Weighing a moving object using captured torque data
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01G-009/00
G01G-021/22
출원번호
US-0562798
(2009-09-18)
등록번호
US-8129635
(2012-03-06)
발명자
/ 주소
Turner, Bryan
출원인 / 주소
RAF Technology, Inc.
대리인 / 주소
Stolowitz Ford Cowger LLP
인용정보
피인용 횟수 :
9인용 특허 :
26
초록▼
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. Fourier analysis can conveniently be applied for analyzing the acquired current data and comparing to stored calibration data to determine weight. Weight is determined without regard to the actual speed of the moving article.
대표청구항▼
1. A method for weighing a moving article, comprising: receiving an incoming article having a first velocity;gripping the incoming article between a pinch roller and a capstan roller;synchronizing rotation of the pinch roller and the capstan roller to each other to avoid slippage of the article grip
1. A method for weighing a moving article, comprising: receiving an incoming article having a first velocity;gripping the incoming article between a pinch roller and a capstan roller;synchronizing rotation of the pinch roller and the capstan roller to each other to avoid slippage of the article gripped between them;providing a capstan servo motor having a shaft operatively coupled to the capstan roller so that the motor shaft and the capstan roller rotate in unison;providing a servo amplifier coupled to the capstan servo motor so as to form a closed-loop servo system for driving the motor and for monitoring actual torque applied by the motor;in the servo amplifier, prior to said gripping the article, commanding the servo motor to a predetermined, constant command speed that is different from the first velocity of the incoming article;beginning after the article is gripped between the pinch roller and the capstan roller, acquiring a series of capstan servo motor torque sample data as the mail piece moves through 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; andprocessing the acquired torque data to determine a weight of the article without regard to actual speed of the article. 2. A method according to claim 1 wherein said processing the acquired torque data includes: forming an acquired torque data waveform responsive to the acquired servo motor torque sample data; andcomparing the acquired torque data waveform to a stored calibration torque data waveform. 3. A method according to claim 2 wherein said comparing step includes: applying a Fourier transform to the acquired torque data waveform to determine acquired torque data waveform coefficients;applying a Fourier transform to the stored calibration torque data waveform to determine calibration coefficients; andcomparing the acquired torque data waveform coefficients to the calibration coefficients to determine the weight of the article. 4. A method according to claim 2 wherein applying a Fourier transform to the stored calibration torque data waveform to determine calibration coefficients is computed in advance, and the calibration coefficients stored in memory. 5. An in-line weighing apparatus comprising: an intake transport belt assembly arranged for moving a mail piece along a predetermined transport path at a predetermined intake transport speed;a weighing station positioned along the transport path to receive a mail piece from the intake transport assembly while the mail piece is moving at substantially the transport speed;the weighing station arranged for gripping a mail piece after the mail piece is released from the transport belt assembly;the weighing station including a capstan servo motor arranged to rotate in synchrony with the moving mail piece;a capstan servo controller coupled to the capstan servo motor to drive the capstan servo motor to a predetermined, constant command speed that is different from the transport speed;the capstan servo controller also arranged to acquire motor torque data from the capstan servo motor as the mail piece moves through the weighing station, so that the captured torque data reflects the torque applied by the servo motor to change the mail piece speed from the intake transport speed to the command speed; anda processor arranged to determine a weight of a mail piece from the captured torque data. 6. The in-line weighing apparatus according to claim 5 including: a pair of weigh belts in the weigh station, arranged for gripping a mail piece between them after the mail piece is released from the transport belt assembly;the capstan servo motor arranged to synchronously drive the pair of weigh belts; andthe servo controller arranged to acquire motor torque data from the capstan servo motor as the mail piece moves through the weighing station gripped between the pair of weigh belts, so that the captured torque data reflects the torque applied by the capstan servo motor to change the mail piece speed from the intake transport speed to the command speed. 7. The in-line weighing apparatus according to claim 6 and including: a first photocell positioned along the transport path for detecting when a mail piece enters the weighing station;a first set of repositionable guide rollers arranged for moving the weigh belts into proximity with one another for gripping the mail piece in between them;a second set of repositionable guide rollers arranged for moving the intake transport belts away from the mail piece so as to release it; anda scale system controller coupled to the first photocell for detecting when a mail piece enters the weighing station, and coupled to the first repositionable guide rollers for repositioning the guide rollers so as to move the weigh belts into proximity with one another for gripping the mail piece in between them responsive to a mail piece entering the weighing station, andthe scale system controller further coupled to the second repositionable guide rollers for repositioning the guide rollers so as to move the intake transport belts to release the mail piece responsive to the mail piece entering the weighing station, whereby the mail piece is gripped solely by the weigh belts during a weighing operation. 8. The in-line weighing apparatus according to claim 7 and including: a first memory for storing servo motor torque data acquired from the servo controller during a weighing operation;a second memory storing calibration data;and wherein the processor is coupled to the first and second memories for determining a weight of a mail piece by comparing the acquired motor torque data to the stored calibration data. 9. The in-line weighing apparatus according to claim 8 and wherein: the processor is arranged to calculate a Fourier transform of the acquired motor torque data;the stored calibration data comprises Fourier transform coefficients; andthe processor determines the weight by comparing the calculated Fourier transform of the acquired motor torque data to the stored calibration Fourier transform coefficients. 