The investigation and reconciliation of the dynamic characteristics of a thin plate laser spot welded joint structure / Mohd Hakimi Othman
In the structural dynamic analysis, having accurate information on the dynamic characteristics of a structure is vital to help engineers or modal analysts to understand the structure's characteristics. The dynamic characteristics can be identified by the use of the finite element method (FEM) a...
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| Format: | Thesis |
| Language: | English |
| Published: |
2017
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| Subjects: | |
| Online Access: | https://ir.uitm.edu.my/id/eprint/67570/1/67570.pdf |
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| Summary: | In the structural dynamic analysis, having accurate information on the dynamic characteristics of a structure is vital to help engineers or modal analysts to understand the structure's characteristics. The dynamic characteristics can be identified by the use of the finite element method (FEM) and also by the experimental modal analysis (EMA). However, it is challenging for the modal analysts to reliably and accurately identify the dynamic characteristics of the structure merely using the finite element method, especially with the presence of mechanical joints such as spot welds, rivets, and bolted joints in the structure. The work presented in this thesis was primarily to investigate appropriate element connectors to be used for modelling and to reconcile the dynamic characteristics of a thin plate, laser spot welded structure via the finite element and model updating method. The initial finite element models of the welded structure were developed using three different element cpnnectors (RBE, ACM and CWELD) and the models were then used to predict the dynamic characteristics of the structure. Meanwhile, the measured dynamic characteristics were obtained using an impact hammer and roving accelerometers under free-free boundary conditions. The measured results were then employed in the updating method for reconciling the initial finite element model with the test structure. The largest total error of the discrepancy between the predicted and measured natural frequencies was recorded in the RBE based initial finite element model (47.61%) followed by ACM2 based initial finite element model (23.28%). The CWELD based initial finite element model with the smallest total error (22.66%) was found to be the most appropriate model to represent the thin plate laser spot welded structure and to then be used for model updating. The CWELD based initial finite element model was successfully reconciled to the test structure within a satisfactory, acceptable level of error. The results suggest that CWELD element connectors have a better capability to represent the laser spot welds in the structure in comparison with other element connectors. The improvement in the CWELD based initial finite element model reveals that the finite element model updating can be used successfully to reconcile the initial finite element model with appropriate modelling of the test structure. |
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