Capturing the influence of concrete mesostructure at the macroscale remains a significant challenge in computational modeling. This paper presents a novel methodology for simulating concrete cracking at the macroscale while considering mesoscale characteristics and overcoming the difficulties of generating computational specimens. To this end, a tensile damage model incorporating high aspect ratio interface elements via mesh fragmentation is employed to capture nonlinear behavior. The Rule of Mixture is utilized to derive effective properties. A notched square plate under uniaxial tensile loading is simulated, and the average result from five mesoscale realizations is compared with a single macroscale result, considering varying aggregate fractions and shapes. A three-point bending test and an L-shaped panel test are also performed to verify the effectiveness of the strategy under different fracture modes, and the results are compared with experimental and computational references. The findings demonstrate the efficacy of the approach in capturing mesoscale characteristics through macroscale analysis, encouraging further application to more complex analyses, such as thermomechanical or three-dimensional problems, which involve more computationally demanding aggregate arrangements in the mortar matrix.
AghajanzadehSMMirzabozorgH (2019) Concrete fracture process modeling by combination of extended finite element method and smeared crack approach. Theoretical and Applied Fracture Mechanics101: 306–319.
2.
AgorasMPonte CastañedaP (2011) Homogenization estimates for multi-scale nonlinear composites. European Journal of Mechanics - A/Solids30(6): 828–843.
3.
AlyhyaWSDhaheerMAAl-RubayeM, et al. (2016) Influence of mix composition and strength on the fracture properties of self-compacting concrete. Construction and Building Materials110: 312–322.
4.
American Society for Testing and Materials (2024) ASTM C31/C31M-2024, Standard Practice for Making and Curing Concrete Test Specimens in the Field.
5.
AmmendoleaDGrecoFLeonettiL, et al. (2023) Fatigue crack growth simulation using the moving mesh technique. Fatigue & Fracture of Engineering Materials & Structures46(12): 4606–4627.
6.
ArrudaMRPachecoJCastroLM, et al. (2022) A modified Mazars damage model with energy regularization. Engineering Fracture Mechanics259: 1–22.
7.
AssisLSDal-SassoMFFarageMCR, et al. (2021) Numerical analysis of mechanical damage on concrete under high temperatures. Revista IBRACON de Estruturas e Materiais15(1): 1–14.
8.
BonifácioAL (2017) Estratégia computacionalpara avaliação de propriedades mecânicas de agregado leve. Tese de doutorado, Universidade Federal de Juiz de Fora, Juiz de Fora, Brasil.
CastañedaP (1991) The effective mechanical properties of nonlinear isotropic composites. Journal of the Mechanics and Physics of Solids39(1): 45–71.
11.
ChabocheJKanoutéPRoosA (2005) On the capabilities of mean-field approaches for the description of plasticity in metal matrix composites. International Journal of Plasticity21(7): 1409–1434.
12.
ChengPZhuHYanZ, et al. (2022) Multiscale modeling for fire induced spalling in concrete tunnel linings based on the superposition-based phase field fracture model. Computers and Geotechnics148: 1–16.
13.
ChungPWTammaKKNamburuRR (2001) Asymptotic expansion homogenization for heterogeneous media: Computational issues and applications. Composites Part A: Applied Science and Manufacturing32(9): 1291–1301.
14.
CongroMRoehlDMejiaC (2021) Mesoscale computational modeling of the mechanical behavior of cement composite materials. Composite Structures257: 1–10.
15.
CountoUJChiorinoMA (1965) The effect of the elastic modulus of the aggregate on the elastic modulus, creep and creep recovery of concrete. Magazine of Concrete Research17(52): 142–151.
16.
CundallPAStrackODL (1979) A discrete numerical model for granular assemblies. Géotechnique29(1): 47–65.
17.
Dal-SassoMFAssisLSFarageMCR, et al. (2023) Numerical evaluation of aggregate size influence on concrete mechanical damage under high temperatures. Revista IBRACON de Estruturas e Materiais16(6): e16605.
18.
DanasKIdiartMCastañedaPP (2008) A homogenizationbased constitutive model for isotropic viscoplastic porous media. International Journal of Solids and Structures45(11): 3392–3409.
