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چکیده
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The static and time-dependent behaviours of adhesively bonded polyethylene Double-Strap (DS) joints were
investigated to assess the viability of this joint configuration relative to the Single-Lap (SL) joints. Both experiments
and finite element simulations are conducted. First, we individually characterise the tensile and creep
behaviour of the adhesive and adherent materials; an epoxy-based adhesive and polyethylene, respectively. This
information is used to develop suitable constitutive models that are then implemented in the commercial finite
element package ABAQUS by means of user material subroutines, UMATs. The numerical models are used to
design the creep tests on the adhesive joints. Afterwards, an extensive experimental campaign is conducted
where we characterise the static and creep behaviour of two joint configurations, SL and DS joints, and three
selected values of the overlap length. In regard to the static case, results reveal an increase in the failure load with
increasing overlap length, of up to 10% for an overlap length of 39 mm. Also, slightly better performance is
observed for the SL joint configuration. For the creep experiments, we show that the DS adhesive joint configuration
leads to much shorter elongations, relative to the SL joints. These differences diminish with increasing
overlap length but remain substantial in all cases. In both joint configurations, the elongation increases with
decreasing overlap length. For instance, increasing the overlap length to 39 mm led to a 50% and a 30%
reduction in elongation for SL and DS joints, respectively. Moreover, the numerical predictions show a good
agreement with the experiments. The stress redistribution is investigated and it is found that the shear stress is
highly sensitive to the testing time, with differences being more noticeable for the DS joint system. The findings
bring insight into the creep behaviour of polyethylene-based adhesive joints, a configuration of notable industrial
interes
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