Crack Growth in a Range of Additively Manufactured Aerospace Structural Materials

Iliopoulos, Athanasios; Jones, Rhys; Michopoulos, John G.; Phan, Nam; Singh, Raman Raghuvir Kumar

doi:10.3390/aerospace5040118

Cited by 48 publications

(58 citation statements)

References 41 publications

(123 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The main analyses methods used in the present paper are described in detail [17], and also in the subsequent sections.…”

Section: Methodsmentioning

confidence: 99%

“…In this context, Cao, Zhang, Ryde, and Lados [24] presented an early review of cracking in AM Ti-6Al-4V, where fatigue thresholds associated with the different AM processes were carefully assessed. References [3,16,17,21] subsequently revealed that crack growth in a range of AM materials could be represented by the Hartman-Schijve (HS) variant of the NASGRO crack growth equation, viz:…”

Section: Crack Growth In Am Ti-6al-4vmentioning

confidence: 99%

“…Returning to the critical question of the variability in the crack growth curves associated with AM materials, this paper builds on previous studies [3,16,17,21] and illustrates the degree of variability in the da/dN versus ∆K curves associated with AM Ti-6Al-4V materials that have been either heat-treated or HIPed (hot isostatic pressed). We also illustrate that provided there are sufficient test data, as is the case for crack growth in AM Ti-6Al-4V, a reasonably accurate representation of the associated upper bound curve and the small crack curve can be calculated using the Hartman-Schijve crack growth equation [3,[15][16][17][18][19][20][21]. The present study also analyses crack growth in AM Inconel 625 and 17-4 PH stainless steel.…”

Section: Introductionmentioning

confidence: 97%

“…The MIL-STD-1530D [12] and EZ-SB-19-01 [4] requirement to perform a damage tolerance and durability analysis (DADT) requires a knowledge of the da/dN versus ΔK curves associated with AM materials. However, it is now known [3,16,17] that whereas for conventionally manufactured materials, the variability in the cyclic fracture toughness term A can be small, for AM materials, its variability can be quite large. Furthermore, the influence of this variability on the total life can be significant [3].…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Further Studies into Crack Growth in Additively Manufactured Materials

et al. 2020

Self Cite

View full text Add to dashboard Cite

Understanding and characterizing crack growth is central to meeting the damage tolerance and durability requirements delineated in USAF Structures Bulletin EZ-SB-19-01 for the utilization of additive manufacturing (AM) in the sustainment of aging aircraft. In this context, the present paper discusses the effect of different AM processes, different build directions, and the variability in the crack growth rates related to AM Ti-6Al-4V, AM Inconel 625, and AM 17-4 PH stainless steel. This study reveals that crack growth in these three AM materials can be captured using the Hartman–Schijve crack growth equation and that the variability in the various da/dN versus ΔK curves can be modeled by allowing the terms ΔKthr and A to vary. It is also shown that for the AM Ti-6AL-4V processes considered, the variability in the cyclic fracture toughness appears to be greatest for specimens manufactured using selective layer melting (SLM).

show abstract

“…The main analyses methods used in the present paper are described in detail [17], and also in the subsequent sections.…”

Section: Methodsmentioning

confidence: 99%

Section: Crack Growth In Am Ti-6al-4vmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Further Studies into Crack Growth in Additively Manufactured Materials

et al. 2020

Self Cite

View full text Add to dashboard Cite

show abstract

“…Applications to bridge and rail steels are given in [50][51][52], to polymers in [53] and to bonded wooden joints in [54]. Equation (1) has also been shown to be able to represent the growth of both long and small cracks in additively-manufactured materials [55][56][57], to laser additive deposition (LAD) and cold spray repairs to metallic structures [58,59]. A feature of this formulation is that the scatter in the crack growth curves can often be accounted for by allowing for the variability in the threshold term ∆K thr [22,42,44,49,56,57].…”

Section: Theoretical Considerationsmentioning

confidence: 99%

Requirements and Variability Affecting the Durability of Bonded Joints

et al. 2020

Self Cite

View full text Add to dashboard Cite

This paper firstly reveals that when assessing if a bonded joint meets the certification requirements inherent in MIL-STD-1530D and the US Joint Services Standard JSSG2006 it is necessary to ensure that: (a) There is no yielding at all in the adhesive layer at 115% of design limit load (DLL), and (b) that the joint must be able to withstand design ultimate load (DUL). Secondly, it is revealed that fatigue crack growth in both nano-reinforced epoxies, and structural adhesives can be captured using the Hartman–Schijve crack growth equation, and that the scatter in crack growth in adhesives can be modelled by allowing for variability in the fatigue threshold. Thirdly, a methodology was established for estimating a valid upper-bound curve, for cohesive failure in the adhesive, which encompasses all the experimental data and provides a conservative fatigue crack growth curve. Finally, it is shown that this upper-bound curve can be used to (a) compare and characterise structural adhesives, (b) determine/assess a “no growth” design (if required), (c) assess if a disbond in an in-service aircraft will grow and (d) to design and life in-service adhesively-bonded joints in accordance with the slow-growth approach contained in the United States Air Force (USAF) certification standard MIL-STD-1530D.

show abstract

Review on Fatigue of Additive Manufactured Metallic Alloys: Microstructure, Performance, Enhancement, and Assessment Methods

Liu,

Yu,

Guo

et al. 2023

Advanced Materials

View full text Add to dashboard Cite

Additive manufacturing (AM), which is a process of building objects in a layer‐upon‐layer fashion from designed models, has received unprecedented attention from research and industry because it offers outstanding merits of flexibility, customization, reduced buy‐to‐fly ratio, and cost‐effectiveness. However, the fatigue performance of safety‐critical industrial components fabricated by AM is still far below that obtained from conventional methods. This review discusses the microstructural heterogeneities, randomly dispersed defects, poor surface quality, and complex residual stress generated during the AM process that can negatively impact the fatigue performance of as‐printed parts. The difference in microstructural origin of fatigue failure between conventionally manufactured and printed metals is reviewed with particular attention to the effects of the trans‐scale microstructures on AM fatigue failure mechanisms. Various methods for mitigating the fatigue issue, including pre‐process, inter‐process and post‐process treatments, are illustrated. Empirical, semi‐empirical and microstructure‐sensitive models are presented to predict fatigue strength and lifetime. Summary and outlooks for future development of the fatigue performance of AM materials are provided.This article is protected by copyright. All rights reserved

show abstract

Crack Growth in a Range of Additively Manufactured Aerospace Structural Materials

Cited by 48 publications

References 41 publications

Further Studies into Crack Growth in Additively Manufactured Materials

Further Studies into Crack Growth in Additively Manufactured Materials

Requirements and Variability Affecting the Durability of Bonded Joints

Review on Fatigue of Additive Manufactured Metallic Alloys: Microstructure, Performance, Enhancement, and Assessment Methods

Contact Info

Product

Resources

About