Depth of cut per abrasive in fixed diamond wire sawing

Chung, Chunhui; Le, Van Nhat

doi:10.1007/s00170-015-7089-z

Cited by 51 publications

(7 citation statements)

References 24 publications

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“…Considering a fixed range of diamond grain protrusion and that all diamond grains are in contact with the surface of the mono-Si specimen, an increase in v c would increase the engagement frequency of the diamond grains on the mono-Si specimen along the sawing line, leading to a decrease in h cu . As a result, more kinematic cutting edges will engage and contribute to the removal of ductile material, as reported by Liu et al (2017b) and Chung and Le (2015). This change from brittle to ductile mode in the material removal mechanism, resulting in surfaces with more regions that are free of fractures associated with the fragile mode.…”

Section: Surface Morphologymentioning

confidence: 78%

Effect of cutting parameters on surface integrity of monocrystalline silicon sawn with an endless diamond wire saw

et al. 2020

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The cutting of silicon wafers using multi-diamond wire sawing is a critical stage in solar cell manufacturing due to brittleness of silicon. Improving the cutting process output requires an in-depth understanding of phenomena associated with cutting parameters. In order to investigate the influence of diamond wire sawing on surface integrity of monocrystalline silicon, a looped diamond wire was used and cutting parameters wire cutting speed, feed rate and wire tension were varied. The surface morphology was observed by scanning electron microscopy. Surface roughness S a was measured with a non-contact profilometer. The brittle-ductile transition was identified by presence of residual phases on sawn surface. A bevel-polishing method was employed to determine the microcrack depth. The results show that with higher feed rate the surface presents deeper and wider craters because of deeper penetration of diamond grain. On increasing wire cutting speed, there were more regions formed in ductile mode. The higher S a values was observed on increasing both feed rate and wire tension, while S a decreased with an increase in wire cutting speed. The brittle mode was predominant with an increase in feed rate, resulting in Si-I phase in regions formed in fragile mode. Material removal in ductile mode led to appearance of a-Si phase at high wire cutting speed. No significant effect was observed on increasing wire tension. Subsurface microcracks mainly initiating from bottom of grooves generated by cutting mechanism. The most appropriate set of cutting parameters is the lowest feed rate and wire tension and highest wire cutting speed.

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Section: Surface Morphologymentioning

confidence: 78%

Effect of cutting parameters on surface integrity of monocrystalline silicon sawn with an endless diamond wire saw

et al. 2020

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“…On the other hand, on increasing v c , the h cu value is reduced considerably and this leads to a predominance of ductile material removal. However, as reported by Chung and Le [10], there is still a number of grits with high h cu , which leads to cutting in the brittle mode, resulting in a sawn surface with mixed brittle and ductile cutting modes.…”

Section: Morphology Of the Sawn Surfacementioning

confidence: 92%

“…Considering the ndings of Li et al [15] and Liu et al [36], around of 10% of the kinematics edges take the ductile mode cutting, affecting the sawn surface, and they are restricted to the position angle on the wire cross-section of θ ≤ 25º. Chung and Le [10] complement that the diamond grits on upper side of the wire cross-section (50º ≤ θ ≤ 90º) assume mainly the brittle cutting mode. Theoretically, it is possible that the collected silicon chips have been formed in the following regions of the wire cross-section: at upper region of the wire, in which the diamond grits assume predominantly the brittle cutting, there is the formation of fragmented chips (Fig.…”

Section: Chip Formation and Morphologymentioning

confidence: 99%

“…Considering a random distribution of the characteristic abrasives, their position over the wire and brittle and ductile modes during the cutting, the model was able to predict the surface roughness value obtained on varying the cutting parameters. Chung and Le [10] studied the depth of cut per diamond grit in the diamond wire sawing process, based on polar coordinates to identify the grit position for the generation of a wire pro le. Different depths of cut were observed due to the random diamond distribution, which led to both brittle and ductile cutting modes.…”

Section: Introductionmentioning

confidence: 99%

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Study on surface integrity and ductile cutting of PV polycrystalline silicon and wear mechanisms of electroplated diamond wire

Costa

Santos

Carvalho

et al. 2022

Int J Adv Manuf Technol

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This study aimed to evaluate and better understand the mechanical and crystalline responses of polycrystalline silicon sawn by diamond wire sawing. To simplify the multi-wire sawing kinematic, an endless wire saw with a single looped diamond wire was used. The wire cutting speed and feed rate of the sawing process were varied in order to evaluate the characteristics of sawn surface morphology, surface roughness and subsurface damage. The analysis of brittle-ductile transition and residual stress of the sawn surface and silicon chips were performed with Raman spectroscopy. The wear and failure mechanism of the diamond wire were analyzed. The results show that sawn surface is composed of brittle and ductile regions and the predominance of one of these directly affected the surface roughness R a . The ductile cutting mode induced the predominance of microgrooves and ploughing over the sawn surface and led to formation of an amorphous layer with residual compressive stress of up to -192.3 MPa. Micro-cracks in subsurface were identi ed and it reached a minimum depth of 7.2±1.6 µm.Chip fragments and elongated chips were observed and Raman spectra showed that the latter are amorphous. The wire wear analysis indicated that during the cutting there is deformation of the Ni-layer, exposed grits and grit pullout. The main wear mechanisms are Ni-matrix removal and abrasive wear of the diamond grit. A better surface quality of polycrystalline silicon was obtained on increasing wire cutting speed and decreasing feed rate. The results found in this study can help to reach a high quality surface of silicon wafer for photovoltaic application. HighlightsAnisotropy of poly-Si induces to sawn surface composed of brittle and ductile regions and it affected the surface roughness Ductile cutting leads to surface formation with amorphous phases and residual compressive stress On increasing wire cutting speed and decreasing feed rate was obtained a minimum micro-crack depth Chip fragments and elongated chips were observed and Raman spectra showed that the latter are amorphous Wear mechanisms of the diamond wire were Ni-matrix deformation and removal, abrasive wear and grits pullout

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“…The density of diamond abrasive grains on the wire is determined by counting the number of abrasives on sections of wire. The ratio of active abrasives on the wire is taken to be 0.3 [21]. In the experiments conducted in this paper, Vx = 0.75 mm/min, the total wire length is 65 m and Qp = 0.2 MPa.…”

Section: Experiments Systemmentioning

confidence: 99%

Dynamic Force Modeling of Wire Saw Machining Processes

Lie¹,

Wang³

et al. 2023

Preprint

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Wire saw machining is extensively used to cut hard and brittle materials because of the resulting narrow kerf size, low cutting forces, and minimal material waste. The change of cutting forces strongly affects the part surface quality. Current models compute static machining forces based on the process variables and cutting conditions. This paper builds a dynamic machining force model that includes the effect of the wire tension and describes how the force changes as the wire engages with the part and as the wire changes direction due to reciprocation. Machining of silicon monocrystal parts is used to experimentally validate the proposed dynamic force model. The results show a very good correlation between the simulated and experimental data. The model captures the transient effect of the machining forces as the wire becomes fully engaged with the part and it is able to capture the fluctuations in the normal force, which is due to the changes in wire tension, as the wire reciprocates.

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Depth of cut per abrasive in fixed diamond wire sawing

Cited by 51 publications

References 24 publications

Effect of cutting parameters on surface integrity of monocrystalline silicon sawn with an endless diamond wire saw

Effect of cutting parameters on surface integrity of monocrystalline silicon sawn with an endless diamond wire saw

Study on surface integrity and ductile cutting of PV polycrystalline silicon and wear mechanisms of electroplated diamond wire

Dynamic Force Modeling of Wire Saw Machining Processes

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