Pore Size Distribution Effect on the Mass Transfer and Reaction in a Cylindrical Porous Gas Sensitive Medium

Ming Chun Li; Chen Wang; Jia Tao Liu; Yu Jing

doi:10.4028/www.scientific.net/AMR.550-553.2972

Paper Titles

Sintering Behavior and Microwave Dielectric Properties of BaTi₄O₉ Ceramics Prepared from Different Size Powders by Sol-Gel Method
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Study on Intrinsic Safety and Volume Expansion Ratio of Liquefied Gas Cylinder
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Investigation on Laminar Flow Field Performances in a Dual-Impeller Stirred Tank
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Fluidization Behavior of Mixtures of Nanoparticles in Vibrated Fluidized Beds
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Pore Size Distribution Effect on the Mass Transfer and Reaction in a Cylindrical Porous Gas Sensitive Medium
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Phase Split of Oil-Water Two-Phase Flows at a T-Junction with a Vertically Downward Branch
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Formation Mechanism and the Solving Measures of Sediments in Surface Pipelines of ASP Flooding
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Numerical Simulation and Experimental Validation of the Four Channel Hot Air Gun Heating System
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Tests on a New Vibration Isolation Module
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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 550-553Pore Size Distribution Effect on the Mass Transfer...

Pore Size Distribution Effect on the Mass Transfer and Reaction in a Cylindrical Porous Gas Sensitive Medium

Abstract:

Based on the pore size distribution simulation and the derivation of the effective diffusion coefficient, a mathematical model describing the mass transfer and chemical reaction in a cylindrical gas sensitive porous medium is formulated. The reaction features and the effective utilization of the gas sensitive porous medium are analyzed under different pore size distribution. The results indicate that, an increase in porosity or in the most probably pore diameter leads to a higher mass transfer rate of the target gas, while the surface chemical reaction ability decreases. Depending on the calculated value of the Thiele number, the variation of the gas sensitivity and the effective surface utilization can be analyzed. The gas sensitivity and the effective utilization coefficient of the gas sensitive porous medium can be controlled by adjusting pore structure parameters. This will be useful for the pore structure design of gas sensor and choosing the most reasonable operation conditions.