Coal-Derived Warm Syngas Purification and CO<sub>2</sub> Capture-Assisted Methane Production [electronic resource].
- Washington, D.C. : United States. Dept. of Energy, 2014. and Oak Ridge, Tenn. : Distributed by the Office of Scientific and Technical Information, U.S. Dept. of Energy
- Physical Description:
- 76 pages : digital, PDF file
- Additional Creators:
- Pacific Northwest National Laboratory (U.S.), United States. Department of Energy, and United States. Department of Energy. Office of Scientific and Technical Information
- Restrictions on Access:
- Free-to-read Unrestricted online access
- Gasifier-derived syngas from coal has many applications in the area of catalytic transformation to fuels and chemicals. Raw syngas must be treated to remove a number of impurities that would otherwise poison the synthesis catalysts. Inorganic impurities include alkali salts, chloride, sulfur compounds, heavy metals, ammonia, and various P, As, Sb, and Se- containing compounds. Systems comprising multiple sorbent and catalytic beds have been developed for the removal of impurities from gasified coal using a warm cleanup approach. This approach has the potential to be more economic than the currently available acid gas removal (AGR) approaches and improves upon currently available processes that do not provide the level of impurity removal that is required for catalytic synthesis application. Gasification also lends itself much more readily to the capture of CO<sub>2</sub>, important in the regulation and control of greenhouse gas emissions. CO<sub>2</sub> capture material was developed and in this study was demonstrated to assist in methane production from the purified syngas. Simultaneous CO<sub>2</sub> sorption enhances the CO methanation reaction through relaxation of thermodynamic constraint, thus providing economic benefit rather than simply consisting of an add-on cost for carbon capture and release. Molten and pre-molten LiNaKCO<sub>3</sub> can promote MgO and MgO-based double salts to capture CO<sub>2</sub> with high cycling capacity. A stable cycling CO<sub>2</sub> capacity up to 13 mmol/g was demonstrated. This capture material was specifically developed in this study to operate in the same temperature range and therefore integrate effectively with warm gas cleanup and methane synthesis. By combining syngas methanation, water-gas-shift, and CO<sub>2</sub> sorption in a single reactor, single pass yield to methane of 99% was demonstrated at 10 bar and 330°C when using a 20 wt% Ni/MgAl<sub>2</sub>O<sub>4</sub> catalyst and a molten-phase promoted MgO-based sorbent. Under model feed conditions both the sorbent and catalyst exhibited favorable stability after multiple test cycles. The cleanup for warm gas cleanup of inorganics was broken down into three major steps: chloride removal, sulfur removal, and the removal for a multitude of trace metal contaminants. Na<sub>2</sub>CO<sub>3</sub> was found to optimally remove chlorides at an operating temperature of 450oC. For sulfur removal two regenerable ZnO beds are used for bulk H<sub>2</sub>S removal at 450oC (<5 ppm S) and a non-regenerable ZnO bed for H<sub>2</sub>S polishing at 300oC (<40 ppb S). It was also found that sulfur from COS could be adsorbed (to levels below our detection limit of 40 ppb) in the presence of water that leads to no detectable slip of H<sub>2</sub>S. Finally, a sorbent material comprising of Cu and Ni was found to be effective in removing trace metal impurities such as AsH<sub>3</sub> and PH<sub>3</sub> when operating at 300oC. Proof-of-concept of the integrated cleanup process was demonstrated with gasifier-generated syngas produced at the Western Research Institute using Wyoming Decker Coal. When operating with a ~1 SLPM feed, multiple inorganic contaminant removal sorbents and a tar-reforming bed was able to remove the vast majority of contaminants from the raw syngas. A tar-reforming catalyst was employed due to the production of tars generated from the gasifier used in this particular study. It is envisioned that in a real application a commercial scale gasifier operating at a higher temperature would produce lesser amount of tar. Continuous operation of a poison-sensitive copper-based WGS catalyst located downstream from the cleanup steps resulted in successful demonstration.
- Published through SciTech Connect., 10/01/2014., "pnnl--23777", "48155", "46194", "600305000", and Robert A. Dagle; David L. King; Xiaohong S. Li; Rong Xing; Kurt A. Spies; Yunhua Zhu; James E. Rainbolt; Liyu Li; B. Braunberger.
- Funding Information:
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