TY - JOUR
T1 - Extended Regression Models for Predicting the Pumping Capability and Viscous Dissipation of Two-Dimensional Flows in Single-Screw Extrusion
AU - Roland, Wolfang
AU - Kommenda, Michael
AU - Marschik, Christian
AU - Miethlinger, Jürgen
PY - 2019/2/14
Y1 - 2019/2/14
N2 - Generally, numerical methods are required to model the non-Newtonian flow of polymer melts in single-screw extruders. Existing approximation equations for modeling the throughput- pressure relationship and viscous dissipation are limited in their scope of application, particularly when it comes to special screw designs. Maximum dimensionless throughputs of Π V < 2.0, implying minimum dimensionless pressure gradients Π p,z , ≥ -0.5 for low power-law exponents are captured. We present analytical approximation models for predicting the pumping capability and viscous dissipation of metering channels for an extended range of influencing parameters (Π p,z ≥ -1.0, and t/D b ≥ 2.4) required to model wave- and energy-transfer screws. We first rewrote the governing equations in dimensionless form, identifying three independent influencing parameters: (i) the dimensionless down-channel pressure gradient Π p,z , (ii) the power-law exponent n, and (iii) the screw-pitch ratio t/D b . We then carried out a parametric design study covering an extended range of the dimensionless influencing parameters. Based on this data set, we developed regression models for predicting the dimensionless throughput-pressure relationship and the viscous dissipation. Finally, the accuracy of all three models was proven using an independent data set for evaluation. We demonstrate that our approach provides excellent approximation. Our models allow fast, stable, and accurate prediction of both throughput-pressure behavior and viscous dissipation.
AB - Generally, numerical methods are required to model the non-Newtonian flow of polymer melts in single-screw extruders. Existing approximation equations for modeling the throughput- pressure relationship and viscous dissipation are limited in their scope of application, particularly when it comes to special screw designs. Maximum dimensionless throughputs of Π V < 2.0, implying minimum dimensionless pressure gradients Π p,z , ≥ -0.5 for low power-law exponents are captured. We present analytical approximation models for predicting the pumping capability and viscous dissipation of metering channels for an extended range of influencing parameters (Π p,z ≥ -1.0, and t/D b ≥ 2.4) required to model wave- and energy-transfer screws. We first rewrote the governing equations in dimensionless form, identifying three independent influencing parameters: (i) the dimensionless down-channel pressure gradient Π p,z , (ii) the power-law exponent n, and (iii) the screw-pitch ratio t/D b . We then carried out a parametric design study covering an extended range of the dimensionless influencing parameters. Based on this data set, we developed regression models for predicting the dimensionless throughput-pressure relationship and the viscous dissipation. Finally, the accuracy of all three models was proven using an independent data set for evaluation. We demonstrate that our approach provides excellent approximation. Our models allow fast, stable, and accurate prediction of both throughput-pressure behavior and viscous dissipation.
KW - polymer processing
KW - modeling and simulation
KW - extrusion
KW - symbolic regression
KW - power-law fluid
KW - polymer processing
KW - modeling and simulation
KW - extrusion
KW - symbolic regression
KW - power-law fluid
KW - Symbolic regression
KW - Modeling and simulation
KW - Powerlaw fluid
KW - Extrusion
KW - Polymer processing
UR - http://www.scopus.com/inward/record.url?scp=85061570991&partnerID=8YFLogxK
U2 - 10.3390/polym11020334
DO - 10.3390/polym11020334
M3 - Article
SN - 2073-4360
VL - 11
JO - Polymers
JF - Polymers
IS - 2
M1 - 334
ER -