The influence of ultrasonic vibrations on walls deposited using the waam technology

The results of a study examining the effect of ultrasonic vibrations (UT) on the microstructure and anisotropy of steel samples produced by wire-arc additive cladding are presented. UT suppresses the formation of columnar grains and crystallographic texture caused by epitaxial growth from the substrate. X‑ray diffraction analysis confirmed a 1.5–3.0‑fold decrease in the intensity of the (110) α‑Fe reflection without UT, while with UT, the structure approaches isotropic. The results demonstrate the effectiveness of UT control in the WAAM cladding process.

1. Anzalone G., Zhang Ch., Wijnen B. [et al.] A Low‑Cost Open‑Source Metal 3‑D Printer. IEEE Access, 2013, no. 1, pp. 803–810.

2. Milewski J. O. Lasers, electron beams, plasma arcs. Additive Manufacturing of Metals, 2017, vol. 258, pp. 85–97.

3. Sames W. J., Unocic K.A., Helmreich G. W. [et al.] Feasibility of in situ controlled heat treatment (ISHT) of Inconel 718 during electron beam melting additive manufacturing. Additive Manufacturing, vol. 13, pp. 156–165.

4. Taminger K., Hafley R.A. Electron beam freeform fabrication: a rapid metal deposition process. Proceedings of the 3rd Annual automotive composites conference. Troy, 2003.

5. Jackson M.A., Van Asten A., Morrow J. D. [et al.] A comparison of energy consumption in wire‑based and powder‑based additive‑subtractive manufacturing. Procedia Manufacturing, 2016, vol. 5, pp. 989–1005.

6. Gu D. D., Meiners W., Wissenbach K. [et al.] Laser additive manufacturing of metallic components: materials, processes and mechanisms. International Materials Reviews, 2012, vol. 57, pp. 133–164.

7. Guo J., Zhou Y., Liu C. [et al.] Wire arc additive manufacturing of AZ31 magnesium alloy: grain refinement by adjusting pulse frequency. Materials, 2016, vol. 9.

8. Williams S. W., Martina F., Addison A. C. [et al.] Wire arc additive manufacturing. Materials Science and Technology, 2016, vol. 32, pp. 641–647.

9. DebRoy T., Wei H. L., Zuback J. S. [et al.] Additive manufacturing of metallic components –Process, structure and properties.Progress in Materials Science, 2018, vol. 92, pp. 112–224.

10. Zhang M., Wang B., Li X. [et al.] Grain refinement of NiTi alloys during ultrasound‑assisted wire‑arc directed energy deposi‑ tion. Virtual and Physical Prototyping, 2023, vol. 19.

11. Resnina N., Palani I.A., Belyaev S. [et al.] Structure, martensitic transformations and mechanical behaviour of NiTi shape memory alloy produced by wire arc additive manufacturing. Journal of Alloys and Compounds, 2021, vol. 851.

12. Sampaio R. F. V., Pragana J. P. M., Bragança I. M. F. [et al.] Modelling of wire‑arc additive manufacturing – A review. Advances in Industrial and Manufacturing Engineering, 2023, vol. 6, pp. 100121.

13. Zhang M., Wang B., Li X. [et al.] Grain refinement of NiTi alloys during ultrasound‑assisted wire‑arc directed energy deposition. Virtual and Physical Prototyping, 2023, vol. 19.

14. Colegrove P.A., Donoghue J., Martina F. [et al.] Application of bulk deformation methods for microstructural and material property improvement and residual stress and distortion control in additively manufactured components. Scripta Materialia, 2017, vol. 135, pp. 111–118.

15. Donoghue J., Antonysamy A.A., Martina F. [et al.] The effectiveness of combining rolling deformation with wire‑arc additive manufacture on β‑grain refinement and texture modification in Ti‑6Al‑4V. Materials Characterization, 2016, vol. 114, pp. 103–114.

16. Tangestani R., Farrahi G. H., Shishegar M. [et al.] Effects of vertical and pinch rolling on residual stress distributions in wire and arc additively manufactured components. J. of Mater. Eng. and Perform, 2020, vol. 29, pp. 2073–2084.

17. Yan F., Xiong W., Faierson E. J. Grain structure control of additively manufactured metallic materials. Materials, 2017, vol. 10, pp. 1260.

18. Nickel A. H., Barnett D. M., Prinz F. B. Thermal stresses and deposition patterns in layered manufacturing. Materials Science and Engineering: A, 2001, vol. 317, pp. 59–64.

19. Zhang J., Xing Y., Zhang J. [et al.] Effects of in‑process ultrasonic vibration on weld formation and grain size of wire and arc additive manufactured parts. Materials, 2022, vol. 15, p. 5168.

20. Ji Feilong, Qin Xunpeng, Hu Zeqi [et al.] Influence of ultrasonic vibration on molten pool behavior and deposition layer forming morphology for wire and arc additive manufacturing. International Communications in Heat and Mass Transfer, 2022, vol. 130, pp. 105789.