accelerating power

Understanding Accelerating Power in Synchronous Machines: The Case of Short Circuits

In the realm of electrical engineering, synchronous machines play a crucial role in power generation and distribution. These machines, operating at a constant speed synchronized with the power grid, are subject to various phenomena, one of which is the concept of "accelerating power". This article delves into the concept of accelerating power and its significance, particularly in the context of short circuits near the terminals of a synchronous machine.

What is Accelerating Power?

Accelerating power refers to the excess electric power generated by a synchronous machine that cannot be transmitted to the load due to a fault, such as a short circuit. This excess power manifests as a torque acting on the rotor, causing it to accelerate. The accelerating power, denoted by P_acc, is given by the difference between the mechanical power input to the machine (P_m) and the electrical power output (P_e):

P_acc = P_m - P_e

Short Circuits and Accelerating Power:

When a short circuit occurs near the terminals of a synchronous machine, the electrical power output (P_e) drops drastically, often reaching zero. This sudden reduction in electrical load leads to a significant imbalance, with the mechanical power input (P_m) exceeding the electrical power output. This difference in power is manifested as accelerating power.

Consequences of Accelerating Power:

The accelerating power causes the rotor of the synchronous machine to accelerate, leading to an increase in the rotor angle (θ). This increase in rotor angle is a critical parameter as it can lead to several undesirable consequences:

Loss of Synchronism: As the rotor angle increases, the synchronous machine may lose synchronism with the grid, resulting in instability and potential damage to the machine.
Increased Stresses: The accelerating torque can impose significant mechanical stresses on the machine's rotor and bearings, potentially causing damage or failure.
Voltage Instability: The sudden reduction in electrical output due to the short circuit can lead to voltage instability in the grid, impacting other equipment and potentially causing widespread blackouts.

Mitigating Accelerating Power:

To mitigate the effects of accelerating power, various techniques are employed in synchronous machine systems, including:

Protective Relays: These devices detect short circuits and quickly isolate the faulty portion of the system, limiting the amount of accelerating power experienced by the machine.
Automatic Voltage Regulators (AVRs): AVRs help maintain stable voltage levels during short circuits, reducing the impact on the grid and limiting the accelerating power.
Under-excitation Limiters: These devices limit the excitation current to the synchronous machine, reducing the accelerating power during a short circuit.

Conclusion:

Understanding the concept of accelerating power is crucial for ensuring safe and reliable operation of synchronous machines. The potential consequences of a short circuit, specifically the excess power that cannot be transmitted to the load, must be addressed through appropriate protective measures and control strategies. By implementing these safeguards, engineers can effectively mitigate the risks associated with accelerating power and ensure the continued stability and integrity of electrical power systems.

Test Your Knowledge

Quiz on Accelerating Power in Synchronous Machines

Instructions: Choose the best answer for each question.

1. What is the primary cause of accelerating power in a synchronous machine?

(a) A sudden increase in load demand (b) A fault condition like a short circuit (c) An increase in mechanical power input (d) A decrease in the speed of the rotor

Answer

(b) A fault condition like a short circuit

2. How is accelerating power calculated?

(a) P_acc = P_e - P_m (b) P_acc = P_m + P_e (c) P_acc = P_m - P_e (d) P_acc = P_e / P_m

Answer

3. What is a major consequence of accelerating power?

(a) Increased efficiency of the machine (b) Loss of synchronism with the grid (c) Reduced voltage fluctuations (d) Increased electrical power output

Answer

(b) Loss of synchronism with the grid

4. Which device is specifically designed to limit the excitation current during a short circuit?

(a) Protective relay (b) Automatic voltage regulator (AVR) (c) Under-excitation limiter (d) Speed governor

Answer

5. How do protective relays help mitigate accelerating power?

(a) By increasing the mechanical power input (b) By stabilizing the grid voltage (c) By isolating the faulty part of the system (d) By adjusting the excitation current

Answer

Exercise:

Scenario: A 100 MW synchronous generator is operating at its rated capacity when a short circuit occurs near its terminals. The mechanical power input to the generator remains constant at 100 MW. The electrical power output drops to 20 MW during the fault.

Task:

Calculate the accelerating power during the short circuit.
Explain what effect this accelerating power will have on the rotor of the generator.
Briefly describe two measures that could be implemented to mitigate the consequences of this accelerating power.

Exercice Correction

1. **Accelerating power calculation:** P_acc = P_m - P_e = 100 MW - 20 MW = 80 MW 2. **Effect on rotor:** The 80 MW accelerating power will create a significant torque on the rotor, causing it to accelerate. This increase in rotor speed will lead to a larger rotor angle, potentially causing the generator to lose synchronism with the grid. 3. **Mitigating measures:** * **Protective Relays:** These devices will detect the short circuit and quickly isolate the faulty portion of the system, effectively reducing the accelerating power. * **Under-excitation Limiters:** By limiting the excitation current, the accelerating power can be reduced, preventing excessive rotor acceleration and the risk of losing synchronism.

Books

Power System Stability and Control by P. Kundur: Provides a comprehensive understanding of power system dynamics, including the concept of accelerating power.
Electric Machinery Fundamentals by Stephen J. Chapman: Covers the fundamentals of synchronous machines and their operation, including the principles behind accelerating power.
Synchronous Machines by J.B. Gupta: A dedicated text on synchronous machines, focusing on their design, operation, and fault analysis, including the concept of accelerating power.

Articles

"Short-Circuit Characteristics of Synchronous Machines" by IEEE Transactions on Industry Applications: This article provides detailed analysis of short-circuit conditions in synchronous machines and the impact of accelerating power.
"Understanding Accelerating Power in Synchronous Machines: A Practical Approach" by Power Engineering Journal: A practical guide to understanding accelerating power and its impact on synchronous machine operation.
"Accelerating Power and its Mitigation in Synchronous Generators" by Journal of Power and Energy Systems: An in-depth exploration of the mechanisms behind accelerating power and the effectiveness of different mitigation strategies.

Online Resources

National Electrical Manufacturers Association (NEMA): Provides standards and guidelines for synchronous machines and their operation, including information on short-circuit performance.
Electrical Engineering Stack Exchange: A platform for asking and answering questions related to electrical engineering, with numerous discussions on accelerating power and synchronous machine fault analysis.
Wikipedia: "Synchronous Motor" A good starting point to learn the basics of synchronous machines, including their operating principles and characteristics.

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