Numerical And Analytical Study Of Unsteady Arterial Blood Flow In Time-Dependent Stenosis Using The Non-Newtonian Power-Law Blood Fluid Flow Model
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Abstract
This study tests the traits of shaky ancestry flow in a channel accompanying an occasion reliant blockage utilizing the Power-Law fluid model. Mathematical and computational models are grown to decide the chief order flow speed, pressure slope, resistance and divider clip stress at the throats and at the fault-finding crest of the blockage and we interrogate reliance of these quantities on the momentary and dimensional variables in addition to on the repetitiveness of the flow swinging sooner than expected and the main limits of the flow order. We find that as the proportion of blockage raised accompanying period and commonness, the principles of the size of the main speed, the resistance and the obstruction cut stress in the blockage district raised. We still find that magnitudes of these quantities are greater for the Newtonian fluid than for non-Newtonian fluid.
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