Showing total 17 results

1. Asphalt concrete crack propagation parameters from XFEM modelling of the Texas Overlay Test.

Author

Alrashydah, Esra'a and Papagiannakis, A.T.

Subjects

*ASPHALT concrete, *CRACKING of concrete, *CRACK propagation (Fracture mechanics), *CRACK closure, *FINITE element method, *FATIGUE crack growth, *STRESS intensity factors (Fracture mechanics)

Abstract

Paris' power law is commonly used to describe transverse thermal cracking propagation in asphalt concrete (AC) pavements. In its most common format, it relates the rate of change in the crack length per cycle to changes in either the stress intensity factor K or the energy release. The parameters defining this relationship for ACs can be obtained using the Texas cyclic Overlay Test (OTR). This paper describes two numerical approaches for simulating the OTR using the extended finite element method (XFEM). The first uses the direct low-cyclic fatigue (LCF) approach and the second uses the virtual crack closure technique (VCCT). Comparisons of the model predictions to laboratory OTR measurements for six mixtures suggest that the XFEM model coupled with VCCT is better suited for simulating the OTR. The model output includes the crack length and the energy release rate ERR (i.e. ${\rm \Delta }J_R$ Δ J R ) as cracks propagate. This data was used to fit the modified Paris' law parameters ${A}^{\prime}$ A ′ and ${n}^{\prime}$ n ′ as a function ${\rm \Delta }J_R$ Δ J R . Subsequently, the traditional A and n Paris' power law parameters were fitted by estimating the corresponding ΔK. Using this model, it was possible to efficiently estimate the AC cracking parameters using as input only the tensile modulus and the critical ERR. [ABSTRACT FROM AUTHOR]

Published

2023

2. Fatigue crack growth characterization of composite-to-steel bonded interface using ENF and 4ENF tests.

Author

Feng, Weikang, Arouche, Marcio Moreira, and Pavlovic, Marko

Subjects

*FRACTURE mechanics, *CRACK closure, *FINITE element method, *DIGITAL image correlation, *SHEAR strain, *FATIGUE crack growth, *FATIGUE cracks

Abstract

• Mode II fatigue crack growth is characterized at the steel-to-composite interface. • Displacement and load controlled ENF and 4ENF test methods are compared. • Novel method is proposed to determine crack growth by shear strains from DIC. • Friction and geometrical non-linearity is considered by finite element models. In this paper, mode II fatigue crack growth properties of the composite-to-steel interface are characterised through different test configurations, namely ENF and 4ENF tests. Different loading types including force control and displacement control methods are compared. An innovative shear strain based method is proposed for monitoring the mode II crack growth at the bi-material interface through Digital Image Correlation (DIC). A 3D finite element model with Virtual Crack Closure Technique (VCCT) is built and used for obtaining the strain energy release rate (SERR) to investigate the effect of geometrical nonlinearity, friction at the interface and steel yielding, as well as to verify the mode mixity. The results show that the standard 3-point bending ENF specimen can be unstable under force control and sweeps narrow SERR range by a single test under displacement control. The 4-point bending 4ENF test shows stable crack propagation and clear SERR developing trend. More pronounced geometrical nonlinearity and friction effect exist for 4ENF test which can be considered when interpreting the Paris curves by a nonlinear finite element model. [ABSTRACT FROM AUTHOR]

Published

2024

3. Research on crack propagation of CRTS III track slabs under train load.

Author

Chen, Wei, Zhang, Yushuo, Li, Dongbai, Pan, Zili, and Lou, Ping

Subjects

*CRACK propagation (Fracture mechanics), *CONSTRUCTION slabs, *FRACTURE mechanics, *FINITE element method, *FRACTURE toughness, *FATIGUE crack growth, *STRESS intensity factors (Fracture mechanics)

