1. 3-E analysis of advanced power plants based on high ash coal
- Author
-
K.S. Reddy, M. Suresh, and Ajit Kumar Kolar
- Subjects
Exergy destructions ,Exergy ,Engineering ,Power station ,Fossil fuel power plants ,Energy and exergy efficiency ,Energy Engineering and Power Technology ,Thermal power station ,Coal combustion products ,Higher plants ,Steam-electric power station ,Steam power plants ,Climatic conditions ,Environmental impact ,Subcritical supercritical ,Thermal power plants ,Thermoelectric power plants ,Coal ,Energy ,Sliding pressure ,Waste management ,Renewable Energy, Sustainability and the Environment ,business.industry ,Energy dissipation ,Load following power plant ,Steam parameters ,Environmental engineering ,Heat rejection ,AD700 ,Coal industry ,Coal combustion ,Steam ,Energy loss ,Throttle control ,Energy efficiency ,Fuel Technology ,High ash coal ,Nuclear Energy and Engineering ,Load following ,Control techniques ,Part load ,Super-critical ,business - Abstract
The objective of the study is to identify the 'best' possible power plant configuration based on 3-E (namely energy, exergy, and environmental) analysis of coal-based thermal power plants involving conventional (subcritical (SubC)) and advanced steam parameters (supercritical (SupC) and ultrasupercritical (USC)) in Indian climatic conditions using high ash (HA) coal. The analysis is made for unit configurations of three power plants, specifically, an operating SubC steam power plant, a SupC steam power plant, and the AD700 (advanced 700�C) power plant involving USC steam conditions. In particular, the effect of HA Indian coal and low ash (LA) reference coal on the performance of these power plants is studied. The environmental impact of the power plants is estimated in terms of specific emissions of CO2, SOx, NOx, and particulates. From the study, it is concluded that the maximum possible plant energy efficiency under the Indian climatic conditions using HA Indian coal is about 42.3% with USC steam conditions. The results disclose that the major energy loss is associated with the heat rejection in the cooling water, whereas the maximum exergy destruction takes place in the combustor. Further, the sliding pressure control technique of load following results in higher plant energy and exergy efficiencies compared to throttle control in part-load operation. Copyright � 2009 John Wiley & Sons, Ltd.
- Published
- 2010
- Full Text
- View/download PDF