气体箔推力轴承热性能边界角的优化设计

IF 3.1 3区工程技术 Q2 ENGINEERING, MECHANICAL

Lubricants Pub Date : 2024-04-24 DOI:10.3390/lubricants12050143

Bin Hu, Anping Hou, Rui Deng, Xiaodong Yang, Zhiyong Wu, Qifeng Ni, Zhong Li

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引用次数: 0

摘要

随着空气压缩机能量密度和效率要求的不断提高，气膜推力轴承因其转速高、冷却空间有限而面临着热失效的高风险。本文提出了一种可增强热特性的新型气膜推力轴承结构。采用热-流体-固体相互作用方法建立了热弹性-流体动力学模型，以研究气动和热性能。分析了九种不同边界角的承载能力和热特性。对模型进行了验证，并使用试验台检验了具有不同边界角的气膜轴承的实际特性。结果表明，与边界角为 0° 的传统推力气膜轴承相比，边界角为 -10° 至 -5° 的新结构不仅保持了承载能力，还改善了热特性。此外，这种改善在转速越高时越明显。因此，所提出的优化方案在降低热失效风险方面具有优势。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Optimal Design of Boundary Angle for Gas Foil Thrust Bearing Thermal Performance

As the energy density and efficiency requirements of air compressors continue to increase, gas foil thrust bearings face a high risk of thermal failure due to their elevated speed and limited cooling space. This paper proposes a novel structure for gas foil thrust bearings with enhanced thermal characteristics. A thermo-elastic–hydrodynamic model is developed using a thermal-fluid–solid interaction approach to investigate aerodynamic and thermal performance. The load capacity and thermal characteristics of nine different boundary angles are analyzed. The model is validated, and the actual characteristics of gas foil bearings with various boundary angles are examined using a test rig. The results indicate that, compared to conventional gas foil thrust bearings with a boundary angle of 0°, the new structure with a boundary angle ranging from −10° to −5° not only maintains the load carrying capacity but also improves thermal characteristics. Furthermore, this improvement becomes more pronounced with higher rotational speeds. Therefore, the proposed optimization is advantageous in reducing the risk of thermal failure.

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来源期刊

Lubricants Engineering-Mechanical Engineering

CiteScore

3.60

自引率

25.70%

发文量

293

审稿时长

11 weeks

期刊介绍： This journal is dedicated to the field of Tribology and closely related disciplines. This includes the fundamentals of the following topics: -Lubrication, comprising hydrostatics, hydrodynamics, elastohydrodynamics, mixed and boundary regimes of lubrication -Friction, comprising viscous shear, Newtonian and non-Newtonian traction, boundary friction -Wear, including adhesion, abrasion, tribo-corrosion, scuffing and scoring -Cavitation and erosion -Sub-surface stressing, fatigue spalling, pitting, micro-pitting -Contact Mechanics: elasticity, elasto-plasticity, adhesion, viscoelasticity, poroelasticity, coatings and solid lubricants, layered bonded and unbonded solids -Surface Science: topography, tribo-film formation, lubricant–surface combination, surface texturing, micro-hydrodynamics, micro-elastohydrodynamics -Rheology: Newtonian, non-Newtonian fluids, dilatants, pseudo-plastics, thixotropy, shear thinning -Physical chemistry of lubricants, boundary active species, adsorption, bonding