Numerical Studies on Mechanisms and Rules of Fuel Deposition at Transient Moment of Fuel Supply in a Fuel Injector

doi:10.13675/j.cnki.tjjs.200049

Journal of Propulsion Technology ›› 2021, Vol. 42 ›› Issue (6): 1329-1338.DOI: 10.13675/j.cnki.tjjs.200049

• Combustion, Heat and Mass Transfer • Previous Articles Next Articles

Numerical Studies on Mechanisms and Rules of Fuel Deposition at Transient Moment of Fuel Supply in a Fuel Injector

1.AECC Sichuan Gas Turbine Establishment，Chengdu 610500，China;2.School of Chemical Engineering and Technology，Tianjin University，Tianjin 300072，China;3.College of Electromechanical Engineering，Qingdao University of Science & Technology，Qingdao 266061，China

Online:2021-06-15 Published:2021-08-15

供油瞬态喷油杆内燃油结焦机理及规律数值研究

周雄¹，康玉东¹，康松¹，邓远灏¹，刘国柱²，隋春杰³

1.中国航发四川燃气涡轮研究院，四川成都 610500;2.天津大学化工学院，天津 300072;3.青岛科技大学机电工程学院，山东青岛 266061

基金资助:
国家自然科学基金（21522605）。

Abstract

Abstract: In order to investigate mechanisms of rapid increase of fuel deposition rate at the transient moment of fuel supply under the on-off cycle mode in a fuel injector， one-dimensional unsteady heat-fluid-solid coupled heat transfer and fuel deposition model along the axial direction of fuel injector was established. Axial distributions of wall temperature， oil temperature and fuel deposition rate at different fuel supply moments were obtained. By comparing with results of continuous fuel supply mode， effects of thermal shock caused by the hot inner wall of fuel injector at the moment of fuel supply on fuel deposition were analyzed， so as to obtain mechanisms of sharp increase of fuel deposition. Results show that at the beginning of each on-off cycle， sharp peak values of oil temperature and deposition precursor are formed rapidly after fuel supply. The solid-phase surface reaction which leads to fuel deposition is excited rapidly， so the deposition rate increases sharply. There is respectively a peak area of fuel deposition rate near the front （x=100mm） and bottom （x=260mm） of the injector. Under the on-off mode， at x=100mm and x=260mm， peak values of deposition rate at the beginning of each cycle are respectively about 5000μg/（cm²·h） and 2000μg/（cm²·h）， which are much higher than those under the continuous fuel supply mode. However， at the end of fuel supply， influences of fuel supply mode are greatly reduced. Besides， under the on-off mode， influences of thermal shock on fuel deposition decrease along the axial direction of the injector. When the inlet flow rate is reduced， effects of thermal shock are smaller than those under the baseline condition， and first increase with time and then decrease. With the increase of inlet oil temperature， effects of thermal shock become smaller significantly， and gradually decrease with the fuel supply time.

Key words: On-off cyclic fuel supply;Fuel injector;Thermal shock;Fuel deposition;Numerical simulation

摘要： 为获得喷油杆通断循环供油工作模式下，供油瞬间燃油结焦速率陡增机理，本文建立起沿喷杆轴向的一维非稳态热-流-固耦合换热与燃油结焦计算模型。获得不同时刻壁温、油温与结焦速率等参数轴向分布。通过与连续供油模式下的结果对比，来分析供油瞬间灼热喷杆内壁对燃油热冲击的影响，以获得结焦速率陡增机理。结果表明：通断供油模式下，供油瞬间会迅速形成一尖锐的油温和结焦前体浓度峰值，结焦固相表面反应被迅速激发，结焦速率陡增。在喷杆前端（x=100mm）与底部（x=260mm）附近各存在一结焦速率峰值区域。通断供油模式下，在x=100mm和x=260mm位置处，每个周期供油起始时刻结焦速率峰值分别在5000μg/（cm²·h）和2000μg/（cm²·h）左右，远大于连续供油下的值。但供油结束时刻，供油模式的影响大幅下降。此外通断供油下，供油瞬间热冲击对燃油结焦的影响沿喷杆轴向逐渐减小。减小喷杆供油流量，热冲击的影响有所下降，且随时间先升高后降低。提高进口油温，热冲击的影响显著减小，且随供油时间逐渐降低。

关键词: 通断循环供油;喷油杆;热冲击;燃油结焦;数值模拟

ZHOU Xiong¹, KANG Yu-dong¹, KANG Song¹, DENG Yuan-hao¹, LIU Guo-zhu², SUI Chun-jie³. Numerical Studies on Mechanisms and Rules of Fuel Deposition at Transient Moment of Fuel Supply in a Fuel Injector[J]. Journal of Propulsion Technology, 2021, 42(6): 1329-1338.

