Study Of Impact Of Frequency Deviation On Power System
The study of the impact of frequency deviation on power systems involves analyzing how fluctuations in the frequency of an alternating current (AC) power grid can affect its stability, reliability, and performance. Frequency deviation, which refers to variations in the nominal frequency of the power system, can arise from various factors such as changes in load demand, generator output, or network disturbances. These deviations can lead to imbalances between generation and demand, potentially causing voltage and frequency instability, as well as affecting the operation of interconnected grids. Understanding the consequences of frequency deviation is crucial for ensuring the efficient operation and resilience of power systems, as it enables the implementation of control strategies and technologies to mitigate adverse effects and maintain grid stability.
The operation and the development of power system networks introduce new types of stability problems. The effect of the power generation and consumption on the frequency of the power system can be described as a demand/generation imbalance resulting from a sudden increase/decrease in the demand and/or generation. This paper investigates the impact of a loss of generation on the transient behaviour of the power grid frequency. A simplified power system model is proposed to examine the impact of change of the main generation system parameters (system inertia, governor droop setting, load damping constant, and the high-pressure steam turbine power fraction), on the primary frequency response in responding to the disturbance of a 1.32 GW generation loss on the power grid. Various rates of primary frequency responses are simulated via adjusting system parameters of the synchronous generators to enable the controlled generators providing a fast-reliable primary frequency response within 10 s after a loss of generation. It is concluded that a generation system inertia and a governor droop setting are the most dominant parameters that effect the system frequency response after a loss of generation. recent power systems have become a widely interconnected and complicated network, containing thousands of buses and generating stations. In order to provide the required power, it is required to extend the power network by adding new power generating and transmission lines. Due to economic and environmental constraints of new installations for generators and load demand growth, the transmission lines flow on existing transmission lines have increased, leading to risks of losing frequency stability and system blackout. This paper presents an overview on the impact of frequency deviation on power system.
COVER PAGE
TITLE PAGE
APPROVAL PAGE
DEDICATION
ACKNOWELDGEMENT
ABSTRACT
CHAPTER ONE
INTRODUCTION
1.1 BACKGROUND OF THE STUDY
1.2 PROBLEM STATEMENT
1.3 OBJECTIVE OF THE STUDY
1.4 SIGNIFICANCE OF THE STUDY
1.5 SCOPE OF THE STUDY
CHAPTER TWO
2.0 LITERATURE REVIEW
2.1 OVERVIEW OF POWER SYSTEM STRUCTURE
2.2 POWER SYSTEM COMPONENTS
2.3 BASIC CONCEPTS AND DEFINITIONS OF POWER SYSTEM STABILITY
2.4 FREQUENCY CONTROL IN POWER SYSTEM
2.5 REVIEW OF RELATED STUDIES
CHAPTER THREE
METHODOLOGY
3.1 POWER SYSTEM MODEL AND GOVERNING PARAMETERS
CHAPTER FOUR
4.1 RESULTS AND DISCUSSION
4.2 FREQUENCY VARIATIONS AND THEIR EFFECTS ON EQUIPMENT
CHAPTER FIVE
5.1 CONCLUSION
5.2 REFERENCES
INTRODUCTION
1.1 BACKGROUND OF THE STUDY
The operation and the development of power system networks introduce new types of stability problems [Abdulraheem et al, 2016]. The effect of the power generation and consumption on the frequency of the power system can be described as a demand/generation imbalance resulting from a loss of generation or load manifests itself as a variation in the system frequency [Qazi et al, 2016]. A high demand on consumption will cause system frequency to decrease, while low demand on consumption will increase the system frequency, and vice versa with the generation [Kirby et al, 2013]. There are many possible parameters involved when analysing the problems associated with the controlled operation of the power systems [Kirby et al, 2013].
A power system is a highly nonlinear system and its dynamic response is influenced by a wide range of devices with different characteristics and response rates [Kirby et al, 2013]. Characteristics such as rapid load changes and generation outputs, loss of synchronisation among generators, short-circuiting on the transmission, and other operating parameters that are affected by the changes of the environment and operational disturbances.
Although the power systems are designed to withstand wide-ranging disturbances, stability of the power system becomes remarkably unstable with the greater. The potential of research in investigating how power generation–consumption and frequency stability affect the overall performance of the power grid system, including the parameters that define and determine the frequency output after a disturbance, has remarkably increased [Saleh et al, 2013].
At the generation side, the rotational speed of synchronous machines is directly proportional to the systems frequency [Kundur et al, 2014]. Frequency stability refers to the ability of the power system to maintain steady frequency following a severe system disturbance resulting in a significant imbalance between generation and load [Kundur et al, 2014]. Deviations in frequency will result in the use of control applications to regulate the frequency of the power grid to the safe and satisfactory levels [Sarma et al, 2014]. The UK Grid regulates frequency to be maintained at 1% of the nominal system frequency (50 Hz), except at exceptional circumstances [Kundur et al, 2014].