Abstract

• The CRTS Ⅲ slab track model with prefabricated cracks is established by extended finite element method. • The stress intensity factors (SIFs) at the tips of cracks on the track slab under train load are solved. • The effects of the crack length and depth on the SIFs of three types of cracks are discussed. • The variations of crack growth rate calculated by Paris' semi-empirical during service are analyzed. Microcracks may occur in Chinese Railway Track System type III (CRTS III) ballastless track slabs during service, and it is necessary to investigate their potential propagation under train load, which could lead to slab deterioration and affect the durability of the track structure. In this paper, based on the fracture mechanics theory, the stress intensity factors (SIFs) at the tips of transverse crack, longitudinal crack and vertical crack on the CRTS III track slabs under train load are solved by the extended finite element method (XFEM) in Abaqus software. The changes of SIFs at the crack tips during the passage of the train are analyzed, and the effects of the crack length and depth on the SIFs of the three types of cracks are discussed under train load. Crack growth rate is calculated using Paris' semi-empirical law to estimate slab life. The results show that the train load contributes to the propagation of transverse and vertical cracks in the vertical direction and inhibits the longitudinal cracks. When the middle of the sixth vehicle is above the crack, the SIFs at the tips of the crack reach their maximum values. The SIF of vertical cracks exceeds the fracture toughness at a certain depth. The fatigue load cycles calculated by Paris' semi-empirical law suggest that maintenance will not be required due to insufficient propagation under train load during service. [ABSTRACT FROM AUTHOR]

Published

2024

4. Maximum volume ellipsoid vessels under cyclic pressure and mass constraints: LEFM-based design criteria.

Author

Abdalla, Hassan Mohamed Abdelalim, Sowiński, Krzysztof, and Casagrande, Daniele

Subjects

*LINEAR elastic fracture mechanics, *STRAINS & stresses (Mechanics), *FRACTURE mechanics, *FINITE element method, *ELLIPSOIDS, *STRUCTURAL shells

Abstract

The paper deals with an optimization problem related to axisymmetric membrane shells made of homogeneous, linear and isotropic materials and subject to a cyclic internal pressure. The optimization problem considers the possible crack growth in the shell as a structural constraint, which is accounted for by the well-known Paris law, and hence obeys the Linear Elastic Fracture Mechanics (LEFM) principles. The design variables are the meridian shape and the thickness distribution along the axis of the shell. After recalling the general background on the mechanics of thin-walled shells, the optimization problem is stated, formulated and solved in closed form by means of Pontryagin's Principle, showing two LEFM-based design criteria capable to help the designer in selecting the desired elastic performance through which the shell undergoes. It is shown that the derived optimal solutions are ellipsoids with variable thicknesses, whose distributions depend on the mass constraint and the applied pressure. Nevertheless, the optimal shapes guarantee the uniformity of either the meridian or the hoop stress, and such uniformity has been verified within a numerical example by an accurate finite element analysis. • The maximum volume problem for axisymmetric membrane shells is formulated. • The shells are subject to cyclic pressure and mass constraints. • The membrane theory of shells and Paris law are taken into consideration. • Optimal shapes are derived analytically by means of Pontryagin's Principle. • Two design criteria are given for uniform meridian and hoop membrane stresses. • The finite element method confirms the theoretical stress behavior. [ABSTRACT FROM AUTHOR]

Published

2023

5. Crack propagation and fatigue life estimation of spur gear with and without spalling failure.

Author

Singh Raghav, Mahendra and Patel, Shivdayal

Subjects

*SPUR gearing, *FATIGUE crack growth, *CRACK propagation (Fracture mechanics), *FATIGUE life, *FATIGUE cracks, *DAMAGE models, *SEPARATION (Law), *FINITE element method