周雄，康玉东，康松，邓远灏，刘国柱，隋春杰. 供油瞬态喷油杆内燃油结焦机理及规律数值研究[J]. 推进技术, 2021, 42(6): 1329-1338.

References

[1] 郭成富，王勇，曹康. 加力燃烧室喷油杆结焦实验研究［J］. 燃气涡轮实验与研究， 1997，（1）： 26-31.
[2] Branstetter J R. Afterburner Performance of Circular V-Gutters and a Sector of Parallel V-Gutters for a Range of Inlet Temperatures to 1255K［R］. NASA-TN-D-7212， 1995.
[3] Sobel D R， Spadaccini L J. Hydrocarbon Fuel Cooling Technologies for Advanced Propulsion［J］. Journal of Engineering for Gas Turbine and Power， 1997， 119（2）： 344-351.
[4] Spadaccini L J， Sobel D R， Huang H. Deposit Formation and Mitigation in Aircraft Fuels［J］. Journal of Engineering for Gas Turbines and Power， 2001， 123（4）： 741-746.
[5] Chin J S， Lefebvre A H. Experimental Techniques for the Assessment of Fuel Thermal Stability［R］. AIAA 92-0685.
[6] 王英杰，徐国强，吴宏伟，等. 进口雷诺数影响RP-3结焦特性实验研究［J］. 工程热物理学报， 2009， 30（10）： 1710-1712.
[7] 杨彩华，汪旭清，刘国柱，等. 冷却通道预氧化处理抑制碳氢燃料热裂解结焦的研究［J］. 推进技术， 2014， 35（2）： 262-268.
[8] 白兴艳，张频捷，岳连捷，等. 加力用气冷与气动雾化喷油杆的性能研究［J］. 航空动力学报， 2000， 15（4）： 391-396.
[9] 邢菲，孟祥泰，樊未军，等. 气冷气动雾化喷油杆冷却性能实验［J］. 推进技术， 2007， 28（6）： 612-615.
[10] 闫宝华，樊未军，李瑞明，等. 外涵引气加力喷油杆冷却特性模拟实验［J］. 航空动力学报， 2008， 23（10）： 1788-1794.
[11] 刘友宏，王晓博. 风兜面积对喷油杆性能影响的数值研究［J］. 航空动力学报， 2016， 31（2）： 337-344.
[12] 王培，程波. 气流对喷嘴壁温和燃油温升影响的试验研究［C］. 北京：中国航空学会第十九届燃烧与传热传质学术交流会， 2017.
[13] DeWitt M J， Zabarnick S， Ervin J S， et al. Inhibition of Jet Fuel Deposition Within a Complete Oxygen Consumption Regime［C］. Colorado： The 8th International Conference on Stability and Handling of Liquid Fuels （IASH）， 2003.
[14] Chin J S， Rizk N， Razdan M. Engineering Model for Prediction of Deposit Rates in Heated Fuels［R］. AIAA 95-2989.
[15] Gnielinski V. New Equations for Heat and Mass Transfer in Turbulent Pipe and Channel Flows［J］. Internal Chemical Engineering， 1976， 16（2）： 359-368.
[16] Churchill S W， Bernstein M. A Correlating Equation for Forced Convection from Gases and Liquids to a Circular Cylinder in Cross Flow［J］. Journal of Heat Transfer， 1977， 99（2）： 300-306.
[17] 周雄，康玉东，康松，等. 加力燃烧室用气冷喷油杆结焦特性数值研究［J］. 推进技术， 2020， 41（6）： 1340-1350.

Numerical Studies on Mechanisms and Rules of Fuel Deposition at Transient Moment of Fuel Supply in a Fuel Injector

供油瞬态喷油杆内燃油结焦机理及规律数值研究

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