MECHANICS OF FLUIDS (I) Figure 1(1)QinL.dz == 0.075 m| QoutFigure 1(II):Qout,210 mQout,1di = 0.075 m kin = 0.18 m³/s. N(1) A cylindrical tank is open at the top, with water flow rate of Qindischarged into the tank. Water is flow out from the tank throughcircular outlet with diameter of di =0.075 m as shows in Figure 1(1). Design the tank with all necessarydimension, such that:Water will not overflow for given Qin, andGiven Qin can fill half of the tank in 100 s, with maximum volume ofwater.(ii) After the flow in (I) reached steady state (maximum possible height),the inflow is stopped (Qin = 0), and another opening is created at 10 mfrom the bottom of the tank, as shows in Figure 1(1) below. Water islet discharged from the tank through two outlets. Predict the minimumvalue of diameter d2 of the new outlet so that the water can be fullydischarged from the tank in time T s. Note that water discharge fromsecond outlet (Qout.2) will be 0 once the water level is below 10 m.Take T = 188 s,

Given : Qin=0.18 m3/st=100 sd1=0.075 m To find : Design the tank dimension

kin = 0.18 m³/s. N (6) A cylindrical tank is open at the top, with water flow rate of Qin discharged into the tank. Water is flow out from the tank through circular outlet with diameter of di = 0.075 m as shows in Figure 1(1). Design the tank with all necessary dimension, such that: Water will not overflow for given Qin, and Given Qin can fill half of the tank in 100 s, with maximum volume of water. (i) After the flow in (I) reached steady state (maximum possible height), the inflow is stopped (Qin = 0), and another opening is created at 10 m from the bottom of the tank, as shows in Figure 1(1) below. Water is let discharged from the tank through two outlets. Predict the minimum value of diameter d2 of the new outlet so that the water can be fully discharged from the tank in time T s. Note that water discharge from second outlet (Qout.2) will be 0 once the water level is below 10 m. Take T = 188 s,

kin = 0.18 m³/s. N (6) A cylindrical tank is open at the top, with water flow rate of Qin discharged into the tank. Water is flow out from the tank through circular outlet with diameter of di = 0.075 m as shows in Figure 1(1). Design the tank with all necessary dimension, such that: Water will not overflow for given Qin, and Given Qin can fill half of the tank in 100 s, with maximum volume of water. (i) After the flow in (I) reached steady state (maximum possible height), the inflow is stopped (Qin = 0), and another opening is created at 10 m from the bottom of the tank, as shows in Figure 1(1) below. Water is let discharged from the tank through two outlets. Predict the minimum value of diameter d2 of the new outlet so that the water can be fully discharged from the tank in time T s. Note that water discharge from second outlet (Qout.2) will be 0 once the water level is below 10 m. Take T = 188 s,

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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Concept explainers

Properties of Fluids

The term fluid represents a type of substance that can easily change its shape under any external pressure/force and can flow. Fluids can acquire any shape in which it is stored and can resist normal stresses but cannot resist shear stress in rest condition. Whenever external shear stress is applied to fluids, it starts to flow. The fluids may be liquid or gas. Example- water, air, etc.

Question

MECHANICS OF FLUIDS (I)

Figure 1(1)
Qin
L.
dz =
= 0.075 m
| Qout
Figure 1(II):
Qout,2
10 m
Qout,1
di = 0.075 m

kin = 0.18 m³/s. N
(1) A cylindrical tank is open at the top, with water flow rate of Qin
discharged into the tank. Water is flow out from the tank through
circular outlet with diameter of di =
0.075 m as shows in Figure 1(1). Design the tank with all necessary
dimension, such that:
Water will not overflow for given Qin, and
Given Qin can fill half of the tank in 100 s, with maximum volume of
water.
(ii) After the flow in (I) reached steady state (maximum possible height),
the inflow is stopped (Qin = 0), and another opening is created at 10 m
from the bottom of the tank, as shows in Figure 1(1) below. Water is
let discharged from the tank through two outlets. Predict the minimum
value of diameter d2 of the new outlet so that the water can be fully
discharged from the tank in time T s. Note that water discharge from
second outlet (Qout.2) will be 0 once the water level is below 10 m.
Take T = 188 s,

Branch of science that deals with the stationary and moving bodies under the influence of forces.

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