The following block diagrams highlight the process of Energy
Conversion in the nuclear , Fossil fueled and hydro power stations.
Introduction To Conventional And Renewable Energy Resources
For Power Generation.
In order to generate electrical energy we have to depend on
sources such as coal, natural gas, hydro(water), and nuclear energy. These can
be classified as follows:
A) Fossil Fuels
1) Coal
2) Oil
3) Natural gas
4) Substitute fuels eg. coal liquefaction and coal
gasification
5) Oil from shale
6) Oil from tar sand
B) Nuclear Energy
1) Fission Reactors
2) Breeder Reactors
3) Fusion Reactors
C) Natural Sources
1) Hydro electric Power
2) Geothermal
3) Wind
4) Solar – Solar thermal, Photovoltaic
5) Ocean – Ocean thermal, Ocean current, tidal
Conventional Energy Sources
The conventional Energy Sources are as those that have been
in use for over a century and which are considered less risky. Examples are
hydroelectric power stations, fossil fueled power stations.
The following block diagrams highlight the process of Energy
Conversion in the nuclear , Fossil fueled and hydro power stations.
Fossil Fuel --à
Boiler ---à
Heat Energy --à
Steam Turbine --à
Mechanical Energy -à
Generator à
Electrical Energy
Water in Reservoir --à Hydraulic Turbine --à Mechanical Energy -à Generator à Electrical Energy
Heat From Nuclear Reactor --àSteam
Generator ---à
Heat Energy --à
Steam Turbine --à
Mechanical Energy -à
Generator à
Electrical Energy
Name:Ozoede Chukwudi .C.
ReplyDeleteReg No:Esut/2009/102191
PRACTICAL TRANSFORMER
It is a transformer that works in the real world and it is not one that is imaginary rather we can see it and it can get spoilt.It has a flux loss.
PROPERTIES
1)The permeability of the core is not infinity.
2)The winding resistance is present.
3)Loss occur in the iron to slightly change the direction of the flux.
4)Not all the flux linking one winding links the other winding...
Name:Ozoede Chukwudi .C.
ReplyDeleteReg No:Esut/2009/102191
PRACTICAL TRANSFORMER
It is a transformer that works in the real world and it is not one that is imaginary rather we can see it and it can get spoilt.It has a flux loss.
PROPERTIES
1)The permeability of the core is not infinity.
2)The winding resistance is present.
3)Loss occur in the iron to slightly change the direction of the flux.
4)Not all the flux linking one winding links the other winding...
Name:Ozoede Chukwudi .C.
ReplyDeleteReg No:Esut/2009/102191
PRACTICAL TRANSFORMER
It is a transformer that works in the real world and it is not one that is imaginary rather we can see it and it can get spoilt.It has a flux loss.
PROPERTIES
1)The permeability of the core is not infinity.
2)The winding resistance is present.
3)Loss occur in the iron to slightly change the direction of the flux.
4)Not all the flux linking one winding links the other winding...
Name:Ogu Ifeanyichukwu B.P
ReplyDeleteReg No.Esut/2009/102316
Symmetrical component:it is a balance phasor which is used in representing other phase which may or may not be balanced in electrical power system,
The three types that are been used in electrical power system are as follows. (1)positive . (2) negative and zero phasors,
The effect of impendance.
Vabc=zabcia..........(1)
Vabc=A [A] vo12.....(2)
Iabc=[A]Io12.........(3)
[A]Vo12=2abc(A)Io12.....(4)
Vo12[A]zabc[A].....(5)
Zo12=(A)_1 zabc A....(6)
So that Vo12=zo12gIo12
L>240km
An electric generator is defined as a device that is used in the conversion of mechanical energy to electrical energy by means of electromagnetic induction. Its main work is to force electrons to flow via an electrical circuit.
ReplyDeletehydro electric
hydro electric power
what is hydro electric
inventhistory
power generator
wind power generator
solar and power
electric transportation
Visit the website and get more information => www.inventhistory.com
Thank you!
ReplyDeletename: NWOBODO ONYEDIKACHI JOEL
ReplyDeletereg no:ESUT/2010/110319
faullt analysis is a study of electrical power system after a fault with a view of determinig the current and voltage distribution subsequentially.
