Abstract
A numerical solution is worked out for unsteady flow around a revolving disk exhibiting upward/downward motion. A temperature-dependent viscosity model is introduced that yields a system in which momentum and energy equations are coupled in terms of a parameter [Formula: see text]. The disk revolves with the time-dependent angular velocity [Formula: see text] and vertically moves with the axial velocity [Formula: see text], where [Formula: see text] denotes the location of disk at any time t. The considered expressions of [Formula: see text] and [Formula: see text] suggest that upward/downward motion of the rotating disk leads to the case of accelerated/decelerated disk. Solutions are worked out by a widely employed routine bvp4c of MATLAB. The vertical motion of the disk leads to a two-dimensional flow problem when the disk is nonrotating. However, simultaneous vertical movement and rotation of the disk impart a three-dimensional motion. A marked variation in solution profiles is detected whenever temperature dependency in fluid viscosity is retained. In addition, the deceleration phenomenon of the disk declines heat transfer rate from the surface.
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Schedule a callMore From: Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering
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