Effect of tool angle on cutting force and residual stress in the oblique cutting of TC21 alloy

Abstract The residual stresses could affect the ability of components to bear loading conditions and also the performance. The researchers considered workpiece surface as a plane and ignored the effect of surface topography induced by the intermittent cutting process when modeling residual stresses. The aim of this research develops an analytical model to predict workpiece residual stresses during intermittent machining by correlating the effect of surface topography. The relative motions of tool and workpiece are analyzed for modeling thermal-mechanical and surface topography. The influence of dynamic cutting force and thermal on different positions of surface topography is also considered in analytical model. Then the residual stresses model with the surface topography effect can be developed in intermittent cutting. The analytical models of dynamic cutting force, surface topography and residual stresses are verified by the experiments. The variation trend of evaluated values of the residual stress of workpiece is basically consistent with that of measured values. The compressive residual stress of workpiece surface in highest point of the surface topography are higher than that in the lowest point.

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Three-dimensional cutting force analysis based on the lower boundary of the shear zone. Part 2: Two edge oblique cutting

International Journal of Machine Tools and Manufacture ◽

10.1016/0890-6955(95)00070-4 ◽

1996 ◽

Vol 36 (3) ◽

pp. 325-338 ◽

Cited By ~ 3

Author(s):

Patri K. Venuvinod

Keyword(s):

Cutting Force ◽

Shear Zone ◽

Three Dimensional ◽

Lower Boundary ◽

Force Analysis ◽

Oblique Cutting

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Analytical, FEA, And Experimental Research of 2D-Vibration Assisted Cutting ( 2D-VAC) In Titanium Alloy Ti6Al4V

10.21203/rs.3.rs-474065/v1 ◽

2021 ◽

Author(s):

Rendi Kurniawan ◽

Farooq Ahmed ◽

Gun Chul Park ◽

Tae Jo Ko

Keyword(s):

Residual Stress ◽

Plastic Strain ◽

Cutting Force ◽

Frequency Modulation ◽

High Frequency ◽

Cutting Temperature ◽

Cutting Speed ◽

Von Mises Stress ◽

Micro Hardness ◽

Micro Structure

Abstract In the 2D-Vibration Assisted Cutting (2D-VAC) method, the cutting tool shakes in a 2-dimensional approach because of superimposed high-frequency modulation. This high-frequency modulation effect creates a displacement at a tiny scale of micrometers and causes an escalation in the resultant cutting speed. Consequently, 2D-VAC has superior advantages compared to traditional cutting (TC). This manuscript describes research on 2D-VAC that focuses on modeling cutting forces (mathematical model) and finite element analysis (FEA) results. The FEA results are focused on the von Mises stress, plastic strain, cutting force, cutting temperature, and residual stress. In addition, an experiment for the chip formation, micro-structure layer, and micro-hardness was also analyzed in this study. According to the modeling results, the cutting force has a comparable pattern to the FEA results. The stress contour result confirms that the 2D-VAC method has lower stress than that in the TC method during tool retraction mode. Additionally, the plastic strain in the 2D-VAC method can be higher than that in the TC method. According to the temperature results, the peak temperature in the 2D-VAC could be higher than that in the TC method. The residual stress shows that there is a compressive effect. Thus, the compressive stress is higher than that in the TC method. Micro-hardness results confirmed that there is not too much change from the original surface in the 2D-VAC method. The result of micro-structure morphology also confirmed that there is a significant shear deformation flow in case of the TC method, although less occurs in the 2D-VAC method.

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Sensitivity Analysis of Johnson-Cook Material Constants and Friction Coefficient Influence on Finite Element Simulation of Turning Inconel 718

Materials ◽

10.3390/ma12193121 ◽

2019 ◽

Vol 12 (19) ◽

pp. 3121 ◽

Cited By ~ 2

Author(s):

Xiaoli Qiu ◽

Xianqiang Cheng ◽

Penghao Dong ◽

Huachen Peng ◽

Yan Xing ◽

...

Keyword(s):

Residual Stress ◽

Sensitivity Analysis ◽

Finite Element ◽

Friction Coefficient ◽

Constitutive Model ◽

Cutting Force ◽

Inconel 718 ◽

Coulomb Friction ◽

Cutting Conditions ◽

Simulation Results

The Johnson-Cook (J-C) constitutive model, including five material constants (A, B, n, C, m), and the Coulomb friction coefficient (μ) are critical preprocessed data in machining simulations. Before they become reliable preprocessed data, investigating these parameters’ effect on simulation results benefits parameter-selecting. This paper aims to investigate the different influence of five settings of the J-C constitutive equation and Coulomb friction coefficient on the turning simulation results of Inconel 718 under low-high cutting conditions, including residual stress, chip morphology, cutting force and temperature. A three-dimensional (3-D) finite element model was built, meanwhile, the reliability of the model was verified by comparing the experiment with the simulation. Sensitivity analysis of J-C parameters and friction coefficient on simulation results at low-high cutting conditions was carried out by the hybrid orthogonal test. The results demonstrate that the simulation accuracy of Inconel 718 is more susceptible to strain hardening and thermal softening in the J-C constitutive model. The friction coefficient only has significant effects on axial and radial forces in the high cutting condition. The influences of the coefficient A, n, and m on the residual stress, chip thickness, cutting force and temperature are especially significant. As the cutting parameters increase, the effect of the three coefficients will change visibly. This paper provides direction for controlling simulation results through the adjustment of the J-C constitutive model of Inconel 718 and the friction coefficient.

