The influence of the source material and the method of forming the object by layer-by-layer synthesis on the structure of the resulting product

The article presents the studies’ results aimed at structure and properties learning of steel samples obtained by layer‑by‑layer application of structural material in the form of powder and wire. The ways that allow controlling the grain size in the formed products are given. It is shown that the structural products grinding manufactured by selective laser fusion can be achieved using powders obtained by reaction mechanical alloying and products formed by plasma and arc surfacing – by optimizing the conditions for applying layers.

1. Yu-sheng S. et al. Additive manufacturing and foundry innovation. China Foundry, 2021, vol. 18, pp. 286–295.

2. Gebhardt A., Hötter J-S. Additive Manufacturing 3D Printing for Prototyping and Manufacturing. Hanser Publications, 2016, 606 р.

3. Mastering 3D Printing [Electronic resource].  Mode of access: https//www.pdfdrive.com/mastering‑3d‑printing‑e32990869. Date of access: 23.01.2023.

4. Yap C. Y. Review of selective laser melting: Materials and applications. Applied Physics Reviews, 2015, vol. 2, pp. 041101.1– 041101.21.

5. Pratheesh K. S. et al. Review on surface characteristics of components produced by direct metal deposition process. Journal of Mechanical Engineering and Sciences, 2022, vol. 16, Iss. 4, pp. 9197–9229.

6. https://www.intechopen.com/books/10974.  Date of access: 19.02.2023.

7. Treutler K., Wesling V. The Current State of Research of Wire Arc Additive Manufacturing (WAAM). Аpplied Sciences, 2021, vol. 11(18), 8619, Р. 1.

8. DebRoy T. Additive manufacturing of metallic components – Process, structure and properties. Progress in Materials Science, 2018, no. 92, pp. 112–224.

9. Lovshenko F. G., Fedosenko A. S. Mehanicheski legirovannye zharoprochnye poroshki dlja proizvodstva izdelij additivnymi tehnologijami [Mechanically alloyed heat‑resistant powders for the production of products by additive technologies]. Mogilev, Belorussko‑Rossijskij universitet Publ., 2019, 405 p.

10. Lovshenko G. F., Lovshenko Z. M., Habibullin A. I. Vysokojeffektivnyj apparat dlja reakcionnogo mehanicheskogo legirovanija metallicheskih sistem [Highly efficient apparatus for reactive mechanical alloying of metal systems]. Vestnik BelorusskoRossijskogo universiteta = Bulletin of the Belarusian‑Russian University, 2007, no. 4, pp. 72–80.

11. Lovshenko F. G., Lovshenko G. F. Kompozicionnye nanostrukturnye mehanicheski legirovannye poroshki dlja gazotermicheskih pokrytij [Composite nanostructured mechanically alloyed powders for gas‑thermal coatings]. Mogilev, Belorussko‑Rossijskij universitet Publ., 2013, 216 p.

12. Lovshenko G. F., Lovshenko F. G., Hina B. B. Nanostrukturnye mehanicheski legirovannye materialy na osnove metallov

13. [Nanostructural mechanically alloyed materials based on metals]. Mogilev, Belorussko‑Rossijskij universitet Publ., 2008, 679 p.

14. Zhang H., Xu J., Wang G. Fundamental study on plasma deposition manufacturing. Surface and Coatings Technology, 2003, vol. 171(1–3), pp. 112–118.

15. Xinhong X., Jialin C., Dunmiao Q. Directly Manufacturing Mouse Mold by Plasma Deposition Manufacturing. Advanced Materials Research, 2014, vol. 941–944., pp. 2190–2193.

16. Hoefer K. 3D plasma metal deposition for processing multi material Titanium parts. Welding International, 2021, vol. 35, Iss. 1–3, pp. 12–15.

17. Hoefer K., Mayr P. Additive Manufacturing of Titanium Parts Using 3D Plasma Metal. Materials Science Forum, 2018, vol. 941, pp. 2137–2141.

18. Hoefer K. Fabrication of SS316L to Ni80Cr20 graded structures by 3D plasma metal deposition. Welding in the World, 2020, vol. 64, pp. 1307–1311.

19. Fanrong K., Haiou Z., Guilan W. Numerical Simulation of Transient Multiphase Field During Hybrid Plasma‑Laser Deposition Manufacturing. Journal of Heat Transfer, 2008, vol. 130, pp. 112101‑1–112101‑7.