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Part 1 Advanced power plant materials and designs: Gas turbine technology; Gas-fired combined-cycle technology; Integrated gasification combined cycle (IGCC) technology; Improving thermal cycle efficiency in advanced power plants. Part 2 Gas separation membranes, emissions handling, and instrumentation and control: Hydrogen (H2) gas separation; Carbon dioxide (CO2) gas separation; Flue gas cleaning for SOx, NOx and mercury emissions control; Flue gas dedusting systems for ash and particulate emissions control; Sensors for combustion monitoring; Monitoring and process control technology. Part 3 Improving the fuel flexibility, environmental impact and generation performance of advanced power plants: Low-rank coal utilisation; Biomass utilisation; Underground coal gasification (UCG); CO2 storage; Syngas and H2 production from fossil-fuel feedstocks.
Fossil-fuel power plants account for the majority of worldwide power generation. Increasing global energy demands, coupled with issues of ageing and inefficient power plants, have led to new power plant construction programmes. As cheaper fossil fuel resources are exhausted and emissions criteria are tightened, utilities are turning to power plants designed with performance in mind to satisfy requirements for improved capacity, efficiency, and environmental characteristics.
Advanced power plant materials, design and technology provides a comprehensive reference on the state of the art of gas-fired and coal-fired power plants, their major components and performance improvement options. Part one critically reviews advanced power plant designs which target both higher efficiency and flexible operation, including reviews of combined cycle technology and materials performance issues.
Part two reviews major plant components for improved operation, including advanced membrane technology for both hydrogen (H2) and carbon dioxide (CO2) separation, as well as flue gas handling technologies for improved emissions control of sulphur oxides (SOx), nitrogen oxides (NOx), mercury, ash and particulates. The section concludes with coverage of high-temperature sensors, and monitoring and control technology that are essential to power plant operation and performance optimisation.
Part three begins with coverage of low-rank coal upgrading and biomass resource utilisation for improved power plant fuel flexibility. Routes to improve the environmental impact are also reviewed, with chapters detailing the integration of underground coal gasification and the application of carbon dioxide (CO2) capture and storage. Finally, improved generation performance is reviewed with coverage of syngas and hydrogen (H2) production from fossil-fuel feedstocks.
With its distinguished international team of contributors, Advanced power plant materials, design and technology is a standard reference for all power plant engineers and operators, as well as to academics and researchers in this field.
- Provides a comprehensive reference on the state-of-the-art gas-fired and coal-fired power plants, their major components and performance improvement options
- Examines major plant components for improved operation as well as flue gas handling technologies for improved emissions control
- Routes to improve environmental impact are discussed with chapters detailing the integration of underground coal gasification
Power plant engineers and operators, as well as to academics and researchers in this field
- No. of pages:
- © Woodhead Publishing 2010
- 24th May 2010
- Woodhead Publishing
- Hardcover ISBN:
- eBook ISBN:
...should fill a long-vacant gap in this most interesting of technological opportunities in chemical engineering., Review of chapter 13, Ian Burdon, Technical Director (Energy), Parsons Brinckerhoff.
…an indispensible reference for those who will be involved in the development of advanced power plants. It covers all of the bases including operational issues and environmental control., Professor Jim Skea, Research Director, UK Energy Research Centre, UK
Dermot Roddy is the Science City Professor of Energy and Director of the Sir Joseph Swan Institute at Newcastle University, UK. He was previously responsible for the development of a renewable energy and alternative fuel programme for Renew Tees Valley Ltd, UK, and he is noted for his research in optimisation and control.
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