Modelling of the Deburring Process

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.5-6.367 ◽

2006 ◽

Vol 5-6 ◽

pp. 367-374

Author(s):

C. G. Dumitraş

Keyword(s):

Central Composite Design ◽

Cutting Force ◽

Cutting Forces ◽

Cutting Process ◽

Central Composite ◽

The Way

Due to robotic deburring development, the research gains a new orientation and focused on the cutting forces and the chip control. The present paper will emphasize the main difference which occurs between the normal cutting process and the deburring process, the way it develops and the parameters which characterize this process. Also the dynamics of the process are considered. Based on a central composite design one determine a relation between the geometry of the tool, workpiece hardness and cutting force.

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Finite Element Analysis of Cutting Forces in High Speed Machining

Materials Science Forum ◽

10.4028/www.scientific.net/msf.532-533.753 ◽

2006 ◽

Vol 532-533 ◽

pp. 753-756 ◽

Cited By ~ 3

Author(s):

Jun Zhao ◽

Xing Ai ◽

Zuo Li Li

Keyword(s):

Finite Element ◽

Cutting Force ◽

Cutting Forces ◽

High Speed ◽

Fem Simulation ◽

Chip Thickness ◽

Cutting Conditions ◽

Cutting Process ◽

Undeformed Chip Thickness ◽

High Speed Cutting

The Finite Element Method (FEM) has proven to be an effective technique to investigate cutting process so as to improve cutting tool design and select optimum cutting conditions. The present work focuses on the FEM simulation of cutting forces in high speed cutting by using an orthogonal cutting model with variant undeformed chip thickness under plane-strain condition to mimic intermittent cutting process such as milling. High speed cutting of 45%C steel using uncoated carbide tools are simulated as the application of the proposed model. The updated Lagrangian formulation is adopted in the dynamic FEM simulation in which the normalized Cockroft and Latham damage criterion is used as the ductile fracture criterion. The simulation results of cutting force components under different cutting conditions show that both the thrust cutting force and the tangential cutting force increase with the increase in undeformed chip thickness or feed rate, whereas decrease with the increase in cutting speed. Some important aspects of modeling the high speed cutting are discussed as well to expect the future work in FEM simulation.

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Analysis of Oblique Cutting Forces

Journal of Engineering for Industry ◽

10.1115/1.3610051 ◽

1967 ◽

Vol 89 (2) ◽

pp. 347-355 ◽

Cited By ~ 4

Author(s):

Russell F. Henke

Keyword(s):

Steady State ◽

Cutting Force ◽

Cutting Forces ◽

Metal Cutting ◽

Single Point ◽

Orthogonal Cutting ◽

Cutting Process ◽

Chip Area ◽

Oblique Cutting ◽

The Stability

This paper is the latest of a continuing series on the subject of self-excited machine tool chatter. The representation of the metal cutting process as required by the previously developed closed-loop chatter theory is extended to oblique cutting with tools of practical shape and geometry. The cutting process parameters essential to proper application of the stability theory are found by an analytical formulation leading to a classical eigenvalue problem. Techniques are developed to determine the steady-state constant of proportionality between resultant cutting force and uncut chip area, the direction of resultant cutting force, and the direction of maximum cutting stiffness for any single-point cutting operation. In the process, a general method to predict steady-state oblique cutting forces is evolved. The method depends on certain experimentally justifiable assumptions and utilizes previously compiled orthogonal cutting data.

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Cutting Forces Prediction in the Dry Slotting of Aluminium Stacks

Materials Science Forum ◽

10.4028/www.scientific.net/msf.797.47 ◽

2014 ◽

Vol 797 ◽

pp. 47-52

Author(s):

Jorge Salguero ◽

Madalina Calamaz ◽

Moisés Batista ◽

Franck Girot ◽

Mariano Marcos Bárcena

Keyword(s):

Cutting Force ◽

Cutting Forces ◽

Metal Cutting ◽

Cutting Speed ◽

Parametric Models ◽

Cutting Process ◽

Cutting Force Components ◽

Force Components ◽

Input Variables ◽

The Individual

Cutting forces are one of the inherent phenomena and a very significant indicator of the metal cutting process. The work presented in this paper is an investigation of the prediction of these parameters in slotting processes of UNS A92024-T3 (Al-Cu) stacks. So, cutting speed (V) and feed per tooth (fz) based parametric models, for experimental components of cutting force, F(fz,V) have been proposed. These models have been developed from the individual models extracted from the marginal adjustment of the cutting force components to each one of the input variables: F(fz) and F(V).