19.
De SaCBenboudjemaF (2011) Modeling of concrete nonlinear mechanical behavior at high temperatures with different damage-based approaches. Materials and Structures/Materiaux et Constructions44(8): 1411–1429.
20.
De SchutterGTaerweL (1993) Random particle model for concrete based on Delaunay triangulation. Materials and Structures26(2): 67–73.
21.
DongYSuCQiaoP (2021) An improved mesoscale damage model for quasi-brittle fracture analysis of concrete with ordinary state-based peridynamics. Theoretical and Applied Fracture Mechanics112: 1–14.
22.
DuXJinLMaG (2014) Numerical modeling tensile failure behavior of concrete at mesoscale using extended finite element method. International Journal of Damage Mechanics23(7): 872–898.
23.
Edalat BehbahaniABarrosJAOVentura-GouveiaA, et al. (2015) Plasticdamage smeared crack model to simulate the behaviour of structures made by cement based materials. International Journal of Solids and Structures73-74: 20–40.
24.
Elhaj SalahSBNait-AliAGueguenM, et al. (2020) Non-local modeling with asymptotic expansion homogenization of random materials. Mechanics of Materials147: 103459.
25.
FarahaniBVBelinhaJPiresFM, et al. (2017) A meshless approach to non-local damage modelling of concrete. Engineering Analysis with Boundary Elements79: 62–74.
26.
FeistCHofstetterG (2006) An embedded strong discontinuity model for cracking of plain concrete. Computer Methods in Applied Mechanics and Engineering195(52): 7115–7138.
27.
FishJYangZYuanZ (2019) A second-order reduced asymptotic homogenization approach for nonlinear periodic heterogeneous materials. International Journal for Numerical Methods in Engineering119(6): 469–489.
28.
GaoZZhangLYuW (2018) A nonlocal continuum damage model for brittle fracture. Engineering Fracture Mechanics189: 481–500.
29.
GeersMGDKouznetsovaVGMatoušK, et al. (2017) Homogenization Methods and Multiscale Modeling: Nonlinear Problems. Hoboken, NJ, USA: John Wiley Sons, Ltd. ISBN 9781119176817, pp. 1–34. DOI: 10.1002/9781119176817.ecm2107.
30.
GeersMGDYvonnetJ (2016) Multiscale modeling of microstructure-property relations. MRS Bulletin41(8): 610616.
31.
GeißlerGNetzkerCKaliskeM (2010) Discrete crack path prediction by an adaptive cohesive crack model. Engineering Fracture Mechanics77(18): 3541–3557.
32.
GhoshSBaiJPaquetD (2009) Homogenization-based continuum plasticity-damage model for ductile failure of materials containing heterogeneities. Journal of the Mechanics and Physics of Solids57(7): 1017–1044.
33.
GrasslPPearceC (2010) Mesoscale approach to modeling concrete subjected to thermomechanical loading. Journal of Engineering Mechanics136(3): 322–328.
34.
GrecoFAmmendoleaDLonettiP, et al. (2021) Crack propagation under thermo-mechanical loadings based on moving mesh strategy. Theoretical and Applied Fracture Mechanics114(June): 1–20.
35.
GrégoireDRojas-SolanoLPijaudier-CabotG (2013) Failure and size effect for notched and unnotched concrete beams. International Journal for Numerical and Analytical Methods in Geomechanics37(10): 1434–1452.
36.
GuoFZhangHYangZ, et al. (2023) A spherical harmonic-random field coupled method for efficient reconstruction of ct-image based 3d aggregates with controllable multiscale morphology. Computer Methods in Applied Mechanics and Engineering406: 115901.
37.
HaiLWriggersPHuangY, et al. (2024) Dynamic fracture investigation of concrete by a rate-dependent explicit phase field model integrating viscoelasticity and microviscosity. Computer Methods in Applied Mechanics and Engineering418: 116540.
38.
HuangYHaiLLiQ, et al. (2025) Stochastic analysis of dynamic fracture of concrete using CTimage based mesoscale models with a rate-dependent phase field method. International Journal of Impact Engineering197: 105188.
39.
