Si and Mn effect on mechanical properties and linear shrinking of non-magnetic Cu-Al system cast bronzes
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- Category: Content №2 2025
- Last Updated on 26 April 2025
- Published on 30 November -0001
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Authors:
T.V.Kimstach, orcid.org/0000-0002-8993-201X, Ukrainian State University of Science and Technologies, Dnipro, Ukraine, е-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
K.I.Uzlov, orcid.org/0000-0003-0744-9890, Ukrainian State University of Science and Technologies, Dnipro, Ukraine, е-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
O.P.Bilyi, orcid.org/0000-0003-1234-5404, Ukrainian State University of Science and Technologies, Dnipro, Ukraine, е-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
S.I.Repyakh*, orcid.org/0000-0003-0203-4135, Ukrainian State University of Science and Technologies, Dnipro, Ukraine, е-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
* Corresponding author e-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.
Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu. 2025, (2): 113 - 120
https://doi.org/10.33271/nvngu/2025-2/113
Abstract:
Purpose. To establish Si and Mn influence on mechanical properties level at 20 °C and aluminum bronzes structure with Al from 3 to 9 % mass content investigation.
Methodology. Cast bronzes mechanical properties have been determined based on their fracture results on FP-100/1 machine and PSW-30 pendulum impactor. Microstructure has been examined using Neophot-21 optical microscope. Bronzes linear shrinkage coefficients have been calculated based on results of determining cast cylindrical samples lengths changes. Si and Mn complex influence on bronzes properties has been determined by the results of simplex triangles according to H. Scheffer plan constructing. Temperature has been measured with chromel-alumel thermocouple completed with electronic potentiometer. Bronzes chemical composition has been determined on EXPERT 4L analyzer.
Findings. Silicon (up to 2 %) and manganese (up to 2 %) adding to Cu-Al system bronze, while aluminum content from 9 to 3 % reducing, leads to bronze ultimate tensile and yield strength decreasing during stretching and its plasticity increasing. At the same time, bronze structure, at any combination of Al, Si and Mn contents within their changes in studied limits, remains single-phase.
Originality. For the first time, comprehensive assessment of influence of Si and Mn with simultaneous decrease in Al content on mechanical properties and linear shrinkage of Cu-Al-Si-Mn system cast bronzes has been carried out. It has been established that all bronzes of studied compositions have a single-phase structure and mechanical properties level that is inherent for pressure-worked bronzes.
Practical value. The research results expand understanding about elemental and complex influence of Si and Mn on aluminum bronzes properties, provide an opportunity to choose a bronze with properties required level from its cast billet for deformation or to design castings taking into account the linear shrinkage values discovered in this work. The data obtained can also be the basis for new foundry, corrosion-resistant, non-magnetic bronzes, which have strength and density at the level of some carbon steel grades, development. Such materials have been used for parts that operate in chemically aggressive environments manufacturing, for control and measuring equipment and devices parts, for ship parts and naval devices, fittings, bushings, couplings, intrinsically safe tools, etc.
Keywords: bronze, strength, shrinkage, mechanical properties, aluminum, silicon, manganese
References.
1. Donatus, U., Omotoyinbo, J. A., & Momoh, I. M. (2012). Mechanical Properties and Microstructures of Locally Produced Aluminium-Bronze Alloy. Journal of Minerals and Materials Characterization and Engineering, 11(10), 1020-1026. https://doi.org/10.4236/jmmce.2012.1110105
2. Kat de Naoum, & Conniff, M. (2024, 10 January). Aluminum Bronze: Definition, Composition, Types, Properties, and Applications. Xometry. Retrieved from https://www.xometry.com/resources/materials/aluminum-bronze/
3. Richardson, I. (2016). Guide to Nickel Aluminium Bronze for Engineers. In C. Powell (Ed.) Copper Development Association (222 nd ed.). Retrieved from https://copper.org/applications/marine/nickel_al_bronze/pub-222-nickel-al-bronze-guide-engineers.pdf
4. Magnetic Behavior of Bronze: How Magnetic Are Bronze Alloys? – BOYI (2024). BOYI. Retrieved from https://www.boyiprototyping.com/materials-guide/is-bronze-magnetic/
5. Zhang, B., Wang, J., & Yan, F. (2018). Load-dependent tribocorrosion behaviour of nickel-aluminium bronze in artificial seawater. Corrosion Science, 131, 252-263. https://doi.org/10.1016/j.corsci.2017.11.028.
