直升机中减三相流金属屑末可达性

doi:10.7527/S1000-6893.2023.28524

Abstract

Abstract:

The helicopter intermediate gearbox operates under splash lubrication， and the bearing will produce metal particles due to insufficient lubrication or wear. If the metal particles signal at the bottom of the gearbox fails to absorb and alarm in time， it will lead to the helicopter failure. Therefore， based on Computational Fluid Dynamics （CFD） theory， this paper established the solid-liquid-gas three-phase flow model of the intermediate gearbox， using Fluent 18.2 software. Based on the Euler-Lagrange coupling calculation method， the accessibility of metal particles was calculated and analyzed by applying the RNG k-ɛ turbulence model and dynamic grids and the VOF-DPM coupling model simulation， which achieved good consistency with tests. The results show that the motion of the metal particles is mainly dominated by their own state upon initial entry into casing. After the gear completely stirs the lubricating oil， the motion state of the gear dominates， and the randomness and disorder of the movement are fairly great. The trajectory will abruptly change after bouncing off the casing wall. All metal particles in the gearbox tend to move centrifugally around the gear， and the average velocity of the metal particles shows a nonlinear negative correlation with the distance from the gear. The accessibility of metal particles in the gearbox is weak， and the metal particles will deposit in the grooves and return holes of the oil guide pipe， which prevents the helicopter from achieving real-time alarm monitoring. The gearbox structure， where the metal particles are easy to deposit， should be improved.

Key words: intermediate gearbox, computational fluid dynamics, metal particles, three-phase flow, accessibility

CLC Number:

V228.5

Fengxia LU, Kun WEI, Chunlei WANG, Heyun BAO, Rupeng ZHU. Accessibility of metal particles in three-phase flow of helicopter intermediate gearbox[J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(1): 128524-128524.

