Design and Performance of an Improved Trapped Vortex Combustor

A trapped vortex combustor (TVC) has been a very promising novel concept for it offers improvements in lean blow out, altitude relight, operating range, as well as a potential to decrease NOx emissions compared to conventional combustors. The present paper discusses the improved designs of the new c...

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Bibliographic Details
Published in:Chinese journal of aeronautics 2012-12, Vol.25 (6), p.864-870
Main Authors: JIN, Yi, HE, Xiaomin, JIANG, Bo, WU, Zejun, DING, Guoyu
Format: Article
Language:English
Subjects:
combustion
experimental demonstration
improved design
trapped vortex combustor
入口温度
发动机燃烧室
性能改进
氮氧化物排放量
燃烧效率
航空发动机
设计
驻涡
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Summary:A trapped vortex combustor (TVC) has been a very promising novel concept for it offers improvements in lean blow out, altitude relight, operating range, as well as a potential to decrease NOx emissions compared to conventional combustors. The present paper discusses the improved designs of the new combustor over the prior ones of our research group, including that:a) the over-all dimensions, both axial and radial, are reduced to those of an actual aero-engine combustor; b) the air flow distribution is optimized, and especially 15% of the air is fed into the liner as cooling air; c) a straight-wall diffuser with divergence angle 9°is added. A series of experiments (cavity-fueled only, under atmospheric pressure) has been conducted to investigate the performance of the improved TVC. Experimental results show that at the inlet temperature of 523 K, the inlet pressure of 0.1 MPa, stable operation of the TVC test rig is observed for the Mach number 0.15-0.34, indicating good flame stability; the combustion efficiency obtained in this paper falls into the range of 60%-96%; as the total excess air ratio increases, the combustion efficiency decreases, while the increase of the inlet temperature is beneficial to high combustion efficiency; besides, the optimal Mach numbers for high combustion efficiency under different inlet conditions are confirmed. The outlet temperature profiles feature a bottom in the midheight of the exit. This paper demonstrates the feasibility for the TVC to be applied to a realistic aero-engine preliminarily and provides reference for TVC design.
ISSN:1000-9361
DOI:10.1016/S1000-9361(11)60456-1