Manufacturing of full-scale fibre reinforced thermoplastic composite hockey stick prototype
Composites are an attractive material for manufacturing in a wide range of industries, providing high levels of mechanical performance at a low weight. Carbon fiber has long been the reinforcement material of choice, paired with thermosetting epoxy matrices to create the lightweight, yet strong...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2023
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| Online Access: | https://hdl.handle.net/10356/167119 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Composites are an attractive material for manufacturing in a wide range of industries, providing
high levels of mechanical performance at a low weight. Carbon fiber has long been the
reinforcement material of choice, paired with thermosetting epoxy matrices to create the
lightweight, yet strong composite parts that are attractive for use in the high-performance sporting
goods industry. Ice hockey sticks have adopted the use of carbon fiber composite materials for its
construction, making use of thermosetting epoxies as the resin matrix, and are conventionally
manufactured through the use of fiber prepregs. An alternative manufacturing process, Bladder Assisted Resin Transfer Molding (BARTM) was trialed in this project for the manufacturing of a
full-scale shaft. In addition, a novel thermoplastic resin system, Elium®, was also trialed as an
alternative to traditional epoxies. Elium® has the unique property of being able to be processed at
room temperature, with a short curing time, unlike other thermoplastic resins. The thermoplastic
nature also affords Elium®-based composites greater ductility and damage resistance, properties
that are desirable for use in sporting goods. The properties of composite sandwich structures
modelled after the hockey stick blade were investigated through flat-scale trials with Elium® and
compared against a selection of thermosetting epoxies representing comparable commercially
available solutions. The flat-scale testing showed that Elium® composite sandwich flexural
performance was lower when assembled with a PVC foam core as compared to a PMI core, with
the CF/EL/PVC and CF/EL/PMI configurations reaching peak loads of 97.9 N and 217.0 N
respectively. Across resin systems, Elium® had a lower flexural strength than its epoxy
counterparts, with the HTEP configuration achieving 29% higher peak load and the RTEP
configuration achieving 13% higher peak load for the 3 mm PMI core. Although the flexural
performance of Elium® was lower than the epoxies, it still presents an attractive potential for
manufacturers as it can be processed at room temperature and also has a short processing time.
This grants it desirable manufacturing processing characteristics superior to its competitors, and
can be attractive for applications where high strength is not critical. Through this current Final
Year Project study, a new method of producing composite parts was realized which can be adopted
by manufacturers for use in the mass-production of composites in a wide range of industries. |
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