Abstract

Due to their vanishingly low air friction, high wear resistance, and environmental friendliness, aerostatic bearings are used in machines, machine tools, and devices that require high accuracy of micro-movement and positioning. The characteristic disadvantages of aerostatic bearings are low load capacity, high compliance and an increased tendency for instability. In radial bearings, it is possible to use longitudinal microgrooves, which practically exclude circumferential air leakage, and contributes to a significant increase in load-bearing capacity. To reduce compliance to zero and negative values, inlet diaphragm and elastic airflow regulators are used. Active flow compensation is inextricably linked to the problem of ensuring the stability of bearings due to the presence of relatively large volumes of gas in the regulator, which have a destabilizing effect. This problem was solved by using an external combined throttling system. Bearings with input flow regulators have a number of disadvantages-they are very energy-intensive and have an insufficiently stable load capacity. A more promising way to reduce compliance is the use of displacement compensators for the movable element. Such bearings also allow for a decrease in compliance to zero and negative values, which makes it possible to use them not only as supports, but also as active deformation compensators of the technological system of machine tools in order to reduce the time and increase the accuracy of metalworking. The new idea of using active flow compensators is to regulate the flow rate not at the inlet, but at the outlet of the air flow. This design has the energy efficiency that is inherent to a conventional bearing, but the regulation of the lubricant output flow allows the compliance to be reduced to zero and negative values. This article discusses the results of a theoretical study of the static and dynamic characteristics of a two-row radial aerostatic bearing with longitudinal microgrooves and an output flow regulator. Mathematical modeling and theoretical study of stationary modes have been carried out. Formulas for determining static compliance and load capacity are obtained. Iterative finite-difference methods for determining the dynamic characteristics of a structure are proposed. The calculation of dynamic quality criteria was carried out on the basis of the method of rational interpolation of the bearing transfer function, as a system with distributed parameters, developed by the authors. It was found that the volumes of the microgrooves do not have a noticeable effect on the bearing dynamics. It is shown that, in this design, the external combined throttling system is an effective means of maintaining stability and high dynamic quality of the design operating in the modes of low, zero and negative compliance.

Highlights

  • Due to the vanishingly low friction in the air, high wear resistance, and environmental friendliness, aerostatic bearings are used in machines, in particular, in machine tools, which are devices that require high accuracy of micro-movement and positioning [1,2,3,4,5,6,7,8]

  • This problem found a solution in the form of using an system of external combined throttling (SECT) containing the main throttling resistance, additional damping resistance and a flow-through air resonator chamber located between them, the optimal volume of which contributes to a drastic improvement in dynamic characteristics [26,27]

  • This article discusses the results of a theoretical study of the static and dynamic characteristics of a two-row radial aerostatic bearing with a SECT, longitudinal microgrooves and an output flow regulator

Read more

Summary

Introduction

Due to the vanishingly low friction in the air, high wear resistance, and environmental friendliness, aerostatic bearings are used in machines, in particular, in machine tools, which are devices that require high accuracy of micro-movement and positioning [1,2,3,4,5,6,7,8]. The technical problem of implementing the principle of active flow compensation is inextricably linked with the problem of ensuring the stability of bearings due to the presence of relatively large volumes of gas in the regulator, which have a destabilizing effect This problem found a solution in the form of using an system of external combined throttling (SECT) containing the main throttling resistance, additional damping resistance and a flow-through air resonator chamber located between them, the optimal volume of which contributes to a drastic improvement in dynamic characteristics [26,27]. A more effective solution to reduce compliance is the use of compensators for displacement of the movable element (shaft) [18,19,20] Such bearings allow for a decrease in compliance to zero and negative values, which, like designs with membrane and elastic regulators, allows them to be used as supports, and as active deformation compensators of the technological system of machine tools in order to reduce time and increase the accuracy of metalworking. This article discusses the results of a theoretical study of the static and dynamic characteristics of a two-row radial aerostatic bearing with a SECT, longitudinal microgrooves and an output flow regulator

Description of the Bearing Design and the Principle of Its Operation
Stationary Model of Bearing Operation with Arbitrary Eccentricities
Non-Stationary Model of the Bearing at Small Deviations from the Central
Bearing Dynamic Characteristics
Findings
Conclusions

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.