Demand Side Response (DSR) is a real-time intervention using energy controlled applications when the power systems is disturbed or stressed [Kundur et al, 2014]. Load-shedding is a coordinated controlled response which results in reduction in electrical load, this relieves stress on the main power system [Kundur et al, 2014].
The frequency measurements are compared to European electrical standards EN 50160 [Meegahapola, 2010] and EN 50160/A1 [Qazi, 2016] in order to establish if the frequency deviations in the grid during islanded operation surpasses the range set for systems without synchronous connection to an interconnected system. The frequency variations are also compared to International Electrotechnical Commission (IEC) Standard 60034-1 [Teng et al, 2015], computer power supply ATX12V design specifications [Wood, et al, 2013], Intel power supply design specifications [Kerahroudi et al, 2015] and IEC Standard 60076-1 [Kundur et al, 2014] to predict possible effects on connected equipment.
1.2 PROBLEM STATEMENT
Power systems are complex systems consisting of large number of generating units and interconnected network of transmission lines. The frequency deviation is an issue of prime importance in this complex power system network since the demand for electric power is increasing drastically. The tendency of a power system to develop restoring forces equal to or greater than the disturbing forces to maintain the state of equilibrium is known as stability. Frequency deviation is one of the power stability problems commonly noticed in power system. A high demand on consumption will cause system frequency to decrease, while low demand on consumption will increase the system frequency, and vice versa with the generation. This study was carried out to study the impact of frequency deviation on power system.
1.3 OBJECTIVE OF THE STUDY
The objective of this work is to carry out a study on the impact of frequency deviation of power system.
1.4 SIGNIFICANCE OF THE STUDY
This study will be of great benefit to the reader in that it will help the reader to understand the effect of frequency deviation in power system also the make known to the reader the causes of frequency deviation in power system.
1.5 SCOPE OF THE STUDY
The scope of this work is on the investigation of the effect of frequency deviation on power system. This paper investigates the impact of frequency deviation on power system. A simplified power system model is proposed to examine the impact of change of the main generation system parameters (system inertia, governor droop setting, load damping constant, and the high-pressure steam turbine power fraction), on the primary frequency response in responding to the disturbance on the power grid.
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Frequency deviation in a power system refers to the variation in the system frequency from its nominal value. In most power systems, the nominal frequency is 50 Hz or 60 Hz, depending on the region. Frequency is a critical parameter in power systems, and deviations from the nominal frequency can have various impacts:
- Equipment Synchronization Issues:
- Most electrical equipment in a power system is designed to operate at a specific frequency. Deviations from the nominal frequency can lead to synchronization issues, affecting the performance and efficiency of generators, motors, and other rotating machinery.
- Clock Accuracy:
- Many modern electronic devices rely on the power system frequency for timekeeping. Deviations in frequency can result in inaccurate timekeeping in devices such as clocks, timers, and communication systems.
- Generator Performance:
- Generators are designed to operate optimally at a specific frequency. Frequency deviations can affect the output and efficiency of generators. Generators may trip offline if the frequency deviates significantly from the nominal value to prevent damage.
- Load Shedding and Load Shedding Devices:
- Power systems are designed to maintain a balance between generation and consumption. Frequency deviations can indicate an imbalance. In response, automatic load shedding devices may be triggered to disconnect non-critical loads to restore the balance and prevent a complete system collapse.
- Voltage Stability:
- Frequency and voltage stability are closely related. Frequency deviations can impact the voltage stability of the system. If not corrected promptly, significant frequency deviations can lead to voltage collapse and widespread blackouts.
- Resonance Issues:
- Frequency deviations can lead to resonance in the power system. Resonance can cause excessive voltages and currents, potentially damaging equipment and infrastructure.
- Grid Synchronization:
- Interconnected power systems must be synchronized to ensure seamless and reliable operation. Frequency deviations can disrupt the synchronization of different parts of the grid, leading to instability and potential cascading failures.
- Frequency-Dependent Protection Devices:
- Some protection devices in the power system, such as relays, are designed to operate based on frequency variations. Deviations outside certain limits may cause these devices to trip, affecting the protection and reliability of the system.
- Economic Impacts:
- Frequency deviations can result in decreased efficiency of power generation, increased fuel consumption, and potential damage to equipment. These factors can contribute to economic losses for both power generators and consumers.
- Grid Operation and Control:
- System operators continuously monitor and control the power system to maintain frequency within acceptable limits. Significant frequency deviations can challenge the ability of operators to control the system effectively, leading to emergency measures and potential disruptions.
In summary, maintaining system frequency within specified limits is crucial for the reliable and stable operation of a power system. Frequency deviations can have cascading effects on equipment, synchronization, and overall system stability. Power system operators use various control mechanisms to manage and correct frequency deviations promptly to avoid widespread disruptions.