Electrical Power System Stability - Beginner To Advanced

Generator Dynamics, Synchronism of Generators, Direct and Quadrature Axis Model, Swing Equation, Equal Area Criterion

What you'll learn
Fundamentals of Generator Dynamics
Fundamentals of Transient Stability Analysis
Single and Two Generator Transients Fundamentals and ETAP Examples
Synchronism Between Two Generating Sources
Synchronous Generator Direct (D) and Quadrature (Q) Axis Model
Synchronous Generator Sub-transient, Transient and Steady-state Model
Derivation of Swing Equation for Generator
Derivation of Inertia Constant (H) From Moment of Inertia (J)
Deriving Rotor Angle From Swing Equation
Derivation of Small Disturbance Stability Equation OR Synchronizing Power
Derivation of Simple Harmonic Motion (SHM) Equation
Small Disturbance Stability of Single Machine Infinite Bus (SMIB) System
Large Disturbance Stability or Equal Area Criterion
Requirements
Electrical Engineering
No Prior Knowledge
Description
"Want To Become Expert In ETAP Software and Power System Stability and Transient Analysis?" This course will help you to achieve your goals to become ETAP and Power System Expert.Welcome to the course " Electrical Power System Stability – Beginner to Advance Level Course"The purpose of this course is to learn power system modeling & power system stability analysis using ETAP software which will cover a range of ETAP functionalities used to design & solve various power system practical problems.The course begins with fundamentals of generator dynamics and transient stability analysis, synchronism of generating sources, synchronous generator direct (d) and quadrature (q) axis model as well as sub-transient, transient and steady-state model, swing equation, small and large disturbance stability, equal area criterion etc.  The course also covers the simulation of transient stability analysis using ETAP software. The user will be able to create a single line diagram, data entry, and quickly expand the knowledge to automatically perform multiple ‘what if’ studies using multiple scenarios. The topics are explained with theoretical aspects as well as hand calculations so that it becomes more easier to the attendees to understand the concepts.Below major topics are covered in this course:Fundamentals of Generator DynamicsFundamentals of Transient Stability AnalysisSingle and Two Generator Transients Fundamentals and ETAP ExamplesSynchronism Between Two Generating SourcesSynchronous Generator Direct (D) and Quadrature (Q) Axis ModelSynchronous Generator Sub-transient, Transient and Steady-state ModelDerivation of Swing Equation for GeneratorDerivation of Inertia Constant (H) From Moment of Inertia (J)Deriving Rotor Angle From Swing EquationDerivation of Small Disturbance Stability Equation OR Synchronizing PowerDerivation of Simple Harmonic Motion (SHM) EquationSmall Disturbance Stability of Single Machine Infinite Bus (SMIB) SystemLarge Disturbance Stability or Equal Area CriterionBenefits of attending this course:Course is published using ETAP 20.5Topics are supported with theoretical explanation Downloadable course material and Hand Calculations

Overview

Section 1: Introduction To Power System Stability

Lecture 1 Introduction To Power System Stability

Section 2: Generator Dynamics and Transients Fundamentals

Lecture 2 Generator Dynamics and Transients Fundamentals

Section 3: Generator Dynamics Fundamentals and ETAP Example

Lecture 3 Generator Dynamics_Load Addition_Fundamentals

Lecture 4 Generator Dynamics_Load Addition_ETAP Example

Lecture 5 Generator Dynamics_Load Rejection_Fundamentals

Lecture 6 Generator Dynamics_Load Rejection_ETAP Example

Lecture 7 Generator Dynamics_Phase Fault_Fundamentals

Lecture 8 Generator Dynamics_Phase Fault_ETAP Example

Section 4: Multiple OR Parallel Generator Dynamics Fundamentals and ETAP Example

Lecture 9 Multiple OR Parallel Generator Dynamics Fundamentals_Part-1

Lecture 10 Multiple OR Parallel Generator Dynamics Fundamentals_Part-2

Lecture 11 Multiple OR Parallel Generator Dynamics Fundamentals_Part-3

Lecture 12 Need for Synchronism Between Generating Sources

Lecture 13 Two Generator Dynamics_ETAP Example-1

Lecture 14 Two Generator Dynamics_Under Frequency Load Shedding_ETAP Example-2

Section 5: Synchronous Generator Direct (d) and Quadrature (q) Axis Impedance Model

Lecture 15 Synchronous Generator Direct (d) and Quadrature (q) Axis Impedance Model

Lecture 16 Synchronous Generator-Subtransient-Transient-Steadystate_d & q Axis Model

Section 6: Swing Equation For Generators

Lecture 17 Derivation of Swing Equation For Generators

Section 7: Derivation of Inertia Constant (H) From Moment of Inertia (J)

Lecture 18 Derivation of Inertia Constant (H) From Moment of Inertia (J)

Section 8: Deriving Generator Rotor Angle From Swing Equation

Lecture 19 Deriving Generator Rotor Angle From Swing Equation

Section 9: Small Disturbance Stability OR Synchronizing Power

Lecture 20 Small Disturbance Stability OR Synchronizing Power Equation

Lecture 21 Simple Harmonic Motion (SHM) Equation

Lecture 22 Small Disturbance Stability of Single Machine Infinite Bus (SMIB) System

Section 10: Large Distrubance Stability OR Equal Area Criterion

Lecture 23 Large Disturbance Stability OR Equal Area Criterion

Beginners Who Are New To ETAP Software,Students Preparing Their Projects/Thesis,Graduate Electrical Engineers For Cracking The Interviews,Professionals Working For Companies & Needs To Execute Power System Study Projects,Project Engineers,Electrical Technicians,Project Managers,Electrical Operators