2D Finite Element Modeling of the Cutting Force in Peripheral Milling of Cellular Metals

Silva, Rafael Guerra; Teicher, Uwe; Brosius, Alexander; Ihlenfeldt, Steffen

doi:10.3390/ma13030555

Cited by 8 publications

(3 citation statements)

References 33 publications

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“…It has been shown by several studies that the machining of porous materials has been a challenging task primarily due to severe subsurface damage and smeared material caused as a result of chip tearing and heterogenous crack propagation during chip formation. Rafael et al [22] have studied the interaction between the tool edge and the mesostructure during the peripheral milling of heat resistant austenitic stainless-steel cellular material. The chip formation and cutting forces were found to be highly dependent on the arrangement of cells.…”

Section: Introductionmentioning

confidence: 99%

On the Role of Hollow Aluminium Oxide Microballoons during Machining of AZ31 Magnesium Syntactic Foam

et al. 2020

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The role played by hollow ceramic thin-walled aluminium oxide microballoons on the shear deformation characteristics of AZ31 Magnesium syntactic foam is studied through high-speed machining. The ceramic microballoons embedded in the AZ31 matrix provides the necessary stiffness for these novel foams. The effect of hollow ceramic microballoon properties, such as the volume fraction, thin wall thickness to diameter ratio, and microballoon diameter, profoundly affects the chip formation. A novel force model has been proposed to explain the causes of variation in cutting forces during chip formation. The results showed an increase in machining forces during cutting AZ31 foams dispersed with higher volume fraction and finer microballoons. At a lower (Davg/h) ratio, the mode of microballoon deformation was a combination of bubble burst and fracture through an effective load transfer mechanism with the plastic AZ31 Mg matrix. The developed force model explained the key role played by AZ31 matrix/alumina microballoon on tool surface friction and showed a better agreement with measured machining forces.

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Section: Introductionmentioning

confidence: 99%

On the Role of Hollow Aluminium Oxide Microballoons during Machining of AZ31 Magnesium Syntactic Foam

et al. 2020

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“…Converting 3D FEM-based to orthogonal 2D FEM-based simulations effectively reduced the number of elements and improved the simulation time. Although orthogonal 2D FEM-based simulations do not fully reproduce the geometric complexity and features of the full 3D milling process, they are very helpful for providing detailed information about the machining process [6].…”

Section: Introductionmentioning

confidence: 99%

A Study for Improved Prediction of the Cutting Force and Chip Shrinkage Coefficient during the SKD11 Alloy Steel Milling

2022

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This study proposed an innovative method for improving the prediction of the cutting force (F) and chip shrinkage coefficient (K) for milling of SKD11 alloy steels using simulations and experimental results. Preliminary experimental measurements of the F and K were made for variable cutting speeds and depths, and simulations were then conducted using the Johnson–Cook model. However, significant discrepancies between the experiments and simulations were observed for the F and K. Therefore, an improved method was proposed, utilizing the relationship between simulation/experimental cutting forces and the equivalent fracture strain of simulation elements in the shear zone in the space of the stress triaxiality and equivalent strain. The progression of fracture strain paths according to the stress triaxiality until the desired cutting forces were achieved was utilized for adding new data to the fracture strain locus in the space of the stress triaxiality and equivalent strain. The new fracture strain locus was adopted again, to simulate and predict the F and K at full 2 × 3 levels of cutting speeds and cutting depths, and the results were compared with those of the corresponding experiments. Based on the highest deviations between the simulation and experimental data for the cutting force (5.29%) and chip shrinkage coefficient (5.08%), this study confirmed that the proposed method for determining the new fracture strain locus can improve the prediction of the F and K for milling of SKD11 alloy steels.

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“…Last but not least, a study on the machinability of foams was published by Silva et al [ 12 ]. The machining of cellular metals has been a challenge, as the resulting surface is extremely irregular, with torn off or smeared material and poor accuracy.…”

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confidence: 99%

Special Issue ‘Advanced and High Performance Metallic Foams’

Orbulov

2021

Materials

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2D Finite Element Modeling of the Cutting Force in Peripheral Milling of Cellular Metals

Cited by 8 publications

References 33 publications

On the Role of Hollow Aluminium Oxide Microballoons during Machining of AZ31 Magnesium Syntactic Foam

On the Role of Hollow Aluminium Oxide Microballoons during Machining of AZ31 Magnesium Syntactic Foam

A Study for Improved Prediction of the Cutting Force and Chip Shrinkage Coefficient during the SKD11 Alloy Steel Milling

Special Issue ‘Advanced and High Performance Metallic Foams’

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