A viscous-cohesive model for concrete fracture in quasi-static loading rate

2020 ◽  
Vol 228 ◽  
pp. 106893
Author(s):  
Fábio Luis Gea dos Santos ◽  
José Luiz Antunes de Oliveira e Sousa
Keyword(s):  
Static Loading ◽  
Loading Rate ◽  
Concrete Fracture ◽  
Cohesive Model

scholarly journals Numerical Study on the Dynamic Fracture Energy of Concrete Based on a Rate-Dependent Cohesive Model

Materials ◽  
2021 ◽  
Vol 14 (23) ◽  
pp. 7421
Author(s):  
Penglin Zhang ◽  
Zhijun Wu ◽  
Yang Liu ◽  
Zhaofei Chu
Keyword(s):  
Strain Rate ◽  
Fracture Energy ◽  
Dynamic Fracture ◽  
Loading Rate ◽  
Numerical Study ◽  
Damage Zone ◽  
Concrete Fracture ◽  
Obvious Effect ◽  
Cohesive Model ◽  
Rate Dependent

As an important parameter for concrete, fracture energy is difficult to accurately measure in high loading rate tests due to the limitations of experimental devices and methods. Therefore, the utilization of numerical methods to study the dynamic fracture energy of concrete is a simple and promising choice. This paper presents a numerical investigation on the influence of loading rate on concrete fracture energy and cracking behaviors. A novel rate-dependent cohesive model, which was programmed as a user subroutine in the commercial explicit finite element solver LS-DYNA, is first proposed. After conducting mesh sensitivity analysis, the proposed model is calibrated against representative experimental data. Then, the underlying mechanisms of the increase in fracture energy due to a high strain rate are determined. The results illustrate that the higher fracture energy during dynamic tension loading is caused by the wider region of the damage zone and the increase in real fracture energy. As the loading rate increases, the wider region of the damage zone plays a leading role in increasing fracture energy. In addition, as the strain rate increases, the number of microcracks whose fracture mode is mixed mode increases, which has an obvious effect on the change in real fracture energy.

A loading rate dependent cohesive model for concrete fracture

2012 ◽  
Vol 82 ◽  
pp. 195-208 ◽  
Author(s):  
A.L. Rosa ◽  
R.C. Yu ◽  
G. Ruiz ◽  
L. Saucedo ◽  
J.L.A.O. Sousa
Keyword(s):  
Loading Rate ◽  
Concrete Fracture ◽  
Cohesive Model ◽  
Rate Dependent

FRACTURE BEHAVIOR OF Zr-BASED BULK METALLIC GLASS UNDER IMPACT LOADING

2006 ◽  
Vol 20 (25n27) ◽  
pp. 4359-4364 ◽  
Author(s):  
HYUNG-SEOP SHIN ◽  
KI-HYUN KIM ◽  
SANG-YEOB OH
Keyword(s):  
Fracture Toughness ◽  
Crack Initiation ◽  
Fracture Energy ◽  
Impact Loading ◽  
Static Loading ◽  
Fracture Behavior ◽  
Loading Rate ◽  
Shear Bands ◽  
Maximum Load ◽  
Cu Alloy

The fracture behavior of a Zr -based bulk amorphous metal under impact loading using subsize V-shaped Charpy specimens was investigated. Influences of loading rate on the fracture behavior of amorphous Zr - Al - Ni - Cu alloy were examined. As a result, the maximum load and absorbed fracture energy under impact loading were lower than those under quasi-static loading. A large part of the absorbed fracture energy in the Zr -based BMG was consumed in the process for crack initiation and not for crack propagation. In addition, fractographic characteristics of BMGs, especially the initiation and development of shear bands at the notch tip were investigated. Fractured surfaces under impact loading are smoother than those under quasi-static loading. The absorbed fracture energy appeared differently depending on the appearance of the shear bands developed. It can be found that the fracture energy and fracture toughness of Zr -based BMG are closely related with the extent of shear bands developed during fracture.

scholarly journals Determination of parameters of a viscous-cohesive fracture model by inverse analysis

