Method and device for optically determining a filling level in liquid-filled containers
원문보기
IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0369084
(2003-02-18)
|
우선권정보 |
DE-0006824 (2002-02-18) |
발명자
/ 주소 |
|
출원인 / 주소 |
- Kautex Textron GmbH &
- Co. KG
|
대리인 / 주소 |
Grossman Tucker Perreault &
|
인용정보 |
피인용 횟수 :
10 인용 특허 :
10 |
초록
▼
In a method of optically determining a level of liquid in a liquid-filled container a light guide body projects into the container. The light guide body has an end face for the entry and exit of light and stepped side faces forming separate reflection faces. The light is totally reflected at those r
In a method of optically determining a level of liquid in a liquid-filled container a light guide body projects into the container. The light guide body has an end face for the entry and exit of light and stepped side faces forming separate reflection faces. The light is totally reflected at those reflection faces which are not immersed in the liquid but refracted into the liquid at immersed reflection faces. The totally reflected light is reflected back to the end face. The intensity of the light beam reflected totally by each reflection face back to the end face is measured separately. Measurement signals for determining the filling level are subjected to plausibility checking to recognise and eliminate measurement faults and errors. The invention can be used for determining the level of liquid in a container or tank for fuel, washing water, oil, hydraulic fluid and the like in a motor vehicle.
대표청구항
▼
1. A method of determining a filling level in a liquid-filled container using a light guide body which projects into the volume of the container and which has an end face for the entry and exit of light and side faces providing reflection faces separated by steps,wherein light introduced into the li
1. A method of determining a filling level in a liquid-filled container using a light guide body which projects into the volume of the container and which has an end face for the entry and exit of light and side faces providing reflection faces separated by steps,wherein light introduced into the light guide body at said end face is totally reflected at those reflection faces which are not immersed in liquid in the container but is refracted into the liquid at immersed reflection faces, wherein light totally reflected by a reflection face is reflected back to the end face as a light beam, and wherein at least one measurement signal of the intensity of the light beam totally reflected is provided for each step and separately detected as a separate measurement of the intensity of the light reflected by each step relative to other steps, said at least one measurement signal being evaluated and checked, said evaluation and checking including plausibility checking for recognizing and eliminating measurement errors. 2. A method as set forth in claim 1wherein the at least one measurement signal for each light beam reflected totally by a reflection face and back to the end face is effected by means of at least one photosensor. 3. A method as set forth in claim 2wherein the measurement signals of the totally reflected light are passed to a display unit to display the filling level of liquid in the container. 4. A method as set forth in claim 1wherein the evaluation operation includes correction in respect of at least one of the effects consisting of light attenuation in the light guide body, noise and scatter light. 5. A method as set forth in claim 1wherein at least one reference signal is produced and evaluated, and the reference signal is reflected completely independently of the filling level of liquid in the container. 6. A method as set forth in claim 5wherein a respective reference signal which is independent of said filling level is produced for a longest and a shortest signal path through the light guide body and evaluated. 7. A method as set forth in claim 1wherein for each reflection face a reference signal reflected independently of said filling level is produced and evaluated. 8. A method as set forth in claim 1wherein the light guide body is of rectangular cross-section. 9. A method as set forth in claim 1wherein the light guide body is of square cross-section. 10. The method of claim 1, wherein said plausibility checking comprises evaluating the measurement signal from a reflection face and identifying whether or not said reflection face is signaling full under conditions where a lower reflection face is signaling empty.11. Device for determining a filling level in a liquid-filled container, includinga light guide body which is adapted in operation of the device to project into the internal volume of the container, the light guide body being of rectangular cross-section and having an end face with an entry region for the entry of light into the light guide body and an exit region for the exit of light from the light guide body and first and second side faces each comprising steps providing at least two reflection faces, the reflection faces at the one side face being associated with respective reflection faces at the other side face, wherein the reflection faces of the first side face are at least in part such that light entering the light guide body at said entry region is refracted into the liquid when the reflection face in question is immersed in the liquid but is totally reflected back into