Analytical optimization of a nanoparticle of microstructural fused deposition of resins for additive manufacturing

The evolution of Additive manufacturing technologies (AMT) with Bioengineering production materials have been constantly researched, but not all have the necessary characteristics adequate fracture toughness to resist forces and crack propagation, with an improved mechanical and structural properties. The aim of this research was to analyse the nanoparticle microstructure and possible reinforcement of different resins behaviour to enhance productivities for AMT. Also to analyse the behaviour of different polymer resins in the attempt to make filaments for use in AMT, contributing to the sustainable search for natural resources of resins for 3D printing. Novel test analyses were carried out, which included mechanical evaluation of the materials for tensile and compression stress, density, glass transition temperature, Frequency analysis and optimization as well as the functional analytic behaviour of the samples with differential scanning calorimetry (DSC). The further analytical structural of the particle was performed, evaluating the surface luminance structure and the profile structure of a resin material in 3D printing, analysing the profile curve of the nanostructure from the scanning electron microscope (SEM). The filter profile of a cross-sectional view of the specimen was extracted and analyse and the Firestone curve of the Gaussian filter checking the roughness and waviness profile of the structure. According to the results, the materials present an in low tensile strength and compression, but excellent moulding to be extruded in the filaments and also injected. The resin sample B give a higher tensile and compressive force of about 365 kN/m2 and 650 kN/m2 respectively compare to others.