Influence of Intermetallics on Complex Alloyed Brass Hardness

R.K. Mysik; A.V. Sulitsin; S.V. Brusnitsyn

doi:10.4028/www.scientific.net/SSP.265.789

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Influence of Intermetallics on Complex Alloyed Brass Hardness

Abstract:

The results of the study of phase composition, structure, and properties of multi-component complex alloyed wear-resistant brass are presented. The material contains aluminium, manganese, silicon, nickel, and chromium besides copper and zinc. A review of the influence of these components on the formation of intermetallics with different chemical composition and morphology is made. Based on the analysis it is revealed that the wear resistance of brass is highly dependent on the ratio of α-and β-phases and the volume fraction of the intermetallic particles. Chemical X-ray fluorescence, scanning electron microscopy (SEM) and electron-probe microanalysis (EPMA) are used. Based on the experiments it is established that alloys without chromium contain rod-shaped intermetallics based on Mn-Si compound with a ratio of length to cross sectional dimension 2–4. These intermetallics create the effect of anisotropy in an alloy. The presence of chromium in an alloy leads to the formation of equiaxial intermetallics with the chromium silicide core and manganese silicide coat; in this case the alloy is isotropic. It is established with metallographic study that the density of intermetallic compounds distribution of 50–130 thousand particles per 1 mm³ is required to archive the 291–298 HB hardness of brass. Cast ingots are made following the semi-casting method and then pressed to tube bars; the finished products are made by stamping so, the production technology can improve the mechanical characteristics of alloy.

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Periodical:

Solid State Phenomena (Volume 265)

Pages:

789-792

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.265.789

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Online since:

September 2017

Authors:

R.K. Mysik*, A.V. Sulitsin, S.V. Brusnitsyn

Keywords:

Cast Bar, Complex Alloyed Brass, Density of Distribution, Hardness, Intermetallics, Structure

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References

[1] M.I. Volkov, Yu.N. Loginov, L.M. Zhukova [et al. ], RU Patent 2, 382, 099 (2010).

Google Scholar

[2] R.K. Mysik, S.V. Brusnitsyn, A.V. Sulitsin, M.O. Ivkin, A.V. Karpinskiy, Features of copper alloys cast bars production, Bulletin of the South Ural State University. Series Metallurgy,. 14(2) (2014) 26-34.

Google Scholar

[3] H. Mindivan, H. Сimenoglu, E.S. Kayali, Microstructures and wear properties of brass synchroniser rings, Wear. 254 (2003) 532-537.

DOI: 10.1016/s0043-1648(03)00023-1

Google Scholar

[4] A. Hidetoshi, U.S. Patent 4, 995, 924 (1991).

Google Scholar

[5] A. Hidetoshi, U.S. Patent 4, 874, 439 (1989).

Google Scholar

[6] S.V. Brusnitsyn, R.K. Mysik, A.V. Sulitsin, Semicontinuous casting of complex alloyed wear-resistant brasses, USTU-UPI, Ekaterinburg, (2009).

Google Scholar

[7] S.V. Brusnitsyn, R.K. Mysik, M.O. Ivkin, A.V. Sulitsin, Investigation of wear-resistant brass structure, Foundry production today and tomorrow: Conference proceedings, Saint Petersburg, (2014) 221-238.

Google Scholar

[8] R.K. Mysik, S.V. Brusnitsyn, M.O. Ivkin, A.V. Sulitsin, Investigation of fine structure of complex alloyed brass, Problems and achievements in innovation materials and mechanical engineering: Conference proceedings, Komsomolsk on Amur, (2015).

Google Scholar

[9] K.S. Lee, D.K. Park, U.S. Patent 4, 851191 (1989).

Google Scholar

[10] R.K. Mysik, S.V. Brusnitsyn, M.O. Ivkin, Structure of complex alloyed copper alloy CuZnMnAlSiNiCr, 2014 Sino-Russian Symposium on Advanced Materials and Processing Technology: Abstracts, Qindao, China, (2014).

Google Scholar

[11] S.A. Saltykov, Stereometrical metallography, Metallurgy, Moscow, (1976).

Google Scholar

[12] A.S. Ovchinnikov, Yu.N. Loginov, Features of the extrusion of pipes of complex alloyed brass Cu70Zn13Mn7Al5Fe2Si2Pb1, Production of rolled metal, 4 (2012) 38-41.

Google Scholar