Abstract

• The Johnson-cook damage model, traction separation and Paris law equations are incorporated in the XFEM model to predict the formation of spalling, crack propagation and fatigue life for the spur gear respectively. • 3D finite element analysis was performed to determine the fatigue life of the spur gear using with and without spall using different crack lengths and backup ratio. • Numerical modeling of spur gear developed and results showed that the increase in backup ratio from 0.3 to 3.3, an exponential increase in the fatigue life with and without spall. • The spalling depth obtained on the spur gears with backup ratio 0.3, 0.5, 1.0, and 3.3 are within the range of 20–100 μm. Spur gears are most commonly used to transmit power, and speed variation from one shaft to another shaft. Spalling more frequently occurs surface fault in the gears and sometimes it causes severe damage to the gear tooth. This paper focuses on the effect of spalling on the fatigue life of spur gear. The simulation study is conducted in two parts. In the first part, the Johnson-Cook Damage model is used for the spall generation on the tooth surface. After that, the spalling results are imported as input into the crack initiation /crack propagation model and calculated the rate of crack growth of fatigue crack is based on Paris law implemented in user-defined subroutine Abaqus software. User-defined subroutine code is also validated with the comparison of the numerical and experimental results available in the literature. Cracks with different initial lengths are placed in the deeper cavities of spalling and the crack propagation analysis is conducted using XFEM. The study is conducted for four different backup ratios with cracks of three different initial lengths. The fatigue crack growth life of spur gears is investigated using different crack lengths and backup ratios. Further, a comparison has been made between the fatigue life of a spur having a spalling fault with the fatigue life of spur gear that does not have spalling fault present on its surface. It has also been found in this study that spur gear having cracks originating from the spall region have a less fatigue life as compared to the spur gear without spalling. With the increase in backup ratio from 0.3 to 3.3, an exponential increase in fatigue life is observed. However, the fatigue life of spur gear without the presence of spalling fault has higher fatigue for all backup ratios. [ABSTRACT FROM AUTHOR]

Published

2023

6. Influence of fillet end geometry on fatigue behaviour of welded joints.

Author

da Silva, António L.L., Correia, José A.F.O., de Jesus, Abílio M.P., Lesiuk, Grzegorz, Fernandes, António A., Calçada, Rui, and Berto, Filippo

Subjects

*FATIGUE crack growth, *NOTCH effect, *WELDED joint fatigue

Abstract

Highlights • A fatigue analysis of a type of fillet welded joint is presented. • Four welded joint series for evaluating the fatigue performance were produced. • The fatigue behaviour combines an experimental campaign and numerical analysis. • In this fatigue analysis two main numerical tools – FEM and XFEM – were used. • Fatigue predictions based on crack initiation and propagation phases were made. Abstract This paper presents a fatigue analysis of a type of fillet welded joint representative of one main joint of the steel box girder of the Alcácer do Sal railway bridge. From previous studies, it was found that the welded joint between the box girder diagonal and the central hanger gusset is one of the most stressed details of the bridge. This welded joint was not fully manufactured according to current construction procedures, as regards the fillet weld end configuration. In order to assess the fatigue behaviour of such welded joint, the present study combines an experimental campaign and numerical analysis. A total of four welded joint series were produced in order to allow the comparison of the fatigue performance of similar type of welded joint of the Alcácer do Sal bridge with welded joints produced according to existing recommendations, such as EC3. Since scale-down specimens were considered, two different thicknesses were included in this study for each joint configuration, to allow the verification of any thickness effect. Concerning the numerical analyses, two main numerical tools were used: the standard Finite Element Method (FEM) with ANSYS and the eXtended Finite Element Method (XFEM) with ABAQUS. Fatigue life predictions were performed including both fatigue crack initiation and fatigue crack propagation phases. The number of cycles to initiate a fatigue crack was computed using local notch strain-life approaches, and the number of cycles for fatigue crack propagation was computed by integrating the Paris fatigue crack growth law with stress intensity factors computed with ANSYS (virtual crack closure technique) and ABAQUS (contour integral method, 3D XFEM model). Experimental tests demonstrated little influence of fillet weld end geometry on fatigue behaviour of welded joints and plate thickness effects were also reduced as also confirmed by the similar fatigue crack propagation rates. Both numerical simulations provided very accurate predictions of the experimental S-N curves, however the XFEM modelling opens new possibilities for mix-mode fatigue crack propagation simulations. [ABSTRACT FROM AUTHOR]

Published

2019

7. Experimental and computational assessment of disbond growth and fatigue life of bonded joints and patch repairs for primary airframe structures.

