Laboratory Investigations of Low-Swirl Injectors Operating With Syngases

TitleLaboratory Investigations of Low-Swirl Injectors Operating With Syngases
Publication TypeJournal Article
Year of Publication2009
AuthorsLittlejohn, David, Robert K. Cheng, David R. Noble, and Tim Lieuwen
JournalJournal of Engineering for Gas Turbines and Power
Volume132
Start Page011502
Issue1
Pagination011502-011509
Date Published09/2009
ISSN07424795
Abstract

The low-swirl injector (LSI) is a lean premixed combustion technology that has the potential for adaptation to fuel-flexible gas turbines operating on a variety of fuels. The objective of this study is to gain a fundamental understanding of the effect of syngas on the LSI flame behavior, the emissions, and the flowfield characteristics for adaptation to the combustion turbines in integrated gasification combined cycle clean coal power plants. The experiments were conducted in two facilities. Open atmospheric laboratory flames generated by a full size (6.35 cm) LSI were used to investigate the lean blow-off limits, emissions, and the flowfield characteristics. Verification of syngas operation at elevated temperatures and pressures were performed with a reduced scale (2.54 cm) LSI in a small pressurized combustion channel. The results show that the basic LSI design is amenable to burning syngases with up to 60% H2. Syngases with high H2 concentration have lower lean blow-off limits. From particle image velocimetry measurements, the flowfield similarity behavior and the turbulent flame speeds of syngases flames are consistent with those observed in hydrocarbon and pure or diluted hydrogen flames. The NOx emissions from syngas flames show log-linear dependency on the adiabatic flame temperature and are comparable to those reported for the gaseous fuels reported previously. Successful firing of the reduced-scale LSI at 450 K < T < 505 K and 8 atm verified the operability of this concept at gas turbine conditions.

DOI10.1115/1.3124662
Short TitleJ. Eng. Gas Turbines Power
DOI10.1115/1.3124662