This 4-day workshop on power system stability and control will be held from June 8-11, 2015 at the Grand Hyatt in Bali, Indonesia. It will be facilitated by Dr. Prabha Kundur, a world-renowned expert in this area. Attendees will gain a comprehensive understanding of issues relating to power system stability, including an overview of equipment, modeling techniques, and control of active power, frequency, reactive power and voltage. The workshop will also cover topics such as transient stability, small-signal stability, voltage stability and frequency stability.
Speed control in 3 phase induction motorKakul Gupta
Speed control in induction motors is required for efficient operation
Various methods of speed control through semiconductor devices:
1. Stator voltage control
2. Stator frequency control
3. Stator voltage control
4. Stator current control
5. Static Rotor Resistance Control
6. Slip Energy Recovery Control
As the fifth in a series of tutorials on the power system, Leonardo ENERGY introduces its minute lecture on voltage and frequency control, using the analogy of a metal/rubber plate to demonstrate the centralised nature of frequency control, whereas voltage control is more a local matter.
This report gives an overview of patenting activity around Doubly-fed Induction Generators (DFIG) used in the horizontal axis wind turbines for efficient power generation. Patents were categorized as per key DFIG technologies and analyzed for generating different trends within PatSeer Project.
High Voltage Direct Current technology has certain characteristics which
make it especially attractive for transmission system applications. HVDC
transmission system is useful for long-distance transmission, bulk power delivery and
long submarine cable crossings and asynchronous interconnections. The study of
faults is essential for reasonable protection design because the faults will induce a
significant influence on operation of HVDC transmission system. This paper provides
the most dominant and frequent faults on the HVDC systems such as DC Line-to-
Ground fault and Line-to-Line fault on DC link and some common types of AC faults
occurs in overhead transmission system such as Line-to-Ground fault, Line-to-Line
fault and L-L-L fault. In HVDC system, faults on rectifier side or inverter side have
major affects on system stability. The various types of faults are considered in the
HVDC system which causes due to malfunctions of valves and controllers, misfire
and short circuit across the inverter station, flashover and three phase short circuit.
The various faults occurs at the converter station of a HVDC system and
Controlling action for those faults. Most of the studies have been conducted on line
faults. But faults on rectifier or inverter side of a HVDC system have great impact on
system stability. Faults considered are fire-through, misfire, and short circuit across
the inverter station, flashover, and a three-phase short circuit in the ac system. These
investigations are studied using matlab simulink models and the result represented in
the form of typical time responses.
Speed control in 3 phase induction motorKakul Gupta
Speed control in induction motors is required for efficient operation
Various methods of speed control through semiconductor devices:
1. Stator voltage control
2. Stator frequency control
3. Stator voltage control
4. Stator current control
5. Static Rotor Resistance Control
6. Slip Energy Recovery Control
As the fifth in a series of tutorials on the power system, Leonardo ENERGY introduces its minute lecture on voltage and frequency control, using the analogy of a metal/rubber plate to demonstrate the centralised nature of frequency control, whereas voltage control is more a local matter.
This report gives an overview of patenting activity around Doubly-fed Induction Generators (DFIG) used in the horizontal axis wind turbines for efficient power generation. Patents were categorized as per key DFIG technologies and analyzed for generating different trends within PatSeer Project.
High Voltage Direct Current technology has certain characteristics which
make it especially attractive for transmission system applications. HVDC
transmission system is useful for long-distance transmission, bulk power delivery and
long submarine cable crossings and asynchronous interconnections. The study of
faults is essential for reasonable protection design because the faults will induce a
significant influence on operation of HVDC transmission system. This paper provides
the most dominant and frequent faults on the HVDC systems such as DC Line-to-
Ground fault and Line-to-Line fault on DC link and some common types of AC faults
occurs in overhead transmission system such as Line-to-Ground fault, Line-to-Line
fault and L-L-L fault. In HVDC system, faults on rectifier side or inverter side have
major affects on system stability. The various types of faults are considered in the
HVDC system which causes due to malfunctions of valves and controllers, misfire
and short circuit across the inverter station, flashover and three phase short circuit.