Author

Tanulia, Veldyanto, Wang, John, Pearce, Garth M., Baker, Alan, Chang, Paul, and Gangadhara Prusty, B.

Subjects

*REPAIRING, *AIRFRAMES, *FATIGUE life, *FRACTURE mechanics, *FATIGUE testing machines, *MATERIAL fatigue, *FINITE element method, *COST control

Abstract

• Implementation of slow growth design strategy for bonded joints/patch repairs for primary aircraft structures, consistent with FAA guidance. • Static and fatigue testing of a novel specimen configuration to identify the entire disbond crack growth process. • Indication of slow growth management approach feasible for bonded joints/patch repairs if the doubler/patch is designed to be sufficiently long. • Establishment of modified Paris law for predicting allowable fatigue life and determining inspection interval, in accordance with FAA guidance. • Potential solution for maintenance cost reduction for primary aircraft structures. The applicability of a damage slow growth management strategy to bonded joints/patch repairs of primary aircraft structures was evaluated through an experimental and computational study. Fatigue tests were conducted to investigate the entire process of disbond growth from initiation up to joint ultimate failure. The residual static strength of the joint as a function of disbond length was established using finite element modelling, in which the mesh size was calibrated using the static strength of the specimens measured in room temperature and dry (RD) and hot-wet (HW) conditions, based on the characteristic distance approach. A virtual crack close technique (VCCT) approach was utilised to assess the strain energy release rates (SERRs) as a function of disbond crack length. The measured disbond growth rates were correlated with the SERRs using a modified Paris law that enabled prediction of joint fatigue life. The fatigue test results indicated that for a joint having a sufficient static strength safety margin under a typical fatigue loading that would propagate disbond, the disbond growth would be stable in a particular length range. Thus, the slow growth approach would be feasible for a bonded joint/patch repairs if the patch is designed to be sufficiently large to allow extended damage propagation (whilst in the case when patch size must be limited, safe-life design for the patch termination region in critical repairs must be considered. Should disbond growth occur in this case, the joint must be repaired or replaced). The work presented in this paper validated the framework/procedure proposed previously by the authors (Tanulia et al., 2020) for managing damage slow growth in bonded joints/patch repairs. In the last part of this paper the planned follow-on research is briefly described. [ABSTRACT FROM AUTHOR]

Published

2022

8. A Crack Propagation Method for Pipelines with Interacting Corrosion and Crack Defects.

Author

Xie, Mingjiang, Wang, Yifei, Xiong, Weinan, Zhao, Jianli, and Pei, Xianjun

Subjects

*CRACK propagation (Fracture mechanics), *FRACTURE mechanics, *FATIGUE cracks, *CORROSION fatigue, *FATIGUE crack growth, *STRESS corrosion cracking, *FINITE element method, PIPELINE corrosion

Abstract

Corrosion and crack defects often exist at the same time in pipelines. The interaction impact between these defects could potentially affect the growth of the fatigue crack. In this paper, a crack propagation method is proposed for pipelines with interacting corrosion and crack defects. The finite element models are built to obtain the Stress Intensity Factors (SIFs) for fatigue crack. SIF interaction impact ratio is introduced to describe the interaction effect of corrosion on fatigue crack. Two approaches based on extreme gradient boosting (XGBoost) are proposed in this paper to predict the SIF interaction impact ratio at the deepest point of the crack defect for pipelines with interacting corrosion and crack defects. Crack size, corrosion size and the axial distance between these two defects are the factors that have an impact on the growth of the fatigue crack, and so they are considered as the input of XGBoost models. Based on the synthetic samples from finite element modeling, it has been proved that the proposed approaches can effectively predict the SIF interaction impact ratio with relatively high accuracy. The crack propagation models are built based on the proposed XGBoost models, Paris' law and corrosion growth model. Sensitivity analyses regarding corrosion initial depth and axial distance between defects are performed. The proposed method can support pipeline integrity management by linking the crack propagation model with corrosion size, crack size and the axial distance. The problem of how the interaction between corrosion and crack defects impacts crack defect growth is investigated. [ABSTRACT FROM AUTHOR]