Figures/Tables 16

Fig.1

Fig. 2

Table1

Fig. 3

Fig. 4

Fig.5

Fig.6

Fig.7

Fig.8

Fig.9

Fig.10

Fig.11

Table 3

Table 4

Fig.12

References 23

1	吴亮. 含固体颗粒的两相流界面变化的数值研究： DEM-VOF方法的实现［D］. 天津：天津大学， 2018.
	WU L. Development of a DEM-VOF model for the turbulent free-surface flows with particle［D］. Tianjin： Tianjin University， 2018 （in Chinese）.
2	孙茂川. 多相流系统中微颗粒的运动特性研究［D］. 成都：西南交通大学， 2017.
	SUN M C. The study of micro-partical movement characteristics in multiphase flow system［D］. Chengdu： Southwest Jiaotong University， 2017 （in Chinese）.
3	赵海鸣，谢信，廖小乐，等. 径向直叶片风机三相除尘数值模拟［J］. 合肥工业大学学报（自然科学版）， 2017， 40（8）： 1020-1025.
	ZHAO H M， XIE X， LIAO X L， et al. Numerical simulation of three-phase dust removal in radial-straight-blade fan［J］. Journal of Hefei University of Technology （Natural Science）， 2017， 40（8）： 1020-1025 （in Chinese）.
4	夏铖. 基于CFD-DEM方法的两级混流泵内部粗颗粒固液两相流特性研究［D］. 镇江：江苏大学， 2019.
	XIA C. Study on solid-liquid two-phase flow characteristics of coarse particles in two-stage mixed-flow pump based on CFD-DEM method［D］.Zhenjiang： Jiangsu University， 2019 （in Chinese）.
5	YU J C， LUO X T， WANG B， et al. Analysis of gas-liquid-solid three-phase flows in hydrocyclones through a coupled method of volume of fluid and discrete element model［J］. Journal of Fluids Engineering， 2021， 143（11）： 111402.
6	XIAO Y L， TIAN Y F， WANG Q， et al. Numerical investigation of lime particle motion in steelmaking BOF process［J］. JOM， 2021， 73（9）： 2733-2740.
7	ZHANG T， ZENG X J， GUO J C， et al. Numerical simulation on oil-water-particle flows in complex fractures of fractured-vuggy carbonate reservoirs［J］. Journal of Petroleum Science and Engineering， 2022， 208： 109413.
8	WANG H K， YU Y， YU J X， et al. Numerical simulation of the erosion of pipe bends considering fluid-induced stress and surface scar evolution［J］. Wear， 2019， 440-441： 203043.
9	ZHANG Y， CHANG Q， GE W. Coupling DPM with DNS for dynamic interphase force evaluation［J］. Chemical Engineering Science， 2021， 231： 116238.
10	YANG Y， WEN C. CFD modeling of particle behavior in supersonic flows with strong swirls for gas separation［J］. Separation and Purification Technology， 2017， 174： 22-28.
11	SONG C M， PEI B B， JIANG M T， et al. Numerical analysis of forces exerted on particles in cyclone separators［J］. Powder Technology， 2016， 294： 437-448.
12	LI L C， XU B. CFD simulation of gas-liquid floating particles mixing in an agitated vessel［J］. Chemical Industry and Chemical Engineering Quarterly， 2017， 23（3）： 377-389.
13	MITHUN M G， KOUKOUVINIS P， KARATHANASSIS I K， et al. Numerical simulation of three-phase flow in an external gear pump using immersed boundary approach［J］. Applied Mathematical Modelling， 2019， 72： 682-699.
14	GALLETTI C， RUM A， TURCHI V， et al. Numerical analysis of flow field and particle motion in a dynamic cyclonic selector［J］. Advanced Powder Technology， 2020， 31（3）： 1264-1273.
15	YANG K， HU W H. Simulation on debris particles conveying process in lubricant between gear engagement［J］. Wear， 2019， 426-427： 1391-1398.
16	HIRT C W， NICHOLS B D. Volume of fluid （VOF） method for the dynamics of free boundaries［J］. Journal of Computational Physics， 1981， 39（1）： 201-225.
17	GOSMAN A D， LOANNIDES E. Aspects of computer simulation of liquid-fueled combustors［J］. Journal of Energy， 1983， 7（6）： 482-490.
18	MORSI S A， ALEXANDER A J. An investigation of particle trajectories in two-phase flow systems［J］. Journal of Fluid Mechanics， 1972， 55（2）： 193.
19	陆凤霞，王孟，王春雷，等. 直升机中减飞溅润滑流场分析与优化方法［J］. 航空学报， 2020， 41（11）： 123659.
	LU F X， WANG M， WANG C L， et al. Analysis and optimization method for flow field of intermediate gearbox splash lubrication in helicopters［J］. Acta Aeronautica et Astronautica Sinica， 2020， 41（11）： 123659 （in Chinese）.
20	LEMFELD F， FRANA K， UNGER J. Numerical simulation of unsteady oil flows in the gearboxes［J］. Journal of Applied Science in the Thermodynamics and Fluid Mechanics， 2007， 1（1）： 1-5.
21	LIN Y H， HU Z H， XIONG C Q， et al. Research of flow field simulation for lubrication system and effect evaluation on a 7-speed dual clutch transmission［C］∥Proceedings of the FISITA 2012 World Automotive Congress. Berlin： Springer， 2013： 285-298.
22	MOSHAMMER T， MAYR F， KARGL K， et al. Simulation of oil flow in gear box housing［C］∥SAE World Congress & Exhibition. Detroit： SAE， 2006.
23	GORLA C， CONCLI F， STAHL K， et al. Hydraulic losses of a gearbox： CFD analysis and experiments［J］. Tribology International， 2013， 66： 337-344.

