Please try to solve in 1 hour Water is discharging out of a tank via a pipe with length L = 4.2 m and diameter D = 3.5 cm into an unconnected reservoir (note the free-flowing jet starting at the end of thehorizontal pipe section in the figure below).The water level in the tank above the centre of the pipe remains constant at H = 4.2 m (see figure below).You can assume a density of water p = 1001 kg/m³, dynamic viscosity of water u = 0.001 Pa · s and acceleration due to gravity 9.81 m/s?.You can assume that there are no local losses.HL, Da) Whatthe friction factor of the pipe for a flow rate of Q = 3.9 L/s?Provide your answers to 3 decimal places.b) For this case, what is the roughness height of the pipe?Provide your answers to 3 decimal places.kis =mm

Length of pipe = 4.2 mDiameter of pipe = 3.5 cm = 0.035 mH = 4.2 mDensity of water = ρ = 1001 kg/m3μ…

Water is discharging out of a tank via a pipe with length L 4.2 m and diameter D= 3.5 cm into an unconnected reservoir (note the free-flowing jet starting at the end of the horizontal pipe section in the figure below). The water level in the tank above the centre of the pipe remains constant at H = 4.2 m (see figure below). You can assume a density of water p= 1001 kg/m, dynamic viscosity of water u = 0.001 Pa s and acceleration due to gravity 9.81 m/s². You can assume that there are no local losses. H L. D a) What is the friction factor of the pipe for a flow rate of Q = 3.9L/s? Provide your answers to 3 decimal places. f = b) For this case, what is the roughness height of the pipe? Provide your answers to 3 decimal places. k. = mm

Water is discharging out of a tank via a pipe with length L 4.2 m and diameter D= 3.5 cm into an unconnected reservoir (note the free-flowing jet starting at the end of the horizontal pipe section in the figure below). The water level in the tank above the centre of the pipe remains constant at H = 4.2 m (see figure below). You can assume a density of water p= 1001 kg/m, dynamic viscosity of water u = 0.001 Pa s and acceleration due to gravity 9.81 m/s². You can assume that there are no local losses. H L. D a) What is the friction factor of the pipe for a flow rate of Q = 3.9L/s? Provide your answers to 3 decimal places. f = b) For this case, what is the roughness height of the pipe? Provide your answers to 3 decimal places. k. = mm

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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