Explanation Given information: The flow rate of water is 30 gal / min . The diameter of the double pipe bend is 0.75 in . The pressure at section (1) is 30 lbf / in 2 and pressure at section (2) is 24 lbf / in 2 . The vertical difference between the section (1) and section (2) is 3 ft . The angle of the bend is 50 ° . Write the expression for the torque at point B . T = F 1 z 1 + F 2 z 2 ...(I) Here, the torque is T , the force at the section (1) is F 1 , the force at section (2) is F 2 , the height of section (1) is z 1 and the height of section (2) is z 2 . Write the expression for the force at section (1). F 1 = p 1 A + m ˙ V ...(II) Here, the pressure at section (1) is p 1 , the area is A , the mass flow rate is m ˙ and the velocity is V . Write the expression for the force at section (2). F 2 = p 2 A + m ˙ V ...(III) Here, the pressure at section (2) is p 2 . Write the expression for the area. A = π 4 d 2 Here, the diameter of the pipe is d . Write the expression for the mass flow rate. m ˙ = ρ Q Here, the density of water is ρ and the flow rate is Q . Substitute ρ Q for m ˙ and π 4 d 2 for A in Equation (II). F 1 = p 1 ( π 4 d 2 ) + ρ Q V Substitute ρ Q for m ˙ and π 4 d 2 for A in Equation (III). F 2 = p 2 ( π 4 d 2 ) + ρ Q V Substitute p 1 ( π 4 d 2 ) + ρ Q V for F 1 and p 2 ( π 4 d 2 ) + ρ Q V for F 2 in Equation (I). T = { p 1 ( π 4 d 2 ) + ρ Q V } z 1 + { p 2 ( π 4 d 2 ) + ρ Q V } z 2 ...(IV) Write the expression for the flow rate. Q = A V V = Q A ...(V) Substitute π 4 d 2 for A in Equation (I). V = Q ( π 4 d 2 ) = 4 Q ( π d 2 ) ...(VI) Calculation: Substitute 30 gal / min for Q and 0.75 in for d in Equation (VI). V = 4 ( 30 gal / min ) ( π ( 0.75 in ) 2 ) = 4 ( 30 gal / min ) ( 0.133681 ft 3 1 gal ) ( 1 min 60 s ) ( 1

8th Edition

ISBN: 9789385965494

Author: Frank White

Publisher: MCGRAW-HILL HIGHER EDUCATION

See similar textbooks

Videos

Question

Chapter 3, Problem 3.154P

To determine

The torque required to keep the pipe rotating.

Expert Solution & Answer

Want to see the full answer?

Check out a sample textbook solution

See solution

Chapter 3, Problem 3.153P

Chapter 3, Problem 3.155P

Students have asked these similar questions

Temperature EXAMPLE 1: A diesel engine is fitted with a turbocharger, which comprises a radial compressor driven by a radial exhaust gas turbine. The air is drawn into the compressor at a pressure of 0.95 bar and at a temperature of 15°C, and is delivered to the engine at a pressure of 2.0 bar. The engine is operating on a gravimetric air/fuel ratio of 18: 1, and the exhaust leaves the engine at a temperature of 600°C and at a pressure of 1.8 bar; the turbine exhausts at 1.05 bar. The isentropic efficiencies of the compressor and T(K) turbine are 70 per cent and 80 per cent, respectively. Calculate (i) the temperature of the air leaving the compressor (ii) the temperature of the gases leaving the turbine (iii) the mechanical power loss in the turbocharger expressed as a percentage of the power generated in the turbine. Using the values of : Cpair = 1.01 kJ/kg K, Vair = 1.4 Cpex = 1.15 kJ/kg K, Yex = 1.33 and 2s с P2 Engine P3 W W₁ = mexpex (T3-TA) At W₁ = mair Cpex (T2-T₁) 4 P4…

Problem 8.28 Part A 10 of 10 ■Review The uniform crate resting on the dolly has a mass of 530 kg and mass center at G as shown in (Figure 1). If the front casters contact a high step, and the coefficient of static friction between the crate and the dolly is μs = 0.45, determine the greatest force P that can be applied without causing motion of the crate. The dolly does not move. Express your answer to three significant figures and include the appropriate units. Figure -0.5 m- 0.6 m 0.3 m 0.1 m B 0.4 m 0.3 m > ☐ P = 1210 Submit о ΜΑ N Previous Answers Request Answer × Incorrect; Try Again 1 of 1 < Return to Assignment Provide Feedback ?

Q1: For the system shown in Fig. 6.7, the following data are applicable P1 = 7 bar Q=0.002 m3/sec Pipe: total length 15m and ID 38mm Oil: SG-0.90 and kinematic viscosity (v-0.0001 m2/s) Solve for P2 in units of bars. Motor OH Pump Breather P1 Pipe length = 3m 90' elbow ☐ 38 mm (ID) Pipe length = 2m P2 Load force Pipe length 4 m = Pipe length=6m 90' elbow

Chapter 3 Solutions

Fluid Mechanics, 8 Ed

Ch. 3 - Prob. 3.1P Ch. 3 - Consider the angular momentum relation in the form...Ch. 3 - For steady low-Reynolds-number (laminar) flow...Ch. 3 - Water at 20°C flows through a long elliptical duct...Ch. 3 - Water at 20°C flows through a 5-in-diameter smooth...Ch. 3 - Water fills a cylindrical tank to depth h. The...Ch. 3 - A spherical tank, of diameter 35 cm, is leaking...Ch. 3 - Three pipes steadily deliver water at 20°C to a...Ch. 3 - A laboratory test tank contains seawater of...Ch. 3 - Water flowing through an 8-cm-diameter pipe enters...

Knowledge Booster

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, mechanical-engineering and related others by exploring similar questions and additional content below.