Influence of specimen size on compression behavior of cement paste and mortar under high strain rates

Xudong Chen; Chen Chen; Pingping Qian; Lingyu Xu

doi:10.1007/s11595-016-1367-y

Journal of Wuhan University of Technology Materials Science Edition ›› 2016, Vol. 31 ›› Issue (2) : 300 -306. DOI: 10.1007/s11595-016-1367-y

Cementitious Materials

Influence of specimen size on compression behavior of cement paste and mortar under high strain rates

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Abstract

Static and dynamic compression tests were carried out on mortar and paste specimens of three sizes (ϕ68 mm×32 mm, ϕ59 mm×29.5 mm and ϕ32 mm×16 mm) to study the influence of specimen size on the compression behavior of cement-based materials under high strain rates. The static tests were applied using a universal servo-hydraulic system, and the dynamic tests were applied by a spilt Hopkinson pressure bar (SHPB) system. The experimental results show that for mortar and paste specimens, the dynamic compressive strength is greater than the quasi-static one, and the dynamic compressive strength for specimens of large size is lower than those of small size. However, the dynamic increase factors (DIF) has an opposite trend. Obviously, both strain rate and size effect exist in mortar and paste. The test results were then analyzed using Weibull, Carpinteri and Bažant’s size effect laws. A good agreement between these three laws and the test results was reached on the compressive strength. However, for the experimental results of paste and cement mortar, the size effect is not evident for the peak strain and elastic modulus of paste and cement mortar.

Keywords

size effect / cement-based materials / dynamic loading / compressive behavior

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Xudong Chen, Chen Chen, Pingping Qian, Lingyu Xu. Influence of specimen size on compression behavior of cement paste and mortar under high strain rates. Journal of Wuhan University of Technology Materials Science Edition, 2016, 31(2): 300-306 DOI:10.1007/s11595-016-1367-y

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References

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[1]	Yon JH, Hawkins N K AS. Strain-rate Sensitivity of Concrete Mechanical Properties[J]. ACI Materials Journal, 1992, 89(2): 146-153.

[2]	Scott BD, Park R, Priestley MJN. Stress-Strain Behaviour of Concrete Confined by Overlapping Hoops at Low and High Strain Rates[J]. ACI Journal Proceedings, 1982, 79(1): 13-27.

[3]	Lok TS, Zhao PJ. Impact Response of Steel Fiber-Reinforced Concrete Using a Split Hopkinson Pressure Bar[J]. Journal of Materials in Civil Engineering, 2004, 16(1): 54-59.

[4]	Hasan ASMZ, Hamid R, Ariffin AK, Gani R. Stress-Strain Behaviour of Normal Strength Concrete Subjected to High Strain Rate[J]. Asian Journal of Applied Sciences, 2010, 3(2): 145-152.

[5]	Rong Z, Sun W, Zhang Y. Dynamic Compression Behavior of Ultrahigh Performance Cement Based Composites[J]. International Journal of Impact Engineering, 2010, 37(5): 515-520.

[6]	Spooner D. C. Stress-strain-time Relationship for Concrete[J]. Magazine of Concrete Research, 1971, 23(75-76): 127-131.

[7]	Ross CA, Tedesco JW, Kuennen ST. Effects of Strain Rate on Concrete Strength[J]. ACI Materials Journal, 1995, 92(1): 37-47.

[8]	Li QM, Meng H. About the Dynamic Strength Enhancement of Concrete-like Materials in a Split Hopkinson Pressure Bar Test[J]. International Journal Solids and Structures, 2003, 40(2): 343-360.

[9]	Tai YS. Uniaxial Compressive Tests at Various Loading Rates for Reactive Powder Concrete[J]. Theoretical and Applied Fracture Mechanics, 2009, 52(3): 14-21.

[10]	Weibull W. Phenomenon of Rupture in Solids[J]. Proceedings of Royal Swedish Institute of Engineering Research, 1939, 153: 1-55.