参数	主动轮	从动轮
旋向	右旋	左旋
齿数	31	43
模数m/mm	3.8	3.8
齿宽b/mm	25	25
压力角α/（°）	20	20
螺旋角β/（°）	30	30
轴交角Σ/（°）	128	128

参数	输入轴轴承	输出轴轴承
滚子数量	22/25		22/25
内圈转速/（r·min^-1）	5 000	3 804
小滚子转速/（r·min^-1）	2 264.05	1 722.65
大滚子转速/（r·min^-1）	2 228.82	1 695.84
内圈直径d₁/mm	55		55
外圈直径d₂/mm	90		90
轴承宽度b/mm	40		40
金属屑末粒径/mm	0.72		0.72
金属屑末材料	M50-NiL		M50-NiL
金属屑末密度/（kg·m^-3）	7 810		7 810

位置	信号器吸收	通气孔逃离
长排锥轴承	gear_5， gear_7	pinion_9
短排锥轴承	gear_8	0
齿轮啮合处	niehe_1	niehe_4， niehe_5， niehe_9

粒径/mm	信号器吸收	通气孔逃离
0.3	0	1
0.5	0	0
0.72	2	1
1.0	2	0
1.2	0	0

[1]	Jiong REN, Gang WANG, Guodong HU, Xiaolu SHI. Adaptive finite volume method with Walsh basis functions [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2023, 44(8): 127444-127444.
[2]	Wenbo CAO, Yilang LIU, Weiwei ZHANG. Accelerated convergence method for fluid dynamics solvers based on reduced⁃order model and gradient optimization [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2023, 44(6): 127090-127090.
[3]	Sihua LIU, Zhanying WANG, Lijian LI, Mindi ZHANG. Influence of nose shapes on high-speed water entry stability of projectile [J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(21): 528437-528437.
[4]	Yuxiang FAN, Rui ZHAO, Zhengxuan ZUO, Guang YANG, Yu LI. Gas⁃injection effects on wall heat flux and skin⁃friction of vehicles [J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(21): 528587-528587.
[5]	Jianling QIAO, Zhonghua HAN, Yulin DING, Wenping SONG, Bifeng SONG. Effects of stratified atmospheric turbulence on farfield sonic boom propagation [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2023, 44(2): 626350-626350.
[6]	Shengye WANG, Xiaogang DENG, Yidao DONG, Dongfang WANG, Jiahong CAI. High-order numerical methods for engineering turbulence simulation [J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(15): 528728-528728.
[7]	XIAHOU Tangfan, CHEN Jiangtao, SHAO Zhidong, WU Xiaojun, LIU Yu. Model validation metrics for CFD numerical simulation under aleatory and epistemic uncertainty [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2022, 43(8): 25716-025716.
[8]	CHEN Guangqiang, DOU Guohui, WEI Haogong, ZOU Xin, LI Qi, LIU Zhou, ZHOU Weijiang. Air data sensing technology of Mars probe [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2022, 43(3): 626619-626619.
[9]	YI Jianmiao, DENG Feng, QIN Ning, LIU Xueqiang. Fast prediction of transonic flow field using deep learning method [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2022, 43(11): 526747-526747.
[10]	WANG Di, QIAN Zhansen, LENG Yan. High-order scheme discretization of sonic boom propagation model based on augmented Burgers equation [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2022, 43(1): 124916-124916.
[11]	BAO Jun, WANG Yu, NIU Qian, ZHU Xidong, CHENG Jianjie. Influencing parameters and film flow mechanism of spray droplet impacting liquid film [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2021, 42(S1): 726360-726360.
[12]	CHEN Jianqiang, WU Xiaojun, ZHANG Jian, LI Bin, JIA Hongyin, ZHOU Naichun. FlowStar: General unstructured-grid CFD software for National Numerical Windtunnel (NNW) Project [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2021, 42(9): 625739-625739.
[13]	LI Zuobiao, WEN Fengbo, TANG Xiaolei, SU Liangjun, WANG Songtao. Prediction of single-row hole film cooling performance based on deep learning [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2021, 42(4): 524331-524331.
[14]	YANG Xiaofeng, LI Qin, DU Yanxia, LIU Lei, GUI Yewei. Progress in numerical research on interface heterogeneous catalysis of hypersonic vehicles [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2021, 42(12): 625908-625908.
[15]	CHANG Siyuan, BAI Xiaozheng, LIU Jun. A two-dimensional shock wave pattern recognition algorithm based on cluster analysis [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2020, 41(8): 123626-123626.

Accessibility of metal particles in three-phase flow of helicopter intermediate gearbox

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 16

References 23

Related Articles 15

Recommended Articles

Metrics

Comments