The gauge pressure of water at A is 150.5 kPa. Water flows through the pipe at A with a velocity of 18 m/s, and out the pipe at B and C with the same velocity v. Neglect the weight of water within the pipe and the weight of the pipe. The pipe has a diameter of 50 mm at A, and at B and C the diameter is 25 mm. Pw = 1000 kg/m³. (Figure 1) Figure B A 1 of 1 18 m/s Part A Determine the component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium. Express your answer to three significant figures and include the appropriate units. F₂ = Submit Part B F₁ = ■μÅ Submit Value Request Answer Determine the y component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium. Express your answer to three significant figures and include the appropriate units. ■μÅ Value Units Request Answer ? Units Review ?

The gauge pressure of water at A is 150.5 kPa. Water flows through the pipe at A with a velocity of 18 m/s, and out the pipe at B and C with the same velocity v. Neglect the weight of water within the pipe and the weight of the pipe. The pipe has a diameter of 50 mm at A, and at B and C the diameter is 25 mm. Pw = 1000 kg/m³. (Figure 1) Figure B A 1 of 1 18 m/s Part A Determine the component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium. Express your answer to three significant figures and include the appropriate units. F₂ = Submit Part B F₁ = ■μÅ Submit Value Request Answer Determine the y component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium. Express your answer to three significant figures and include the appropriate units. ■μÅ Value Units Request Answer ? Units Review ?

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

See similar textbooks

Related questions

Q: Water is flowing in a 90ο pipe with uniform cross section area of A=0.0083 m2. The velocity along…

Q: A horizontal pipe is full of flowing water. At location A the velocity is 1.5 m/s and the…

A: The Pressure of the water at B is 133.43 kN/m3.Explanation:Given:v1 = Velocity at location A = 1.5…

Q: 1. Water (p = 1000- kg H = 10-3 flows in a horizontal constant-area pipe; the pipe cross ms section…

Q: Assume the water in the first tank maintains its height and pressure. The valve is opened and after…

A: Solution: Given Data: P=200 kPaρ=1000 kg/m3D=5 cmPatm=100 kPa To Find: Mass flow rate through the…

Q: A small, high pressure water jet can be used for cutting various materials. A jet with a speed of…

A: For the solution refer below images.

Q: Water is stored in a pressurised container at a height HT = 8 m. It then moves through a horizontal…

Q: Water enters a turbine through a 320mm diameter pipe at the rate of 215 lit/s at a pressure at A of…

A: given data diameter at A = 320mm flow rate = 215 lit/s pressure at A = 150kpa pressure at B = -35…

Q: Water flow steadily at the rate of 10 gpm through a horizontal tee and discharges to the atmosphere.…

Q: As part of a processing of biofuels, water is pumped into a circular tank with a diameter Dt, as…

A: For the solution refer below images.

Q: Given that h=30 mm, μ=0.002 Pa.s and ρ=1000 kgm-3 Consider a steady-state turbulent flow between…

A: 1 2

Q: The gauge pressure of water at A is 150.5 kPa. Water flows through the pipe at A with a velocity of…

Q: Problem 2- Determine the manometer reading as shown in the figure, when the velocity of fluid…

Q: The jet plane has a mass of 250 Mg and a horizontal velocity of 140 m/s when t = 0. Figure F(KN)…

Q: 1a. Water flows into a tee fitting at a flow rate of 0.02 m3 /s. A pipe is connected to B. The…

Q: Air enters the circular nozzle with a velocity of 32 m/s and then exits to the atmosphere at B.…

A: Given:Velocity at A,VA=32msDiameter at section A,DA=0.4mDiameter at section B,DB=1.2mCross sectional…

Q: 2.attention to the piping system shown in the figure below. Pipes 1, 2, and 3 are installed in…

Q: The gauge pressure of water at A is 150.5 kPa. Water flows through the pipe at A with a velocity of…

Q: Water is stored in a pressurised container at a height HT= 8.4 m. It then moves through a horizontal…

Q: According to Torricelli´s theorem, the velocity of a fluid discharging through the hole of a…

A: Given: The tank with water is shown below: Area of the tank is Ab. Area of the hole is Ao.

Q: The pressure in the 6-in. -diameter pipe at A is 8 psi, and the water column rises to a height of h…

A: Applying Bernoulli's equation at points A and D…

Concept explainers

Fluid Dynamics

The study of the flow of gases and liquids, usually in and around solid surfaces, is known as fluid dynamics in physics and engineering. Fluid dynamics, for example, can be used to evaluate the movement of air through an airplane wing or the surface of a vehicle. It can also be used in ship design to increase the speed at which ships pass through water.

Question

The gauge pressure of water at A is 150.5 kPa. Water
flows through the pipe at A with a velocity of 18 m/s, and
out the pipe at B and C with the same velocity v. Neglect
the weight of water within the pipe and the weight of the
pipe. The pipe has a diameter of 50 mm at A, and at B
and C the diameter is 25 mm. pw = 1000 kg/m³.
(Figure 1)
Figure
v B
22
< 1 of 1 >
A
18 m/s
Part A
Determine the component of force exerted on the elbow necessary to hold the pipe assembly in
equilibrium.
Express your answer to three significant figures and include the appropriate units.
F₂ =
Submit
Part B
F₁ =
Submit
μA
Value
Request Answer
Determine the y component of force exerted on the elbow necessary to hold the pipe assembly in
equilibrium.
Express your answer to three significant figures and include the appropriate units.
Provide Feedback
μA
Value
S
Units
Request Answer
Review
Units
Next >

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

SEE SOLUTION Check out a sample Q&A here

Step 1

Step 2

Step 3

Step 4

Final answer

Step by step

Solved in 5 steps with 3 images

SEE SOLUTION Check out a sample Q&A here

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.

