High-performance end milling of aluminum alloy: Influence of different serrated cutting edge tool shapes on the cutting force

Burek, Jan; Płodzień, Marcin; Żyłka, Łukasz; Sułkowicz, Paweł

doi:10.14743/apem2019.4.344

Cited by 13 publications

(10 citation statements)

References 19 publications

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“…Agarwal and Rao [20] discussed the mechanism of damage and material removal of SiC cutting. Burek et al [21] analysed the cutting edge-shape cutting-force components model, and the study proved that serrated cutting edges adopting end mills had lower cutting force components.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Cutting Performance of a Circular Saw Blade Based on ANSYS/LS-DYNA

Wang

Zeng

et al. 2021

SV-JME

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The circular saw blade is widely applied in rock processing; its cutting performance significantly impacts rock processing. Therefore, the numerical simulation model of rock cutting with the flexible circular saw blade has been established to investigate the effects of cutting parameters on the stress and cutting force of circular saw blade, and the damage and stress of rock in the circular saw blade cutting into rock vertically at constant feed speed and rotation speed. The research results indicate that the stress of the saw blade and rock rises with the increase of feed speed and rotation speed of the saw blade. Furthermore, the rock damage and the cutting force of the circular saw blade increase with the increasing feed speed and decrease with increasing rotation speed. The circular saw blade cutting force, vertical force, and horizontal force increase with the rising distance between the double circular saw blade. However, the axial force decreases. The research results of cutting hard rock with the flexible circular saw blade can aid in the optimization of cutting parameters and improve cutting efficiency.

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Section: Introductionmentioning

confidence: 99%

Investigation of Cutting Performance of a Circular Saw Blade Based on ANSYS/LS-DYNA

Wang

Zeng

et al. 2021

SV-JME

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“…For an acceptable deburring accuracy of less than 3•10 −5 m, the maximum rotation of the rotary table at each toolpath segment must be in the following interval: rot t,c ∈ −π•10 −5 , π•10 −5 (20) If the current toolpath segment is at the outer edge of the table, the maximum relative motion between the workpiece and the tool is 2.4880•10 −5 m.…”

Section: Rotary Table Constraintsmentioning

confidence: 99%

“…The adjustable stiffness of such a mechanism is easy to determine, but the approach still requires some design effort and reduces the flexibility of an autonomous robotic solution. To some extent, force control can also be shifted directly to the cutting tool [20]. To highlight the advantages of robotic deburring, an optimization of the deburring toolpath with respect to the robot stiffness is required.…”

Section: Introductionmentioning

confidence: 99%

Stiffness-Based Cell Setup Optimization for Robotic Deburring with a Rotary Table

2021

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Deburring is recognized as an ideal technology for robotic automation. However, since the low stiffness of the robot can affect the deburring quality and the performance of an industrial robot is generally inhomogeneous over its workspace, a cell setup must be found that allows the robot to track the toolpath with the desired performance. In this work, the problems of robotic deburring are addressed by integrating components commonly used in the machining industry. A rotary table is integrated with the robotic deburring cell to increase the effective reach of the robot and enable it to machine a large workpiece. A genetic algorithm (GA) is used to optimize the placement of the workpiece based on the stiffness of the robot, and a local minimizer is used to maximize the stiffness of the robot along the deburring toolpath. During cutting motions, small table rotations are allowed so that the robot maintains high stiffness, and during non-cutting motions, large table rotations are allowed to reposition the workpiece. The stiffness of the robot is modeled by an artificial neural network (ANN). The results confirm the need to optimize the cell setup, since many optimizers cannot track the toolpath, while for the successful optimizers, a performance imbalance occurs along the toolpath.

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“…It is also important that during milling of thin-walled elements, the contact time of the cutting edge with the workpiece should be limited. This is possible due to the use of increased cutting speeds v c and a small ratio of depth of cut a p to milling width a e ( a p / a e ) [ 17 , 26 , 27 ].…”

Section: Introductionmentioning

confidence: 99%

A Comparison of the Geometrical Accuracy of Thin-Walled Elements Made of Different Aluminum Alloys

et al. 2021

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In modern constructions, especially aircraft, the aim is to minimize the weight of the components used. This necessitates the use of innovative construction materials, or the production of these parts with ever-decreasing wall thicknesses. To simplify assembly and improve strength properties, so-called structural elements are being used in the form of monolithic elements, which are replacing the assemblies of parts joined by, for example, riveting. These structures often have a complex, thin-walled geometry with deep pockets. This paper attempts to assess the accuracy of manufacturing thin-walled elements, in the shape of walls with different geometries, made of various aluminum alloys. Machining tests were conducted at different cutting speeds, which allowed comparisons of the geometric accuracy of parts manufactured under conventional and high-speed cutting conditions. Based on the result obtained, it was found that the elements made of EN AW-7075 T651 alloy underwent the greatest deformations during machining in comparison to that of other two materials (EN AW-6082 T651 and EN AC-43000). An increase in the geometrical accuracy of the manufactured elements was also observed with the increase in the cutting speed for the HSC range. Hence, to minimize the postmachining deformation of thin-walled elements, the use of high-speed cutting is justified.

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High-performance end milling of aluminum alloy: Influence of different serrated cutting edge tool shapes on the cutting force

Cited by 13 publications

References 19 publications

Investigation of Cutting Performance of a Circular Saw Blade Based on ANSYS/LS-DYNA

Investigation of Cutting Performance of a Circular Saw Blade Based on ANSYS/LS-DYNA

Stiffness-Based Cell Setup Optimization for Robotic Deburring with a Rotary Table

A Comparison of the Geometrical Accuracy of Thin-Walled Elements Made of Different Aluminum Alloys

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