DEE-24106 Electric Power Systems, 5 cr

Person responsible

Sami Repo, Enrique Acha Daza

Lessons

Implementation 1: DEE-24106 2015-01

Study type P1 P2 P3 P4 Summer

Lectures
Excercises
Assignment

24 h/per
16 h/per
40 h/per

Lecture times and places: Tuesday 12 - 15 SE100J

Requirements

To attend the lectures; to pass the one final exam (60% of grade) and to complete the course assignments (40% of grade)

Learning Outcomes

Student having taken the course should understand the principles of how an electrical power system is planned and operated. They are expected to model and analyse the steady-state and dynamic performance of simple power systems using: power flows; short-circuit fault current calculations and the various forms of power system stability assessments. Student should be able to carry out simulation studies of practical power systems operating under steady-state and dynamic conditions using commercial power system analysis software; to check the sanity of the simulation results by resorting to basic theory; to assess the operation of the actual power system under study and to produce a well laid-out simulations report.

Content

Content Core content Complementary knowledge Specialist knowledge

1. Week 1. Transmission Line Performance: Active and reactive power flows in short, medium and long transmission lines, SIL. Principles of compensation Week 1. Transmission Line Performance: Standing waves and basic concepts of corona effects Week 1. Transmission Line Performance: At harmonic frequencies

2. Week 2. Power Flow Analysis: Basic theory, power flow solution algorithms (e.g.. Newton-Raphson, Fast Decoupled) Week 2. Power Flow Analysis: Computer-based power flow solutions of medium and large-scale power systems Week 2. Power Flow Analysis: Sparse matrix techniques Three-phase power flows

3. Week 3. Short-Circuit Analysis: Background theory, fault level and the representation of classical power system faults Week 3. Short-Circuit Analysis: Power flow-initialized short-circuit analyses Advanced transformer modelling Week 3. Short-Circuit Analysis: Dynamics of short-circuits, circuit breaker selection and protection relay studies

4. Week 4. Grid Operation & Frequency Control: Principles and hierarchy of frequency control at electricity market. Primary and secondary frequency control. General principles of grid operation in today’s power industry: Transmission system congestion management, Power balance management and Reserves. Week 4. Grid Operation & Frequency Control: Area control error. Automatic generation control using SCADA and EMS systems. Advanced principles of grid operation and frequency control Week 4. Grid Operation & Frequency Control: Dynamics of grid operation and frequency control

5. Week 5. Voltage Control & Stability: Equipment for voltage control and reactive power compensation. Primary voltage control. Voltage control principles in Finland. Basics of voltage stability and voltage collapse. Voltage stability analysis methods: PV- and VQ-curves. Week 5. Voltage Control & Stability: Secondary voltage control. Modelling of SVC, tap changer and polynomial loads in Newton-Raphson power flows. Week 5. Voltage Control & Stability: Dynamics of voltage control FACTS equipment

6. Week 6. Power Systems Stability: Stability classification, swing equation, power-angle equation and equal-area criterion. Classical model of synchronous machine. Analysis of simple systems Week 6. Power Systems Stability: Analysis of multi-machine systems, combination of dynamic and static equations, factors influencing angle stability. Introduction to small signal stability Week 6. Power Systems Stability: State-space presentation of large-scale power systems for small signal stability analysis

7. Week 7. Power system harmonics: Week 7. Power system harmonics: Week 7. Power system harmonics:

Instructions for students on how to achieve the learning outcomes

Exam (60%) Assignments (40%)

Assessment scale:

Numerical evaluation scale (1-5) will be used on the course

Study material

Type Name Author ISBN URL Additional information Examination material

Lecture slides Enrique Acha Yes

Lecture slides Sami Repo Yes

Online book Electric Energy Systems A. Gomez-Exposito, A.J. Conejo and C. Canizarez 9781420007275 Applicable chapters: 1,2,3,8,9,10 Yes

Prerequisites

Course Mandatory/Advisable Description

DEE-23106 Fundamentals of Electrical and Power Engineering Mandatory

Correspondence of content

Course Corresponds course Description

DEE-24106 Electric Power Systems, 5 cr SET-6316 Electric Power Systems, 5 cr

Last modified 07.01.2016

Study type	P1	P2	P3	P4	Summer
Lectures Excercises Assignment			24 h/per 16 h/per 40 h/per

Content	Core content	Complementary knowledge	Specialist knowledge
1.	Week 1. Transmission Line Performance: Active and reactive power flows in short, medium and long transmission lines, SIL. Principles of compensation	Week 1. Transmission Line Performance: Standing waves and basic concepts of corona effects	Week 1. Transmission Line Performance: At harmonic frequencies
2.	Week 2. Power Flow Analysis: Basic theory, power flow solution algorithms (e.g.. Newton-Raphson, Fast Decoupled)	Week 2. Power Flow Analysis: Computer-based power flow solutions of medium and large-scale power systems	Week 2. Power Flow Analysis: Sparse matrix techniques Three-phase power flows
3.	Week 3. Short-Circuit Analysis: Background theory, fault level and the representation of classical power system faults	Week 3. Short-Circuit Analysis: Power flow-initialized short-circuit analyses Advanced transformer modelling	Week 3. Short-Circuit Analysis: Dynamics of short-circuits, circuit breaker selection and protection relay studies
4.	Week 4. Grid Operation & Frequency Control: Principles and hierarchy of frequency control at electricity market. Primary and secondary frequency control. General principles of grid operation in today’s power industry: Transmission system congestion management, Power balance management and Reserves.	Week 4. Grid Operation & Frequency Control: Area control error. Automatic generation control using SCADA and EMS systems. Advanced principles of grid operation and frequency control	Week 4. Grid Operation & Frequency Control: Dynamics of grid operation and frequency control
5.	Week 5. Voltage Control & Stability: Equipment for voltage control and reactive power compensation. Primary voltage control. Voltage control principles in Finland. Basics of voltage stability and voltage collapse. Voltage stability analysis methods: PV- and VQ-curves.	Week 5. Voltage Control & Stability: Secondary voltage control. Modelling of SVC, tap changer and polynomial loads in Newton-Raphson power flows.	Week 5. Voltage Control & Stability: Dynamics of voltage control FACTS equipment
6.	Week 6. Power Systems Stability: Stability classification, swing equation, power-angle equation and equal-area criterion. Classical model of synchronous machine. Analysis of simple systems	Week 6. Power Systems Stability: Analysis of multi-machine systems, combination of dynamic and static equations, factors influencing angle stability. Introduction to small signal stability	Week 6. Power Systems Stability: State-space presentation of large-scale power systems for small signal stability analysis
7.	Week 7. Power system harmonics:	Week 7. Power system harmonics:	Week 7. Power system harmonics:

Type	Name	Author	ISBN	URL	Additional information	Examination material
Lecture slides		Enrique Acha				Yes
Lecture slides		Sami Repo				Yes
Online book	Electric Energy Systems	A. Gomez-Exposito, A.J. Conejo and C. Canizarez	9781420007275		Applicable chapters: 1,2,3,8,9,10	Yes

Course	Mandatory/Advisable	Description
DEE-23106 Fundamentals of Electrical and Power Engineering	Mandatory

Course	Corresponds course	Description
DEE-24106 Electric Power Systems, 5 cr	SET-6316 Electric Power Systems, 5 cr