In Situ Nondestructive Fatigue‐Life Prediction of Additive Manufactured Parts by Establishing a Process–Defect–Property Relationship

Seyyed Hadi Seifi; Aref Yadollahi; Wenmeng Tian; Haley Doude; Vincent H. Hammond; Linkan Bian

doi:10.1002/aisy.202000268

Advanced Intelligent Systems (Dec 2021)

In Situ Nondestructive Fatigue‐Life Prediction of Additive Manufactured Parts by Establishing a Process–Defect–Property Relationship

Seyyed Hadi Seifi,
Aref Yadollahi,
Wenmeng Tian,
Haley Doude,
Vincent H. Hammond,
Linkan Bian

Affiliations

Seyyed Hadi Seifi: Department of Industrial and Systems Engineering Mississippi State University 479-2 Hardy Road, 260 McCain Hall Mississippi State MS 39762 USA
Aref Yadollahi: Department of Mechanical Engineering University of South Alabama 150 Student Services Dr Mobile AL 36688 USA
Wenmeng Tian: Department of Industrial and Systems Engineering Mississippi State University 479-2 Hardy Road, 260 McCain Hall Mississippi State MS 39762 USA
Haley Doude: Center for Advanced Vehicular Systems Mississippi State University 200 Research Blvd Starkville MS 39759 USA
Vincent H. Hammond: Weapons and Materials Research Directorate US Army Research Laboratory Aberdeen Proving Ground Maryland 21005 USA
Linkan Bian: Department of Industrial and Systems Engineering Mississippi State University 479-2 Hardy Road, 260 McCain Hall Mississippi State MS 39762 USA

DOI: https://doi.org/10.1002/aisy.202000268
Journal volume & issue: Vol. 3, no. 12
pp. n/a – n/a

Abstract

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The presence of process‐induced internal defects (i.e., pores, microcracks, and lack‐of‐fusions) significantly deteriorates the structural durability of parts fabricated by additive manufacturing. However, traditional defects characterization techniques, such as X‐ray CT and ultrasonic scanning, are costly and time‐consuming. There is a research gap in the nondestructive evaluation of fatigue performance directly from the process signature of laser‐based additive manufacturing processes. Herein, a novel two‐phase modeling methodology is proposed for fatigue life prediction based on in situ monitoring of thermal history. Phase (I) includes a convolutional neural network designed to detect the relative size of the defects (i.e., small gas pores and large lack‐of‐fusions) by leveraging processed thermal images. Subsequently, a fatigue‐life prediction model is trained in Phase (II) by incorporating the defect characteristics extracted from Phase (I) to evaluate the fatigue performance. Estimating defect characteristics from the in situ thermal history facilitates the fatigue predicting process.

Published in Advanced Intelligent Systems

ISSN: 2640-4567 (Online)
Publisher: Wiley
Country of publisher: Germany
LCC subjects: Technology: Electrical engineering. Electronics. Nuclear engineering: Electronics: Computer engineering. Computer hardware; Technology: Mechanical engineering and machinery: Control engineering systems. Automatic machinery (General)
Website: https://onlinelibrary.wiley.com/journal/26404567

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