-Ve, Ae, Pe10Vz. AzV₁,A₂ ====3. You are designing a piping system for a art instillation. As shown in Figure 3, a pipe splits into two at an angle030º, the splits both exit to atmosphere. If the pipe contains a fluid with density p = 1000kg/m³, Pin = 150kPagauge pressure, Vin 25m/s, Ain 0.02m², A₁ 0.003m², A₂ = 0.007m², and finally the artist has requested thatthe velocity of exit 2 to be V2 = 21m/s. Determine the anchoring force necessary to hold the pipe junction stationary.Fx [16000 20000N] Fy: [18700 - 25000N]:

Answered: Image /qna-images/answer/d0e37ddf-0a58-445e-b4d8-6fe6f8d2a71f.jpg

Answered: -Ve, Ae, Pe 10 Vz. Az V₁,A₂ = = = = 3.…

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

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Problem 3. Outcome 5. Please show all work. Air at standard pressure but with T= 50°C flows through the ducting system shown in the figure. The gauge measures the pressure difference between the downstream and upstream points. All duct sections have circular cross section. Use the following geometry: D₁ = 60 mm, D, = 200 mm, L= 2 m. At this temperature, ai = 1.95 x 10-5 kg/m-s. Also recall that Rai = 287 J/kg-K. The center pipe is smooth with e0. Ap Voo D2 L D₁ Dz Figure for problem 3. The velocity entering the system, Voo; is measured to be 20 m/s. Estimate the Ap = Pdownstream Pupstream measured by the pressure gauge.
Can you do Part D of this question. Parts A - C have already been done.
D1: 0.3 m D2: 0.1 m
x= 7 y=8 z=16 9=2.8
a=2 , b=1 As seen in the figure, the vacuum pump provides air flow in an insulated pipe with a cross section of 4a,b mm2. The air moves along a straight line in a room with a pressure of 100,ab kPa and a temperature of 2a,b oC. If the pressure in section 1 is 98,ab kPa and the temperature in section 2 is 1a,b oC; This is Fanno flow. i) Calculate mass flow rate, ii) Calculate at section 1, flow velocity U1, density, Mach number Ma1, Re, f values iii) Calculate at section 2, find the stopping pressure and temperature, Mach number Ma2, U2 velocity, density, mass flow rate iv) Calculate friction coefficient and force on the channel walls between section 1 and 2. Solve the problem by making the necessary assumptions. v) Calculate L1-2 pipe length and expressions can also be used. Solve the problem by making the necessary assumptions and drawing the schematic figure.
I need the answer quickly
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…
1. Water flows steadily through a smooth, circular, horizontal pipe. The discharge rate is 1.5 ft3/s and the pipe diameter is 6 in. Find the difference in the pressure between two points 400 f t apart if the water temperature is 60°F. 2. A 2000-gallon swimming pool is to be filled with a 0.75 in. diameter garden hose. If the supply pressure is 60 psig, find the time required to fill the pool. The hose is 100 f t long, with a friction factor equal to 0.02.
Find and show the desired ones.
water flows through 30 mm internal diameter pipe at atmospheric pressure. pitot tube measures the velocity of water at the center of pipe as shown in the fig. the pressure difference between the impact tube and the static tube is 20cm of carbon tetrachloride (density: 1600 kg/m³). calculate the volumetric flow rate through the pipe in cubic meter per hour. velocity of water is cp.
In Figure 1, water flows vertically downwards in a trococonical tube. Diameters are D1=40 in ; D2=20in and the height of the device H=6 ft .If the flow is 1 ft³/s, find the pressure difference between the ends of the pipe
Given: diameter of pipe in point 1 = 3.9indiameter of pipe in point 2 = 2.5inspecific gravity of the liquid = 0.79h(ft) = 0.60ftpressure at point 1 = 14.6 psiapressure at point 2 = 49 psiapump and motor efficiency = 66%diameter of pipe in point 4 = 4.5indiameter of pipe in point 5 = 2.3 inZ3 = 35ft With the schematic diagram of a pump, tanks, and piping determine the following:1) The velocity of the liquid at point 2 (ft/s)2) Pump work used by the liquid (Wpump U) (hp)3) Electric motor power in out (kW)4) In figure 3, the shaded (pink) in the U tube is mercury; determine y. specific gravity of mercury 13.75) Mass flow rate

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