Skip to main content

IMIS

A new integrated search interface will become available in the next phase of marineinfo.org.
For the time being, please use IMIS to search available data

 

[ report an error in this record ]basket (0): add | show Print this page

Experimental and numerical analysis of strength and deformation of large-scale steel-composite adhesive joints subjected to fatigue followed by static loading
Jaiswal, P.R.; Kumar, R.I.; Bormann, F.; Juwet, T.; Luyckx, G.; Mouton, L.; Verhaeghe, C.; De Waele, W. (2024). Experimental and numerical analysis of strength and deformation of large-scale steel-composite adhesive joints subjected to fatigue followed by static loading. Strain Early View: 18. https://dx.doi.org/10.1111/str.12468
In: Strain. British Society for Strain Measurement: Swansea. ISSN 0039-2103; e-ISSN 1475-1305, more
Peer reviewed article  

Available in  Authors 

Author keywords
    digital image correlation; fibre optic sensor; finite element modelling; MMA adhesive; strain

Authors  Top 
  • Jaiswal, P.R., more
  • Kumar, R.I., more
  • Bormann, F.
  • Juwet, T.
  • Luyckx, G.
  • Mouton, L.
  • Verhaeghe, C.
  • De Waele, W., more

Abstract

    This work reports a study of the fatigue behaviour and quasi-static strength of full-scale adhesively bonded steel-composite joints. Three joints with an approximately 10-mm-thick layer of methyl methacrylate adhesive were manufactured in dockyard conditions. One specimen was tensile tested till failure, while two specimens were subjected to ~3.5 million fatigue cycles, followed by a residual tensile test supported with digital image correlation. The shear, longitudinal and peel strain values within the adhesive bondlines are significantly higher at the gripped sides due to the asymmetrical design of the steel brackets. All specimens showed a significantly higher shear strength than the design values defined by the shipbuilder. Fibre Bragg sensors monitored strains at steel and composite constituents and allowed to detect damage onset and evolution in tensile tested specimens. A finite element model of the joint was developed with material and interface properties based on dedicated small-scale experiments. The simulation results of strains during a static load test corresponded closely to the DIC measurements. All specimens failed near the composite-adhesive interface due to delamination of the composite panel.


All data in the Integrated Marine Information System (IMIS) is subject to the VLIZ privacy policy Top | Authors