| dc.description.abstract | Currently, the use of industrial materials heavily relies on non-renewable
metals, necessitating alternative materials that are more cost-effective and of high
quality. Composites possess better mechanical properties, strength, and rigidity
than metals, making them suitable alternatives. To create new and more useful
materials, composites combine two or more materials at a macroscopic level, or
directly visible level. Composites consist of a matrix and fibers; the matrix
functions to bind the fibers and keep them in place. The matrix also has properties
that allow it to easily change shape according to design. Typically, resin
materials act as adhesives for fiber materials and strongly hold the fiber batts
together. Natural and synthetic fibers are used in composites. Natural fiber
composites are highly effective in reducing the use of non-renewable and
petroleum-based materials. Natural composites consist of various materials such
as hemp, bamboo, banana, palm, and others. Fiber reinforcement composites are
used instead of glass. The conducted research is experimental and aims to
determine the tensile strength and characteristics of coconut husk fiber-carbon
fiber sandwich composites. In this study, sandwich composite specimens were
created using vacuum infusion techniques. The production of sandwich composite
specimens involved coconut husk fiber in 0°, 90°, random alkalization, and
random non-alkalization fiber orientations, with an epoxy resin matrix. The
coconut husk fibers were soaked in a NaOH solution for 30 minutes. Afterward,
the fibers were arranged according to the desired fiber orientations. The
manufacturing of the sandwich composites involved carbon fiber - coconut husk
fiber - carbon fiber, which was then processed using the vacuum infusion method.
The highest tensile strength value obtained was 54.07 MPa in the 90° fiber
orientation. The lowest tensile strength value was 33.23 MPa, which was achieved
with the 0° fiber orientation. This is influenced by the effect of fiber orientation
aligned with the direction of load and force, resulting in greater tensile strength.
Conversely, a transverse fiber orientation with the direction of load and force
leads to lower tensile strength. The micro-observation of the composite
characteristics revealed numerous imperfect fiber-matrix interface bonds. This
can be seen from the presence of fiber failures, such as fiber pullout. | en_US |