HuangYNatarajanSZhangH, et al. (2023) A ct image-driven computational framework for investigating complex 3d fracture in mesoscale concrete. Cement and Concrete Composites143: 105270.
40.
HuangYYangZChenX, et al. (2016) Monte carlo simulations of meso-scale dynamic compressive behavior of concrete based on x-ray computed tomography images. International Journal of Impact Engineering97: 102–115.
41.
HuangYYangZRenW, et al. (2015) 3d meso-scale fracture modelling and validation of concrete based on in-situ x-ray computed tomography images using damage plasticity model. International Journal of Solids and Structures67-68: 340–352.
42.
HuangYZhangHZhouJ, et al. (2022) Efficient quasi-brittle fracture simulations of concrete at mesoscale using micro ct images and a localizing gradient damage model. Computer Methods in Applied Mechanics and Engineering400: 115559.
43.
JirásekMZimmermannT (2001) Embedded crack model: I. Basic formulation. International Journal for Numerical Methods in Engineering50(6): 1269–1290.
44.
Juárez-LunaGTena-ColungaAAyalaG (2015) Computational modelling of rc slabs cracking with an embedded discontinuity formulation. Latin American Journal of Solids and Structures12: 2539–2561.
45.
JukićMBrankBIbrahimbegovićA (2013) Embedded discontinuity finite element formulation for failure analysis of planar reinforced concrete beams and frames. Engineering Structures50: 115–125.
46.
KalamkarovALAndrianovIVDanishevs’kyyVV (2009) Asymptotic homogenization of composite materials and structures. Applied Mechanics Reviews62(3): 030802.
47.
KozákVValaJ (2023) Crack growth modelling in cementitious composites using xfem. Procedia Structural Integrity43: 4752.
48.
KurumataniMTeradaKKatoJ, et al. (2016) An isotropic damage model based on fracture mechanics for concrete. Engineering Fracture Mechanics155: 49–66.
49.
LiSTianLCuiX (2019) Phase field crack model with diffuse description for fracture problem and implementation in engineering applications. Advances in Engineering Software129: 44–56.
50.
LuGChenJ (2020) A new nonlocal macro-meso-scale consistent damage model for crack modeling of quasi-brittle materials. Computer Methods in Applied Mechanics and Engineering362: 1–36.
51.
MaioUDGrecoFLeonettiL, et al. (2022) A cohesive fracture model for predicting crack spacing and crack width in reinforced concrete structures. Engineering Failure Analysis139: 1–18.
52.
ManzoliOLGaminoALRodriguesEA, et al. (2012) Modeling of interfaces in two-dimensional problems using solid finite elements with high aspect ratio. Computers and Structures94-95: 70–82.
53.
ManzoliOLMaedoMABitencourtLA, et al. (2016) On the use of finite elements with a high aspect ratio for modeling cracks in quasi-brittle materials. Engineering Fracture Mechanics153: 151–170.
54.
MarzecITejchmanJMrózZ (2019) Numerical analysis of size effect in RC beams scaled along height or length using elasto-plastic-damage model enhanced by non-local softening. Finite Elements in Analysis and Design157: 1–20.
55.
MazzuccoGXottaGPomaroB, et al. (2018) Elastoplastic-damaged meso-scale modelling of concrete with recycled aggregates. Composites Part B: Engineering140: 145–156.
56.
NaderiSZhangM (2021) Meso-scale modelling of static and dynamic tensile fracture of concrete accounting for real-shape aggregates. Cement and Concrete Composites116: 1–19.
57.
NavidtehraniYBetegónCMartínez-PañedaE (2021) A simple and robust abaqus implementation of the phase field fracture method. Applications in Engineering Science6: 1–12.
58.
ParvathiISMaheshMKamalDR (2022) Xfem method for crack propagation in concrete gravity dams. Journal of The Institution of Engineers (India): Series A103(2): 677–687.
59.
PascuzzoAGrecoFLeonettiL, et al. (2022) Investigation of mesh dependency issues in the simulation of crack propagation in quasi-brittle materials by using a diffuse interface modeling approach. Fatigue & Fracture of Engineering Materials & Structures45(3): 801820.
60.