the light body in a direction towards the second side face thereof when the reflection face in question is not immersed in the liquid and the light totally reflected by a reflection face at said first side face is reflected by the respectively associated reflection face at the second side face in a direction towards the exit region of said end face, measuring means for providing at least one measurement signal of the intensity of a light beam totally reflected by each said reflection face of said second side face wherein said measurement signal is separately detected as a separate measurement of the intensity of the light reflected by each step relative to other steps, and an evaluation means for implementing a plausibility check in respect of signals from said measuring means for recognizing and eliminating measurement errors. 12. Device as set forth in claim 11wherein the reflection faces of the first side face are permanently reflective. 13. Device as set forth in claim 11wherein the reflection faces of the second side face are permanently reflective. 14. Device as set forth in claim 11wherein the reflection faces of the first side face are at least in part of a permanently reflective nature in a portion thereof. 15. Device as set forth in claim 11wherein the reflection faces of the second side face are at least in part of a permanently reflective nature in a portion thereof. 16. Device as set forth in claim 11wherein the measuring means are disposed on the light exit region of said end face. 17. Device as set forth in claim 11wherein the measuring means are disposed in the light exit region of said end face. 18. Device as set forth in claim 11wherein said reflection faces form an angle of substantially 45° with the direction of incident light. 19. Device as set forth in claim 11wherein said measuring means includes at least one photosensor for each reflection face. 20. Device as set forth in claim 19wherein said measuring means comprises a line sensor. 21. Device as set forth in claim 11 includinga light source for providing light for said light guide body, wherein said measuring means comprises a photosensor measuring means; and wherein a limit band of the light source, a light guide spectrum of said light guide body and a sensitivity spectrum of said photosensor measuring means are matched to each other. 22. The device according to claim 11, wherein said plausibility check implemented by said evaluation means comprises evaluating the measurement signal from a reflection face and identifying whether or not said reflection face is signaling full under conditions where a lower reflection face is signaling empty.23. Device for determining a filling level in a liquid-filled container, includinga light guide body which is adapted in operation of the device to project into the internal volume of the container, having an end face with an entry region for the entry of light into the light guide body and an exit region for the exit of light from the light guide body and a side face comprising steps providing at least two at least substantially annular reflection faces, wherein said reflection faces are so designed at least over a portion of a periphery of said reflection faces that light entering the light guide body at the entry region is refracted into the liquid at a respective reflection face when the reflection face in question is immersed in the liquid but is totally reflected back into the light guide body in a direction on to the oppositely disposed region of the reflection faces and from there further to said end face when the said reflection face is not immersed in the liquid, measuring means for providing at least one measurement signal of the intensity of each respective light beam totally reflected by each step to said end face wherein said measurement signal is separately detected as a separate measurement of the intensity of the light reflected by each step relative to other steps, and an evaluation means for implementing a plausibility check in respect of signals from said measuring means for recognizing and eliminating measurement errors. 24. Device as set forth in claim 23wherein at least some of the reflection faces are of a permanently reflective nature over a part of the periphery of said reflection faces. 25. Device as set forth in claim 23wherein said light guide body is of a circular cross-section. 26. Device as set forth in claim 23wherein the measuring means are disposed on the light exit region of said end face. 27. Device as set forth in claim 23wherein the measuring means are disposed in the light exit region of said end face. 28. Device as set forth in claim 23wherein said reflection faces form an angle of substantially 45° with the direction of incident light. 29. Device as set forth in claim 23wherein said measuring means includes at least one photosensor for each step. 30. Device as set forth in claim 23wherein said measuring means comprises a line sensor. 31. Device as set faith in claim 23 includinga light source for providing light for said light guide body, wherein a limit band of the light source, a light guide spectrum of said light guide body and a sensitivity spectrum of a photosensor measuring means are matched to each other. 