Analysis of Geometrical Characteristics and Microstructural Evolution of Laser Deposited Titanium Alloy Based Composite Coatings

O. S. Fatoba, T. C. Jen, B. A. Tadesse, E. A. Mekonen, E. T. Akinlabi

Research output: Chapter in Book/Report/Conference proceedingConference contributionpeer-review

Abstract

The significance of additive manufacturing has been felt in aerospace industry, but the full implementation of this technique has not been adopted yet due to drawbacks in terms of quality and surface finishing. Quality and surface finishing need to be addressed for the full impact of additive manufacturing to be utilized in many industries, which in turn will impact on the economic aspect of nations. Additive manufacturing reliability must be addressed and research on reliability must be continuous in order to fully utilized all the advantages and benefits of this process in medical and aerospace industries for wide applications. The experiment of quartenary titanium alloy of Ti-Al-Si-Cu was carried out with cladding machine of 3000 Watts (CW) Ytterbium Laser System (YLS-2000-TR). This machine is situated at the National Laser Centre in the Council of Scientific and Industrial Research (NLC-CSIR). The characterization was done using the standardization ASTM E3-11 procedure. Optical images of the samples were taking via the cross-sectional areas of the samples using the standardization procedure ASTM E2228-10 standard with BX51M Olympus microscope. The microstructural evolution was carried out using the TESCAN machine with an X-MAX instrument with ASTM E766-14e1 standardization procedure.The metallurgical bond formed as a result of the melting between the base metal and the reinforcement powders was done by a reduced laser energy input in the range of 27 to 22.5 J/mm2 at samples fabricated at 900 W with increased scanning velocity. While samples fabricated at 1000 W showed decrease in laser energy input between 30 to 25 J/mm2 at increased scanning velocity. Narrow deposit width is achieved at higher scanning velocity due to small amount of reinforcement powders used during the laser material interaction. There is sharp reduction of 20.7% in clad height with 11% of copper to 12.1% in clad height reduction as the weight percent of copper is increased to 12% and further reduction to 10% in clad height as the weight percent of copper is increased to 13% with increased velocity between 1.0 to 1.2 m/min at lower laser power of 900 W. A slight reduction of 14.14 % was shown by specimen Ti-Al-9Si-3Cu. Different result was observed when the specimen was fabricated at 1000 W. The clad height reduction was in the range of 14.14 to 3.85 %.

Original languageEnglish
Title of host publicationProceedings of 2021 IEEE 12th International Conference on Mechanical and Intelligent Manufacturing Technologies, ICMIMT 2021
PublisherInstitute of Electrical and Electronics Engineers Inc.
Pages53-58
Number of pages6
ISBN (Electronic)9780738144627
DOIs
Publication statusPublished - 13 May 2021
Event12th IEEE International Conference on Mechanical and Intelligent Manufacturing Technologies, ICMIMT 2021 - Cape Town, South Africa
Duration: 13 May 202115 May 2021

Publication series

NameProceedings of 2021 IEEE 12th International Conference on Mechanical and Intelligent Manufacturing Technologies, ICMIMT 2021

Conference

Conference12th IEEE International Conference on Mechanical and Intelligent Manufacturing Technologies, ICMIMT 2021
Country/TerritorySouth Africa
CityCape Town
Period13/05/2115/05/21

Keywords

  • Clad depth
  • Clad height
  • Clad width
  • Heat affected zone
  • LMD
  • Titanium alloy

ASJC Scopus subject areas

  • Industrial and Manufacturing Engineering
  • Mechanical Engineering
  • Mechanics of Materials
  • Metals and Alloys
  • Artificial Intelligence
  • Civil and Structural Engineering

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