SBIR-STTR Award

Active Fiber Optic Sensor Array for Cryogenic Fuel Monitoring and Management
Award last edited on: 3/19/2024

Sponsored Program
STTR
Awarding Agency
NSF
Total Award Amount
$649,316
Award Phase
2
Solicitation Topic Code
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Principal Investigator
Philip R Swinehart

Company Information

Lake Shore Cryotronics Inc (AKA: Desert Cryogenics)

575 McCorkle Boulevard
Westerville, OH 43082
   (614) 891-2243
   info@lakeshore.com
   www.lakeshore.com

Research Institution

University of Pittsburgh

Phase I

Contract Number: 0810429
Start Date: 7/1/2008    Completed: 6/30/2009
Phase I year
2008
Phase I Amount
$149,887
This Small Business Technology Transfer (STTR) Phase I proposal addresses key components for managing the liquid natural gas and hydrogen fuel supply economy. Transporting and storing cryogenic liquid fuels entails danger of fire and explosion. Since these fuel technologies are growing and acquiring increasing US strategic as well as worldwide importance, sensors and instrumentation to safely manage it are required. The outcome of this work will be a basic technology, first demonstrated at the University of Pittsburgh, consisting of active fiber optic sensors powered by in-fiber light, to measure cryogenic liquid level, temperature and hydrogen concentration in air. Such sensors can be multiplexed at multiple points on a single fiber. The sensors are fiber Bragg gratings (FBG), which produce a signal that is independent of optical intensity noise, electromagnetic interference, and are all-dielectric, avoiding the potential for electrical sparking. With the heating laser off, temperature can be accurately measured to detect liquid density stratification and other management problems. With the heating laser on, Bragg grating with functional coating can be used to measure the thermal conductance difference between cold liquids and gases for leveling sensing. Hydrogen is detected by the strain on the fiber induced by the absorption of hydrogen in a palladium film applied to the fiber at each Bragg grating. The palladium will be heated by the heating laser into a temperature range where it is most active even if it is near a cold pipe or vessel. If successful this technology will assist in providing security when transporting liquid natural gases. The safety of people and facilities are also great importance and impact. A bad accident could delay the wide adoption of hydrogen as a major fuel source. Having a flexible, multi-use system available that can be installed with absolute confidence to monitor and manage these fuels, as well as the health of installed systems, will have a major impact on the acceptance of hydrogen as a safe alternative fuel source. The ability to multiplex many sensors on a single fiber will enable safer and more economical penetrations in cryogenic walls and the low corrosion potential of the fibers will enable sensors to be placed along piping underground. The same basic active fiber sensor technology has the potential to be extended to fuel flow and other economically useful functions.

Phase II

Contract Number: 0956816
Start Date: 7/1/2008    Completed: 6/30/2009
Phase II year
2009
Phase II Amount
$499,429
This Small Business Technology Transfer (STTR) Phase II project will develop a multi-functional active fiber Bragg grating sensor technology for the monitoring and management of cryogenic fuel such as liquid hydrogen and liquefied natural gas. The proposed technology uses in-fiber light to actively adjust sensor temperature, which will drastically improve responsivity and sensitivity of fiber sensors in the cryogenic environment. By coating fiber Bragg grating sensors with functional films, liquid fuel levels, spatial distribution, hydrogen concentration, and temperature can be simultaneously measured at cryogenic temperatures. Active sensors to be developed in this program are immune to electromagnetic interference and can be multiplexed in a single fiber, which allows a one-fiber and one-fiber-feedthrough solution for the cryogenic fuel management on the ground and in space. The broader impact/commercial potential of this project will be the development of a prudent sensing technology and system to improve the safety and reliability of the use of both liquid hydrogen and liquefied natural gas fuels. As major alternative fuels to power the U.S. economy for decades to come, they share a high economic value that requires accurate and reliable metering and management. Having a flexible, multi-use system available that can be installed with absolute confidence to monitor and manage these fuels, as well as the health of installed systems, will have a major impact on the acceptance of these volatile fuels as safe alternative energy sources. The ability to multiplex many sensors on a single fiber will enable safer and more economical penetrations in cryogenic walls and the low corrosion potential of the fibers will enable sensors to be placed along piping underground. The same basic active fiber sensor technology has the potential to be extended to fuel flow and other economically useful functions