金斯伯里推力轴承的空气润滑性能演示

IF 0.9 Q4 ENGINEERING, MECHANICAL

International Journal of Rotating Machinery Pub Date : 2021-02-27 DOI:10.1155/2021/6690479

Wanjun Xu, Jiangang Yang

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引用次数: 1

摘要

为了了解Kingsbury推力轴承演示的空气润滑行为，对模拟Kingsburry推力轴承进行了实验和理论研究。在三种质量载荷情况下，通过涡流传感器测量了推力盘和可倾瓦的运动。建立了推力盘运动的简化理论模型。该轴承成功通过了灯泡熄灭检查，并保持了16的最大旋转时间 s.厚度约为5 μm集中在工作表面的中间区域，平坦度为0.010 三个表面凸起的不利影响通过倾斜垫的摆动运动而最小化。此外，由于表面不规则性，大约1/3的空气膜厚度被证明是浪费的。然而，通过中心枢转倾斜垫的设计，表面质量和错位的要求得到了适当的放宽。这种设计有利于薄膜润滑，是微型涡轮机的潜在应用。

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The Air Lubrication Behavior of a Kingsbury Thrust Bearing Demonstration

In order to understand the air lubrication behavior of Kingsbury thrust bearing demonstration, an experimental and theoretical investigation on a simulated Kingsbury thrust bearing was presented. The motions of the thrust disk and tilting pads were measured by eddy current sensors for three mass load cases. A simplified theoretical model governing the motion of the thrust disk was established. The bearing successfully passed the examination of lamp extinction and maintained the maximum rotation time of 16 s. The effective hydrodynamic film with a thickness of about 5 μm was concentrated on the middle region of the working surface under a flatness of 0.010 mm. The adverse effect of the three surface bumps was minimized by the swing motion of tilting pads. Moreover, about 1/3 air film thickness was shown to be wasted due to the surface irregularity. However, the requirements of surface quality and misalignment were appropriately relaxed through the design of the centrally pivoted tilting pads. This design is conducive to thin-film lubrication and is a potential application for microturbines.

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来源期刊

International Journal of Rotating Machinery ENGINEERING, MECHANICAL-

CiteScore

2.40

自引率

0.00%

发文量

审稿时长

25 weeks

期刊介绍： This comprehensive journal provides the latest information on rotating machines and machine elements. This technology has become essential to many industrial processes, including gas-, steam-, water-, or wind-driven turbines at power generation systems, and in food processing, automobile and airplane engines, heating, refrigeration, air conditioning, and chemical or petroleum refining. In spite of the importance of rotating machinery and the huge financial resources involved in the industry, only a few publications distribute research and development information on the prime movers. This journal is the first source to combine the technology, as it applies to all of these specialties, previously scattered throughout literature.