Investigation of cutting force and temperature variation in orthogonal cutting of cortical bone

The formation of serrated chips is an important feature during machining of difficult-to-cut materials, such as titanium alloy, nickel based alloy, and some steels. In this study, Ti6Al4V alloys with equiaxial and acicular martensitic microstructures were adopted to analyze the effects of material structures on the formation of serrated chips in straight line micro orthogonal machining. The martensitic alloy was obtained using highly efficient electropulsing treatment (EPT) followed by water quenching. The results showed that serrated chips could be formed on both Ti6Al4V alloys, however the chip features varied with material microstructures. The number of chip segments per unit length of the alloy with martensite was more than that of the equiaxial alloy due to poor ductility. Besides, the average cutting and thrust forces were about 8.41 and 4.53 N, respectively, for the equiaxed Ti6Al4V alloys, which were consistently lower than those with a martensitic structure. The high cutting force of martensitic alloy is because of the large yield stress required to overcome plastic deformation, and this force is also significantly affected by the orientations of the martensite. Power spectral density (PSD) analyses indicated that the characteristic frequency of cutting force variation of the equiaxed alloy ranged from 100 to 200 Hz, while it ranged from 200 to 400 Hz for workpieces with martensites, which was supposedly due to the formation of serrated chips during the machining process.

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Influence of tool edge form factor and cutting parameters on milling performance

Advances in Mechanical Engineering ◽

10.1177/16878140211009041 ◽

2021 ◽

Vol 13 (4) ◽

pp. 168781402110090

Author(s):

Xuefeng Zhao ◽

Hao Qin ◽

Zhiguo Feng

Keyword(s):

Form Factor ◽

Simulation Model ◽

Cutting Force ◽

Surface Quality ◽

High Speed ◽

Orthogonal Cutting ◽

Cutting Temperature ◽

Tool Edge ◽

Drag Finishing ◽

Edge Preparation

Tool edge preparation can improve the tool life, as well as cutting performance and machined surface quality, meeting the requirements of high-speed and high-efficiency cutting. In general, prepared tool edges could be divided into symmetric or asymmetric edges. In the present study, the cemented carbide tools were initially edge prepared through drag finishing. The simulation model of the carbide cemented tool milling steel was established through Deform software. Effects of edge form factor, spindle speed, feed per tooth, axial, and radial cutting depth on the cutting force, the tool wear, the cutting temperature, and the surface quality were investigated through the orthogonal cutting simulation. The simulated cutting force results were compared to the results obtained from the orthogonal milling experiment through the dynamometer Kistler, which verified the simulation model correctness. The obtained results provided a basis for edge preparation effect along with high-speed and high effective cutting machining comprehension.

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Preparation and cutting performance of nano-scaled Al2O3-coated micro-textured cutting tool prepared by atomic layer deposition

High Temperature Materials and Processes ◽

10.1515/htmp-2021-0021 ◽

2021 ◽

Vol 40 (1) ◽

pp. 77-86

Author(s):

Siwen Tang ◽

Pengfei Liu ◽

Zhen Su ◽

Yu Lei ◽

Qian Liu ◽

...

Keyword(s):

Friction Coefficient ◽

Atomic Layer Deposition ◽

Cutting Force ◽

Cutting Tool ◽

Orthogonal Cutting ◽

Cutting Tools ◽

Atomic Layer ◽

Cutting Performance ◽

Cutting Test ◽

Layer Deposition

Abstract Al2O3 nano-scaled coating was prepared on micro-textured YT5 cemented carbide cutting tools by atomic layer deposition ALD. The effect of Al2O3 nano-scaled coating, with and without combined action of texture, on the cutting performance was studied by orthogonal cutting test. The results were compared with micro-textured cutting tool and YT5 cutting tool. They show that the micro-texture and nano-scaled Al2O3 coated on the micro-texture both can reduce the cutting force and friction coefficient of the tool, and the tools with nano-scaled Al2O3 coated on the micro-texture are more efficient. Furthermore, the friction coefficient of the 100 nm Al2O3-coated micro-texture tool is relatively low. When the distance of the micro-pits is 0.15 mm, the friction coefficient is lowest among the four kinds of pit textured nanometer coating tools. The friction coefficient is the lowest when the direction of the groove in strip textured nanometer coating tool is perpendicular to the main cutting edge. The main mechanism of the nanometer Al2O3 on the micro-textured tool to reduction in cutting force and the friction coefficient is discussed. These results show that the developed tools effectively decrease the cutting force and friction coefficient of tool–chip interface.

