Low cycle fatigue analysis of marine structures
Fatigue fracture has affected the aircraft industry largely due to the high cyclic loadings of the airplane. However, in recent years, marine structures are found to fail at loading cycles lower than the design life. This brings to the attention of researchers about low cycle fatigue which occur at...
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sg-ntu-dr.10356-539802023-03-04T18:40:21Z Low cycle fatigue analysis of marine structures Ng, Wen Hao. Ong Lin Seng School of Mechanical and Aerospace Engineering DRNTU::Engineering::Materials::Material testing and characterization Fatigue fracture has affected the aircraft industry largely due to the high cyclic loadings of the airplane. However, in recent years, marine structures are found to fail at loading cycles lower than the design life. This brings to the attention of researchers about low cycle fatigue which occur at cycles lesser than 104 cycles. Fatigue damage accumulated in the lower cycle life can be recorded and assessed, thereby predicting the failure of the structure. The damage is due to the stresses at notches of higher stress concentrations. At these notches, yielding occurs even though the macrostructure may still be in the elastic regions. Therefore, approaches used to obtain the pseudo stresses at the notches are done via the strain values. The first approach using the empirical Neuber’s relationships provide a fast and indicative representation of the pseudo stresses experienced due to the nominal loadings. The other approach is using non-linear finite element analysis. Both of which utilizes ANSYS Parametric Design Language to obtain the required values. The model joint used in this analysis is a cruciform joint which is common in most marine structures due to the use of longitudinal and transverse backings to provide higher sectional modulus. In this report, the approaches will be adopted, compared and discussed. It shows that the empirical Neuber’s approach results in a set of pseudo stress values lower than the non-linear approach and hence a practical fatigue experiment might be needed to justify this. Also, it is derived that that there is minimal effect of modelling the notch radius on the pseudo stress values. However, the effect of variation of Young’s Modulus due to undermatching or overmatching of welds can have considerable effect on the pseudo stresses. Bachelor of Engineering (Mechanical Engineering) 2013-06-10T09:13:38Z 2013-06-10T09:13:38Z 2013 2013 Final Year Project (FYP) http://hdl.handle.net/10356/53980 en Nanyang Technological University 78 p. application/pdf |
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DRNTU::Engineering::Materials::Material testing and characterization Ng, Wen Hao. Low cycle fatigue analysis of marine structures |
| description |
Fatigue fracture has affected the aircraft industry largely due to the high cyclic loadings of the airplane. However, in recent years, marine structures are found to fail at loading cycles lower than the design life. This brings to the attention of researchers about low cycle fatigue which occur at cycles lesser than 104 cycles.
Fatigue damage accumulated in the lower cycle life can be recorded and assessed, thereby predicting the failure of the structure. The damage is due to the stresses at notches of higher stress concentrations. At these notches, yielding occurs even though the macrostructure may still be in the elastic regions. Therefore, approaches used to obtain the pseudo stresses at the notches are done via the strain values. The first approach using the empirical Neuber’s relationships provide a fast and indicative representation of the pseudo stresses experienced due to the nominal loadings. The other approach is using non-linear finite element analysis. Both of which utilizes ANSYS Parametric Design Language to obtain the required values.
The model joint used in this analysis is a cruciform joint which is common in most marine structures due to the use of longitudinal and transverse backings to provide higher sectional modulus.
In this report, the approaches will be adopted, compared and discussed. It shows that the empirical Neuber’s approach results in a set of pseudo stress values lower than the non-linear approach and hence a practical fatigue experiment might be needed to justify this. Also, it is derived that that there is minimal effect of modelling the notch radius on the pseudo stress values. However, the effect of variation of Young’s Modulus due to undermatching or overmatching of welds can have considerable effect on the pseudo stresses. |
| author2 |
Ong Lin Seng |
| author_facet |
Ong Lin Seng Ng, Wen Hao. |
| format |
Final Year Project |
| author |
Ng, Wen Hao. |
| author_sort |
Ng, Wen Hao. |
| title |
Low cycle fatigue analysis of marine structures |
| title_short |
Low cycle fatigue analysis of marine structures |
| title_full |
Low cycle fatigue analysis of marine structures |
| title_fullStr |
Low cycle fatigue analysis of marine structures |
| title_full_unstemmed |
Low cycle fatigue analysis of marine structures |
| title_sort |
low cycle fatigue analysis of marine structures |
| publishDate |
2013 |
| url |
http://hdl.handle.net/10356/53980 |
| _version_ |
1759854068879065088 |