The various faults occurs at the converter station of a HVDC system and
Controlling action for those faults. Most of the studies have been conducted on line
faults. But faults on rectifier or inverter side of a HVDC system have great impact on
system stability. Faults considered are fire-through, misfire, and short circuit across
the inverter station, flashover, and a three-phase short circuit in the ac system. These
investigations are studied using matlab simulink models and the result represented in
the form of typical time responses.
Wide area monitoring systems (WAMS) are essentially based on the new data acquisition technology of phasor measurement and allow monitoring transmission system conditions over large areas in view of detecting and further counteracting grid instabilities.
What is islanding ?
Consider the power network as shown in fig.1
Now if we disconnect the line AB from the infinite transmission grid there will be an isolated region . The D1, D2 are power sources (eg : inverter , solar power cells ). The power generated in this region is fed to the island only.
We see that there no longer is any control over the island voltage at the bus X . Also there is no mechanism here for control of frequency.
This state is referred to as islanding.
Objectives: This course will provide a comprehensive overview of power system stability and control problems. This includes the basic concepts, physical aspects of the phenomena, methods of analysis, the integration of MATLAB and SINULINK in the analysis of power system .
Course Content: 1. Power System Stability: Introduction
2. Stability Analysis: Swing Equation
3. Models for Stability Studies
4. Steady State Stability
5. Transient Stability
6. Multimachine Transient Stability
7. Power System Control: Introduction
8. Load Frequency Control
9. Automatic generation Control
10. Reactive Power Control
Functions and Performance Requirements
Elements of an Excitation System
Types of Excitation Systems
Control and Protection Functions
Modeling of Excitation Systems
The functions of an excitation system are
to provide direct current to the synchronous generator field winding, and
to perform control and protective functions essential to the satisfactory operation of the power system
The performance requirements of the excitation system are determined by
Generator considerations:
supply and adjust field current as the generator output varies within its continuous capability
respond to transient disturbances with field forcing consistent with the generator short term capabilities:
rotor insulation failure due to high field voltage
rotor heating due to high field current
stator heating due to high VAR loading
heating due to excess flux (volts/Hz)
Power system considerations:
contribute to effective control of system voltage and improvement of system stability
Physical Description
Mathematical Model
Park's "dqo" transportation
Steady-state Analysis
phasor representation in d-q coordinates
link with network equations
Definition of "rotor angle"
Representation of Synchronous Machines in Stability Studies
neglect of stator transients
magnetic saturation
Simplified Models
Synchronous Machine Parameters
Reactive Capability Limits
Consists of two sets of windings:
3 phase armature winding on the stator distributed with centres 120° apart in space
field winding on the rotor supplied by DC
Two basic rotor structures used:
salient or projecting pole structure for hydraulic units (low speed)
round rotor structure for thermal units (high speed)
Salient poles have concentrated field windings; usually also carry damper windings on the pole face.Round rotors have solid steel rotors with distributed windings
Nearly sinusoidal space distribution of flux wave shape obtained by:
distributing stator windings and field windings in many slots (round rotor);
shaping pole faces (salient pole)
DYNAMIC STABILITY ANALYSIS (Small Signal Stability) – 1
Small-Signal Stability of Multi-machine Systems
Special techniques for analysis of very large systems
Characteristics of Small-Signal Stability Problems
Local problems
Global problems
DYNAMIC STABILITY ANALYSIS – 2
Introduction
Overview of the Proposed Method
Generating Unit
Synchronous Machine
Calculation of Equilibrium State Conditions
Excitation and Governor Control Systems
Excitation System
Turbine-Governor System
Combined Model of Generating Unit
Wide area monitoring systems (WAMS) are essentially based on the new data acquisition technology of phasor measurement and allow monitoring transmission system conditions over large areas in view of detecting and further counteracting grid instabilities.
What is islanding ?
Consider the power network as shown in fig.1
Now if we disconnect the line AB from the infinite transmission grid there will be an isolated region . The D1, D2 are power sources (eg : inverter , solar power cells ). The power generated in this region is fed to the island only.
We see that there no longer is any control over the island voltage at the bus X . Also there is no mechanism here for control of frequency.
This state is referred to as islanding.
