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Stability Problems in Power Systems

What is Stability? 
Stability is essentially the ability of a system to recover from disturbances, both large and small, and settle to an acceptable equilibrium. Randomly occurring load changes, faults resulting in line or generator tripping and changes in reference values of regulating controllers, are examples of disturbances.

One should note that equipment constraints are distinct from stability constraints in the sense that even though an equilibrium condition may exist (which is within equipment constraints), a system may not be able to "settle down" to it if it is perturbed or initially away from it.

If a system is not stable for even small disturbances, it cannot be operated at all since there are always small and random perturbations in the system due to load variations

If a system is stable for small disturbances but unstable if the disturbances are "large", then the system can be operated. However, the system may not be secure, i.e., it may be unstable if a large enough disturbance does actually occur .

The major stability problems which are inherent in AC interconnected grids are discussed next.
   Angle Stability

An interesting physical characteristic of interconnected synchronous generators is their ability to generate restoring torques when disturbed from an equilibrium. These torques ensure that all machines stay in synchronism --- generator electrical speeds become equal in steady state. Equivalently, the phase angular differences between ac voltages at various points become constant if machines stay in equilibrium.

However, the restoring torques can become zero or negative for very large disturbances. This can result in machines falling out of step (i.e., they lose synchronism - the machines do not settle to the same electrical speed; this makes operation unviable - see Module 1). Sometimes, due to presence of automatic controllers, damping of the rotor oscillations is inadequate or negative, causing growing or sustained oscillations ('hunting') and may also lead to loss of synchronism.

The problem of loss of synchronism between synchronous machines is also known as the "angular stability problem". Note that if machines lose synchronism, then the phase angular difference between ac buses in the system will not settle to constant values.
 

To study the angular stability problem, consider the governing equations of the system.

Stability Problems in Power Systems | Power Systems - Electrical Engineering (EE)

SMIB System 
A Single - Machine Infinite Bus system (SMIB), is an oversimplified model of a power system but it helps us to understand the essence of the large disturbance angular stability problem. The SMIB system represents a small generator connected to a large power system. The large power system is represented by an infinite bus (fixed voltage source with a constant frequency). The generator itself is represented as a constant magnitude voltage source behind its transient reactance. The infinite bus voltage is assumed to have a frequency wo. The phase angle of the internal voltage E with respect to the infinite bus is given by d. Note that this angle will change if the relative frequency between the generator and infinite bus changes.

Thus, if d does not reach a steady state value after a disturbance, then it implies that the generator has lost synchronism, or equivalently, is angular unstable.
Stability Problems in Power Systems | Power Systems - Electrical Engineering (EE)

Stability Problems in Power Systems | Power Systems - Electrical Engineering (EE)

xe is the transmission line reactance in W

Stability Problems in Power Systems | Power Systems - Electrical Engineering (EE)
Stability Problems in Power Systems | Power Systems - Electrical Engineering (EE)


→ The equations of a single machine infinite bus system reveal that torque is a nonlinear function of rotor angle

 

The document Stability Problems in Power Systems | Power Systems - Electrical Engineering (EE) is a part of the Electrical Engineering (EE) Course Power Systems.
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FAQs on Stability Problems in Power Systems - Power Systems - Electrical Engineering (EE)

1. What are stability problems in power systems?
Ans. Stability problems in power systems refer to the ability of the power system to maintain a steady and balanced operation under normal and abnormal conditions. These problems include voltage instability, frequency instability, and transient stability issues.
2. What causes voltage instability in power systems?
Ans. Voltage instability in power systems can be caused by various factors such as inadequate reactive power supply, large and sudden changes in load demand, and insufficient voltage control devices. These factors can lead to voltage fluctuations, voltage collapse, and even blackouts.
3. How does frequency instability occur in power systems?
Ans. Frequency instability in power systems occurs when the generation and demand of electrical power are imbalanced. This can happen due to sudden changes in load demand, loss of generation capacity, or faults in the power system. Frequency instability can result in fluctuations in the frequency of the electrical power, leading to disruptions in the operation of connected devices.
4. What is transient stability in power systems?
Ans. Transient stability in power systems refers to the ability of the system to maintain stability during and after a disturbance, such as a fault or a sudden change in load demand. It is concerned with the system's ability to recover and maintain stable operation within a short period of time (a few seconds to a few minutes) after the disturbance occurs.
5. How can stability problems in power systems be mitigated?
Ans. Stability problems in power systems can be mitigated through various measures such as improving reactive power supply, implementing effective voltage control schemes, enhancing frequency control mechanisms, and ensuring proper coordination between generation, transmission, and distribution systems. Additionally, the use of advanced control and monitoring technologies, such as wide-area measurement systems, can help in detecting and mitigating stability issues in real-time.
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