6. Iannuzzi, M., Vasanth, K. L., & Frankel, G. S. (2017). Unusual Correlation between SKPFM and Corrosion of Nickel Aluminum Bronzes. Journal of The Electrochemical Society, 164(9), C488-C497. https://doi.org/10.1149/2.0391709jes
7. Copper.org – C95600 Alloy. Advanced Search for Wrought and Cast Copper Alloys. Retrieved from https://alloys.copper.org/alloy/C95600
8. Achiṭei, D.-C., Vizureanu, P., Dană, D.-I., Minciună, M.-G., & Grancea, V. (2013). Study of aluminium bronze, mark CuAl9Mn2. TEHNOMUS ‒ New Technologies and Products in Machine Manufacturing Technologies, 20, 172-177.
9. Official Site of Copper Development Association, Inc. (USA) (2012). Copper Alloys for Marine Environments. Retrieved from https://www.copper.org/applications/marine/cuni/alloys/pub-206-copper-alloys-for-marine-environments.pdf
10. Yang, F., Kang, H., Guo, E., Li, R., Chen, Z., Zeng, Y., & Wang, T. (2018). The role of nickel in mechanical performance and corrosion behaviour of nickel-aluminium bronze in 3.5 wt.% NaCl solution. Corrosion Science, 139, 333-345. https://doi.org/10.1016/j.corsci.2018.05.012
11. Ni, D. R., Xiao, B. L., Ma, Z. Y., Qiao, Y. X., & Zheng, Y. G. (2010). Corrosion properties of friction–stir processed cast NiAl bronze. Corrosion Science, 52(5), 1610-1617. https://doi.org/10.1016/j.corsci.2010.02.026
12. Wu, Z., Cheng, Y. F., Liu, L., Lv, W., & Hu, W. (2015). Effect of heat treatment on microstructure evolution and erosion–corrosion behavior of a nickel-aluminum bronze alloy in chloride solution. Corrosion Science, 98, 260-270. https://doi.org/10.1016/j.corsci.2015.05.037
13. Qin, Z., Xia, D.-H., Zhang, Y., Wu, Z., Liu, L., Lv, Y., Liu, Y., & Hu, W. (2020). Microstructure modification and improving corrosion resistance of laser surface quenched nickel–aluminum bronze alloy. Corrosion Science, 174, 108744. https://doi.org/10.1016/j.corsci.2020.108744
14. Qin, Z., Luo, Q., Zhang, Q., Wu, Z., Liu, L., Shen, B., & Hu, W. (2018). Improving corrosion resistance of nickel-aluminum bronzes by surface modification with chromium ion implantation. Surface and Coatings Technology, 334, 402-409. https://doi.org/10.1016/j.surfcoat.2017.11.066
15. Witasiak, D., Garbacz-Klempka, A., Papaj, M., Papaj, P., Piękoś, M., Kozana, J., Maj, M., & Perek-Nowak, M. (2023). Effect of Alloying Additives and Casting Parameters on the Microstructure and Mechanical Properties of Silicon Bronzes. Archives of Foundry Engineering. https://doi.org/10.24425/afe.2023.146669
16. Copper ‒ Periodic Table. Periodic-Table.io. Retrieved from https://uk.periodic-table.io/element-29
17. Aluminum ‒ Periodic Table. Periodic-Table.io. Retrieved from https://uk.periodic-table.io/element-13
18. Silicon ‒ Periodic Table. Periodic-Table.io. Retrieved from https://uk.periodic-table.io/element-14
19. Manganese ‒ Periodic Table. Periodic-Table.io. Retrieved from https://uk.periodic-table.io/element-25
20. Contributors to Wikimedia projects. (2014, April 10). Stoichiometric valence.
21. Tantardini, C., & Oganov, A. R. (2021). Thermochemical electronegativities of the elements. Nature Communications, 12(1). https://doi.org/10.1038/s41467-021-22429-0
22. Kimstach, T. V., Uzlov, K. I., Solonenko, L. I., Repiakh, S. I., Khrychykov, V. Ye., Bilyi, O. P., Bilyi, A. P., & Ivanova, L. Kh. (2021). Investigation of impurities in bronze BrO3A3 influence on its mechanical properties. Theory and practice of metallurgy, 4(129), 41-47. https://doi.org/10.34185/tpm.4.2021.05
23. Uzlov, K. I., Repiakh, S. I., Mazorchuk, V. F., Dziubina, A. V., & Kimstach, T. V. (2021). Method of manufacturing bells and sound elements of percussion-type musical instruments] (Patent of Ukraine No. 146989). National Intellectual Property Authority State Enterprise “Ukrainian Institute of Intellectual Property”. Retrieved from https://sis.nipo.gov.ua/uk/search/detail/1585903/
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