RodriguesEAManzoliOLBitencourtLA, et al. (2016) 2D Mesoscale model for concrete based on the use of interface element with a high aspect ratio. International Journal of Solids and Structures94-95: 112–124.
61.
RodriguesEAManzoliOLBitencourtLA, et al. (2018) An adaptive concurrent multiscale model for concrete based on coupling finite elements. Computer Methods in Applied Mechanics and Engineering328: 26–46.
62.
RodriguesEAManzoliOLBitencourtLA (2020) 3D Concurrent multiscale model for crack propagation in concrete. Computer Methods in Applied Mechanics and Engineering361: 1–33.
63.
SanchoJMPlanasJCendónDA, et al. (2007) An embedded crack model for finite element analysis of concrete fracture. Engineering Fracture Mechanics74(1-2): 75–86.
64.
SekkateZAboutajeddineASeddoukiA (2022) Elastoplastic mean-field homogenization: Recent advances review. Mechanics of Advanced Materials and Structures29(3): 449474.
65.
ShenLZhangHDi LuzioG, et al. (2022) Mesoscopic discrete modeling of multiaxial load-induced thermal strain of concrete at high temperature. International Journal of Mechanical Sciences232: 1–10.
66.
ShiCShiQTongQ, et al. (2021) Peridynamics modeling and simulation of meso-scale fracture in recycled coarse aggregate (RCA) concretes. Theoretical and Applied Fracture Mechanics114: 1–16.
67.
StanićABrankBIbrahimbegovicA, et al. (2021) Crack propagation simulation without crack tracking algorithm: Embedded discontinuity formulation with incompatible modes. Computer Methods in Applied Mechanics and Engineering386: 114090.
68.
Van MierJVan VlietM (2003) Influence of microstructure of concrete on size/scale effects in tensile fracture. Engineering Fracture Mechanics70(16): 2281–2306.
69.
WanWMVLeeHCHuiPM, et al. (1996) Mean-field theory of strongly nonlinear random composites: Strong power-law nonlinearity and scaling behavior. Phys. Rev. B54: 3946–3953.
70.
WangJGuoXZhangN (2021) Study of the progressive failure of concrete by phase field modeling and experiments. International Journal of Damage Mechanics30(9): 1377–1399.
71.
WinklerBHofstetterGNiederwangerG (2001) Experimental verification of a constitutive model for concrete cracking. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications215(2): 75–86.
72.
WriggersPMoftahSO (2006) Mesoscale models for concrete: Homogenisation and damage behaviour. Finite Elements in Analysis and Design42(7 SPEC. ISS.): 623–636.
73.
WuLHuangDXuY, et al. (2020) A rate-dependent dynamic damage model in peridynamics for concrete under impact loading. International Journal of Damage Mechanics29(7): 1035–1058.
74.
WuSFangS (2009) Modeling cohesive cracks with meshless method. International Journal of Damage Mechanics18(8): 721–737.
75.
XiaYWuWYangY, et al. (2021.) Mesoscopic study of concrete with random aggregate model using phase field method. Construction and Building Materials310: 1–20.
76.
YangDDongWLiuX, et al. (2018) Investigation on mode-I crack propagation in concrete using bond-based peridynamics with a new damage model. Engineering Fracture Mechanics199: 567–581.
77.
YazdiSRSAmiriT (2021) An efficient automatic adaptive algorithm for cohesive crack propagation modeling of concrete structures using matrix-free unstructured Galerkin Finite Volume Method. Computers and Mathematics with Applications97: 237–250.
78.
ZhangHHuangYXuS, et al. (2023) 3d Cohesive fracture of heterogeneous ca-uhpc: A mesoscale investigation. International Journal of Mechanical Sciences249: 108270.
79.
ZhangHLiQZhangX, et al. (2024) Stochastic fracture of concrete composites: A mesoscale methodology. Engineering Fracture Mechanics306: 110234.
80.
ZhouHTianXWuJ (2024) Cracking and thermal resistance in concrete: Coupled thermo-mechanics and phasefield modeling. Theoretical and Applied Fracture Mechanics130(January): 104285.
81.
ZhouRLuY (2018) A mesoscale interface approach to modelling fractures in concrete for material investigation. Construction and Building Materials165: 608–620.