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Model-based sensitivity analysis of machining-induced residual stress under minimum quantity lubrication

Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture ◽

10.1177/0954405415601802 ◽

2015 ◽

Vol 231 (9) ◽

pp. 1528-1541 ◽

Cited By ~ 3

Author(s):

Xia Ji ◽

Steven Y Liang

Keyword(s):

Residual Stress ◽

Sensitivity Analysis ◽

Cutting Force ◽

Cutting Temperature ◽

Minimum Quantity Lubrication ◽

Cutting Parameters ◽

Tool Geometry ◽

Depth Of Cut ◽

Mixture Ratio ◽

Minimum Quantity

This article presents a sensitivity analysis of residual stress based on the verified residual stress prediction model. The machining-induced residual stress is developed as a function of cutting parameters, tool geometry, material properties, and lubrication conditions. Based on the residual stress predictive model, the main effects of the cutting force, cutting temperature, and residual stress are quantitatively analyzed through the cosine amplitude method. The parametric study is carried out to investigate the effects of minimum quantity lubrication parameters, cutting parameters, and tool geometry on the cutting performances. Results manifest that the cutting force and residual stress are more sensitive to the heat transfer coefficient and the depth of cut, while the cutting temperature is more sensitive to the cutting speed. Large maximum compressive residual stress is obtained under a lower flow rate of minimum quantity lubrication, small depth of cut, and the proper air–oil mixture ratio. This research can support the controlling and optimization of residual stress in industrial engineering by strategically adjusting the application parameters of minimum quantity lubrication.

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Predictive Modeling of Minimum Quantity Lubrication: Cutting Force, Temperature and Residual Stress

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.365-366.1181 ◽

2013 ◽

Vol 365-366 ◽

pp. 1181-1184 ◽

Cited By ~ 2

Author(s):

Xia Ji ◽

Xue Ping Zhang ◽

Bei Zhi Li ◽

Steven Y. Liang

Keyword(s):

Residual Stress ◽

Cutting Force ◽

Predictive Modeling ◽

Analytical Approach ◽

Orthogonal Cutting ◽

Minimum Quantity Lubrication ◽

Minimum Quantity ◽

Machining Force ◽

Tc4 Alloy ◽

Cooling Effects

This paper presents an analytical approach to predict the machining force, temperature and residual stress under minimum quantity lubrication (MQL) condition. Both the lubrication and cooling effects are considered to change the tribological and thermal properties in the modified Oxleys model, which is capable to predict the cutting force and temperature in MQL machining directly from cutting conditions. The machining-induced residual stress is predicted by modified McDowell hybrid algorithm. The predicted cutting forces and residual stresses are verified by orthogonal cutting tests for C45 steel and TC4 alloy steel.

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Modeling and Experiment of the Cutting Force for Aluminium Alloy Work-Piece

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.268-270.422 ◽

2012 ◽

Vol 268-270 ◽

pp. 422-425

Author(s):

Mu Lan Wang ◽

Jun Ming Hou ◽

Bao Sheng Wang ◽

Wen Zheng Ding

Keyword(s):

Finite Element ◽

Aluminium Alloy ◽

Cutting Force ◽

Orthogonal Cutting ◽

Experimental Period ◽

Production Costs ◽

Work Piece ◽

Force Model ◽

Oblique Cutting ◽

Cutting Model

The application of Finite Element Method (FEM) in cutting force model for Aluminium alloy work-piece is useful to reduce the production costs and shorten the experimental period. Firstly, the theoretical model of the orthogonal cutting and the oblique cutting are analyzed in this paper. And then, the corresponding finite element models are theoretically constructed. By comparing the results, the following conclusions are drawn: with the increase of the cutting thickness, the cutting force increasing is in an enhancement tendency. The oblique cutting model of overall tool is more conductive to the subsequent runout and the flutter analysis.

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Analysis of Cutting Forces in Precision Turning Based on Oblique Cutting Model

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.97-101.1961 ◽

2010 ◽

Vol 97-101 ◽

pp. 1961-1964 ◽

Cited By ~ 1

Author(s):

Wei Guo Wu ◽

Gui Cheng Wang ◽

Chun Gen Shen

Keyword(s):

Cutting Force ◽

Cutting Forces ◽

Orthogonal Cutting ◽

Differential Method ◽

Force Model ◽

Cutting Force Model ◽

Linear Change ◽

Oblique Cutting ◽

Precision Turning ◽

Cutting Model

In this work, the prediction and analysis of cutting forces in precision turning operations is presented. The model of cutting forces is based on the oblique cutting force model which was rebuilt by two coordinate conversions from the orthogonal cutting model. Then the cutting field in precision turning was divided into two fields which are characterized as curve change and linear change on cutter edge and they were modeled respectively. Cutting field of cutter nose was modeled by differential method and its cutting force distribution is predicted by the proposed method. The predicted results for the cutting forces are in agreement with the experimental results under a variety of operation variables, including changes in the depths of cut and in the feedrate.

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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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