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Journal of Materials Engineering and Performance

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18-04-2022 | Technical Article

Inspection of Additively Manufactured Aero-engine Parts Using Computed Radiography Technique

Authors: B. K. Nagesha, S. Anand Kumar, S. Rajeswari, Sanjay Barad, Akshay Pathania

Published in: Journal of Materials Engineering and Performance | Issue 8/2022

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Abstract

The recent advancement and development of fabricating metallic end-use parts by the additive manufacturing (AM) process are targeted for the complex shapes and part consolidation applications of aero-engine systems. Among various AM technologies, laser powder bed fusion (LPBF) is promising for complex geometries with better dimensional accuracy and surface finish. Application of non-destructive testing (NDT) methods to inspect the quality and integrity of LPBF processed parts is inevitable for quantitative assessment of process-related defects like voids and porosities. The LPBF process also tosses inspection and metrological challenges for end-use parts involving the inherent geometric complexity of topology-optimized AM parts and inaccessible internal geometries, primarily for conventional NDT methods. The computed radiography (CR) is a simpler and faster NDT technique employed in the present study to inspect the inaccessible internal geometries in the LPBF parts. CR inspection methodology is established on the different LPBF samples with different internal through-hole of 0.5 and 1.0 mm diameters. The established methodology was employed on the aero-engine parts such as instrument probe, oil injector, and diffusion cooling hole plate. The dimensional analysis demonstrated that the CR results were comparable with the CAD model. In the present study, a reasonable accuracies of 0.6, 0.6, 0.8, 0.85, and 1.24% for thin-walled plate (0.5 mm hole), thin-walled plate (1.0 mm hole), diffusion cooling hole plate, oil injector, and instrument probe, respectively, were arrived. The present study envisages the CR technique as a quicker and cost-effective inspection tool for early-stage detection of unacceptable dimensional deviations and process-induced defects for shortening the lead time of the complex-shaped aero-engine end-use parts.

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S.A. Kumar and R.V.S. Prasad, Chapter 2 - Basic Principles of Additive Manufacturing: Different Additive Manufacturing Technologies, Additive Manufacturing, M. Manjaiah, K. Raghavendra, N. Balashanmugam, and J.P. Davim, Eds., Woodhead Publishing, 2021, p 17–35. https://doi.org/10.1016/B978-0-12-822056-6.00012-6.

B.K. Nagesha, K. Vinodh, A.K. Tigga, S. Barad and S.A. Kumar, Influence of Post-Processing Techniques on Residual Stresses of SLM Processed HPNGV, J. Manuf. Processes, 2021, 66, p 189–197. CrossRef

A.K. Subramaniyan, S.R. Anigani, S. Mathias, A. Pathania, P. Raghupatruni, and S.S. Yadav, Influence of Post-Heat Treatment on Microstructure, Mechanical, and Wear Properties of Maraging Steel Fabricated Using Direct Metal Laser Sintering Technique, Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications, 2021, p 14644207211037342.

A.K. Subramaniyan, A.S. Reddy, S. Mathias, A. Shrivastava and P. Raghupatruni, Influence of Post-Processing Techniques on the Microstructure, Properties and Surface Integrity of AlSiMg Alloy Processed by Laser Powder Bed Fusion Technique, Surf. Coat. Technol., 2021, 425, p 127679. CrossRef

S. Liu and Y.C. Shin, Additive Manufacturing of Ti6Al4V Alloy: A Review, Mater. Des., 2019, 164, p 107552. CrossRef

A. Shrivastava, S. Anand Kumar, B.K. Nagesha and T.N. Suresh, Electropolishing of Inconel 718 Manufactured by Laser Powder Bed Fusion: Effect of Heat Treatment on Hardness, 3D Surface Topography and Material Ratio Curve, Opt. Laser Technol., 2021, 144, p 107448. CrossRef

W.E. Frazier, Metal Additive Manufacturing: A Review, J. Mater. Eng. Perform., 2014, 23(6), p 1917–1928. CrossRef

BK. Nagesha, S. Anand Kumar, K. Vinodh, A. Pathania, and S. Barad, A Thermo – Mechanical Modelling Approach on the Residual Stress Prediction of SLM Processed HPNGV Aeroengine Part, Materials Today: Proceedings, 2021. https://doi.org/10.1016/j.matpr.2020.12.940.

