Methods and apparatus for weighing an article, such as a mail piece, while the article is moving at high speed. An article (900) is received from an intake transport (1200), and gripped in a weighing station (1310), in between a capstan roller and a pinch roller (1316), which are synchronized to min
Methods and apparatus for weighing an article, such as a mail piece, while the article is moving at high speed. An article (900) is received from an intake transport (1200), and gripped in a weighing station (1310), in between a capstan roller and a pinch roller (1316), which are synchronized to minimize slipping. A first precision servo system (1252, 1250) alters the speed of the article, and in the process acquires torque data for storage and analysis (1212, 1282). A second precision servo system (1260,1330) applies a constant force, via a tension arm (1320), urging the pinch roller (1316) against the capstan roller, independently of the thickness of the mail piece. Active electronic damping (1900) reduces oscillation when an inconsistency in thickness of the article is encountered during weighing. The damping force is subtracted from the capstan motor torque data for improved accuracy (FIG. 20B).
대표청구항▼
1. A method for weighing a moving article on the fly, comprising: receiving an incoming article having a first velocity;without stopping the article, gripping the article between a capstan roller and an opposed pinch roller;synchronizing rotation of the pinch roller and the capstan roller to avoid s
1. A method for weighing a moving article on the fly, comprising: receiving an incoming article having a first velocity;without stopping the article, gripping the article between a capstan roller and an opposed pinch roller;synchronizing rotation of the pinch roller and the capstan roller to avoid slippage of the article gripped between them;providing a capstan servo motor having a shaft operatively coupled to the capstan roller and opposed pinch roller;providing a first servo amplifier coupled to the capstan servo motor so as to form a first closed-loop servo system for driving the capstan servo motor and for monitoring torque applied by the capstan servo motor;in the first servo amplifier, commanding the capstan servo motor to a predetermined command speed that is different from the first velocity of the article in order to cause an acceleration of the article;beginning after the article is gripped between the pinch roller and the capstan roller, weighing the article on the fly by acquiring a series of capstan servo motor torque sample data as the article moves between the pinch roller and capstan roller, so that the captured torque data reflects the torque applied by the capstan servo motor to change the article speed from the first velocity to the command speed;storing the acquired torque sample data in a memory;providing a second closed-loop servo system arranged for controllably repositioning the pinch roller relative to the capstan roller to apply a controllable gripping force on the article as the article moves between the pinch roller and capstan roller, wherein the second closed-loop servo system provides an indication of a current position of the pinch roller as the article moves between the pinch roller and capstan roller;detecting a change in the current position of the pinch roller responsive to a change in thickness of the article as it moves along still gripped between the pinch roller and the capstan roller;correcting the stored capstan servo motor torque data to remove a torque error caused by the change in thickness of the article; andprocessing the corrected torque data to determine a weight of the article independently of the actual speed of the article. 2. The method of claim 1 including, in the second closed-loop servo system, actively damping the relative motion of the pinch roller and the capstan roller in order to reduce bouncing and capstan slippage while gripping the article. 3. The method of claim 2 including disabling said damping when moving the pinch roller away from the capstan roller to release the article. 4. The method of claim 2 wherein said actively damping includes: determining a velocity vector of the pinch roller position responsive to the indications of a current position;determining a sense of the velocity vector; andif the sense of the velocity vector indicates that the pinch roller is moving away from the capstan roller, enabling said active damping. 5. The method of claim 4 and further comprising: multiplying the velocity vector by a configurable damping gain factor to generate a damping signal; andwhile said active damping is enabled, adding the damping signal to a selected static torque setting to generate a modified torque command for driving the pinch roller toward the capstan roller to grip the article, wherein said adding step is configured so that the damping signal increases the magnitude of the selected static torque setting. 6. The method of claim 2 wherein said actively damping includes: providing a rigid tension arm;mounting the pinch roller to the tension arm;operatively mounting the tension arm to a tension arm motor for repositioning the tension arm and thereby repositioning the pinch roller relative to the capstan roller;driving the tension arm motor with the second closed-loop servo system to control the applied gripping force while the article is weighed; andin the second closed-loop servo system, electronically damping the tension arm motion. 7. The method of claim 6 including: in the second closed-loop servo system, receiving a tension arm command from a controller;if the tension arm command is to close the tension arm, driving the tension arm motor to force the pinch roller toward the capstan roller to grip the article; andif the tension arm command is to open the tension arm, driving the tension arm motor to move the pinch roller away from the capstan roller to release the article, and disabling the electronic damping. 8. The method of claim 6 wherein said correcting the stored capstan servo motor torque data includes subtracting an amount of torque attributable to the electronic damping of the tension arm motion resulting from the change in thickness of the article. 9. A method for weighing a moving article, comprising: receiving an incoming article having a first velocity;without stopping the article, gripping the article in an electro-mechanical gripping assembly, wherein the gripping assembly is rotatable so that it does not stop the moving article;driving the gripping assembly to a predetermined command speed that is different from the first velocity of the article in order to cause an acceleration of the article;monitoring a torque applied to the gripping assembly so as to acquire torque data responsive to the acceleration of the article;storing the acquired torque data in a memory;applying a controllable gripping force sufficient to retain the moving article in the gripping assembly at least during the acceleration of the article;monitoring a thickness of the article as it moves in the gripping assembly;detecting a change in the thickness of the article as it moves along still gripped in the gripping assembly;correcting the acquired torque data to remove a torque error caused by the change in thickness of the article; andprocessing the corrected torque data to determine a weight of the moving article independently of the actual speed of the article. 10. The method of claim 9 and further comprising: providing a first closed-loop servo system coupled to the gripping assembly for driving the gripping assembly to the predetermined command speed, and for said monitoring the torque applied to the gripping assembly. 11. The method of claim 10 and further comprising: providing a second closed-loop servo system coupled to the gripping assembly and arranged to provide the controllable gripping force sufficient to retain the moving article in the gripping assembly at least during the acceleration of the article. 12. The method of claim 11 and further comprising: actively damping the relative second closed-loop servo system in order to reduce bouncing and slippage while gripping the article. 13. The method of claim 12 including disabling said damping when releasing the article from the gripping assembly. 14. The method of claim 12 wherein said actively damping includes: detecting a change in thickness of the moving article; andenabling said active damping only if the change in thickness is an increase in thickness.
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이 특허에 인용된 특허 (74)
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