Published

2022

9. A singular crack tip element based on sub-partition and XFEM for modeling crack growth in plates and shells.

Author

Xing, Chen, Zhou, Chuwei, and Sun, Yulin

Subjects

*FRACTURE mechanics, *GROWTH plate, *FATIGUE cracks, *CYLINDRICAL shells, *FINITE element method, *FATIGUE crack growth, *DEGREES of freedom

Abstract

This paper presents a novel method to construct a plate element enveloping crack tip in the extended finite element method (XFEM) frame for crack growth simulation. The element enveloping a crack tip is sub-partitioned into several triangular quarter-point singular elements around the crack tip. The sub-triangular singular element cut by the crack, like the ordinary elements separated by the crack in other regions, is enriched with the Heaviside function. As the sub-partition scheme retains the original boundary of the crack tip element and the discontinuity of the entire crack is reproduced by the Heaviside enrichment, the proposed method can model cracks independent of the background mesh. Using the singular elements instead of analytical asymptotic functions employed in the conventional XFEM allows to reflect the crack tip singularity for more fracture scenarios. The additional nodes created by the sub-partition act as internal nodes of the crack tip element, thus the classical and enriched degrees of freedom (DOFs) on these nodes can be eliminated through an element-level condensation, which could reduce the condition number of the system matrix. Crack growth in plates and shells under fatigue loading is described by using Paris' law. The performance of the proposed method is investigated through stress intensity factors (SIFs) prediction, convergence study, and fatigue crack growth analysis in several examples of cracked plates and cylindrical shells. • A novel method for constructing crack tip element is developed based on XFEM. • The crack tip element is sub-partitioned into several triangular singular elements. • The sub-triangular singular element cut by crack is enriched with the Heaviside function. • All the DOFs on the sub-partition-induced nodes are eliminated through element-level condensation. • Several examples including fatigue crack growth in cylindrical shells show effectiveness and accuracy of the method. [ABSTRACT FROM AUTHOR]

Published

2023

10. Numerical modelling of a 32 m deep excavation in the suburbs of Paris.

Author

Nejjar, Khadija, Dias, Daniel, Cuira, Fahd, Chapron, Gilles, and Le Bissonnais, Hervé

Subjects

*EARTH pressure, *BENDING moment, *STRAIN gages, *SOILS, *SUBURBS, *FINITE element method

Abstract

• Plastic clay can be modelled in drained conditions. • FEM-3D calculations are appropriate to reproduce on site recorded displacements. • SRM underestimates the props loads. As part of the Grand Paris Express project, Fort d'Issy-Vanves-Clamart (FIVC) is one of the 60 new metro stations involving a 32 m deep excavation in layered soils made of limestones and clays. The support system was subject to a comprehensive monitoring program to assess the behavior of the soil and the structure during the works [22]. It comprises wall displacements using inclinometers, bending moments using fiber optic, struts and beams loads using strain gauges and earth pressures at the soil/wall interface using pressure cells. The present paper presents the back analysis done using Finite Elements Models (FEM) in 2D and 3D and, the subgrade reaction method (SRM). The results depict a great consistency between FEM and SRM in terms of reproducing, at the same accuracy level, the wall displacements and bending moments. However, the earth pressure redistribution behind the wall and the props loads are significantly underestimated by SRM (40%) especially for deep excavations. Only FEM can reproduce the measurements since arching effect is allowed within the soil. The present back analysis provides adjustment to the input soil parameters in compliance with their variation range. The resulting set of parameters could be used for an optimization purpose in future designs of deep excavations in similar ground conditions. [ABSTRACT FROM AUTHOR]