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Analytical cutting force modelling of micro-slot grinding considering tool-workpiece interactions on both primary and secondary tool surfaces

Journal of Manufacturing Science and Engineering ◽

10.1115/1.4051235 ◽

2021 ◽

pp. 1-43

Author(s):

Ashwani Pratap ◽

Karali Patra

Keyword(s):

Cutting Force ◽

Cutting Forces ◽

Orthogonal Cutting ◽

Surface Interactions ◽

Surface Interaction ◽

Edge Density ◽

Force Model ◽

Height Distribution ◽

Force Modeling ◽

Tool Surface

Abstract This work presents an analytical cutting force modeling for micro-slot grinding. Contribution of the work lies in the consideration of both primary and secondary tool surface interactions with the work surface as compared to the previous works where only primary tool surface interaction was considered during cutting force modeling. Tool secondary surface interaction with workpiece is divided into two parts: cutting/ ploughing by abrasive grits present in exterior margin of the secondary tool surface and sliding/adhesion by abrasive grits in the inner margins of the secondary tool surface. Orthogonal cutting force model and indentation based fracture model is considered for cutting by both the abrasives of primary tool surface and the abrasives of exterior margin on the secondary surface. Asperity level sliding and adhesion model is adopted to solve the interaction between the workpiece and the interior margin abrasives of secondary tool surface. Experimental measurement of polycrystalline diamond tool surface topography is carried out and surface data is processed with image processing tools to determine the tool surface statistics viz., cutting edge density, grit height distribution and abrasive grit geometrical measures. Micro-slot grinding experiments are carried out on BK7 glass at varying feed rate and axial depths of cut to validate the simulated cutting forces. Simulated cutting forces considering both primary and secondary tool surface interactions are found to be much closer to the experimental cutting forces as compared to the simulated cutting forces considering only primary tool surface interaction.

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The cutting behavior of cortical bone in different bone osten cutting angles and depths of cut

10.21203/rs.3.rs-232708/v1 ◽

2021 ◽

Author(s):

Yuanqiang Luo ◽

Yinghui Ren ◽

Yang Shu ◽

Cong Mao ◽

Zhixiong Zhou ◽

...

Keyword(s):

Fracture Toughness ◽

Cutting Force ◽

Cortical Bone ◽

Depth Of Cut ◽

Cutting Angle ◽

Small Depth ◽

Proposed Model ◽

Cutting Processes ◽

The Impact ◽

Cutting Path

Abstract Cortical bones are semi-brittle and anisotropic, this brings the challenge to suppress vibration and avoid undesired fracture in precise cutting processes in surgeries. In this paper, we proposed a novel analytical model to represent cutting processes of cortical bones, and we used to evaluate cutting forces and fracture toughness, and investigate the formations of chips and cracks under varying bone osteon cutting angles and depths. To validate the proposed model, the experiments are conducted on orthogonal cuttings over cortical bones to investigate the impact of bone osteon cutting angle and depth on cutting force, crack initialization and growth, and fracture toughness of cortical bone microstructure. The experimental results highly agreed with the prediction by the proposed model in sense that (1) curly, serrated, grainy and powdery chips were formed when the cutting angle was set as 0°, 60°, 90°, and 120°, respectively. (2) Bone materials were removed dominantly by shearing at a small depth of cut from 10 to 50 µm, and by a mixture of pealing, shearing, and bending at a large depth of cut over 100 µm at different cutting orientations. Moreover, it was found that a cutting path along the direction of crack initialization and propagation benefited to suppress the fluctuation of cutting force thus reduce the vibration. The presented model has theoretical and practical significance in optimizing cutting tools and operational parameters in surgeries.

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A Metallo-Thermomechanically Coupled Analysis of Orthogonal Cutting of AISI 1045 Steel

Journal of Manufacturing Science and Engineering ◽

10.1115/1.4007464 ◽

2012 ◽

Vol 134 (5) ◽

Cited By ~ 27

Author(s):

Hongtao Ding ◽

Yung C. Shin

Keyword(s):

Experimental Data ◽

Cutting Force ◽

Orthogonal Cutting ◽

Cutting Temperature ◽

Chip Morphology ◽

Machining Process ◽

Coupled Analysis ◽

Aisi 1045 Steel ◽

Aisi 1045 ◽

1045 Steel

Materials often behave in a complicated manner involving deeply coupled effects among stress/stain, temperature, and microstructure during a machining process. This paper is concerned with prediction of the phase change effect on orthogonal cutting of American Iron and Steel Institute (AISI) 1045 steel based on a true metallo-thermomechanical coupled analysis. A metallo-thermomechanical coupled material model is developed and a finite element model (FEM) is used to solve the evolution of phase constituents, cutting temperature, chip morphology, and cutting force simultaneously using abaqus. The model validity is assessed using the experimental data for orthogonal cutting of AISI 1045 steel under various conditions, with cutting speeds ranging from 198 to 879 m/min, feeds from 0.1 to 0.3 mm, and tool rake angles from −7 deg to 5 deg. A good agreement is achieved in chip formation, cutting force, and cutting temperature between the model predictions and the experimental data.

