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An incompressible, viscous fluid is placed between horizontal, infinite, parallel plates as shown below. The two plates move in opposite directions with constant velocities U 10 m/s and U2 = 5 m/s as shown. The pressure gradient in the x direction is zero and the only external force is gravity (in the y-direction). Use the Navier-Stokes equations to determine where the fluid velocity is zero (in terms of a fraction of b, i.e. 0.75 for y-75% of b) Enter Number...
An incompressible viscous fluid is placed between horizontal, infinite parallel plates as shown. The two plates move in the same direction but with different velocities, U1 and U2. The pressure gradient in the x direction is zero and the only body force is due to the fluid weight. Using the continuity and the Navier-Stokes equations, find an expression for the velocity profile between the plates. Show ALL work for full credit. U1 V=O b KO wo U2
An incompressible viscous fluid is placed between horizontal, infinite parallel plates as shown. The two plates move in the same direction but with different velocities, U1 and U2. The pressure gradient in the x direction is zero and the only body force is due to the fluid weight. Using the continuity and the Navier-Stokes equations, find an expression for the velocity profile between the plates. Show ALL work for full credit. U1 V=O g u K wo U2
Water can be considered as a non-viscous incompressible fluid of density p. A laboratory set-up is such that water flows through a pipe, exhibiting a laminar and steady-state flow. At the top end of the pipe, the flow tube has a cross-sectional area A and point 1 (located on the central streamline) is exposed to the ambient environment. The pipe drops through a A vertical distance h7 while its area decreases to when it reaches point 2 (also on the...
3. An incompressible, viscous fluid with density, p, flows past a solid flat plate which has a depth, b, into the page. The flow initially has a uniform velocity U., before contacting the plate. After contact with the plate at a distance x downstream from the leading edge, the flow velocity profile is altered due to the no-slip condition. The velocity profile at location x is approximated to have a linear shape, u = U. z for y s 8...
Problem 1 An incompressible, viscous fluid with density, p, flows past a solid flat plate which has a width, b, into the page. The flow initially has a uniform velocity U before contacting the plate. The velocity profile at location x is estimated to have a parabolic shape, u-u[(Y)-(,)21"for ysiand u-vfor y 20 where isthe boundary layer thickness. (a) Determine the upstream height from the plate, h, of a streamline which has a height, 6, at the downstream location, x....
According to Bernoulli's principle, all other things being equal, for a non-viscous incompressible fluid undergoing streamline flow: b) The greater the density of a fluid, the greater the buoyant force on any object submerged in the fluid. C) The pressure in a fluid is lower where the fluid is moving faster D) Air moves faster over an airplane wing than it does under. E) The deeper the position in an incompressible fluid, the greater the density of the fluid.
Incompressible fluid flow field
2. (a) An incompressible fluid flow field is given as Vx = x2+y+z2 and Vy=xy+yz+z, what is V?=? that satisfies continuity equation? (b) Plot the 2-D flow field represented by Vx=2y, Vy=4x. First obtain an expression for stream function, and then plot flow lines corresponding to constant stream function values.