Research on Five-Axis Dual-NURBS Adaptive Interpolation Algorithm for Flank Milling

In order to exploit the advantages of five-axis flank milling method for space free surface machining to the full, a definition of non-equidistant dual-NURBS tool path is presented first. On this basis, the constraint of velocity of points on the tool axis and the constraint of scanning area of the tool axis are deduced. Considering both of these constraints, an adaptive feed five-axis dual-NURBS interpolation algorithm is proposed. The simulation results show that the feedrate with the proposed algorithm satisfies both of the constraints and the machining time is reduced by 38.3% in comparison with the constant feed interpolator algorithm.

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A novel tool-path generation method for five-axis flank machining of centrifugal impeller with arbitrary surface blades

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

10.1177/0954405415599943 ◽

2016 ◽

Vol 231 (1) ◽

pp. 155-166 ◽

Cited By ~ 9

Author(s):

Hong-Zhou Fan ◽

Shang-Jin Wang ◽

Guang Xi ◽

Yan-Long Cao

Keyword(s):

Tool Path ◽

Tool Path Generation ◽

Ruled Surface ◽

Centrifugal Impeller ◽

Flank Milling ◽

Path Generation ◽

Rough Machining ◽

Machining Time ◽

Geometrical Structures ◽

Five Axis

The centrifugal impeller with arbitrary surface blades is a very important component in automobile, ships, and aircraft industry, and it is one of the most difficult parts to process. Focusing on the machining efficiency improvement, combining the geometric advantages of ruled surface and arbitrary surface, and utilizing the efficient and accurate advantages of flank machining and point machining, this article presents a novel and targeted tool-path generation method and algorithm for five-axis flank machining of centrifugal impeller with arbitrary surface blades. In light of specific characters of different surfaces, the analyses of two different impeller blades are proposed first, the more characteristic and complex geometrical structures of the arbitrary blade are achieved. In rough machining, an approximate ruled surface blade is obtained, and a simple channel is achieved; the flank milling of the centrifugal impeller with ruled surface blades is achieved relative to the point milling of the centrifugal impeller with arbitrary surface blades; and the triangle tool path planning method is added in this process to save the machining time and cost collectively. Furthermore, in semi-finish machining, the approximate sub-ruled blade surfaces are calculated, and a new flank milling method of the sub-ruled blade surfaces is achieved; a new solution for tool interference is achieved in this process and the generation of non-interference tool paths becomes easy. Machining experiments of two different impellers are presented as a test of the proposed methods.

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Calculation and Optimization of Cutter Position for Flank Milling Spatial Cam Based on NURBS

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.375-376.578 ◽

2008 ◽

Vol 375-376 ◽

pp. 578-582

Author(s):

Rong Yu Ge ◽

Xian Ying Feng ◽

Xian Chun Song

Keyword(s):

Tool Path ◽

Optimization Method ◽

Least Square ◽

Flank Milling ◽

Normal Vector ◽

Machining Error ◽

Cam Mechanism ◽

Tool Axis ◽

Milling Method ◽

Tool Axis Vector

In some cases the spatial cam is manufactured with a cutter whose diameter is smaller than that of the roller of cam mechanism, which is defined as nonequivalent manufacture method in the paper. By the analysis for manufacture of contact lines between the cam and the roller, it is indicated that errors caused by the different directions of normal vector are unavoidable for the nonequivalent manufacture method. In order to find the best tool axis vector to minimize the machining error, this paper realized the nonequivalent machining of spatial cam surfaces using the NC flank milling method and proposed a new generation algorithm of the tool path based on NURBS. The NURBS ruled surface of tool axis trajectory is confirmed based on the least square optimization method and the machining error model is given. At last, a numerical calculation and simulation example is described to verify the effectiveness of the algorithm proposed in the paper.

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Feed Optimization for Five-Axis Flank Milling Thin-Walled Parts

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.703.150 ◽

2014 ◽

Vol 703 ◽

pp. 150-155

Author(s):

Ming Yong Wang

Keyword(s):

Process Optimization ◽

Sequential Quadratic Programming ◽

Tool Path ◽

Milling Process ◽

Flank Milling ◽

Machining Time ◽

Mechanics Model ◽

Finished Surface ◽

Thin Walled ◽

Five Axis

This paper presents process optimization for the five-axis milling based on the mechanics model explained in Part I. The process is optimized by varying the feed as the tool-workpiece engagements. The linear and angular feedrates are optimized by sequential quadratic programming. Sharp feedrate changes may result in undesired feed-marks on the finished surface. The adopted step is to update the the original CL file with optimized and filtered feedrate commands. The five-axis milling process is simulated in a virtual enviroment, and the resulting feedrate outputs are stored at each position along the tool path. The new feedrate profiles are shown to considerably reduce the machining time while avoiding process faults.

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Five-Axis Flank Milling Method of Plane Double Enveloping Hourglass Worm

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.314-316.1523 ◽

2011 ◽

Vol 314-316 ◽

pp. 1523-1532

Author(s):

Lei Zhong ◽

Qing Zhen Bi ◽

Yu Han Wang ◽

Han Ding

Keyword(s):

Surface Quality ◽

Tool Path ◽

End Milling ◽

Tooth Surface ◽

Flank Milling ◽

Machining Efficiency ◽

Contact Lines ◽

Milling Method ◽

Simulation And Experiment ◽

Five Axis

A high-precision and efficient machining method of plane double enveloping hourglass worm is proposed. The worm tooth surface is first created and analyzed based on meshing theory. The analysis reveals that the worm tooth surface is a developable ruled surface. This provides the ability of precise flank milling of the worm tooth surface. The meshing lines on the worm tooth surface indicate the contact lines of the worm tooth and the cutter. The five-axis tool path of flank milling is then generated according to the meshing lines. The flank milling has obviously advantages in machining efficiency and surface quality, compared with the conventional end milling method. The cutting simulation and experiment validate proposed method.

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Global optimization of tool path for five-axis flank milling with a conical cutter

Computer-Aided Design ◽

10.1016/j.cad.2010.06.005 ◽

2010 ◽

Vol 42 (10) ◽

pp. 903-910 ◽

Cited By ~ 54

Author(s):

LiMin Zhu ◽

Gang Zheng ◽

Han Ding ◽

YouLun Xiong

Keyword(s):

Global Optimization ◽

Tool Path ◽

Flank Milling ◽

Five Axis

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Multi-pass progressive tool path planning in five-axis flank milling by particle swarm optimisation

International Journal of Computer Integrated Manufacturing ◽

10.1080/0951192x.2012.667153 ◽

2013 ◽

Vol 26 (10) ◽

pp. 977-987 ◽

Cited By ~ 9

Author(s):

Hsin-Ta Hsieh ◽

Yi-Chun Tsai ◽

Chih-Hsing Chu

Keyword(s):

Path Planning ◽

Tool Path ◽

Particle Swarm ◽

Particle Swarm Optimisation ◽

Flank Milling ◽

Tool Path Planning ◽

Five Axis

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Tool Path Generation for Five-Axis Controlled Machining of Free-Form Surface Using Barrel Tool: Control of Contact Point on Cutting Edge

JSME 2020 Conference on Leading Edge Manufacturing/Materials and Processing ◽

10.1115/lemp2020-8539 ◽

2020 ◽

Author(s):

Tomonobu Suzuki ◽

Koichi Morishige

Keyword(s):

Tool Path ◽

Contact Point ◽

Cutting Edge ◽

Free Form ◽

End Mill ◽

Ball End Mill ◽

Surface Machining ◽

Free Form Surface ◽

The Cost ◽

Five Axis

Abstract This study aimed to improve the efficiency of free-form surface machining by using a five-axis controlled machine tool and a barrel tool. The barrel tool has cutting edges, with curvature smaller than the radius, increasing the pick feed width compared with a conventional ball end mill of the same tool radius. As a result, the machining efficiency can be improved; however, the cost of the barrel tool is high and difficult to reground. In this study, a method to obtain the cutting points that make the cusp height below the target value is proposed. Moreover, a method to improve the tool life by continuously and uniformly changing the contact point on the cutting edge is proposed. The usefulness of the developed method is confirmed through machining simulations.

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Tool Path Planning for Five-Axis U-Pass Milling of an Impeller

10.21203/rs.3.rs-384138/v1 ◽

2021 ◽

Author(s):

J.Y. Feng ◽

Z.C. Wei ◽

M.J. Wang ◽

X.Q. Wang ◽

M.L. Guo

Keyword(s):

Path Planning ◽

Cutting Force ◽

Tool Path ◽

Flank Milling ◽

Small Range ◽

Tool Path Planning ◽

Point Distribution ◽

Parameter Domain ◽

Five Axis ◽

Tool Axis Vector

Abstract U-pass milling is a roughing method that combines the characteristics of flank milling with conventional trochoidal milling. The tool cuts in and out steadily, and the tool–workpiece wrap angle is maintained within a small range. This method can smooth the cutting force and reduce the peak cutting force while avoiding cutting heat accumulation, which can significantly improve the processing efficiency and reduce tool wear. In this study, a tool path model is established for U-pass milling, and the characteristic parameters of the path are defined. Through a comparative test of three-axis groove milling, it is demonstrated that the peak value and average value of the cutting force are reduced by 25% and 60%, respectively. An impeller runner is considered as the processing object, and the milling boundary parameters are pretreated. A tiling micro-arc mapping algorithm is proposed, which maps the three-dimensional boundary to the two-dimensional parameter domain plane with the arc length as the coordinate axis, and the dimensionally reduced tool contact point distribution form is obtained. The geometric domain tool position point and the interference-free tool axis vector are obtained by calculating the bidirectional proportional domain of the runner and the inverse mapping of any vector in the parameter domain. Finally, the calculation results are nested into the automatically programmed tool (APT) encoding form, and the feasibility of the five-axis U-pass milling tool path planning method is verified through a numerical example.

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5-Axis Flank Milling Tool Path Smoothing Based on Kinematical Behaviour Analysis

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.223.691 ◽

2011 ◽

Vol 223 ◽

pp. 691-700 ◽

Cited By ~ 1

Author(s):

Xavier Beudaert ◽

Pierre Yves Pechard ◽

Christophe Tournier

Keyword(s):

Tool Path ◽

Maximum Velocity ◽

Flank Milling ◽

Machining Time ◽

Machined Surface ◽

Tool Paths ◽

Area Of Interest ◽

Milling Tool ◽

Joint Coordinates ◽

Kinematical Behaviour

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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