Issue 52

B. E. Sobrinho et alii, Frattura ed Integrità Strutturale, 52 (2020) 51-66; DOI: 10.3221/IGF-ESIS.52.05 60 Figure 14: Damaged Beam 2 (V5E). Figure 15: Plot of displacements for the intact and damaged Beam 1 - V3E (load 4350N). In the following numerical results obtained from simulations with BEAM3 and SHELL63 elements, Euler-Bernoulli theory, as well as through a proposed simulation that relates the intact model to the damaged experimental model, whose goal is to identify damaged elements in the structure, are presented in Tab. 3. Item Beam Load (N) Elements / Analyses Iterations Damaged Elements % of Damage Objective Function Minimum 1 Beam 1 (V3E) 4350 BEAM3 50th 5 and 12 45% 0.72466525 SHELL63 50th 5 and 12 45% 2.01215635 Euler-Bernoulli 50th 5 and 12 45% 183.19207908 Experimental 100th 5 and 12 45% 148.31064460 Table 3: Results for the Beam1 (V3E). Fig. 16 shows the analyses of the problem solution using the BEAM3 element, which provides values in agreement with the considered problem, finding few residues. In Fig. 17, using the SHELL63 element, it is verified that the damaged values of the elements are in agreement with the considered problem, where there are some distortions, probably, due to not null displacements close to supports. Fig. 18 shows the analyses of the problem solution and the damage values of the elements obtained by using Euler-Bernoulli theory. These values are in agreement with the problem proposed with minor variations, but with good results. In Fig. 19, the results obtained from the proposed numerical simulation of the intact beam are compared to those obtained by the experimental damaged beam. These comparisons between the intact plot analyses and the damaged (experimental) one are provided in terms of displacements along beam length for Beam 1 (V3E), in correspondence of a load application of 4350N.