1 / 36

Placing Controllers in a System

Placing Controllers in a System. Overview of Class So Far…. General Introduction Deregulation Traditional approaches to control Static devices. Type of problems. Steady State Transient Stability Inter-Area Oscillations Subsynchronous Resonance Voltage Stability. Introduction to FACTS.

buffy
Download Presentation

Placing Controllers in a System

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Placing Controllers in a System

  2. Overview of Class So Far… • General Introduction • Deregulation • Traditional approaches to control • Static devices

  3. Type of problems • Steady State • Transient Stability • Inter-Area Oscillations • Subsynchronous Resonance • Voltage Stability

  4. Introduction to FACTS • Detailed analysis of devices • Thyristor controlled inductor • SVC • Statcom • TCSC

  5. System Modeling • Simplified models for use in system simulations and analysis • Statcom • TCSC (see Reference [1]) • UPFC

  6. Set up system equations to include FACTS devices • Get block diagrams or differential equations for device • Define device states • Define device inputs • Express device model in terms of existing system states & device states • Augment system equations

  7. Use these devices to fix system problems!

  8. OK, Say you work at an ISO & are in charge of ensuring system reliability. You've had 5 major blackouts in the last 3 years that have involved the propagation of problems from one part of the system to another. The utility members are convinced that the addition of a FACTS device or two will solve the problems & they even agree to pay!

  9. Now what do you do? . . . • Brainstorming Activity: • What things do you need to worry about? • Break into groups of 2 or 3 • Take 3 minutes & write down as many things as you can • No criticism allowed, Go for variety, Go for quantity not quality

  10. Questions: • Where do I put it? Controller Location • What should it do? Controller Function

  11. Things to consider: • More than one problem • More than one system condition • More than one mode • More than one tool

  12. Problems • Steady State • Insure operating point is within acceptable limits • Interarea Oscillations • Damp eigenvalues

  13. Transient Stability • Provide sufficient synchronizing and damping torque • Subsynchronous Resonance • Avoid resonance frequencies • Voltage Stability • Stabilize eigenvalues and avoid bifurcations

  14. Interarea Oscillation Mitigation • Analysis Tools (Mostly Linear) • Controllability and Observability • Participations • Sensitivities • Power Oscillation Flows

  15. Linearized System x’ = Ax + Bu y = Cx + Du • Eigenvalues are li, i = 1, nstates • Right Eigenvectors ri , R is matrix of ri's • Left Eigenvectors (rows) li, L is matrix of li's • L = R-1

  16. Perform variable transformation to Jordan Form • x = Rz (Inverse transform z = Lx) • Substituting into system equations . . . Rz’ = AR z + B u y = CR z + Du

  17. Multiply through by L = R-1 LRz’ = z’ = LAR z + LB u y = CR z + Du

  18. Controllability and Observability • Modal controllability matrix = LB • tells how strongly connected the inputs (u's) are to each of the modes • Modal observability matrix = CR • tells how well we can measure or "see" each mode in the outputs (y's)

  19. Participations • Connection strengths between modes and states • General participation • pi hk = rih lhk • link between ith (obs.) & kth (con.) states through mode h • Participation Factors • pih = rih lhi • link between mode h & state i

  20. Eigenvalue Sensitivities li’ = dli/dp • p some parameter of the system • Tells how easily we can move an eigenvalue by changing a parameter • In general, li' = li A' ri

  21. Sensitivities are also related to participations • pihk = lh’ for p = aki (element of A) • pih = lh’ for p = akk (diagonal element) xi x(t) u(t) rest of system xk p

  22. Sensitivity with Controllers • The "Hybrid System"

  23. The Power System x’ = Ax + Bu y = Cx • assume no direct connection between y & y2 • The controller transfer functionF(s,p) is the only place p shows up

  24. Sensitivity for Hybrid System • li’ = dli/dp = li B {d/dp [F(s,p)]|s=li } C ri • related to the controllability and observability measures and to the controller transfer function (see Reference [5])

  25. Uses of Sensitivities • Location of controllers • Magnitude of l’ tells the displacement of the eigenvalue if gain is equal to 1 • Large magnitude indicates controller is a good candidate for improving a mode • Phase l’ of gives the direction of the eigenvalue's displacement in the imaginary plane

  26. Introduce devices likely to influence these characteristics • Simulations and Trial & Error

  27. Tuning of a controller . . . • Adjust the phase compensation of the controller so that l’ has a phase of 180 degrees with controller in place • Adjust the gain of the controller to achieve the desired amount of damping

  28. Power Oscillation Flows • Map where oscillations caused by a single eigenvalue appear in the system n x(t) = S ck elkt rk k = 1 • ck is the initial condition in Jordan Space

  29. The idea is to choose ck's so that only one mode is perturbed, i.e. ci = 1 and ck= 0 for all k not equal i then x(t) = ri elit • this solution can then be propagated through the system equations to find the power flow on key lines (or some other variable for that matter)

  30. Placing a FACTS device using participations, sensitivities, etc. • Simple & Fast • Detailed & More Accurate

  31. Transient Stability and FACTS • Usually concerned with providing adequate damping and synchronizing torque • Often design using linear techniques and test with the nonlinear system

  32. Nonlinear Methods • Normal forms of vector fields for extending the linear concepts to the nonlinear regions. • Second-order oscillations, participations, controllability & observability

  33. Energy Methods • Lyapunov-based methods for determining stability indices • Tracking of energy exchanges during a disturbance

  34. Control Strategy • Determine weak points in system • Poorly damped oscillations • Lack of synchronizing torque • Large power swings • Large energy exchanges • Short critical clearing times • Multi-machine instabilities

  35. [1] Paserba, J. J., N. W. Miller, E. V. Larsen, and R. J. Piwko "A Thyristor Controlled Series Compensation Model for Power System Stability Analysis" IEEE Trans. on Power Delivery, Vol. 10?, (July 1994): 1471-1478. [2] Chan, S. M. "Modal Controllability and Observability of Power-System Models" International Journal of Electric Power and Energy Systems, Vol. 6, No. 2, (April 1994): 83-89. [3] Rouco, L., and F. L. Pagola "An Eigenvalue Sensitivity Approach to Location and Controller Design of Controllable Series Capacitors for Damping Power System Oscillations" IEEE-PES 1997 Winter Power Meeting, Paper No. PE-547-PWRS-0-01-1997. References

  36. [4] Ooi, B. T., M. Kazerani, R. Marceau, Z. Wolanski, F. D. Galiana, D. McGillis, and G. Joos "Mid-Point SIting of FACTS Devices in Transimssion Lines" IEEE-PES 1997 Winter Power Meeting, Paper No. PE-292-PWRD-0-01-1997. [5] Pagola, F. L., I. J. Perez-Arriaga, and G.C. Verghese "On Sensitivities, Residues, and Participations: Application to Oscillatory Stability Analysis and Control" IEEE Trans. on Power Systems, Vol. 4, No. 2, (February 1989): 278-285. [6] Messina, A. R., J. M. Ramirez, and J. M. Canedo C. "An Investigation on the use of Power Systme Stabilizers for Damping Inter-Area Oscillations in Longitudinal Power Systems" IEEE-PES 1997 Winter Power Meeting, Paper No. PE-492-PWRS-0-01-1997. [7] Zhou, E. Z. "Power Oscillation Flow Study of Electric Power Systems" International Journal of Electric Power and Energy Systems, Vol. 17, No. 2, (1995): 143-150.

More Related