High-cycle fatigue behavior of a laser powder bed fusion additive manufactured Ti-6Al-4V titanium: Effect of pores and tested volume size

Pessard, Etienne; Lavialle, Manon; Laheurte, Pascal; Didier, Paul; Brochu, Myriam

doi:10.1016/j.ijfatigue.2021.106206

Cited by 36 publications

(9 citation statements)

References 35 publications

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“…Previous publications studied the mechanical properties of metallic SLM parts, including 316 stainless steel [10,11], Ti6Al4V [12][13][14][15], Inconel 718 [16] and aluminum alloys [3][4][5][6][7][8][9][17][18][19][20][21][22][23][24][25][26][27][28].…”

Section: Introductionmentioning

confidence: 99%

Effect of Platform Temperature and Post-Processing Heat Treatment on the Fatigue Life of Additively Manufactured AlSi7Mg Alloy

Martins

Provencher

Brochu

et al. 2021

Metals

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The effect of platform temperature combined with a T5 heat treatment on the fatigue life of additively manufactured aluminum alloy AlSi7Mg was characterized and understood. High-cycle fatigue tests were carried out on samples built with four platform temperatures (35 °C, 60 °C, 80 °C and 200 °C) and post-processing heat treatment strategies (F and T5). Microstructural and fractographic observations combined with microhardness measurements were performed. A log-normal statistical distribution regressed with 90% B-basis probabilities of survival revealed that specimens produced on a platform maintained at 80 °C and post-processed with a T5 heat treatment presented the highest fatigue life among the conditions tested. Precipitation of silicon within the aluminum cells during the T5 heat treatment is the proposed explanation for the improved fatigue life of the T5 samples. In the as-built condition, specimens produced at 200 °C were found to be less resistant to fatigue than the specimens built at lower temperatures. The coarser microstructure and lowest microhardness resulting from high-temperature manufacturing explain this reduced fatigue strength. All fatigue cracks initiated from manufacturing discontinuities. This led to a fatigue life prediction model based upon linear elastic fracture mechanics. The model was fitted to the experimental results of the F and T5 samples separately. With the exception of the 35 °C—T5 specimens, the predicted fatigue lives agree with the experimental results and literature.

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Section: Introductionmentioning

confidence: 99%

Effect of Platform Temperature and Post-Processing Heat Treatment on the Fatigue Life of Additively Manufactured AlSi7Mg Alloy

Martins

Provencher

Brochu

et al. 2021

Metals

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“…This dispersion is shown in Fig. 1 and can be attributed to different sized defects at the origin of fatigue fracture and to the variation of the local microstructure at the initiation site [25][26][27]. In general, the largest defect contained in the loaded sample and close to the free surface is likely to be the critical defect responsible for the final failure in High Cycle Fatigue (HCF) [28,29].…”

Section: Introductionmentioning

confidence: 95%

“…As pointed out by several authors [21,24,25], alloys manufactured by AM are characterized by S-N data showing a large scatter in fatigue lives and fatigue strength. This dispersion is shown in Fig.…”

Section: Introductionmentioning

confidence: 95%

Fatigue strength and life assessment of L-PBF 316L stainless steel showing process and corrosion related defects

Merot

Morel

Pessard

et al. 2022

Engineering Fracture Mechanics

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“…On account of few inherent defects in additively manufacturing methods, such as poor bonding defects, porosities, and edge crack initiations, makes the components vulnerable to cyclic loading. E. Pessard et al [16] have studied the effect of pores and tested volume size on fatigue performance of additively manufactured Ti6Al4V alloy. The different number of hemispherical surface holes are introduced to locally raise the stress and change the size of highly stressed volume.…”

Section: Introductionmentioning

confidence: 99%

Machine Learning Based Predictions of Fatigue Crack Growth Rate of Additively Manufactured Ti6Al4V

Konda

Verma

Jayaganthan

2021

Metals

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The present work focusses on machine learning assisted predictions of the fatigue crack growth rate (FCGR) of Ti6Al4V (Ti64) processed through laser powder bed fusion (L-PBF) and post processing. Various machine learning techniques have provided a flexible approach for explaining the complex mathematical interrelationship among processing-structure-property of the materials. In the present work, four machine learning (ML) algorithms, such as K- Nearest Neighbor (KNN), Decision Trees (DT), Random Forests (RF), and Extreme Gradient Boosting (XGB) algorithms are implemented to analyze the Fatigue Crack growth rate (FCGR) of Ti64 alloy. After tuning the hyper parameters for these algorithms, the trained models were found to estimate the unseen data as equally well as the trained data. The four tested ML models are compared with each other over the training as well as testing phase, based on their mean squared error and R2 scores. Extreme Gradient Boosting has performed better for the FCGR predictions providing least mean squared errors and higher R2 scores compared to other models.

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High-cycle fatigue behavior of a laser powder bed fusion additive manufactured Ti-6Al-4V titanium: Effect of pores and tested volume size

Cited by 36 publications

References 35 publications

Effect of Platform Temperature and Post-Processing Heat Treatment on the Fatigue Life of Additively Manufactured AlSi7Mg Alloy

Effect of Platform Temperature and Post-Processing Heat Treatment on the Fatigue Life of Additively Manufactured AlSi7Mg Alloy

Fatigue strength and life assessment of L-PBF 316L stainless steel showing process and corrosion related defects

Machine Learning Based Predictions of Fatigue Crack Growth Rate of Additively Manufactured Ti6Al4V

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