Your search keyword '"fatigue failure mechanism"' showing total 34 results

1. Contact fatigue performance and failure mechanisms of Fe-based small-module gears fabricated using powder metallurgy technique

Author

Zehua Lu, Dong Wei, Peitang Wei, Huaiju Liu, Huan Yan, Shuixin Yu, and Guanyu Deng

Subjects

Fe-based small-module gear, Powder metallurgical technique (PMT), Contact fatigue performance, Fatigue failure mechanism, Subsurface crack propagation, Mining engineering. Metallurgy, TN1-997

Abstract

Gears fabricated using powder metallurgy technique (PMT) have the potential to replace traditional wrought gears due to their very high forming efficiency and relatively low cost. However, their practical applications are restricted due to the lack of understanding of their fatigue properties and failure mechanisms. This work investigates the contact fatigue performance and corresponding failure mechanism of a typical Fe-based small-module gears fabricated by PMT. The fatigue tests were conducted under grease lubrication condition, using a power-opened small-module gear testing rig. The experimental results show that the current PMT fabricated small-module gears exhibit contact fatigue properties comparable to those of traditional wrought steel gears. It has been found that the subsurface cracks induced from pores are the dominant cause of spalling of PMT fabricated small-module gears during rolling contact. The cracks tend to propagate between adjacent pores, playing a vital role in the overall fatigue life. Thus, this study suggests that PMT can be a successful method for fabricating Fe-based small-module gears with excellent contact fatigue property if formation of pores during fabrication is well inhibited.

Published

2023

2. Editorial: Machining technology and environmental degradation mechanism of surface microstructure of special materials, volume II

Author

Guijian Xiao

Subjects

material surface processing technology, fatigue failure mechanism, reproduction technology, grinding, surface integrity, Technology

Published

2023

3. Fatigue Behavior of Rotary Friction Welding of Acrylonitrile Butadiene Styrene and Polycarbonate Dissimilar Materials.

Author

Kuo, Chil-Chyuan, Gurumurthy, Naruboyana, and Hunag, Song-Hua

Subjects

*FRICTION welding, *FATIGUE life, *ACRYLONITRILE, *BUTADIENE, *STYRENE, *ACRYLONITRILE butadiene styrene resins, *MATERIAL fatigue, *POLYCARBONATES, *CYCLIC loads

Abstract

Understanding the fatigue behaviors of weld joints is significant in engineering practice. Rotary friction welding (RFW) can join the additively manufactured polymer components. Until now, no research has focused on the fatigue behavior of polymer components jointed via RFW. This study investigates the fatigue life of ABS/PC dissimilar components fabricated via RFW and proposes the fatigue mechanism based on the failure structure. This work uses five different cyclic loads and rotational speeds to investigate the fatigue life. The fatigue life of the RFW of ABS/PC dissimilar rods is better compared with the pure ABS and pure PC specimens due to weld and integrity microstructural changes resulting from the combination of ABS and PC materials. The number of cycles until the rupture of RFW of ABS/PC dissimilar components (y) can be determined by the cyclic load (x) according to the prediction equation of y = −838.25x2 − 2035.8x + 67,262. The fatigue life of the RFW of ABS/PC dissimilar components increase with the increased rotational speed. The number of cycles until rupture (y) can be determined by the different rotational speeds (x) according to the prediction equation of y = 315.21x2 + 2710.4x + 32,124. [ABSTRACT FROM AUTHOR]

Published

2023

4. Fatigue properties of resistance spot‐welded maraging steel produced by selective laser melting.

Author

Shi, Yandong, Luo, Cheng, Li, Wenkai, Shi, Liting, Zhang, Yansong, and Su, Xuming

Subjects

*FATIGUE limit, *MARAGING steel, *SELECTIVE laser melting, *SPOT welding, *STRAINS & stresses (Mechanics), *WELDING equipment

Abstract

This research study investigates the fatigue properties of resistance spot welds (RSWs) made from selective laser‐melted (SLMed) maraging steel (MS1) and compares them with dual‐phase (DP) steel RSWs. The findings reveal that MS1 spot welds exhibit superior fatigue properties compared with DP steel RSWs, regardless of the printing orientation of the MS1 substrate. Furthermore, fatigue fracture occurs at the MS1 substrate, with a transition of fracture location observed from MS1 to itself and MS1‐to‐DP600 dissimilar welds. The results of structural stress analysis indicate that the weld nugget diameter is not the only factor affecting the fatigue life. The study also highlights the importance of considering materials inhomogeneity and fracture modes in fatigue life assessment. Based on the findings, the study recommends the development of a new fatigue life prediction curve for spot welds of additive manufacturing (AM) materials. Such a curve would be beneficial in promoting the further application of AM technology for functional parts of design verification vehicles (DCV) and production cars. Overall, the research contributes to the understanding of the fatigue properties of RSWs made from SLMed MS1 and DP steel, which has implications for the design and manufacturing of parts in the automotive industry. Highlights: SLMed MS1 RSWs showed superior fatigue properties compared with DP600‐DP600 spot welds.Softening occurred at weld nugget for MS1‐MS1 RSWs while at HAZ of MS1 for MS1‐DP600 RSWs.Fatigue fracture occurred in MS1 steel for MS1‐DP600 RSWs due to the defects in MS1 sheets.The lower constant m for MS1 than that of other steels explained different fatigue life. [ABSTRACT FROM AUTHOR]

Published

2023

5. Effects of the microstructure on the fatigue fracture of friction stir lap welded Al-clad Al and Al-clad steel sheets

Author

Kun Gao, Soumyabrata Basak, Shengwei Zhang, Sung-Tae Hong, Stephen Yeboah Boakye, and Hoon-Hwe Cho

Subjects

Friction stir lap welding, AA4343-Clad AA3003, AA1050-Clad mild steel, Si distribution, Fatigue failure mechanism, Mining engineering. Metallurgy, TN1-997

Abstract

The microstructural characteristics and mechanical properties of friction stir lap welding (FSLW) of thin Al-clad Al (1.5 mm) and ultra-thin Al-clad mild steel (0.7 mm) sheets are experimentally investigated. Optical microscopic observation confirms that the FSLW joints are successfully fabricated without noticeable joining defects, such as cracks and hooks. The material flow is correlated with the silicon (Si) element distribution in the stir zone (SZ). The distribution of Si indicates that material flow is asymmetrical between the advancing side (AS) and the retreating side (RS) of the SZ. The tensile test result shows that all the FSLW joints fracture from the Al-clad Al side of the joints. During the fatigue tests, two different crack propagation modes (vertical crack in the Al-clad Al loading side; horizontal crack in the Al-clad mild steel loading side) are observed simultaneously due to the combined effect of the asymmetric geometry of the FSLW joint and the different loading configurations. The results of fatigue tests suggest that the asymmetric microstructure of the joint retards the propagation of a vertical crack in the Al-clad Al loading side for the RS-loaded FSLW joint. As a result, the fatigue life of the RS-loaded FSLW joint becomes clearly higher than that of the AS-loaded FSLW joint.

