Deterministic control of adhesive crack propagation through jamming based switchable adhesives

The Split Hopkinson Pressure Bar (SHPB) is an apparatus for testing the dynamic stress-strain response of the cement mortar specimen with pre-set joints at different angles to explore the influence of joint attitudes of underground rock engineering on the failure characteristics of rock mass structure. The nuclear magnetic resonance (NMR) has also been used to measure the pore distribution and internal cracks of the specimen before and after the testing. In combination with numerical analysis, the paper systematically discusses the influence of joint angles on the failure mode of rock-like materials from three aspects of energy dissipation, microscopic damage, and stress field characteristics. The result indicates that the impact energy structure of the SHPB is greatly affected by the pre-set joint angle of the specimen. With the joint angle increasing, the proportion of reflected energy moves in fluctuation, while the ratio of transmitted energy to dissipated energy varies from one to the other. NMR analysis reveals the structural variation of the pores in those cement specimens before and after the impact. Crack propagation direction is correlated with pre-set joint angles of the specimens. With the increase of the pre-set joint angles, the crack initiation angle decreases gradually. When the joint angles are around 30°–75°, the specimens develop obvious cracks. The crushing process of the specimens is simulated by LS-DYNA software. It is concluded that the stresses at the crack initiation time are concentrated between 20 and 40 MPa. The instantaneous stress curve first increases and then decreases with crack propagation, peaking at different times under various joint angles; but most of them occur when the crack penetration ratio reaches 80–90%. With the increment of joint angles in specimens through the simulation software, the changing trend of peak stress is consistent with the test results.

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Crack Propagation in the Tibia Bone within Total Knee Replacement Using the eXtended Finite Element Method

Applied Sciences ◽

10.3390/app11104435 ◽

2021 ◽

Vol 11 (10) ◽

pp. 4435

Author(s):

Ho-Quang NGUYEN ◽

Trieu-Nhat-Thanh NGUYEN ◽

Thinh-Quy-Duc PHAM ◽

Van-Dung NGUYEN ◽

Xuan Van TRAN ◽

...

Keyword(s):

Fatigue Crack ◽

Crack Initiation ◽

Crack Propagation ◽

Fatigue Crack Initiation ◽

Fracture Prevention ◽

Patient Specific ◽

Extended Finite Element ◽

Tibia Bone ◽

Age Related ◽

Final Failure

Understanding of fracture mechanics of the human knee structures within total knee replacement (TKR) allows a better decision support for bone fracture prevention. Numerous studies addressed these complex injuries involving the femur bones but the full macro-crack propagation from crack initiation to final failure and age-related effects on the tibia bone were not extensively studied. The present study aimed to develop a patient-specific model of the human tibia bone and the associated TKR implant, to study fatigue and fracture behaviors under physiological and pathological (i.e., age-related effect) conditions. Computed tomography (CT) data were used to develop a patient-specific computational model of the human tibia bone (cortical and cancellous) and associated implants. First, segmentation and 3D-reconstruction of the geometrical models of the tibia and implant were performed. Then, meshes were generated. The locations of crack initiation were identified using the clinical observation and the fatigue crack initiation model. Then, the propagation of the crack in the bone until final failure was investigated using the eXtended finite element method (X-FEM). Finally, the obtained outcomes were analyzed and evaluated to investigate the age-effects on the crack propagation behaviors of the bone. For fatigue crack initiation analysis, the stress amplitude–life S–N curve witnessed a decrease with increasing age. The maximal stress concentration caused by cyclic loading resulted in the weakening of the tibia bone under TKR. For fatigue crack propagation analysis, regarding simulation with the implant, the stress intensity factorand the energy release rate tended to decrease, as compared to the tibia model without the implant, from 0.152.5 to 0.111.9 (MPa) and from 10240 to 5133 (J), respectively. This led to the drop in crack propagation speed. This study provided, for the first time, a detailed view on the full crack path from crack initiation to final failure of the tibia bone within the TKR implant. The obtained outcomes also suggested that age (i.e., bone strength) also plays an important role in tibia crack and bone fracture. In perspective, patient-specific bone properties and dynamic loadings (e.g., during walking or running) are incorporated to provide objective and quantitative indicators for crack and fracture prevention, during daily activities.

