In fluid mechanics, the equation that models the fluid level in a tank is: dh dt 1 (min-mout) Ap h is the water level of the tank A is the surface area of the bottom of the tank p is the density of the fluid min and mout are the mass flow rates of water in and out of the tank, the flow out is a function of the water level h: mout . . R is the resistance at the exit. Assume that the exit is at the bottom of the tank. g is the gravitational acceleration What to Do: 1. Build a model in Simulink to calculate the water level, h, as a function of time. Your model should stop running as soon as the tank is full. 2. Assuming the height of the tank is 2 meters, after how many seconds does the tank fill up? Use the following constants to test your model: A: area of the bottom of the tank 1 m² p: the density of fluid = 1000 kg/m³ R: the resistance at the exit = 3 (kg.m)-1/2 ho: Initial height of the fluid in the tank = 0 m g: the gravitational acceleration = 9.81 m/s² max: Height of tank = 2 m min: mass flow rate of water = 50 (kg/s) . . . 1 == . √pgh . R water What to Submit: 1. A Simulink file called Tank Simulink.slx 2. A one-page PDF file showing your Simulink mode, the height vs. time plot and showing when the model stops. 41
In fluid mechanics, the equation that models the fluid level in a tank is: dh dt 1 (min-mout) Ap h is the water level of the tank A is the surface area of the bottom of the tank p is the density of the fluid min and mout are the mass flow rates of water in and out of the tank, the flow out is a function of the water level h: mout . . R is the resistance at the exit. Assume that the exit is at the bottom of the tank. g is the gravitational acceleration What to Do: 1. Build a model in Simulink to calculate the water level, h, as a function of time. Your model should stop running as soon as the tank is full. 2. Assuming the height of the tank is 2 meters, after how many seconds does the tank fill up? Use the following constants to test your model: A: area of the bottom of the tank 1 m² p: the density of fluid = 1000 kg/m³ R: the resistance at the exit = 3 (kg.m)-1/2 ho: Initial height of the fluid in the tank = 0 m g: the gravitational acceleration = 9.81 m/s² max: Height of tank = 2 m min: mass flow rate of water = 50 (kg/s) . . . 1 == . √pgh . R water What to Submit: 1. A Simulink file called Tank Simulink.slx 2. A one-page PDF file showing your Simulink mode, the height vs. time plot and showing when the model stops. 41
Principles of Heat Transfer (Activate Learning with these NEW titles from Engineering!)
8th Edition
ISBN:9781305387102
Author:Kreith, Frank; Manglik, Raj M.
Publisher:Kreith, Frank; Manglik, Raj M.
Chapter5: Analysis Of Convection Heat Transfer
Section: Chapter Questions
Problem 5.18P: The drag on an airplane wing in flight is known to be a function of the density of air (), the...
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