1999
DOI: 10.2172/12100
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Life Cycle Assessment of Coal-fired Power Production

Abstract: Prepared under Task No. BP911030 Excluding the consumption of fossil fuels by the power plant, the external energy efficiency and external energy ratio indicate that upstream processes are large consumers of energy. In fact, two operations, those related to flue gas clean-up and coal transportation, account for between 3.8% and 4.2% of the total system energy consumption, and between 67.4% and 70.5% of the non-coal energy. Processes involved in the gas clean-up operations include the production, transport, and… Show more

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Cited by 201 publications
(149 citation statements)
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“…The key factors were found to be the type of technology and the process efficiency. For example, GHG emission factors for direct combustion (DC) were in the range of 750-1050 kg CO 2 -eq/MWh for which the lowest and highest values corresponded to energy recovery efficiencies of 42% and 33%, respectively [41][42][43], calculated relative to the input energy. On the other hand, coal gasification (IGCC) could achieve higher efficiencies (up to 52%), thus leading to lower GHG emission factors compared to direct combustion (660-800 kg CO 2 -eq/MWh).…”
Section: Hard Coalmentioning
confidence: 99%
“…The key factors were found to be the type of technology and the process efficiency. For example, GHG emission factors for direct combustion (DC) were in the range of 750-1050 kg CO 2 -eq/MWh for which the lowest and highest values corresponded to energy recovery efficiencies of 42% and 33%, respectively [41][42][43], calculated relative to the input energy. On the other hand, coal gasification (IGCC) could achieve higher efficiencies (up to 52%), thus leading to lower GHG emission factors compared to direct combustion (660-800 kg CO 2 -eq/MWh).…”
Section: Hard Coalmentioning
confidence: 99%
“…The composition of the fuel used to provide this energy is about 80% coal and 20% Diesel. (Shapouri , Duffield, and Wang 2002); (Spath, Mann, and Kerr 1999); ; (Challman 2007); (Klara 2007); (Evans 2004); (Graboski 2002); (Daly 2008); (Susta, Seon, and Melaysia 2004); (USDL 2007); (Wu, Wang, and Huo 2006); ** Fuel production energy requirements are all provided by 100% by coal except for gasoline which is 81% oil and 19% coal Coal input; kWh output IGCC/ethanol (lb/gal); (kWh/gal) 14. 1 [6,7]; 9.86 [6,7] Power demand of pumps (kW) 11,190 [22] Gasification/Fuel Synthesis …”
Section: Very Different Results Were Found For the Vpms Of Gasificatimentioning
confidence: 99%
“…These assumptions were modified according to specific fuel and automobile conditions of various VPMs. Two other studies, (Shapouri et al 2002) and (Spath et al 1999), made calculations of emissions of ethanol and electricity production, respectively. The scope of their studies started with feedstock acquisition and ended after production.…”
Section: Introductionmentioning
confidence: 99%
“…It is important to consider the entire life cycle and environmental costs of PV power compared to electricity produced from coal. The environmental cost of PV systems over their entire lifecycle is an order of magnitude lower than a coal power station in terms of greenhouse gas emissions (Peng et al 2013;Epstein et al 2011) and other reduced environmental and human impacts associated with non-renewable energy sources (Spath et al 1999). The successful application of the BMS combined with the solar PV has highlighted the opportunity to expand the PV system at the Aquarium if a larger TES is added, delaying the need for electrical battery storage.…”
Section: Renewable Energymentioning
confidence: 99%