Initiation and early-stage growth of internal fatigue cracking under very-high-cycle fatigue regime at high temperature
Initiation and early-stage growth of internal fatigue cracking under very-high-cycle fatigue regime at high temperature
The initiation and early-stage crack growth under very-high-cycle fatigue (VHCF) at room temperature, 750 °C, and 850 °C on directionally solidified Ni-base superalloy have been investigated. There was little frequency effect of 20 kHz on fatigue lives when compared with 100 Hz, nor did the deformation and fracture mechanisms. Dislocation tangles re-arranged themselves to form well-defined networks at interface of γ/γ′, accounting for the enhanced fatigue strength at 850 °C in VHCF regime when compared to that at 750 °C. In most cases, internal casting pore was the crack initiation site. Crack initiation and early-stage growth occurred on one of the {111} planes or their intersecting planes, a characteristic of Stage I cracking. With the use of optimized intermittent loading conditions, both the initiation and early-stage crack growth processes were successfully tracked on the basis of fine but visible beach marks within the Stage I cracking region. The first registered fatigue beach mark can be as close as only 86 μm to the crack initiation site and the crack length increased steadily over the whole early-stage crack growth stage. The enhanced fatigue strength at 850 °C can be rationalized with the higher threshold for propagating the early-stage crack. The fraction of fatigue life consumed for early-stage crack growth reduces with the decreasing stress, eventually leading to the initiation-controlling VHCF fatigue failure. The implications of these results are discussed with respect to the model prediction of fatigue life and fatigue strength.
1575-1592
Zhao, Z.
abe04e3a-01ec-4488-8c57-62543ac8109d
Zhang, F.
396ca776-f0e6-4750-974a-6ba3f9c78a41
Dong, C.
a7841829-e336-4111-96e4-55b6e99ff492
Yang, X.
aa9fef47-6ada-44e9-9239-3109f37f1638
Chen, B.
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
21 January 2020
Zhao, Z.
abe04e3a-01ec-4488-8c57-62543ac8109d
Zhang, F.
396ca776-f0e6-4750-974a-6ba3f9c78a41
Dong, C.
a7841829-e336-4111-96e4-55b6e99ff492
Yang, X.
aa9fef47-6ada-44e9-9239-3109f37f1638
Chen, B.
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
Zhao, Z., Zhang, F. and Dong, C.
,
et al.
(2020)
Initiation and early-stage growth of internal fatigue cracking under very-high-cycle fatigue regime at high temperature.
Metallurgical and Materials Transactions A, 51, .
(doi:10.1007/s11661-020-05633-3).
Abstract
The initiation and early-stage crack growth under very-high-cycle fatigue (VHCF) at room temperature, 750 °C, and 850 °C on directionally solidified Ni-base superalloy have been investigated. There was little frequency effect of 20 kHz on fatigue lives when compared with 100 Hz, nor did the deformation and fracture mechanisms. Dislocation tangles re-arranged themselves to form well-defined networks at interface of γ/γ′, accounting for the enhanced fatigue strength at 850 °C in VHCF regime when compared to that at 750 °C. In most cases, internal casting pore was the crack initiation site. Crack initiation and early-stage growth occurred on one of the {111} planes or their intersecting planes, a characteristic of Stage I cracking. With the use of optimized intermittent loading conditions, both the initiation and early-stage crack growth processes were successfully tracked on the basis of fine but visible beach marks within the Stage I cracking region. The first registered fatigue beach mark can be as close as only 86 μm to the crack initiation site and the crack length increased steadily over the whole early-stage crack growth stage. The enhanced fatigue strength at 850 °C can be rationalized with the higher threshold for propagating the early-stage crack. The fraction of fatigue life consumed for early-stage crack growth reduces with the decreasing stress, eventually leading to the initiation-controlling VHCF fatigue failure. The implications of these results are discussed with respect to the model prediction of fatigue life and fatigue strength.
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Published date: 21 January 2020
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Local EPrints ID: 489903
URI: http://eprints.soton.ac.uk/id/eprint/489903
ISSN: 1073-5623
PURE UUID: 945442c7-cecc-4def-afe0-3e0e4e157aee
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Date deposited: 07 May 2024 16:42
Last modified: 08 May 2024 02:08
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Z. Zhao
Author:
F. Zhang
Author:
C. Dong
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X. Yang
Author:
B. Chen
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