Abstract
The mathematical modeling of the twin screw extrusion process is a challenge associated with the complicated geometry and the necessity to simulate a combination of screw elements in conjunction with the flow behavior of non-Newtonian fluids and under nonisothermal conditions. Here numerical solutions employing 3-D FEM are employed to analyze the coupled flow and heat transfer occurring in the co-rotating fully-intermeshing twin screw extrusion process. Experimental studies employing two well-instrumented twin screw extruders (7.5 mm and 50.8 mm) were conducted to verify the simulation results. Departing significantly from the previous literature FEM meshes were generated to cover combinations of pressure generating and pressure losing elements of the geometry. For example, the flow and heat transfer occurring in reversely configured (left-handed and thus pressure losing) kneading discs were simulated together with the pressure generating fully-flighted and right-handed screw elements. The novel use of combinations of elements in the simulations are shown to offer realistic solutions as demonstrated with the experimental studies.
Original language | English |
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Pages | 5554 |
Number of pages | 1 |
State | Published - 2005 |
Event | 05AIChE: 2005 AIChE Annual Meeting and Fall Showcase - Cincinnati, OH, United States Duration: 30 Oct 2005 → 4 Nov 2005 |
Conference
Conference | 05AIChE: 2005 AIChE Annual Meeting and Fall Showcase |
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Country/Territory | United States |
City | Cincinnati, OH |
Period | 30/10/05 → 4/11/05 |