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Abstract

The dynamic pressure oil-air separator plays a vital role in aero-engine lubrication systems, as its performance directly determines overall reliability and efficiency. To enhance lubrication performance, it is essential to understand the internal flow characteristics within the separator. In this study, a Mixture multiphase flow model was employed to numerically investigate the oil-air two-phase flow field inside the separator. The effects of inlet velocity and initial oil-air ratio on the distributions of air phase, tangential velocity, and axial velocity were systematically analyzed to elucidate the correlation between flow field structure and separation performance. Numerical results indicate that the tangential velocity distribution conforms to a Rankine vortex structure: a forced vortex exists in the central region, while a free vortex forms near the wall. Axial velocity is negative near the central axis, indicating air motion toward the outlet, and positive near the wall, representing oil motion toward the bottom. At an initial oil-air ratio of 7:3, increasing the inlet velocity from 3.5 to 4.5 m/s stabilizes the internal swirling flow and mitigates air accumulation at the bottom, raising separation efficiency from 90.7% to a maximum of 93.9%. Moreover, a higher initial oil-air ratio facilitates a stable, continuous oil film along the wall, suppressing turbulent interphase mixing. Consequently, at 4.0 m/s, increasing the ratio from 7:3 to 8:2 further enhances efficiency from 92.5% to 93.3%. Numerical predictions agree well with experimental data, with a maximum error of 6%.

Keywords

aero-engine dynamic pressure oil-air separator separation efficiency mixture model

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References

Xin

Wei

, et al. Overview of architecture and technologies of turbofan engine mechanical system. Aeroengine 2024; 50(04): 1–9.

Qiu

Zhou

Bai

, et al. Empirical and numerical advancements in gas-liquid separation technology: a review. Geoenergy Sci Eng 2024; 233: 212577.

Flouros

Salpingidou

Yakinthos

, et al. Ejector application for scavenging of an aero engine bearing chamber. Journal of Engineering for Air Turbines and Power-Transactions of the ASME 2017; 139(10): 101202.

Zhu

Wang

Zhang

, et al. Experimental study on performance of dynamic pressure type lubricant-air separator. J Propuls Technol 2016; 37(05): 852–857.

Zhang

, et al. Numerical study on the influence of length-diameter ratio on the performance of dynamic pressure oil-air separator. Int J Chem Eng 2021; 2021: 6649128.

Zhu

Zhang

. The effects of the lower outlet on the flow field of small gas-liquid cylindrical cyclone. Proc IME C J Mech Eng Sci 2019; 233(4): 1262–1270.

Guo

. Research on heat exchange and oil-gas separation technology of high and low temperature mixed thin oil lubrication system. Master’s thesis: Xi’an University of Technology, 2023.

Ghasemi

Shams

Heyhat

. A numerical scheme for optimizing gas liquid cylindrical cyclone separator. Proc Inst Mech Eng Part E J Process Mech Eng 2017; 231(4): 836–848.

Nguyen

, et al. The effect of the different inlet's structures of the gas-liquid cylindrical cyclone (GLCC) separator. Appl Mech Mater 2019; 894: 112–125.

10.

Wang

Chen

Yang

, et al. Experimental and numerical performance study of a downward dual-inlet gas-liquid cylindrical cyclone (GLCC). Chem Eng Sci 2021; 238: 116595.

11.

Zhou

Chen

Wang

, et al. Experimental and numerical study on the performance of a new dual-inlet gas-liquid cylindrical cyclone (GLCC) based on flow pattern conditioning. Chem Eng J 2023; 453: 139778.

12.

Caceres

JSC

Prieto

Gonzalez

, et al. Numerical simulation of a natural gas cylindrical cyclone separator using computational fluid dynamics. Ind Eng Chem Res 2019; 58(31): 14323–14332.

13.

Van

. Influence of inlet angle on flow pattern and performance of gas-liquid cylindrical cyclone separator. Part Sci Technol 2017; 35(5): 555–564.