Objectives: This course will provide a comprehensive overview of power system stability and control problems. This includes the basic concepts, physical aspects of the phenomena, methods of analysis, the integration of MATLAB and SINULINK in the analysis of power system .
Course Content: 1. Power System Stability: Introduction
2. Stability Analysis: Swing Equation
3. Models for Stability Studies
4. Steady State Stability
5. Transient Stability
6. Multimachine Transient Stability
7. Power System Control: Introduction
8. Load Frequency Control
9. Automatic generation Control
10. Reactive Power Control
Functions and Performance Requirements
Elements of an Excitation System
Types of Excitation Systems
Control and Protection Functions
Modeling of Excitation Systems
The functions of an excitation system are
to provide direct current to the synchronous generator field winding, and
to perform control and protective functions essential to the satisfactory operation of the power system
The performance requirements of the excitation system are determined by
Generator considerations:
supply and adjust field current as the generator output varies within its continuous capability
respond to transient disturbances with field forcing consistent with the generator short term capabilities:
rotor insulation failure due to high field voltage
rotor heating due to high field current
stator heating due to high VAR loading
heating due to excess flux (volts/Hz)
Power system considerations:
contribute to effective control of system voltage and improvement of system stability
Physical Description
Mathematical Model
Park's "dqo" transportation
Steady-state Analysis
phasor representation in d-q coordinates
link with network equations
Definition of "rotor angle"
Representation of Synchronous Machines in Stability Studies
neglect of stator transients
magnetic saturation
Simplified Models
Synchronous Machine Parameters
Reactive Capability Limits
Consists of two sets of windings:
3 phase armature winding on the stator distributed with centres 120° apart in space
field winding on the rotor supplied by DC
Two basic rotor structures used:
salient or projecting pole structure for hydraulic units (low speed)
round rotor structure for thermal units (high speed)
Salient poles have concentrated field windings; usually also carry damper windings on the pole face.Round rotors have solid steel rotors with distributed windings
Nearly sinusoidal space distribution of flux wave shape obtained by:
distributing stator windings and field windings in many slots (round rotor);
shaping pole faces (salient pole)
DYNAMIC STABILITY ANALYSIS (Small Signal Stability) – 1
Small-Signal Stability of Multi-machine Systems
Special techniques for analysis of very large systems
Characteristics of Small-Signal Stability Problems
Local problems
Global problems
DYNAMIC STABILITY ANALYSIS – 2
Introduction
Overview of the Proposed Method
Generating Unit
Synchronous Machine
Calculation of Equilibrium State Conditions
Excitation and Governor Control Systems
Excitation System
Turbine-Governor System
Combined Model of Generating Unit
Modelado y simulación del transformador eléctrico.Orlando Ramirez
El documento analiza el modelado del trasformador con carga y en vacío en su parte lineal, también se analiza su comportamiento debido a la saturación.
Power Quality is a combination of Voltage profile, Frequency profile, Harmonics contain and reliability of power supply.
The Power Quality is defined as the degree to which the power supply approaches the ideal case of stable, uninterrupted, zero distortion and disturbance free supply.
Preguntas:
1- Enumere los tipos de máquinas de corriente continua.
2- ¿Qué diferencia física tiene una máquina síncrona de la máquina asíncrona?
3- ¿Qué es un motor?
4- ¿Qué es un generador?`
5- ¿Qué es una máquina eléctrica?
6- Enumere los tipos de máquinas de corriente alterna.
7- ¿Qué es dinamo?
8- ¿Cuál es la principal diferencia entre una máquina síncrona y una máquina asíncrona?
9- ¿Cuál es la ley que rige el funcionamiento de las máquinas eléctricas? Explique.
10- ¿Qué es un transformador?
11- ¿Qué expresa la ley de ampere?
12- ¿Qué expresa la ley de Biot-Savart?
13- ¿Qué es una máquina síncrona?
14- ¿Qué es una máquina asíncrona?
15- Haga un breve comentario de las partes físicas de la máquina síncrona y de la máquina asíncrona?
16- ¿Qué es un rotor devanado?
17- ¿Qué es un rotor jaula de ardilla?
18- ¿Qué es un rotor cilíndrico?
19- ¿Qué es un rotor polos salientes?
20- ¿Cómo se desarrolla el par en la máquina asíncrona trifásica?