Similar questions

Consider the water flowing through the pipe shown in (Figure 1). The height of the water column in the pitot tube is h = 12 and the height in the piezometer is 3 in. 3 in. B 2 in. 4 in. Determine the average velocity in the pipe at A. Express your answer using three significant figures.
The gauge pressure of water at A is 150.5 kPa. Water flows through the pipe at A with a velocity of 18 m/s, and out the pipe at B and C with the same velocity v. Neglect the weight of water within the pipe and the weight of the pipe. The pipe has a diameter of 50 mm at A, and at B and C the diameter is 35 mm. Pw = 1000 kg/m³. (Figure 1) %D Determine the x component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium. Express your answer to three significant figures and include the appropriate units. View Available Hint(s) HẢ ? Value Units %3D Submit Previous Answers
A fire hydrant supplies water under a pressure of 190 kPa. A 100-mm-diameter hose is connected to it at A and the hose extends 40 m to the fire truck inlet at B. B Part A Determine the pressure of the water as it arrives at B. The friction loss is 1.5 m for every 10 m of hose. The inlet at Bis 0.5 m higher than the hydrant outlet. Express your answer to three significant figures and include the appropriate units.
Calculate the flow rate of the system by accepting the fluid passing through the reservoir-pipe system shown in the figure as ideal. As D1 = 0.5 m, D2 = 0.30 m and D3 = 0.40 m, determine the velocity heights in each pipe. Calculate and show the water levels in the pressure gauge pipes (it will be taken into account that the pressure gauge pipes are externally connected to the 1st and 2nd pipes, but the end of the pressure gauge pipe on the 3rd pipe is turned to the flow direction). Draw the relative energy and relative piezometer lines of the system.
Review The gauge pressure of water at A is 150.5 kPa. Water flows through the pipe at A with a velocity of 18 m/s, and out the pipe at B and C with the same velocity v. Neglect the weight of water within the pipe and the weight of the pipe. The pipe has a diameter of 50 mm at A, and at B and C the diameter is 27 mm Pw = 1000 kg/m³. (Figure 1) Part A Determine the x component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium. Express your answer to three significant figures and include the appropriate units. HA ? F, = Value Units Figure 1 of 1> Submit Request Answer В Part B Determine the y component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium. Express your answer to three significant figures and include the appropriate units. A μΑ ? F, = Value Units y L. 18 m/s Submit Request Answer
Water flows from a nozzle with a speed of V= 10m/s and is collected in a container that moves toward the nozzle with a speed of Vcv = 2 m/s as shown in the figure. If the water between the nozzle and the tank is in the constant diameter stream, what is the accumulation rate of water in the tank?
Oil flows through the 100-mm-diameter pipe with a velocity of 8 m/s (Figure 1). The flow occurs in the horizontal plane. Take p = 900 kg/m³. ▼ Part A If the pressure in the pipe at A and B is assumed to be 90 kPa, determine the component of force the flow exerts on the elbow. Express your answer to three significant figures and include the appropriate units. ▾ View Available Hint(s) ▾ Hint 1. How to determine the component of force the flow exerts on the elbow Build a free body diagram of the control volume containing oil within the pipe and elbow between cross-sections at A and B. Then using the linear momentum equation determine the component of the force the flow exerts on the elbow. F₂ = Part B HÅ Submit Previous Answers Request Answer Value Fy = X Incorrect; Try Again; 4 attempts remaining Submit Units If the pressure in the pipe at A and B is assumed to be 90 kPa, determine they component of force the flow exerts on the elbow. Express your answer to three significant figures and…
0.95 m3/sec flow rate of water flows downwards in a pipe as shown in figure. If the pressures at points 1 and 2 are to be equal. Determine the diameter of the pipe at point 2.The velocity at point 1 is 6.5 m/sec and the diameter of pipe at point 1 is 330 mm. The height between point 1 and point 2 is 2.8 m?
Water is flowing in a 90ο pipe with uniform cross section area of A=0.0083 m2. The velocity along the horizontal direction is v1=6.0 m/s. The pressure at the section 1 is p1=500kPa. Elevation difference and energy losses can be neglected. The density of water is ρ=1000kg/m3. An external force is needed to hold the pipe in equilibrium. (1) Select the correct expression of the external force component in the horizontal direction Rx_________ A. B. C. D.
Starting from the Bernoulli equation and conservation of mass equation, derive the flow rate equation for the pipe shown in Figure Q2. Then, determine the magnitude of the flow rate.
Figure 5 shows a pump connected to a large tank of water. Water flows out of the tank through the pump into a galvanized iron pipe of diameter D = 80 mm at a length, L = 40 m. At the end of the pipe, water exits through a nozzle of diameter D2 = 50 mm. With the height of water h, the pump adds 30 kW of power to the water resulting in a volumetric flowrate of Q=0.05 m³/s. Ignore the length of the nozzle and assume that the velocities are uniform. By using the same height of water and pipe, explain and justify with your calculation, which parameter(s) will be affected if the pump is to be removed from the system. ♡ (1) D2 = 50 mm h (2) Ритp L= 40 m D= 80 mm Figure 5
The diameter of a pipe gradually reduces from 1 m to 0.7 m. The pressure intensity atthe center line of 1 m section is 8and rate of flow of water through the pipe is600 liters/s.,I. Find the intensity of pressure at the center line of 0.7 m section.II. Determine the force exerted by flowing water on transition of the pipe.