Published

2023

6. Recent developments in cold dwell fatigue of titanium alloys for aero-engine applications: a review

Author

Zhihong Wu, Hongchao Kou, Nana Chen, Zhicheng Xi, Jiangkun Fan, Bin Tang, and Jinshan Li

Subjects

Cold dwell fatigue, Titanium alloys, Fatigue failure mechanism, Aero gas turbine engines, Rogue grain pair, Dislocation, Mining engineering. Metallurgy, TN1-997

Abstract

Cold dwell fatigue of titanium alloys used in aero-engine components has threatened flight safety for over five decades. This phenomenon was encountered in Al-containing titanium alloys, occurring at relatively low temperatures, where load hold at applied peak stress result in reduction in number of cycles by an order of magnitude or more (the so-called dwell debit). The present paper reviews the recent advances in dwell-fatigue of titanium alloys with the primary motivation being to understand the dwell-fatigue damage mechanism relating microstructural configurations, dislocations and local strain rate sensitivity. Numerous studies have focused on the identification of fatigue-critical microstructural configurations, such as microtextured regions, rogue grain pairs and (0001) twist grain boundaries. As an example of dwell resistant alloy design, Timetal 575 is a candidate alloy for aero-engine fan disc applications with both superior static and cyclic strengths and low dwell sensitivity.

Published

2022

7. Friction stir welding of AA3003-clad AA6013 thin sheets: Microstructural changes related to tensile properties and fatigue failure mechanism

Author

Kun Gao, Soumyabrata Basak, Mounarik Mondal, Shengwei Zhang, Sung-Tae Hong, Stephen Yeboah Boakye, and Hoon-Hwe Cho

Subjects

Friction stir welding, Al-clad material, Tensile properties, Fatigue failure mechanism, Mining engineering. Metallurgy, TN1-997

Abstract

The microstructure, tensile properties, and fatigue behavior of friction stir welding (FSW) joints of multilayer AA3003-clad AA6013 are experimentally investigated. Linear butt welding is performed using a concave tool equipped with a columnar threaded pin at a rotating speed of 600 rpm and a transverse speed of 200 mm/min. The microstructures of FSW joints were observed using a field emission scanning electron microscope equipped with an electron backscatter diffraction system and an energy dispersive spectrometer. The microstructural characterization in the stir zone (SZ) reveals grain refinement, precipitate refinement, zigzag line, and the AA3003-clad layer fragments due to material mixing. The tensile test result of all-weld joints shows that the tensile strength of the SZ is significantly higher than that of base metal, while the cross-weld joints show a typical ductile fracture in the base metal. The result of fatigue tests shows that all the cross-weld joints fracture from the SZ. Analysis of the fatigue failure mechanism indicates that the crack causing the fatigue fracture originates from the AA3003-clad layer fragments in the advancing side of the SZ. The fatigue analysis also confirms that surface roughness and zigzag line are not the cause of the final fatigue fracture of the cross-weld joint for the present study.

Published

2022

8. Fatigue Behavior of Rotary Friction Welding of Acrylonitrile Butadiene Styrene and Polycarbonate Dissimilar Materials

Author

Chil-Chyuan Kuo, Naruboyana Gurumurthy, and Song-Hua Hunag

Subjects

rotary friction welding, fatigue life, fatigue failure mechanism, number of cycles to rupture, rotational speed, cyclic load, Organic chemistry, QD241-441

Abstract

Understanding the fatigue behaviors of weld joints is significant in engineering practice. Rotary friction welding (RFW) can join the additively manufactured polymer components. Until now, no research has focused on the fatigue behavior of polymer components jointed via RFW. This study investigates the fatigue life of ABS/PC dissimilar components fabricated via RFW and proposes the fatigue mechanism based on the failure structure. This work uses five different cyclic loads and rotational speeds to investigate the fatigue life. The fatigue life of the RFW of ABS/PC dissimilar rods is better compared with the pure ABS and pure PC specimens due to weld and integrity microstructural changes resulting from the combination of ABS and PC materials. The number of cycles until the rupture of RFW of ABS/PC dissimilar components (y) can be determined by the cyclic load (x) according to the prediction equation of y = −838.25x2 − 2035.8x + 67,262. The fatigue life of the RFW of ABS/PC dissimilar components increase with the increased rotational speed. The number of cycles until rupture (y) can be determined by the different rotational speeds (x) according to the prediction equation of y = 315.21x2 + 2710.4x + 32,124.

Published

2023

9. Crack Initiation Mechanism and Life Prediction of Ti60 Titanium Alloy Considering Stress Ratios Effect in Very High Cycle Fatigue Regime.

Author

He, Ruixiang, Peng, Haotian, Liu, Fulin, Khan, Muhammad Kashif, Chen, Yao, He, Chao, Wang, Chong, Wang, Qingyuan, and Liu, Yongjie

Subjects

*HIGH cycle fatigue, *TITANIUM alloys, *FATIGUE limit, *FATIGUE cracks, *FATIGUE life, *CRACK initiation (Fracture mechanics)

Abstract

Ultrasonic fatigue tests were performed on Ti60 titanium alloy up to a very high cycle fatigue (VHCF) regime at various stress ratios to investigate the characteristics. The S-N curves showed continuous declining trends with fatigue limits of 400, 144 and 130 MPa at 109 cycles corresponding to stress ratios of R = −1, 0.1 and 0.3, respectively. Fatigue cracks found to be initiated from the subsurface of the specimens in the VHCF regime, especially at high stress ratios. Two modified fatigue life prediction models based on fatigue crack initiation mechanisms for Ti60 titanium alloy in the VHCF regime were developed which showed good agreement with the experimental data. [ABSTRACT FROM AUTHOR]

Published

2022

10. Three-dimensional nonlinear vibration model and fatigue failure mechanism of deepwater test pipe.

Author

Guo, Xiaoqiang, Nie, Yuxin, Liu, Jun, He, Yufa, Mao, Liangjie, Wang, Guorong, and Dai, Liming

Abstract

In deepwater test condition, the riser–test pipe (tubing string) system (RTS) is subject to the vortex-induced effect on riser, flow-induced effect on test pipe and longitudinal/transverse coupling effect, which is prone to buckling deformation, fatigue fracture and friction perforation. To resolve this, the three-dimensional (3D) nonlinear vibration model of deepwater RTS is established using the micro-finite method, energy method and Hamilton variational principle. Based on the elastic–plastic contact collision theory, the nonlinear contact load calculation method between riser and test pipe is proposed. Compared with experimental measurement results, calculation results using the proposed vibration model in this study and the single tubing vibration model in our recent work, the correctness and effectiveness of the proposed vibration model of the deepwater RTS are verified. Meanwhile, the cumulative damage theory is used to establish the fatigue life prediction method of test pipe. Based on that, the influences of outflow velocity, internal flow velocity, significant wave height, as well as top tension coefficient on the fatigue life of test pipe are systematically analyzed. The results demonstrate that, first, with the increase in outflow velocity, the maximum alternating stress and the annual fatigue damage rate increased. The location where fatigue failure of the test pipe is easy to occur at the upper "one third" and the bottom of test pipe are easy to occur fatigue failure. Second, with the increase in internal flow velocity, the "one third damage effect" of the test pipe will decrease, and the "bottom damage effect" of the test pipe increased that needs the attention of field operators. Third, during field operation, it is necessary to properly configure the top tension coefficient so that there can be a certain relaxation between the riser and the test pipe, so as to cause transverse vibration and consume some axial energy and load. The study led to a theoretical method for safety evaluation and a practical approach for effectively improving the fatigue life of deepwater test pipe. [ABSTRACT FROM AUTHOR]

Published

2022

11. Control of fatigue failure mechanisms in multilayer coatings by varying the architectural parameters of an intermetallic interlayer.

