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The present invention provides a probe having a resistance that varies with temperature and is operable to determine the quantity of a fluid, such as hydrogen, in a storage tank, such as a cryogenic storage tank. The probe relies upon differing heat transfer rates for the gaseous and liquid phases o

The present invention provides a probe having a resistance that varies with temperature and is operable to determine the quantity of a fluid, such as hydrogen, in a storage tank, such as a cryogenic storage tank. The probe relies upon differing heat transfer rates for the gaseous and liquid phases of the fluid and a change in resistance due to a change in temperature of the probe to ascertain the quantity of fluid within the storage tank. The probe can be configured to account for the geometry of the storage tank thereby providing a linearized signal indicative of the quantity of fluid in the storage tank.

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What is claimed is: 1. A level sensor for detecting a quantity of a fluid in a tank, the sensor comprising: a resistor having a resistance that varies as a function of a temperature of said resistor, said resistor having a shape that compensates for a varying geometry of the tank, and said resistor

What is claimed is: 1. A level sensor for detecting a quantity of a fluid in a tank, the sensor comprising: a resistor having a resistance that varies as a function of a temperature of said resistor, said resistor having a shape that compensates for a varying geometry of the tank, and said resistor includes a wire having a substantially serpentine shape; a power source operable to supply at least one of a constant voltage drop across and a constant current to said resistor for a predetermined period; and a measuring component operable to measure at least one of a current flow through said resistor when supplied with said constant voltage drop and a voltage drop across said resistor when supplied with said constant current during said predetermined period. 2. The sensor of claim 1, wherein said serpentine-shaped wire has a plurality of segments of varying lengths. 3. The sensor of claim 2, wherein said varying lengths of said segments compensate for the geometry of the tank. 4. The sensor of claim 1, wherein said resistor is mounted on a frame. 5. The sensor of claim 1, wherein said resistor is substantially vertically oriented in the tank. 6. The sensor of claim 1, wherein said resistor is diagonally oriented in the tank. 7. The sensor of claim 1, wherein the fluid has a dielectric property. 8. The sensor of claim 1, wherein said shape of said resistor is configured to compensate for a non-linearly varying volumetric capacity of the tank. 9. A level sensor for detecting a quantity of a fluid in a tank, the sensor comprising: a resistor having a resistance that varies as a function of a temperature of said resistor, said resistor having a shape that compensates for a varying geometry of the tank, and said resistor includes a wire having a substantially coil shape; a power source operable to supply at least one of a constant voltage drop across and a constant current to said resistor for a predetermined period; and a measuring component operable to measure at least one of a current flow through said resistor when supplied with said constant voltage drop and a voltage drop across said resistor when supplied with said constant current during said predetermined period. 10. The sensor of claim 9, wherein said coil shaped wire has a pitch that varies. 11. The sensor of claim 10, wherein said varying pitch of said coil shaped wire compensates for a geometry of the tank. 12. A method of determining a quantity of a fluid in a tank, the method comprising: (a) positioning a generally coil-shaped resistor with a pitch that varies and having a resistance that varies with a temperature of said resistor in the tank and in contact with the fluid, said resistor being oriented so that said varying pitch of said resistor compensates for said geometry of the tank; (b) inducing current flow through said resistor during a predetermined period of time; (c) measuring a characteristic of said resistor in response to said current flow over said predetermined period of time; and (d) ascertaining a quantity of the fluid in the tank based on said measured characteristic during said predetermined period of time. 13. The method of claim 12, wherein (b), (c) and (d) are performed more than once and further comprising allowing a temperature of said resistor to substantially equalize with a temperature of the fluid between each performance of (b). 14. The method of claim 12, wherein (b) includes inducing said current flow by supplying one of a constant voltage drop across and a constant current to said resistor, and (c) includes measuring one of a current flow through said resistor when supplied with said constant voltage drop and a voltage drop across said resistor when supplied with said constant current. 15. The method of claim 12, wherein (d) includes comparing said measured characteristic to empirical data to ascertain the quantity. 16. The method of claim 12, wherein (d) includes ascertaining the quantity by using an algorithm to determine a best fit to a curve of said measured characteristic over said predetermined period of time. 17. The method of claim 12, wherein the tank is a cryogenic storage tank and the fluid is hydrogen. 18. The method of claim 12, wherein (d) includes ascertaining a quantity of a fluid having a dielectric property. 19. A method of determining a guantity of a fluid in a tank, the method comprising: (a) positioning a generally serpentine-shaped resistor with a plurality of segments of varying lengths and having a resistance that varies with a temperature of said resistor in the tank and in contact with the fluid, said resistor being oriented so that said varying lengths of said segments of said resistor compensates for said geometry of the tank; (b) inducing current flow through said resistor during a predetermined period of time; (c) measuring a characteristic of said resistor in response to said current flow over said predetermined period of time; and (d) ascertaining a guantity of the fluid in the tank based on said measured characteristic during said predetermined period of time. 20. A method of determining a quantity of a fluid in a tank, the method comprising: (a) positioning a resistor having a resistance that varies with a temperature of said resistor in the tank and in contact with the fluid; (b) inducing current flow throuah said resistor during a predetermined period of time; (c) measuring a characteristic of said resister in response to said current flow ever said predetermined period of time; and (d) ascertaining a quantity of the fluid in the tank based on said measured characteristic during said predetermined period of time and compensating for a pressure level in the tank.