21- ¿Por qué es imposible que un motor de inducción opere a velocidad síncrona?
22- ¿Cómo funciona la máquina de inducción como generador?
23- ¿Qué es permeabilidad?
24- ¿Qué es retentividad y remanencia?
25- ¿Qué es fuerza magnetomotriz?
26- ¿Cuál es la diferencia entre FEM y FMM?
27- ¿Qué es histéresis?
28- ¿Qué es curva de histéresis?
29- ¿Qué es un circuito magnético?
30- ¿Qué entiende por reluctancia o resistencia magnética?
31- Explica la ley de Ohm aplicada a circuitos magnéticos.
32- Explica las leyes de Kirchhoff aplicada a los circuitos magnéticos.
33- Explique de forma general el método de solución de circuitos magnéticos conocido como el método directo.
34- Explique de forma general el método de solución de circuitos magnéticos conocido como el método de prueba y error.
35- ¿Qué es pérdidas por histéresis?
36- ¿Qué es perdidas por corrientes parasitas (corrientes de Foucault)?
37- ¿Qué es efecto piel en corriente alterna?
38- ¿Por qué la resistencia de corriente alterna difiere de la resistencia de corriente continua?
39- ¿Qué es un transformador?
40- Describa sobre las principales partes físicas de un transformador.
41- Explique el concepto de transformador ideal
42- Explique el concepto del transformador real
43- Explique sobre los componentes del circuito equivalente del transformador.
44- ¿Cómo funciona un transformador?
45- ¿En qué consiste la prueba de vacío?
46- ¿En qué consiste la prueba de corto circuito?
47- Explique el diagrama vectorial completo del transformador
48- Explique el diagrama vectorial simplificado del transformador
Injection of the wind power into an electric grid affects the power quality. The performance of the wind turbine and thereby power quality are determined on the basis of measurements and the norms followed according to the guideline specified in International Electro-technical Commission standard, IEC-61400. The influence of the wind turbine in the grid system concerning the power quality measurements are-the active power, reactive power, variation of voltage, flicker, harmonics, and electrical behavior of switching operation and these are measured according to national/international guidelines. The paper study demonstrates the power quality problem due to installation of wind turbine with the grid. In this proposed scheme STATic COMpensator (STATCOM) is connected at a point of common coupling with a battery energy storage system (BESS) to mitigate the power quality issues. The battery energy storage is integrated to sustain the real power source under fluctuating wind power. The STATCOM control scheme for the grid connected wind energy generation system for power quality improvement is simulated using MATLAB/SIMULINK in power system block set. The effectiveness of the proposed scheme relives the main supply source from the reactive power demand of the load and the induction generator. The development of the grid co-ordination rule and the scheme for improvement in power quality norms as per IEC-standard on the grid has been presented.
This seminar is specifically designed to provide an advanced understanding of the principles of power system protection design. Yet, via a progressive “building block” approach, this seminar has been specifically designed to meet the learning requirements of those who presently have only a fundamental knowledge of protection principles, while also considering advanced topics to provide a valuable insight for those more experienced in the discipline of power system protection design. Hence, this seminar will assist both those whose day to day work involves them in the application of protection design, coordination and relay setting, and also those in less directly associated areas of electricity system design
Power System Protection for Utility and Power ProfessionalsPowerEDGE
This seminar is specifically designed to provide a comprehensive and in-depth understanding of the fundamental principles of protection design. This seminar has been carefully formulated to provide a valuable insight into power system protection design and principles for those more experienced in the discipline of protection design while yet meeting the learning requirements of those who presently have a more limited or basic knowledge of power system protection principles..
Although the probability of failures of electrical equipment such as switchgear, transformers, protection systems and ancillary equipment are low, the consequences of failure can be substantial. It is therefore vital to keep up the switchgear safe and reliable. This 2-day course is aimed at owners, operators and users of electrical switchgear in industrial and commercial organisations in both high and low voltage networks, plant and equipment. This training course will deal with the issues around design, maintaining and operating switchgear safe. It provides the latest UK industry practices and incorporates the very latest R&D work being undertaken by UK electricity utilities. It will help managers, engineers and others to understand their responsibilities and duties in the selection, use, operation and maintenance of high-voltage switchgear. Safety issues associated with switchgear and the non-invasive diagnostic techniques in use today will be fully discussed. Degradation processes are well determined with the latest monitoring techniques as well as typical failure modes in switchgear and other electrical equipment. By using historic performance information, failure data coupled to modern diagnostic information and simple but effective asset management techniques the risk of failure can be considerably reduced. The learning process is also aided by the use of practical advice and case examples.
