Please use this identifier to cite or link to this item: https://hdl.handle.net/10321/4858
Title: Hybrid syntactic foam core cased natural-glass fibre sandwich composite
Authors: Afolabi, Olusegun Adigun 
Keywords: Syntactic foam composites;Hollow glass microspheres;Hybrid sandwich composite;Sandwich syntactic foam composite
Issue Date: May-2023
Abstract: 
Composite materials comprised of two separates with different properties to form a single material
that reflect the properties of the combined materials. Syntactic foam composites (SFC) are made
from the combination of hollow glass microspheres and epoxy resin. They are lightweight and used
as a core in the hybrid sandwich composite. Hollow glass microspheres (HGM) are high strength
microballoons that provide closed cell porosity and help to reduce material weight. SFCs made of
HGM, and resin matrix are used as the core in sandwich composite material and reinforced with
natural or synthetic fiber materials. The sandwich syntactic foam composite (SSFC) has a wide
range of applications in the marine, aerospace, structural, and automobile industry. Therefore, it is
important to investigate their physical, mechanical, thermal, and morphological properties to achieve
high strength and low density. Most of the previous work in literature employed the use of different
fillers and core materials in sandwich composite but are limited in strength because of their high
density. In this study, a single HGM filler was employed as heterogeneous and homogenous by
varying into four different particle sizes to investigate the effect of these particle sizes on the
mechanical and physio-mechanical properties of the SFC used as the core in the SSFC. The effect
of wall thickness and radius ratio of the HGM on the microstructural properties of SFC was also
determined.
The heterogeneous and homogeneous SFC was fabricated by degassing method mixing the epoxy
matrix with HGM filler, the filler was varied into five-volume fractions of 5, 10, 15, 20, and 25%. The
functional group of the HGM filler and the neat epoxy was determined and compared with that of the
SFCs fabricated using Fourier Transform Infrared Spectroscopy (FTIR). The results showed that the
filler contain various functional groups such as hydroxyl group, phenol-OH, aldehyde C-H group,
aromatic proton, epoxy group, which enhanced the bonding process. It was determined that the
intensity of the SFCs for all the volume fractions increased more than the neat epoxy due to the
shifts in the peaks representing the filler and the matrix groups. The physical (density, water
absorption, buoyancy) properties and the mechanical (hardness, tensile, flexural, and impact)
properties of the SFCs improved significantly compared with the neat epoxy. The Scanning Electron
Microscopy (SEM), Dynamic Mechanical Analysis (DMA), and Thermo-gravimetric Analysis (TGA)
were also used to determine the morphological structure, the viscoelastic properties, and
degradation temperature of the HGM and the neat epoxy and compared with the fabricated SFCs.
The surface of the HGM showed the microballoons in their different sizes before separation. The
surface of the SFCs showed the epoxy matrix, matrix porosity, microballoons porosity, and microballoons structure in their mixed state. It was an indication of good interaction between the
epoxy matrix and the HGM filler using degassing processing method. The DMA showed improved
storage and loss modulus values by 9% and above 100% respectively compared to the neat epoxy
and the TGA showed better glass transition Tg values of 4.5% and 2.7% at 20% and 55% weight
loss respectively compared to the neat epoxy. This indicated that good interaction and interfacial
bonding existed between HGM and the epoxy matrix and because of lower density and void content.
The SFC was used as the core to fabricate a lightweight sandwich syntactic foam composite
(SSFC). The SSFC was made into four different orientations (kenaf-SFC-kenaf, as KK; glass –SFCglass, as GG; glass/kenaf – SFC – kenaf/glass, as GK; and kenaf/glass –SFC- glass/kenaf, as KG)
using kenaf and glass fibers as reinforcement. The physical properties (density, water absorption
capacity, and buoyancy), mechanical properties (hardness, tensile, compression, and flexural),
morphological properties (SEM), and acoustic properties were determined. The porosity of KK
increased by 21.6% because the kenaf fiber is less dense and more porous in terms of water
absorption which makes it require higher buoyancy force to stay afloat. The mechanical properties
results showed that GK and KG have the highest hardness, flexural and compressive strength of
70.2%, 74.4%, and 42.7% respectively, while GG has improved tensile strength of 210.96% increase
than KK. The acoustic properties results showed that GG improved in sound level (P) dB by 24.1%
compared to KK, while the sound pressure (Lp) dB does not show a significant difference in the
SSFC.
In conclusion, the degassing processing method of SFCs improved its physical and mechanical
properties by reducing the density using particle distribution analysis (PSA) and particle variation
analysis (PVA) with the aid of a gas pycnometer, and porosity values thereby making it a suitable
core material for the sandwich composite. A novel sandwich syntactic foam composite (SSFC)
material was fabricated by hybridizing the face-sheets in different layering pattens. The SSFC
physical and mechanical properties improved significantly with the use of hybrid fibers. Hence, this
study has demonstrated that for structural and marine purposes, hybrid fibers can perform better as
reinforcement in the sandwich composite than using a single fiber.
Description: 
A thesis submitted in fulfillment of the academic requirements for the degree of
Doctor of Engineering, Durban University of Technology, Durban, South Africa, 2023.
URI: https://hdl.handle.net/10321/4858
DOI: https://doi.org/10.51415/10321/4858
Appears in Collections:Theses and dissertations (Engineering and Built Environment)

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