Issue 20

H. Jasarevic et alii, Frattura ed Integrità Strutturale, 20 (2012) 32-35; DOI: 10.3221/IGF-ESIS.20.04 34 C RACK TRAJECTORIES SIMULATION CASE STUDIES Sandstone he test results on macroscopically identical sandstone discs tested in indirect tensile strength test (ASTM [8] and ISRM [9]) were reported by Jasarevic at al [10, 11]. 50.8 mm diameter and 25.4 mm thickness (t/D = 0.5) discs cut from a block of Torry Buff sandstone are used for the tests. The Torry Buff material tested is a very fine-grained porous, consolidated sandstone, porosity ~19%, permeability ~3-millidarcy, Young’s modulus 10.5 MPa (measured on three 44.5-mm diameter, 92.4-mm length cylinders) and dry unconfined compressive strength ~40 MPa. Total of ten discs were tested and observed crack trajectories are shown in Fig. 1 (Jasarevic, 2009a). Results clearly show that crack trajectories are random (i.e. no two coincide) satisfying SFM formalism described before. Result of computer simulated crack trajectories for fractal dimension d=1.2 and D=0.01 (see Jasarevic [10] for calculation details) is shown in Fig. 2 for comparison. Concrete The test results for study of size effects in concrete fracture on multiple sizes of macroscopically identical compact tension specimens tested in the quasi-static splitting tensile test (ramp test) were reported by Issa at al [6, 12]. The specimens were positioned so that the notch was at the top and the actuator applied the load downward through a wedge at an angle of 8.7  . A wedge applied the load on the rollers that passed through rectangular cylinders. The rectangular cylinders had the same dimensions as the rectangular part of the notch. The downward force applied through a wedge was translated into a splitting tensile force through the rollers. The test was conducted in the displacement control mode at a rate of loading of 0.125 mm/min. Some of conclusions of this work are that concrete fracture surfaces with the larger aggregate sizes appear to have a higher roughness than those with smaller aggregate sizes. The crack path is less tortuous for geometrically identical specimens with smaller size aggregates. Similarly, the crack path deviates from the centerline of the specimen to a less degree for the smaller size aggregates than that for the larger ones. Crack trajectories for 6 macroscopically identical specimens with maximum aggregate size of ¾ in. (19mm) are shown in Fig. 3. Same as for sandstone, experimentally observed crack path appears to be random, i.e., no two macroscopically identical specimens exhibit the same fracture path. Result of computer simulated crack trajectories for fractal dimension d=1.1 and D=0.05 (see Issa at al [12] and Hammad and Issa [13] for calculation details) is shown in Fig. 4 for comparison. Figure 3 : Experimentally observed crack trajectories in concrete specimens. Figure 4 : Simulated concrete crack trajectories for d=1.1 and D=0.05 . C ONCLUSION andstone and concrete as brittle materials satisfy the SFM formalism in which no two fracture paths for macroscopically identical specimens coincide. The “diffusion approximation” of the crack diffusion model cannot be applied to crack trajectories experimentally observed in sandstone and concrete, since their fractal dimension is less then 1.5. Instead fractional integration of Wiener processes together with parameters extracted from experiments was T S