Simulation of High-Speed Cutting Using Deform 3D Software

Leonid Moiseevich Gurevich; Roman  Novikov; Alexander  Bannikov

doi:10.4028/www.scientific.net/SSP.299.340

Paper Titles

Production of Hybrid Polymer-Oxide Materials Based on Molybdenum Oxide Compounds Using Transient Electrolysis Method
p.316

The Influence of Cylindrical Specimen Size and Material Properties on the Distribution of Deformation during Torsion Test
p.323

Hardenability and Wear Resistance of Carburized to Hypereutectic Concentrations Steels
p.330

The Mechanical Properties of the Pipe Steel after Rolling at the Plate Mill
p.335

Simulation of High-Speed Cutting Using Deform 3D Software
p.340

Formation of Bead Shape, Structure and Mechanical Properties of Cold-Resistant High-Strength Steel Produced by Direct Laser Deposition Method
p.345

Theoretical Investigation of the Bending Process of the Pre-Strained Metal Sheet
p.351

On the Role of Gamma-Alpha Transformation in the Increase of the Fracture Toughness of Maraging Steel
p.358

Verification of a New Torsion Test Method to Study the Rheological Properties of Materials in a Cold State
p.363

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Simulation of High-Speed Cutting Using Deform 3D Software

Abstract:

The paper presents the result of the simulation of high-speed hot cutting process for ordinary and new saw geometry, using the Deform 3D software package. It was shown that the use of an additional side rake angle allows to controllably leave burr on one side of the work-piece only, and shift max stress from the saw gullets to the top of teeth.

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Periodical:

Solid State Phenomena (Volume 299)

Pages:

340-344

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.299.340

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Online since:

January 2020

Authors:

Leonid Moiseevich Gurevich, Roman Novikov*, Alexander Bannikov

Keywords:

Finite Element Method, High-Speed Cutting, Simulation

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