Aluminum Composites With Small Nanoparticles Additions: Corrosion Resistance

<- Back to I. Materials Science Vol.2

Cite the paper

Agureev, L; Kostikov, V; Eremeeva, Zh.; Barmin, A; Savushkina, S; Ivanov, B

Aluminum Composites With Small Nanoparticles Additions: Corrosion Resistance Journal Article

Mechanics, Materials Science & Engineering, 2 (1), pp. 26-31, 2016, ISSN: 2412-5954.

Abstract | Links | BibTeX

Authors: L.E. Agureev, V.I. Kostikov, Zh.V. Eremeeva, A.A. Barmin, S.V.Savushkina, B.S. Ivanov

ABSTRACT. Research of corrosion resistance of the aluminum powder composites containing microadditives (0.01 – 0.15% is executed about.) zirconium oxide nanoparticles. Extreme dependence of speed of corrosion of aluminum composites in 10-% solutions of sulfuric and nitric acid from the maintenance of nanoadditives is shown. It has been shown the dynamics of mass loss of aluminum composites with nanoparticles of ZrO2 during corrosion tests in acids solutions. The lowest corrosion rate of 3.36 mm/a of nitric acid was observed in the sample containing ZrO2 0.01 vol.% nanoparticles. For the case of sulfuric acid with the best result of 2.21 mm/a showed the material with 0.05 vol.% nano-additive.

Keywords: nanometric particles, aluminum composites, PM method, corrosion resistance. corrosion rate

DOI 10.13140/RG.2.1.3617.6400

References

[1] Berestenko V.I., Torbov V.I., Torbova O.D. Poluchenie ul’tradispersnyh poroshkov dioksida cirkonija v plazme SVCh razrjada. Tezisy dokladov IV Vsesojuznogo simpoziuma po plazmohimii, g. Dnepropetrovsk, 1984 g., s. 59-60. – Berestenko V.I., Torbay V.I., Torbova O.D. Getting ultrafine powders of zirconia in microwave plasma discharge. Abstracts of IV All-Union Symposium on Plasma Chemistry, Dnepropetrovsk, 1984, p. 59-60. [In Russian]

[2] Kevorkijan, V.M. Aluminum composites for automotive applications: a global perspective / VJVL Kevorkijan // JOM; -19991- №11.- P. 54- 58.

[3] Tang, F. The microstructure-processing-property relationships in an A1 matrix composite system reinforced by Al-Cu-Fe alloy particles / Thesis D.Ph. -Iowa State University. – Ames, Iowa. – 2004.

[4] Kang Y.C., Chan S.L.-I. Tensile properties of nanometric Al2O3 particulate-reinforced aluminum matrix composites // Materials chemistry and physics, 85, 2004. P. 438-443.

[5] Ma Z.Y., Tjong S.C., Li Y.L. et al. High temperature creep behavior of nanometric Si3N4 particulate reinforced aluminium composite .// Materials Science and Engineering, A225, 1997. -P. 125-134.

[6] Mazahery A., Osfadshabani M. Investigation on mechanical properties of nano-Al2O3-reinforced aluminum matrix composites .// Journal of Composite Materials, 45 (24), 2011. -P. 2579-2586.

[7] Roduner Je. Razmernye jeffekty v nanomaterialah. –M.: Tehnosfera, 2010. -252 s.- E. Roduner size effects in nanomaterials. -M .: Technosphere, 2010. -252 p. [In Russian]

[8] Kostikov V.I., Varenkov A.N. Sverhvysokotemperaturnye kompozicionnye materialy. –M.: Intermet Inzhiniring, 2003. -560 s. – Kostikov V.I., Varenko A.N. Ultra high temperature composites. -M .: Intermet Engineering, 2003. -560 p. [In Russian]

[9] Tehnologija proizvodstva izdelij i integral’nyh konstrukcij iz kompozicionnyh materialov v mashinostroenii./ Nauchnye redaktory A.G.Bratuhin, V.S.Bogoljubov, O.S.Sirotkin. –M.: Gotika, 2003. -516 s.- The production technology and integrated manufacturing of composite structures in mechanical engineering. / Scientific Editors A.G.Bratuhin, V.S.Bogolyubov, O.S.Sirotkin. -M .: Gothic, 2003. -516 p. [In Russian]

[10] Pilotiruemaja jekspedicija na Mars./ Pod red. A.S.Koroteeva. –M.: Rossijskaja akademija kosmonavtiki imeni K.Je.Ciolkovskogo, 2006. -320 s. – Manned expedition to Mars. / Ed. A.S.Koroteeva. -M .: Russian Academy of Cosmonautics Tsiolkovsky, 2006. -320 p. [In Russian]

[11] Alifanov O.M., Andreev A.N., Gushhin V.N. i dr. Ballisticheskie rakety i rakety-nositeli. –M.: Drofa, 2004. -512 s. – Alifanov OM, Andreev AN, VN Gushchin and others. Ballistic missiles and launchers. -M .: Bustard, 2004. -512 p. [In Russian]