Author

Lu, Songsong, Cook, Richard, Zhang, Yi, and Reed, Philippa

Subjects

*MECHANICAL behavior of materials, *MULTILAYERED thin films, *SURFACE coatings, *SURFACE cracks, *SURFACE resistance, *SYSTEM failures, *MENTAL fatigue

Abstract

A multilayer overlay coating system containing an intermediate intermetallic layer is an architecture expected to show good fatigue resistance. Experimental characterization and modeling simulations were carried out to classify the different crack initiation mechanisms occurring during fatigue of this coating system (2IML coating system) and to reveal how changes in the layer architecture lead to fatigue improvement. Surface crack initiation seems to play the dominated role in the fatigue failure of this coating system as over 55% of observed cracks were surface cracks. Fatigue improvement is achieved by increasing surface initiation resistance via decreasing the IML‐Top layer thickness. However, subsurface initiation mechanisms inhibit the improvement (dominated by surface initiation mechanism) achieved by locating the IML‐Top layer closer to the top surface. Optimizing the design of 2IML multilayer coatings based on the fatigue performance should eliminate the unreacted nickel layer in the intermediate IML‐Top layer, increase the subsurface interface strength, and decrease the density of voids occurring in the annealing process. Highlights: Mechanical properties of materials in layered coatingsFatigue failure mechanisms in layered coatings composed by harder and softer materialsEffect of each mechanism on fatigue performance with varying architectural parameters [ABSTRACT FROM AUTHOR]

Published

2022

12. Quantitative analysis of performance degradation in movable MEMS devices by a multiscale approach.

Author

Cheng, Jiaxing, Chen, Xuanyi, Li, Zhaoxia, Lu, Junxi, and Liu, Bangjian

Subjects

*QUANTITATIVE research, *MOLECULAR dynamics, *MEMS resonators, *MANUFACTURING processes, *FINITE element method, *HARDY spaces

Abstract

• The multi-scale computational model for the long-term service performance degradation of movable MEMS devices is established by integrating finite element and molecular dynamics methods. • The modeling location for molecular dynamics needs to select an appropriate unit to ensure temporal and spatial consistency with the finite element method. • The developed method can discern the influence patterns of microstructural changes on long-term service performance, providing optimized strategies for material processing and design. The rapid advancements in AI and 5G/6G communication technologies have intensified the demand for MEMS devices characterized by exceptional performance and diversity. Simultaneously, the imperative for enduring stability in these devices has become increasingly critical. Unforeseen reliability issues pose substantial challenges to the full-scale application of these advanced MEMS devices, underscoring the importance of understanding their failure mechanisms. Presently, there is a scarcity of comprehensive research in reliability computation and analysis. In this study, we adopt cross-scale damage variables as a nexus, linking responses across three scales: material, structural, and performance. We implement a synergistic finite element-molecular dynamics approach for multiscale analysis. Using a prototypical MEMS resonator structure as a case study, we establish quantitative interrelations among these three scales, enabling precise depiction of atomic failure behavior and its impact on resonant frequency degradation. This approach offers an atomically grounded explanation for the fundamental material processes underlying frequency degradation. Our numerical analyses explore the failure mechanisms responsible for the frequency degradation in MEMS resonators. Additionally, we propose several optimized strategies for the design and preparation phases aimed at enhancing fatigue performance. These findings are particularly relevant in light of the growing necessity for devices that maintain long-term stability. [ABSTRACT FROM AUTHOR]

Published

2024

13. Crack Initiation Mechanism and Life Prediction of Ti60 Titanium Alloy Considering Stress Ratios Effect in Very High Cycle Fatigue Regime

Author

Ruixiang He, Haotian Peng, Fulin Liu, Muhammad Kashif Khan, Yao Chen, Chao He, Chong Wang, Qingyuan Wang, and Yongjie Liu

Subjects

very high cycle fatigue, Ti60 titanium alloy, fatigue failure mechanism, fatigue life prediction, fatigue strength prediction, stress ratio, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Ultrasonic fatigue tests were performed on Ti60 titanium alloy up to a very high cycle fatigue (VHCF) regime at various stress ratios to investigate the characteristics. The S-N curves showed continuous declining trends with fatigue limits of 400, 144 and 130 MPa at 109 cycles corresponding to stress ratios of R = −1, 0.1 and 0.3, respectively. Fatigue cracks found to be initiated from the subsurface of the specimens in the VHCF regime, especially at high stress ratios. Two modified fatigue life prediction models based on fatigue crack initiation mechanisms for Ti60 titanium alloy in the VHCF regime were developed which showed good agreement with the experimental data.

Published

2022

14. Fatigue failure mechanism of duplex stainless steel welded joints including role of heterogeneous cyclic hardening/softening: Experimental and modeling.

Author

Dong, Zhilong, Xie, Xue-fang, Jiang, Wenchun, Niu, Ruiyan, Wan, Yu, Zhai, Xiangnan, and Zhao, Xu

Subjects

*STAINLESS steel welding, *MATERIAL fatigue, *STRAINS & stresses (Mechanics), *DIGITAL image correlation, *STAINLESS steel, *DUPLEX stainless steel

Abstract

• The correlation among heterogeneous microstructure, cyclic hardening/softening and fatigue failure behavior was analyzed extensively. • The fracture location was changed with the fatigue amplitude due to the amplitude-dependent and heterogeneous cyclic hardening/softening of BM and WM. • A modified cyclic constitutive model was proposed to precisely predict the heterogeneous cyclic mechanical response and failure location for both stress-controlled and strain-controlled conditions. This work performed experimental and modeling investigations on the fatigue failure mechanism of duplex stainless steel welded joints, and the correlation among heterogeneous microstructure, cyclic hardening/softening and fatigue failure behavior was analyzed extensively. A series of experiments including the characterization of microstructure by the electron back-scattered diffraction observation and fatigue mechanical tests assisted by digital image correlation technique were performed. The results show that at the lower stress amplitudes (approximately 520 MPa), the fatigue failure occurred in the weld metal, while it shifted to the base metal at higher amplitudes. Due to the grain refinement, the strain amplitude of weld metal was lower than that of base metal, particularly at the higher amplitudes, leading to the final failure at the base metal. However, at the lower amplitudes, due to the effect of Kurdjumov-Sachs orientation relationship at the weld metal, its cyclic softening behavior was much drastic than that of base metal, resulting in the overshoot of strain amplitude during fatigue process and finial rupture at the weld metal. A cyclic constitutive model was developed by considering the amplitude-dependent and heterogeneous cyclic hardening/softening, to accurately predict the cyclic mechanical response and fatigue failure location for both stress-controlled and strain-controlled conditions. This work can be used as guidance of structure integrity assessment and life prediction for the engineering components of duplex stainless steel. [ABSTRACT FROM AUTHOR]

Published

2024

15. Effect of fiber orientation distribution on constant fatigue life diagram of chopped carbon fiber chip-reinforced Sheet Molding Compound (SMC) composite.

