In this study, a new type of concrete test, called the tube-squash test, that achieves, without fracturing under high pressures, enormous shear and deviatoric strains is developed. Tubes 76.2 mm and 63.5 mm in diameter, with wall thicknesses of 14.22 mm and 12.7 mm, made of highly ductile steel alloy, are filled with concrete. After curing, they are squashed in a high-capacity compression testing machine to half their original length, forcing the tubes to bulge. Normal and high-strength concretes at hydrostatic pressures of approximately 125 MPa are found to be remarkably ductile, capable of sustaining shear angles over 70 deg (1.225 rad) without visually detectable cracks or voids, though significant distributed mechanical damage does take place. Tests of cores drilled out from squashed tubes show that, after such enormous deformation, the concrete still retains approximately 25-35% of its initial uniaxial compression strength and initial stiffness and approximately 10-20% of its initial split-cylinder tensile strength. What makes the tube-squash test meaningful is the development of a relatively simple method of test results analysis that avoids solving the inverse nonlinear finite strain problem with finite elements despite high nonuniformity of the strain field. Approximate stress-strain diagrams of concrete at such large shear angles and strains are obtained by finite strain analysis of the middle cross section utilizing the measured lateral expansion, axial shortening, and bulge profile. The finite strain triaxial plastic constitutive law of the steel alloy needs to be determined first, and a method to do that is also formulated. Approximate stress-strain diagrams and internal friction angles of concrete are deduced from the test without making any hypotheses about its constitutive equation. Tests of tubes filled by hardened portland cement paste and cement mortar, as well as tubes with a snugly fitted limestone insert, show similar ductile shear strains and residual strengths.
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