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Introduction to Equipment & Stability Constraints in System Operation | Power Systems - Electrical Engineering (EE) PDF Download

Introduction 
 

Power System Operating Constraints 
Can you use the 50 Hz power supply at your home to drive a 100 kW load? Obviously, the answer is no!

The reason is that the power supply in your house is not designed to handle such power. If you tried to connect a motor of that rating, you would find that the fuse (or miniature circuit breaker) will trip and disconnect the power supply. If it did not do so, the wiring would be damaged.

In a similar fashion, a power system is designed to handle several load demand scenarios. This design is done much in advance (planning stages) based on the expected demand, while keeping some reserve "margins" for situations in which one or more equipment is out of service. A planner will not over-design (i.e., have unreasonably large margins) since it will cost a lot of money.

However during operation, it is not possible to requisition or install equipment at short notice. Therefore, an operator is forced to ensure that the system is operated within the existing design constraints.

Nature of constraints 

There are two types of constraints which limit the capability of a power system:
a) Equipment Constraints: An equipment must be operated within the specified ratings otherwise it may result in damage. Examples of such ratings are the maximum current handling capability of a conductor, the maximum voltage across an insulator before it breaks down etc. Equipment like generators may have a relatively large number of constraints. An equipment which is designed to have a larger capability is also costlier (e.g. a higher current ability will require one to use thicker conductors). Therefore, system and equipment designers do not over-design an equipment. Under abnormal or unforeseen situations, an equipment may get overloaded. If the overloading exceeds limits, the equipment is tripped out by protection systems.

b) Stability Constraints: A power system may not be able to cater to power flows beyond a certain point due to stability constraints. An unstable system is a one which cannot withstand disturbances, i.e., it may not settle to an equilibrium although a post-disturbance equilibrium condition may exist. This is due to the basic physical characteristics which define the behavior under transient conditions. Improvement of stability may require system reinforcement (like adding new transmission lines) and/or improving/augmenting existing automatic controllers. Inability to come to an equilibrium may eventually lead to equipment constraints being violated too. This will cause operation of protection systems.

Loss of equipment due to stability or equipment constraints may take the system into an emergency or inextremis state wherein interconnected operation may become unviable.

Therefore, it is important to characterize the capability of the system to handle load power demands and power flows in a transmission network without violation of the above constraints.

Equipment Constraints 
There are two major equipment constraints:
1) Thermal: Excessive heat produced by current carrying conductors results in unacceptable sags in transmission lines and degradation of insulation in other equipment. Depending on the thermal time constants (note that the temperature does not jump instantaneously), an equipment may have larger short time thermal ratings.

2) Dielectric: Over-voltages result in large electric fields causing dielectric breakdown. Dielectric breakdown may also occur due to aging or degradation of insulation due to thermal limit violations. Typically +/- 10% variation in the rated voltage is often permissible.

For mechanical equipment, parameters like steam pressure and temperature (which may restrict for instance, the rate of ramping the mechanical power in steam plants) have to be monitored to prevent overheating. Vibration of turbine blades also needs to be monitored especially during off-nominal frequency operation.
We shall now consider equipment constraints of 2 major power system components:
(1) Generators
(2) Transmission lines

The document Introduction to Equipment & Stability Constraints in System Operation | Power Systems - Electrical Engineering (EE) is a part of the Electrical Engineering (EE) Course Power Systems.
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FAQs on Introduction to Equipment & Stability Constraints in System Operation - Power Systems - Electrical Engineering (EE)

1. What are the main types of equipment used in electrical engineering system operation?
Ans. The main types of equipment used in electrical engineering system operation include generators, transformers, circuit breakers, relays, and control systems. These equipment are essential for generating, transmitting, distributing, and controlling electrical power.
2. What are stability constraints in electrical engineering system operation?
Ans. Stability constraints in electrical engineering system operation refer to the limitations or factors that can affect the stability of the power system. These constraints include voltage stability, frequency stability, and transient stability. Maintaining stability is crucial to ensure the reliable and efficient operation of the electrical system.
3. How do voltage stability constraints impact electrical system operation?
Ans. Voltage stability constraints can impact electrical system operation by causing voltage fluctuations, which can lead to equipment failures and power outages. If the voltage falls below a certain limit, it can result in voltage collapse, where the system becomes unstable and unable to supply the required power. Voltage stability constraints require the power system to maintain acceptable voltage levels to ensure proper operation.
4. What is the role of circuit breakers in electrical system operation?
Ans. Circuit breakers play a vital role in electrical system operation by protecting the system from overloads, short circuits, and other faults. They are designed to interrupt the flow of electricity when a fault occurs, thus preventing damage to equipment and ensuring the safety of the system. Circuit breakers help maintain the stability and reliability of the electrical system.
5. How do control systems contribute to the stability of electrical system operation?
Ans. Control systems contribute to the stability of electrical system operation by continuously monitoring and adjusting various parameters, such as voltage, frequency, and power flow. These systems use feedback mechanisms to detect any deviations from the desired operating conditions and initiate corrective actions. By maintaining stability through control actions, the electrical system can operate efficiently and reliably.
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