Cemented Carbides for Machining of Heat-Resistant Materials

A.M. Adaskina; S.N. Grigoriev; A.A. Vereschaka; A.S. Vereschaka; V.V. Kashirtsev

doi:10.4028/www.scientific.net/AMR.628.37

Paper Titles

Development of Natural Fiber Reinforced Laminated Hybrid Composites
p.15

Characterization of Chemically Synthesized Ag₂Se Nanowires via Anodic Alumina Membrane as Template
p.21

Ultrafine Glass Fibers Produced by Centrifugal-Spinneret-Blow Process
p.27

Influence of Density on the Thermal Conductivity of Fiberglass Felt
p.33

Cemented Carbides for Machining of Heat-Resistant Materials
p.37

Controlled Patterning and Dimensional Control of Suspended Carbon Nanofibers
p.43

Research on Mechanical Properties of Nano-Concrete
p.50

Modern Office Furniture Design Based on Ergonomics
p.57

Multi-Role-Based Employee Performance Appraisal Method for Manufacturing Enterprise
p.63

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 628Cemented Carbides for Machining of Heat-Resistant...

Cemented Carbides for Machining of Heat-Resistant Materials

Abstract:

The optimum ratio of rhenium and cobalt in Co-Re binder of a cemented carbides based on the analysis of phase diagrams and studying the carbides properties is defined.It is shown that properties of carbide binder at the same ratio of rhenium and cobalt are also the same, and the carbide properties are determined by the amount of carbide binders.Researches of wear resistance of the tool from carbides with Co-Re binder at machining of a constructional steel and hard-to-machining alloys have confirmed their high efficiency.

You might also be interested in these eBooks

Manufacturing Engineering and Technology for Manufacturing Growth

View Preview

Info:

Periodical:

Advanced Materials Research (Volume 628)

Pages:

37-42

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.628.37

Citation:

Cite this paper

Online since:

December 2012

Authors:

A.M. Adaskina, S.N. Grigoriev, A.A. Vereschaka, A.S. Vereschaka, V.V. Kashirtsev

Keywords:

Carbides Binder, Cemented Carbide, Ratio of Rhenium and Cobalt in Carbides Binder, Tool Life

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Maslenkov S.V. Heat resisting steels and alloys. Handbook. Moscow. Meta Lasr version. Paper fo San-Diego coferance/USA, 2012. metallurgija. 1988. 191 p.

Google Scholar

[2] Kremnev L.S. Alloying and thermal treatment of cutting tool steels and alloys. Handbook M.L. Bernshten, A.G. Rahshtade aditors. Moscow. Mashinostroenie. 183. V. 2. P. 298 - 318.

Google Scholar

[3] Phase diagrams of a condition of double metal systems. Under the editorship of N.P. Ljapisheva. Moscow. Mashinostroenie. v. 1.P. 911.

Google Scholar

[4] Kieffer R., Schwarzkopf P. Hardstoffe Hardmetalle. –Wien: Springer-Verlag, (1953).

Google Scholar

[5] Iutina I.A., Kuprina V.V., Sokolovsky E.M., Spasov I.A. Rhenium interaction with cobalt and nickel. In book"Research and application of rhenium alloys". Moscow. Publisher Science,. 1975. 54-56.

Google Scholar

[6] Giamei I., Curma J., Rabin S. Cobalt, 1968. №40.P. 140-157.

Google Scholar

[7] Vereshchaka A.S., Vereshchaka A.A. Functional coаtings for an edge cutting tools. Strengthening technologies and coatings. 2010. №6.P. 28-37.

Google Scholar

[8] Vereshchara A.S., Anikin A.I., Dacheva A.V. Tough machining effectiveness by application of tooling with nanostructured wear-resistant coating. Moscow. Technology of mechanical engineering. 2010. №3.P. 17-22.

Google Scholar

[9] Metel A.; Grigoriev S.; Melnik Y. et al. Cutting tools nitriding in plasma produced by a fast neutral molecule beam/Japanese Journal of Applied Physics. 2011. V 50 No. 8. Article 08JG04.

DOI: 10.1143/jjap.50.08jg04

Google Scholar

[10] Grigoriev S.N., Vereschaka A.A., Vereschaka A.S., Kutin A.A. Cutting tools made of layered composite ceramics with nano-scale multilayered coatings. Procedia CIRP 1(2012)318–323.

DOI: 10.1016/j.procir.2012.04.054

Google Scholar

[11] Metel A.S., Grigoriev C.N., Melnik Yu.A. et. al. Glow discharge with electrostatic confinement of electrons in a chamber bombardment by fast electrons/Plasma physics reports. 2011/Vol. 37, N 7, pp.628-637.

DOI: 10.1134/s1063780x11050072

Google Scholar