Published

2022

11. External surface cracked offshore pipes reinforced with composite repair system: A numerical analysis.

Author

Li, Zongchen, Jiang, Xiaoli, and Hopman, Hans

Subjects

*SURFACE cracks, *NUMERICAL analysis, *FRACTURE mechanics, *STEEL pipe, *STEEL fracture, *COHESIVE strength (Mechanics), *FINITE element method

Abstract

• Finite element analysis on the surface crack growth in steel pipes reinforced with CRS. • The FE model is validated by the experimental results. • Based on the FE model and Paris' law, surface crack growth rate is quantitatively evaluated. • Revealing the mechanism of CRS reinforcement on the surface cracked steel pipes. • Indicating the key influential parameters of CRS reinforcement on surface cracked steel pipe. This paper conducts a numerical analysis on the external surface cracked steel pipes reinforced with Composite Repair System. A three-dimensional finite element (FE) model is developed to calculate the Stress Intensity Factor (SIF) of the surface crack, and the crack growth process is evaluated by the Paris' law. The effect of FRP-to-steel interfacial bond condition on the SIF evaluation has been considered by incorporating the cohesive zone modelling. Then the FE model is validated by the experimental results. Thereafter, major issues including "interfacial bond condition" and "reinforcement effectiveness and influential parameters" have been discussed. The results indicate the reinforcement effectiveness on reducing the SIF owes to the decreasing of stress magnitude and the crack-bridging effect. Because of the crack-bridging effect, composite reinforcement performs more efficiently on reducing the SIF at the surface point than at the deepest point of the surface crack. The negative influence of the FRP-to-steel bond condition on the surface crack growth is not as significant as on reinforcing through-thickness cracks. However, since the interfacial stiffness is sensitive to the adhesive thickness, choosing an ideal adhesive thickness to acquire a good reinforcement effectiveness and to avoid potential interfacial bond failures is recommended. [ABSTRACT FROM AUTHOR]

Published

2022

12. Biaxial fatigue crack growth in proton exchange membrane of fuel cells based on cyclic cohesive finite element method.

Author

Wang, Y.X., Guo, X., Shi, S.W., Weng, G.J., Chen, G., and Lu, J.

Subjects

*PROTON exchange membrane fuel cells, *FATIGUE crack growth, *FINITE element method, *FATIGUE cracks, *FRACTURE mechanics

Abstract

• Biaxial fatigue crack growth is modeled using CFEM with the cyclic damage. • Effects of loading conditions on fatigue crack growth are explored systematically. • Both transverse stress and tensile overload reduce fatigue crack growth rate. • Fatigue crack growth is faster under low-high loading than high-low one. • The mechanisms of fatigue crack growth are elaborated by plastic dissipation. During the operation of proton exchange membrane in fuel cells, cyclic mechanical loads are introduced due to the humidity cycles. The resulting fatigue crack is known to be the main source for its mechanical degradation. In this paper, we use a relation between damage evolution of the cohesive elements and Paris law to simulate the biaxial fatigue crack growth. The effects of various loading conditions are investigated. The predicted crack growth is in a good agreement with experimental studies. Both the transverse stress and the tensile overload have retardation effects. It is also found that the fatigue crack growth rate associated with a shorter pre-crack depends more on the load waveform. Moreover, fatigue crack grows faster under the low-high loading history than the high-low one. These simulation results have provided significant insights into the fatigue failure behavior of membranes during operation conditions and can help improve their durability. Image, graphical abstract [ABSTRACT FROM AUTHOR]

Published

2021

13. Numerical simulation of initiation and crack growth on cast valve body.

Author

Galić, Ivica, Vučković, Krešimir, Tonković, Zdenko, and Čular, Ivan

Subjects

*FRACTURE mechanics, *VALVES, *COMPUTER simulation, *BRITTLE fractures, *FINITE element method, *STEEL pipe