R.V.S. Prasad and S.A. Kumar, Chapter 10 - Materials for Additive Manufacturing and 4D Printing, Additive Manufacturing, M. Manjaiah, K. Raghavendra, N. Balashanmugam, and J.P. Davim, Eds., Woodhead Publishing, 2021, p 209–232. https://doi.org/10.1016/B978-0-12-822056-6.00008-4.

10.

M. Bayat, A. Thanki, S. Mohanty, A. Witvrouw, S. Yang, J. Thorborg, N.S. Tiedje and J.H. Hattel, Keyhole-Induced Porosities in Laser-Based Powder Bed Fusion (L-PBF) of Ti6Al4V: High-Fidelity Modelling and Experimental Validation, Addit. Manuf., 2019, 30, p 100835.

11.

H.D. Vora and S. Sanyal, A Comprehensive Review: Metrology in Additive Manufacturing and 3D Printing Technology, Prog. Addit. Manuf., 2020, 5(4), p 319–353. CrossRef

12.

M. Khan, M. Brothers, and T. Gillis, “Computed Radiography for High Resolution Imaging Applications of Aircraft Structures,” 11th Int. Symp. NDT Aerosp., Paris-Saclay, France, 2019.

13.

P. Minetola, The Importance of a Correct Alignment in Contactless Inspection of Additive Manufactured Parts, Int. J. Precis. Eng. Manuf., 2012, 13(2), p 211–218. CrossRef

14.

L. De Chiffre, S. Carmignato, J.-P. Kruth, R. Schmitt and A. Weckenmann, Industrial Applications of Computed Tomography, CIRP Ann., 2014, 63(2), p 655–677. CrossRef

15.

C.-X.J. Feng, A.L. Saal, J.G. Salsbury, A.R. Ness and G.C.S. Lin, Design and Analysis of Experiments in CMM Measurement Uncertainty Study, Precis. Eng., 2007, 31(2), p 94–101. CrossRef

16.

T. Brajlih, B. Valentan, J. Balic and I. Drstvensek, Speed and Accuracy Evaluation of Additive Manufacturing Machines, Rapid Prototyping J., 2011, 17(1), p 64–75. CrossRef

17.

N. Sanaei, A. Fatemi and N. Phan, Defect Characteristics and Analysis of Their Variability in Metal L-PBF Additive Manufacturing, Mater. Des., 2019, 182, p 108091. CrossRef

18.

N. Kourra, J.M. Warnett, A. Attridge, G. Dibling, J. McLoughlin, S. Muirhead-Allwood, R. King and M.A. Williams, Computed Tomography Metrological Examination of Additive Manufactured Acetabular Hip Prosthesis Cups, Addit. Manuf., 2018, 22, p 146–152.

19.

J.P. Kruth, M. Bartscher, S. Carmignato, R. Schmitt, L. De Chiffre and A. Weckenmann, Computed Tomography for Dimensional Metrology, CIRP Ann., 2011, 60(2), p 821–842. CrossRef

20.

B.E. Stoner, G.T. Jones, S. Joshi and R. Martukanitz, Optimization of Digital Radiography for Large Metallic Additively Manufactured Components, Rapid Prototyping J., 2020, 26(3), p 531–537. CrossRef

21.

R.K. Leach, D. Bourell, S. Carmignato, A. Donmez, N. Senin and W. Dewulf, Geometrical Metrology for Metal Additive Manufacturing, CIRP Ann., 2019, 68(2), p 677–700. CrossRef

22.

P. Allisy-Roberts and J. Williams, Chapter 5 - Digital Radiography, Farr’s Physics for Medical Imaging (Second Edition), P. Allisy-Roberts and J. Williams, Eds., W.B. Saunders, 2008, p 79–90. https://doi.org/10.1016/B978-0-7020-2844-1.50009-0.

23.

J.A. Rowlands, The Physics of Computed Radiography, Phys. Med. Biol., 2002, 47(23), p R123–R166. CrossRef

24.

P. Vuylsteke, E. Schoeters, N.V. Agfa-Gevaert, and B. Mortsel, Image Processing in Computed Radiography, Proc. Comput. Tomography and Image Processing, 1999, p 87–101.

25.

C.M. Burman, 11 - Immobilization and Simulation, Leibel and Phillips Textbook of Radiation Oncology (Third Edition), R.T. Hoppe, T.L. Phillips, and M. Roach, Eds., (Philadelphia), W.B. Saunders, 2010, p 193–212, https://doi.org/10.1016/B978-1-4160-5897-7.00011-1.

