Optimization of the Internal Roller Burnishing Process for Energy Reduction and Surface Properties

Nguyen, Trung Thanh; Thai, Le Minh

doi:10.5545/sv-jme.2021.7106

Cited by 12 publications

(5 citation statements)

References 26 publications

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“…Figure 10 (b) shows the relationship between surface roughness average and feed rate value subjected to the spring tool. However, previous studies showed that the surface roughness was decreased as the feed rate increased until it reaches a certain value then it begins to be increased again [6][7][8][9][10][11][12][13][14][15][16][17][18][19][20]. Furthermore, in this study increasing the feed rate is correlated with an increase in surface roughness [21].…”

Section: Burnishing Feed Ratementioning

confidence: 60%

“…As manufacturing tolerances progressively tighten to meet precision requirements in applications involving fluid sealing, coefficient of friction control, and miniature clearances, understanding how surface shaping methods like burnishing sculpt very near-surface geometry becomes imperative [7,8]. Previous research has also identified opportunities to optimize process parameters to reduce energy consumption during surface treatment while enhancing surface quality [9]. For instance, it has been observed that surface roughness decreases with increasing burnishing speed, reaching a minimum value before rising again at higher speeds [10].…”

Section: Introductionmentioning

confidence: 99%

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Investigating the Influence of Tool Selection on Surface Quality in Burnished AISI 1035 Steel

Alsamanty,

Youssef,

Abdelsalam

et al. 2024

Engineering Research Journal (Shoubra)

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The metal burnishing process is a vital and modern technique for achieving high-quality surface finishes. This research uses the Taguchi and RSM (Response Surface Methodology) methods to optimize the ball burnishing process parameters. Three different tools were specifically designed and utilized in this study, and a Taguchi L16 matrix was employed for the experimental design. The results of surface roughness parameters and surface out-ofroundness were conducted. The resulting data was subjected to square regression analysis. The findings of this research demonstrate that both the tool type selected as well as the burnishing parameters significantly influence the surface roughness and out-of-roundness values. The analysis revealed intricate relationships between these factors, providing valuable insights for process optimization. Specifically, the research identified optimal parameter combinations for each tool type, leading to improved surface quality. The rigid tool exhibited minimum surface roughness at a rotational speed of 450 RPM, a feed rate of 0.09 mm/rev, and a penetration depth of 0.35 mm. While the spring tool achieved minimum surface roughness at a rotational speed of 500 RPM, a feed rate of 0.09 mm/rev, and a penetration depth of 0.35 mm. For out-of-roundness, the rigid tool exhibited minimum out-of-roundness at a rotational speed of 600 RPM, a feed rate of 0.12 mm/rev, and a penetration depth of 0.35 mm. While the spring tool achieved minimum out-of-roundness at a rotational speed of 475 RPM, a feed rate of 0.09 mm/rev, and a penetration depth of 0.20 mm. Additionally, the pneumatic tool yielded minimum surface roughness at a rotational speed of 600 RPM, a feed rate of 0.11 mm/rev, and a depth of penetration of 0.20 mm, with minimum out-of-roundness achieved at a rotational speed of 300 RPM, a feed rate of 0.10 mm/rev, and a depth of penetration of 0.20 mm.

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Section: Burnishing Feed Ratementioning

confidence: 60%

Section: Introductionmentioning

confidence: 99%

Investigating the Influence of Tool Selection on Surface Quality in Burnished AISI 1035 Steel

Alsamanty,

Youssef,

Abdelsalam

et al. 2024

Engineering Research Journal (Shoubra)

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“…The outcome demonstrates a 90% reduction in surface roughness and a 41% improvement in microhardness. Nguyen, T. T. et al [3] innovated the goals in terms of Internal Roller Burnishing parameters by utilizing an adaptive neurobased fuzzy inference system (ANFIS). the result of the optimization process.…”

Section: 𝐾 𝑈 = 𝐹…8mentioning

confidence: 99%

Enhancing Surface Integrity and Quality through Roller Burnishing: A Comprehensive Review of Parameters Optimization, and Applications.

Avinash A. Somatkar

2024

cana

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Surface integrity is a critical aspect in ensuring the quality of components or products, particularly in industries such as automotive, aerospace, and machinery where superior surface finish and prolonged functionality of cylindrical parts are essential. Burnishing, a chip-less cold working finishing process, enhances the surface finish of machined workpieces through plastic deformation. This review paper delves into various aspects of the burnishing process and its impact on surface properties, drawing insights from multiple research projects. It explores topics including residual stresses, surface roughness, microhardness, cooling strategies, and modeling techniques. Key findings underscore the influence of burnishing parameters such as speed, feed rate, penetration depth, and number of passes on surface roughness and microhardness. Moreover, the process induces compressive residual strains on the workpiece surface, with their magnitude varying based on operational parameters. The choice of cooling methods, including kerosene, minimum quantity lubrication (MQL), cryogenic cooling, and hybrid cooling, significantly affects surface integrity. Various modeling approaches, such as Artificial Neural Networks (ANN), Adaptive Neuro-Fuzzy Inference Systems (ANFIS), and Response Surface Methodology (RSM), aid in predicting and optimizing surface characteristics. Despite the extensive discussion on surface roughness, microhardness, residual stresses, cooling methods, and modeling, out-of-roundness in the burnishing process remains understudied and warrants further investigation. This review contributes valuable insights for enhancing surface qualities in manufacturing applications and deepening our understanding of the burnishing process.

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“…The energy efficiency of the internal burnishing was enhanced by 7.0%, while the noise emission and Rs were decreased by 2.2%, and 25.0% [12]. Nguyen and Le revealed that the energy consumption and Rs of the external burnishing were reduced by 33.0% and 16.0%, respectively [13]. Nguyen et al stated that the total energy, mean roughness, and roundness of the MQL-assisted internal burnishing were reduced by 12.0%, 14.0%, and 43.0%, respectively [14].…”

Section: Introductionmentioning

confidence: 99%

Ecological design optimization of nozzle parameters for burnishing operation

Thai¹,

Van²,

Nguyen³

et al. 2023

J Appl Eng Science

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The design configuration of the nozzle has a vital role in the performance measures of the machining processes. However, parameter optimizations are primary considerations of published works. This study optimizes nozzle design parameters to minimize environmental impacts and enhance the surface quality for the diamond burnishing (DB) operation. The performance measures considered are energy efficiency (ED), noise emission (NE), and the total height of profile roughness (Rt). The variables are the inner diameter (D), spraying distance (S), and pitch angle (P). The optimal Taguchi-based Bayesian regularized feed-forward neural network (TBRFFNN) was applied to propose performance models. The CRITIC approach is utilized to compute the weight values of responses, while the desirability approach (DA) is employed to select optimality. The observed results of the D, S, and P were 3.0 mm, 15 mm, and 45 deg., respectively. The ED was enhanced by 12.7%, while the RT and NE were decreased by 24.4% and 9.1%, respectively, as compared to the original design parameters. The obtained outcomes could be utilized in the practice to boost technical characteristics. The developed optimizing approach could be employed to deal with optimization problems for different machining processes

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Optimization of the Internal Roller Burnishing Process for Energy Reduction and Surface Properties

Cited by 12 publications

References 26 publications

Investigating the Influence of Tool Selection on Surface Quality in Burnished AISI 1035 Steel

Investigating the Influence of Tool Selection on Surface Quality in Burnished AISI 1035 Steel

Enhancing Surface Integrity and Quality through Roller Burnishing: A Comprehensive Review of Parameters Optimization, and Applications.

Ecological design optimization of nozzle parameters for burnishing operation

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