Deck 15: Fluid Dynamics and Aerodynamics

$\text {In the region near the wall where \(\overline { u ^ { \prime } v ^ { \prime } }\) is constant, if \(\bar { u } ( y ) = c _ { 1 } \ln y + c _ { 2 }\) (see Example \(7.8\) ), the }$$\text {eddy viscosity \(\eta\) is proportional to:}$
(A) $\ln y$
(B) $y$
(C) $y ^ { - 1 }$
(D) $y ^ { 2 }$

$\text {A large dirigible measures \(18 \mathrm {~m}\) in diameter and is \(100 \mathrm {~m}\) long. The thin boundary layer can}$ $\text {be assumed to be developing on a flat plate with thickness at the leading edge. The drag}$ $\text {contributed by the shear stress due to the boundary layer for a dirigible speed of \(10 \mathrm {~m} / \mathrm { s }\) is}$$\text { approximately:}$
(A) $\delta = 3.6 \sqrt { v x / U _ { \infty } }$
(B) $\delta = 3.3 \sqrt { \nu x / U _ { \infty } }$
(C) $\delta = 3 \sqrt { v x / U _ { \infty } }$
(D) $\delta = 2.8 \sqrt { v x / U _ { \infty } }$

A traffic flow on a freeway is very dense and it is proposed that possibly a fluid flow could simulate the flow. If it was decided to study the feasibility of the proposal, which flow would
Be a possibility?
(A) An incompressible flow
(B) A compressible flow with M < 1
(C) A compressible flow with M > 1
(D) A compressible flow with M = 1

$\text {If an irrotational vortex approximates the air flow in a tornado, the highest possible velocity,}$ $\text {assuming an incompressible flow with \(p _ { \text {atm } } = 100 \mathrm { kPa }\), is nearest:}$
(A) $400 \mathrm {~m} / \mathrm { s }$
(B) $350 \mathrm {~m} / \mathrm { s }$
(C) $300 \mathrm {~m} / \mathrm { s }$
(D) $250 \mathrm {~m} / \mathrm { s }$

To determine boundary-layer characteristics on a body, for example the boundary-layer thickness, we must first know the potential-flow solution. The information used from the
Potential-flow solution is:
(A) The lift and drag acting on the body
(B) The pressure and velocity at the boundary of the body
(C) The shearing stress acting on the boundary of the body
(D) The normal and shearing stress acting on the boundary of the body

A bomb blast sends a shock wave through the 20 $$20 ^ { \circ } \mathrm { C }$$ C atmosphere. At a certain location, the shock wave is travelling at M = 3. The induced velocity behind the wave is nearest:

A smooth 10-cm-diameter sphere weighs 6 N. If it is dropped in 5 $5 ^ { \circ } \mathrm { C }$ C water, its terminal velocity will be nearest:

Select the incorrect statement for an inviscid flow.
(A) The drag on a body in an inviscid flow is zero
(B) The lift on a streamlined body can be approximated by neglecting viscous effects
(C) The velocity distribution in the wake of a body can be approximated by neglecting viscous effects
(D) The normal velocity component at the boundary of a body in an inviscid flow is zero

$\text {A line source of strength \(2 \mathrm {~m} ^ { 2 } / \mathrm { s }\) is superposed with a velocity of \(8 \mathrm {~m} / \mathrm { s }\) producing along-}$$\text {slender body that resembles the one shown. The thickness \(h\) of the body is nearest:}$
(A) $15 \mathrm {~cm}$
(B) $20 \mathrm {~cm}$
(C) $25 \mathrm {~cm}$
(D) $30 \mathrm {~cm}$

$\text {If the straight-line approximation \(u = U _ { \infty } y / \delta\) to the velocity profile is used, the boundary-}$$\text {layer thickness for a zero-pressure gradient flow on a flat plate would be approximated to be:}$
(A) $15 \mathrm {~cm}$
(B) $20 \mathrm {~cm}$
(C) $25 \mathrm {~cm}$
(D) $30 \mathrm {~cm}$

$\text {If the velocity potential in an inviscid flow is given by \(\phi = A y\), where \(\mathrm { A }\) is a constant, the}$ $\text {stream function is:}$
(A) $- A y ^ { 2 } + B$
(B) $A x ^ { 2 } + B$
(C) $A y + B$
(D) $- A x + B$

A farmer is using a tank of 20 $20 ^ { \circ } \mathrm { C }$ C nitrogen pressurized to 540 kPa absolute. It exits the tank out a hose. The hose snaps and the farmer is hit with the expanding nitrogen. Air is primarily
Nitrogen so assuming it is air flowing with no losses, the temperature of the exiting nitrogen is
Nearest:

