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A platform for research: civil engineering, architecture and urbanism
Flexural strength and energy absorption of carbon-fiber–aluminum-honeycomb composite sandwich reinforced by aluminum grid
Abstract The full potential of carbon-fiber and aluminum-honeycomb sandwich panels and structures has been limited by the huge property mismatch between the high-stiffness carbon fiber and low-stiffness aluminum honeycomb. In this study, an orthogrid structure was added into the sandwich structure to raise the stiffness of soft honeycomb and therefore reduce the interfacial mismatch. The core then became an aluminum orthogrid structure filled with aluminum-honeycomb blocks. Three point bending tests were conducted to compare carbon fiber sandwiches with different types of core: (1) aluminum-honeycomb core; (2) aluminum-plate orthogrid core; and (3) aluminum-plate orthogrid core filled by aluminum-honeycomb blocks. The honeycomb filled orthogrid core sandwich was a bit heavier than the honeycomb or grid sandwich, but the critical load, specific strength and energy absorption ability were all improved. The results indicated that the honeycomb filled orthogrid core sandwich with carbon fiber face sheet could provide improved structural properties for thin walled engineering structures.
Highlights An orthogrid was added into the honeycomb core for reinforcement. 3-Point bending test was conducted to examine the honeycomb filled orthogrid core. The critical load and energy absorption were improved by adding an orthogrid. The specific strength of honeycomb filled orthogrid sandwich is higher as well. In addition, the interfaces were successfully toughened by aramid fiber tissue.
Flexural strength and energy absorption of carbon-fiber–aluminum-honeycomb composite sandwich reinforced by aluminum grid
Abstract The full potential of carbon-fiber and aluminum-honeycomb sandwich panels and structures has been limited by the huge property mismatch between the high-stiffness carbon fiber and low-stiffness aluminum honeycomb. In this study, an orthogrid structure was added into the sandwich structure to raise the stiffness of soft honeycomb and therefore reduce the interfacial mismatch. The core then became an aluminum orthogrid structure filled with aluminum-honeycomb blocks. Three point bending tests were conducted to compare carbon fiber sandwiches with different types of core: (1) aluminum-honeycomb core; (2) aluminum-plate orthogrid core; and (3) aluminum-plate orthogrid core filled by aluminum-honeycomb blocks. The honeycomb filled orthogrid core sandwich was a bit heavier than the honeycomb or grid sandwich, but the critical load, specific strength and energy absorption ability were all improved. The results indicated that the honeycomb filled orthogrid core sandwich with carbon fiber face sheet could provide improved structural properties for thin walled engineering structures.
Highlights An orthogrid was added into the honeycomb core for reinforcement. 3-Point bending test was conducted to examine the honeycomb filled orthogrid core. The critical load and energy absorption were improved by adding an orthogrid. The specific strength of honeycomb filled orthogrid sandwich is higher as well. In addition, the interfaces were successfully toughened by aramid fiber tissue.
Flexural strength and energy absorption of carbon-fiber–aluminum-honeycomb composite sandwich reinforced by aluminum grid
Shi, Shanshan (author) / Sun, Zhi (author) / Hu, Xiaozhi (author) / Chen, Haoran (author)
Thin-Walled Structures ; 84 ; 416-422
2014-07-19
7 pages
Article (Journal)
Electronic Resource
English
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