Author

Tang, Haibin, Chen, Zhangxing, Zhou, Guowei, Sun, Xuze, Li, Yang, Huang, Li, Guo, Haiding, Kang, Hongtae, Zeng, Danielle, Engler-Pinto, Carlos, and Su, Xuming

Subjects

*FATIGUE life, *CARBON fibers, *FIBER orientation, *CYCLIC fatigue, *MATERIAL fatigue, *FAILURE mode & effects analysis

Abstract

• Fatigue behavior of SMC composites under different stress ratios has been tested. • Correlation between fiber orientation and fatigue behavior is observed. • Fatigue failure mechanisms are analyzed through microstructure characterization. • Constant fatigue life diagram of SMC is established with fiber orientation tensor. The material behavior of chopped carbon fiber chip-reinforced Sheet Molding Compound (SMC) composite is investigated under both quasi-static and cyclic fatigue loading conditions in the present study. Quasi-static tensile and compressive strength data is collected, followed by a series of fatigue tests under three different cyclic loading conditions, i.e., Tension-Tension (T-T), Compression-Compression (C-C), and Tension-Compression (T-C). The experimental results show a considerable amount of variation for each loading condition, which is found to be induced by the spatial distribution of fiber orientation within the tested specimens. An analytical approach is developed to correlate the fatigue performance of the SMC material with the local modulus, which is determined by the fiber orientation distribution. Additionally, the similar failure modes are observed under different loading conditions. Based on these findings, a new form of Constant Fatigue Life (CFL) diagram is established in which the impact of fiber orientation tensor to the fatigue behavior of SMC is considered. This developed CFL diagram is examined by comparing the measured fatigue performance with prediction where local fiber orientation distribution is quantified from microscopic images. [ABSTRACT FROM AUTHOR]

Published

2019

16. Effect of carbon nanotubes modification on bending fatigue properties of carbon fiber reinforced polyimide composites.

Author

Liu, Yue, Li, Jikang, Kuang, Yue, Liu, Zheng, Zhang, Zhe, and Chen, Xu

Subjects

*MATERIAL fatigue, *FATIGUE limit, *CARBON nanotubes, *CARBON fibers, *AEROSPACE materials, *CONSTRUCTION materials, *FIBROUS composites

Abstract

• Carbon fiber fabric reinforced polyimide composites (CF/PI) were modified by carbon nanotubes (CNTs). • Both monotonic bending and bending fatigue behavior of CNTs modified CF/PI were investigated at room temperature. • The CNTs filler could inhibit crack initiation and retard crack propagation. • The fatigue resistance is significantly enhanced in CNTs modified CF/PI. Polyimide-based composites have been widely used as structural materials in aerospace and automotive industries. In the present work, carbon fiber fabric reinforced polyimide composites (CF/PI) were modified by carbon nanotubes (CNTs). The monotonic bending properties and bending fatigue performance of CNTs modified CF/PI were investigated at room temperature. Both bending strength and bending modulus of CF/PI can be increased by CNTs. The CNTs filler could inhibit crack initiation and retard crack propagation. The fatigue resistance is significantly enhanced in CNTs modified CF/PI, which is related to the CNTs enhanced matrix crack resistance and fiber/matrix debonding. [ABSTRACT FROM AUTHOR]

Published

2023

17. Fatigue failure mechanism of Ti60 titanium alloy in HCF and VHCF regime at different temperatures.

Author

Chen, Chao-Lin, Shang, De-Guang, Tang, Zhi-Qiang, Li, Dao-Hang, Yin, Xiang, and Guo, Yi-Er

Subjects

*TITANIUM alloys, *HIGH cycle fatigue, *ALLOY fatigue, *FATIGUE cracks, *HIGH temperatures

Abstract

• Subsurface failure is in the form of oversized facet formed by α p phase cluster cleavage. • The oxide shedding causes the surface failure at high temperature. • Higher temperature and stress make the oxide shedding failure mechanism dominant. The failure mechanism of Ti60 titanium alloy in the high cycle fatigue (HCF) and very high cycle fatigue (VHCF) at different temperatures was investigated. The results showed that, at different temperatures, there are two different fatigue failure mechanisms, i.e., the oversized facet and oxide shedding failure mechanisms. At room temperature, most of the fatigue cracks initiate at the oversized facet. At 300℃, the crack initiates at the oversized facet for the test with small applied stress, while the crack initiates at the oxide shedding site for the test with large applied stress. At 400℃, all the fatigue cracks initiate at the oxide shedding site. Higher temperature and stress will be conducive to the failure mechanism of oxide shedding to become dominant. [ABSTRACT FROM AUTHOR]

Published

2023

18. Effect of structural details on the fatigue failure of welded hollow spherical joints under uniaxial tension.

Author

JI Yanling, LEI Honggang, and JIAO Jinfeng

Subjects

FUSION zone (Welding), STRESS concentration, FATIGUE cracks, STEEL tubes, MATERIAL fatigue

Abstract

In order to understand the fatigue failure mechanism of welded hollow spherical joints, a formula of the stress concentration coefficient Kt about α=d/D and β=t/T was deduced based on ANSYS finite element software. The results show that the stress concentration coefficient increases with the diameter D of the hollow sphere and the thickness t of the wall of the steel tube. It also decreases with the diameter d of the steel tube and the wall thickness T of the hollow sphere. The stress concentration coefficient decreases with the increase of a and increases with the increase of β. Fatigue cracks arise from the stress concentration at the fusion zone of the weld, which is the starting point of fatigue failure. Stress concentration is the main reason for the low fatigue strength of welded hollow ball joints. [ABSTRACT FROM AUTHOR]

Published

2018

19. Low-cycle fatigue testing and thermal fatigue life prediction of electroplated copper thin film for through hole via.

