Your search keyword '"Shah, Karim Ali"' showing total 3 results

1. Machine learning‐based time series analysis of polylactic acid bead foam extrusion.

Author

Shah, Karim Ali, Albuquerque, Rodrigo Q., Brütting, Christian, and Ruckdäschel, Holger

Subjects

EXTRUSION process, TIME series analysis, MELT spinning, POLYMER melting, RANDOM forest algorithms

Abstract

Understanding the behavior of polymer melts during extrusion is essential for optimizing processes and developing new materials. However, analyzing the continuous data generated by an extruder poses significant challenges. This paper investigates the utility of machine learning in predicting melt pressure at the die plate in polylactic acid (PLA) bead foam extrusion, a critical parameter in the extrusion process. Utilizing a random forest (RF) model, we examine how various processing parameters influence melt pressure. By segmenting the data into time‐delayed intervals, we achieve accurate predictions. We present forecasts of melt pressure at the die for intervals of 5 s, 1 min, and 5 min, demonstrating particularly strong performance for the 5‐min forecast with a Mean Absolute Error (MAE) of 1.88 and the coefficient of determination (R2 score) of 0.90. By exploring time series data, our study demonstrates the effectiveness of the RF model and provides a foundation for more advanced and precise control strategies in polymer bead extrusion processes. [ABSTRACT FROM AUTHOR]

Published

2024

2. Machine learning investigation of polylactic acid bead foam extrusion

Author

Shah, Karim Ali, primary, Brütting, Christian, additional, Albuquerque, Rodrigo Q., additional, and Ruckdäschel, Holger, additional

Published

2024

3. High-performance Monte Carlo Computations for Adhesive Bands Formation

Author

Shah, Karim Ali and Shah, Karim Ali

Abstract

We propose a lattice model for three stochastically interacting components that mimicsthe formation of the internal structure of adhesive bands via evaporating one component(the solvent) by thermal gradient. We use high-performance computing resources toinvestigate the formation of rubber-acrylate morphologies. We pay special attentionto the role of varying temperature as well as of the changing the solvent interaction inconnection to the shape of the obtained rubber morphologies.In the lattice model, we start with microscopic spins of three particles in the latticewith short-range interactions between them. This microscopic model is approximatednumerically via a Monte Carlo Metropolis-based algorithm. High-performancecomputing resources and Python-based implementations have been used for thenumerical simulation of the lattice model. The numerical implementation highlights theeffect of the model parameters (volatility of the Solvent, temperature, and interactionbetween the particles) on the structure of the obtained morphologies. We demonstratethat one can utilize a reasonably simple model to explain the impact of parameters onthe creation of morphology in ternary systems when one component evaporates.

Published

2022