High-Performance Concrete under Biaxial and Triaxial Loads

by T. Hampel, (corresponding author), Research Associate; Dept. of Civil Engineering, Technische Universität Dresden, George-Bähr-Str. 1, 01062 Dresden, Germany, Torsten.Hampel@tu-dresden.de,
K. Speck, Research Associate; Dept. of Civil Engineering, Technische Universität Dresden, George-Bähr-Str. 1, 01062 Dresden, Germany., Kerstin.Speck@tu-dresden.de,
S. Scheerer, Research Associate; Dept. of Civil Engineering, Technische Universität Dresden, George-Bähr-Str. 1, 01062 Dresden, Germany., Silke.Scheerer@tu-dresden.de,
R. Ritter, Research Associate; Dept. of Civil Engineering, Technische Universität Dresden, George-Bähr-Str. 1, 01062 Dresden, Germany., Robert.Ritter@tu-dresden.de,
M. Curbach, (M.ASCE), Full Professor; Dept. of Civil Engineering, Technische Universität Dresden, George-Bähr-Str. 1, 01062 Dresden, Germany., Manfred.Curbach@tu-dresden.de,


Serial Information: Issue 11, Pg. 1274-1280


Document Type: Journal Paper

Abstract: This paper presents results of multiaxial strength tests on various high-performance concretes (HPCs) with uniaxial compressive strength from 58 to 94 MPa. A large number of stress ratios of biaxial compression-tension, compression-compression, and triaxial compression tests were investigated. Experiments were performed using a servohydraulic jack with variable stress ratios, whereas steel brushes were used to transfer the load to the specimen. With increasing uniaxial strength the obtained normalized multiaxial strength decreases. The results, along with mathematical approximations, are discussed for the description of failure. The formulated failure criteria for HPC can be used, e.g., in finite-element simulations. The increase in strength by acting a multiaxial compressive stress state or the decrease in strength by acting a compressive-tensile stress state related to the uniaxial compressive strength can be considered and enables a better material exploitation.

Subject Headings: Biaxial loads | Triaxial loads | Compressive strength | High-performance concrete | Compression | Compression tests | Failure analysis | Triaxial tests | Finite element method |

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