A Modulus Variation Model of Concrete under External Sulfate Attack: New Perspective from Statistical Evolution of Microcracks

Hao Zhang , Wei She

Journal of Wuhan University of Technology Materials Science Edition ›› 2018, Vol. 33 ›› Issue (6) : 1465 -1471.

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Journal of Wuhan University of Technology Materials Science Edition ›› 2018, Vol. 33 ›› Issue (6) : 1465 -1471. DOI: 10.1007/s11595-018-1992-8
Cementitious Materials

A Modulus Variation Model of Concrete under External Sulfate Attack: New Perspective from Statistical Evolution of Microcracks

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Abstract

A numerical model was proposed to describe the modulus variation of mortar exposed to external sulfate attack and the effectivity was verified by experiments. The model joints statistical evolution of microcracks to effective elastic modulus with microcracks and is applied to predict the damage degree of mortar attacked by sulfate. The experimental results show that the model can predict the modulus variation development of the specimen and the microcraks density. The elastic modulus values calculated by the model are consistent with that measured by experiments. The model focuses on nucleation of microcracks and finds that the theoretical results of microcracks number density show a linear growth over time in mortar. Compared with other sulfate attack damage model, this model provides a more suitable damage evolution equation that can be used to analyze the chemically assisted damage.

Keywords

sulfate attack / effective elastic modulus / microcracks number density / damage evolution

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Hao Zhang, Wei She. A Modulus Variation Model of Concrete under External Sulfate Attack: New Perspective from Statistical Evolution of Microcracks. Journal of Wuhan University of Technology Materials Science Edition, 2018, 33(6): 1465-1471 DOI:10.1007/s11595-018-1992-8

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References

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

Mehta PK, Monteiro PJM. Concrete: Microstructure, Properties and Materials[M]. 3rd ed, 2006 New York: McGraw–Hill.
[2]

Irassar EF, Bonavetti VL, Gonzalez M. Microstructural Study of Sul–Fate Attack on Ordinary and Limestone Portland Cements at Ambient Temperature[J]. Cement and Concrete Research, 2003, 33: 31-41.
[3]

Gollop RS, Taylor HFW. Microstructural and Microanalytical Studies of Sulfate Attack. I. Ordinary Portland Cement Paste[J]. Cement and Concrete Research, 1992, 22: 1 027-1 038.

[4]

Cohen MD. Modeling of Expansive Cements[J]. Cement and Concrete Research, 1983, 13: 519-528.

[5]

Cohen MD. Theories of Expansion in Sulfoaluminate–type Expansion Cements: Schools of Thought[J]. Cement and Concrete Research, 1983, 13: 809-818.

[6]

Skalny J, Marchand J, Odler I. Sulfate Attack on Concrete[M]. 2002
[7]

Evans LS. Salt Crystallization and Rock Weathering[J].Review of Geomorphologie Dynamique, 1969, 70: 153-177.
[8]

Scherer GW. Stress from Crystallization of Salt[J]. Cement and Concrete Research, 2004 613-1 624.
[9]

Yang R, Lawrence CD, Lynsdale CJ, et al. Delayed Ettringite Formation in Heat–cured Portland Cement Mortars[J]. Cement and Concrete Research, 1999, 29: 17-25.

[10]

Prince W, Espangne M, Aitcin PC. Ettringite Formation: A Crucial Step in Cement Super Plasticizes Compatibility[J]. Cement and Concrete Research, 2003, 33: 635-641.

[11]

Tixier R, Mobasher B. Modeling of Damage in Cement–based Materials Subjected to External Sulfate Attack. I: Formulation[J]. Journal of Material of Civil Engineering, 2003, 15: 305-313.
[12]

Tixier R, Mobasher B. Modeling of Damage in Cement–based Materials Subjected to External Sulfate Attack. II: Comparison with Experiments [J]. Journal of Material of Civil Engineering, 2003, 15: 314-322.
[13]

Krajcinovic D, Basista M, Mallick K. Chemo–micromechanics of Brittle Solid[J]. Journal of the Mechanic and the Physic of Solid, 1992, 40: 965-990.

[14]

Basista M, Weglewski W. Micromechanical Modeling of Sulphate Corrosion in Concrete: Influence of Ettringite Forming Reaction[J]. Theoretical Applied Mechanic, 2008, 35: 29-52.

[15]

Chen JK, Qian C, Song H. A New Chemo–mechanical Model of Damage in Concrete under Sulfate Attack[J]. Construction and Building Material, 2016, 115: 536-543.

[16]

Sarkar S, Mahadevan S, Meeussen JCL. Numerical Simulation of Cementitious Materials Degradation under External Sulfate Attack[J]. Cement and Concrete Composites, 2010, 32: 241-252.

[17]

Leea H, Codyb RD, Codyb AM, et al. The Formation and Role of Ettringite in Iowa Highway Concrete Deterioration[J]. Cement and Concrete Research, 2005, 35: 332-343.

[18]

Paul B, Hooton RD. Ettringite and Thaumasite Formation in Laboratory Concretes Prepared Using Sulfate–resisting[J]. Cement and Concrete Composites, 2002, 24: 361-370.

[19]

Krajcinovic D. Damage Mehcanics[J]. Mechanics and Material, 1989, 8: 117-197.

[20]

Huang Y, Hu K, Chandra A. A Generalized Sellf–consistent Mechanics Method for Microcracked Solid[J]. Journal of the Mechanic and the Physic of Solid, 1994, 42: 1 273-1 291.

[21]

Ke FJ, Bai YL, Xia MF. Formulation of Statistical Evolution of Microcracks in Solid[J]. China Science(A), 1990, 20: 621-631.
[22]

Curran DR, Seaman L, Shockey DA. Dynamic Failure of Solids[J]. Physics Report, 1987, 147: 253-388.

[23]

Karihaloo BL. Fracture Mechanics and Structural Concrete[M]. 1995 London: Longman Scientific & Technical.
[24]

Budiansky B, Vonnell R. Elastic Moduli of a Crack Solid[J]. International Journal of Solids Structure, 1976, 12: 81-97.

[25]

Su XP. Research on the Concrete Durability Due to Salinized Soil in the Western Region of Jilin Province[D]. 2013 Jilin: Jilin University.
[26]

Jin ZQ. Durability and Service Life of Concrete Exposed to Harsh Environment in West of China[D]. 2006 Jiangsu: Southeast University.
[27]

Cao YH. Study on the Evolution of Dynamic Mechanics Properties of Mortar under Sulfate Erosion[D]. 2007 Zhejiang: Ningbo University.
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