Your search keyword '"Advanced process"' showing total 2 results

1. Advanced process design for re-contouring using a time-domain dynamic material removal simulation

Author

O. Pape, Berend Denkena, A. Mücke, and Thilo Grove

Subjects

0209 industrial biotechnology, Ternary alloys, Topography, Welds, Material removal, Process parameters, Computer science, Dewey Decimal Classification::600 | Technik::670 | Industrielle und handwerkliche Fertigung, Process design, 02 engineering and technology, Welding, 010501 environmental sciences, 01 natural sciences, law.invention, Surface topography, Process strategies, Ball milling, Time-domain dynamics, 020901 industrial engineering & automation, law, ddc:670, Titanium alloys, Time domain, Process engineering, Vanadium alloys, Milling, Konferenzschrift, 0105 earth and related environmental sciences, General Environmental Science, Titanium, Contouring, business.industry, End milling, Process stability, Dewey Decimal Classification::600 | Technik, Aluminum alloys, High surface, Machined surface, Machined surface topography, General Earth and Planetary Sciences, Advanced process, business, ddc:600, Milling (machining), Simulation

Abstract

The repair of components often requires the removal of excess weld material. This removal is considered as re-contouring. Re-contouring processes have to be designed individually for each case of damage to fulfil the high quality requirements. Therefore, a prognosis of the machined surface topography is crucial. The material removal simulation introduced in this paper allows the prediction of process stability and surface topography for 5-axis ball end milling including dynamic effects. Different process strategies for re-contouring of Ti-6Al-4V welds are examined. It is shown, that selecting suitable process parameters can lead to high surface quality while maintaining productivity. © 2019 The Author(s).

Published

2019

2. Optimization of complex cutting tools using a multi-dexel based material removal simulation

Author

O. Pape, Thilo Grove, and Berend Denkena

Subjects

Optimization, 0209 industrial biotechnology, Turning, Discretization, Material removal, Computer science, Dewey Decimal Classification::600 | Technik::670 | Industrielle und handwerkliche Fertigung, Mechanical engineering, Geometry, 02 engineering and technology, Serrated end mills, 010501 environmental sciences, 01 natural sciences, Dexel, Indexable inserts, 020901 industrial engineering & automation, Position (vector), ddc:670, Machining centers, Representation (mathematics), Turning operations, Konferenzschrift, 0105 earth and related environmental sciences, General Environmental Science, Milling cutters, Rake, Process (computing), Cutting tools, Dewey Decimal Classification::600 | Technik, Discretizations, Face (geometry), General Earth and Planetary Sciences, Geometric modeling, Advanced process, Simulaton, ddc:600, Milling (machining)

Abstract

Multi-dexel based material removal simulations provide a fast and flexible way to compute process forces and tool deflections for milling and turning operations. This allows an advanced process planning including detection of collisions for complex toolpaths. However, using dexel simulations for designing cutting tools has rarely been investigated. Especially the position of individual cutting edges is not considered, because current approaches only subtract the sweep volume of the tool envelop instead of the rake face. This paper presents a new method to design cutting tools using material removal simulations and a detailed tool geometry representation. The discretization of the tool allows an efficient calculation of the engagement conditions of individual cutting edges. The method is used to optimize novel porcupine milling cutters with round indexeble inserts, which produces a geometry analogous to serrated end mills. Based on the calculated forces, the positions of individual indexable inserts are adjusted to minimize the maximum radial force. An optimum has been found that reduces radial force by 12% compared to conventional porcupine milling cutters with squared inserts. © 2019 The Authors. Published by Elsevier B.V. Peer-review under responsibility of the scientific committee of The 17th CIRP Conference on Modelling of Machining Operations

Published

2019