Method and system for measuring and managing inventory of product in a collapsible tank
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-017/00
G06N-005/00
출원번호
US-0561579
(2009-09-17)
등록번호
US-8195590
(2012-06-05)
발명자
/ 주소
Coggins, Keith R.
Holcomb, Dirk
Archer, Timothy L.
출원인 / 주소
Varec, Inc.
대리인 / 주소
King & Spalding LLP
인용정보
피인용 횟수 :
3인용 특허 :
6
초록▼
Measuring, controlling, and automating inventory of product stored in a collapsible tank. An interface device can interact with a sensor installed at the collapsible tank and a metering device, such as a flow meter, to generate a strap table for the collapsible tank. The strap table can include entr
Measuring, controlling, and automating inventory of product stored in a collapsible tank. An interface device can interact with a sensor installed at the collapsible tank and a metering device, such as a flow meter, to generate a strap table for the collapsible tank. The strap table can include entries that correlate a process value measured by the sensor to a volume of product corresponding to that process value. Current volume of product stored in the collapsible tank can be determined by comparing a current process value to entries in the strap table or by an interpolation process. The interface device can generate an updated strap table based on a relaxation curve to account for settling of the collapsible tank. The interface device can synchronize data with a host device, such as a personal computer or handheld computer, that includes software for tracking inventory in collapsible tanks.
대표청구항▼
1. A method for determining volume of a product stored in a collapsible container, the method comprising the steps of: performing a learning process on the collapsible container to generate a strap table comprising a plurality of table entries, each table entry comprising a process measurement measu
1. A method for determining volume of a product stored in a collapsible container, the method comprising the steps of: performing a learning process on the collapsible container to generate a strap table comprising a plurality of table entries, each table entry comprising a process measurement measured by a sensor associated with the collapsible container and a volume of product stored in the collapsible container corresponding to the process measurement;obtaining a current process measurement from the sensor;determining a first strap volume corresponding to the current process measurement by performing a linear interpolation on the strap table using the current process measurement;determining a second strap volume corresponding to the current process measurement by performing at least one polynomial interpolation on the strap table using the current process measurement; andselecting the first or second strap volume as the volume of product stored in the container. 2. The method of claim 1, wherein the step of determining a second strap volume comprises the steps of: generating an array of strap volumes by performing the at least one polynomial interpolation;estimating an error associated with each of the strap volumes in the array; andselecting one of the strap volumes in the array of strap volumes having the least estimated error as the second strap volume. 3. The method of claim 1, wherein the step of selecting the first or second strap volume comprises the steps of: determining if the second strap volume meets an error threshold relative to a linear interpolation of the strap table;selecting the second strap volume based on a determination that the second strap volume meets the error threshold; andselecting the first strap volume based on a determination that the second strap volume does not meet the error threshold. 4. The method of claim 1, further comprising the step of adjusting the strap table to account for the collapsible container relaxing with product stored in the collapsible container. 5. The method of claim 1, wherein the learning process is performed while filling the collapsible container and the learning process comprises the steps of: obtaining an initial process measurement from the sensor;storing the initial process measurement in an initial strap table entry with a corresponding volume of zero;storing additional entries in the strap table while supplying product to the collapsible container, each additional entry being added when the volume of product in the collapsible container reaches a target volume for that entry; andstoring a final entry in the strap table when the volume of product in the collapsible container reaches a final volume. 6. The method of claim 1, wherein the learning process is performed while emptying the collapsible container and the learning process comprises the steps of: obtaining an initial process measurement from the sensor;storing the initial process measurement in an initial strap table entry with a corresponding initial volume, the initial volume equal to the volume of product stored in the collapsible container when the initial process measurement is obtained;storing additional entries in the strap table while releasing product from the collapsible container, each additional entry being added when the volume of product in the collapsible container reaches a target volume for that entry; andstoring a final entry in the strap table when the volume of product in the collapsible container reaches a final volume. 7. The method of claim 1, wherein the sensor comprises a level sensor and the process measurement for each entry in the strap table comprises a level obtained from the level sensor when the collapsible container stored the volume of product for that entry. 8. The method of claim 1, wherein the sensor comprises a pressure sensor and the process measurement for each entry in the strap table comprises a pressure obtained from the pressure sensor when the collapsible container stored the volume of product for that entry. 9. A system for determining volume of a product stored in a collapsible tank, comprising: a process sensor for obtaining process measurements for the collapsible tank; andan interface device communicably coupled to the process sensor and to a metering device, the interface device operable to: perform a learning process on the collapsible tank to generate a strap table comprising a plurality of table entries, each table entry comprising one of the process measurements measured by the process sensor and a volume of product stored in the collapsible tank as determined by the interface device in conjunction with the metering device; anddetermine a current volume of product stored in the collapsible tank by obtaining a current process measurement from the process sensor and performing at least one polynomial interpolation on the strap table using the current process measurement. 10. The system of claim 9, wherein the interface device is further operable to perform a linear interpolation on the strap table using the current process measurement and wherein the interface device determines the current volume of product stored in the collapsible tank by selecting between a first strap volume determined from the at least one polynomial interpolation and a second strap volume determined from the linear interpolation. 11. The system of claim 10, wherein the interface device selects the first strap volume when the first strap volume meets an error criteria. 12. The system of claim 11, wherein the error criteria comprises an error band of process measurements relative to a linear interpolation of the strap table. 