According to Institute of Electrical and Electronic Engineers (IEEE) standard IEEE 1100, power quality is defined as “the concept of powering and grounding sensitive electronic equipment in a manner suitable for the equipment”.
WHY POWER QUALITY MATTERS
Power quality and supply reliability are extremely important. Our world is increasingly dependent on electronic equipment and controls, and high sensitivity devices and processes are heavily dependent on a clearly defined power quality. Some facilities operate 7 days a week, 24 hours a day, so incur a high cost of downtime.
Course Overview
The two day course is designed for electrical engineers and operational staff involved in power generation. The content
is relevant for all types of generation involving synchronous machines; from traditional coal, oil, gas and hydro, to
offshore and nuclear. The course will give delegates a firm understanding in the operation of excitation control systems
along with an appreciation of the different types available and the numerous systems offered by the major manufacturers.
Course Learning Outcomes
Delegates will learn about:
Fundamentals of the synchronous machine
The generator capability diagram
Excitation system components
Excitation system control theory
Parallel operation of generators
Brushless / Rotating excitation systems
Static excitation systems
Power System Stabilisers
Transmission company compliance
IEEE Excitation Standards
Who Should Attend
•Electrical engineers involved in power generation both onshore and offshore
•Power plant operational staff
About This Training Course
The two day course is designed for electrical engineers and operational staff involved in power generation. The content
is relevant for all types of generation involving synchronous machines; from traditional coal, oil, gas and hydro, to
offshore and nuclear. The course will give delegates a firm understanding in the operation of excitation control systems
along with an appreciation of the different types available and the numerous systems offered by the major manufacturers.
Learning Outcomes
Delegates will learn about:
Fundamentals of the synchronous machine
The generator capability diagram
Excitation system components
Excitation system control theory
Parallel operation of generators
Brushless / Rotating excitation systems
Static excitation systems
Power System Stabilisers
Transmission company compliance
IEEE Excitation Standards
Who Should Attend
•Electrical engineers involved in power generation both onshore and offshore
•Power plant operational staff
This seminar will provide a comprehensive understanding of the various types of generators, exciters, automatic voltage regulators (AVR’s), and protective systems. This seminar will focus on maximizing the efficiency, reliability, and longevity of this equipment by providing an understanding of the characteristics, selection criteria, common problems and repair techniques, preventive and predictive maintenance. The emphasis in this seminar is on inspection methods, diagnostic testing, troubleshooting, modern maintenance techniques, refurbishment, rewind and upgrade options, and advanced methods for preventing partial discharge and other failures.
This seminar is a MUST for anyone who is involved in the selection, applications, or maintenance of generators, exciters, automatic voltage regulators (AVR’s), and protective systems because it covers how this equipment operates, the latest maintenance techniques, and provides guidelines and rules that ensure the successful operation of this equipment. In addition, this seminar will cover in detail the basic design, operating characteristics, specification, selection criteria, advanced fault detection techniques, critical components and all preventive and predictive maintenance methods in order to increase reliability of the equipment and reduce the operation and maintenance cost.
The Power System Engineering training course will help you to understand the basic concepts of power system engineering and how to start a successful career in power engineering. Furthermore, you will learn the fundamentals of electrical systems, transient and steady state analysis, main components of power systems, electrical machines, high voltage direct current system, active/reactive power control in power systems and power system operation.
Who should attend the TONEX’s Power Systems Engineering training and seminars?
