Rosenhain and Sturney revisited: The ‘tear’ chip in cutting interpreted in terms of modern ductile fracture mechanics

Atkins, A.G.

doi:10.1243/0954406042369044

Cited by 13 publications

(4 citation statements)

References 17 publications

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“…In 1925 it published two reports of the Cutting Tools Research Committee [16,17], which were of great significance to the field. Atkins [18] reviewed the work in detail in 2004 in JMES.…”

Section: Discussionmentioning

confidence: 99%

Measuring fracture toughness from machining tests

Patel

Blackman

Williams

2009

Proceedings of the Institution of Mechanical Engineers, Part C:

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An analysis of the forces involved in orthogonal cutting or machining is presented in which yielding on a shear plane is assumed. The fracture toughness Gc is included and it is observed that Gc may be determined by measuring the cutting and transverse forces together with the chip thickness for a range of cutting depths. This latter measurement enabled the shear plane angle ϕ to be determined experimentally. A simplified version of the analysis is also given in which ϕ is predicted by a cutting force minimization scheme. Neither scheme requires any details of the friction condition to be known since the transverse force is sufficient information for any type to be included in the analysis. A friction model including a coefficient of friction and an adhesion toughness is also utilized. Data for both polymer and metal cutting are taken from the literature and Gc is determined. In some datasets the tool rake angle α is also varied and the values of Gc and the yield stress σY are found to be independent of α. The force minimization method gives a good estimate of ϕ for most polymers. For metals (aluminium alloy, steel, and brass) the method worked well. For aluminium alloy Gc was independent of α and the predicted and measured ϕ values agreed. For steel and brass this was not so. Gc was mostly independent of α except at low values where high values of Gc were observed. A constant value of the coefficient of friction was observed for each α value but values for both the coefficient of friction and the adhesion toughness varied significantly with increasing rake angle.

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“…In 1925 it published two reports of the Cutting Tools Research Committee [16,17], which were of great significance to the field. Atkins [18] reviewed the work in detail in 2004 in JMES.…”

Section: Discussionmentioning

confidence: 99%

Measuring fracture toughness from machining tests

Patel

Blackman

Williams

2009

Proceedings of the Institution of Mechanical Engineers, Part C:

View full text Add to dashboard Cite

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“…Several recent papers advocate modeling of orthogonal cutting as a ductile fracture mechanics problem for a crack propagating in the direction of the tool tip [1,2,3,4,5,6,7]. Some analytical modeling [1,6] and experiments [4,5,8] show the fracture mechanics view can help interpret experiments and explain some problems of classic cutting models based solely on plasticity and friction [1,2].…”

Section: Introductionmentioning

confidence: 99%

“…Some analytical modeling [1,6] and experiments [4,5,8] show the fracture mechanics view can help interpret experiments and explain some problems of classic cutting models based solely on plasticity and friction [1,2]. A suggestion of this new approach is that cutting experiments can be used to measure the toughness of ductile materials.…”

Section: Introductionmentioning

confidence: 99%

Numerical simulation of orthogonal cutting using the material point method

Nairn

2015

Engineering Fracture Mechanics

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“…However, in less ductile materials cracks are visible ahead of the tool. 25 Nakasuji et al 26 proposed the cleavage fracture phenomena as the dominant mechanism affecting the machining mode. The obtained results indicate that if the uncut chip thickness is sufficiently small, the critical stress field is small to suppress fracture.…”

Section: Introductionmentioning

confidence: 99%

Numerical-experimental study on the mechanisms of material removal during magnetic abrasive finishing of brittle materials using extended finite element method

Pashmforoush

Rahimi

2015

Proceedings of the Institution of Mechanical Engineers, Part C:

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Magnetic abrasive finishing (MAF) is an advanced machining process efficiently used for finishing of hard-to-machine materials. In this method, material removal takes place through nano-/microindentations in the presence of a controllable magnetic field generated via a permanent or an electronic magnet. Understanding the material removal mechanisms of the process is of particular importance for achievement of a high-quality surface with minimum surface defects. Therefore, in this work a numerical-experimental study was performed toward this issue using the extended finite element method (X-FEM). In this regard, the MAF operation was simulated as an indentation and sliding process of a sharp abrasive and the prevailing material removal mechanisms were obtained during MAF of BK7 optical glass. The constitutive material model for the specimen was defined according to the elastic-plastic-cracking model, which takes into account the tensile cracking and compressive yielding behavior of brittle materials. The X-FEM analysis revealed that both microcutting and microfracture mechanisms exist during MAF process of brittle materials depending on the process parameters. Among various parameters, magnetic particles size and abrasives size were the most influential factors affecting the dominant mechanism of material removal. The obtained numerical results were then validated experimentally by using scanning electron microscopy (SEM). The SEM observations revealed good performance of X-FEM analysis in prediction of material removal mechanisms during MAF of brittle materials.

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Rosenhain and Sturney revisited: The ‘tear’ chip in cutting interpreted in terms of modern ductile fracture mechanics

Cited by 13 publications

References 17 publications

Measuring fracture toughness from machining tests

Measuring fracture toughness from machining tests

Numerical simulation of orthogonal cutting using the material point method

Numerical-experimental study on the mechanisms of material removal during magnetic abrasive finishing of brittle materials using extended finite element method

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