[11]	Bazant ZP, Chen E-P. Sealing of Structure Failure[J]. American Society of Mechanical Engineers, 1997, 50(10): 593-627.

[12]	Carpinteri A. Sealing Laws and Renormalization Groups for Strength and Toughness of Disordered Materials[J]. International Journal of Solids and Structures, 1994, 31: 291-302.

[13]	Bažant Z, Li Z. Modulus of Rupture: Size Effect due to Fracture Initiation in Boundary Layer[J]. Journal of Structural Engineering, 1995, 121(4): 739-746.

[14]	Carpinteri A. Stress-singularity and Generalized Fracture Toughness at the Vertex of Re-entrant corners[J]. Engineering and Fracture Mechanics, 1987, 26(1): 143-155.

[15]	Dor B-A, Drake JM. The Solute Size Effect in Rotational Diffusion Experiments: A Test of Microscopic Friction Theories[J]. Journal of Chemical Physics, 1988, 89(2): 1019

[16]	Sabins GM, Mirza SM. Size Effects in Model Concretes[J]. Journal of Structural Division, 1979, 105(6): 67-90.

[17]	Kim JK, Eo SH. Size Effect in Concrete Specimens with Dissimilar Initial Cracks[J]. Magazine of Concrete Research, 1990, 64(2): 233-238.

[18]	Kim YJK, Tae S. Application of Size Effect to Compressive Strength of Concrete Members[J]. Sadhana: Academy Proceedings in Engineering Science, 2002, 27(4): 467-484.

[19]	Zhou H. Experimental Study on Size Effect on Concrete Strength[D], 2010 Dalian: Dalian University of Technology.

[20]	Bindiganavile V, Banthia N. Size Effects and the Dynamic Response of Plain Concrete[J]. Journal of Materials in Civil Engineering, 2006, 18(4): 899-1561.

[21]	Zhou JK. Experimental Study on Dynamic Flexural Tensile Mechanical Properties of Full-graded Concrete in High Arch Dam[D], 2007 Nanjing: Hohai University.

[22]	Motaz M Elfahal. Size Effect in Normal and High Strength Concrete Cylinders Subjected to Static and Dynamic Axial Compressive Loads [D], 2005 USA: The Pennsylvania State University, the Graduate School College of Engineering.

[23]	Lai J, Sun W. Dynamic Mechanical Behavior of Ultra-high Performance Fiber Reinforced Concretes[J]. Journal of Wuhan University Technology-Materials Science Edition, 2008, 23(6): 938-945.

[24]	ASTM C 192/C 192M-06 Standard Practice for Making and Curing Concrete Test Specimens in the Laboratory[S], 2006

[25]	Tedesco JW, Powell JC, Ross CA, Hughes ML. A Strain Rate Dependent Concrete Material Model for ADINA[J]. Computers and Structures, 1997, 64(1): 1052-1067.

[26]	Grote DL, Park SW, Zhou M. Dynamic Behavior of Concrete at High Strain Rates and Pressures: I. Experimental Characterization[J]. International Journal of Impact Engineering, 2001, 25(1): 869-886.

[27]	Beppu M, Miwa K, Itoh M, Katayama M, Ohno T. Damage Evaluation of Concrete Plates by High-velocity Impact[J]. International Journal of Impact Engineering, 2008, 35(2): 1419-1426.

[28]	Hartmann T, Pietzsch A, Gebbeken N. A Hydro-code Material Model for Concrete[J]. International Journal of Protective Structures, 2010, 1(4): 443-68.

[29]	Zhou XQ, Hao H. Modeling of Compressive Behaviour of Concretelike Materials at High Strain Rates[J]. International Journal of Solids and Structures, 2008, 45(2): 4648-4661.

[30]	Dilger WH, Koch R, Kowalczyk R. Ductility of Plain and Confined Concrete under Different Strain Rates[J]. ACI Journal Proceedings, 1984, 81(11): 73-81.