Abstract
This article describes the development of a mathematical model of the reverse roll coating of a thin film for an incompressible non-isothermal magnetohydrodynamics (MHD) viscoplastic fluid as it passes through a small gap between two rolls rotating reversely. The equations of motion required for the fluid added to the web are constructed and simplified using the lubrication approximation theory (LAT). Analytical results are obtained for the velocity profile, pressure gradient, and temperature distribution. The pressure distributions and flow rate are calculated numerically using the trapezoidal rule and regular false position method, respectively. Some of these results are presented graphically, while others are shown in a tabular form. From the present analysis, it has been observed that the magnitude of pressure distributions increases by increasing the value of the involved parameters. It is worth mentioning that the velocities ratio and Brickman’s number are controlling parameters for the temperature distributions. The results indicate the strong effectiveness of the viscoplastic parameter and velocities ratio for the velocity and pressure distributions. It is also concluded that the coating of Casson material has been remarkably affected by the magnetohydrodynamics effects.
Highlights
The coating of surfaces with a liquid film is frequently used in the magnetic tape, photography, and wrapper industries and for paint and paper to shield a sizeable surface region with one/numerous uniform layers
Instabilities in films are observed, which can only be explored by deliberating the problems of fluid dynamics related to the coating process, as a nonlinear occurrence is seen in the procedure [4,5] for Newtonian flows
The velocities ratio, viscoplasticity, and MHD effects on the flow of Casson material are explored via graphs and tables
Summary
The coating of surfaces with a liquid film is frequently used in the magnetic tape, photography, and wrapper industries and for paint and paper to shield a sizeable surface region with one/numerous uniform layers. A wide range of procedures are available to attain the goal of a fluid layer on a surface continuously. Chandio and Webster [6] developed a numerical scheme purely based on the methodology of finite elements with the prediction of a free surface in time and presented an analysis of transient instabilities with a variable speed ratio.
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