The result of the fault analysis is used for different purposes wich include;
-it is used for protection scheme design
-it is used for determining the current transformer and voltage transformer
-it is used for contengency provision in the case of emergency
NAME: DAVID CHRISTOPHER CHUKWUDI
ReplyDeleteDEPARTMENT: ELECTRICAL AND ELECTRONICS ENGINEERING
REG NO: ESUT/2012/137635
COURSE CODE: EEE554
ASSESSMENT ON EEE 554
What I have learnt so far on this course.
Stability study is the ability to know if a system will retain its synchronism after perturbation. One may ask, what is perturbation? Perturbation is the influence on a power system that causes it to deviate slightly.
A power system is assumed to be steady, but it is not. Under normal condition, a system is considered to be quazistatic, this means that the system changes continually, for the purpose of power system analysis, we then apply steady state analytic procedure. That is why this study is of a great importance to us. Because it makes you know the condition of a power system.
Load flow analysis is a study of the power system with the view of knowing the voltages at the various buses using system configuration. There are two types of flow analysis namely; Newton Raphson iteration method and the Gauss seidal iteration method.
Fault analysis is a study of power system after a fault with the view of finding the voltage and current distribution. There exist two main types of fault namely:
Balanced fault and Unbalanced fault. In the balanced fault, it is easy to analyse compared to the unbalanced fault. When a fault is affecting the whole parts of the system, it is a balanced fault.
In the unbalanced fault, we can analyse the system using symmetrical components. What is a symmetrical component? Symmetrical components are phasors which are balanced, but they are used to represent other phasor which may or may not be balanced.
NAME: OZIOKO KINGSLEY VALENTINE
ReplyDeleteREG. NO: ESUT/2012/137619
DEPT: ELECTRICAL/EECTRONICS ENGINEERING
COURSE: POWER SYSTEM ANALYSIS
COURSE CODE: EEE 554
WHAT I LEARNT SO FAR
Symmetrical components: These are set balanced phasors which can be used to represent or resolve an unbalanced system of ‘n’ related phasor into ‘n’ systems of balanced phasors. The symmetrical components have both length and angle between them equal.
Types of symmetrical components
1 Positive sequence components
2 Negative sequence components 3. Zero sequence components
Load flow analysis: This is the study of power system to know the voltages at the various buses using the system configuration, loading at various buses, system topology and system parameters.
Types of load flow analysis
1. Newton Raphson iteration method which is based on algebraic analysis.
2. Gauss Seidel iteration method which is based on Taylor series expansion of power system expression with error analysis to correct and improve the guessed voltage values, ignoring second derivatives and higher derivatives.
Fault analysis : This is the study of power system after fault, with a view of finding the voltage and current distribution subsequently .
There are two types of fault
1. Balanced fault 2. Unbalanced fault
Stability studies: this is the study of a system to know if a system will retain synchronism after perturbation or disturbance.
Types of stability studies
1. Transient 2. Dynamic 3. Steady state
NAME: AGBOWO IZUCHUKWU MONDAY
ReplyDeleteREG. NO: ESUT/2012/137672
DEPT: ELECTRICAL/EECTRONICS ENGINEERING
TITLE: POWER SYSTEM ANALYSIS
COURSE CODE: EEE 554
WHAT I LEARNT SO FAR
Load flow analysis: This is the study of power system to know the voltages at the various buses using the system configuration, loading at various buses, system topology and system parameters.
Types of load flow analysis
1. Newton Raphson iteration method.
2. Gauss Seidel iteration method.
Fault analysis : This is the study of power system after fault, with a view of finding the voltage and current distribution subsequently .
There are two types of fault
1. Balanced fault 2. Unbalanced fault
Symmetrical components: These are set balanced phasors which can be used to represent or resolve an unbalanced system of ‘n’ related phasor into ‘n’ systems of balanced phasors. The symmetrical components have both length and angle between them equal.
Types of symmetrical components
1 Positive sequence components
2 Negative sequence components 3. Zero sequence components
Stability studies: this is the study of a system to know if a system will retain synchronism after perturbation or disturbance.
Types of stability studies
1. Transient 2. Dynamic 3. Steady state
NAME: ANYAWU DESMOND ONYEBUCHI
ReplyDeleteDEPT: ELECTRCAL/ELECTRICAL ENGINEERING
REG NO.: ESUT/2012/137641
TITLE: POWER SYSTEM ANALYSIS
CODE: EEE554
WHAT I HAVE LEARNT so far
Load flow analysis: This is the study of power system to know the voltages at the various buses using the system configuration, loading at various buses, system topology and system parameters.
