Dimensional verification and correction of five-axis numerically controlled milling tool paths

In the context of 5-axis flank milling, the machining of non-developable ruled surfaces may lead to complex tool paths to minimize undercut and overcut. The curvature characteristics of these tool paths generate slowdowns affecting the machining time and the quality of the machined surface. The tool path has to be as smooth as possible while respecting the maximum allowed tolerance. In this paper, an iterative approach is proposed to smooth an initial tool path. An indicator of the maximum feedrate is computed using the kinematical constraints of the considered machine tool, especially the maximum velocity, acceleration and jerk. Then, joint coordinates of the tool path are locally smoothed in order to raise the effective feedrate in the area of interest. Machining simulation based on a N-buffer algorithm is used to control undercut and overcut. This method has been tested in flank milling of an impeller and can be applied in 3 to 5-axis machining.

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Study of The Tool Path Generation Method of an Ultra-Precision Spherical Complex Surface Based on a Five-Axis Machine Tool

10.21203/rs.3.rs-167042/v1 ◽

2021 ◽

Author(s):

Tianji Xing ◽

Xuesen Zhao ◽

Zhipeng Cui ◽

Rongkai Tan ◽

Tao Sun

Keyword(s):

Surface Roughness ◽

Tool Path ◽

Spherical Surface ◽

Tool Path Generation ◽

Path Generation ◽

Tool Paths ◽

Spherical Surfaces ◽

Spherical Complex ◽

Ultra Precision ◽

Five Axis

Abstract The improvement of ultra-precision machining technology has significantly boosted the demand for the surface quality and surface accuracy of the workpieces to be machined. However, the geometric shapes of workpiece surfaces cannot be adequately manufactured with simple plane, cylindrical, or spherical surfaces because of their different applications in various fields. In this research, a method was proposed to generate tool paths for the machining of complex spherical surfaces based on an ultra-precise five-axis turning and milling machine with a C-Y-Z-X-B structure. Through the proposed tool path generation method, ultra-precise complex spherical surface machining was achieved. First, the complex spherical surface model was modeled and calculated, and then it was combined with the designed model to generate the tool path. Then the tool paths were generated with a numerically controlled (NC) program. Based on an ultra-precision three-coordinate measuring instrument and a white light interferometer, the machining accuracy of a workpiece surface was characterized, and t[1]he effectiveness of the provided tool path generation method was verified. The surface roughness of the machined workpiece was less than 90 nm. Furthermore, the surface roughness within the spherical region appeared to be less than 30 nm. The presented tool path generation method in this research produced ultra-precision spherical complex surfaces. The method could be applied to complex spherical surfaces with other characteristics.

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Experimental Investigation of the Effect of the Machine Kinematic Behavior on the Surface Topography and Roughness in High Speed Ball end Milling of the AISI4142 Steel

10.21203/rs.3.rs-197062/v1 ◽

2021 ◽

Author(s):

Sai Lotfi ◽

Belguith Rami ◽

Baili Maher ◽

Desseins Gilles ◽

Bouzid Wassila

Keyword(s):

Surface Topography ◽

High Speed ◽

End Milling ◽

Experimental Investigations ◽

Ball End Milling ◽

Tool Paths ◽

Stationary Zone ◽

Machining Errors ◽

Kinematic Behavior ◽

Milling Tool

Abstract The analysis of the surface topography in ball end milling is an objective studied by many researchers, several methods were used and many combinations of cutting conditions and machining errors are considered. In the milling tool paths the trajectories presents a points of changing direction where the tool decelerates before and accelerates after respecting the velocity profiles of the machine. In this paper, we propose experimental investigations of the effect of the kinematic behavior of the machine tool on the surface quality. A poor topography and roughness are remarked on the deceleration and the acceleration zones compared to the stationary zone.

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Five-axis flank milling tool path generation with curvature continuity and smooth cutting force for pockets

Chinese Journal of Aeronautics ◽

10.1016/j.cja.2018.12.003 ◽

2020 ◽

Vol 33 (2) ◽

pp. 730-739 ◽

Cited By ~ 3

Author(s):

Changqing LIU ◽

Yingguang LI ◽

Xin JIANG ◽

Wenyao SHAO

Keyword(s):

Cutting Force ◽

Tool Path ◽

Tool Path Generation ◽

Flank Milling ◽

Path Generation ◽

Milling Tool ◽

Curvature Continuity ◽

Five Axis

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A discrete simulation-based algorithm for the technological investigation of 2.5D milling operations

Proceedings of the Institution of Mechanical Engineers Part C Journal of Mechanical Engineering Science ◽

