Numerical models verification of cracked tubular T, Y and K-joints under combined loads
This paper summarizes the key steps involved in the construction of an accurate and consistent finite element model for general cracked tubular T, Y and K-joints. The joint under consideration contains a surface crack which can be of any length and located at any position along the bracechord int...
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| Main Authors: | , , , |
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| Other Authors: | |
| Format: | Article |
| Language: | English |
| Published: |
2014
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| Subjects: | |
| Online Access: | https://hdl.handle.net/10356/103293 http://hdl.handle.net/10220/19178 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This paper summarizes the key steps involved in the construction of an accurate and consistent
finite element model for general cracked tubular T, Y and K-joints. The joint under consideration
contains a surface crack which can be of any length and located at any position along the bracechord
intersection. Welding details along the brace-chord intersection, compatible with the
American Welding Society (AWS) specifications (2000), are included in the geometrical model. In
order to develop a systematic and consistent modelling procedure, the whole process is divided into
four key steps. They are, namely, (1) construction of a consistent geometrical model of the joint
with welding details, (2) determination of cracked surface to define the semi-elliptical surface crack
profile, (3) generation of well-graded finite element meshes, and (4) stress intensity factor studies
around the crack front. To produce a well-graded finite element mesh, a sub-zone technique is used
in the mesh generation whereby the entire structure is divided into several sub-zones with each zone
consisting of different types of elements and mesh densities. The stress intensity factors (SIFs) are
evaluated using the standard J-integral method. Two full-scale T and K-joint specimens were tested
to failure under axial load (AX), in-plane bending (IPB), and out-of-plane bending (OPB). In the
tests, the rate of crack propagation was monitored carefully using the alternating current potential
drop (ACPD) technique. Using the known material parameters C and m , the experimental SIFs
were obtained, and they are found to be in complete agreement with the computed SIFs obtained
from the generated models. Hence, the proposed finite element models are both efficient and
reliable. |
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