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Modeling of Fatigue Crack Propagation

Journal of Engineering Materials and Technology ◽

10.1115/1.1631026 ◽

2004 ◽

Vol 126 (1) ◽

pp. 77-86 ◽

Cited By ~ 53

Author(s):

Yanyao Jiang ◽

Miaolin Feng

Keyword(s):

Fatigue Crack ◽

Fatigue Crack Growth ◽

Crack Initiation ◽

Crack Propagation ◽

Crack Growth ◽

Fatigue Damage ◽

Fatigue Crack Propagation ◽

Fatigue Crack Initiation ◽

Cyclic Plasticity ◽

R Ratio

Fatigue crack propagation was modeled by using the cyclic plasticity material properties and fatigue constants for crack initiation. The cyclic elastic-plastic stress-strain field near the crack tip was analyzed using the finite element method with the implementation of a robust cyclic plasticity theory. An incremental multiaxial fatigue criterion was employed to determine the fatigue damage. A straightforward method was developed to determine the fatigue crack growth rate. Crack propagation behavior of a material was obtained without any additional assumptions or fitting. Benchmark Mode I fatigue crack growth experiments were conducted using 1070 steel at room temperature. The approach developed was able to quantitatively capture all the important fatigue crack propagation behaviors including the overload and the R-ratio effects on crack propagation and threshold. The models provide a new perspective for the R-ratio effects. The results support the notion that the fatigue crack initiation and propagation behaviors are governed by the same fatigue damage mechanisms. Crack growth can be treated as a process of continuous crack nucleation.

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Considerations of crack initiation and crack propagation in low-cycle fatigue

Scripta Metallurgica ◽

10.1016/0036-9748(75)90394-4 ◽

1975 ◽

Vol 9 (11) ◽

pp. 1141-1146 ◽

Cited By ~ 29

Author(s):

P.S. Maiya

Keyword(s):

Crack Initiation ◽

Crack Propagation ◽

Low Cycle Fatigue ◽

Cycle Fatigue

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Crack initiation and crack propagation under thermal cyclic loading

High Temperature Technology ◽

10.1080/02619180.1990.11753464 ◽

1990 ◽

Vol 8 (2) ◽

pp. 98-104 ◽

Cited By ~ 6

Author(s):

K. Bethge ◽

D. Munz ◽

J. Neumann

Keyword(s):

Cyclic Loading ◽

Crack Initiation ◽

Crack Propagation

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Design of crack arrestors for ultra high grade gas transmission pipelines: simulation of crack initiation, propagation and arrest

International Journal Sustainable Construction & Design ◽

10.21825/scad.v2i2.20528 ◽

2011 ◽

Vol 2 (2) ◽

pp. 307-319

Author(s):

F. Van den Abeele ◽

M. Di Biagio ◽

L. Amlung

Keyword(s):

Crack Initiation ◽

Crack Propagation ◽

Large Scale ◽

Large Diameter ◽

Pipe Material ◽

High Grade ◽

Gas Pipelines ◽

Ductile Crack ◽

Reinforced Plastics ◽

Four Point Bending

One of the major challenges in the design of ultra high grade (X100) gas pipelines is the identification of areliable crack propagation strategy. Recent research results have shown that the newly developed highstrength and large diameter gas pipelines, when operated at severe conditions, may not be able to arrest arunning ductile crack through pipe material properties. Hence, the use of crack arrestors is required in thedesign of safe and reliable pipeline systems.A conventional crack arrestor can be a high toughness pipe insert, or a local joint with higher wall thickness.According to experimental results of full-scale burst tests, composite crack arrestors are one of the mostpromising technologies. Such crack arrestors are made of fibre reinforced plastics which provide the pipewith an additional hoop constraint. In this paper, numerical tools to simulate crack initiation, propagationand arrest in composite crack arrestors are introduced.First, the in-use behaviour of composite crack arrestors is evaluated by means of large scale tensile testsand four point bending experiments. The ability of different stress based orthotropic failure measures topredict the onset of material degradation is compared. Then, computational fracture mechanics is applied tosimulate ductile crack propagation in high pressure gas pipelines, and the corresponding crack growth inthe composite arrestor. The combination of numerical simulation and experimental research allows derivingdesign guidelines for composite crack arrestors.

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Fatigue Behavior of Circumferentially Notched Round Bars of Austenitic Stainless Steel Under Torsional and Axial Loads

ASME 2010 Pressure Vessels and Piping Conference: Volume 1 ◽

10.1115/pvp2010-25472 ◽

2010 ◽

Author(s):

Masao Itatani ◽

Keisuke Tanaka ◽

Isao Ohkawa ◽

Takehisa Yamada ◽

Toshiyuki Saito

Keyword(s):

