Triaxial test on concrete material containing accelerators under physical sulphate attack
暂无分享,去创建一个
[1] Xiaoguang Jin,et al. Mechanical responses of shotcrete specimens in direct shear tests , 2018, Construction and Building Materials.
[2] Wang Yanlei,et al. Experimental study on mechanical properties and failure modes of low-strength rock samples containing different fissures under uniaxial compression , 2018, Engineering Fracture Mechanics.
[3] Feng Ouyang,et al. Study on the mechanical properties of the mortars exposed to the sulfate attack of different concentrations under the triaxial compression with constant confining pressure , 2017 .
[4] R. Hooton,et al. Accelerated testing of cementitious materials for resistance to physical sulfate attack , 2017 .
[5] M. F. Najjar,et al. Damage mechanisms of two-stage concrete exposed to chemical and physical sulfate attack , 2017 .
[6] R. Hooton. Current developments and future needs in standards for cementitious materials , 2015 .
[7] A. Soliman,et al. Effect of surface treatment on durability of concrete exposed to physical sulfate attack , 2014 .
[8] A. Soliman,et al. Investigation of concrete exposed to dual sulfate attack , 2014 .
[9] Lei Xue,et al. A Study on Crack Damage Stress Thresholds of Different Rock Types Based on Uniaxial Compression Tests , 2014, Rock Mechanics and Rock Engineering.
[10] Jiang-ying Chen,et al. Study on the evolution of dynamic mechanics properties of cement mortar under sulfate attack , 2013 .
[11] J. Labuz,et al. Mohr–Coulomb Failure Criterion , 2012, Rock Mechanics and Rock Engineering.
[12] H. Ludwig,et al. Field performance of concrete exposed to sulphate and low pH conditions from natural and industrial sources , 2012 .
[13] M. Bassuoni,et al. Physical Salt Attack on Concrete , 2011 .
[14] C. Oguchi,et al. Resistance of plain and blended cement mortars exposed to severe sulfate attacks , 2011 .
[15] Edgardo F. Irassar,et al. Sulfate attack on cementitious materials containing limestone filler — A review , 2009 .
[16] Jian-kang Chen,et al. Damage evolution in cement mortar due to erosion of sulphate , 2008 .
[17] P. Moreira,et al. Performance of Concrete in Aggressive Environment , 2008 .
[18] P. Mehta,et al. Salt Weathering Distress on Concrete Exposed to Sodium Sulfate Environment , 2008 .
[19] Carlo Pistolesi,et al. A Case History: Effect of Moisture on the Setting Behaviour of a Portland Cement Reacting with an Alkali-free Accelerator , 2007 .
[20] T. Cerulli,et al. Effects of setting regulators on the efficiency of an inorganic acid based alkali-free accelerator reacting with a Portland cement , 2007 .
[21] Cheng-Tzu Thomas Hsu,et al. Behavior of high strength concrete with and without steel fiber reinforcement in triaxial compression , 2006 .
[22] B. Möser,et al. Influence of sulfate solution concentration on the formation of gypsum in sulfate resistance test specimen , 2006 .
[23] G. Scherer. Stress from crystallization of salt , 2004 .
[24] Ming Cai,et al. Generalized crack initiation and crack damage stress thresholds of brittle rock masses near underground excavations , 2004 .
[25] Jean Marc Christian Tulliani,et al. Sulfate attack of concrete building foundations induced by sewage waters , 2002 .
[26] Armen Der Kiureghian,et al. Sulfate Attack of Concrete: Reliability Analysis , 2001 .
[27] P K Mehta,et al. Sulfate attack on concrete separating myths from reality , 2000 .
[28] Farhad Ansari,et al. HIGH - STRENGTH CONCRETE SUBJECTED TO TRIAXIAL COMPRESSION , 1998 .
[29] C. Martin,et al. Seventeenth Canadian Geotechnical Colloquium: The effect of cohesion loss and stress path on brittle rock strength , 1997 .
[30] T. Mellors. NORWEGIAN TUNNELLING METHODS , 1995 .
[31] N. A. Chandler,et al. The progressive fracture of Lac du Bonnet granite , 1994 .
[32] A. A. Colville,et al. Efflorescent mineral assemblages associated with cracked and degraded residential concrete foundations in Southern California , 1989 .
[33] G. L. Kalousek,et al. Concrete for long-time service in sulfate environment , 1972 .