[12] Kalashnikov, I.E. Razvitie metodov armirovanija i modificirovanija struktury aljumomatrichnyh kompozicionnyh materialov [Tekst]: avtoref. dis. na soisk. uchjon. step. dokt.tehn.nauk (05.16.06)/ Kalashnikov Igor’ Evgen’evich; IMET RAN. –Moskva, 2011. -26 s. – Kalashnikov IE Development of methods of reinforcement and modification of the structure of aluminum-matrix composite materials [Text]: Author. Dis. on soisk. Kazan. step. dokt.tehn.nauk (05.16.06) / Kalashnikov Tamm; IMET RAS. -Moscow, 2011. -26 p. [In Russian]

[13] Kurganova, Ju.A. Razrabotka i primenenie dispersno uprochnjonnyh aljumomatrichnyh kompozicionnyh materialov v mashinostroenii [Tekst]: avtoref. dis. na soisk. uchjon. step. dokt.tehn.nauk (05.16.06)/ Kurganova Julija Anatol’evna; IMET RAN. –Moskva, 2008. -26 s.- Kurganova, Y. Development and application of dispersion hardened aluminum-matrix composite materials in engineering [Text]: Author. Dis. on soisk. Kazan. step. dokt.tehn.nauk (05.16.06) / Kurganova Juliya; IMET RAS. -Moscow, 2008. -26 p. [In Russian]

[14] Grigorovich V.K., Sheftel’ E.N. Dispersionnoe uprochnenie tugoplavkih metallov. –M.: Nauka, 1980. -302 s.- Grigorovich V.K., Sheftel E.N. Precipitation hardening refractory metals. -M .: Nauka, 1980. -302 p. [In Russian]

[15] Sliney N.E. Kompozicionnye materialy dlja podshipnikov i uplotnitelej gazovyh turbin // Sovremennoe mashinostroenie, 1991, №3, s. 175-201. – Sliney N.E. Composite materials for bearings and seals of gas turbines // Modern Machinery, 1991, №3, p. 175-201. [In Russian]

[16] Sliding, wear response of an Al – Cu alloy the influence of SiC particle reinforcement and test parameters / Prasad B.K., Jha A.K., Modi O.P., Das S., Dasgupta R., Yegneswaran A.N. // J.Mater. Sci. Lett.- 1998.-17, № 13, p. 1121-1123.

[17] Hosking F.M., Portillo F., Wunderlin R., Mehrabian R. Composites of aluminum alloys; fabrication and wear behaviour // J.Mater.Sci. -1982.- 17, №2. P.477-498.

[18] Rohatgi P. Cast aluminum – matrix composites for automotive applications // JOM. -1991. – 43, №4.- P.10-16.

[19] Prigozhin I., Nikolis G. Samoorganizacija v neravnovesnyh sistemah: Ot dissipativnyh struktur k uporjadochennosti cherez fluktuacii. –M.: Mir, 1979. -512 s.- Prigogine I., Nicolis G. Self-organization in nonequilibrium systems: From dissipative structures for ordering through fluctuations. -M .: Mir, 1979. -512 p. [In Russian]

[20] Arnol’d V.I. Teorija katastrof. Teorija katastrof. «Sovremennye problemy matematiki. Fundamental’nye napravlenija. T. 5(Itogi nauki i tehniki VINITI AN SSSR». –M., 1988, s. 5-218. – Arnold V.I. Catastrophe Theory. Catastrophe Theory. “Contemporary Mathematics. Fundamental Directions. T. 5 (Results of Science and Technology VINITI. “-M., 1988, pp. 5-218. [In Russian]

[21] Obrazcov I.F., Lur’e S.A., Belov P.A. i dr. Osnovy teorii mezhfaznogo sloja. Mehanika kompozicionnyh materialov i konstrukcij, 2004, t. 10, №3, s. 596-612.- Samples IF, Lurie SA, Belov PA et al. Basic theory of the interfacial layer. Mechanics of Composite Materials and Structures, 2004, v. 10, №3, p. 596-612. [In Russian]

[22] Tajra S., Otani R. Teorija vysokotemperaturnoj prochnosti materialov. –M.: Metallurgija, 1986. -280 s.- Taira S., R. Otani theory of high-strength materials. -M .: Metallurgy, 1986. -280 p. [In Russian]

[23] Chuvil’deev V.N. Neravnovesnye granicy zjoren v metallah. Teorija i prilozhenija. –M.: FIZMATLIT, 2004. -304 s.- Chuvildeev VN Non-equilibrium grain boundaries in metals. Theory and Applications. -M .: FIZMATLIT, 2004. -304 p. [In Russian]

[24] Ohji T., Jeong Y.-K., Choa Y.-H., Niihara K. Strengtheing and toughening mechanisms of ceramic nanocomposites .// Journal of American Ceramic Society. – 1998. – №81. – P. 1453-1460.

[25] Handbook of Corrosion Data / Ed. by B.D.Craig, D.S.Anderson. – Ohio: ASM International, 998 p.

https://mmse.xyz/ID20160101RU5.pdf

Creative Commons Licence
Mechanics, Materials Science & Engineering Journal by Magnolithe GmbH is licensed under a Creative Commons Attribution 4.0 International License.
Based on a work at www.mmse.xyz.