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The Study of Cutting Forces About Dynamic Stability of Milling Machine Tools

Volume 2: Automotive Systems; Bioengineering and Biomedical Technology; Computational Mechanics; Controls; Dynamical Systems ◽

10.1115/esda2008-59231 ◽

2008 ◽

Cited By ~ 1

Author(s):

Petru A. Pop

Keyword(s):

Machine Tool ◽

Cutting Force ◽

Dynamic Stability ◽

Cutting Forces ◽

Machine Tools ◽

Cutting Process ◽

Depth Of Cut ◽

Milling Machine ◽

Dynamic Tests ◽

Machining System

The paper has presented a study of cutting forces about dynamic stability of milling machine tools. For that has required the analysis of dynamic machining system (DMS), represented by the interaction between elastic structure of machine tool and cutting process. The cutting force occurred during cutting process is dependent by a certain factors as thickness cut, physics-mechanics properties of workpiece, geometry of shaped edge tool, etc. An important factor, which has direct influenced about DMS, is present of vibration, in special at chatter frequency due to real perturbation and damages of DMS. The magnitude of cutting force depends largely on the tool-work engagement and depth of cut. The dynamic installation has used for study of milling cutting process assured the acquisition of vibration and cutting force on each three axes of milling machine tool. The calculus and interpretation of dynamic tests had done by MATLAB R14.v7.01 Program. Dynamic tests have been more that 150 recordings, by variation of cutting depth for each spindle speeds of machine until occurring chatter. It had used for testing four milling cutters with different geometric parameters and differential pitch of cutter. These dynamic tests are emphasizing the direct influences of cutting forces about dynamic machining system. Thus, by reducing, the magnitude of cutting forces due to suppressing the vibrations and implicit enhanced the dynamic stability of milling machine and quality of machining workpiece.

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Non-Free Cutting and Its Degree of Freedom Confinement

Journal of Manufacturing Science and Engineering ◽

10.1115/1.2830568 ◽

1999 ◽

Vol 121 (1) ◽

pp. 150-153 ◽

Cited By ~ 2

Author(s):

H. Shi ◽

X. Wang ◽

Tao Lu

Keyword(s):

General Theory ◽

Cutting Force ◽

Cutting Forces ◽

Cutting Tool ◽

Minimum Energy ◽

Cutting Tools ◽

Synthesis Method ◽

Degree Of Freedom ◽

Cutting Process ◽

Good Agreement

Plunge-turning processes of round-edged cutters is analyzed and its cutting force modeled in the light of a general theory of non-free cutting developed by the authors. In this study the whole cutting tool is treated as a combination of a series of Elementary Cutting Tools (ECTs). Due to the non-linearity of chip-ejection interference among all the ECTs the total cutting force of the whole cutter, however, cannot be calculated by simply superposing the incremental cutting forces generated by all the ECTs. A Non-Linear Synthesis Method (NLSM) is therefore suggested for modeling this non-free cutting force. The main feature of the method is that the chip-ejection interference is under consideration and modeled on the basis of the Principle of Minimum Energy (PME). Good agreement between the predicted and measured main cutting forces is identified. Furthermore, a Coefficient of Non-Free Cutting (CNFC) is applied to quantitatively indicate the strength of chip-ejection interference among the ECTs and the degree of freedom confinement of the cutting process.

