Catalogue of NIMS fatigue data sheets

Furuya, Yasubumi; Nishikawa, Hideaki; Hirukawa, Hisashi; Nagashima, Nobuo; Takeuchi, Etsuo

doi:10.1080/14686996.2019.1680574

Cited by 30 publications

(24 citation statements)

References 135 publications

(7 reference statements)

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“…Cyclic yield stresses were estimated by fitting the peak stresses of the hysteresis curves to a Ramberg‐Osgood type equation by linear regression:

ε_{a} = ε_{el} + ε_{pl} = \frac{σ_{a}}{E} + {(\frac{σ_{a}}{C})}^{\frac{1}{n}},

where E is Young modulus, C is the cyclic strain hardening coefficient, n is the cyclic hardening strain exponent, ε a is strain amplitude, ε el is elastic strain amplitude, ε pl is plastic strain amplitude, and σ a is stress amplitude. In the following figures, previously reported data on HAZ 11 and existing data 4 on steels and aluminium alloys, measured using incremental step fatigue tests, 25 were also plotted. Similar to the previous conclusion, 11 cyclic yielding stresses were comparable to data for existing steels regardless of changes in microstructure and were approximately proportional to monotonic tensile strength.…”

Section: Resultssupporting

confidence: 66%

“…Unlike existing data, quench‐tempered carbon and low‐alloy steels, the HAZ microstructure does not clearly show cyclic softening. This is somewhat similar to SUS630 and A7075‐T6 aluminium alloys, which are precipitation‐hardened materials 4 …”

Section: Resultsmentioning

confidence: 99%

“…Because the fatigue crack growth rate is generally governed by the cyclic J integral, plastic strain amplitude has a greater impact than stress amplitude, especially in the low‐cycle fatigue region 26 . On the other hand, because the fatigue limit is usually proportional to tensile strength, 4 the high‐cycle fatigue region tends to be sensitive to tensile stress. Therefore, the data variation in Figures 8 and 9 is narrower than in Figure 7.…”

Section: Resultsmentioning

confidence: 99%

“…The effects of microstructure changes on fatigue property have been widely investigated and discussed based on a large fatigue database 4–6 . For example, it is well known that the fatigue limit is normally proportional to the monotonic tensile strength of the microstructure 4 . However, these previous investigations were mostly conducted on the “normal” microstructure of base metals such as quench‐tempered martensite or ferrite‐pearlite microstructure.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Effect of microstructure of simulated heat‐affected zone on low‐ to high‐cycle fatigue properties of low‐carbon steels

Nishikawa

Furuya

Igi³

et al. 2020

Fatigue Fract Eng Mat Struct

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To clarify the effect of microstructural changes on the fatigue property of the weld heat-affected zone (HAZ), low-to high-cycle fatigue tests were conducted on 16 types of simulated HAZ specimens that had been prepared using thermal processes. The results showed the fatigue S-N curves of the HAZ to be widely scattered as a function of strength level. These fatigue data were divided into two groups: coarse grain (CG) and fine grain (FG) HAZ, when strain amplitude was used to represent S-N curves. The fatigue data for the CGHAZ group showed a relatively short fatigue life. Based on surface observations, the initiated fatigue crack size of CGHAZ was larger than that of FGHAZ as a function of microstructural unit size. Hence, fatigue crack growth life, which is almost the same as total fatigue life of CGHAZ, decreased. K E Y W O R D Sfatigue, heat affected zone, low-carbon steel, welding

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“…Cyclic yield stresses were estimated by fitting the peak stresses of the hysteresis curves to a Ramberg‐Osgood type equation by linear regression:

ε_{a} = ε_{el} + ε_{pl} = \frac{σ_{a}}{E} + {(\frac{σ_{a}}{C})}^{\frac{1}{n}},

Section: Resultssupporting

confidence: 66%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Effect of microstructure of simulated heat‐affected zone on low‐ to high‐cycle fatigue properties of low‐carbon steels

Nishikawa

Furuya

Igi³

et al. 2020

Fatigue Fract Eng Mat Struct

Self Cite

View full text Add to dashboard Cite

show abstract

“…With the continuous improvement of aviation equipment reliability and life index, the ultra-high-cycle-fatigue (10 7 ~10 12 cycles) problem has attracted increasingly more attention, and has become the focus of fatigue research [ 1 , 2 , 3 , 4 , 5 ]. Ultra-high-cycle fatigue belongs to micro-scale fatigue, which differs from traditional high-cycle fatigue (10 5 ~10 7 cycles) not only in the life length, but also in the more complex crack initiation and initial propagation mechanism, and also in the great difference due to different materials [ 6 , 7 , 8 ]. Titanium alloys have become the most widely used metal materials in the modern aviation industry because of their high specific strength, low density, excellent corrosion resistance, and good heat resistance, and the ultra-high-cycle fatigue problems are also the most prominent.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study on Forged TC4 Titanium Alloy Fatigue Properties under Three-Point Bending and Life Prediction

Wang

2021

Materials

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Ultrasonic fatigue tests of TC4 titanium alloy equiaxed I, II and bimodal I, II obtained by different forging processes were carried out in the range from 105 to 109 cycles using 20 kHz three-point bending. The results showed that the S-N curves had different shapes, there was no traditional fatigue limit, and the bimodal I had the best comprehensive fatigue performance. The fracture morphology was analyzed by SEM, and it was found that the fatigue cracks originated from the surface or subsurface facets, showing a transgranular quasi-cleavage fracture mechanism. EDS analysis showed that the facets were formed by the cleavage of primary α grains, and the fatigue cracks originated from the primary α grain preferred textures, rather than the primary α grain clusters. From the microstructure perspective, the reasons for better equiaxed high-cycle-fatigue properties and better bimodal ultra-high-cycle-fatigue properties were analyzed. The bimodal I fatigue life prediction based on energy was also completed, and the prediction curve was basically consistent with the experimental data.

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Digital Methods for the Fatigue Assessment of Engineering Steels

Fliegener,

Rosenberger,

Luke

et al. 2024

Adv Eng Mater

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Engineering steels are used for a wide range of applications in which their fatigue behavior is a crucial design factor. The fatigue properties depend on various influencing factors such as chemical composition, heat treatment, surface properties, load parameters, microstructure, and others. During product development, various material characterization and qualification experiments are mandatory. For a faster and more cost‐efficient development, data driven methods (machine learning) promise to replace or to complement material testing by prediction of the fatigue strength. With an ontology‐based, semantically‐linked knowledge graph, representing the manufacturing history of the material, the influence of the parameters of the process chain on the resulting properties can be accounted for. Herein, it is shown how a fatigue database containing a wide range of materials is assembled from literature. After postprocessing and curation of the data, machine learning predictions of mechanical properties are discussed under multiple aspects. A domain ontology is defined, containing the relevant class definitions for the use case. After applying a data integration and mapping workflow, it is shown how the data can be systematically queried using knowledge graphs describing the manufacturing history of the materials.

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Catalogue of NIMS fatigue data sheets

Cited by 30 publications

References 135 publications

Effect of microstructure of simulated heat‐affected zone on low‐ to high‐cycle fatigue properties of low‐carbon steels

Effect of microstructure of simulated heat‐affected zone on low‐ to high‐cycle fatigue properties of low‐carbon steels

Experimental Study on Forged TC4 Titanium Alloy Fatigue Properties under Three-Point Bending and Life Prediction

Digital Methods for the Fatigue Assessment of Engineering Steels

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