26.

P. Leblans, D. Vandenbroucke and P. Willems, Storage Phosphors for Medical Imaging, Materials, 2011, 4(6), p 1034–1086. CrossRef

27.

S. Everton, P. Dickens, C. Tuck and B. Dutton, Using Laser Ultrasound to Detect Subsurface Defects in Metal Laser Powder Bed Fusion Components, JOM, 2018, 70(3), p 378–383. CrossRef

28.

B. Zhang, M. Duemmler, L. Sripragash, O. Adewumi, A. Davies, J. Zeigart, C. Waters, and C. Evans, Detection of Subsurface Defects for Metal Additive Manufacturing Using Flash Thermography, Proceeding of ASPE/euspen, 2018, (July).

29.

R.J. Smith, M. Hirsch, R. Patel, W. Li, A.T. Clare and S.D. Sharples, Spatially Resolved Acoustic Spectroscopy for Selective Laser Melting, J. Mater. Process. Technol., 2016, 236, p 93–102. CrossRef

30.

M. Ferrucci, R.K. Leach, C. Giusca, S. Carmignato and W. Dewulf, Towards Geometrical Calibration of X-Ray Computed Tomography Systems—a Review, Meas. Sci. Technol., 2015, 26(9), p 092003. CrossRef

31.

A. Lopez, R. Bacelar, I. Pires, T.G. Santos, J.P. Sousa and L. Quintino, Non-Destructive Testing Application of Radiography and Ultrasound for Wire and Arc Additive Manufacturing, Addit. Manuf., 2018, 21, p 298–306.

32.

B. Zhang, Y. Li and Q. Bai, Defect Formation Mechanisms in Selective Laser Melting: A Review, Chin. J. Mech. Eng., 2017, 30(3), p 515–527. CrossRef

33.

F. Kim, H. Villarraga-Gómez, and S. Moylan, “Inspection of Embedded Internal Features in Additive Manufactured Metal Parts Using Metrological X-Ray Computed Tomography,” American Society for Precision Engineering 2016 Summer Topical Meeting, 2016, p 191–195.

34.

T. Mishurova, S. Cabeza, T. Thiede, N. Nadammal, A. Kromm, M. Klaus, C. Genzel, C. Haberland and G. Bruno, The Influence of the Support Structure on Residual Stress and Distortion in SLM Inconel 718 Parts, Metall. and Mater. Trans. A., 2018, 49(7), p 3038–3046. CrossRef

35.

A. Pathania, S. Anand Kumar, B.K. Nagesha, S. Barad and T.N. Suresh, Reclamation of Titanium Alloy Based Aerospace Parts Using Laser Based Metal Deposition Methodology, Mater. Today Proc., 2021, 45, p 4886–4892. CrossRef

36.

S. Gruber, C. Grunert, M. Riede, E. López, A. Marquardt, F. Brueckner and C. Leyens, Comparison of Dimensional Accuracy and Tolerances of Powder Bed Based and Nozzle Based Additive Manufacturing Processes, J. Laser Appl., 2020, 32(3), p 032016. CrossRef

37.

B. Ehrhart, B. Valeske, and C. Bockenheimer, 9 - Non-Destructive Evaluation (NDE) of Aerospace Composites: Methods for Testing Adhesively Bonded Composites, Non-Destructive Evaluation (NDE) of Polymer Matrix Composites, V.M. Karbhari, Ed., Woodhead Publishing, 2013, p 220–237. https://doi.org/10.1533/9780857093554.2.220.

38.

F. Górski, W. Kuczko and R. Wichniarek, Influence of Process Parameters on Dimensional Accuracy of Parts Manufactured Using Fused Deposition Modelling Technology, Adv. Sci. Technol. Res. J., 2013, 7(19), p 27–35. CrossRef

Title: Inspection of Additively Manufactured Aero-engine Parts Using Computed Radiography Technique
Authors: B. K. Nagesha
S. Anand Kumar
S. Rajeswari
Sanjay Barad
Akshay Pathania
Publication date: 18-04-2022
Publisher: Springer US
Published in: Journal of Materials Engineering and Performance / Issue 8/2022
Print ISSN: 1059-9495
Electronic ISSN: 1544-1024
DOI: https://doi.org/10.1007/s11665-022-06890-6

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