An presentation on power system stability
1 like637 views
The document is a presentation on power system stability for the course EEE-3301 at Northwestern University, covering definitions, classifications, and the importance of stability in power systems. It details various types of stability such as rotor angle stability, voltage stability, and frequency stability, along with their characteristics and implications. The conclusion emphasizes the need for improvement in power system stability through various methods and technologies.
An presentation on power system stability
- 1. PRESENTATION ON POWER SYSTEM STABILITY Course Code: EEE-3301 Course Tittle: Power System North Western University, Khulna Submitted By: Name: DEBBROTA KUMAR GHUHA ID:20172030021 3 rd Year, 3rd Semester (Spring- 2020) Submitted To: Name:Mohyminul Islam Lecturer of Electrical & Electronics Engineering Department North Western University, Khulna
- 3. Contents Power System Stability Overview Power System Stability: A Proposed Definition Need of Stability Classification Classification of stability Power System Stability Classification Rotor Angle Stability Voltage Stability Frequency Stability Rotor Angle Stability vs. Voltage Stability Advantage and Disadvantage Conclusion References
- 4. Power System Stability Overview Power system is defined as a network of one or more generating units, loads and power transmission lines including the associated equipments connected to it. The stability of a power system is its ability to develop restoring forces equal to or greater than the disturbing forces to maintain the state of equilibrium. Power system stability problem gets more pronounced in case of interconnection of large power networks.
- 5. Power System Stability A Proposed Definition The ability of a power system to reach a normal or stable condition after being disturbed is called the power system stability. Power system stability is the ability of an electric power system, for a given initial operating condition, to regain a state of operating equilibrium after being subjected to a physical disturbance, with most system variables bounded so that practically the entire system remains intact.
- 6. Need of Stability Classification Stability analysis is easier. Also it leads to proper and effective understanding of different power system instabilities. Key factors that leads to instability can be easily identified. Methods can be devised for improving power system stability.
- 7. Classification of stability Classification is based on the following considerations: physical nature of the resulting instability size of the disturbance considered processes, and the time span involved
- 8. Steady State Stsbility It is the ability of the power system to regain the synchronism after small or slow disterbances. Ability to regain normal and stable operation after being subjected to gradual or slow change in the load. Concerned with upper loading of machine before losing synchronism. Load is assume to be applied at a rate which is slow. System is Analysis by the set of linear equation. Action of Voltage regulators and turbine governers are not included.
- 9. Transient Stability It is the stability of the power system to regain synchronism after large disturbance. Ability to regain normal and stable operation after being subjected to sudden & large changes in the load. Losses-generator excitation, transmission, switching operations and faults. Linearization of system equation is not permitted. Studied on the basis of swing. Action of Voltage regulators and turbine governer are not included.
- 10. Dynamic Stability The dynamic stability is concerned with small disturbances lasting for a long time with the inclusion of automatic control devices. Same as steady state stability. Included action of turbine governers and voltage regulators. Study time is 4-10 sec.
- 11. SWING EQUATION
- 12. Power System Stability Classification Rotor angle stability. Small disturbance angle stability. Transient stability. Voltage stability. Small disturbance voltage stability. Large disturbance voltage stability. Frequency stability. Short term frequency stability. Long term frequency stability.
- 13. Stability Classification at a Glance
- 14. Rotor Angle Stability Rotor angle stability refers to the ability of synchronous machines of an interconnected power system to remain in synchronism after being subjected to a disturbance. Rotor angle instability occurs due to angular swings of some generators leading to their loss of synchronism with other generators. Depends on the ability to maintain/restore equilibrium between electromagnetic torque and mechanical torque of each synchronous machine. At equilibrium, Input mechanical torque equals output electromagnetic torque of each generator. In case of any disturbance the above equality doesn’t hold leading to acceleration/ deceleration of rotors of machines.
- 15. Rotor Angle Stability Classification Small Disturbance Rotor Angle Stability: It is the ability of the power system to maintain synchronism under small disturbances. Disturbances are considered to be sufficiently small such that the linearization of system equations is permissible for purposes of analysis. The time frame of interest in small-disturbance stability studies is of the order of 10 to 20 seconds following a disturbance.
- 16. Large Disturbance Rotor Angle Stability: It is the ability of the power system to maintain synchronism under a severe disturbance, such as a short circuit on a transmission line. Disturbances are large so that the linearization of system equations is not permissible for purposes of analysis. The time frame of interest in small-disturbance stability studies is of the order of 3 to 5 seconds following a disturbance.
- 17. Voltage Stability Voltage stability refers to the ability of a power system to maintain steady voltages at all buses in the system after being subjected to a disturbance from a given initial operating condition. A system is voltage instable if for atleast one bus in the system, the voltage magnitude decreases as reactive power injection is increased. Voltage instability results in progressive fall or rise of voltages of some buses.
- 18. Large scale effect of voltage instability leads to Voltage collapse. It is a process by which the sequence of events accompanying voltage instability leads to a blackout or abnormally low voltages in a significant part of the power system. The driving force for voltage instability is usually the loads. Voltage stability problems is also experienced at terminals of HVDC links connected to weak ac systems.
- 19. Voltage Stability Classification Small Disturbance Voltage Stability: Small-disturbance voltage stability refers to the system’s ability to maintain steady voltages when subjected to small disturbances such as incremental changes in system load. A combination of both linear and non-linear techniques are used for analysis.
- 20. Large Disturbance Voltage Stability: Large-disturbance voltage stability refers to the system’s ability to maintain steady voltages following large disturbances such as system faults, loss of generation, or circuit contingencies. The study period of interest may extend from a few seconds to tens of minutes.
- 21. Frequency Stability Frequency stability refers to the ability of a power system to maintain steady frequency following a severe system upset resulting in a significant imbalance between generation and load. Frequency instability leads to tripping of generating units and/or loads. Frequency stability may be a short-term phenomenon or a long-term phenomenon.
- 23. Rotor Angle Stability vs.Voltage Stability Rotor angle stability is basically a generator stability while voltage stability means load stability. Rotor angle stability is mainly interlinked to real power transfer whereas voltage stability is mainly related to reactive power transfer.
- 24. Advatages and Disadvantages Advantages: Much lower cost compared to SVC . Switching speeds can be quite fast when compared to other compensation devices . Disadvantages: With the increase in voltages the capacitor value (in turn the size) increase which is difficult to design them . precise and rapid control of voltages are not possible .
- 25. Conclusion Power system is always required normal and stable operation at rated operating condition & it’s also required improvement of stability . Stability of power system is improved by using shunt & series capacitors, governing system and Facts controllers. Reduce transmission losses. Power is generated by renewable energy sources and ceate a power park.
- 27. THANK YOU