Efficient Technological Control of the Processing of Bearing Rollers

Vainer, L.; Gamolya, U.

doi:10.4028/www.scientific.net/MSF.945.675

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HomeMaterials Science ForumFarEastСon - Materials and ConstructionEfficient Technological Control of the Processing...

Efficient Technological Control of the Processing of Bearing Rollers

Abstract:

In the article the strategy and algorithm of technological control of the process of bilateral abrasive processing of cylindrical bearing rollers are considered. The main variable control parameters of the process are the parameters of the angular position of the grinding wheels, the size of the removed allowance and the feed rate of the workpieces. As a result of complex theoretical and experimental research, control principles, criterial conditions, functional and parametric constraints are formulated. The solution of the problem of synthesis of control parameters is given. The effectiveness of the technological control is confirmed by production tests and is expressed in increasing the accuracy and productivity of processing rollers.

Info:

Periodical:

Materials Science Forum (Volume 945)

Main Theme:

FarEastСon - Materials and Construction

Edited by:

Dr. Denis Solovev

Pages:

675-681

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.945.675

Citation:

L. Vainer and U. Gamolya, "Efficient Technological Control of the Processing of Bearing Rollers", Materials Science Forum, Vol. 945, pp. 675-681, 2019

Online since:

February 2019

Authors:

L. Vainer, U. Gamolya

Keywords:

Accuracy, Bearing Rollers, Bilateral Grinding, Control Principles, Criterial Conditions, Technological Control

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$41.00

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References

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DOI: https://doi.org/10.1109/meacs.2015.7414974

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DOI: https://doi.org/10.3103/s1068798x11120276

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DOI: https://doi.org/10.3103/s1068798x13030179

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DOI: https://doi.org/10.3103/s1068798x14050165

Paper TitlePages

Modeling of Virtual Grinding Wheel and its Grinding Simulation

Authors: Wan Shan Wang, Chong Su, Tian Biao Yu, Li Da Zhu

Abstract: Based on virtual reality technology, a friendly human-computer interaction interface and virtual machining environment were developed by Visual C++ and OpenGL. Considering the inhomogeneity of grain size and randomicity of grain distribution, virtual grinding wheel was modeled by taking ortho-hexahedron as basic shape of abrasive grains and randomly distributes them on the wheel base. Mathematic model of interference between abrasive grain and workpiece was established. By using the virtual grinding wheel modeled, surface grinding processes with different machining parameters were simulated. The simulation results show that the system could make operators have a further understanding to chip formation, and the machining results could reflect realistic surface topography of workpiece. Complex grinding process can be realistically simulated. It provides visualization models for the research of grinding mechanism and production forecast.

216

Trajectory Interpolation in CNC Grinding of Indexable Inserts

Authors: Xin Cheng Tian, Xiao Hong Deng

Abstract: Most of the commenly adotped interpolation algorithems are for the curve machining on CNC machine tools with Cartesian coordinates configuration. For a CNC machine tool with non-Cartesian configuration, new trajectory interpolation algorithem must be developed to machine complex part sueface. Based on the analysis of the geometric characteristics and the CNC grinding principle of indexable inserts, this paper proposes two interpolation algorithems to grind the nose surface of indexable inserts with constant or variable back angle. The algorithm precision analysis is also made in this paper.

2007

Analysis of Super-High Speed Point Grinding Forces

Authors: Ya Dong Gong, Jian Qiu, Yue Ming Liu, Jun Cheng

Abstract: Super high-speed point grinding is a good performance grinding with high surface quality due to its low force. To model point grinding forces including swivel angle formed by tilting wheel to the horizontal workpiece axis seems necessary. In this research, a point grinding force model was present, and the point grinding forces are influenced by factors such as grinding depth, wheel velocity, swivel angle as well as equivalent diameter. And then some experimental tests are carried out. It is found that the experimental data was in good agreement with theoretical model.

A Study on the Manufacturing System of the Axes Linked Ultra-Precision Grinding of Aspheric Surface

Authors: Li Jun Li, Y. Jiang, Fei Hu Zhang

Abstract: The manufacturing system developed in this paper is mainly used for the ultra-precision grinding of the hard-cutting materials, such as high strength steel and carbonized tungsten, which are characteristics with axisymmetric aspheric surface. Under the priority of accuracy and grinding rigidity to design the key components of multi-axis linked parallel grinding system of aspheric surface, such as high speed grinding spindle, B axis grinding rotary table, clamps and center high adjusting system. Maximum speed of the grinding spindle is 90,000rpm, spindle rotating accuracy is 0.1μm, rotation-angle-accuracy of B axis is , center height adjusting accuracy is 0.1μm, using the system can realize parallel grinding of aspheric surface[1].

500

Ultra Precision Grinding of Wafer Scale

Authors: Martin Hünten, Fritz Klocke, Olaf Dambon, Benjamin Bulla

Abstract: Manufacturing moulds for the wafer-scale replication of precision glass optics sets new demands in terms of grinding tool lifetime and the processes to be applied. This paper will present different approaches to grinding processes and kinematics to machine wafer-scale tungsten carbide moulds with diameters of up to 100 mm and more than 100 single aspheric cavities, each featuring form accuracies in the micron range. The development of these processes will be described and advantages and disadvantages of the approaches derived from practical tests performed on an ultra precision grinding machine (Moore Nanotech 350FG) will be discussed. Finally, a comparison between the developed processes is made where achieved form accuracies and surface topography are analyzed.

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