Power System Engineers
Electric Power Utility Engineers
Technicians
Test Engineers
Protection and Control Engineers
Engineers Seeking PDH
Learn about:
Power system planning and advanced applications
Power systems design
Power engineering
System safety engineering
Power Markets, Energy Economics and Strategic Planning
Emerging Generation Technologies
Dynamic/static loads
Synchronous/induction motors
Synchronous/induction generators
Solar generation
Wind generation
Energy storage units
Power factor concept
High voltage direct current system (HVDC)
Multi-terminal HVDC system
Converter circuits
Concept of harmonics and filters
Active power and frequency control
Primary droop control
Reactive power and voltage control
Static VAR compensation
Synchronous condensers
Synchronous Machine Fundamentals
Power System Dynamics
Distribution Systems Planning and Engineering
Substation/Distribution Automation
Smart Grid
Fundamentals of Renewable Energy Systems
Distributed Energy Resources, Microgrids
Grid Resiliency, Energy Storage and Electric Vehicles
Training Outline:
Why Power System Engineering?
Basic Power Systems Engineering Principals
Generation, Transmission and Distribution System Planning
Fundamentals of Electric Circuits
Transient and Steady State Analysis
Power System Components
Electrical Machines
High Voltage Direct Current (HVDC) Transmission
Control of Active and Reactive Power
Power System Operation
Power System Engineering Applied
Call us today at +1-972-665-9786. Learn more about this course audience, objectives, outlines, seminars, pricing etc. Visit our website link below.
Power system engineering training
https://www.tonex.com/training-courses/power-system-engineering-training/
2. 4 Days Workshop
8th-11th June 2015
Grand Hyatt,Bali
indonesia
This course will provide a unique opportunity for engineers in the power industry to undertake a compre-
hensive and rigorous study of a critical area, delivered by the world's foremost expert on the subject. The
course will cover the comprehensive overview of power system stability and control issues and problems.
The broad subject is concerned with the operation of the power system including generating plants under
normal and abnormal conditions.
Holds a Ph.D. In Electrical Engineering from the University of Toronto and has over 35 years of experience in the electric power industry.
Leading edge of development and application of technology that has made the operation of large-scale interconnected power systems more safe, secure
and reliable.
Impacted many areas, including modeling and measurement tools, analysis methods and control techniques that enhance power system stability.
Dr. Kundur's development and validation of comprehensive power plant models for dynamic analysis and control design have been incorporated in
software packages that address transient stability, small signal stability, voltage stability and dynamic reduction for large-scale power systems. Widely
recognized and applied by the power industry, these models are important tools in testing whether the power system can handle and recover from
disturbances without taking down a large portion of the grid.
Dr. Kundur's contributions to advanced excitation control designs have enhanced overall system dynamic performance. In addition to improving system
security, the designs also improved efficiency since the system is able to operate at higher limits.
Dr. Kundur is the author of the book “Power System Stability and Control,” which has been used by academics and practicing engineers worldwide
and is considered an industry classic.
Dr. Kundur is an IEEE Life Fellow and the recipient of several awards, including the 1997 IEEE Nikola Tesla Award, the 2005 IEEE PES Charles Concordia
Power System Engineering Award and the 2010 IEEE Medal in Power Engineering “For leadership in the development and application of analytical
methods, tools and techniques for modeling, simulation and control of large-scale interconnected power systems.”
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Job title:
General Managers
Heads
Senior Manager
Managers
Specialist
System Planners
Network Planners
Grid Operators
Power Engineers
Electrical Engineers
Division / Department
Electrical Engineering
Operations
Technical
Instrumentation & Control
Industry:
Public Electric Utility Companies
Independent Power Producers
Manufactures
Power Distribution Companies
Power Transmission Companies
Generation Industries
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About Power System Stability and Control
Why you should attend this practical course?
Your Facilitator
Who should attend?
Highlights
Facilitated by:
Dr. Prabha Kundur,
President,
Kundur Power System
Solutions Inc, Canada
Operate the power plant at an optimal and efficient state
Better prepare against disturbances and downtime
Meet forecast energy requirements at a minimum cost
Minimize outages due to unforeseen circumstances
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Definition and classification of power system stability
Comprehensive review of synchronous machines, excitation systems, governors and
transmission systems
Control of active power and frequency
Control of reactive power and voltage
Transient and small signal stability
Voltage and frequency stability
Defense plans and island operation
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Senior positions involving power system planning and design at Ontario Hydro, Canada
President and CEO of Powertech Labs Inc., Canada
President of Kundur Power System Solutions Inc.
