Investigation on Filament Extrusion of Thermoplastic Elastomer (TPE) for Fused Deposition Modeling

Zicheng, Wang, Nouri, Mohammad

January 2019

This thesis is an investigation of the TPE filament for Fused Deposition Modelling (FDM) manufacturing method. All the investigations aim to optimize the quality of the filament in order to make Thermoplastic Elastomer (TPE) material possible for FDM manufacturing method. Optimization experiments were made to find out key parameters in the extrusion process that determine the quality of the filament. With the optimal parameters, further investigation of the additive content in the TPE granulate was made to solve the current problem of the filament in practical 3D printing, which the high surface friction massively affects the FDM manufacturing feasibility. The filaments were manufactured by the desktop extruder 3devo filament extruder and the surface friction tests were performed on TribotesterTM. Additionally, discussion was made to summarize the pros and cons of TPE material as well as the significance of 3D printing TPE. Potential application and benefits are mentioned for combining the property of TPE and the advantage of FDM manufacturing. Current state-of-art extrusion equipment and FDM technology are also summarized.

Filament Extrusion

Thermoplastic Elastomer

Fused Deposition Modeling

Mechanical Engineering

Maskinteknik

Enhancing Filament Quality and Investigations on Print Quality of Thermoplastic Elastomer (TPE) products manufactured by Fused Deposition Modeling (FDM)” : Developing a robust methodology by optimizing the respective process variables

KUMAR, BHARGAV, MAZZA, FEDERICO

January 2018

Additive manufacturing is gaining popularity at a rapid rate and has been a resourceful production process to reduce material usage, wastage (scrap) and manufacturing costs for various applications. The project conducted, emphasizes on Thermoplastic Elastomer (TPE SE6300C-65A) material, which is a highly versatile compound, and has the ability to exhibit properties of both rubber (Elastomers) in terms of flexibility and plastic (Polymers) in terms of recyclability. Cost reduction without compromising quality is one of the important factors for industries. The project involves the use of TPE pellets to extrude filaments that could be used for 3D Printing. Filament extrusion involves process variables like Nozzle Temperature, De-humidification of pellets, Diameter of the nozzle, Distance of collection, Cooling and Angle of inclination of the extruder. These process variables are optimized to accomplish the desired quality of filament. The filament produced through extrusion is further used to make products using Fused Deposition Modeling (FDM). FDM also involves numerous process variables like Layer Thickness, Build Orientation, Print Infill, Print Speed etc. In this study, different test specimens, in terms of geometrical shapes are printed from the material, TPE SE6300C-65A and tested in order to understand how the surface features as well as the dimensional accuracy change with different process variables. It is observed that the surface topography produced throughout FDM process is majorly affected by the angle of orientation of the printed part. The main goal of this thesis is to give the reader a better understanding on which process variable, such as layer thickness, temperature and print speed affect the surface roughness of the models and also a comparison between these three variables, highlighting which is more or less affecting. It is also observed the dimensional accuracy of the real specimen deviate from the value input into the CAD software. The results obtained in this study clearly suggest that there is a lot of opportunities for future improvements especially regarding the dimensional accuracy, it is imperative to achieve the highest precision possible in order to have commercial values for the FDM 3D printing.

FILAMENT EXTRUSION

FUSED DEPOSITION MODELING (FDM)

THERMO PLASTIC ELASTOMER (TPE)

SURFACE TOPOGRAPHY

DIMENSIONAL ACCURACY

Manufacturing Carbon Nanotube Yarn Reinforced Composite Parts by 3D Printing

Vijayakumar, Dineshwaran

January 2016

No description available.

Mechanics

Mechanical Engineering

Carbon Nanotubes

3D Printing

Wire Coating filament extrusion

Filament production

Fused Filament Fabrication

Fiber reinforced 3D Printer filament