Fatigue Life ◽

Stress Concentration ◽

Crack Initiation ◽

Crack Propagation ◽

Fatigue Behavior ◽

Fatigue Crack Initiation ◽

Static Tension ◽

Cyclic Torsion ◽

Cyclic Tension ◽

Crack Initiation Life

Fatigue tests of smooth and notched round bars of austenitic stainless steels SUS316NG and SUS316L were conducted under cyclic tension and cyclic torsion with and without static tension. Fatigue strength under fully reversed (R=−1) cyclic tension once increased with increasing stress concentration factor up to Kt=1.5, but it decreased from Kt=1.5 to 2.5. Fatigue life increased with increasing stress concentration under pure cyclic torsion, while it decreased with increasing stress concentration under cyclic torsion with static tension. From the measurement of fatigue crack initiation and propagation lives using electric potential drop method, it was found that the crack initiation life decreased with increasing stress concentration and the crack propagation life increased with increasing stress concentration under pure cyclic torsion. Under cyclic torsion with static tension, the crack initiation life also decreased with increasing stress concentration but the crack propagation life decreased or not changed with increasing stress concentration then the total fatigue life of sharper notched specimen decreased. It was also found that the fatigue life of smooth specimen under cyclic torsion with static tension was longer than that under pure cyclic torsion. This behavior could be explained based on the cyclic strain hardening under non-proportional loading and the difference in crack path with and without static tension.

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Progressive Failure and Acoustic Emission Characteristics of Red Sandstone with Different Geometry Parallel Cracks under Uniaxial Compression Loading

Advances in Materials Science and Engineering ◽

10.1155/2021/5569091 ◽

2021 ◽

Vol 2021 ◽

pp. 1-11

Author(s):

Xizhen Sun ◽

Fanbao Meng ◽

Ce Zhang ◽

Xucai Zhan ◽

He Jiang

Keyword(s):

Acoustic Emission ◽

Crack Initiation ◽

Crack Propagation ◽

Geometric Distribution ◽

Progressive Failure ◽

Fractured Rock ◽

Propagation Mode ◽

Wing Crack ◽

Red Sandstone ◽

Parallel Cracks

The geometric distribution of initial damages has a great influence on the strength and progressive failure characteristics of the fractured rock mass. Initial damages of the fractured rock were simplified as parallel cracks in different geometric distributions, and then, the progressive failure and acoustic emission (AE) characteristics of specimens under the uniaxial compression loading were analyzed. The red sandstone (brittle materials) specimens with the parallel preexisting cracks by water jet were used in the tests. The energy peak and stress attenuation induced by the energy release of crack initiation were intuitively observed in the test process. Besides, three modes of rock bridge coalescence were obtained, and wing crack was the main crack propagation mode. The wing crack and other cracks were initiated in different loading stages, which were closely related to the energy level of crack initiation. The propagation of wing crack (stable crack) consumed a large amount of energy, and then, the propagation of shear crack, secondary crack, and anti-wing crack (unstable crack) was inhibited. The relationship between the crack propagation mode and the geometric distribution of existing cracks in the specimen was revealed. Meanwhile, the strength characteristic and failure mode of fractured rock with the different geometric distributions of preexisting crack were also investigated. The energy evolution characteristics and crack propagation were also analyzed by numerical modeling (PFC2D).

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Crack Propagation Prediction Using Haensel Damage Model

Volume 7: Structures and Dynamics, Parts A and B ◽

10.1115/gt2012-68162 ◽

2012 ◽

Author(s):

Piotr Bednarz ◽

Jaroslaw Szwedowicz

Keyword(s):

Cyclic Loading ◽

Crack Initiation ◽

Crack Propagation ◽

Damage Model ◽

Lifetime Prediction ◽

Dissipated Energy ◽

Mathematical Approach ◽

Loading Conditions ◽

Stored Energy ◽

Tensile Stresses

The Haensel damage model correlates lifetime of a component until crack initiation to the dissipated and stored energy in the material during cyclic loading. The crack initiation is influenced by mean stresses. The Haensel damage model considers the mean stress effect by including compressive and tensile stresses in calculations of elastic strain energy during cyclic loading conditions. The goal of the paper is to extend the above model to predict crack propagation under large cyclic plasticity and non-proportional loading conditions. After voids initiation onset of necking, voids growth and linking takes place among them. During this process a mesocrack is created. This stage of fracture involves the same amount of released energy for new crack surface creation as dissipated energy for mesocrack initiation. The amount of dissipated and stored energy is related to the process zone size and to the number of cycles. Ilyushin’s postulate is used to calculate the amount of dissipated energy. In order to consider a contribution of tensile stresses only during loading to crack propagation, tensile/compressive split is performed for the stress tensor. One of the key drivers of this paper is to provide a straightforward engineering approach, which does not require explicit modelling of cracks. The proposed mathematical approach accounts for redistribution of stresses, strains and energy during crack propagation. This allows to approximate the observed effect of distribution of dissipated energy on the front of a crack tip. The developed approach is validated through FE (Finite Element) simulations of the Dowling and Begley experiment. The Haensel lifetime prediction of Dowling’s experiment is in good agreement with the experimental data and the explicit FE results. Finally, the proposed mathematical approach simplifies significantly the engineering effort for Nonlinear Fracture Mechanics lifetime prediction by avoiding the requirement to simulate real crack propagation using node base release methods, XFEM or remeshing procedures.

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