Abstract

• Fatigue analysis of valve bodies DN100 and DN50. • Crack initiation on a valve body according to Basquin-Coffin-Manson equation. • Stress intensity factor estimation with eXtended Finite Element Method (XFEM). • Cycles for crack growth across the valve body thickness. • The engineering and the true stress–strain diagrams and cycle fatigue behaviour of GP240GH steel. Global industry depends of the different type of valves, such as globe valves which are used for precise flow regulation. Since most of the power plants rely on performance of globe valves, it is necessary that valves function without interruption. In this paper, the main part of the globe valve, valve body, is investigated. Simulation of crack initiation and its growth in a wall of valve body is carried out. Required number of cycles for crack initiation is estimated according to Basquin-Coffin-Manson equation. Afterwards, stress intensity factor is estimated through eXtended Finite Element Method (XFEM) and required number of cycles for crack growth across the valve body thickness is calculated according to Paris' law. The aforementioned method is validated on the results from the available literature by employing relatively simple shapes such as steel pipe with integrated flaw. Subsequently, the method is used on a relatively complex geometry, as is the valve body. The obtained results indicate lack of brittle fracture in a valve body. In other words, the results imply occurrence of Leakage Before Brake (LBB). This is utterly important for power plant industries, since it ensures the proper reaction of the user and possibly avoids possible catastrophic consequences for personnel and the equipment located in the proximity of the valve. [ABSTRACT FROM AUTHOR]

Published

2020

14. Numerical investigation on the surface crack growth in FRP-reinforced steel plates subjected to tension.

Author

Li, Zongchen, Jiang, Xiaoli, Hopman, Hans, Zhu, Ling, and Liu, Zhiping

Subjects

*SURFACE cracks, *FRACTURE mechanics, *IRON & steel plates, *FATIGUE crack growth, *STEEL fracture, *BENDING moment, *CHEMICAL bond lengths, *METALLIC surfaces

Abstract

• Evaluate the SIF of surface cracked steel plate reinforced with FRP under tension by FEM. • The FE model is validated by a experimental study. • By the validated FE model and Paris' law, surface crack growth rate is quantitatively predicted. • Reveal the mechanism of FRP reinforcement on the surface crack growth. • Indicate the key influential parameters of FRP reinforcement on surface crack growth. In this paper, we analyse the surface crack growth in the Fibre-Reinforced Polymer (FRP) reinforced steel plates subjected to tension by means of the finite element (FE) method. Following the experimental study, a three-dimensional FE model is developed to evaluate the Stress Intensity Factor (SIF) of the surface crack, and the crack growth rate is calculated by using the Paris' law. Then the FE model is validated by the experimental results. Afterwards, on account of the validated FE model, a parametric study is developed in order to guide the optimization design of FRP reinforcement accounting for different reinforcing schemes and multiple influential parameters. The results indicate that the single-side FRP reinforcement on the cracked surface is the most efficient method, owing to the generated out-of-plane bending moment. In addition, the optimum bond length and number of layers are indicated. Besides, surface crack growth is sensitive to the influential parameters including aspect ratio of the surface crack and crack dimension, while less sensitive to the Carbon-FRP (CFRP) tensile modulus, and the adhesive thickness. The analysis is of instructive value to facilitate the application of FRP reinforcement on the surface cracked metallic structure repairing domain. [ABSTRACT FROM AUTHOR]

Published

2020

15. A polygonal finite element approach for fatigue crack growth analysis of interfacial cracks.

Author

Nguyen, Nam V., Lee, Dongkyu, Nguyen-Xuan, H., and Lee, Jaehong

Subjects

*FATIGUE crack growth, *FRACTURE mechanics, *FATIGUE cracks, *FINITE element method

