Graduation Year
2018
Document Type
Thesis
Degree
M.S.M.E.
Degree Name
MS in Mechanical Engineering (M.S.M.E.)
Degree Granting Department
Mechanical Engineering
Major Professor
Nathan B. Crane, Ph.D.
Committee Member
David Murphy, Ph.D.
Committee Member
Tansel Yucelen, Ph.D.
Keywords
Additive Manufacturing, Powder Bed Sintering, Controls, Nylon 12, Heat Transfer
Abstract
Additive manufacturing involves the layer-wise patterned addition of material to create 3D parts, allowing for parts with complex geometries that traditional subtractive manufacturing processes cannot create, while offering good value for low run production parts by eliminating the cost of tooling. Large Area Sintering is a form of powder based additive manufacturing where entire layer cross sections are heated and fused in a single continuous exposure process. This layer by layer powder sintering process is similar to selective laser sintering, but by heating the cross section at a slower and controllable rate there is an opportunity to achieve tighter control over thermal history. This thesis discusses the design, construction, and validation of a large area sintering test platform, as well as a preliminary study on feature resolution. A key component of this system was the integration of an infrared camera, allowing point-wise temperature control of the sintering cross section. There is a hypothesis that longer and controlled heating rates in Large Area Sintering (in comparison to Selective Laser Sintering) would allow the capability to process a wider range of materials, and give more control over the resulting final part properties. The test platform created a repeatable test environment, and successfully demonstrated the capability for point wise temperature control of the sintering cross section, enabling the ability to examine the effects of slower controlled heating rates. Available power on the system was 2.22 W/cm2 for heating, with a temperature control loop time of 160 – 180 ms. The results of the preliminary study on feature resolution also suggested a positive correlation between point wise closed loop temperature control and improved feature resolution, giving motivation for further study.
Scholar Commons Citation
Gardiner, Christopher J., "Large Area Sintering Test Platform Design and Preliminary Study on Cross Sectional Resolution" (2017). USF Tampa Graduate Theses and Dissertations.
https://digitalcommons.usf.edu/etd/7026