Types of load flow analysis
1. Newton Raphson iteration method.
2. Gauss Seidel iteration method.
Symmetrical components: These are set balanced phasors which can be used to represent or resolve an unbalanced system of ‘n’ related phasor into ‘n’ systems of balanced phasors. The symmetrical components have both length and angle between them equal.
Types of symmetrical components
1 Positive sequence components
2 Negative sequence components 3. Zero sequence components
Stability studies: this is the study of a system to know if a system will retain synchronism after perturbation or disturbance.
Types of stability studies
1. Dynamic
2. Transient
3. Steady state
NAME: MBATA ALEXANDER C
ReplyDeleteDEPT: ELECTRICAL/ELECTRONICS ENGINEERING
REG NO: ESUT/2012/137704
TITLE: POWER SYSTEM ANALYSIS
CODE: EEE 554
WHAT I LEARNT SO FAR
Stability studies: this is the study of a system to know if a system will retain synchronism after perturbation or disturbance.
Types of stability studies
1. Transient 2. Dynamic 3. Steady state
Symmetrical components: These are set balanced phasors which can be used to represent or resolve an unbalanced system of ‘n’ related phasor into ‘n’ systems of balanced phasors. The symmetrical components have both length and angle between them equal.
Types of symmetrical components
1 Positive sequence components 2. Negative sequence components
2. Zero sequence components
Fault analysis : This is the study of power system after fault, with a view of finding the voltage and current distribution subsequently .
There are two types of fault
1. Balanced fault
2. Unbalanced fault
Load flow analysis: This is the study of power system to know the voltages at the various buses using the system configuration, loading at various buses, system topology and system parameters.
Types of load flow analysis
1. Newton Raphson iteration method.
2. Gauss Seidel iteration method.
NAME=EZE CHRISTIAN CHINONSO
ReplyDeleteREG NO : ESUT/2012/137632
DEPARTMENT: ELECTRICAL/ELECTRONIC ENGINEERING
COURSE TITLE:POWER SYSTEM ANALYSIS
COURSE CODE:EEE553 [ QUIZ]
FAULT ANALYSIS IN POWER SYSTEM
What is fault analysis? Fault analysis is the study of a power system after a fault with the view rhe purpose for the analysis of a fault in power system is to get a result that will be used for protection scheme design.
Types of fault
There are two types of faults experienced in a power system they are:
1 Balanced fault: this is a type of system that affects the whole parts of the power system equally. This type of fault is analysed using a single line equivalent circuit
2 Unbalanced fault: this is a type of fault that does not affect all parts of the system equally but affects a portion of the system. This type of fault is analysed using symmentrical components
Steps for fault analysis
1. Determine the terminal conditions
2. Rewrite the terminal conditions in terms of their symmentrical components
3. Simplify the resultant equation
4. Draw a symmentrical component interconnection network that satisfies these set of equations
5. Solve the resultant equation
6. Determine the current and voltage distribution in the resultant network in symmentrical component form
7. Calculate the original current and voltage phasor sequentially
GOD BLESS YOU SIR
ReplyDeleteNAME: NWEKE AMBROSE CHUKWUEBUKA
ReplyDeleteREG : ESUT/2012/137671
DEPT: ELECTRICAL /ELECTRONICS ENGINEERING
COURSE TITLE: POWER SYSTEM ANALYSIS
COURSE CODE: EEE 554
DATE: 19/02/2017
QUIZ
WRITE WHAT YOU HAVE LEARNT SO FAR:
I learnt that LOAD FLOW ANALYSIS is the study of the power system with a view of knowing the voltages at various buses using configuration loading at each buses.
TOOLS FOR LOAD FLOW ANALYSIS
1. BUS SYSTEM TOPOLOGY
2. SYSTEM PARAMETERS
THE TWO TYPE OF SYSTEM LOAD FLOW ANALYSIS ARE:
1 NEWTON RAPHSON ITERATIVE METHOD: Newton Raphson method is the method based on Taylor series expansion of a power system, ignoring second derivative and higher derivatives. Error analysis is applied to Taylor series to correct or improve the guess voltage value.
2 GAUSS SEIDEL ITERATIVE METHOD: Gauss Seidel iterative method is based on the algebraic system.
I also learnt about what FAULT ANALYSIS IS: Fault analysis is the study of power system after a fault, with a view of finding the voltages and currents distribution.
