210 KPad. 244 KPatatton V: An orifice 100 mm diameter was placed 0.82m above the ground at a vertical side ofan upright cylindrical tank 2.50 m diameter. When opened, its jet hit the ground initially 1.90 mhorizontally away from the orifice. The initial flow rate was 0.023m3/s when water surface was 1.2m above the center of the orifice.24. How long will it take the jet reach the ground?a. 0.51 scecb. 0.322 secC. 0.409 secd. 0.527 sec25. Find the coefficient of velocity.a. 1.2b. 0.82C. 0.60d. 0.9626. Find the coefficient of contraction.a. 0.80b. 0.63c. 0.74d. 0.57he end by the nozzle and the total energyectedSituation VI: The pipe 60 em in lengar is co 2 ZoomRotate DrawSituation VII: Water flows from a reservoir A with water surface elevation 150 m above sea level toower reservoir B at the rate of 190 li/sec. If the length of pipe connecting them is 510 m long andlowerhas a diameter of 300 mm, neglect minor losses,28.What would be the elevation in meters of the water surface in reservoir B if f- 0.02.137.48 mb. 142.60 ma.C.129.60md. 119.20 m= 1.04) oil (sp.gr.0.80), mercurySttuation VIII: A tank contains three liquids, sca water (sp.gr.(sp.gr.diameter is located at the bottom with C 0.60.13.60) with a depth 0.60 m, 1.30 m, and 0.50 m respectively. An orifice 100 mm in29.Determine the discharge.a. 0.016 m'/sb. 0.052 m /sc. 0.121 m /sd. 0.081 m/sSituation IX: Pipes 1, 4. and 3 are connected in series while pipes 2 and 3 are connected in paralerto cach other. Pipe 1 started at point A while that of pipe 4 ends.at-point D. If the discharge of thesystem is 400 liters/second and f- 0.022 for all pipes.LengthPipeDiameter700m800 mmdiameis 2.20

Given values are - Distance of orifice from ground y=0.82 m , Horizontal distance from orifice where…

ton V: An orifice 100 mm diameter was placed 0.82m above the ground at a vertical side of an upright cylindrical tank 2.50 m diameter. When opened, its jet hit the ground initially 1.90 m horizontally away from the orifice. The initial flow rate was 0.023m/s when water surface was 1.2 m above the center of the orifice. 24. How long will it take the jet reach the ground? a. 0.51 sec b. 0.322 sec c. 0.409 sec d. 0.527 sec 25. Find the coefficient of velocity. a. 1.2 b. 0.82 C. 0.60 d. 0.96 26. Find the coefficient of contraction. a. 0.80 b. 0.63 C. 0.74 d. 0.57 end by the nozzle and the total energy

ton V: An orifice 100 mm diameter was placed 0.82m above the ground at a vertical side of an upright cylindrical tank 2.50 m diameter. When opened, its jet hit the ground initially 1.90 m horizontally away from the orifice. The initial flow rate was 0.023m/s when water surface was 1.2 m above the center of the orifice. 24. How long will it take the jet reach the ground? a. 0.51 sec b. 0.322 sec c. 0.409 sec d. 0.527 sec 25. Find the coefficient of velocity. a. 1.2 b. 0.82 C. 0.60 d. 0.96 26. Find the coefficient of contraction. a. 0.80 b. 0.63 C. 0.74 d. 0.57 end by the nozzle and the total energy

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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