Author

Watanabe, Kazuki, Kariya, Yoshiharu, Yajima, Naoyuki, Obinata, Kizuku, Hiroshima, Yoshiyuki, Kikuchi, Shunichi, Matsui, Akiko, and Shimizu, Hiroshi

Subjects

*THERMAL fatigue, *FATIGUE life, *MATERIAL fatigue, *ELECTROPLATING, *THIN films

Abstract

A new fatigue test method was proposed for low-cycle fatigue lives of electroplated copper thin films for the through hole (TH) in a printed wiring board. And the low-cycle fatigue lives were investigated according to the proposed method. Furthermore, thermal stress analysis of the TH with the finite element method was performed to predict thermal fatigue life of the TH based on Manson-Coffin law for electroplated copper thin films obtained from the low-cycle fatigue test. Low-cycle fatigue damage in the electroplated copper thin film was occurring in the grain boundaries and the damage mechanism was found same as that for thermal fatigue damage in TH in the printed wiring board. And the fatigue life of TH predicted from the Manson-Coffin law at the maximum temperature of thermal fatigue test was good agreement with the thermal fatigue life obtained from the experimental result of thermal fatigue test. [ABSTRACT FROM AUTHOR]

Published

2018

20. The effects of temperature and stress on the high-cycle fatigue properties of a Ni-based wrought superalloy.

Author

Chen, Yipeng, Kong, Weiwen, Yuan, Chao, Liu, Shuai, Cai, Yong, Wang, Yongqiang, and Gao, Xinyu

Subjects

*FATIGUE limit, *ALLOY fatigue, *SURFACE defects, *TEMPERATURE effect, *HEAT resistant alloys, *HIGH cycle fatigue, *FATIGUE cracks

Abstract

[Display omitted] • The fatigue strength at 107 cycles of GH4742 alloy increases with increasing of temperatures. • The high cycle fatigue fracture mode is surface defect fracture at room temperature. • At 650 °C and 750 °C, the high cycle fatigue fracture mode is the subsurface, and the surface defects and internal or surface crystallographic planes. • The deformation mechanism is mainly governed by APBs shearing and Orowan bypassing. The high-cycle fatigue behavior of the wrought superalloy GH4742 was studied at room-temperature (RT), 650 °C and 750 °C. The fatigue strength at 107 cycles of the GH4742 alloy increases with increasing temperature, which is mainly due to the different fracture modes at different temperatures. Fatigue cracks at room temperature originate from the specimen surface, including surface inclusions, surface carbides, surface slip and surface crystallographic facets. At 650 °C and 750 °C, the fatigue crack initiations originate from the subsurface or internal crystallographic planes under lower stress levels, while the surface defects or surface crystallographic planes originate under higher stress levels. The dislocation density of the GH4742 superalloy is low at room temperature and 650 °C, and the deformation mechanism is mainly governed by APBs shearing primary γ′ and Orowan bypassing secondary and tertiary γ′. When the temperature rises to 750 °C, the deformation mechanism is mainly governed by stacking faults shearing primary, secondary and tertiary γ′. Furthermore, antiphase boundaries (APBs) shearing primary γ′ and Orowan bypassing secondary and tertiary γ′ occur. [ABSTRACT FROM AUTHOR]

Published

2023

21. Experimental investigation on fatigue strength of joints between SRC beams and concrete-filled RHS columns.

Author

Xian, Qingjun, Tong, Lewei, Zhou, Liying, and Chen, Yiyi

Abstract

Fatigue behavior, failure mechanism and fatigue strength of joints between steel reinforced concrete (SRC) beams and Concrete Filled Rectangular Hollow Section (CFRHS) columns is discussed in this paper. Three identical beam-to-column joint specimens were designed and tested under static loading and two stages of fatigue loading. In the first stage of fatigue loading, the specimens were subjected to design fatigue load for 2 million cycles, while during the second stage, they were loaded to failure under increased fatigue load in order to know failure mechanism and fatigue strength. It is found that the joints satisfied design requirements when subjected to static loading and design fatigue loading. Fatigue failure occurred after these joints were applied higher-level fatigue loading. The crack initiated at the weld toe of stud or stirrup hole in the upper flange of I-shaped steel in certain SRC beam, and then it propagated along flange width in winding trajectory until fatigue fracture occurred. Stress amplitude of tension flange in SRC beam can be regarded as the parameter representing fatigue strength of the joints. S-N curves in related codes are selected to evaluate fatigue strength of the joints. The design method is suggested to consider fatigue design of the joints. [ABSTRACT FROM AUTHOR]

Published

2017

22. Low cycle fatigue behavior of wire arc additive manufactured and solution annealed 308 L stainless steel

Author

Yajing Li, Yutong Yuan, Dexin Wang, Sichao Fu, Danrong Song, Maurizio Vedani, and Xu Chen

Subjects

Additive manufacturing, Austenitic stainless steel, Wire arc additive manufacturing, Low cycle fatigue, Biomedical Engineering, Fatigue failure mechanism, General Materials Science, Engineering (miscellaneous), Industrial and Manufacturing Engineering

Published

2022

23. Influence of heat treatment on fatigue performances for self-piercing riveting similar and dissimilar titanium, aluminium and copper alloys.

Author

Zhang, Xianlian, He, Xiaocong, Xing, Baoying, Zhao, Lun, Lu, Yi, Gu, Fengshou, and Ball, Andrew

Subjects

*HEAT treatment, *METAL fatigue, *COPPER alloys, *RIVETING machines, *TITANIUM alloys, *SCANNING electron microscopy

Abstract

The fatigue performances of self-piercing riveting (SPR) joints connecting similar and dissimilar sheets of TA1 titanium alloy (TA1), Al5052 aluminium alloy (Al5052) and H62 copper alloy (H62) were studied in this paper. The specimens of similar TA1 sheets treated with stress relief annealing were prepared to investigate the influence of relief annealing on the mechanical properties of SPR joints. Fatigue tests were conducted to characterize the fatigue lives and failure modes of the joints. Scanning electron microscopy (SEM) was employed to determine the fatigue failure mechanisms of the joints. The results showed that stress relief annealing has an apparent impact on the fatigue performances but has little influence on the static strengths of the joints. For SPR joints in similar or dissimilar sheets, joints between similar TA1 sheets possess the best fatigue resistance, which are significantly higher than the joints in dissimilar sheets. In addition, most of the joints failed in the rivet and the locked sheet through fatigue tests, except the joints between TA1 and Al5052, which failed only in the locked sheets. [ABSTRACT FROM AUTHOR]

Published

2016

24. Experimental investigation of mixed mode I–II fatigue crack propagation in concrete using a digital image correlation method.

Author

Jia, Mengdi, Wu, Zhimin, Yu, Rena C., and Zhang, Xiaoxin

Subjects

*CONCRETE fatigue, *FATIGUE cracks, *DIGITAL image correlation, *CRACK propagation (Fracture mechanics), *CRACKING of concrete, *DEAD loads (Mechanics), *DIGITAL images

