Modeling Heat Transfer and Densification during Laser Sintering of Viscoelastic Polymers

Schultz, Jeffrey Patrick

16 January 2004

Laser sintering (LS) is an additive manufacturing process which uses laser surface heating to induce consolidation of powdered materials. This work investigates some of the process-structure-property relationships for LS of viscoelastic polymers. A one-dimensional closed-form analytical solution for heating of a semi-infinite body, with a convective boundary condition, by a moving surface heat flux was developed. This solution approximates the shape of the Gaussian energy distribution of the laser beam more accurately than previous solutions in the literature. A sintering model that combines the effects of viscoelastic deformation driven by attractive surface forces and viscous flow driven by curvature-based forces was developed. The powder-bed temperature was approximated using the thermal model developed herein. The effect of the enthalpy of melting for semi-crystalline polymers was accounted for using a temperature recovery approach. Time-temperature superposition was used to account for the temperature dependence of the tensile creep compliance. The results of the combined-mechanism sintering model will be compared to the classic Mackenzie-Shuttleworth sintering model. A lab-scale LS unit was constructed to fabricate test specimens for model validation and to test the applicability of materials to LS. In this work, sintering four materials, polycarbonate (PC) and three molecular weights of polyethylene-oxide (PEO) was predicted using the aforementioned thermal and sintering models. Samples were fabricated using the lab-scale LS unit and the sintered microstructures were investigated using scanning electron microscopy. The rheologic, thermal and physical properties of the materials were characterized using standard methods and the relevant properties were used in the models. The choice of an amorphous polymer, PC, and a semi-crystalline polymer, PEO, affords comparison of the effects of the two material forms on contact growth during LS. The three molecular weights of PEO exhibit significantly different tensile creep compliances, however, the thermal and physical properties are essentially the same, and therefore the effect of molecular weight and subsequently the rheologic characteristics on contact growth during LS will be investigated. The effects of particle size, laser power, and bed temperature were also investigated. / Ph. D.

laser sintering

polymer powder

sintering

Heat--Transmission

viscoelastic contact growth

The redispersion of supported metal catalysts

Handa, Pawan Kumar.

January 1978

Call number: LD2668 .T4 1978 H347 / Master of Science

Metal catalysts.

Sintering.

Masters theses

Design based integration for improving overall quality of selective laser sintered rapid prototypes

Shi, Dongping., 石東平.

January 1999

published_or_final_version / Mechanical Engineering / Doctoral / Doctor of Philosophy

Sintering.

Lasers in engineering.

Prototypes, Engineering.

Integrated robot finishing system for polymer prototypes fabricated bythe selective laser sintering process

黎卓峰, Lai, Cheuk-fung, Matthew.

January 2003

published_or_final_version / Mechanical Engineering / Master / Master of Philosophy

Robots, Industrial.

Prototypes, Engineering.

Sintering.

Heat transfer properties and fusion behaviour of polymer based composite powders in selective laser sintering

Fan, Kin-ming., 范健明.

January 2004

published_or_final_version / Mechanical Engineering / Doctoral / Doctor of Philosophy

Plastic powders.

Sintering.

Lasers in engineering.

Novel zirconium oxide-based ceramic composites

Zhe, Xiaoli

January 1999

No description available.

669

Metallic Al; Powders; Sintering

Compatibility of electrolyte and electrode materials for intermediate temperature solid oxide fuel cells

Williams, Caroline

January 2000

No description available.

666

Sintering; Cerium; Barrier layer

Development of preceramic polymers for high temperature composite applications

Matthews, Siobhan O.

January 1999

No description available.

620.118

Silicon carbide; Pyrolysis; Sintering

Controlled atmosphere sintering in the system ZrO2̲-Cr2̲O3̲

Doughty, G. R.

January 1988

No description available.

546

Sintering of ZrO2̲-Cr2̲O3̲

Study of diamond/mullite composites by sol/gel and hot press sintering methods

Govo, Simbarashe Piniel

15 April 2011

MSc, School of Chemical and Metallurgical Engineering, Faculty of Engineering and the Built Environment / A study has been conducted into the synthesis of 10wt% diamond/ mullite composites through two methods: First through the hot press sintering of alumina and silica in stoichiometric composition for 3:2 mullites (mullite formed in situ) at 1400, 1450 and 1500oC. Second through the sol/ gel process. The sol/ gel method only provided the basis for future development with no further discussion of the results while the hot press sintering method yielded composites with residual cristobalite and corundum phases. Achieved densities of the composites were 93.7, 94.6 and 95.8% of the theoretical density with respect to sintering temperatures of 1400, 1450 and 1500oC for compact samples by the first method. Hardness – measured by Vickers indentation – of the composites decreased with increase in temperature with 15.5 ± 0.33GPa achieved at the lowest sintering temperature investigated. The decrease in hardness was attributed to the structural degradation of diamond to non-diamond carbon forms with increase in temperature as observed from Raman spectra of each of the composites. X-ray traces showed an increase in the mullite content with increase in temperature. The fracture toughness of compacts initially hot press sintered from alumina and silica in stoichiometric composition for 3:2 mullite with no diamond added decreased with increase in sintering temperature with 4.75 ± 0.10MPa·m1/2 achieved at the lowest sintering temperature investigated. Further discussion to the structure and physical properties is presented.

sintering methods

composites

diamond

mullite