Abstract:
Fibre Reinforced Plastic (FRP) structures and components are widely used in the modern world
as they offer significant advantages compared to traditional raw materials. As a result, leading
sectors such as aerospace, automobile, marine, naval architecture, civil, and energy have
adopted FRP manufacturing techniques to produce required structural components. However,
FRP products negatively affect the environment since they add harmful waste materials to
nature in different stages of their lifespan. The wastages generated at manufacturing and
disposal phases become significant and a proper mechanism is required to manage them.
Therefore, the applicability of the waste management hierarchy was considered and the
mechanical shredding technique was finalized as the most practical and reliable method to
recycle the FRP wastage. Then, a prototype machine was designed by integrating the shredder
mechanism. The blade profile used for the shredder mechanism was identified as the most
critical component of the machine as it directly related to the properties of recyclates. As a
result, structural integrity analyses were undertaken for five different blade profiles which were
developed varying the hook angle of the cutting tools (0°, 13°, 18°, 16°, and 0°) and three teeth
were considered for the blade profile. The selection of hook angles was based on the experiences
of the authors. The maximum working stress and the deformation pattern of the blade profile
were the main criteria considered and Finite Element Analysis (FEA) was conducted for all the
blade profiles to identify their structural integrity for selecting the most suitable blade profile.
Based on the FEA results, it was able to observe lower working stress and deformation pattern
from the blade profile which consisted of body part and tool tip and has a 0° hook angle as it
was selected to manufacture 24 blade profiles to fabricate the shredding section of the machine.