Abstract

• PFEM based on 12-fold branch functions is first proposed for interfacial cracks. • Wachspress shape functions for arbitrary polygonal elements are exploited. • Fatigue crack growth analysis of interfacial edge crack in bi-materials is performed. • Excellent performance of proposed approach is confirmed via numerical investigations. The fatigue crack growth analysis of an interfacial cracked structure plays an essential role in the design process as well as the safety assessment for various engineering fields in real life. This paper proposes a novel and effective computational approach based on polygonal meshes for crack growth simulation of interfacial crack problems. Polygonal meshes are fully exploited to provide greater flexibility in mesh generation for complicated domains as well as obtain more accuracy in terms of the numerical results. The twelve crack tip enrichment functions to capture the near-tip oscillating singular field are first implemented for polygonal meshes to improve the obtained results. The Wachspress shape function is applied for arbitrary polygonal elements. The strong discontinuities e.g. crack face, crack tip can be modeled, respectively, via Heaviside and asymptotic crack tip enrichment functions while the material interface discontinuities are defined by signed distance functions. The stress intensity factors (SIFs) of the interfacial crack problems can obtain by using the domain based interaction integral approach while the fatigue life is estimated via the Paris law. The accuracy and efficiency of the present approach are demonstrated through several numerical investigations regarding the crack growth problems in both homogeneous materials and bi-materials. The results which are generated from the proposed approach are compared with other earlier ones as well as the conventional XFEM solutions. [ABSTRACT FROM AUTHOR]

Published

2020

16. Investigation of the Enhancement Interactions between Double Parallel Cracks on Fatigue Growth Behaviors.

Author

Han, Zhichao, Qian, Caifu, and Li, Huifang

Subjects

*FATIGUE crack growth, *FRACTURE mechanics, *FATIGUE cracks, *FINITE element method

Abstract

In this paper, interactions of double parallel cracks were studied by performing experiments and numerical simulations. Fatigue crack propagation tests were carried out to measure crack growth rates in the specimens with double parallel cracks or a single crack. Finite element method was adopted to calculate stress intensity factors at the crack tips. Results show that the double parallel cracks at different positions present a shielding effect or enhancement effect on crack growth rates and stress intensity factors. When the double parallel cracks are offset, crack interactions mostly behave as enhancement effects. Empirical formulas were obtained to calculate the stress intensity factor at the "dangerous" crack tip of the double parallel cracks. By modifying the material parameters in Paris equation of the single crack, the double parallel cracks are simplified into a single crack with the same crack growth rates. [ABSTRACT FROM AUTHOR]

Published

2020

17. Development of analogy method for thermal-fatigue crack propagation in pressurized cylinder by using permeation diffusion-fracture model.

Author

Yan, Ziming, Tang, Minjin, Chen, Gang, Wang, Tao, Li, Xiang, and Zhuang, Zhuo

Subjects

*FATIGUE crack growth, *FATIGUE life, *METAL fatigue, *STEAM-turbines, *ANALOGY, *HEAT equation, *PRESSURE vessels, *FINITE element method

Abstract

• Corresponding relationship between heat diffusion equation and seepage diffusion equation. • An analogy method to compute fatigue fracture in steam turbine by using ABAQUS. • An analysis process for turboset to estimate the remaining thermal-fatigue life. • To supply a structural assessment and lifetime prediction for pressure vessels. Natural crack propagation analysis in thermal-fatigue fracture problem is a challenging problem. Reliable predictions for the crack path and residual live of structure provide essential information for the structural integrity assessment and repairment. Various conventional predictive fatigue models have been proposed to evaluate the remaining life, but most of them can't build an explicit relation between damage degree and fatigue life. In recent years, the advanced techniques on crack propagation analyses were proposed, which were used to simulate the fatigue crack growth, but no coupling thermal-fracture function existed in the commercial finite element codes. Fortunately, the extended finite element method (XFEM) in ABAQUS has the coupling permeation diffusion-fracture model. In this paper, an analogy method from coupling permeation diffusion-fracture to coupling thermal-fatigue is proposed to compute fatigue fracture, which is applied for predicting the fatigue life in a specific steam turbine by directly using ABAQUS. Typical fatigue experiments by compact specimens of cast iron are carried out for the fatigue parameters measurement. By using analogy method and Paris' Law, an entire analysis process for the turbine units is built to estimate the thermal-fatigue life. The simulation results predicting remaining life and analyzing fatigue crack growth for the pressurized cylinder are agreed well with the measured engineering data. [ABSTRACT FROM AUTHOR]

Published

2019