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Transient Stability

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Title: Transient Stability


1
ECE 476POWER SYSTEM ANALYSIS
  • Lecture 24
  • Transient Stability
  • Professor Tom Overbye
  • Department of Electrical andComputer Engineering

2
Announcements
  • Be reading Chapter 13.
  • HW 11 is not turned in but should be done before
    final. HW 11 is 13.1, 13.7, 13.8, 13.18, and the
    special problem (see website for complete
    assignment)
  • Final is Tuesday Dec 16 from 7 to 10pm in EL 165
    (note this is NOT what the web says). Final is
    comprehensive. One new note sheet, and your two
    old note sheets are allowed

3
Generator Electrical Model
  • The simplest generator model, known as the
    classical model, treats the generator as a
    voltage source behind the direct-axis transient
    reactance the voltage magnitude is fixed, but
    its angle changes according to the mechanical
    dynamics

4
Generator Mechanical Model
Generator Mechanical Block Diagram
5
Generator Mechanical Model, contd
6
Generator Mechanical Model, contd
7
Generator Mechanical Model, contd
8
Generator Swing Equation
9
Single Machine Infinite Bus (SMIB)
  • To understand the transient stability problem
    well first consider the case of a single machine
    (generator) connected to a power system bus with
    a fixed voltage magnitude and angle (known as an
    infinite bus) through a transmission line with
    impedance jXL

10
SMIB, contd
11
SMIB Equilibrium Points
12
Transient Stability Analysis
  • For transient stability analysis we need to
    consider three systems
  • Prefault - before the fault occurs the system is
    assumed to be at an equilibrium point
  • Faulted - the fault changes the system equations,
    moving the system away from its equilibrium point
  • Postfault - after fault is cleared the system
    hopefully returns to a new operating point

13
Transient Stability Solution Methods
  • There are two methods for solving the transient
    stability problem
  • Numerical integration
  • this is by far the most common technique,
    particularly for large systems during the fault
    and after the fault the power system differential
    equations are solved using numerical methods
  • Direct or energy methods for a two bus system
    this method is known as the equal area criteria
  • mostly used to provide an intuitive insight into
    the transient stability problem

14
SMIB Example
  • Assume a generator is supplying power to an
    infinite bus through two parallel transmission
    lines. Then a balanced three phase fault occurs
    at the terminal of one of the lines. The fault
    is cleared by the opening of this lines circuit
    breakers.

15
SMIB Example, contd
Simplified prefault system
16
SMIB Example, Faulted System
During the fault the system changes
The equivalent system during the fault is then
During this fault no power can be
transferred from the generator to the system
17
SMIB Example, Post Fault System
After the fault the system again changes
The equivalent system after the fault is then
18
SMIB Example, Dynamics
19
Transient Stability Solution Methods
  • There are two methods for solving the transient
    stability problem
  • Numerical integration
  • this is by far the most common technique,
    particularly for large systems during the fault
    and after the fault the power system differential
    equations are solved using numerical methods
  • Direct or energy methods for a two bus system
    this method is known as the equal area criteria
  • mostly used to provide an intuitive insight into
    the transient stability problem

20
Transient Stability Analysis
  • For transient stability analysis we need to
    consider three systems
  • Prefault - before the fault occurs the system is
    assumed to be at an equilibrium point
  • Faulted - the fault changes the system equations,
    moving the system away from its equilibrium point
  • Postfault - after fault is cleared the system
    hopefully returns to a new operating point

21
Transient Stability Solution Methods
  • There are two methods for solving the transient
    stability problem
  • Numerical integration
  • this is by far the most common technique,
    particularly for large systems during the fault
    and after the fault the power system differential
    equations are solved using numerical methods
  • Direct or energy methods for a two bus system
    this method is known as the equal area criteria
  • mostly used to provide an intuitive insight into
    the transient stability problem

22
Numerical Integration of DEs
23
Examples
24
Eulers Method
25
Eulers Method Algorithm
26
Eulers Method Example 1
27
Eulers Method Example 1, contd
28
Eulers Method Example 2
29
Euler's Method Example 2, cont'd
30
Euler's Method Example 2, cont'd
31
Euler's Method Example 2, cont'd
Below is a comparison of the solution values for
x1(t) at time t 10 seconds
32
Transient Stability Example
  • A 60 Hz generator is supplying 550 MW to an
    infinite bus (with 1.0 per unit voltage) through
    two parallel transmission lines. Determine
    initial angle change for a fault midway down one
    of the lines.H 20 seconds, D 0.1. Use
    Dt0.01 second.

Ea
33
Transient Stability Example, cont'd
34
Transient Stability Example, cont'd
35
Transient Stability Example, cont'd
36
Transient Stability Example, cont'd
37
Equal Area Criteria
  • The goal of the equal area criteria is to try to
    determine whether a system is stable or not
    without having to completely integrate the system
    response.

System will be stable after the fault if the
DecelArea is greater than the Accel. Area
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