Experimental and numerical study on crack propagation in pre-cracked beam specimens under three-point bending

Hadi Haeri

Journal of Central South University ›› 2016, Vol. 23 ›› Issue (2) : 430 -439.

PDF
Journal of Central South University ›› 2016, Vol. 23 ›› Issue (2) : 430 -439. DOI: 10.1007/s11771-016-3088-y
Article

Experimental and numerical study on crack propagation in pre-cracked beam specimens under three-point bending

Author information +
History +
PDF

Abstract

A simultaneous experimental and numerical study on crack propagation in the pre-cracked beams specimens (concrete-like materials) is carried out using three-point bending flexural test. The crack propagation and coalescence paths of internal cracks in side beam specimens are experimentally studied by inserting double internal cracks. The effects of crack positions on the fracturing path in the bridge areas of the double cracked beam specimens are also studied. It has been observed that the breaking of concrete-like cracked beams specimens occurs mainly by the propagation of wing cracks emanating from the tips of the pre-existing cracks in the numerical and experimental analyses, respectively. The same specimens are numerically simulated by an indirect boundary element method (IBEM) known as displacement discontinuity method (DDM) using higher displacement discontinuity. These numerical results are compared with the existing experimental results. This comparison illustrates the higher accuracy of the results obtained by the indirect boundary element method by using only a small number of elements compared with the discrete element method (PFC2D code).

Keywords

double internal cracks / concrete-like specimens / crack propagation

Cite this article

Download citation ▾
Hadi Haeri. Experimental and numerical study on crack propagation in pre-cracked beam specimens under three-point bending. Journal of Central South University, 2016, 23(2): 430-439 DOI:10.1007/s11771-016-3088-y

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

ZengG, YangX, YinaA, BaiF. Simulation of damage evolution and crack propagation in three-point bending pre-cracked asphalt mixture beam [J]. Construction and Building Materials, 2014, 55: 323-332

[2]

WangT, DaiJ G, ZhengJ J. Multi-angle truss model for predicting the shear deformation of RC beams with low span-effective depth ratios [J]. Engineering Structures, 2015, 91: 85-95

[3]

OzcebeG. Minimum flexural reinforcement for T-beams made of higher strength concrete [J]. Canadian Journal of Civil Engineering, 2011, 26: 525-534

[4]

RuizG, CarmonaR J. Experimental study on the influence of the shape of the cross-section and the rebar arrangement on the fracture of LRC beams [J]. Materials and Structures, 2006, 39: 343-352

[5]

RuizG, CarmonaR J, CendonD A. Propagation of a cohesive crack through adherent reinforcement layers [J]. Computer Methods in Applied Mechanics and Engineering, 2006, 195: 7237-7248

[6]

JaeiroR P, EinsteinH H. Experimental study of the cracking behavior of specimens containing inclusions (under uniaxial compression) [J]. Int J Fract, 2010, 164: 83-102

[7]

YangS Q. Crack coalescence behavior of brittle sandstone samples containing two coplanar fissures in the process of deformation breakage [J]. Engin Fract Mech, 2011, 78: 3059-3081

[8]

LeeH, JeonS. An experimental and numerical study of fracture coalescence in pre-cracked specimens under uniaxial compression [J]. Int J Solids and Structures, 2011, 48: 979-999

[9]

AmeenM, Raghu ParasadB K, GopalakrishnanA R. Modeling of concrete cracking—A hybrid technique of using displacement discontinuity element method and direct boundary element method [J]. Engineering Analysis with Boundary Elements, 2011, 35: 1054-1059

[10]

XiaK, ZhengH, WangY X. Determination of dynamic rock mode-I fracture parameters using cracked chevron notched semi–circular bend specimen [J]. Eng Fract Mech, 2011, 78: 2633-2644

[11]

AyatollahiM R, SistaniniaM. Mode II fracture study of rocks using Brazilian disk specimens [J]. Int J Rock Mech Min Sci, 2011, 48: 819-826

[12]

WangQ Z, FengF, NiM, GouX P. Measurement of mode I and mode II rock dynamic fracture toughness with cracked straight through flattened Brazilian disc impacted by split Hopkinson pressure bar [J]. Eng Fract Mech, 2011, 78: 2455-2469

[13]

TavaralL, ManticV, GracianiE, ParisF. BEM analysis of crack onset and propagation along fiber–matrix interface under transverse tension using a linear elastic-brittle interface model [J]. Engineering Analysis with Boundary Elements, 2011, 35: 2207-2221
[14]

