چکیده
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In this study, heat transfer characteristics of an elastically-mounted circular cylinder wrapped by a porous layer
are studied numerically. The vibration of the cylinder is modeled as a forced mass-spring-damping system and it
is assumed that the cylinder can move only in the transverse direction. The effects of Darcy number
(10E-6 ≤ Da≤ 10E-2), the dimensionless thickness of the porous layer (ep = 0.25, 0.5, 1) and reduced velocity
(3≤ ur ≤ 20) on the cylinder displacement, vortex shedding pattern, and Nusselt number are investigated. The
Reynolds number, damping ratio, and mass ratio are taken as Re = 150 , ζ = 0.01 and mr = 2, respectively.
Results show that increasing Darcy number decreases the displacement amplitude of the cylinder. It is concluded
that by increasing the reduced velocity from ur = 3 to ur = 9, the Nusselt number and the displacement
amplitude of the cylinder increase and reach a maximum value at some optimum reduced velocity which depends
on the value of Darcy number. Beyond which those quantities are reduced. It is observed that for all values
of reduced velocity, the temperature distribution inside the porous layer is not affected by the position of the
cylinder and the temperature variations are approximately equal at crest and rest points. Also, at low Darcy
numbers, the temperature distributions are uniform in the peripheral direction due to small flow penetration into
the porous material Moreover, at Da = 10E-2, 10E-3 and 10E-4 the Nusselt number is increased by 7%, 9% and 10%
for the reduced velocities of ur = 7, ur = 3 and ur = 6, respectively.
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