Integration and Verification of Miniature Fluid Film Pressure Sensors in Hydrodynamic Linear Guides

Q2 Engineering

Journal of Machine Engineering Pub Date : 2023-08-19 DOI:10.36897/jme/169525

Burhan Ibrar, V. Wittstock, J. Regel, M. Dix

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引用次数: 0

Abstract

Previously, a 2D simulation model for hydrodynamic linear guides with two reduction factors has been developed to calculate oil film pressure and floating heights/angle numerically. However, no method was available to verify the oil film pressure experimentally but only with floating heights measurement. Therefore, different pressure sensor’s integration methods were tested in a stationary Plexiglas rail to measure fluid film pressure inside the lubrication gap. The pressure sensors were statically and dynamically calibrated. However, floating heights could not be measured with the preliminary used Plexiglas rail. This paper reports the suitable integration of pressure sensors into a stationary steel rail to compensate this drawback. It focuses on the measurement of pressure rise using pressure sensors inside the lubrication gap in combination with the floating heights. Experimental results have shown that the oil film pressure inside the lubrication gap can be measured using pressure sensors, which draw conclusions about cavitation and lack of lubrication. The variation of oil film pressure measured along the length of the carriage can be used to improve the simulation model i.e. the reduction factors. The pressure measurement can help to identify the lubrication conditions and further actions can be taken to improve the lubrication cycle.

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流体动力直线导轨中微型液膜压力传感器的集成与验证

以前，已经开发了一个具有两个折减因子的流体动力学线性导轨的二维模拟模型，以数值计算油膜压力和浮动高度/角度。然而，没有任何方法可以通过实验来验证油膜压力，而只能通过浮动高度测量来验证。因此，在固定的有机玻璃导轨上测试了不同的压力传感器集成方法，以测量润滑间隙内的液膜压力。对压力传感器进行了静态和动态校准。然而，浮动高度无法用初步使用的有机玻璃轨道进行测量。本文报道了将压力传感器适当地集成到固定钢轨中以补偿这一缺点。它的重点是使用润滑间隙内的压力传感器结合浮动高度来测量压力上升。实验结果表明，使用压力传感器可以测量润滑间隙内的油膜压力，从而得出气穴和润滑不足的结论。沿滑架长度测量的油膜压力的变化可用于改进模拟模型，即折减系数。压力测量有助于识别润滑条件，并可采取进一步措施改善润滑循环。

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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来源期刊

Journal of Machine Engineering Engineering-Industrial and Manufacturing Engineering

CiteScore

2.70

自引率

0.00%

发文量

审稿时长

25 weeks

期刊介绍： ournal of Machine Engineering is a scientific journal devoted to current issues of design and manufacturing - aided by innovative computer techniques and state-of-the-art computer systems - of products which meet the demands of the current global market. It favours solutions harmonizing with the up-to-date manufacturing strategies, the quality requirements and the needs of design, planning, scheduling and production process management. The Journal'' s subject matter also covers the design and operation of high efficient, precision, process machines. The Journal is a continuator of Machine Engineering Publisher for five years. The Journal appears quarterly, with a circulation of 100 copies, with each issue devoted entirely to a different topic. The papers are carefully selected and reviewed by distinguished world famous scientists and practitioners. The authors of the publications are eminent specialists from all over the world and Poland. Journal of Machine Engineering provides the best assistance to factories and universities. It enables factories to solve their difficult problems and manufacture good products at a low cost and fast rate. It enables educators to update their teaching and scientists to deepen their knowledge and pursue their research in the right direction.