Development of an Analytical Design Tool for Monolithic Emission Control Catalysts and Application to Nano-Textured Substrate System-Reference-Cited by-同舟云学术

Development of an Analytical Design Tool for Monolithic Emission Control Catalysts and Application to Nano-Textured Substrate System

Published:2014-04-11 Issue:3 Volume:6 Page:
ISSN:1948-5085
Container-title:Journal of Thermal Science and Engineering Applications
language:en
Short-container-title:

Author:

Baker Chad A.¹,Osman Emiroglu Alaattin²,Mallick Rehan³,Ezekoye Ofodike A.⁴,Shi Li⁵,Hall Matthew J.⁶

Affiliation:

1. Research and Advanced Engineering,Ford Motor Company,2151 Village RdDearborn, MI 48124e-mail: cbake134@ford.com

2. Department of Mechanical Engineering,Abant Izzet Baysal University,Bolu 14100, Turkeye-mail: aosmanemiroglu@gmail.com

3. Department of Mechanical Engineering,University of Texas at Austin,204 E. Dean Keeton,Austin, TX 78712e-mail: rmallick6806@gmail.com

4. Department of Mechanical Engineering,University of Texas at Austin,204 E. Dean Keeton,Austin, TX 78712e-mail: dezekoye@mail.utexas.edu

5. Department of Mechanical Engineering,University of Texas at Austin,204 E. Dean Keeton,Austin, TX 78712e-mail: lishi@mail.utexas.edu

6. Department of Mechanical Engineering,University of Texas at Austin,204 E. Dean Keeton,Austin, TX 78712e-mail: mjhall@mail.utexas.edu

Abstract

Abstract An analytical transport/reaction model was developed to simulate the catalytic performance of ZnO nanowires as a catalyst support. ZnO nanowires were chosen because they have easily characterized, controllable features and a spatially uniform morphology. The analytical model couples convection in the catalyst flow channel with reaction and diffusion in the porous substrate material; it was developed to show that a simple analytical model with physics-based mass transport and empirical kinetics can be used to capture the essential physics involved in catalytic conversion of hydrocarbons. The model was effective at predicting species conversion efficiency over a range of temperature and flow rate. The model clarifies the relationship between advection, bulk diffusion, pore diffusion, and kinetics. The model was used to optimize the geometry of the experimental catalyst for which it predicted that maximum species conversion density for fixed catalyst surface occurred at a channel height of 520 μm.

Publisher

ASME International

Subject

Fluid Flow and Transfer Processes,General Engineering,Condensed Matter Physics,General Materials Science

Link

http://asmedigitalcollection.asme.org/thermalscienceapplication/article-pdf/6/3/031014/6765481/tsea_006_03_031014.pdf

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