14.

Van Sy

Lan

. Selecting the inlet configuration for gas-liquid cylindrical cyclone separator. IOP Conf Ser Mater Sci Eng 2023; 1294(1): 012008.

15.

Kolla

Mohan

Shoham

. Gas carry-under in gas-liquid cylindrical cyclone separator: a mechanistic model. In: Proceedings of the ASME-JSME-KSME 2019 8th Joint Fluids Engineering Conference: ASME, July 28-August 1, 2019, vol 5. Paper No. V003T03A045.

16.

Kolla

Mohan

Shoham

. Swirling flow regimes and gas carry-under in gas-liquid cylindrical cyclone separator in a separated outlet configuration. Journal of Energy Resources Technology-Transactions of the ASME 2021; 143(4): 042101.

17.

Wang

Chen

Yue

, et al. Measurement of thickness and analysis on flow characteristics of upper swirling liquid film in gas-liquid cylindrical cyclone. Exp Therm Fluid Sci 2021; 123: 110331.

18.

Wang

Yan

Fan

, et al. Experimental study on a swirl-vane separator for gas-liquid separation. Chem Eng Res Des 2019; 151: 108–119.

19.

Wang

Liao

Feng

, et al. Experimental investigation of oil film flow and droplets behavior in the annular channel of a cyclone separator. Exp Therm Fluid Sci 2023; 147: 110943.

20.

Ren

Kong

Wang

. Analysis of flow of aerial dynamic pressure oil-gas separator. Modern Machinery 2023; 3: 26–30.

21.

Siadaty

Kheradmand

Ghadiri

. Study of inlet temperature effect on single and double inlets cyclone performance. Adv Powder Technol 2017; 28(6): 1459–1473.

22.

Yan

Sun

, et al. Numerical simulations of the dynamic pressure oil-gas separator. Ib: Recent Advances in Mechanisms, Transmissions and Applications: Springer, 2020, pp. 203–212.

23.

Huang

Deng

Chen

, et al. Numerical analysis of a novel gas-liquid pre-separation cyclone. Separation and Purification Technology 2018; 194: 470–479.

24.

Yang

Zhang

, et al. Experimental and numerical study of separation characteristics in gas-liquid cylindrical cyclone. Chem Eng Sci 2020; 214: 115362.

25.

Jiang

Liu

Lyu

, et al. Numerical simulation on the oil capture performance of the oil scoop in the under-race lubrication system. Proc Inst Mech Eng G J Aerosp Eng 2021; 235(15): 2258–2273.

26.

Chen

. Optimization of the hole exit shape of the Vortex generator jets in a compressor Cascade. Proc Inst Mech Eng G J Aerosp Eng 2022; 236(1): 11–23.

27.

Fang

, et al. Research on the air-oil two-phase flow regime in an aeroengine bearing chamber based on hilbert-Huang transform. Proc Inst Mech Eng G J Aerosp Eng 2022; 236(1): 24–32.

28.

Wang

Feng

, et al. An experimental investigation of the oil film distribution in an oil-gas cyclone separator. Proc IME E J Process Mech Eng 2017; 231(1): 14–25.

29.

Zhang

Wang

, et al. Experimental study on radial evolution of droplets in vertical gas-liquid two-phase annular flow. Int J Multiphas Flow 2020; 129: 103325.

30.

Erdal

Shirazi

. Effect of inlet configuration on flow behavior in a cylindrical cyclone separator. American Society of Mechanical Engineers, Petroleum Division (Publication) PD, 2002, pp. 521–529.

31.

Hreiz

Gentric

Midoux

. Numerical investigation of swirling flow in cylindrical cyclones. Chem Eng Res Des 2011; 89(12): 2521–2539.

32.

Zhang

. The research on performance of dynamic pressure type gas-oil separator in aero-engine. PhD thesis: Harbin Engineering University, 2018.

Numerical analysis of two-phase flow and separation efficiency in a dynamic pressure oil-air separator for aero-engines

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