32. The device according to claim 23, wherein said plausibility check implemented by said evaluation means comprises evaluating the measurement signal from a reflection face and identifying whether or not said reflection face is signaling full under conditions where a lower reflection face is signaling empty.33. Device for determining a filling level in a liquid-filled container, includingan elongate light guide body having a side surface and an end face with an entry region for the entry of light into the light guide body and an exit region for the exit of light from the light guide body, the light guide body further comprising steps at said side surface defining at least two reflection faces at a spacing in the direction of elongation of the light guide body, means for mounting the light guide body to a said container in a position such that the light guide body projects into an internal volume of the container, an arrangement of said light guide body and said means for mounting being such that in operation light entering the light guide body at said entry region is refracted into the liquid at a said reflection face immersed in the liquid but at a said reflection face clear of the liquid said light is totally reflected back into the light guide body on to the side surface at a location in opposite relationship to the location of its reflection and is totally reflected therefrom in a direction towards the exit region of said end face, measuring means for providing at least one measurement signal of the intensity of the light beam totally reflected at a step which is clear of the liquid wherein said measurement signal is separately detected as a separate measurement of the intensity of the light reflected by each step relative to other steps, and an evaluation means for implementing a plausibility check in respect of signals from said measuring means for recognizing and eliminating measurement errors. 34. The device according to claim 33, wherein said plausibility check implemented by said evaluation means comprises evaluating the measurement signal from a reflection face and identifying whether or not said reflection face is signaling full under conditions where a lower reflection face is signaling empty.
이 특허에 인용된 특허 (10)
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Powell Frederic D. (Middlebury VT), Combination water contaminant and fuel density detector.
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Grossiord Claude (Annecy FRX), Device for detecting the liquid level in a tank, particularly a lighter tank and tank provided with such device.
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Eisele Ronald (Daenisch-Nienhof DEX), Device for optoelectronic interface measurement and refractometry in liquids.
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David R. Nowak ; Ryan Lindsay, Fluid level indicator.
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Weiss Jonathan D., Fluorescent optical liquid level sensor.
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Henry James W. (Kingsport TN), Measurement of material level in vessels.
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Nemeth Frank A. (Harwinton CT), Multi-level fiber-optic liquid-level sensing system.
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Ellinger Sylvester M. (Charlotte VT) Kline Bruce R. (Starksboro VT), Optical fuel/air/water sensor and detector circuit.
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Modlin Douglas N. ; Jansen Jan Frederik ; Jansen Renee, Optical level sensor.
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Bruhl J. D. (2074 Audubon Dr. Glendale Heights IL 60137) Geisinger William R. (204 Parkchester Rd. Elk Grove IL 60007), Volumetric leak detection means and method.
이 특허를 인용한 특허 (10)
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Zhao, Ying; She, Jun, Apparatuses and methods for managing liquid volume in a container.
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Coates, John; Qualls, Robert, Low-temperature safe sensor package and fluid properties sensor.
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Coates, John; Qualls, Robert, Optical devices for fluid sensing and methods therefor.
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Coates, John; Qualls, Robert, Optical sensing device for fluid sensing and methods therefor.
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Grinderslev, Soren; Stouklov, Igor; Benton, Mark, Optical sensor for detecting accumulation of a material.
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Dietz, Paul; Eidelson, Benjamin David, Optically monitoring fullness of fluid container.
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Wu, Bo-Yi; Liao, Chi-Fan; Liu, Ciu-Hsing; Cheng, Chao-Kai, Self-alignment filling level detecting device.
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Perrelli, Jonathon E.; Wheatley, David J.; Metlen, Todd; Wheatley, Maxim D.; Bacon, Connor J., System and apparatus for optimizing hydration and for the contextual dispensing of additives.
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Kious, Kennebec Miles, System for automatically identifying power system type and identifying likely errors of wiring and connection.
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Perrelli, Jonathon E.; Wheatley, David J.; Wheatley, Maxim D.; Metlen, Todd; Bacon, Connor J., System, method, and apparatus for dispensing variable quantities of additives and controlling characteristics thereof in a beverage.
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