10.1177/0954406218757267 ◽

2018 ◽

Vol 233 (1) ◽

pp. 78-90 ◽

Cited By ~ 4

Author(s):

Adam Jacso ◽

Tibor Szalay ◽

Juan Carlos Jauregui ◽

Juvenal Rodriguez Resendiz

Keyword(s):

Tool Path ◽

Analytical Description ◽

Machining Process ◽

Simulation Algorithm ◽

Tool Paths ◽

Milling Operations ◽

Nc Simulation ◽

2.5D Milling ◽

Milling Tool ◽

Nc Milling

Many applications are available for the syntactic and semantic verification of NC milling tool paths in simulation environments. However, these solutions – similar to the conventional tool path generation methods – are generally based on geometric considerations, and for that reason they cannot address varying cutting conditions. This paper introduces a new application of a simulation algorithm that is capable of producing all the necessary geometric information about the machining process in question for the purpose of further technological analysis. For performing such an analysis, an image space-based NC simulation algorithm is recommended, since in the case of complex tool paths it is impossible to provide an analytical description of the process of material removal. The information obtained from the simulation can be used not only for simple analyses, but also for optimisation purposes with a view to increasing machining efficiency.

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A Voxel Model-Based Process-Planning Method for Five-Axis Machining of Complicated Parts

Journal of Computing and Information Science in Engineering ◽

10.1115/1.4046589 ◽

2020 ◽

Vol 20 (4) ◽

Author(s):

Yamin Li ◽

Kai Tang ◽

Long Zeng

Keyword(s):

Process Planning ◽

Planning Method ◽

Dynamic Problems ◽

Tool Paths ◽

New Process ◽

Part Surface ◽

Voxel Model ◽

Voxel Representation ◽

Complex Features ◽

Five Axis

Abstract This paper presents a new process planning method for five-axis machining, which is particularly suitable for parts with complex features or weak structures. First, we represent the in-process workpiece as a voxel model. Facilitated by the voxel representation, a scalar field called subtraction field is then established between the blank surface and the part surface, whose value at any voxel identifies its removal sequence. This subtraction field helps identify a sequence of intermediate machining layers, which are always accessible to the tool and are free of self-intersection and the layer redundancy problem as suffered, respectively, by the traditional offset layering method and the morphing method. Iso-planar collision-free five-axis tool paths are then determined on the interface surfaces of these machining layers. In addition, to mitigate the deformation of the in-process workpiece and avoid potential dynamic problems such as chattering, we also propose a new machining strategy of alternating between the roughing and finishing operations, which is able to achieve a much higher stiffness of the in-process workpiece. Ample experiments in both computer simulation and physical cutting are performed, and the experimental results convincingly confirm the advantages of our method.

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Tool path generation for a car rear door die: UMO versus rest milling tool paths

IOP Conference Series Materials Science and Engineering ◽

10.1088/1757-899x/671/1/012146 ◽

2020 ◽

Vol 671 ◽

pp. 012146

Author(s):

Ali K. Alwan ◽

Wissam K. Hamdan

Keyword(s):

Tool Path ◽

Tool Path Generation ◽

Path Generation ◽

Tool Paths ◽

Rear Door ◽

Milling Tool

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Generating Milling Tool Paths for Prismatic Parts Using Genetic Programming

Procedia CIRP ◽

10.1016/j.procir.2015.06.060 ◽

2015 ◽

Vol 33 ◽

pp. 490-495 ◽

Cited By ~ 4

Author(s):

Jack Barclay ◽

Vimal Dhokia ◽

Aydin Nassehi

Keyword(s):

Genetic Programming ◽

Tool Paths ◽

Prismatic Parts ◽

Milling Tool

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Production of Castings by Patternless Process

Archives of Foundry Engineering ◽

10.2478/v10266-012-0017-x ◽

2012 ◽

Vol 12 (1) ◽

pp. 87-92

Author(s):

R. Pastirčák ◽

D. Urgela ◽

E. Krivoš

Keyword(s):

Water Glass ◽

3D Model ◽

Tool Paths ◽

Milling Tool ◽

Moulding Compound ◽

Mould Cavity ◽

Model Setting ◽

Process Method

Production of Castings by Patternless ProcessThis paper deals with production of safety inlay for steam locomotive valve by the Patternless Process method. For the moulds creation was used moulding mixtures of II. generation, whereas binder was used a water glass. CNC miller was used for creation of mould cavity. Core was created also by milling into block made of moulding compound. In this article will be presented also making of 3D model, setting of milling tool paths and parameters for milling.

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