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Strain-Gauge Measurement of Weight of Fluid in a TankA method of determining the amount of fluid in a tank is based on measurement of strains induced in tank supports by the weight of the fluid. Unlike most prior methods, this method is nonintrusive: there is no need to insert instrumentation in the tank and, hence, no need to run wires, cables, or tubes through the tank wall. Also unlike most prior methods, this method is applicable even if the fluid in the tank is at supercritical pressure and temperature, because it does not depend on the presence of a liquid/gas interface (as in liquid-level-measuring methods). The strain gauges used in this method may be of two types: foil and fiber-optic. Four foil gauges (full bridge) are mounted on each of the tank-supporting legs. As the tank is filled or emptied, the deformation in each leg increases or decreases, respectively. Measured deformations of all legs are added to obtain a composite deformation indicative of the change in weight of the tank plus fluid. An initial calibration is performed by recording data at two points (usually, empty and full) for which the mass or weight of fluid is known. It is assumed that the deformations are elastic, so that the line passing through the two points can be used as a calibration curve of mass (or weight) of fluid versus deformation. One or more fiber-optic gauges may be used instead of the foil gauges. The resolution of the fiber-optic and foil gauges is approximately the same, but the fiber-optic gauges are immune to EMI (electromagnetic interference), are linear with respect to temperature over their entire dynamic range (as defined by the behavior of the sample), and measure thermally induced deformations as predictable signals. Conversely, long term testing has demonstrated that the foil gauges exhibit an erratic behavior whenever subjected to direct sun radiation (even if protected with a rubberized cover). Henceforth, for deployment in outdoor conditions, fiber-optic gauges are the only option if one is to rely on the system for an extended period of time when a recalibration procedure may not be acceptable. A set of foil gauges had been tested on the supports of a 500-gallon (1,900-liter) tank. The gauges were found to be capable of measuring the deformations (up to 22 micro-strain) that occurred during filling and emptying of the tank. The fluid masses calculated from the gauge readings were found to be accurate within 4.5 percent. However, the reliability of the foil gauges over a few hours was not acceptable. Therefore, the foil sensor system is acceptable for use only in controlled environments (complete shade, or indoors).
Document ID
20110016667
Acquisition Source
Stennis Space Center
Document Type
Other - NASA Tech Brief
External Source(s)
http://www.techbriefs.com/index.php?option=com_staticxt&staticfile=/Briefs/Mar04/SSC00187.html
Authors
Figueroa, Jorge (NASA Stennis Space Center Stennis Space Center, MS, United States)
St. Cyr, William (NASA Stennis Space Center Stennis Space Center, MS, United States)
Rahman, Shamim (NASA Stennis Space Center Stennis Space Center, MS, United States)
McVay, Gregory (Lockheed Martin Corp. Bay Saint Louis, MS, United States)
Van Dyke, David (Lockheed Martin Corp. Bay Saint Louis, MS, United States)
Mitchell, William (Lockheed Martin Corp. Bay Saint Louis, MS, United States)
Langford, Lester (Lockheed Martin Corp. Bay Saint Louis, MS, United States)
Date Acquired
August 25, 2013
Publication Date
March 1, 2004
Publication Information
Publication: NASA Tech Briefs, March 2004
Subject Category
Man/System Technology And Life Support
Report/Patent Number
SSC-00187
Distribution Limits
Public
Copyright
Public Use Permitted.

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IDRelationTitle20110016643Collected WorksNASA Tech Briefs, March 2004
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