10. The in-line weighing apparatus according to claim 8 and wherein the torque data is acquired over a measurement period of less than approximately 70 msec in order to weigh a mail piece in real time at a typical transport speed. 11. The in-line weighing apparatus according to claim 10 and wherein the torque data acquired over a measurement period comprises a number of digital samples equal to an integral power of two samples. 12. The in-line weighing apparatus according to claim 8 and wherein the exit transport speed is equal to the intake transport speed. 13. The in-line weighing apparatus according to claim 8 and wherein the command speed is greater than the intake speed, so the mail piece is accelerated in the weighing station by the capstan servo motor, giving rise to a motor torque impulse. 14. The in-line weighing apparatus according to claim 8 and wherein the servo motor comprises an instrument grade, brushless AC servo motor with integrated encoder. 15. The in-line weighing apparatus according to claim 8 and wherein the weigh belts comprise an upper pair of weigh belts disposed above the transport belts, and a lower pair of weigh belts disposed below the transport belts. 16. An in-line weighing apparatus comprising: a primary transport belt assembly arranged for moving a mail piece along a predetermined transport path at a predetermined transport speed;the primary transport belt assembly including a pair of transport belts for gripping a mail piece between them, the pair of transport belts arranged to insert the mail piece into a weighing station and also routed around the weighing station and arranged to receive a mail piece when it exits the weighing station;a weighing station positioned along the transport path and located to receive a mail piece from the primary transport belt assembly for weighing the mail piece while the mail piece is moving along the transport path, by changing the speed of the mail piece;the weighing station including a pair of weigh belts arranged for gripping a mail piece between them for weighing;and the weighing station including means for capturing data that describes an impulse applied to a motor to change the speed of the mail piece while the mail piece is gripped by the weigh belts;a pair of secondary transport belts arranged for gripping a mail piece there-between as it exits the weighing station and moving the mail piece along the transport path at the predetermined transport speed;wherein the primary transport belts, and the secondary transport belts, are arranged so that none of them contacts the mail piece while the mail piece is gripped in the weighing station during a weighing operation. 17. The in-line weighing apparatus according to claim 16 including: a capstan servo motor arranged to synchronously drive the pair of weigh belts;a servo controller coupled to the capstan servo motor to control the capstan servo motor to a predetermined command speed that is different from the transport speed;the servo controller also arranged to acquire motor torque data from the capstan servo motor as the mail piece moves through the weighing station, so that the captured torque data reflects the torque applied by the capstan servo motor to change the mail piece speed from the intake transport speed to the command speed; anda processor arranged to determine a weight of a mail piece from the captured torque data. 18. The in-line weighing apparatus according to claim 17 and including: a first photocell positioned along the transport path for detecting when a mail piece enters the weighing station;a set of repositionable guide rollers arranged for moving the weigh belts into proximity with one another for gripping the mail piece in between them;the guide rollers arranged to reposition the weigh belts so that the mail piece is gripped between the weight belts and the secondary transport belts no longer contact the mail pieces; anda scale system controller coupled to the first photocell for detecting when a mail piece enters the weighing station, and coupled to the repositionable guide rollers for repositioning the guide rollers so as to move the weigh belts into proximity with one another for gripping the mail piece in between them responsive to a mail piece entering the weighing station. 19. The in-line weighing apparatus according to claim 18 and including: a first memory for storing servo motor torque data acquired from the servo controller during a weighing operation;a second memory storing calibration data;and wherein the processor is coupled to the first and second memories for determining a weight of a mail piece by comparing the acquired motor torque data to the stored calibration data. 20. The in-line weighing apparatus according to claim 19 and wherein: the processor is arranged to calculate a Fourier transform of the acquired motor torque data;the stored calibration data comprises Fourier transform coefficients; andthe processor determines the weight by comparing the calculated Fourier transform of the acquired motor torque data to the stored calibration Fourier transform coefficients. 21. The in-line weighing apparatus according to claim 19 and wherein the torque data is acquired over a measurement period of less than approximately 70 msec in order to weigh a mail piece in real time at a typical transport speed.
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이 특허에 인용된 특허 (26)
Nasuta ; Jr. Anthony T. (Timonium MD) Brown Dale H. (Glen Burnie MD), Apparatus and method for weighing moving objects.
Sansone Ronald P. (Weston CT) Keating Raymond (Purdys NY) Wall Joseph W. (Monroe CT) Durst ; Jr. Robert T. (Monroe CT), Certified weigher-short paid mail.
Doerman Eryk S. (45 Cromwell Road London SW7 2ED GB2) Turner William J. (83 Twyford Road Harrow ; Middlesex HA2 OSJ GB2) Homer David A. (35 Keble Road Maidenhead ; SL6 6BB GB2) Stewart Andrew D. G. (, LVDT displacement sensor with signal noise reduction for use in weighing apparatus.
Smithe Eliot S. (Hollidaysburg PA) Lambert Michael P. (Altoona PA) Wilkinson Jason H. (Altoona PA), Method and apparatus for controlling tension between variable speed driver rollers.
Hays Lisa M. ; Crowe John H. ; Crowe Lois M. ; Feeney Robert E. ; Oliver Ann E., Prevention of leakage and phase separation during thermotropic phase transition in liposomes and biological cells.
Doerman Eryk S. (45 Cromwell Road London SW7 2ED GB2) Turner William J. (83 Twyford Road Harrow ; Middlesex HA2 0SJ GB2) Homer David A. (35 Keble Road Maidenhead ; SL6 6BB GB2) Stewart Andrew D. G. (, Weighing a number of objects in succession.
Turner, Bryan, In-line conveyor scale with a primary first motor to provide constant torque, a secondary servo motor to provide fine-grained variable torque in response to a closed loop torque sensor, and a processor to assertain weight of an item conveved based on the closed loop servo motor response.
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