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At the end of the workshop, you will be able to:
Dr. Prabha Kundur
Companies Dr. Kundur has worked with:
OPTIMIZINGPOWERSYSTEMSTOACHIEVEMAXIMUMRELIABILITY
POWER SYSTEM
STABILITY AND
CONTROL
azimah@blazeavenue.com.my GL: 03 227 22 088 blazeavenue.com.myFax: 03 226 03 187
3. Course Delivery
Course Outline
DAY ONE
DAY TWO
DAY THREE
Course schedule
Registration and coffee
Course commences
Morning refreshments and networking break
Course resumes
Luncheon
Course resumes
Afternoon refreshments and networking break
Course resumes
Course Ends
08:30
09:00
10:30
11:00
12:45
14:00
15:15
15:45
17:30
Day 1
Session One
Introduction to Power System Stability
• Definition and classification of power system stability
• Brief description of each category of system stability
• Conceptual relationship between power system stability, security and reliability
• Traditional approach power system security assessment
• Challenges to secure operation of present-day power systems
Review of Equipment Characteristics and Modelling
Session Two
• Synchronous machines: theory and modelling, machine parameters, saturation modelling, synchronous
machine representation in stability studies, reactive capability limits.
• Excitation systems: elements of an excitation system, types of excitation systems,
control and protective functions,modelling.
• Prime movers and governing systems: hydraulic turbines and governing systems, steam turbines and
governing systems, gas turbines and combined-cycle units.
• Generating unit testing and model validation: test procedures, current industry practices.
• AC Transmission: performance equations and parameters, surge impedance loading,
voltage-power characteristics, reactive power requirements, loadability characteristics, factors influencing transfer of active and reactive power.
• Power system loads: basic modelling concepts, static and dynamic models, acquisition of load model parameters.
Session Three
Control of Active Power and Frequency
• Fundamentals of frequency control
• Composite regulating characteristics of power systems
• Automatic generation control
• Under-frequency load shedding
4 Days Workshop
8th-11th June 2015
Grand Hyatt,Bali
indonesia
POWER SYSTEM
STABILITY AND
CONTROL
azimah@blazeavenue.com.my GL: 03 227 22 088
blazeavenue.com.myFax: 03 226 03 187
4. Day 2
Control of Reactive Power and Voltage
• Control objectives
• Production and absorption of reactive power
• Methods of voltage control
• Principles of reactive compensation in transmission systems
• Static and dynamic compensators
• Coordinated control of reactive power and voltage
Transient (angle) Stability
• An elementary view of the transient stability problem
• Simulation of power system dynamic response
• Numerical integration methods
• Performance of protective relaying
• Case Studies
• Transient stability enhancement
• Examples of major system blackouts due to transient instability
Session Four
Session Five
Day 3
Small-Signal (angle) Stability
• Nature and description of small-signal stability (SSS) problems
• Methods of analysis; modal analysis approach
• Characteristics of local-plant mode and inter-area mode oscillations
• Case studies
• SSS enhancement
• Examples of major system disturbances due to small-signal instability
Subsynchronous Oscillations
• Steam turbine generator torsional characteristics
• Torsional interaction with power system controls: PSS, HVDC converter controls
• Subsynchronous resonance
• Impact of network-switching disturbances
Session Six
Session Seven
Voltage Stability
• Description of the phenomenon
• Factors influencing voltage stability
• Methods of analysis
• Typical scenarios of short-term voltage instability and long-term voltage instability
• Prevention of voltage instability
• Case studies
• Examples of major system disturbances due to voltage instability
Day 4
Frequency Stability
• Nature and description of frequency stability problems
• Examples of system disturbances caused by frequency instability
• Analysis of frequency stability problems
• Case studies
• Mitigation of frequency stability problems.
