Q2) The process shown in Figure below consists of: V₁-3 m³, and V2-1 m³. Volumetric flow rate q=300 1/s and assuming constant flow and perfect mixing: 1- Find the transfer function C2(s)/Ci(s) 2- If Ci(0) = 0.0 and Ci(0+) = 0.5, calculate C2(13) and C2(00). 3- Plot the response of C2(t) on a graph paper. Is the response non-oscillatory? qi C₁ V: 91 C1 8³ C2. 92

Introductory Circuit Analysis (13th Edition)
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ISBN:9780133923605
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Q2) The process shown in Figure below consists of: V1=3 m³, and V2=1 m³. Volumetric
flow rate q =300 1/s and assuming constant flow and perfect mixing:
1- Find the transfer function C2(s) / Ci(s)
2- If C:(0) = 0.0 and Ci(0+) = 0.5, calculate C2(13) and C2(0).
%3D
3- Plot the response of C2(t) on a graph paper. Is the response non-oscillatory?
91
V:
C1
Vz
C2.
92
Transcribed Image Text:Q2) The process shown in Figure below consists of: V1=3 m³, and V2=1 m³. Volumetric flow rate q =300 1/s and assuming constant flow and perfect mixing: 1- Find the transfer function C2(s) / Ci(s) 2- If C:(0) = 0.0 and Ci(0+) = 0.5, calculate C2(13) and C2(0). %3D 3- Plot the response of C2(t) on a graph paper. Is the response non-oscillatory? 91 V: C1 Vz C2. 92
Q1) As a new control engineer, your first task is to develop an empirical transfer function
model the temperature in a bioreactor. The manipulated variable that you will use is the
position of the cooling water valve. The plant operations manager, you increase the
cooling water valve position by 5%. The results of step test are shown below (plotted in
perturbation variables). Write the appropriate response as function of time T(t).
Response of Reactor Temperature to a 5% increase in
coolant flow at t=10 minutes
10
ㅇ
-5 0
20
40 60
1000
80
-10
-10
-15
-20
-20
-25
-30
-30
-35
-40
Time in minutes
Temperature in C
Valve opening %
Transcribed Image Text:Q1) As a new control engineer, your first task is to develop an empirical transfer function model the temperature in a bioreactor. The manipulated variable that you will use is the position of the cooling water valve. The plant operations manager, you increase the cooling water valve position by 5%. The results of step test are shown below (plotted in perturbation variables). Write the appropriate response as function of time T(t). Response of Reactor Temperature to a 5% increase in coolant flow at t=10 minutes 10 ㅇ -5 0 20 40 60 1000 80 -10 -10 -15 -20 -20 -25 -30 -30 -35 -40 Time in minutes Temperature in C Valve opening %
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