Wave Cycle Design for Wave Rotor Gas Turbine Engines With Low NOx Emissions

Source: Journal of Engineering for Gas Turbines and Power:;1996:;volume( 118 ):;issue: 003::page 474
Author:
M. R. Nalim
 ,
E. L. Resler
DOI: 10.1115/1.2816670
Publisher: The American Society of Mechanical Engineers (ASME)
Abstract: The wave rotor is a promising means of pressure-gain for gas turbine engines. This paper examines novel wave rotor topping cycles that incorporate low-NOx combustion strategies. This approach combines two-stage “rich-quench-lean” (RQL) combustion with intermediate expansion in the wave rotor to extract energy and reduce the peak stoichiometric temperature substantially. The thermodynamic cycle is a type of reheat cycle, with the rich-zone air undergoing a high-pressure stage. Rich-stage combustion could occur external to or within the wave rotor. An approximate analytical design method and CFD/combustion codes are used to develop and simulate wave rotor flow cycles. Engine cycles designed with a bypass turbine and external combustion demonstrate a performance enhancement equivalent to a 200–400 R (110–220 K) increase in turbine inlet temperature. The stoichiometric combustion temperature is reduced by 300–450 R (170–250 K) relative to an equivalent simple cycle, implying substantially reduced NOx formation.
keyword(s): Waves , Design , Gas turbines , Rotors , Cycles , Nitrogen oxides , Emissions , Combustion , Temperature , Turbines , Analytical design , Engines , Pressure , Flow (Dynamics) , High pressure (Physics) , Thermodynamic cycles AND Computational fluid dynamics ,
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URI
http://yetl.yabesh.ir/yetl1/handle/yetl/116891
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