Mechanical properties of hybrid honeycomb sandwich structure having facesheets reinforced with flax, kenaf and glass fibers
The honeycomb sandwich structures are consisted of two thin facesheets and a thick honeycomb core. The commercially available sandwich structures used in aircraft interiors are based on synthetic fiber composite facesheet but have limitations like recycling, non-biodegradability and disposal prob...
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Main Author: | |
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Format: | Thesis |
Language: | English |
Published: |
2022
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Subjects: | |
Online Access: | http://psasir.upm.edu.my/id/eprint/104015/1/FK%202022%2093%20IR.pdf http://psasir.upm.edu.my/id/eprint/104015/ |
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Institution: | Universiti Putra Malaysia |
Language: | English |
Summary: | The honeycomb sandwich structures are consisted of two thin facesheets and a thick
honeycomb core. The commercially available sandwich structures used in aircraft
interiors are based on synthetic fiber composite facesheet but have limitations like
recycling, non-biodegradability and disposal problems. These factors push the need for
environmentally friendly materials. From the literature review, it has been identified that
the studies reported on the natural fiber-based composite facesheet with a honeycomb
core are minimal. In this research, a new class of sandwich structures with glass fiber
and natural fiber like flax and kenaf composite facesheet has been fabricated using the
pre-cure fabrication technique. Two layers of the epoxy adhesive film sheet were used
each to bond the top and bottom pre-cured facesheets with an aluminium honeycomb
core. The mechanical properties of the sandwich structure specimens under various loads
(Tensile, edgewise compression, and flexural) with respect to the fiber stacking sequence
and natural fiber treatment were studied. The peel strength was measured through the
climbing drum peel test to analyze the facesheet and core bonding strength. The lowvelocity
impact behavior was analyzed by the drop weight impact test, and the residual
strength of the impacted specimen was characterized through the bending test. Among
the studied configurations, the glass composite facesheet revealed the highest mechanical
performance than the natural composite facesheet. However, the compression strength
and flexural stiffness of the natural fiber were improved when they were combined with
synthetic material by around 38% and 66 % in flax/glass hybrid and 52% and 83% in
kenaf/glass hybrid facesheet, respectively, compared to their non-hybrid composite. The
mechanical performance of the sandwich structure was further enhanced by around 7%
to 15 % when alkali-treated natural fibers were used in a hybrid combination. Overall,
the hybrid combination, which has glass in the outer layer, showed better mechanical
performance than stacking it in the middle. The flax/glass hybrid composite facesheet
exhibited competitive performance by achieving 96% edgewise compression, 92%
flexural facing stress, and 94 % flexural stiffness of the sandwich structure having a glass
composite facesheet. The drum peel strength revealed the competitive strength by using
the pre-cure method of sandwich structure fabrication. The low-velocity impact results revealed that the hybrid composite facesheet showed
promising results compared to the glass composite sandwich structure. The hybrid
composite sandwich structure showed more penetration of the impactor, resulting in
better energy absorption by around 5% to 18 % than the glass composite. The glass and
both hybrid facesheet combinations exhibited similar residual bending performance
when results were compared with their counter non-impacted specimens. Based on the
findings in this work, the results showed the potential of using hybrid reinforcement to
improve the structural performance compared to non-hybrid flax and non-hybrid kenaf
composite and revealed the promising and comparable structural performance compared
with pure glass composite facesheet. The sandwich structure with hybrid composite
facesheet sandwich structure can substitute existing sandwich structures in aerospace and
ground transportation such as railways and the automobile sector with the benefit of low
cost, low density, and low environmental impact. |
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