Coal-Fired Power Generation Handbook. James G. Speight

Читать онлайн книгу.

Coal-Fired Power Generation Handbook - James G. Speight


Скачать книгу

      Cohen, A.D. 1970. An Allochthonous Peat Deposit from Southern Florida. Bulletin, Geological Society of America, 81: 2477-2482.

      DOE/EIA. 1995. Coal Data: A Reference. Report No. DOE/EIA-0064(93). Energy Information Administration, United States Department of Energy, Washington, DC.

      Dublin, T., and Licht, W. 2005. The Face of Decline: The Pennsylvania Anthracite Region in the Twentieth Century. Cornell University Press, Ithaca, New York.

      Elphick, J.O. and Suggate, R.P. 1964. Depth/Rank Relations of High-Volatile Bituminous Coals. New Zealand Journal of Geology and Geophysics, 7(3): 594-601.

      Energy Information Administration. 2011. International Energy Outlook. 2011. Report No. DOE/EIA-0484(2011). Energy Information Administration, Unites States Department of Energy, Washington, DC. September.

      Energy Information Administration. 2012a. Annual Energy Outlook. 2012 with Projections to 2035. Report No. DOE/EIA-0383(2012). Energy Information Administration, Unites States Department of Energy, Washington, DC. June.

      Energy Information Administration. 2012b. International Energy Outlook. 2012. Report No. DOE/EIA-03834(20121). Energy Information Administration, Unites States Department of Energy, Washington, DC. September.

      EWG. 2007. Coal: Resources and Future Production. EWG-Paper No. 1/07. Energy Watch Group, Berlin, Germany.

      Freese, B. 2003. Coal: A Human History. Perseus Publishing Company, Cambridge Massachusetts.

      GAO. 2012. Electricity: Significant Changes Are Expected in Coal-Fueled Generation, but Coal is Likely to Remain a Key Fuel Source. Report GAO-13-72. Report to the Chairman, Committee on Commerce, Science, and Transportation, U.S. Senate. United States Government Accountability Office, Washington, DC.

      Hessley, R.K. 1990. In Fuel Science and Technology Handbook. J.G. Speight (Editor). Marcel Dekker Inc., New York.

      Höök, M., and Aleklett, K. 2009. Historical Trends in American Coal Production and a Possible Future Outlook. International Journal of Coal Geology, 78(3): 201-216.

      Hordeski, M.F. 2008. Alternative Fuels: The Future of Hydrogen. 2nd Edition. CRC Press, Taylor & Francis Group, Boca Raton, Florida.

      Horwitch, M. 1979. In Energy Future. R. Stobaugh and D. Yergin (Editors). Random House Inc., New York.

      Hubbard, H.M. 1991. Scientific American. 264(4): 36.

      International Energy Agency. 2010. Coal Information 2010. International Energy Agency, Paris France. July.

      Irfan, H.D., Yongli, G., Small, C., Do, Y.K., Subbiah, J. and So, F. 2010. Energy Level Evolution of Air and Oxygen Exposed Molybdenum Trioxide Films. Applied Physics Letters 96:1-3.

      Kavalov, B., and Peteves, S.D. 2007. The Future of Coal. Report No. EUR 22744 EN. Directorate-General Joint Research Center, Institute for Energy, Petten, Netherlands.

      Malvić, T. 2011. Unconventional Hydrocarbon Gas Sources as a Challenge to Renewable Energies. Energies, 4: 1-14.

      Mamay, S.H., and Yochelson, E.L. 1962. Occurrence and Significance of Marine Animal Remains in American Coal Balls. Professional Paper 354-1. United States Geological Survey. Page 193-224.

      MIT. 2007. The Future of Coal: An Interdisciplinary MIT Study. Massachusetts Institute of Technology, Cambridge, Massachusetts.

      Nederlof, M.H. 1988. The Scope for Natural Gas Supplies from Unconventional Sources. Annual Review of Energy. 13: 95.

      NRC. 1979. Energy in Transition 1985-2010. National Research Council. National Academy of Sciences. W.H. Freeman and Company, San Francisco.

      NRC. 1990. Fuels to Drive Our Future. National Research Council. National Academy of Sciences. National Academy Press, Washington, DC.

      Rupke, N.A. 1969. Sedimentary Evidence for the Allochthonous Origin of Stigmaria, Carboniferous, Nova Scotia. Bulletin, Geological Society of America, 80: 2109-2114.

      Speight, J.G. 2011b. An Introduction to Petroleum Technology, Economics, and Politics. Scrivener Publishing, Salem, Massachusetts.

      Speight, J.G. 2013. The Chemistry and Technology of Coal. 3rd Edition. CRC Press, Taylor and Francis Group, Boca Raton, Florida.

      Speight, J.G. 2014. The Chemistry and Technology of Petroleum. 5th Edition. CRC Press, Taylor and Francis Group, Boca Raton, Florida.

      Speight, J.G. 2020. Synthetic Fuels Handbook: Properties, Processes, and Performance. McGraw-Hill, New York.

      Suggate, R.P. (1974) Coal Ranks in Relation to Depth and Temperature in Australian and New Zealand Oil and Gas Wells. New Zealand Journal of Geology and Geophysics, 17(1): 149-167.

      Thorpe, T.E., Green, A.H., Miall, L.C., Rücker, A.W., and Marshall, A. 1878. Coal: Its History and Uses. Macmillan & Co., London, United Kingdom.

      Ward, C.R. 2008. Introduction to Applied Coal Petrology. In: Applied Coal Petrology. Elsevier BV, Amsterdam, Netherlands. Chapter 1. Page 2-18.

      World Coal Institute. 2008. The Role of Coal as an Energy Source. World Coal Institute, World Coal Association, Richmond, United Kingdom.

      Yergin, D. 1991. The Prize: The Epic Quest for Oil, Money, and Power. Simon & Schuster, New York.

      2

      Classification

      2.1 Introduction

      Following from the statements in Chapter 1, coal is the biggest single source of energy for electricity production and plays an essential role in the energy mix of many countries, particularly for power generation, but there is an urgent need to use coal efficiently and reduce the environmental footprint of the coal. Thus, the measurement and reporting of efficiency performance and carbon dioxide emissions is a prerequisite to the more sustainable use of coal in power plants.

      The direct and indirect utilization of coals for production of energy (and chemicals) is the foundation upon which interest in classifying coal resource is built. However, because of the complex, heterogeneous nature, and the variety of coals used throughout the world, classification is a difficult task. Identification of the most advantageous raw material, whether by quality, cost, availability or a combination of several such factors has always been one of the driving forces behind the development of classification systems. In fact, many of the systems currently in use in the coal industry were derived specifically from a need to identify quality coals for coke making, and in that respect only classify a relatively narrow range of coals. Other systems that have been developed to address the scientific need to understand the origin, constitution and fundamental properties follow the approach that any sound classification will identify all coals for all potential industrial uses (Speight, 2013).

      Coal is a combustible dark-brown-to-black organic sedimentary rock that occurs in coal beds or coal seams (Chapter 1) and is


Скачать книгу