초록 ▼

A robot (1) having a workpiece mass measurement function for measuring the mass of a workpiece that is held, includes a force measurement unit (5) that measures the force that is applied to the tip part (2) of the mechanism part of the robot (1), and a mass estimation unit (11) that estimates the ma

A robot (1) having a workpiece mass measurement function for measuring the mass of a workpiece that is held, includes a force measurement unit (5) that measures the force that is applied to the tip part (2) of the mechanism part of the robot (1), and a mass estimation unit (11) that estimates the mass of the workpiece that is held by the robot (1), based on information about the force acquired by the force measurement unit (5) while the robot (1) is moving.

대표청구항 ▼

1. A robot having a workpiece mass measurement function for measuring a mass of a workpiece held by the robot, the robot comprising: a force measurement unit configured to measure a force applied to a tip part of a mechanism part of the robot; anda mass estimation unit configured to estimate the mas

1. A robot having a workpiece mass measurement function for measuring a mass of a workpiece held by the robot, the robot comprising: a force measurement unit configured to measure a force applied to a tip part of a mechanism part of the robot; anda mass estimation unit configured to estimate the mass of the workpiece held by the robot, based on the force measured by the force measurement unit while the robot is moving;whereinthe mass estimation unit comprises an acceleration acquiring unit configured to acquire, by measuring or estimating, an acceleration applied to the tip part of the mechanism part of the robot;the mass estimation unit is configured to estimate the mass of the workpiece held by the robot, based on an equation between the force measured by the force measurement unit while the robot is moving, the acceleration acquired by the acceleration acquiring unit and the mass of the workpiece held by the robot;the force measurement unit is configured to measure the force in a plurality of directions;the acceleration acquiring unit is configured to acquire the acceleration in the plurality of directions;the mass estimation unit is configured to estimate the mass with respect to the plurality of directions, so that the mass corresponding to a direction where an absolute value of the acceleration is greatest, among the plurality of directions, is made a mass estimation value of the mass of the workpiece, andat a given time, the force measurement unit is configured to measure force values of the force in the plurality of directions,the acceleration acquiring unit is configured to acquire acceleration values of the acceleration in the plurality of directions,the mass estimation unit is configured to determine the greatest absolute value, among the acquired acceleration values, as corresponding to one direction among the plurality of directions, andthe mass estimation unit is configured to use the force value and the acceleration value in said one direction to estimate the mass of the workpiece. 2. The robot as defined in claim 1, wherein the force measurement unit is configured to estimate the mass of the workpiece based on a force measurement value of the force measured by the force measurement unit when the workpiece is held by the robot, anda force measurement value of the force measured by the force measurement unit when the workpiece is not held by the robot. 3. The robot as defined in claim 1, wherein a posture of the tip part of the mechanism part is not changed while the robot is moving. 4. The robot as defined in claim 1, wherein an average value of a plurality of masses of the workpiece estimated by the mass estimation unit at a plurality of times while the robot is moving, is made a mass estimation value of the mass of the workpiece. 5. The robot as defined in claim 1, wherein the acceleration acquiring unit is configured to calculate the acceleration by a dynamics equation. 6. The robot as defined in claim 1, wherein the acceleration acquiring unit is configured to acquire the acceleration measured by an acceleration sensor attached to the robot. 7. The robot as defined in claim 1, wherein the mass estimation unit is configured to estimate the mass of the workpiece held by the robot, based on the force measured by the force measurement unit while the tip part of the mechanism part is moving on a plane perpendicular to a direction of a gravitational force applied to the tip part of the mechanism part of the robot without changing the posture of the tip part. 8. The robot as defined in claim 1, wherein the mass estimation unit is configured to estimate the mass of the workpiece held by the robot, based on the force measured by the force measurement unit while the tip part of the mechanism part of the robot is moving on a linear path at constant speed. 9. The robot as defined in claim 7, further comprising: a posture acquiring unit configured to acquire a posture of the tip part of the mechanism part of the robot,wherein the mass estimation unit is configured to estimate the mass of the workpiece held by the robot, based on the forces measured by the force measurement unit in the plurality of directions and the posture acquired by the posture acquiring unit. 10. The robot as defined in claim 8, further comprising: a posture acquiring unit configured to acquire a posture of the tip part of the mechanism part of the robot,wherein the mass estimation unit is configured to estimate the mass of the workpiece held by the robot, based on the forces measured by the force measurement unit in the plurality of directions and the posture acquired by the posture acquiring unit.