Hambali, Ruzy Haryati and Vaudelin, Maeva and Rennie, Allan (2011) Optimisation of build orientation for FDM additive manufactured products. In: International Conference on Humanities, Social Sciences, Science & Technology 2011 (ICHSST’11), 2011-06-27 - 2011-06-28.
Full text not available from this repository.Abstract
Fused Deposition Modelling (FDM) is one of a number of additive manufacturing (AM) technologies that are being used for the production of end-use components due to the technologies ability for short production times and as a method for producing geometrically complex parts. As it is a polymeric process, FDM in general is more flexible and can easily accommodate without significant expense, changes to a products design during the product development cycle (known as rapid prototyping) prior to fabricating end-use functional parts (known as rapid manufacturing (RM)). However, the quality and functional performance of FDM parts is dependent on a number of process parameters including layer thickness, build orientation, etc. Taking all this into account, these parameters have to be optimised in order to obtain the ideal part, for fit and function testing as well as an end-use products. This paper seeks to depict the optimisation of the FDM process for optimum performance of ABS plastic parts in term of tensile and shear effects, where the parameter of build orientation is observed. This research uses load bearing exhibition board mounting clips as the case study product. Series of experiments are conducted to attain the optimal value of the tensile strength of clips fabricated via FDM manufactured in different orientations. The orientations are in the y-axis with constraints in x and z-axis with the direction from y = 0º to y =180º in increments of 10º. The experimental setup for the physical study used a Kern Ch15 K20 load gauge to measure the load on the clips for each orientation. From the results, it is found that the build orientation significantly affects the strength performance of FDM parts. This contributes to further research into the development of RM design rules, specifically in design analysis and optimisation for validation of AM as a viable route for producing functional parts.