Wind Turbine Generators
• Wind turbine characteristics
• Types of wind turbine generator technologies
• Protection systems
• Impact on power system dynamic performance
Major Power Grid Blackouts in 2003
• Description of events
• Causes of blackouts
• Lessons learned
Comprehensive Approach to Power System Security
• Application of robust power system controls
• Defense plan against extreme contingencies
• Restoration plans
• On-line security assessment
• Reliability management system
• Wide-area monitoring and control
• Widespread use of distributed generation
Session Eight
Session Nine
Session Ten
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azimah@blazeavenue.com.my GL: 03 227 22 088 blazeavenue.com.myFax: 03 226 03 187
5. Pleasephotocopyforadditionaldelegates
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Email :
Telephone : Fax : Priority Code :
DELEGATES’ DETAILS
First Delegate : Mr./Ms. Fourth Delegate : Mr./Ms.
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:liamE:liamE
Diet Preference : None/Vegetarian/Halal/Others: Diet Preference : None/Vegetarian/Halal/Others:
Second Delegate : Mr./Ms. Fifth Delegate : Mr./Ms.
:eltiTboJ:eltiTboJ
:eniLtceriD:eniLtceriD
:liamE:liamE
Diet Preference : None/Vegetarian/Halal/Others: Diet Preference : None/Vegetarian/Halal/Others:
Power System Stability & Control
8th-11th June 2015
Grand Hyatt,Bali
indonesia
USD 2,700 USD 2,899
Register before 15th AprilRegister before 27 February Register before 15th May
Group Registration of minimum 3 delegates (offer valid until 15th April only): USD 2,500 /delegate
Gold Package: Register 5 delegates, 6th delegate participates for FREE (5 + 1 Free)
Platinum Package: Register 10, additional 3 delegates participates for Free (10 + 3 Free)
TERMS & CONDITIONS
• Payment Terms: Payment is required within 7 days of invoice date. Blaze Avenue reserves the right to refuse admission IF payment is not received before the event date. • Transfer: Transfer
is allowed upon written notification. • Cancellation: Registration carries a 70% cancellation liability, notwithstanding, full fee is payable when cancellation is less than two (2) weeks before
the event. Cancellation has to be done in writing. If Blaze Avenue decides to cancel or postpone this event, it is not responsible for covering airfare, hotel, or other travel costs incurred by
clients. The fee will not be refunded, but credited to a future event. No Show: No show does not constitute transfer or cancellation and the full fee is payable. Changes: Blaze Avenue
reserves the right to change event dates, venue, speakers, or omit event features, or merge the event with another event, as it deems necessary without penalty, refunds or alternative
offers. • Tax: Registration fees exclude tax. For clients outside Malaysia, the sum payable is as the listed fees, exclusive of tax. To this sum shall be added any other local tax or withholding
tax from client's country of origin, if any. • Marketing: Blaze Avenue may use your company’s logo or business name or otherwise refer to your company in our website, any marketing,
promotional or advertising material as a client of our services. • Governing law: This Agreement shall be governed and construed in accordance with the law of Malaysia and the parties
submit to the exclusive jurisdiction of the Courts in Malaysia. • Indemnity: Should for any reason outside the control of Blaze Avenue, the event be cancelled due to an act of terrorism,
extreme weather conditions or industrial action, Blaze Avenue shall endeavour to reschedule but the client hereby indemnifies and holds Blaze Avenue harmless from and against any and
all costs, damages and expenses, including attorney’s fees, which are incurred by the client.
Register Now azimah@blazeavenue.com.my GL: 03 227 22 088
blazeavenue.com.myFax: 03 226 03 187
FREE
Early Bird
USD 2,500
AUTHORISATION METHODOFPAYMENT
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Payable by Cheque to: BLAZE AVENUE (M) SDN BHD
Payment by bank transfer should be made to: Hong Leong Bank Berhad (HLBB)
Account No: 29200020908
Account Name: BLAZE AVENUE (M) SDN BHD
SWIFT/BIC Code: HLBB MYKL
150, Jalan Tun Sambanthan, 50470, Kuala Lumpur
Branch: BKF (Brickfields)
Third Delegate : Mr./Ms. Sixth Delegate : Mr./Ms.
:eltiTboJ:eltiTboJ
:eniLtceriD:eniLtceriD
:liamE:liamE
Diet Preference : None/Vegetarian/Halal/Others: Diet Preference : None/Vegetarian/Halal/Others:
4 Days Workshop
8th-11th June 2015
Grand Hyatt,Bali
indonesia
Power System Stability &
Control