The drag on a blunt object is due primarily to:
(A) The relatively high pressure on the front of the object
(B) The wake region
(C) The shear stress acting on the front and rear of the object
(D) The separated region

Water at 20 $$20 ^ { \circ } \mathrm { C }$$ C flows between 80-cm-wide horizontal parallel plates 12 mm apart such that a pressure drop of 100 Pa occurs over a distance of 2 m. If the top plate is moving at 1.8 m/s in
The direction of the flow, the flow rate is nearest: (A) $0.0144 \mathrm {~m} ^ { 3 } / \mathrm { s }$
(B) $0.0104 \mathrm {~m} ^ { 3 } / \mathrm { s }$
(C) $0.0084 \mathrm {~m} ^ { 3 } / \mathrm { s }$
(D) $0.0054 \mathrm {~m} ^ { 3 } / \mathrm { s }$

A pressure drop of 200 kPa is measured over a 50-m-length of 2-mm-diameter pipe trans- porting 30 $$30 ^ { \circ } \mathrm { C }$$ C water. If a laminar flow exists, the flow rate is nearest:

A square smooth conduit, 80 cm on a side, circulates 35 $$35 ^ { \circ } \mathrm { C }$$ C air in a large building. The pressure drop over a 50-m length of the horizontal conduit is not to exceed 800 Pa. Assume an average
Pressure in the conduit of 120 kPa. The maximum flow rate in the conduit is nearest: (A) $37 \mathrm {~m} ^ { 3 } / \mathrm { s }$
(B) $29 \mathrm {~m} ^ { 3 } / \mathrm { s }$
(C) $18 \mathrm {~m} ^ { 3 } / \mathrm { s }$
(D) $11 \mathrm {~m} ^ { 3 } / \mathrm { s }$

The equation (7.3.20) for the head loss is valid for both laminar and turbulent flows. We wish to pump the flow rate Q through a long pipe of diameter D, to be selected. The head loss is
Proportional to what power of D, assuming a constant friction factor? (A) $D ^ { - 2 }$
(B) $D ^ { - 3 }$
(C) $D ^ { - 4 }$
(D) $D ^ { - 5 }$

One liter of $$20 ^ { \circ } \mathrm { C }$$ C water is collected from a 60-cm-long, 4-mm-diameter tube over a time span of 4 minutes. The length of the entrance region is nearest:

$\text {It is desired to transport \(4 \mathrm {~m} ^ { 3 } / \mathrm { s }\) of water through a rectangular finished concrete canal that can}$$\text { be at most \(2 \mathrm {~m}\) wide. The slope of the land through which it passes is \(0.0004\). What depth of}$ $\text {water should be expected?}$

$\text {Water at \(20 ^ { \circ } \mathrm { C }\) is transported in a 10 -cm-diameter cast iron horizontal pipe at a flow rate of}$$\text { \(0.02 \mathrm {~m} ^ { 3 } / \mathrm { s }\). The pressure drop over \(100 \mathrm {~m}\) of the pipe is nearest:}$
(A) $97 \mathrm { kPa }$
(B) $84 \mathrm { kPa }$
(C) $62 \mathrm { kPa }$
(D) $51 \mathrm { kPa }$

$\text {The pressure drop in \(10 \mathrm {~m}\) of a turbulent flow in a pipe is \(200 \mathrm {~Pa}\). The time-average velocity,}$ $\text {in the pipe at three radial locations, is measured to be:}$
$$\begin{array} { c c c c } \bar { u } ( \mathrm {~m} / \mathrm { s } ) & 7.24 & 7.07 & 6.72 \\r ( \mathrm {~mm} ) & 23 & 25 & 27\end{array}$$
$\text {The eddy viscosity at \(r = 25 \mathrm {~mm}\) is nearest (neglect the kinematic viscosity):}$
(A) $0.00163 \mathrm {~m} ^ { 2 } / \mathrm { s }$
(B) $0.00181 \mathrm {~m} ^ { 2 } / \mathrm { s }$
(C) $0.00192 \mathrm {~m} ^ { 2 } / \mathrm { s }$
(D) $0.00227 \mathrm {~m} ^ { 2 } / \mathrm { s }$

The horsepower required to rotate the shaft of Problem 2, if SAE-30 oil at 40 $$40 ^ { \circ } \mathrm { C }$$ ills the gap, is nearest: