Investigation of the Very High Cycle Fatigue (VHCF) Behavior of Austenitic Stainless Steels and Their Welds for Reactor Internals at Ambient Temperature and 300°C

Daniel, Tobias; Smaga, Marek; Beck, Tilmann; Schopf, Tim; Stumpfrock, Ludwig; Weihe, Stefan; Rudolph, Jürgen

doi:10.1115/pvp2020-21460

Cited by 4 publications

(7 citation statements)

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“…Cyclic hardening effects are reproduced with phenomenological approaches and adapted by using mathematical methods and best‐fit algorithms. Therefore, an AFC material model with three backstresses (Chaboche parameters C 1–3 , γ 1–3 ) was applied (see Table 4), and for more details, see literature 23,27,28 . Plasticity initiates when stress passes over σ y0 (yield stress at zero plastic strain).…”

Section: Resultsmentioning

confidence: 99%

“…For this, the converter transforms an electrical signal from the ultrasonic generator into a high‐frequency mechanical oscillation. Using a booster, which amplifies the oscillation depending on its geometry, the mechanical oscillation is transferred to the specimen 22,23 …”

Section: Methodsmentioning

confidence: 99%

“…Using a booster, which amplifies the oscillation depending on its geometry, the mechanical oscillation is transferred to the specimen. 22,23 All parts of the system were designed to assure that under resonance conditions, a standing wave develops along the load axis with a maximum displacement amplitude at the specimen ends and maximum stress-strain amplitude in the center of the gauge length of the specimen (see Figure 4). Due to the strong self-heating of the investigated material, the specimens were loaded in pulse-pause mode, which limits the maximum specimen temperature during cyclic loading.…”

Section: Vhcf Testsmentioning

confidence: 99%

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Fatigue behavior and lifetime assessment of an austenitic stainless steel in the VHCF regime at ambient and elevated temperatures

Schopf

Weihe

Daniel

et al. 2023

Fatigue Fract Eng Mat Struct

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While the LCF behavior of austenitic steels used in nuclear power plants is already well investigated, the VHCF regime has not been characterized in detail so far. For this, fatigue tests on the metastable austenitic steel AISI 347/1.4550 were performed with a servo‐hydraulic testing system at test frequencies up to 980 Hz and with an ultrasonic fatigue testing system at a test frequency of 20,000 Hz. To compare these test results to the ASME standard fatigue curve (total strain amplitude vs. load cycles to failure), a fictitious‐elastic and an elastically plastic assessment method was used. The elaborated elastic–plastic assessment method generates good results, while a purely elastic assessment in the VHCF regime, commonly used in literature, leads to significantly nonconservative results. Moreover, phase transformation from metastable austenite into stable α′‐martensite can take place, and no specimen failure occurs in the VHCF regime. Consequently, for this material, a real endurance limit exists.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Vhcf Testsmentioning

confidence: 99%

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Fatigue behavior and lifetime assessment of an austenitic stainless steel in the VHCF regime at ambient and elevated temperatures

Schopf

Weihe

Daniel

et al. 2023

Fatigue Fract Eng Mat Struct

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show abstract

“…The fatigue test started with 40 ms pulse and 3000 ms pause duration, which corresponds to an effective test frequency of f eff,1 ≈260 Hz. Since the metastable austenitic steel AISI 347 shows pronounced cyclic hardening caused by deformation induced α′-martensite formation, pulse-pause ratios of up to 60 ms/1800 ms become possible after sufficiently high cycle numbers [ 20 ]. Thus, the effective frequency can be increased to f eff,2 ≈ 390 Hz and eventually to f eff,3 = f eff,4 ≈ 650 Hz.…”

Section: Methodsmentioning

confidence: 99%

“…Thus, the effective frequency can be increased to f eff,2 ≈ 390 Hz and eventually to f eff,3 = f eff,4 ≈ 650 Hz. To maintain a constant mode and displacement amplitude of the vibration under these circumstances, the generator voltage and the proportional and integral (PI) control parameters have to be adapted during the test [ 20 , 21 ]. After the measurement at N = 10 8 cycles, the PI parameters were adjusted without changing the effective frequency (f eff,3 = f eff,4 ≈ 650 Hz).…”

Section: Methodsmentioning

confidence: 99%

Detection of Microstructural Changes in Metastable AISI 347, HSS Z-M4 and Tool Steel Ferrotitanit WFN by Mechanical Loss Coefficient at Ultrasonic Frequencies

et al. 2022

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Ultrasonic processes such as ultrasonic welding or ultrasonic fatigue testing use power ultrasound to stimulate materials with amplitudes in the range of 1–100 µm. The ultrasonic welding process is sensitive to any changes in the system or even the environment that may result in lower joint quality. The welding tools, so called sonotrodes, have to be accurately designed to endure high mechanical and thermal loads while inducing a sufficient amount of welding energy into the joining zone by oscillation with the Eigenfrequency of the whole system. Such sonotrodes are often made of thermally treated metals where the heat treatment is accompanied by microstructural changes. During ultrasonic stimulation, the material may further change its properties and microstructure due to cyclic loading. Both are expected to be recognized and identified by loss coefficients. Therefore, the loss coefficient was determined by modal analysis of rods and fatigue specimen made of different materials to correlate microstructural changes to attenuation. The determined loss coefficients indicated microstructural changes in all materials investigated, confirming results from previous investigations that showed an increasing attenuation due to cyclic loading for AISI 347. For the sonotrode materials Z-M4 PM and Ferrotitanit WFN, the loss coefficients decreased due to thermal treatments. Technically most relevant, changes in elastic modulus due to thermal treatments were quantitatively related to frequency changes, which can significantly simplify future sonotrode development.

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Cyclic deformation behavior of metastable austenitic stainless steel AISI 347 in the VHCF regime at ambient temperature and 300 °C

Daniel¹,

Smaga²,

Beck³

2022

International Journal of Fatigue

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Investigation of the Very High Cycle Fatigue (VHCF) Behavior of Austenitic Stainless Steels and Their Welds for Reactor Internals at Ambient Temperature and 300°C

Cited by 4 publications

References 0 publications

Fatigue behavior and lifetime assessment of an austenitic stainless steel in the VHCF regime at ambient and elevated temperatures

Fatigue behavior and lifetime assessment of an austenitic stainless steel in the VHCF regime at ambient and elevated temperatures

Detection of Microstructural Changes in Metastable AISI 347, HSS Z-M4 and Tool Steel Ferrotitanit WFN by Mechanical Loss Coefficient at Ultrasonic Frequencies

Cyclic deformation behavior of metastable austenitic stainless steel AISI 347 in the VHCF regime at ambient temperature and 300 °C

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