Problem 2 (33) The figure shows the vertical wall of a very large tank of water. The fluid flows throughthe small hole in the side of the tank. Fluid path is the curved line. The horizontal velocity of the fluid jetexiting the tank is given by sqrt(2gh), where h is the vertical distance between the water surface andthe opening (h given in table). The tank is D ft deep (D given in table).Find the location R where the fluid hits the sloped surface (x and y values). Use the lower right corner ofthe tank as your origin, as shown.RhD2014(cw pos)10I

Step 1: Let the distance on the ramp where the stream hits from the base of the tank be R. Using the…

Answered: Problem 2 (33) The figure shows the…

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

Similar questions

Q2/ Suppose you have crude oil flows through an annulus between two horizontal pipes with the same center, if the velocity distribution v, and the average velocity Vavg are expressed by: ΔΡ Rr²+ R² In (R₂/R₁) (¹) In 4μL ΔΡ Vavg = R₁ + R₂ R - R In (R₂/R₁ 8µL Where AP: is the pressure drop through the annulus, μ: is the fluid viscosity, L: is the pipe length, R₁ and R₂: are the inside radius of inner and outer pipes, respectively. Write a program in a script file that calculates the velocity distribution and the average velocity. When the script file is executed, it requests the user to input AP, μ, L, R₁ and R₂ where r has many values between R₁ and R₂. The program displays the inputted values and the calculated average velocity (using fprintf) followed by a table with the values r in the first column and the corresponding values of the velocity distribution in the second column.
Answer both
answer it asap and correctly
Please show solution.
The water of a 14’ × 48’ metal frame pool can drain from the pool through an opening at the side of the pool. The opening is about h = 1.05 m below the water level. The capacity of the pool is V = 3740 gallons, the pool can be drained in t = 10.2 mins. P0 is the pressure of the atmosphere. ρ is the density of the water. a. Write the Bernoulli’s equation of the water at the top of the pool in terms of P0, ρ, h. Assuming the opening is the origin. b. Write the Bernoulli’s equation of the water at the opening of the pool in terms of P0, ρ, h and v, where v is the speed at which the water leaves the opening. Assuming the opening is the origin. c. Express v2 in terms of g and h. d. Calculate the numerical value of v in meters per second. e. Express the flow rate of the water in terms of V and t. f. Express the cross-sectional area of the opening, A, in terms of V, v and t. g. Calculate the numerical value of A in cm2
Jet of liquid (14 mm diameter) ejections vertically into the atmosphere. The pressure inside the jet (due to surface tension) will be slightly higher than the atmospheric pressure. Determine the difference in pressure (in Pascal). (take o = 8.35*102 N/m for liquid)
Question 2 A brand of toothpaste is made using a mixture of white and red paste. During the manufacturing process, both pastes are pumped through a pipe, with the red paste lying in the centre of the pipe, as shown in Figure Q2. The pipe has an internal radius, R₂, and the segment of red paste has a radius R₁. The flow is found to follow the Poiseuille equation, i.e. u(r) 1 dp - (R² — r²) 4μ dx dp Where is the pressure gradient. The total flow of dx u is the viscosity of the paste and toothpaste through the pipe is Qtot, and the flowrate of the red paste is red- The toothpaste has a density of p = 1200 kg/m³, and a viscosity of 0.03 Pa.s. The pipe has a radius R₂ 5 cm and a length L = 2 m. = a) Find an expression for the flowrate of the red toothpaste. You answer should be in terms of µ, R₁, R₂, dº) R₂₁ b) The flow in the pipe becomes turbulent when the Reynolds number reaches 2000 (where Re is calculated using the mean velocity across the pipe). What is the maximum pressure drop along…
B) The laminar flow velocity profile in pipe for Newtonian fluid is given by: ux = 2ū [1-(2)²], where us is point velocity at any radial position (r). Use the above relation to find the Ux expression for velocity gradient at the pipe wall.
Q1: Water is flowing from tank A to tank B as shown in the following figure. The flow is steady so that the water level in tank B does not change. Find h, in the figure. The density is constant. The flow is inviscid and irrotational. Hint: apply Bernoulli's equation between the free surface and the discharge for tanks A and B individually. Then, since the flow rate leaving tank A (and entering tank B) must equal the rate leaving tank B, these two Bernoulli's Equations can be substituted and solved for one unknown. 1 10.0 cm = 0.01 m Tank A 士 Tank B d 0.02 m Figure 1. Q1
Study the motion of the fluid has the complex potential in the form : W = - m In Z where m is a real positive constant .
Q(in) is a constant inflow which maintains the water level in the tank. Find the horizontal force needed to hold the tank stationary. If you could make any notes on steps in the method to make it clearer that would be great too. Thanks in advance!
What is the difference in potential energy per pound of mass of fluid at A and at B. STORAGE TANK Z,=30 ft PUMP Z,=10 ft RESERVOIR DATUM

SEE MORE QUESTIONS

Recommended textbooks for you

Elements Of Electromagnetics

Mechanical Engineering

ISBN:

9780190698614

Author:

Sadiku, Matthew N. O.

Publisher:

Oxford University Press

Mechanics of Materials (10th Edition)

Mechanical Engineering

ISBN:

9780134319650

Author:

Russell C. Hibbeler

Publisher:

PEARSON

Thermodynamics: An Engineering Approach

Mechanical Engineering

ISBN:

9781259822674

Author:

Yunus A. Cengel Dr., Michael A. Boles

Publisher:

McGraw-Hill Education

Elements Of Electromagnetics

Mechanical Engineering

ISBN:

9780190698614

Author:

Sadiku, Matthew N. O.

Publisher:

Oxford University Press

Mechanics of Materials (10th Edition)

Mechanical Engineering

ISBN:

9780134319650

Author:

Russell C. Hibbeler

Publisher:

PEARSON

Thermodynamics: An Engineering Approach

Mechanical Engineering

ISBN:

9781259822674

Author:

Yunus A. Cengel Dr., Michael A. Boles

Publisher:

McGraw-Hill Education

Control Systems Engineering

Mechanical Engineering

ISBN:

9781118170519

Author:

Norman S. Nise

Publisher:

WILEY

Mechanics of Materials (MindTap Course List)

Mechanical Engineering

ISBN:

9781337093347

Author:

Barry J. Goodno, James M. Gere

Publisher:

Cengage Learning

Engineering Mechanics: Statics

Mechanical Engineering

ISBN:

9781118807330

Author:

James L. Meriam, L. G. Kraige, J. N. Bolton

Publisher:

WILEY

SEE MORE TEXTBOOKS