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Chapter 10: Q54P (page 260)

Show that the power needed to drive a fluid through a pipe with uniform cross-section is equal to the volume rate of flow, \({\bf{Q}}\), times the pressure difference \({{\bf{P}}_{\bf{1}}}{\bf{ - }}{{\bf{P}}_{\bf{2}}}\), Ignore viscosity.

Short Answer

Expert verified

The power needed to drive a fluid through a pipe is \(\left( {{P_1} - {P_2}} \right)Q\).

Step by step solution

01

Understanding Viscosity

The frictional force which acts between the adjacent layers of the fluid is termed as viscosity. The frictional force acts when the layers of fluid move with respect to each other.

02

Step 2: Calculating the power

The work done on the fluid can be given as,

\(W = \left( {{P_1} - {P_2}} \right)V\)

Here, \(W\) is the work done, \({P_1} - {P_2}\) is the pressure difference and \(V\)is the volume.

The power needed to drive the fluid can be given as,

\(P = \frac{W}{t}\)

Here, \(P\)is the power needed and \(t\)is the time taken.

Substitute the values in the above equation.

\(P = \frac{{\left( {{P_1} - {P_2}} \right)V}}{t}\)

The flow rate of the fluid can be given as,

\(Q = \frac{V}{t}\)

Here, \(Q\)is the flow rate.

Put the known value in equation of power,

\(P = \left( {{P_1} - {P_2}} \right)Q\)

Therefore, the power required to drive the fluid through pipe is \(\left( {{P_1} - {P_2}} \right)Q\).

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Most popular questions from this chapter

(II) Poiseuille’s equation does not hold if the flow velocity is high enough that turbulence sets in. The onset of turbulence occurs when the Reynolds number, \(Re\) , exceeds approximately 2000. \(Re\) is defined as

\({\mathop{\rm Re}\nolimits} = \frac{{2\overline v r\rho }}{\eta }\)

where \(\overline v \) is the average speed of the fluid, \(\rho \) is its density, \(\eta \) is its viscosity, and \(r\) is the radius of the tube in which the fluid is flowing. (a) Determine if blood flow through the aorta is laminar or turbulent when the average speed of blood in the aorta \(\left( {{\bf{r = 0}}{\bf{.80}}\;{\bf{cm}}} \right)\) during the resting part of the heart’s cycle is about \({\bf{35}}\;{\bf{cm/s}}\). (b) During exercise, the blood-flow speed approximately doubles. Calculate the Reynolds number in this case, and determine if the flow is laminar or turbulent.

(II)What is the lift (in newtons) due to Bernoulli’s principle on a wing of area\(88\;{{\rm{m}}^2}\)if the air passes over the top and bottom surfaces at speeds of 280 m/s and 150 m/s, respectively?

Beaker A is filled to the brim with water. Beaker B is the same size and contains a small block of wood that floats when the beaker is filled with water to the brim. Which beaker weighs more?

(a) Beaker A.

(b) Beaker B.

(c) The same for both

A rowboat floats in a swimming pool, and the level of the water at the edge of the pool is marked. Consider the following situations. (i) The boat is removed from the water. (ii) The boat in the water holds an iron anchor which is removed from the boat and placed on the shore. For each situation, the level of the water will,

(a) Rise.

(b) Fall.

(c) Stay the same.

A copper (Cu) weight is placed on top of a 0.40-kg block of wood (\({\bf{density = 0}}{\bf{.60 \times 1}}{{\bf{0}}^{\bf{3}}}\;{\bf{kg/}}{{\bf{m}}^{\bf{3}}}\) ) floating in water, as shown in Fig. 10–58. What is the mass of the copper if the top of the wood block is exactly at the water’s surface?

Figure: 10-58
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