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|College of Engineering and Computer Science

Mechanical Engineering Department

Mechanical Engineering 390

Fluid Mechanics | |

| |Spring 2008 Number: 11971 Instructor: Larry Caretto |

January 29 Homework Solutions

1.6 IF V is a velocity, ℓ, a length, and ν a fluid property having dimensions of L2T-1, which of the following combinations are dimensionless: (a) Vℓν, (b) Vℓ/ν, (c) V2ν, (d) V/ℓν?

Velocity has dimensions of LT-1 and the length, ℓ., has dimensions of L. Check each combination of variables to see if it is dimensionless:

(a) Vℓν has dimensions of (LT-1)(L)(L2T-1) = L4T-2 is not dimensionless.

(b) Vℓ/ν has dimensions of (LT-1)(L)/(L2T-1) = L0T0 = 1 is dimensionless.

(c) V2ν has dimensions of (LT-1)2(L2T-1) = L4T-3 is not dimensionless.

(a) V/ℓν has dimensions of (LT-1)(L)-1(L2T-1)-1 = L-3T is not dimensionless.

1.17 Clouds can weigh thousands of pounds due to their liquid water content. Often this content is measured in grams per cubic meter (g/m3). Assume that a cumulus cloud occupies a volume of one cubic kilometer, and its liquid water content is 0.2 g/m3. (a) what is the volume of this cloud in cubic miles? (b) How much does the water in the cloud weigh in pounds?

(a) [pic]

Note that the conversion factor of 1.609344 km/mi is exact. Travelers often use the approximation of 1.6 = 8/5 km/mi to get a good approximate of the relationship between miles and kilometers.

(b) For this part we want to compute the weight as the product of mass times gravity, W = mg. Here the mass the product of the water content and the cloud volume. We will assume standard gravity of 9.80665 m/s2 to compute the weight.

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The first two terms are the known variables (water content and cloud volume; the remaining terms are the acceleration of gravity and unit conversion factors.

1.34 A closed tank having a volume of 2 ft3 is filled with 0.30 lbf of a gas. A pressure gage attached to the tank reads 12 psi when the gas temperature is 80oF. There is some question as to whether the gas in the tank is oxygen or helium. Which do you think it is? Explain how you arrived at your answer.

Assume that we an apply the ideal gas equation to this problem: PV = mRT where we have all the data to solve for R = PV/(mT). We can compute the value of R and compare it to tabulated values of R in Table 1.7 for helium and oxygen. Assume that the atmospheric pressure is the standard pressure of 14.696 psi and that g = 32.174 ft/s2.

[pic]The gas constants for helium and oxygen from Table 1.7 are 1.242x104 ft·lbf/(slug·R) and 1.554x103 ft·lbf/(slug·R), respectively. The value found above is much closer to the R value for oxygen so we conclude that the gas in the tank is oxygen.

1.49 For air at standard atmospheric pressure the values of the constants that appear in the Sutherland equation (Eq. 1.10) are C = 1.458x10-6 kg/(m·s·K1.5) and S = 110.4 K. Use these values to predict the viscosity of air at 10oC and 90oC and compare with values given tin Table B.4 in Appendix B.

The Sutherland equation for viscosity is m = CT0.5/(T + S). Plugging in the constants given for the two temperatures of 10oC (283.15 K) and 90oC (363.15 K) gives the following results:

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These values agree well with the values from Table B-4 on page 763: μ = 1.76x10-5 N·s/m2 at 10oC and μ = 2.14x10-5 N·s/m2 at 90oC.

1.53 For a parallel plate arrangement of the type shown in Fig. 1.3 (copied at right) it is found that when the distance between plates is 2 mm, a shearing stress of 150 Pa develops at the upper plate when it is pulled at a velocity of 1 m/s. Determine the viscosity of the fluid between the plates. Express your answer in SI units.

The basic relationship between shear stress, viscosity, and velocity gradient is τ = μ du/dy. For the figure shown here, the velocity profile is linear so that du/dy = U/b. From the data given we can find the velocity gradient and use that to compute the viscosity for the given shear stress of 150 Pa.

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1.85 To measure the water depth in a large open tank with opaque walls, an open vertical glass tube is attached to the side of the tank. The height of the water column in the tube is then used as a measure of the depth of water in the tank. (a) For a true water depts. in the tank of 3 ft, make use of Eq. 1.22 (with θ = 0) to determine the percent error due to capillarity as the diameter of the glass tube is changed. Assume a water temperature of 80oF. Show your results on a graph of percent error versus tube diameter, D, in the range 0.1 in < D < 1.0 in. (b) If you want the error to be less than 1%, what is the smallest tube diameter allowed?

Equation 1.22 gives the capillary rise, h = 2σcosθ/γR. For water at 80oF we find σ = 0.00491 lbf/ft and γ = 62.22 lbf/ft3 from Table B-1 on page 761. Substituting these numbers, θ = 0, and R = D/2 (because we are asked to plot the results versus D) into the formula for capillary rise gives

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This gives the capillary rise in ft, when D is given in ft. The relative error in the depth is simply the capillary rise divided by the true depth of 3 ft. Defining this error and using a unit conversion factor so that we can use D in inches gives the following working equation.

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Calculating this equation and plotting results in a spreadsheet gives the results shown below.

D (in) |error |

| | | | | | | |0.1 |1.26% | | | | | | | | |0.15 |0.84% | | | | | | | | |0.2 |0.63% | | | | | | | | |0.25 |0.51% | | | | | | | | |0.3 |0.42% | | | | | | | | |0.35 |0.36% | | | | | | | | |0.4 |0.32% | | | | | | | | |0.45 |0.28% | | | | | | | | |0.5 |0.25% | | | | | | | | |0.55 |0.23% | | | | | | | | |0.6 |0.21% | | | | | | | | |0.65 |0.19% | | | | | | | | |0.7 |0.18% | | | | | | | | |0.75 |0.17% | | | | | | | | |0.8 |0.16% | | | | | | | | |0.85 |0.15% | | | | | | | | |0.9 |0.14% | | | | | | | | |0.95 |0.13% | | | | | | | | |1 |0.13% | | | | | | | | |

(b) For the error to be less than 1% requires that

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So the minimum allowed diameter is 0.126 in.

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