Variable-depth multi-pass tool path generation on mesh surfaces

In a typical multi-pass machining process of freeform surfaces, especially at the roughing stage, the constant Z level strategy is typically used. Under this strategy, the inevitably formed islands where the tool has to travel between increase the machining time as the tool has to air-cut between th...

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Bibliographic Details
Published inInternational journal of advanced manufacturing technology Vol. 95; no. 5-8; pp. 2169 - 2183
Main Authors Chen, Lufeng, Li, Yingguang, Tang, Kai
Format Journal Article
LanguageEnglish
Published London Springer London 01.03.2018
Springer Nature B.V
Subjects
CAE) and Design
Computer simulation
Computer-Aided Engineering (CAD
Engineering
Finite element method
Industrial and Production Engineering
Islands
Machine shops
Material removal rate (machining)
Maximization
Mechanical Engineering
Media Management
Mesh generation
Multiaxis
Optimization
Original Article
Parameters
Process planning
Strategy
Surface geometry
Surface properties
Tool path
Mesh surface
Material removal rate
Iso-parametric
Process planning
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Summary:In a typical multi-pass machining process of freeform surfaces, especially at the roughing stage, the constant Z level strategy is typically used. Under this strategy, the inevitably formed islands where the tool has to travel between increase the machining time as the tool has to air-cut between them. Moreover, the uneven intermediate geometry left on the islands leads to sharp changing of chip load and jeopardizes the finish surface quality. To avoid the staircase-like intermediate geometry of the islands and most of all for the ultimate goal of maximizing the machining efficiency, in this paper we present a method of variable-depth of cut multi-pass tool path generation for multi-axis machining of mesh surfaces. By parameterizing the cut volume to a unit uvw cubic parametric domain, the multi-pass process planning task turns to finding an optimal sequence of w level parameters. To solve the optimization problem, we introduce a machining efficiency indicator—the average material removal rate (AMRR). The w level parameters are obtained by iteratively solving the maximization problem regarding AMRR. The preliminary computer simulation and real physical cutting experiments show that substantial savings in total machining time could be achieved by the proposed method as compared to the traditional constant Z level method.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-017-1367-x