13. The system of claim 9, wherein the interface device is further operable to adjust the strap table to account for the collapsible tank relaxing with product stored in the collapsible container. 14. The system of claim 9, wherein the learning process is performed while filling the collapsible tank and the interface device is operable to perform the learning process by: obtaining an initial process measurement from the process sensor;storing the initial process measurement in an initial strap table entry with a corresponding volume of zero;storing additional entries in the strap table while supplying product to the collapsible tank, each additional entry being added when the volume of product in the collapsible tank reaches a target volume for that entry; andstoring a final entry in the strap table when the volume of product in the collapsible tank reaches a final volume. 15. The system of claim 9, wherein the learning process is performed while emptying the collapsible tank and the interface device is operable to perform the learning process by: obtaining an initial process measurement from the process sensor;storing the initial process measurement in an initial strap table entry with a corresponding initial volume, the initial volume equal to the volume of product stored in the collapsible tank when the initial process measurement is obtained;storing additional entries in the strap table while releasing product from the collapsible tank, each additional entry being added when the volume of product in the collapsible tank reaches a target volume for that entry; andstoring a final entry in the strap table when the volume of product in the collapsible tank reaches a final volume. 16. The system of claim 9, wherein the process sensor comprises a level sensor and the process measurement for each entry in the strap table comprises a level obtained from the level sensor for a volume of product held by the collapsible tank for each entry. 17. The system of claim 9, wherein the process sensor comprises a pressure sensor and the process measurement for each entry in the strap table comprises a pressure obtained from the pressure sensor for a volume of product held by the collapsible tank for each entry. 18. The system of claim 9, wherein the process sensor and the functions of the interface device are integrated as a single device. 19. A method for generating a strap table for a collapsible tank, the method comprising the steps of: performing a learning process on the collapsible tank to generate an initial strap table comprising a plurality of table entries, each table entry comprising a process measurement measured by a sensor associated with the collapsible tank and a volume of product stored in the collapsible tank corresponding to the process measurement;allowing the collapsible tank to store a relaxation volume of product for a time period; andgenerating an updated strap table to account for the collapsible tank settling during the time period. 20. The method of claim 19, wherein the step of generating an updated strap table comprises the steps of: determining a process value corresponding to the relaxation volume;determining an adjustment factor for the process measurements in the initial strap table; andapplying the adjustment factor to the process measurements in the strap table to generate the updated strap table. 21. The method of claim 20, wherein the step of determining a process value corresponding to the relaxation volume comprises the step of performing an interpolation process on the initial strap table and the relaxation volume to determine the process value corresponding to the relaxation volume. 22. The method of claim 21, wherein the step of performing the interpolation process comprises the steps of: determining a first process value corresponding to the relaxation volume by performing a linear interpolation on the initial strap table using the relaxation volume;determining a second process value corresponding to the relaxation volume by performing at least one polynomial interpolation on the initial strap table using the relaxation volume;determining if the second process value meets an error criteria;selecting the second process value as the process value based on a determination that the process value if the second strap volume complies with the error criteria; andselecting the first process value as the process value based on a determination that the second process value does not comply with the error criteria. 23. The method of claim 22, wherein the at least one polynomial interpolation is based on Neville's algorithm. 24. The method of claim 20, wherein the step of determining an adjustment factor for the process measurements in the initial strap table comprises the step of calculating a ratio between the process value and a current process measurement obtained from the sensor. 25. The method of claim 20, further comprising the steps of: determining a scaling factor based on characteristics of the collapsible tank; andrevising the adjustment factor using the scaling factor. 26. A method for determining volume of a product stored in a collapsible container, the method comprising the steps of: generating an initial strap table comprising a plurality of table entries, each table entry comprising a process measurement and a volume of product stored in the collapsible container corresponding to the process measurement;allowing the collapsible container to store a relaxation volume of product for a time period;generating an updated strap table to account for any relaxation of the collapsible container during the time period;obtaining a current process measurement from a sensor associated with the collapsible container; anddetermining a current volume of product in the collapsible container corresponding to the current process measurement using the updated strap table. 27. The method of claim 26, wherein the step of generating an updated strap table comprises the steps of: determining a process value corresponding to the relaxation volume;determining an adjustment factor for the process measurements in the initial strap table; andapplying the adjustment factor to the process measurements in the strap table to generate the updated strap table. 28. The method of claim 27, wherein the step of determining a process value corresponding to the relaxation volume comprises the step of performing an interpolation process on the initial strap table and the relaxation volume to determine the process value corresponding to the relaxation volume. 29. The method of claim 27, wherein the step of determining an adjustment factor for the process measurements in the initial strap table comprises the step of calculating a ratio between the process value and a current process measurement obtained from a sensor associated with the collapsible container.
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이 특허에 인용된 특허 (6)
Jannotta Louis J. (2800 E. Bernice Rd. Lansing IL 60438), Apparatus for monitoring and controlling vessels containing liquid.
Ferretti Michael D. (Nazareth PA) Gabel Brian L. (Northampton PA) Horton James A. (Bethlehem PA) Weiss ; Sr. Thomas S. (Emmaus PA) Miller Kevin K. (Breinigsville PA), Method and system for measurement of a liquid level in a tank.
McGarvey David C. (San Gabriel CA), System to monitor fuel level in a tank, and fuel dispensed from the tank, to determine fuel leakage and theft losses.
Weil, Roark D.; Hollander, Matthew J.; Garcia-Ortiz, Asdrubal; Maciejewski, William F., Methods and apparatuses for determining the volume of a substance in a flexible tank.
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