Abstract:
Nowadays, Additive Manufacturing (AM), also known as 3D printing finds wide
application in automotive, aerospace and medical fields. Functional additive
manufactured parts must satisfy dimensional accuracy as well as to provide an
acceptable quality of surface finish. However the dimensional accuracy of additive
manufactured parts are affected by many process variables including accuracy of
tessellation from Computer Aided Design (CAD) model, slicing algorithm, data transfer,
device motion resolution, powder granulometry, beam offset, process parameters and
shrinkage. The surface finish of additive manufactured parts is often poor due to the
layer-by-layer manufacturing process of AM. The degree of this so called “stairstepping”
is dependent on the type of AM process and layer thickness used. Different
post processing techniques can be used to improve the surface finish. Six post
processing techniques were investigated in this study to improve the surface finish of
small test pieces that were additive manufactured in nylon polyamide, Alumide® and
Acrylonitrile Butadiene Styrene (ABS) plastic materials. The techniques include
tumbling, shot peening, Computer Numerical Control (CNC) machining, spray painting,
undercoat and hand finishing and chemical treatment by dissolving the surface of the
test pieces. A Laser Sintering (LS) process was used to manufacture the nylon polyamide and Alumide® test pieces while Fused Deposition Modelling (FDM) was used
for the ABS test pieces. A Coordinate Measuring Machine (CMM) also known as Touch
probe scan machine was used for assessment of the dimensional accuracy of post
processed test pieces compared to the geometry of the “as built” test pieces. The Chisquare
test ( 2 ) and the test for differences in deviation range proportions were used
to establish the level of significance of differences between ‘“as built” and each post
processing technique. It was shown that there exists a significant difference between
deviation range proportions as one compares the “as built” to any one of the six
considered post processing techniques. For all the three investigated materials, hand
finishing technique produced the best improvement of surface finish though this
technique was generally characterized by a lack of consistency in distribution of
uniform deviation ranges across individual surfaces as well as across entire test pieces.
The spray painting improved the surface finish and was found to be consistent in
distribution of uniform deviation ranges across individual surfaces as well as across entire test pieces. However this technique led to significant positive deviation ranges from the geometry of the “as built” test piece, thus affecting negatively the dimensional accuracy of the “as built” test piece. On one hand, despite the rounding of the sharp corners and the removal of small protrusions, tumbling and shot peening techniques, without affecting negatively the dimensional accuracy of the test piece, it was found that tumbling and shot peening are the optimal post processing techniques to improve the surface finish of relatively wide surfaces of Laser Sintered nylon and Alumide® test pieces. On the other hand, it was realized that tumbling or shot peening technique should not be applied to ABS test pieces as, in addition to the negative effects of the two techniques on nylon and Alumide® test pieces, tumbling and shot peening damage heavily the surfaces of ABS pieces. Chemical treatment by immersion into acetone bath was found to be the optimal technique for improvement of the surface finish of Fused Deposition Modelled ABS test pieces. Though through CNC machining the surface finish of nylon, Alumide® and ABS test pieces was improved, a relatively high standard deviation in surface finish across the entire test piece was observed. In addition to this, excessive negative deviation ranges were observed on the machined surfaces. This can be attributed to a single error during the calibration of the machine or the setting of the cutting parameters which led to the excessive negative deviation ranges from the geometry of the “as built” test piece. The consideration of individual cutting parameters for each surface inclination angle would reduce the standard deviation and eliminate the risk of excessive negative deviation ranges across the entire test piece. However, this approach would lead to excessive machining time, thus increasing the cost of the process. Finally, it was realized that CNC machining is not an appropriate technique to improve the surface finish of small plastic parts with complex shapes in the form of various inclination angles and small entities such as small conical features, round cavities and protrusions.