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CUTTING FORCES ANALYSIS IN WHIRLING PROCESS

International Journal of Modern Physics B ◽

10.1142/s0217979210065635 ◽

2010 ◽

Vol 24 (15n16) ◽

pp. 2786-2791 ◽

Cited By ~ 8

Author(s):

JAE HWAN SON ◽

CHANG WOO HAN ◽

SUN IL KIM ◽

HEE CHUL JUNG ◽

YOUNG MOON LEE

Keyword(s):

Cutting Force ◽

Chip Formation ◽

Cutting Forces ◽

Chip Thickness ◽

Cutting Edge ◽

Cutting Process ◽

Undeformed Chip Thickness ◽

Adams Software ◽

Rotating Workpiece ◽

Cutting Experiments

Whirling is a cutting process in which a series of cutting edges remove material by turning over the rotating workpiece. In this process, the whirling ring with a number of cutting teeth combined with the rotation and advancement of workpiece, produces pitches of worm. Mechanics of chip formation of the process, however, has not been fully estabilished. To estimate the cutting force during the process, the kinematics and the maximum undeformed chip thickness to be removed by each cutting edge should be thoroughly analyzed. In this study, using the recently developed model of undeformed chip thickness and the DEFORM software, cutting forces of the whirling process are estimated. The effects of cutting forces on tool are analyzed using the ADAMS software. The validity of the simulations has been verified with a series of cutting experiments.

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Mechanistic Cutting Process Calibration via Microstructure-Level Finite Element Simulation Model

Journal of Manufacturing Science and Engineering ◽

10.1115/1.1813480 ◽

2004 ◽

Vol 126 (4) ◽

pp. 706-709 ◽

Cited By ~ 14

Author(s):

Sunghyuk Park ◽

S. G. Kapoor ◽

R. E. DeVor

Keyword(s):

Finite Element ◽

Cutting Force ◽

Cutting Forces ◽

Model Calibration ◽

Gray Iron ◽

Carbon Steels ◽

Cutting Process ◽

Force Model ◽

Cutting Force Model ◽

Orthogonal Machining

A methodology for mechanistic cutting force model calibration via microstructure-level finite element cutting process simulation is presented and applied to ferrous materials, including ductile and gray irons and carbon steels. The methodology combines graphite, ferrite, and pearlite grains to produce ductile iron, gray iron, and carbon steel microstructures and obtains cutting forces via orthogonal machining simulations. The simulated forces are used to perform the cutting force model calibration. The cutting forces for the turning process are predicted based on the calibration thusly obtained and experimentally shown to be in good agreement with actual cutting force data.

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Comparison Analysis Between Simulation and Experiment of Cutting Force and Cutting Stress as Well as Chip Morphology During the Macro and Nano Cutting of Single Crystal Copper

10.21203/rs.3.rs-849526/v1 ◽

2021 ◽

Author(s):

Dongju Chen ◽

Shuiyuan Wu ◽

Yazhong He ◽

Shupei Li ◽

Yuchi Luo ◽

...

Keyword(s):

Single Crystal ◽

Cutting Force ◽

Cutting Forces ◽

Chip Morphology ◽

Cutting Process ◽

Dynamics Simulation ◽

Single Crystal Copper ◽

Simulation And Experiment ◽

Change Trend ◽

Cutting Model

Abstract In this paper, the simulation and experiment comparison of cutting force, cutting stress and chip morphology during the macro and nano cutting of single crystal copper are carried out. Firstly, a finite element method based on Johnson-Cook metal strength and failure model were used to establish a macro cutting model, and the cutting force, cutting stress, cutting displacement and chip morphology were obtained. Then a molecular dynamics simulation was used to establish a nano cutting model, and the cutting force, von mises stress and chip morphology were obtained. Afterwards, a comparative analysis of the two was carried out. Finally, the external turning experiment was used to verify the simulation results of the macro cutting model. The results show that: 1. The change trend of the cutting force in x and y directions are different,but the corresponding ratios of cutting forces in x and y directions in macro and nano cutting process are very close, and the corresponding ratios of the average macro and nano cutting forces in x and y directions are also very close. 2. The cutting stress in nano cutting process was about 100 times of macro cutting stress. 3. The chip length in macro cutting process is larger than the chip length in nano cutting process, and the shape is more regular. 4. The experimental cutting force change trend is very similar to the simulation cutting force change trend, but there exits difference in the value between the experiment cutting forces and simulated cutting forces.

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