Fundamentals of Gaseous Combustion

doi:10.1017/9781009072366.015

11 - Fundamentals of Gaseous Combustion

Published online by Cambridge University Press: 01 December 2022

Eric L. Petersen and

Olivier Mathieu

Edited by

Jacqueline O'Connor ,

Bobby Noble and

Tim Lieuwen

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Jacqueline O'Connor: Affiliation:
Pennsylvania State University
Bobby Noble: Affiliation:
Electric Power Research Institute
Tim Lieuwen: Affiliation:
Georgia Institute of Technology

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Summary

Gaseous renewable fuel combustion is of primary interest for a range of applications including aircraft engines, ground power engines, reciprocating engines, and industrial furnaces, among others. While much of the combustion science and engineering that are needed to design and operate such devices is well developed and available in modern textbooks, the attainment of even higher efficiencies, greater performance, and reduced emissions for an ever-increasing array of new fuels and fuel blends requires an even deeper understanding of fundamental combustion concepts and the underlying physical and chemical phenomena. In many cases, these fundamental concepts are areas of much recent and ongoing research. This chapter describes the basic combustion and chemical kinetic properties of the fuels, namely hydrogen, syngas, ammonia, methane, natural gas, and ethanol, considering the flame temperature, ignition delay time, flammability limit, laminar flame speed, and fuel stretch sensitivity.

Keywords

equilibrium adiabatic flame temperature flame speed ignition stretch sensitivity kinetics flammability limit explosion limit ignition time delay

Type: Chapter
Information: Renewable Fuels
Sources, Conversion, and Utilization
, pp. 371 - 413

DOI: https://doi.org/10.1017/9781009072366.015 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2022

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11 - Fundamentals of Gaseous Combustion

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