Investigation of the burnishing process with PCD tool on non-ferrous metals

Luo, Hongyun; Liu, Jianying; Wang, Lijiang; Zhong, Qunpeng

doi:10.1007/s00170-003-1959-5

Cited by 61 publications

(28 citation statements)

References 10 publications

(22 reference statements)

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“…As indicated in Shiou et al [13], the range of burnishing speed was from 200 mm/min to 800 mm/min. According to the study of Banh et al [14], the magnitude of optimal burnishing force is approximately six times smaller than the maximum burnishing force estimated from the boundary analysis of burnishing proposed by Luo et al [24]. For STAVAX material with yielding strength of 1200 MPa, and the 0.5-mm-diameter burnishing ball, the estimated maximum burnishing force is 52.54 N. Hence, the three levels of burnishing forces in this study were 5,10, and 15 N. In agreement with the study of Tam et al [1], although the smaller the step-over produces the lower height of irregularities (Fig.…”

Section: Experimental Factors and Levelsmentioning

confidence: 99%

Determination of Optimal Small Ball-Burnishing Parameters for Both Surface Roughness and Superficial Hardness Improvement of STAVAX

Banh

Shiou

2015

Arab J Sci Eng

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In this study, a novel load cell embedded small ball-burnishing tool with a double spring mechanism was designed and fabricated to conduct the burnishing process on STAVAX material. The influences of process parameters, namely burnishing lubricant, burnishing force, step-over, burnishing speed, and number of passes, on the surface roughness and superficial hardness of the workpiece were investigated. The hybrid grey-based Taguchi method with the weighting coefficients estimated by principal component analysis and grey entropy was employed for experimental design and data analysis. After conducting two sets of experiments, the optimal small ball-burnishing condition on STAVAX material was determined.

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Section: Experimental Factors and Levelsmentioning

confidence: 99%

Determination of Optimal Small Ball-Burnishing Parameters for Both Surface Roughness and Superficial Hardness Improvement of STAVAX

Banh

Shiou

2015

Arab J Sci Eng

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“…The increase of surface strength mainly serves in terms of improved fatigue behavior of workpieces under dynamic load. In addition, this process transforms tensile residual stresses, present in the surface zone after turning, into compressive residual stresses [1][2][3][4][5][6][7][8]. Under certain conditions, this process provides a manufacturing alternative to grinding, precision turning and honing operations [1].…”

Section: Introductionmentioning

confidence: 98%

“…The experimental analysis was mainly undertaken to assess the effects of burnishing feed, speed and depth [1][2][3]5,8,9]. The studies concentrated on determining optimum working parameter ranges in different situations, which are valuable for the application of the burnishing process as the first step.…”

Section: Introductionmentioning

confidence: 99%

Study of the mechanism of the burnishing process with cylindrical polycrystalline diamond tools

Luo

Liu

Wang

et al. 2006

Journal of Materials Processing Technology

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“…Roughness parameters are frequently used for evaluating the reliability of technological operations. In [1,2] a description is given of an investigation of the Ra surface roughness parameter in the context of evaluation of the reliability of a burnishing operation. In turn, Kuczmaszewski and Pieśko used a roughness parameter to evaluate the surface of a groove, and thereby assess the wear on milling tools [3].…”

Section: Introductionmentioning

confidence: 99%

Evaluating the Reliability of Groove Turning for Piston Rings in Combustion Engines with the Use of Neural Networks

Lisiak

Rojek

Twardowski

2017

Archives of Mechanical Technology and Materials

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A B S T R A C TThe article describes a method of evaluating the reliability of groove turning for piston rings in combustion engines. Parameters representing the roughness of a machined surface, Ra and Rz, were selected for use in evaluation. At present, evaluation of surface roughness is performed manually by operators and recorded on measurement sheets. The authors studied a method for evaluation of the surface roughness parameters Ra and Rz using multi-layered perceptron with error back-propagation (MLP) and Kohonen neural networks. Many neural network models were developed, and the best of them were chosen on the basis of the effectiveness of measurement evaluation. Experiments were carried out on real data from a production company, obtained from several machine tools. In this way it becomes possible to assess machines in terms of the reliability evaluation of turning. K E Y W O R D Sreliability evaluation, surface roughness, neural networks

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Investigation of the burnishing process with PCD tool on non-ferrous metals

Cited by 61 publications

References 10 publications

Determination of Optimal Small Ball-Burnishing Parameters for Both Surface Roughness and Superficial Hardness Improvement of STAVAX

Determination of Optimal Small Ball-Burnishing Parameters for Both Surface Roughness and Superficial Hardness Improvement of STAVAX

Study of the mechanism of the burnishing process with cylindrical polycrystalline diamond tools

Evaluating the Reliability of Groove Turning for Piston Rings in Combustion Engines with the Use of Neural Networks

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