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Proceedings of the Mini-Symposium “Coal Based Fuel Cell Technology: Status, Needs and Future Applications”. Morgantown WV, October 11-12, 2007 (NMS_07_P07 31)
A Review of Coal Syngas Cleanup Technologies, Past Trace Contaminant Testing, and Future SOFC Testing Activities at RTI
Jason Trembly, John Albritton, and Raghubir Gupta
RTI International, Center for Energy Technology, 3040 Cornwallis Road, Research Triangle
Park, NC 27709, Tel: (919)-541-8033, E-mail: jtrembly@rti.org
ABSTRACT
Development of integrated gasification and fuel cell (IGFC) power plants has increased considerably over recent years due to the ability to produce electrical power at high efficiencies while being environmentally friendly. The development of these power generation systems is a key goal of the U.S. Department of Energy (DOE). Although the ability of solid oxide fuel cells (SOFCs) to operate on carbon based fuels such as natural gas has previously been reported the use of coal derived syngas as a fuel for SOFCs has only recently been investigated. The main components of coal derived syngas are known not to cause loss in SOFC performance; however the syngas may contain many trace species which may be detrimental towards operation. Although it is well known that H2S will need to be cleaned to sub-ppm concentrations the determination of the level of cleanup which will be required for other trace species contained in coal derived syngas has just recently commenced. A thorough understanding of the interactions between the SOFC anode and various species contained in coal derived syngas is required to develop coal based SOFC systems. RTI International is a leading developer of warm gas cleanup systems for IGCC and future IGFC power plants. This paper will review previous SOFC trace contaminant testing which has been completed and testing methodologies RTI is considering to develop trace contaminant clean up systems for IGFC power systems.
Free Full Text Source: http://nift.wvu.edu/Symposium2007/papers/NMS_07_P07.pdf
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RTI International (www.rit.org) is one of the world’s leading nonprofit research institutes, dedicated to improving the human condition by turning knowledge into practice. Its staff of more than 3,700 provides research and technical expertise to governments and businesses in more than 75 countries.
I found more articles describing RTI syngas research by searching Google® Scholar using this statement …
“RTI International” coal
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International Journal of Clean Coal and Energy, Vol.2 No.3(2013), Article ID:36046,19 pages DOI:10.4236/ijcce.2013.23005
Implementation of a Demoisturization and Devolatilization Model in Multi-Phase Simulation of a Hybrid Entrained-Flow and Fluidized Bed Mild Gasifier
Jobaidur Khan, Ting Wang
Energy Conversion & Conservation Center, University of New Orleans, New Orleans, USA
Email: jrkhan@uno.edu, twang@uno.edu
Copyright © 2013 Jobaidur Khan, Ting Wang. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
ABSTRACT
A mild gasification process has been implemented to provide an alternative form of clean coal technology called the Integrated Mild Gasification Combined Cycle (IMGCC), which can be utilized to build a new, highly efficient, and compact power plant or to retrofit an existing coal-fired power plant in order to achieve lower emissions and significantly improved thermal efficiency. The core technology of the mild gasification power plant lies on the design of a compact and effective mild gasifier that can produce synthesis gases with high energy volatiles through a hybrid system: utilizing the features of both entrained-flow and fluidized bed gasifiers. To aid in the design of the mild gasifier, a computational model has been implemented to investigate the thermal-flow and gasification process inside this mild gasifier using the commercial CFD (Computational Fluid Dynamics) solver ANSYS/FLUENT. The Eulerian-Eulerian method is employed to model both the primary phase (air) and the secondary phase (coal particles). However, the Eulerian-Eulerian model used in the software does not facilitate any built-in devolatilization model. The objective of this study is therefore to implement a devolatilization model (along with demoisturization) and incorporate it into the existing code. The Navier-Stokes equations and seven species transport equations are solved with three heterogeneous (gassolid) and two homogeneous (gas-gas) global gasification reactions. Implementation of the complete model starts from adding demoisturization first, then devolatilization, and then adding one chemical equation at a time until finally all reactions are included in the multiphase flow. The result shows that the demoisturization and devolatilization models are successfully incorporated and a large amount of volatiles are preserved as high-energy fuels in the syngas stream without being further cracked or reacted into lighter gases. The overall results are encouraging but require future experimental data for verification.
Free Full Text Source: http://file.scirp.org/Html/3-2380008_36046.htm
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