Power System Operation, Monitoring & Control (Hands-On Training)
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COURSE DATES AND LOCATIONS
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Duration
LOCATION
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INTRODUCTION
The power system is a huge system as a result of interconnections between each service area to improve reliability and economic efficiency. The social system has been mainly developed based on electrical energy for a better life and economic growth. On the other hand, the power system is exposed to the natural environment at all times; thus, the system has some small or large disturbances, for example, by lightning, storm, and apparatus faults. Under these conditions, the system should maintain stable operation to avoid blackouts in the whole system using appropriate protection and control schemes. However, in a large-scale interconnected system, there are some difficulties in evaluating and maintaining the stability of the whole system.
Recently, a new issue in power systems has come out, which is the penetration of renewable energy sources, bringing more uncertainty that requires more severe opera- tion. For energy security, the introduction of renewable energy sources is indispensable; therefore, to maintain system reliability and make efficient use of sustainable energy, power system monitoring should be a key technology to achieve flexible operation in the system.
On the other hand, in recent years, the development of information and communi- cation technology (ICT) has enabled more flexibility in wide-area monitoring of power systems with fast and large data transmission. Especially, the wide-area measurement
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COURSE OBJECTIVES
By the end of the course, you‘ll be able to:
- Develop equivalent circuits for a given power system for power flow analysis,
- Develop computer programs to perform power flow analysis on a power system,
- Define automatic generation control scheme on a power system and analyze generation control on a power system using simulation tools,
- Define generation dispatching on a power system and develop generation dispatching schemes using analysis packages,
- Define real time monitoring requirements on a power system,
- Define State Estimation problem and analyze state estimation of a power system using analysis programs,
- Define contingency analysis on a power system and perform contingency studies using a power flow analysis program.
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COURSE AUDIENCE
This course is made for
- Field Technicians
- Electricians
- Operations Managers
- Maintenance Supervisors
- Plant Engineers
- Plant Operators
- Electrical Engineers
- Project Engineers
- Electrical Technicians
Instrumentation Engineers
Design Engineers
Workplace Safety Professionals
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COURSE OUTLINE
Day One
- Operation and Control of Power Systems (1 wk)
- Modeling of system components (2 wks)
- Steady-State Power Flow Analysis (3 wks)
– Formulation
– Solution Methods
– LTC control, generator limits - Real-Time Generation Control (4 wks)
– Automatic Generation Control
– Economic Dispatch - Real-Time Monitoring – State Estimation (3 wks)
– Formulation
– Solution Algorithms - System Security – Contingency Analysis (1 wk)
– Formulation
– Solution Methods - Voltage Control
Day Two
AN INTRODUCTION ON POWER SYSTEM MONITORING
- Synchronized Phasor Measurement
- Power System Monitoring and Control with Wide-Area
Measurements - ICT Architecture Used in Wide-Area Power System Monitoring
and Control
OSCILLATION DYNAMICS ANALYSIS BASED ON PHASOR MEASUREMENTS
- Oscillation Characteristics in Power Systems
- Eigenvalue Analysis and Participation Factor
- Oscillation Characteristics in an Interconnected
- Power System
- An Overview of Oscillation Monitoring Using Phasor Measurements
- Monitoring of the Japan Power Network
- Monitoring of the Southeast Asia Power Network
- WAMS-Based Interarea Mode Identification
- Low-Frequency Oscillation Dynamics
- Electromechanical Modes Characteristics
- Oscillation Characteristics Analyses in Southeast Asia
Power Network
Day Three
SMALL-SIGNAL STABILITY ASSESSMENT
- Power System Small-Signal Stability
- Oscillation Model Identification Using Phasor Measurements
- Oscillation Model of the Electromechanical Mode
- Dominant Mode Identification with Signal Filtering
- Small-Signal Stability Assessment of Wide-Area Power Systems
- Simulation Study
- Stability Assessment Based on Phasor Measurements
- Stability Assessment Based on Frequency Monitoring
GRAPHICAL TOOLS FOR STABILITY AND SECURITY ASSESSMENT
- Importance of Graphical Tools in WAMS
- Angle–Voltage Deviation Graph
- Simulation Results
- Disturbance in Generation Side
- Disturbance in Demand Side
- Voltage–Frequency Deviation Graph
- Graph for Contingency Assessment
- Graph for Load Shedding Synthesis
- Frequency–Angle Deviation Graph
- Electromechanical Wave Propagation Graph
- Wave Propagation
- Angle Wave and System Configuration
POWER SYSTEM CONTROL: FUNDAMENTALS AND NEW
- PERSPECTIVES
- Power System Stability and Control
- Angle and Voltage Control
- Frequency Control
- Frequency Control Dynamic
- Operating States and Power Reserves
- Supervisory Control and Data Acquisition
- Challenges, Opportunities, and New Perspectives
- Application of Advanced Control Methods and Technologies
Day Four
WIDE-AREA MEASUREMENT-BASED POWER SYSTEM CONTROL DESIGN
- Measurement-Based Controller Design
- Controller Tuning Using a Vibration Model
- Vibration Model Including the Effect of Damping Controllers
- Tuning Mechanism
- Simulation Results
- Wide-Area Measurement-Based Controller Design
- Wide-Area Power System Identification
- Design Procedure
- Simulation Results
COORDINATED DYNAMIC STABILITY AND VOLTAGE REGULATION
- Need for AVR–PSS Coordination
- A Survey on Recent Achievements
- A Robust Simultaneous AVR–PSS Synthesis Approach
- Control Framework
- Developed Algorithm
- Real-Time Implementation
- Experiment Results
- A Wide-Area Measurement-Based Coordination Approach
- High Penetration of Wind Power
- Developed Algorithm
- An Application Example
- Simulation Results
- Intelligent AVR and PSS Coordination Design
- Fuzzy Logic-Based Coordination System
- Simulation Results
Day Five
WIDE-AREA MEASUREMENT-BASED EMERGENCY CONTROL
- Conventional Load Shedding and New Challenges
- Load Shedding: Concept and Review
- Some Key Issues
- Need for Monitoring Both Voltage and Frequency
- Simultaneous Voltage and Frequency-Based
- Proposed LS Scheme
- Implementation
- Case Studies and Simulation Results
- An Approach for Optimal UFVLS
- Discussion
- Wave Propagation-Based Emergency Control
- Proposed Control Scheme
- Simulation Results
MICROGRID CONTROL: CONCEPTS AND CLASSIFICATION
- Microgrids
- Microgrid Control
- Local Controls
- Secondary Controls
- Global Controls
- Central/Emergency Controls
MICROGRID CONTROL: SYNTHESIS EXAMPLES
- Local Control Synthesis
- Robust Voltage Control Design
- Intelligent Droop-Based Voltage and
- Frequency Control
- Secondary Control Synthesis
- Intelligent Frequency Control
- ANN-Based Self-Tuning Frequency Control
- Global Control Synthesis
- Adaptive Energy Consumption Scheduling
- Power Dispatching in Interconnected MGs
- Emergency Control Synthesis
