A review of unconventional bottoming cycles for waste heat recovery: Part II

A review of unconventional bottoming cycles for waste heat recovery: Part II – Applications

Published:2019-01 Issue: Volume:180 Page:559-583
ISSN:0196-8904
Container-title:Energy Conversion and Management
language:en
Short-container-title:Energy Conversion and Management

Author:

Omar Amr^ORCID,Saghafifar Mohammad,Mohammadi Kasra,Alashkar Adnan,Gadalla Mohamed

Publisher

Elsevier BV

Subject

Energy Engineering and Power Technology,Fuel Technology,Nuclear Energy and Engineering,Renewable Energy, Sustainability and the Environment

Reference126 articles.

1. Climate change 2013 – the physical science basis;Intergovernmental Panel on Climate Change,2013

2. Shnaid I. Thermodynamic and techno-economic analyses of a combined cycle power plant with a simple cycle gas turbine, the bottoming air turbine cycle and the reverse Brayton cycle. In: ASME 1999 international gas turbine and aeroengine congress and exhibition, Indianapolis; 1999.

3. Chmielniak T, Czaja D, Lepszy S. Technical and economic analysis of the gas turbine air bottoming cycle. In: ASME Turbo Expo 2012: turbine technical conference and exposition. In American Society of Mechanical Engineers, Copenhagen, Denmark; 2012.

4. Kaikko J, Hunyadi L, Reunanen A, Larjola J. Comparison between air bottoming cycle and organic rankine cycle as bottoming cycles. In: Heat power cycle conference, Paris; 2001.

5. Performance analysis of the dual gas turbine combined cycle;Hirs;ASME,1995

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