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Statistical Cutting Force Model for Orthogonal Cutting of Polytetrafluoroethylene (PTFE) Composites

Volume 1: Processing ◽

10.1115/msec2013-1033 ◽

2013 ◽

Cited By ~ 1

Author(s):

Felicia Stan ◽

Daniel Vlad ◽

Catalin Fetecau

Keyword(s):

Friction Coefficient ◽

Cutting Force ◽

Feed Rate ◽

Normal Force ◽

Polynomial Regression ◽

Orthogonal Cutting ◽

Cutting Speed ◽

Cutting Parameters ◽

Tool Geometry ◽

Force Model

This paper presents an experimental investigation of the cutting forces response during the orthogonal cutting of polytetrafluoroethylene (PTFE) and PTFE-based composites using the Taguchi method. Cutting experiments were conducted using the L27 orthogonal array and the effects of the cutting parameters (feed rate, cutting speed and rake angle) on the cutting force were analyzed using the S/N ratio response and the analysis of variance (ANOVA). Statistical models that correlate the cutting force with process variables were developed using ANOVA and polynomial regression. The variation of the apparent friction coefficient was analyzed with respect to tool geometry and the cutting process. The results indicated that cutting and thrust forces increase with increasing feed rate, and decrease with increasing rake angles from negative to positive values and increasing cutting speed. A power law relationship between the apparent friction coefficient and the normal force exerted by the chip on the tool-rake face was identified, the former decreasing with an increasing normal force.

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FORCE ANALYSIS OF ORTHOGONAL CUTTING OF BOVINE CORTICAL BONE

Machining Science and Technology ◽

10.1080/10910344.2013.837355 ◽

2013 ◽

Vol 17 (4) ◽

pp. 637-649 ◽

Cited By ~ 16

Author(s):

Jianbo Sui ◽

Naohiko Sugita ◽

Kentaro Ishii ◽

Kanako Harada ◽

Mamoru Mitsuishi

Keyword(s):

Cortical Bone ◽

Orthogonal Cutting ◽

Force Analysis

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Analytical Prediction of Stability Lobes in Ball End Milling

Journal of Manufacturing Science and Engineering ◽

10.1115/1.2833064 ◽

1999 ◽

Vol 121 (4) ◽

pp. 586-592 ◽

Cited By ~ 85

Author(s):

Y. Altıntas¸ ◽

E. Shamoto ◽

P. Lee ◽

E. Budak

Keyword(s):

Cutting Force ◽

End Milling ◽

Orthogonal Cutting ◽

Chip Thickness ◽

Transformation Method ◽

Quadratic Equation ◽

Analytical Prediction ◽

Force Coefficient ◽

Ball End Milling ◽

Stability Lobes

The paper presents an analytical method to predict stability lobes in ball end milling. Analytical expressions are based on the dynamics of ball end milling with regeneration in the uncut chip thickness, time varying directional factors and the interaction with the machine tool structure. The cutting force coefficients are derived from orthogonal cutting data base using oblique transformation method. The influence of cutting coefficients on the stability is investigated. A computationally efficient, an equivalent average cutting force coefficient method is developed for ball end milling. The prediction of stability lobes for ball end milling is reduced to the solution of a simple quadratic equation. The analytical results agree well with the experiments and the computationally expensive and complex numerical time domain simulations.

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Numerical Simulation of Metal Cutting Process Based on ANSYS/LS-DYNA

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.727-728.335 ◽

2015 ◽

Vol 727-728 ◽

pp. 335-338 ◽

Cited By ~ 1

Author(s):

Song Jie Yu ◽

Di Di Wang ◽

Xin Chen

Keyword(s):

Cutting Force ◽

Metal Cutting ◽

Plastic Material ◽

Orthogonal Cutting ◽

Cutting Process ◽

Machining Process ◽

Linear Deformation ◽

Deformation Problem ◽

Non Linear ◽

Elastic Plastic Material

Cutting process is a typical non-linear deformation problem, which involves material non-linear, geometry non-linear and the state non-linear problem. Based on the elastic-plastic material deformation theory, this theme established a strain hardening model. Build the simulation model of two-dimensional orthogonal cutting process of workpiece and tool by the finite element method (FEM), and simulate the changes of cutting force and the process of chip formation in the machining process, and analyzed the cutting force, the situation of chip deformation. The method is more efficient and effective than the traditional one, and provides a new way for metal cutting theory, research of material cutting performance and cutting tool product development.

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