期刊
ENERGY CONVERSION AND MANAGEMENT
卷 55, 期 -, 页码 116-126出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.enconman.2011.10.026
关键词
Magnesium silicate; Magnesium hydroxide; CO2 mineralization; Life cycle assessment; Exergy analysis
资金
- Energy and Environment Systems Group, Institute for Sustainable Energy Environment and Economy at the University of Calgary, Alberta, Canada
- Academy of Finland
- Abo Akademi University's Graduate School for Chemical Engineering (GSCE)
This paper addresses the energy and environmental implications of sequestrating CO2 from a coal power plant using magnesium silicate rock. An accounting type life cycle assessment (LCA) of the mineralization method under development at Abo Akademi University (AAU), Finland, is presented and the results are compared with the process developed at the National Energy Technology Laboratory (NETL), formerly Albany Research Council (ARC) in the US. The AAU process is a multi-staged route where CO2 is sequestered via a process that first produces magnesium hydroxide. Mg(OH)(2) from Mg silicate. The Mg(OH)(2) produced is later reacted with CO2 in a high temperature gas/solid pressurized fluidized bed (FB) reactor, forming pure, stable and environmentally benign MgCO3 product. This study addresses the following important issues; (a) the material and energy requirements of sequestering 1 ton of CO2 (t-CO2) in mineral silicate, (b) the overall environmental burdens associated with CO2 sequestration using serpentinite mineral, (c) the priorities and opportunities for reduction of energy requirements and environmental impacts associated with mineralizing CO2, and (d) comparison of LCA results of the AAU mineralization process route with that of the mineralization process developed by NETL. Exergy calculations show that with heat recovery mineralizing 1 t-CO2 using the AAU process requires 3.6 GJ/t-CO2 while that of the NETL needs 3.4 GJ/t-CO2. Applying results of exergy analysis in the life cycle inventory (LCI) models of the AAU and the NETL processes leads to 517 kg CO(2)e and 683 kg CO(2)e of greenhouse gas emissions (in CO2 equivalents) respectively, for every ton of CO2 mineralized in serpentinite. (C) 2011 Elsevier Ltd. All rights reserved.
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