Subsurface damage in high-speed grinding of brittle materials considering kinematic characteristics of the grinding process

Wang, Changchu; Fang, Qihong; Chen, Jianbin; Liu, Youwen; Jin, Tan

doi:10.1007/s00170-015-7627-8

Cited by 46 publications

(15 citation statements)

References 48 publications

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“…15–17 Wear of the girt is re-sharpened by further process during grinding of hard materials. 18 Grinding force is an important response, which reflects the chip formation and surface integrity. 19 During the grinding process, grit makes physical contact with the workpiece and slides over the workpiece.…”

Section: Introductionmentioning

confidence: 99%

Studies on the grinding force, size effect, surface texture, and mechanism of material removal in the grinding of AA6061-TiB₂/ZrB₂ in situ composite

Mahamani

2019

Journal of Micromanufacturing

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Machining and conversion of aluminum matrix composites into a desired shape with accuracy has been a challenge for many years. Grinding is a process aimed at achieving better-quality surface finish along with reasonable rate of material removal. The present article describes the influence of operating parameters on the tangential grinding force, size effect, and surface integrity in the grinding of in situ aluminum matrix composites using various grinding wheels. The material removal mechanism of the in situ composite under different grinding conditions is established. Experimental results show that the grinding operating parameters have significant influence on the tangential grinding force, size effect, surface integrity, and material removal. Scanning electron and atomic force microscopy findings indicate presence of numerous surface defects on the grounded surface under all grinding conditions. Diamond grinding wheel outperformed the CBN and Al2O3 wheels by requiring lower grinding force and specific grinding energy and generating lower surface defects. Surface defects, including grinding striation, delamination, and ridge formation are unavoidable under all machining conditions. However, the aforementioned surface defects indicate the ductile mode of material removal at all experimental conditions. Undeformed chip thickness under various grinding conditions plays a significant role in material removal and surface generation. These findings help to understand the mechanism of material removal in machining of in situ composites under various grinding conditions, which helps in attaining the economic production rate without compromising the surface integrity.

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Section: Introductionmentioning

confidence: 99%

Studies on the grinding force, size effect, surface texture, and mechanism of material removal in the grinding of AA6061-TiB₂/ZrB₂ in situ composite

Mahamani

2019

Journal of Micromanufacturing

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“…Blaineau et al obtained the relationship between SSD depth and grinding force by comparing experimental results with discrete element method simulation results [ 21 ]. Wang et al used the method of theoretical analysis, numerical simulation, and experimental testing to analyze the SSD during the high-speed grinding of brittle materials [ 22 ]. However, theoretical studies on the SSD of hard brittle materials in the polishing process have been reported with limited success, which is likely because the majority of existing studies rarely take systematic theoretical models for SSD and three-dimensional (3D) dynamic analysis into consideration.…”

Section: Introductionmentioning

confidence: 99%

Subsurface Damage in Polishing Process of Silicon Carbide Ceramic

Zhu

Lin

et al. 2018

Materials

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Subsurface damage (SSD) in the polishing process of silicon carbide (SiC) ceramic presents one of the most significant challenges for practical applications. In this study, the theoretical models of SSD depth are established on the basis of the material removal mechanism and indentation fracture mechanics in the SiC ceramic polishing process. In addition, the three-dimensional (3D) models of single grit polishing are also developed by using the finite element simulation; thereby, the dynamic effects of different process parameters on SSD depth are analyzed. The results demonstrate that the material removal was mainly in brittle mode when the cutting depth was larger than the critical depth of the brittle material. The SSD depth increased as the polishing depth and abrasive grain size increased, and decreased with respect to the increase in polishing speed. The experimental results suggested a good agreement with the theoretical simulation results in terms of SSD depth as a function of polishing depth, spindle speed, and abrasive grain size. This study provides a mechanistic insight into the dependence of SSD on key operational parameters in the polishing process of SiC ceramic.

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“…In HSG process, the grinding wheel linear speed could reach up to higher than 120 m/s (Pang et al, 2018), compared with conventional turning or milling of about 10 m/s or less. Under this circumstance, the machining strain rate could be higher than 10 -5 /s (Wang et al, 2016), which will definitely cause a change of materials properties. Wang et al (2016) simulated the high speed grinding induced damages and cracks in BK7 glass grinding, which concluded that the effect of grinding depth is weaker than wheel speed and a smaller abrasive grain is advantageous to subsurface quality.…”

mentioning

confidence: 99%

“…Under this circumstance, the machining strain rate could be higher than 10 -5 /s (Wang et al, 2016), which will definitely cause a change of materials properties. Wang et al (2016) simulated the high speed grinding induced damages and cracks in BK7 glass grinding, which concluded that the effect of grinding depth is weaker than wheel speed and a smaller abrasive grain is advantageous to subsurface quality. That was based on traditional finite element simulation method and the change of material properties have not been discussed in detail.…”

mentioning

confidence: 99%

High speed toughening-based ceramics grinding mechanism for quality and efficiency

Guo

et al. 2019

JAMDSM

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Subsurface damage in high-speed grinding of brittle materials considering kinematic characteristics of the grinding process

Cited by 46 publications

References 48 publications

Studies on the grinding force, size effect, surface texture, and mechanism of material removal in the grinding of AA6061-TiB₂/ZrB₂ in situ composite

Studies on the grinding force, size effect, surface texture, and mechanism of material removal in the grinding of AA6061-TiB₂/ZrB₂ in situ composite

Subsurface Damage in Polishing Process of Silicon Carbide Ceramic

High speed toughening-based ceramics grinding mechanism for quality and efficiency

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Subsurface damage in high-speed grinding of brittle materials considering kinematic characteristics of the grinding process

Cited by 46 publications

References 48 publications

Studies on the grinding force, size effect, surface texture, and mechanism of material removal in the grinding of AA6061-TiB2/ZrB2 in situ composite

Studies on the grinding force, size effect, surface texture, and mechanism of material removal in the grinding of AA6061-TiB2/ZrB2 in situ composite

Subsurface Damage in Polishing Process of Silicon Carbide Ceramic

High speed toughening-based ceramics grinding mechanism for quality and efficiency

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Studies on the grinding force, size effect, surface texture, and mechanism of material removal in the grinding of AA6061-TiB₂/ZrB₂ in situ composite

Studies on the grinding force, size effect, surface texture, and mechanism of material removal in the grinding of AA6061-TiB₂/ZrB₂ in situ composite