论文信息 - Ultrasonic and resistive hydrogen sensors for inert gas-water vapour atmospheres

Ultrasonic and resistive hydrogen sensors for inert gas-water vapour atmospheres

Hydrogen concentration measurements were developed for a series of experiments in which a molten oxide is mixed with water to study vapour explosion phenomena. The gas mixture to be analysed consisted of hydrogen with water vapour and either helium or argon. Two types of sensor have been developed for these tests. The first is an ultrasonic sensor, which detects variations in the acoustic velocity within a 0.4 mm-diameter palladium wire. The sensor measures hydrogen concentrations in the range 0.1-100%, at atmospheric pressure, over an operating temperature range of 200-400 °C. The response time (for 0-90% of the final response) is about 30 s at 180 °C and 8 s at 380 °C. The second sensor consists of a palladium coil, constructed with 0.05 mm-diameter wire that is wound around a ceramic tube. Measurements of wire resistance were used to detect partial pressure of hydrogen. This sensor operates at 150-300 °C and measures hydrogen concentrations of 1-100%. The response time is short, 1-2 s for a temperature of 300 °C.

[1] I Huhtiniemi,et al. Results of recent KROTOS FCI tests : Alumina versus corium melts , 1999 .

[2] W. T. Lindsay,et al. Electrical Resistance of Alpha Hydrogen‐Palladium , 1962 .

[3] H. Iwahara,et al. Nernstian Hydrogen Sensor Using BaCeO3 ‐ Based , Proton‐Conducting Ceramics Operative at 200°–900°C , 1991 .

[4] I Huhtiniemi,et al. Lessons learnt from FARO/TERMOS corium melt quenching experiments , 1999 .

[5] Powell,et al. Solubility of H, D, and T in Pd at low concentrations. , 1986, Physical review. B, Condensed matter.

[6] Michael A. Butler,et al. Micromirror optical-fiber hydrogen sensor , 1994 .

[7] D. Macdonald,et al. Development of Dissolved Hydrogen Sensors Based on Yttria‐Stabilized Zirconia Solid Electrolyte with Noble Metal Electrodes , 1997 .

[8] C. Liu,et al. An advanced Pd/Pt relative resistance sensor for the continuous monitoring of dissolved hydrogen in aqueous systems at high subcritical and supercritical temperatures , 1995 .

[9] G. Powell. Solubility of hydrogen and deuterium in a uranium--molybdenum alloy , 1976 .

[10] S. Zhuiykov. Hydrogen sensor based on a new type of proton conductive ceramic , 1996 .

[11] K. Weale,et al. The palladium + hydrogen equilibrium at high pressures and temperatures , 1960 .

[12] R. C. Hughes,et al. Solid‐State Hydrogen Sensors Using Palladium‐Nickel Alloys: Effect of Alloy Composition on Sensor Response , 1995 .