PuC-z, CaoPing. Breakage characteristics and its influencing factors of rock-like material with multi-fissures under uniaxial compression [J]. Transactions of Nonferrous Metals Society of China, 2012, 22: 185-191

[15]

TangC-a, Yangy-feng. Crack branching mechanism of rock-like quasi-brittle materials under dynamic stress [J]. Journal of Central South University, 2012, 19: 3273-3284

[16]

ZhaoY-l, CaoP, WangW-j, WanW, ChenRui. Wing crack model subjected to high hydraulic pressure and far field stresses and its numerical simulation [J]. Journal Central South University, 2012, 19: 578-585

[17]

LeonelE D, ChateauneufA, VenturiniW S. Probabilistic crack growth analyses using a boundary element model: Applications in linear elastic fracture and fatigue problems [J]. Engineering Analysis with Boundary Elements, 2012, 36: 944-959

[18]

LancasterI M, KhalidH A, KougioumtzoglouI A. Extended FEM modelling of crack propagation using the semi-circular bending test [J]. Construction and Building Materials, 2013, 48: 270-277

[19]

YoshiharaH. Initiation and propagation fracture toughness of solid wood under the mixed Mode I/II condition examined by mixed-mode bending test [J]. Engin Fract Mech, 2013, 104: 1-15

[20]

JiangZ, WanS, ZhongZ, LiM, ShenK. Determination of mode-I fracture toughness and non-uniformity for GFRP double cantilever beam specimens with an adhesive layer [J]. Engin Fract Mech, 2014, 128: 139-156

[21]

NoelM, SoudkiK. Estimation of the crack width and deformation of FRP-reinforced concrete flexural members with and without transverse shear reinforcement [J]. Engineering Structures, 2014, 59: 393-398

[22]

HaeriH, ShahriarK, MarjiM F, MoarefvandP. On the cracks coalescence mechanism and cracks propagation paths in rock-like specimens containing pre-existing random cracks under compression [J]. Journal of Central South University, 2014, 21(6): 2404-2414

[23]

ShenB, StephanessonO. Modification of the G-criterion for crack propagation subjected to compression [J]. Engin Fract Mech, 1994, 47: 177-189

[24]

ScottM A, SimpsoNR N, EvansJ A, LiptonS, BordasS P, HughesT J, SederbergT W. Isogeometric boundary element analysis using unstructured Tsplines [J]. Comput Meth Appl Mech Eng, 2013, 254: 197-221

[25]

MarjiM F. On the use of power series solution method in the crack analysis of brittle materials by indirect boundary element method [J]. Engin Fract Mech, 2013, 98: 365-382

[26]

OliveiraH L, LeonelE D. An alternative BEM formulation, based on dipoles of stresses and tangent operator technique, applied to cohesive crack growth modeling [J]. Engineering Analysis with Boundary Elements, 2014, 41: 74-82

[27]

LeiJ, WangY S, HuangY, YangQ, ZhangC. Dynamic crack propagation in matrix involving inclusions by a time-domain BEM [J]. Engineering Analysis with Boundary Elements, 2012, 36: 651-657

[28]

ParkC H, BobetA. Crack initiation, propagation and coalescence from frictional flaws in uniaxial compression [J]. Engin Fract Mech, 2010, 77: 2727-2748

[29]

LiH, WongL, NY. Influence of flaw inclination angle and loading condition on crack initiation and propagation [J]. Int J Solids and Structures, 2012, 49: 2482-2499

[30]

MarjiM F. On the use of power series solution method in the crack analysis of brittle materials by indirect boundary element method [J]. Engin Fract Mech, 2013, 98: 365-382

[31]

GhazvinianA, SarfaraziV, SchubertW, BlumelM. A study of the failure mechanism of planar non-persistent open joints using PFC2D [J]. Rock Mech Rock Eng, 2011, 45: 677-693
[32]

SarfaraziV, GhazvinianA, SchubertW, BlumelM, NejatiH R. Numerical simulation of the process of fracture of echelon rock joints [J]. Rock Mech Rock Eng, 2013
[33]

CrouchS L. Analysis of stresses and displacements around underground excavations: An application of the displacement discontinuity method [R]. Minneapolis, Minnesota: University of Minnesota Geomechanics, 1967
[34]

CrouchS L, StarfieldA MBoundary element methods in solid mechanics [M], 1983LondonAllen and Unwin
[35]

BowieL. Solutions of plane crack problems by mapping techniques [S]. Mech Fract, 1973
[36]

ErdoganF, SihG C. On the crack extension in plates under loading and transverse shear [J]. Fluids Eng, 1963, 85: 519-527
AI Summary AI Mindmap
PDF

122

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/