the physical quantity detected by the detection unit with a first threshold value and a second threshold value greater than the first threshold value, stops the robot according to a predetermined stop method when the physical quantity is equal to or greater than the first threshold value and is smaller than the second threshold value, and stops the robot in a shorter period of time as compared with the predetermined stop method when the physical quantity is equal to or greater than the second threshold value.

Abstract: A multi-joint robot using substantially one sensor, capable of performing a proper repositioning motion of an arm of the robot. The controller has a disturbance torque estimating part which estimates a first disturbance torque and a second disturbance torque, by calculating a torque generated by a mass and motion of the robot and subtracting the calculated torque from the first torque and the second torque detected by a torque detecting part. The controller has a repositioning commanding part which generates a motion command for rotating each axis so that the disturbance torque is reduced, when the disturbance torque exceeds a torque threshold. Since the axis is repositioned based on the motion command, a portion of the robot pushed by the operator is repositioned, whereby the operator can easily perform one's work without using a teaching board, etc.

Abstract: A conveying system includes an external force calculation unit which calculates an external force applied to a robot based on a force or torque applied to the robot detected by a force detection unit, and workpiece parameters changed in accordance with the holding state of a workpiece, and a robot stopping unit which stops the robot when the calculated external force exceeds a threshold. The conveying system further includes a relative movement unit which moves the held workpiece and a workpiece support relative to each other. By the relative movement unit, the workpiece and workpiece support are moved relative to each other without changing the position and posture of the robot.

Abstract: A safety monitoring device monitoring a robot includes a workpiece parameter switching unit switching a workpiece parameter, an external force estimation unit estimating, as an external force estimation value, a force acting on the robot from an external environment by using the workpiece parameter, an external force monitoring unit stopping the robot when the external force estimation value satisfies an external force determination condition, an operation monitoring unit stopping the robot, based on conditions such as a position of the robot being included within a predetermined region, an operation monitoring state switching unit switching between a disabling command and an enabling command for the operation monitoring unit, and an external force determination condition setting unit switching the external force determination condition to an operation monitoring disabling time external force determination condition at the disabling command and to an operation monitoring enabling time external force determina

Abstract: A robot control device includes: an internal force estimating unit; a storage unit in which, in each small region of a rotational operation region of a plurality of joints of a robot arm, an internal force estimated by the internal force estimating unit is subtracted from an output of the force sensor in a state in which the robot arm is not in contact with an external environment, thereby storing a force correction amount; a force correction amount determining unit in which a force correction amount corresponding to each of the current angles of the plurality of joints of the robot arm is determined; and a contact force calculating unit in which a contact force when the robot arm is in contact with an external environment is calculated by subtracting an internal force and the force correction amount from a current output of the force sensor.

Abstract: With an object to seek parameters of a biological model corresponding to individual patients, the present invention provides a biological simulation system comprises an internal parameter set generating section which generates internal parameter sets constituting a biological model, and a biological model computing section computing output of a biological model which emulates a biological response of a biological organ based on the generated internal parameter set, wherein the internal parameter set generating section comprises a means for automatically generating a plurality of different internal parameter sets, and a selecting means which determines an approximation between a biological model output calculated applying the automatically generated internal parameter set and an actual biological response corresponding to said output and which selects an appropriate internal parameter set from a plurality of the generated internal parameter sets.

Abstract: A system for computer simulation of object material concentration in a living body using a biological simulation model configured by a blocks readily corresponding to organs of a living body is provided. The functions of organs in a living body related to the object material are described using the biological simulation model to simulate the change over time in the object material concentration in a living body using a computer. The blocks are mutually linked so as to enable the transference of data among blocks. A computer-readable storage medium is also disclosed.