Low cycle fatigue performance of Ni-based superalloy coated with complex thermal barrier coating

“…e YSZ/CoNiCrAlY interface is a significant crack initiation source in specimens that are exposed to 900°C longer than 36 h. As the oxidation proceeds and the TGO scale reaches critical thickness, it is probable that the cracks at the YSZ/CoNiCrAlY interface would be initiated by an increase in the local stresses [33][34][35]. Similarly to our previous studies [17,36], fatigue crack initiation at BC/substrate interface was identified in the vicinity of embedded grit particles (Figure 4(a)). It was proven by Warnes et al [27] that elimination of these particles can improve fatigue life of coated MAR-M247 under thermomechanical loading by 40%.…”

“…Factors that contribute to the higher fatigue life of TEBC-coated MAR-M247 are (i) increased number of cracks in the TEBC-coated material in comparison with uncoated MAR-M247. is suppresses the localization of the plastic strain, and thus, the fatigue crack initiation and propagation can be longer [36,41]; (ii) corrosion and oxidation protection of materials that are employed in harsh Advances in Materials Science and Engineering environments is very important. However, corrosion and oxidation resistance of MAR-M247 is comparatively poor due to the relatively low content of chromium, and the unprotected surface of uncoated MAR-M247 degrades quickly [42].…”

“…e ratio increases with a decrease in the strain amplitude. e ratio (cracks that penetrate to the substrate-TEBC-coated to uncoated MAR-M247) of 2.18 and 6.3 corresponds to the highest and lowest strain amplitude, respectively [17,36].…”

High‐Temperature Low‐Cycle Fatigue Behaviour of MAR‐M247 Coated with Newly Developed Thermal and Environmental Barrier Coating

“…e YSZ/CoNiCrAlY interface is a significant crack initiation source in specimens that are exposed to 900°C longer than 36 h. As the oxidation proceeds and the TGO scale reaches critical thickness, it is probable that the cracks at the YSZ/CoNiCrAlY interface would be initiated by an increase in the local stresses [33][34][35]. Similarly to our previous studies [17,36], fatigue crack initiation at BC/substrate interface was identified in the vicinity of embedded grit particles (Figure 4(a)). It was proven by Warnes et al [27] that elimination of these particles can improve fatigue life of coated MAR-M247 under thermomechanical loading by 40%.…”

“…Factors that contribute to the higher fatigue life of TEBC-coated MAR-M247 are (i) increased number of cracks in the TEBC-coated material in comparison with uncoated MAR-M247. is suppresses the localization of the plastic strain, and thus, the fatigue crack initiation and propagation can be longer [36,41]; (ii) corrosion and oxidation protection of materials that are employed in harsh Advances in Materials Science and Engineering environments is very important. However, corrosion and oxidation resistance of MAR-M247 is comparatively poor due to the relatively low content of chromium, and the unprotected surface of uncoated MAR-M247 degrades quickly [42].…”

“…e ratio increases with a decrease in the strain amplitude. e ratio (cracks that penetrate to the substrate-TEBC-coated to uncoated MAR-M247) of 2.18 and 6.3 corresponds to the highest and lowest strain amplitude, respectively [17,36].…”

High‐Temperature Low‐Cycle Fatigue Behaviour of MAR‐M247 Coated with Newly Developed Thermal and Environmental Barrier Coating

“…In gas turbines, actual components are not submitted to pure creep loading. In fact, due to the start-up and shut-down operations, transient temperature gradients occur, giving rise to combined thermal and mechanical loading [ 95 ], and therefore to thermal mechanical fatigue (TMF) and low cycle fatigue (LCF) [ 95 , 96 ]. High-temperature LCF in nickel-based alloys under air results in the formation of a complex oxide layer and a reaction zone depleted of strengthening precipitates in the adjacent substrate as in creep [ 97 ].…”

“…LCF performance of Ni-based superalloy coated with YSZ conventional thermal barrier coating have been rarely investigated. As reported by Šulák et al [ 96 ], results on studies on LCF of YSZ coated Ni superalloys are a bit controversial, showing in some case a beneficial [ 179 ], an insignificant [ 180 ], or a detrimental effect [ 181 ] on the fatigue life. In their work, Šulák et al have investigated the effect of high-temperature (900 °C) LCF performance of a complex TBC-coated and uncoated Inconel 713LC sample.…”

Critical Raw Materials Saving by Protective Coatings under Extreme Conditions: A Review of Last Trends in Alloys and Coatings for Aerospace Engine Applications

A systematic review of the effects of deposition parameters on the properties of Inconel thin films