1. Dynamic Behavior Chapter 5
In analyzing process dynamic and process control systems, it is important to know how the process responds to changes in the process inputs.
A number of standard types of input changes are widely used for two reasons:
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They are representative of the types of changes that occur in plants.
They are easy to analyze mathematically.

2. Step Input
A sudden change in a process variable can be approximated by a step change of magnitude, M:
Chapter 5
The step change occurs at an arbitrary time denoted as t = 0.
Special Case: If M = 1, we have a “unit step change”. We give it the symbol, S(t).
Example of a step change: A reactor feedstock is suddenly switched from one supply to another, causing sudden changes in feed concentration, flow, etc.

3. Example:
The heat input to the stirred-tank heating system in Chapter 2 is suddenly changed from 8000 to 10,000 kcal/hr by changing the electrical signal to the heater. Thus,
and
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Ramp Input
Industrial processes often experience “drifting disturbances”, that is, relatively slow changes up or down for some period of time.
The rate of change is approximately constant.

4. Chapter 5 We can approximate a drifting disturbance by a ramp input:
Examples of ramp changes:
Ramp a setpoint to a new value.
Feed composition, heat exchanger fouling, catalyst activity, ambient temperature.
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Rectangular Pulse
It represents a brief, sudden change in a process variable:

5. Chapter 5 Examples: Reactor feed is shut off for one hour.
URP h
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tw Time, t
Examples:
Reactor feed is shut off for one hour.
The fuel gas supply to a furnace is briefly interrupted.

6. Chapter 5

7. Other Inputs
4. Sinusoidal Input
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8. Processes are also subject to periodic, or cyclic, disturbances
Processes are also subject to periodic, or cyclic, disturbances. They can be approximated by a sinusoidal disturbance:
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where: A = amplitude, ω = angular frequency
Examples:
24 hour variations in cooling water temperature.
60-Hz electrical noise (in USA)
Day night temperature variation (if no weather change)

9. Chapter 5 Impulse Input Here,
It represents a short, transient disturbance.
Examples:
Electrical noise spike in a thermo-couple reading.
Injection of a tracer dye.
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Useful for analysis since the response to an impulse input is the inverse of the TF. Thus,
Here,

10. Chapter 5 The corresponding time domain express is: where:
Suppose Then it can be shown that:
Consequently, g(t) is called the “impulse response function”.

11. First-Order System Chapter 5
The standard form for a first-order TF is:
where:
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Consider the response of this system to a step of magnitude, M:
Substitute into (5-16) and rearrange,

12. Chapter 5 Take L-1 (cf. Table 3.1),
Let steady-state value of y(t). From (5-18),
t ___
0 0
0.632
0.865
0.950
0.982
0.993
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Note: Large τ means a slow response.

14. Chapter 5 For a sine input (1st order process) output is...
By partial fraction decomposition,

15. Chapter 5 Inverting, note: f is not a function of t but of t and w.
this term dies out for large t
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note: f is not a function of t but of t and w.
For large t, y(t) is also sinusoidal,
output sine is attenuated by…
(fast vs. slow w)

16. Integrating Process Chapter 5
Not all processes have a steady-state gain. For example, an “integrating process” or “integrator” has the transfer function:
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Consider a step change of magnitude M. Then U(s) = M/s and,
Thus, y(t) is unbounded and a new steady-state value does not exist.

17. Chapter 5 Common Physical Example:
Consider a liquid storage tank with a pump on the exit line:
Assume:
Constant cross-sectional area, A.
Mass balance:
Eq. (1) – Eq. (2), take L, assume steady state initially,
For (constant q),
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18. Second-Order Systems Chapter 5 Standard form:
which has three model parameters:
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Equivalent form:

19. Chapter 5 Block Notation:
Composed of two first order subsystems (G1 and G2)
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2nd order ODE model (overdamped)
roots:

20. The type of behavior that occurs depends on the numerical value of damping coefficient, :
It is convenient to consider three types of behavior:
Damping Coefficient
Type of Response
Roots of Charact. Polynomial
Overdamped
Real and ≠
Critically damped
Real and =
Underdamped
Complex conjugates
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Note: The characteristic polynomial is the denominator of the transfer function:
What about ? It results in an unstable system

22. Chapter 5
Note: Responses exhibiting oscillation and overshoot (y/KM > 1) are obtained only for values of ζ less than one.

23. Chapter 5 Note: Large values of ζ yield a sluggish (slow) response.
The fastest response without overshoot is obtained for the critically damped case ζ=1.
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24. Several general remarks can be made concerning the responses show in Figs. 5.8 and 5.9:
Responses exhibiting oscillation and overshoot (y/KM > 1) are obtained only for values of ζ less than one.
Large values of ζ yield a sluggish (slow) response.
The fastest response without overshoot is obtained for the critically damped case ζ=1.
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25. Chapter 5

26. 1. Rise Time: tr is the time the process output takes to first reach the new steady-state value.
Time to First Peak: tp is the time required for the output to reach its first maximum value.
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3. Settling Time: ts is defined as the time required for the process output to reach and remain inside a band whose width is equal to ±5% of the total change in y. The term 95% response time sometimes is used to refer to this case. Also, values of ±1% sometimes are used.

27. Chapter 5 4. Overshoot: OS = a/b (% overshoot is 100a/b).
5. Period of Oscillation: P is the time between two successive peaks or two successive valleys of the response.
6. Decay Ratio: DR = c/a (where c is the height of the second peak).
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28. Second Order Step Change
Overshoot
time of first maximum
c. decay ratio (successive maxima – not min.)
d. period of oscillation
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29. Sinusoidal response
Linear second-order system is forced by a sinusoidal input
Asin ωt, the output for large value of time (after exponential
terms have disappeared) is also sinusoidal signal

30. The ratio of output to input amplitude is the amplitude ratio AR(= )
The ratio of output to input amplitude is the amplitude ratio AR(= ). When normalized by the process gain (K), it is called normalized amplitude ratio ARN

31. Chapter 5