2015 ◽  
Vol 8 (5) ◽  
pp. 669-706 ◽  
Author(s):  
F. L. Gea dos Santos ◽  
J. L. A. O. Sousa
Keyword(s):  
Inverse Analysis ◽  
Fracture Process ◽  
Loading Rate ◽  
Process Zone ◽  
High Strength ◽  
Model Parameters ◽  
Cohesive Fracture ◽  
Cohesive Model ◽  
Determination Of Parameters

ABSTRACTThe quasi-brittle, loading rate dependent behaviour of the concrete, characterized by a fracture process zone (FPZ) ahead of the crack front, can be described through a viscous-cohesive model. In this paper, a viscous cohesive model proposed in a former paper is evaluated for a group of high strength concrete beams loaded at rates from 10-5 mm/s to 10+1 mm/s. A software has been developed to enable the automatic determination of the viscous-cohesive model parameters through inverse analysis on load-versus loading-point displacement (P-d) from threepoint bend tests on notched prismatic specimens. The strategy allowed the sensitivity analysis of the parameters related to viscous behaviour. The analysis of results shows that the formerly proposed model can be improved for a better simulation of the loading rate dependence on the cohesive fracture process.

scholarly journals Cohesive crack modeling of influence of sudden changes in loading rate on concrete fracture

1995 ◽  
Vol 52 (6) ◽  
pp. 987-997 ◽  
Author(s):  
S. Tandon ◽  
K.T. Faber ◽  
Zdeněk P. Bažant ◽  
Yuan N. Li
Keyword(s):  
Loading Rate ◽  
Cohesive Crack ◽  
Concrete Fracture

IAEA Coordinated Research Project on Master Curve Approach to Monitor Fracture Toughness of RPV Steels: Effect of Loading Rate

2009 ◽  
Author(s):  
Hans-Werner Viehrig ◽  
Enrico Lucon ◽  
William L. Server
Keyword(s):  
Static Loading ◽  
Master Curve ◽  
Loading Rate ◽  
Dynamic Testing ◽  
Loading Rates ◽  
Brittle Transition ◽  
Upper Limit ◽  
Rate Effects ◽  
Unloading Compliance ◽  
Ductile To Brittle Transition

The Master Curve (MC) approach procedure standardized in ASTM E1921 is defined for quasi-static loading conditions. However, the extension of the MC method to dynamic testing is still under discussion. The effect of loading rate can be broken down into two distinct aspects: 1) the effect of loading rate on Master Curve To values for loading rates within the loading rate range specified in ASTM E1921 for quasi-static loading, and 2) the effect of loading rate on Master Curve To values for higher loading rates. The IAEA CRP8 includes both aspects, but primarily focuses on the second element of loading rate effects, i.e. loading rate ranges above the upper limit of the E1921 standard and it comprises: - results of a round-robin exercise to validate the application of the Master Curve approach to precracked Charpy (PCC) specimens tested in the ductile-to-brittle transition region using an instrumented pendulum, - Master Curve data obtained at different loading rates on various RPV steels, in order to assess the loading rate dependence of To and compare it with an empirical model proposed by Wallin, and - the comparison of results from unloading compliance and monotonic loading in the quasi-static range.

Quasi-Static Loading Rate Effect on the Master Curve Reference Temperature of Ferritic Steels and Implications

2003 ◽  
Author(s):  
J. B. Hall ◽  
K. K. Yoon
Keyword(s):  
Fracture Toughness ◽  
Static Loading ◽  
Loading Rate ◽  
Rate Effect ◽  
Reference Temperature ◽  
Ferritic Steels ◽  
Rate Range ◽  
Static Fracture ◽  
Quasistatic Loading ◽  
Temperature Test

It has long been recognized that there is a considerable difference between the dynamic and quasi-static fracture toughness reference temperature. However, it has not been clear whether this loading rate effect extends into the quasistatic loading regime. The current fracture toughness reference temperature test standard for ferritic steels (ASTM E1921) specifies an allowable quasi-static loading rate range spanning 100 fold. Recently obtained data from the IAEA JRQ material suggests that the same loading rate effect extends throughout this allowable quasi-static loading rate range. The loading rate effect could amount to a difference in the measured reference temperature of 23°C (41°F) between the extremes of the specified range. This paper presents the data demonstrating this effect, examines different ways of calculating the loading rate, suggests changes to related to the test standard, and discusses the use of applying the loading rate effect on reference temperature.

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