California State University, Northridge



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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 |

May 6 Open-Channel-Flow-Homework Solutions

10.2 The flowrate per unit width in a wide channel is q = 2.3 m2/s. Is the flow subcritical or supercritical if the depth is (a) 0.2 m, (b) 0.8 m, or (c) 2.5 m?

Open-channel flows are subcritical, critical or supercritical if the Froude number is less than, equal to, or greater than one. We can compute the Froude number from the data given using the following relations, where b is the channel width and y is the channel depth

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For the given flow per unit width, q = 2.3 m2/s, we find the following values for Froude number at the different depths.

[pic] Flow is supercritical

[pic] Flow is supercritical

[pic] Flow is subcritical

10.13 Water flows in a rectangular channel with a flowrate per unit width of q = 25 ft2/s. Plot the specific energy diagram for this flow. Determine the two possible depths of flow if E = 7 ft.

We can substitute the given data into the equation for the specific energy, E, to get the following computational equation. Note that the units for the constant mean that the specific energy will be in feet when y is in feet.

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We can find the value of yc that makes E a minimum and the corresponding value of Emin as follows.

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We can check this formula for the minimum energy by substituting yc into our computational equation for the specific energy.

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Using the computational equation for E as a function of y we can determine the specific energy for a range of y values to obtain the plot at the right. The plot shows the minimum energy (and its location, yc) at the values found above.

At the point where E = 7 ft, our graph shows that the depth can be approximately 1.5 ft or 6.5 ft. For E = 7 ft, our computational equation becomes

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Noting that we have dimensional consistency and the solution for y will be in feet we can rearrange this equation into a cubic form as shown below.

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We can solve this equation numerically using the values found from the graph as initial guesses to get the desired solution. The positive roots of this cubic equation are y = 1.306 ft for the supercritical depth and y = 6.790 ft for the subcritical depth. The negative root, y = –1.095 ft is ignored as being physically unrealistic.

10.22 Water flows in a rectangular channel with a flowrate per unit width of q = 1.5 m2/s and a depth of 0.5 m at section (1). The head loss between sections (1) and (2) is 0.03 m. Plot the specific energy diagram for this flow and locate states (1) and (2) on this diagram. Is it possible to have a head loss of 0.06 m? Explain.

We can apply the energy equation to the diagram shown above. Here we use the surface of the liquid as the points to apply the energy equation. This means that p1 = p2 = 0. We assume that the slope is very small so that we can use the fluid depth as the elevation. This gives z1 = y1 = 0.5 ft and z2 = y2. With these simplifications our energy equation becomes.

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We replace the velocity, V, by the flow per unit width: V = Q/A = (qb)/(yb) = q/y. This gives the following result in our energy equation. Note that Q = qb is constant as the flow changes depth. If the width, b, is constant, then q = Q/b, is also constant. Thus we do not have to subscript q in the equation below.

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Although the specific energy changes in the flow as a result of head loss, the relationship between specific energy and depth does not change. At any point in the flow we must have

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We can compute the values of E for various values of y and plot the results as shown in the figure to the left. In particular, we know the value of the depth, y = 0.5 m at section (1) in the flow. Thus, the specific energy at this point can be found as

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This confirms the value that we can read from the chart for y = 0.5 m. According to the energy equation, the head loss means that the energy at station 2 is 0.03 m less than the energy at station (1). This gives E2 = 0.929 ft. This specific energy corresponds to the following a depth of 0.550 m. This is found by solving the final equation below, using a numerical root finder to find y. Both points are shown on the energy curve with the value of their depts. indicated

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We see that the lower energy corresponds to a higher depth with the same flow.

If we had a head loss of 0.06 m from station 1 the energy at station (2) would be 0.959 m – 0.06 m = 0.859 m. This is only possible if the minimum energy is less than 0.859 m. To check this we can compute the minimum energy by first finding the critical depth for this energy, yc. and then applying the formula that Emin = 1.5 yc.

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Since Emin = 0.9183 m we cannot have a head loss of 0.06 m because this would make the specific energy less than its minimum value.

10.34 An old, rough-surfaced, 2-m-diameter concrete pipe with a Manning coefficient of 0.025 carries water at a rate of 5.0 m3/s when it is half full. It is to be replaced by a new pipe with a Manning coefficient of 0.012 that is also to flow half full at the same flowrate. Determine the diameter of the new pipe.

To solve this problem we apply the Manning equation to both the old and new pipes and set the results equal to each other because that the two flowrates are the same: Qold = Qnew.

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We are given no data on the slope, but we can assume that the slope will be the same for the old and the new pipes. In addition, we note that for a pipe half full, the cross sectional area for the flow is A = πD2/8 and the wetted perimeter is P = πD/2, so the hydraulic radius Rh = A/P = D/4. With these expressions for area and hydraulic radius our equation for the old and new flowrates become (after canceling the slope that is the same for both flows)

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Since we are dealing with ratios, the dimensions of the diameters and Manning coefficients will cancel. Taking the 3/8th power of the second equation gives.

[pic] = 1.52 m

10.44 A trapezoidal channel with a bottom width of 3 m and sides with a horizontal:vertical slope of 2:1 is lined with fine gravel (n = 0.020) and is to carry 10 m3/s. Can this channel be built with a slope of S0 = 0.00010 if it is necessary to keep the velocity below 0.75 m/s to prevent scouring of the bottom? Explain.

To solve this problem we apply the Manning equation to determine the size, y. required with the proposed slope and the given flow rate. Once we find the value of y we can solve for the velocity to see if it is less than 0.75 m/s.

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The cross sectional area is the area of the rectangle, 3y, plus two times the areas of one triangular side, (1/2)(2y)(y) = y2, so the total area is 3y + 2y2. The wetted perimeter is the 3 m along the bottom, plus the two diagonal sides of length [(2y)2 + y2]1/2 = 51/2y. This gives a total length of 3 + 2(51/2y). With this definition of the area and perimeter the flowrate is

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With the flow rate in m3/s and the default dimensions for the Manning coefficient, the length terms are in meters, so the value of y will be in meters. Rearranging the equation to solve for y gives.

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Using a computer or calculator equation solver, the value of y is found to be 2.249 m. We can then compute the area and the resulting velocity.

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So, this design will give a velocity less than the required maximum of 0.75 m/s.

10.51 A 10-ft-wide rectangular channel is built to bypass a dam so that fish can swim upstream during their migration. During normal conditions when the water depth is 4 ft, the water velocity is 5 ft/s. Determine the velocity during a flood when the water depth is 8 ft.

In this problem, we can assume that the slope and the Manning coefficient will be the same for both normal and flood conditions and we can write the equations for the velocity in these two conditions as follows.

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With the assumption that the slope and the Manning coefficient will be the same for both normal and flood conditions, these equations give the following relation between the velocities in these two conditions. In getting the final equation we use the definition of the hydraulic radius for a rectangular channel as A/P = by/(2y + b) where y is the depth and b is the width. (Note that the wetted perimeter does not include the open surface of the channel. Since the width, b = 10 ft for both the normal and flood conditions, we do not use a subscript for b.

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[pic] = 6.21 ft/s

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