Abstract

• The COD, CSD, crack width, and the crack propagation length for mixed mode I–II fatigue crack have been continuously captured with the DIC method. • The tortuous mixed mode I–II fatigue crack propagation path has been visualized using the DIC method. • The DIC method is an effective way to measure the complete mixed mode I–II fatigue crack propagation in concrete. The propagation of fatigue cracks leads to the degradation of the load-carrying capacity of concrete structures and even fatigue failure. An in-depth investigation of the fatigue crack propagation process is essential to reveal the fracture mechanism and further assess the safety of concrete structures. This paper presents an experimental study of mixed mode I–II fatigue crack propagation in concrete. Fatigue tests are conducted on three-point bending (TPB) beams with an off-center initial crack with different fatigue load levels. The digital image correlation (DIC) method is employed to observe the complete fatigue crack propagation process, and the method is verified to be applicable. The results indicate that the mixed mode I–II fatigue crack propagation process can be divided into three stages, namely, the rapid propagation in the initial stage, a stable propagation stage, and the final fast propagation until unstable failure. The mixed mode I–II crack propagation path under static loading is a good approximation of that under fatigue loading. The results also show that the crack tip opening displacement (CTOD), crack tip sliding displacement (CTSD), mode I stress intensity factor (SIF), and mode II SIF corresponding to the unstable failure of the TPB beam are approximately constant and independent of the fatigue load level. In particular, the negligible CTSD and mode II SIF demonstrate that the mixed mode I–II fatigue failure of concrete is dominated by the mode I component. [ABSTRACT FROM AUTHOR]

Published

2022

25. Fatigue failure mechanism of 2205 duplex stainless steel using the neutron diffraction and EBSD technologies.

Author

Zhang, Weiya, Song, Ming, Jiang, Wenchun, Sun, Guangai, Shan, Guangbin, Chen, Mindong, and Bai, Yongzhong

Subjects

*NEUTRON diffraction, *DUPLEX stainless steel, *STAINLESS steel, *AUSTENITE, *ELECTRON diffraction, *GRAIN size

Abstract

• The fatigue failure mechanism of 2205 duplex stainless steel is clarified. • The austenite takes a dominant role in LCF regime while the ferrite takes a dominant role in HCF regime. • The evolutions of kernel average misorientation, grain size and textures are revealed. • The relationship of macroscopic fracture and microscopic deformation has been developed. This paper researched the fatigue failure mechanism of 2205 duplex stainless steel (DSS) by neutron diffraction and electron back-scattered diffraction measurement (EBSD) in mesoscopic scale. The results show that the fatigue strength of DSS is rather larger than single-phase stainless steel. The austenite is prone to deform due to mechanical properties difference between ferrite and austenite, and the transgranular and intergranular fracture mode is in austenite grains while the transgranular is mainly in ferrite grains. The relationship between macroscopic fracture and microscopic deformation is clarified by evolutions of kernel average misorientation (KAM), grain size and textures of ferrite and austenite. [ABSTRACT FROM AUTHOR]

Published

2022

26. Enhanced synergy of strength-ductility and low-cycle fatigue resistance of high-entropy alloy through harmonic structure design.

Author

Zhang, Zhe, Zhai, Xinyu, Chen, Gang, Chen, Xu, and Ameyama, Kei

Subjects

*FATIGUE limit, *MECHANICAL alloying, *INHOMOGENEOUS materials, *STRAIN hardening, *ALLOYS

Abstract

Compared with homogeneous structured materials, heterogeneous structured materials exhibit unprecedented performances. In the present work, a series of harmonic structured CoCrFeMnNi high-entropy alloys (HEAs) with different shell fractions were prepared by mechanical milling (MM) and spark plasma sintering (SPS) process. The effects of shell fraction on mechanical properties and low-cycle fatigue (LCF) performances were investigated at room temperature. Results show that the harmonic structured HEAs with a shell fraction between 20% and 40% demonstrate a combination of superior strength-ductility synergy and good LCF resistance. Development and rearrangement of dislocations dominantly occur in the coarse-grained areas (cores) during LCF process, while the ultrafine-grained areas (shells) show good cyclic stability. The enhanced strain hardening leads to a good balance of high strength and high ductility in the harmonic structured HEAs. Moreover, the enhanced ductility also restrains LCF failure. Graphical Abstract [Display omitted]. [ABSTRACT FROM AUTHOR]

Published

2022

27. Fatigue behavior and failure mechanism of steel-concrete composite deck slabs with perforated ribs.

Author

Xiang, Da, Gu, Minjie, Zou, Xiaojie, and Liu, Yuqing

Subjects

*STEEL-concrete composites, *FINITE element method, *CONSTRUCTION slabs, *CONCRETE slabs, *CRACK initiation (Fracture mechanics), *CONCRETE fatigue, *CRACK propagation (Fracture mechanics), *FATIGUE cracks

Abstract

• The fatigue failure process and composite action of steel-concrete composite deck slab are experimentally studied. • Effects of load amplitude and loading sequence on fatigue response are discussed. • The multiaxial stress state of the weld region is revealed using a verified finite element model. • Fatigue crack initiation position is assessed by the critical plane approach. • Effects of structural parameters and shear-span ratio on fatigue damage parameters are clarified. This paper aims at investigating the variable-amplitude fatigue behavior and failure mechanism of the steel-concrete composite (SCC) deck slab with perforated ribs. Firstly, two identical full-scale specimens were tested under different fatigue loading procedures. Test results reveal that the fatigue failure process starts with the initiation of cracks at the welding part between the steel plate and perforated rib, after which the slab could sustain tens or hundreds of thousands of load cycles until the crushing of concrete. As load amplitude increases by 54%, the crack propagation rate is accelerated by 300%, and the fatigue life from the crack initiation to the crushing of concrete is reduced by 79%. Higher load amplitude applied in the earlier service stage leads to the irreversible and a higher level of degradation on the stiffness, deformation recovery, and composite action. Further, the finite element (FE) model is established and verified, through which the stress state of the welding part is analyzed. It reveals that owing to the shear transfer between the steel members and concrete layer, the welding part is in the multiaxial stress condition where longitudinal normal stress, vertical normal stress, and shear stress coexist. Subsequently, the crack initiation position is predicted using the critical plane approach based on the SWT parameter, which shows good consistency with experimental results. Finally, by conducting the parametric analysis, the effects of geometric parameters and shear-span ratio on the SWT parameter of the welding part are clarified. [ABSTRACT FROM AUTHOR]

Published

2022

28. Research on the fatigue failure behavior of 1Cr17Ni2 blades ground by abrasive belt with passivation treatment.

Author

Huang, Yun, Li, Shaochuan, Xiao, Guijian, Chen, Benqiang, He, Yi, and Song, Kangkang

Subjects

*PASSIVATION, *ABRASIVES, *FATIGUE life, *CRACK initiation (Fracture mechanics), *VIBRATION tests, *GRAIN, *MICROSTRUCTURE

Abstract

• Passivation treatment of abrasive belt can effectively improve surface integrity of aero-engine blades. • The passivated abrasive belt grinding can promote the grain refinement and microstructure homogenization of the machined surface. • Blade of passivated abrasive belt grinding can suppress the initiation of fatigue cracks on the surface and prolong fatigue life of aero-engine blades. • An anti-fatigue grinding method with blunt grinding and slow feed was proposed. As precision machining process of aero-engine blades, the surface integrity after abrasive belt grinding closely related to its fatigue resistance. In order to explore new anti-fatigue abrasive belt grinding methods, reveal the influence mechanism of blade surface integrity on anti-fatigue performance, and provide guidance for the anti-fatigue grinding, vibration fatigue tests were carried out on blades processed by different grinding process, and the effects of abrasive belt passivation treatment and feed speed on blade surface integrity and fatigue life were studied. Fatigue failure behavior of blades processed by different processes were also discussed from the fracture morphology and cross-section analysis. Results showed that blades processed by blunt grinding have different fatigue failure mechanisms, and the passivation treatment of abrasive belt and low feed speed can improve the surface integrity and fatigue life of aero-engine blades. The combination process of abrasive belt passivation treatment and slow feed speed were proposed for anti-fatigue grinding processing of aero-engine blades. In this research, compared with blades processed by new abrasive belt with feed speed 1000 mm/min, the fatigue life of blades processed by passivated abrasive belt at feed speed 100 mm/min was increased by 3.1 times. [ABSTRACT FROM AUTHOR]

Published

2021

29. Fatigue failure mechanism of 3D tubing strings used in high-pressure, high-temperature and high-yield curved gas wells.

Author

Guo, Xiaoqiang, Li, Xiao, Liu, Jun, Dai, Liming, Huang, Liang, Wei, Anchao, and Zhang, Xiaohong

Subjects

*TUBES, *GAS wells, *VARIATIONAL principles, *MATERIAL fatigue, *FATIGUE life, *FATIGUE testing machines, *SOUND design

Abstract

• A 3D-FINV model of tubing strings is established and verified by a similar experiment. • A cumulative damage theory is used to establish the fatigue life prediction method. • The fatigue failure mechanism of tubing string in 3H curved wells is elucidated. • The safety control methods of tubing string are proposed. In view of the fatigue failure of tubing strings by flow-induced nonlinear vibration (FINV) in high-temperature, high-pressure and high-yield (3H) curved gas wells, a three-dimensional (3D) FINV model of the tubing string is established using the micro-finite method, energy method and Hamilton variational principle, and verified by a similar experiment of tubing vibration. Meanwhile, the cumulative damage theory is used to establish the fatigue life prediction method of tubing string combined with the stress response which was determined by the proposed FINV model and the S-N curve of the tubing material (13Cr-L80) which was measured by fatigue test. Thus, the influences of production rate, well trajectory parameters (inclination angle and well section length), as well as the installation position of downhole tools (packer and centralizer) on the fatigue life of the tubing string are systematically analyzed. The results obtained demonstrate that, first, with the increase of production rate, the fatigue life of the tubing string decreases, and the field production allocation should be far away from the sudden production rate which can be determined using the proposed analysis method. Second, in the well trajectory design, the vertical section length should be reduced, while that of build-up section and the angle of stable inclined section should be increased. Third, the packer and centralizer should be placed in the optimal position, which depends on the well structure, downhole tool size, etc. and can be determined using the proposed analysis method. The research results provide a theoretically sound guidance for designing and practically sound approach for effectively improving the fatigue life of tubing string in 3H curved gas wells. [ABSTRACT FROM AUTHOR]

Published

2021

30. Coexistence of two distinct fatigue failure mechanisms in Super304H welded joint at elevated temperatures.

Author

Song, Geun Dong, Hwang, Jeong Ho, Kim, Dae-Woong, Park, Byong Chon, Hahn, Junhee, and Hong, Seong-Gu

Subjects

*HIGH temperatures, *STRAINS & stresses (Mechanics), *WELDED joints, *WELDING, *STRUCTURAL reliability, *MENTAL fatigue

Abstract

Super304H steel is a promising candidate for boiler tube materials in thermal power plants operating under ultra-supercritical conditions, and the fatigue properties of its welded joint play a key role in the structural reliability of the thermal power plants. Herein, we report that there is a transition in the fatigue failure location (i.e., fatigue failure mechanism) from the base metal at a high strain amplitude (≥~0.4%) to the weld metal at a low strain amplitude (≤~0.3%) at a constant temperature in the operating range of 500–700 °C, and this leads to a significant reduction in the fatigue resistance of the welded joint as compared to that of the base metal. We found that a longer fatigue test time at a low strain amplitude induces a thermal aging effect that promotes different microstructural evolutions in the base metal and weld metal, deepening material inhomogeneity in the welded joint, and thereby triggering strain localization in the weld metal. With increasing fatigue test time (i.e., thermal aging time), Cr 23 C 6 carbides precipitated in the interdendritic region of the weld metal and at the austenitic grain boundary of the base metal, and Nb (C, N) phases precipitated in the interior of austenitic grain in the base metal, which increased local hardness, whereas there was no significant microstructural change in the dendrite core of the weld metal, retaining its initial hardness. The intensified local hardness inhomogeneity caused the softest zone in the welded joint, wherein strain localization occurred, serving as a crack nucleation site and propagation path, to shift from the base metal to the weld metal (dendrite core). This induced a shift in the fatigue failure location from the base metal to the weld metal with decreasing strain amplitude. • Two distinct fatigue failure mechanisms coexisting at elevated temperatures. • Transition in fatigue failure location from base metal to weld metal at low strain amplitude. • It induced a significant reduction in fatigue resistance of the welded joint. • Different microstructural evolutions in base metal and weld metal by thermal aging. • It caused intensified local hardness inhomogeneity and strain localization in weld metal. [ABSTRACT FROM AUTHOR]

Published

2021

31. Mechanismy únavového poškození niklové superslitiny Inconel 713LC za teploty 800°C

Author

Hutařová, Simona, Juliš, Martin, Smékalová, Jana, Hutařová, Simona, Juliš, Martin, and Smékalová, Jana

Abstract

Niklové superslitiny jsou používány pro vysokoteplotní aplikace v energetickém a leteckém průmyslu. Jsou namáhány v agresivním prostředí za vysokých teplot při spolupůsobení únavových a creepových procesů, vysokoteplotní oxidace, koroze a eroze. Prodloužení životnosti takto namáhaných součástí a současné zvýšení výkonu jednotlivých zařízení je možné pomocí aplikace povrchových ochranných vrstev. Tato práce je zaměřena na zkoumání mechanismů únavového poškození superslitiny Inconel 713LC při teplotě 800 °C a porovnání těchto mechanismů u materiálu s ochrannou povrchovou vrstvou na bázi Al-Si a materiálu bez této vrstvy. Užitím optické mikroskopie, rastrovací elektronové mikroskopie a konfokální laserové rastrovací mikroskopie byly analyzovány iniciační místa únavových trhlin, způsob jejich šíření a v některých oblastech i rychlosti šíření únavových trhlin. Na základě předešlého výzkumu bylo zjištěno, že aplikace povrchové úpravy má pozitivní vliv na únavovou životnost slitiny Inconel 713LC. Tyto výsledky byly v práci potvrzeny a doplněny., Nickel superalloys are used for high-temperature application in energetic and aerospace industry. They are exposed to aggressive environment at high temperatures with the interactions between fatigue and creep processes, high-temperature oxidation, corrosion and erosion. Lifetime extension of such strained parts while increasing the performance of particular machine is possible by applying protective surface coatings. The subject of this work is to investigate the fatigue failure mechanisms of superalloy Inconel 713LC at 800 °C and to compare these mechanisms between material with a protective coating based on Al-Si and material without coating. The location of initiation fatigue cracks, their propagation and the fatigue crack propagation rate in some areas were analyzed by optical microscopy, scanning electron microscopy and confocal laser scanning microscopy. Based on previous research it was found that the application of the coating AlSi has a positive effect on lifetime of alloy Inconel 713LC. These results were confirmed and estimated in the diploma thesis.

32. Mechanismy únavového poškození niklové superslitiny Inconel 713LC za teploty 800°C

Author

Hutařová, Simona, Juliš, Martin, Smékalová, Jana, Hutařová, Simona, Juliš, Martin, and Smékalová, Jana

Abstract

Niklové superslitiny jsou používány pro vysokoteplotní aplikace v energetickém a leteckém průmyslu. Jsou namáhány v agresivním prostředí za vysokých teplot při spolupůsobení únavových a creepových procesů, vysokoteplotní oxidace, koroze a eroze. Prodloužení životnosti takto namáhaných součástí a současné zvýšení výkonu jednotlivých zařízení je možné pomocí aplikace povrchových ochranných vrstev. Tato práce je zaměřena na zkoumání mechanismů únavového poškození superslitiny Inconel 713LC při teplotě 800 °C a porovnání těchto mechanismů u materiálu s ochrannou povrchovou vrstvou na bázi Al-Si a materiálu bez této vrstvy. Užitím optické mikroskopie, rastrovací elektronové mikroskopie a konfokální laserové rastrovací mikroskopie byly analyzovány iniciační místa únavových trhlin, způsob jejich šíření a v některých oblastech i rychlosti šíření únavových trhlin. Na základě předešlého výzkumu bylo zjištěno, že aplikace povrchové úpravy má pozitivní vliv na únavovou životnost slitiny Inconel 713LC. Tyto výsledky byly v práci potvrzeny a doplněny., Nickel superalloys are used for high-temperature application in energetic and aerospace industry. They are exposed to aggressive environment at high temperatures with the interactions between fatigue and creep processes, high-temperature oxidation, corrosion and erosion. Lifetime extension of such strained parts while increasing the performance of particular machine is possible by applying protective surface coatings. The subject of this work is to investigate the fatigue failure mechanisms of superalloy Inconel 713LC at 800 °C and to compare these mechanisms between material with a protective coating based on Al-Si and material without coating. The location of initiation fatigue cracks, their propagation and the fatigue crack propagation rate in some areas were analyzed by optical microscopy, scanning electron microscopy and confocal laser scanning microscopy. Based on previous research it was found that the application of the coating AlSi has a positive effect on lifetime of alloy Inconel 713LC. These results were confirmed and estimated in the diploma thesis.

33. Mechanismy únavového poškození niklové superslitiny Inconel 713LC za teploty 800°C

Author

Hutařová, Simona, Juliš, Martin, Hutařová, Simona, and Juliš, Martin

Abstract

Niklové superslitiny jsou používány pro vysokoteplotní aplikace v energetickém a leteckém průmyslu. Jsou namáhány v agresivním prostředí za vysokých teplot při spolupůsobení únavových a creepových procesů, vysokoteplotní oxidace, koroze a eroze. Prodloužení životnosti takto namáhaných součástí a současné zvýšení výkonu jednotlivých zařízení je možné pomocí aplikace povrchových ochranných vrstev. Tato práce je zaměřena na zkoumání mechanismů únavového poškození superslitiny Inconel 713LC při teplotě 800 °C a porovnání těchto mechanismů u materiálu s ochrannou povrchovou vrstvou na bázi Al-Si a materiálu bez této vrstvy. Užitím optické mikroskopie, rastrovací elektronové mikroskopie a konfokální laserové rastrovací mikroskopie byly analyzovány iniciační místa únavových trhlin, způsob jejich šíření a v některých oblastech i rychlosti šíření únavových trhlin. Na základě předešlého výzkumu bylo zjištěno, že aplikace povrchové úpravy má pozitivní vliv na únavovou životnost slitiny Inconel 713LC. Tyto výsledky byly v práci potvrzeny a doplněny., Nickel superalloys are used for high-temperature application in energetic and aerospace industry. They are exposed to aggressive environment at high temperatures with the interactions between fatigue and creep processes, high-temperature oxidation, corrosion and erosion. Lifetime extension of such strained parts while increasing the performance of particular machine is possible by applying protective surface coatings. The subject of this work is to investigate the fatigue failure mechanisms of superalloy Inconel 713LC at 800 °C and to compare these mechanisms between material with a protective coating based on Al-Si and material without coating. The location of initiation fatigue cracks, their propagation and the fatigue crack propagation rate in some areas were analyzed by optical microscopy, scanning electron microscopy and confocal laser scanning microscopy. Based on previous research it was found that the application of the coating AlSi has a positive effect on lifetime of alloy Inconel 713LC. These results were confirmed and estimated in the diploma thesis.

34. Mechanismy únavového poškození niklové superslitiny Inconel 713LC za teploty 800°C

Author

Hutařová, Simona, Juliš, Martin, Hutařová, Simona, and Juliš, Martin

Abstract

Niklové superslitiny jsou používány pro vysokoteplotní aplikace v energetickém a leteckém průmyslu. Jsou namáhány v agresivním prostředí za vysokých teplot při spolupůsobení únavových a creepových procesů, vysokoteplotní oxidace, koroze a eroze. Prodloužení životnosti takto namáhaných součástí a současné zvýšení výkonu jednotlivých zařízení je možné pomocí aplikace povrchových ochranných vrstev. Tato práce je zaměřena na zkoumání mechanismů únavového poškození superslitiny Inconel 713LC při teplotě 800 °C a porovnání těchto mechanismů u materiálu s ochrannou povrchovou vrstvou na bázi Al-Si a materiálu bez této vrstvy. Užitím optické mikroskopie, rastrovací elektronové mikroskopie a konfokální laserové rastrovací mikroskopie byly analyzovány iniciační místa únavových trhlin, způsob jejich šíření a v některých oblastech i rychlosti šíření únavových trhlin. Na základě předešlého výzkumu bylo zjištěno, že aplikace povrchové úpravy má pozitivní vliv na únavovou životnost slitiny Inconel 713LC. Tyto výsledky byly v práci potvrzeny a doplněny., Nickel superalloys are used for high-temperature application in energetic and aerospace industry. They are exposed to aggressive environment at high temperatures with the interactions between fatigue and creep processes, high-temperature oxidation, corrosion and erosion. Lifetime extension of such strained parts while increasing the performance of particular machine is possible by applying protective surface coatings. The subject of this work is to investigate the fatigue failure mechanisms of superalloy Inconel 713LC at 800 °C and to compare these mechanisms between material with a protective coating based on Al-Si and material without coating. The location of initiation fatigue cracks, their propagation and the fatigue crack propagation rate in some areas were analyzed by optical microscopy, scanning electron microscopy and confocal laser scanning microscopy. Based on previous research it was found that the application of the coating AlSi has a positive effect on lifetime of alloy Inconel 713LC. These results were confirmed and estimated in the diploma thesis.