Improvement of Cutting Forces Modeling Based on Oriented Cutting Tests

Campocasso, Sébastien; Costes, Jean-Philippe; Fromentin, Guillaume; Bissey-Breton, Stéphanie; Poulachon, Gérard

doi:10.1016/j.procir.2013.06.090

Cited by 8 publications

(12 citation statements)

References 12 publications

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“…The clearance angle and the edge radius r β are rarely considered, but they could be introduced. Recent work suggests that the cutting edge angle κ r and the radius of curvature of the workpiece R W o should also be taken into account [41]. In order to calculate the uncut chip thickness, it is helpful to have a definition of the cutting edge in a coordinate system linked to the workpiece.…”

Section: General Principle Of Geometrical Modellingmentioning

confidence: 99%

A generalised geometrical model of turning operations for cutting force modelling using edge discretisation

Campocasso

Costes

Fromentin

et al. 2015

Applied Mathematical Modelling

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is an open access repository that collects the work of Arts et Métiers ParisTech researchers and makes it freely available over the web where possible. AbstractThe knowledge of cutting forces is of prime importance to ensure the success of cutting operations, the desired properties of the machined parts and therefore the functionality of the workpieces. Edge discretisation is one way to model cutting forces. Traditionally used in milling, this methodology enables local changes in uncut chip thickness or cutting geometry to be taken into account and then gives suitable results in the three directions. A key point of this method is the geometrical transformation that enables the description of various tool geometries. This study proposes a geometrical model based on homogeneous matrices, whose main interest is to decompose the transformations step-by-step. The method, generalisable to all machining operations, is detailed for turning operations. Inserted cutters are modelled considering both the positioning of the insert and the local geometry of the insert. The cutting geometry and the edge are described using the same model in the machine coordinates system, allowing forces and moments to be calculated easily.Keywords: Cutting force modelling, Edge discretisation, Tool geometry, Homogeneous matrix transformations, Turning operations Nomenclature α ne Working normal clearance angle; defined in P n [1] α P n Normal clearance angle given by the local preparation (P) of the insert; defined in P n α oe Working orthogonal clearance angle; defined inWorking normal rake angle; defined in P n [1] γ P n Normal rake angle given by the local preparation (P) of the insert; defined in P n ε E Tool included angle of the cutting edge (E); also denoted ε r if the cutting edge is included in P r [1] η Chip flow angle θ Polar angle defined in a coordinate system linked to the insert (parameterisation of the cutting edge) Θ Polar angle defined in a coordinate system linked to the machine (Θ = θ + κ r + ε r /2 − π/2) κ r Tool minor cutting edge angle; defined in

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Section: General Principle Of Geometrical Modellingmentioning

confidence: 99%

A generalised geometrical model of turning operations for cutting force modelling using edge discretisation

Campocasso

Costes

Fromentin

et al. 2015

Applied Mathematical Modelling

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“…representative of a finishing operation in the tool nose), several geometrical parameters are not constant along the cutting edge engaged. It is the case of the uncut chip thickness [12], the cutting edge lead angle [15] but also the clearance face contact radius, as explained and presented in Fig. 2.…”

Section: Clearance Face Contact Radius In Cylindrical and Face Turningmentioning

confidence: 99%

“…However these formulations, relating the ploughing force to polynomial functions of the uncut chip thickness or the cutting speed, can be discussed. Indeed studies concerning the determination of ploughing force are often developed on planning tests, and so doesn't take into account the potential influence of the part diameter, as suggested by Germain or Campocasso et al [14,15]. Therefore the purpose of this study is to enhance the modelling of the ploughing force by analysing the contact radius effect on cutting forces.…”

Section: Introductionmentioning

confidence: 99%

Analysis and Modelling of the Contact Radius Effect on the Cutting Forces in Cylindrical and Face Turning of Ti6Al4V Titanium Alloy

Dorlin

Fromentin²,

Costes³

2015

Procedia CIRP

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Cutting forces are representative data to characterize machining operations.They have to be known to perform the part manufacturing. Therefore, cutting forces predictive models are useful and it is possible to optimize them by taking into account new parameters. Hence, this study deals with the geometrical modelling of tool-workpiece interaction and its influence on the cutting forces. The analysis focuses on convex contact radius between the machined part and the tool. Experiments are based on cylindrical and face turning of Ti6Al4V titanium alloy. The results highlight a significant influence of contact conditions on ploughing mechanisms, and consequently on the cutting forces intensity. This phenomenon is taken into account inthe suggested models, providing a better accuracy of cutting forces modelled.International audienceCutting forces are representative data to characterize machining operations.They have to be known to perform the part manufacturing. Therefore, cutting forces predictive models are useful and it is possible to optimize them by taking into account new parameters. Hence, this study deals with the geometrical modelling of tool-workpiece interaction and its influence on the cutting forces. The analysis focuses on convex contact radius between the machined part and the tool. Experiments are based on cylindrical and face turning of Ti6Al4V titanium alloy. The results highlight a significant influence of contact conditions on ploughing mechanisms, and consequently on the cutting forces intensity. This phenomenon is taken into account inthe suggested models, providing a better accuracy of cutting forces modelled

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“…The shape of the curves, non-monotonic, suggests that two contradictory phenomena are involved. However, at this step of the analysis, these conclusions must be nuanced, because the highest levels of forces for 6 r  mm and the rectilinear edge, can be respectively due to the highest edge radius and the effective workpiece radius -which is equal to infinity when orthogonal cutting on tube, as explained in [12] -.…”

Section: Local Influence Of the Corner Radiusmentioning

confidence: 99%

“…The principle of the corner tests has been already used with a rectilinear cutting edge and an axial feed rate, in order to study the effect of the cutting edge angle r  on the local forces [12]. For both configurations, the uncut chip thickness h along the active cutting edge can be expressed, on the main part of the edge, using Equation (2); where  is the current polar angle defined from the bisectrix.…”

Section: Principlementioning

confidence: 99%

An innovative experimental study of corner radius effect on cutting forces

Campocasso¹,

Poulachon²,

Costes³

et al. 2014

CIRP Annals

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The cutting forces are often modelled using edge discretisation methodology. In finish turning, due to the smaller corner radii, the use of a local cutting force model identified from orthogonal cutting tests poses a significant challenge. In this paper, the local effect of the corner radius  r on the forces is investigated using a new experimental configuration: corner cutting tests involving the tool nose. The results are compared with inverse identifications based on cylindrical turning tests and elementary cutting tests on tubes. The results obtained from these methods consistently show the significant influence of the corner radius  r on the cutting forces.

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Improvement of Cutting Forces Modeling Based on Oriented Cutting Tests

Cited by 8 publications

References 12 publications

A generalised geometrical model of turning operations for cutting force modelling using edge discretisation

A generalised geometrical model of turning operations for cutting force modelling using edge discretisation

Analysis and Modelling of the Contact Radius Effect on the Cutting Forces in Cylindrical and Face Turning of Ti6Al4V Titanium Alloy

An innovative experimental study of corner radius effect on cutting forces

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