Issue 42

S. Seitl et alii, Frattura ed Integrità Strutturale, 42 (2017) 56-65; DOI: 10.3221/IGF-ESIS.42.07 57 modification. The importance of rehabilitating the concrete structures has become obvious especially in some regions of the world that have been suffering from e.g. earthquakes, flooding, military conflict, terrorist attacks etc. Repairing these structures instead of destroying and rebuilding them could save time and finance from the one side and save the nature (do not need preparation of new concrete etc.) from the other side. The structural assessment is carried out by evaluating the concrete quality indicate by e.g. compressive strength, fracture toughness, fracture energy, Young’s modulus, tensile splitting strength, etc. For evaluation of all fracture mechanical properties of materials like concrete, standardized methodology is not published yet. There are norms: ACI [1] and [8] for compressive strength, [9] for flexural strength of test specimens, tensile splitting strength [10], Young’s modulus [7], recommendations for fracture energy determination for three-point-bend (TPB) specimen in RILEM [24] and for wedge splitting test (WST) specimen in [18] or tensile strength and fracture toughness [33]. In literature we can found that researchers used various geometries for measurement of concrete fracture properties , e.g. TPB [13,17], WST [4, 21], the combination of TPB and WST [29-30], disk shaped compact tension [14, 32] and another configurations can be found in handbooks e.g. [22, 28]. (a) (b) Figure 1 : Schemes of modified compact tension (a) and three-point bend test (b) with the characteristic dimensions Widely used testing procedure for measuring the fracture properties of diverse types of materials is a compact tension (CT) test see in ASTM Standard E-399 [2], plastics (ASTM Standard D5045-14) or composite materials with limited orthotropy [23]. Nevertheless, tests applied to concrete samples have not attained satisfactory results leading to the failure prematurely. Wagoner et al. [32] carried out the CT test on concrete specimens and the premature failure was attained in 50% tested cases at the pulling load holes. Modify compact tension (MCT) test is a different version of CT test to reliably obtain the fracture properties of quasi-brittle materials (like the concrete). The specimen morphology is adapted to avoid premature failures during testing procedure. The load holes are replaced for two longitudinal steel bars, inserted in the specimen during its casting stage, to avoid generation of local fracture at load holes, the geometry of MCT and TPB specimens are shown schematically in Fig. 1.a and b, respectively. For fracture analysis of a test specimen, the major parameters that characterize the stress and strain fields around the crack tip should be known for the test specimen. As MCT test is a very recent methodology of calculus, detailed studies must be carried out to deepen on the reliability of the results. In this way, Seitl and Viszlay [26] provided calibration curves corresponding to four fracture mechanical parameters (stress intensity factor, K I , T -stress, crack opening displacement, COD, and crack mouth opening displacement, CMOD) for cement based materials varying the elasticity modulus ( E ). So significant amount of evaluations is measured by means of finite element model of the MCT test developed for them. The results were determined from the aforementioned model for 2D and 3D simulations and discussed the obtained values. In this paper, experimental measured data from tests performed by Cifuentes et al. [5, 6] to assess the use of MCT test for measuring the fracture energy ( G F ) on normal-strength concrete (NSC) and high-strength concrete (HSC) will be processed and analyzed for various crack length to width ratios and the values of fracture mechanics parameters ( K I and T -stress) will be evaluated and discussed using the outputs-calibration curves- from previous performed numerical simulations. Afterwards, an assessment of all procedures used to calculate fracture parameters will be performed. The rest of this paper is organized as follows. Details of experimental campaign, normal and high strength concrete mechanical properties and dosages are shown in Section 2. The numerical simulations and related calibration curves