THERE ARE TWO MAIN TYPES OF FAULT ANALYSIS NAMELY:
1. BALANCED FAULTS: I learnt that in balanced fault, we simply analyze or solve the single phase equivalent circuit when a fault has affected the whole part of the system.
2. UNBALANCED FAULTS: I learnt that in unbalanced fault symmetrical components are used for the analysis.
WHAT IS A TERMINAL CONDITION: Terminal conditions are the equation representing faulted system condition.
STABILITY STUDY: It is the study of power system to know or determine ,if the system will retain synchronism after disturbance.
TYPES OF STABILITY STUDIES.
DYNAMIC
STEADY STATE AND TRANSIENT .
STEPS IN ANALYZING FAULTS
step 1: Write down the terminal conditions
step 2:Simplify the terminal conditions
step 3:Re-write this simplified terminal conditions
step 4:Simplify the resulting expression i.e bringing like terms together.
step 5:Simplify the resulted expression.
step 6:Using three equations to draw the symmetrical component inter connection that will satisfy these equation simultaneously.
ONYIBA NNAEMEKA IGNATIUS
ReplyDeleteESUT/2012/137695
EEE554
EEE
26TH 03,2017.
QUIZ
WHAT YOU HAVE LEARNT SO FAR
Load flow analysis: This is the study of power system to know the voltages at the various buses using the system configuration, loading at various buses, system topology and system parameters.
Types of load flow analysis
1. Newton Raphson iteration method.
2. Gauss Seidel iteration method.
Fault analysis : This is the study of power system after fault, with a view of finding the voltage and current distribution subsequently .
Methods of fault analysis are as listed below
Steps for fault analysis
1. Determine the terminal conditions
2. Rewrite the terminal conditions in terms of their symmentrical components
3. Simplify the resultant equation
4. Draw a symmentrical component interconnection network that satisfies these set of equations
5. Solve the resultant equation
6. Determine the current and voltage distribution in the resultant network in symmentrical component form
7. Calculate the original current and voltage phasor sequentially
Symmetrical components: These are set balanced phasors which can be used to represent or resolve an unbalanced system of ‘n’ related phasor into ‘n’ systems of balanced phasors. The symmetrical components have both length and angle between them equal.
ONYIBA NNAEMEKA IGNATIUS
ReplyDeleteESUT/2012/137695
EEE554
EEE
26TH 03,2017.
QUIZ
WHAT YOU HAVE LEARNT SO FAR
Load flow analysis: This is the study of power system to know the voltages at the various buses using the system configuration, loading at various buses, system topology and system parameters.
Types of load flow analysis
1. Newton Raphson iteration method.
2. Gauss Seidel iteration method.
Fault analysis : This is the study of power system after fault, with a view of finding the voltage and current distribution subsequently .
Methods of fault analysis are as listed below
Steps for fault analysis
1. Determine the terminal conditions
2. Rewrite the terminal conditions in terms of their symmentrical components
3. Simplify the resultant equation
4. Draw a symmentrical component interconnection network that satisfies these set of equations
5. Solve the resultant equation
6. Determine the current and voltage distribution in the resultant network in symmentrical component form
7. Calculate the original current and voltage phasor sequentially
Symmetrical components: These are set balanced phasors which can be used to represent or resolve an unbalanced system of ‘n’ related phasor into ‘n’ systems of balanced phasors. The symmetrical components have both length and angle between them equal.
Name: Aka Chibundu Henry
ReplyDeleteReg. Number: ESUT/2012/137643
Department: E. E. E 500L
Course: EEE 554
EEE 554 Quiz: What I've learnt so far
1) Transient Stability Study: This deals with the ability of the power system to retain synchronism after major disturbances such as Transmission system fault, switching operations.
2) Steady State Stability Study: Deals with the ability of the power system to retain synchronism after a small and gradual change (disturbance) in the system.
3) Dynamic Stability Study: Deals with the ability of the power system to retain synchronism after continuous small disturbances in the system i.e when the system is undergoing small gradual changes.
In all stability studies, the objective is to determine whether or not the rotors of the machine being perturbed returns to constant speed of operation.
- Fault Analysis: is a study of the power system after a fault has occurred, in order to determine the voltage and current distribution subsequently..
- There are two main kinds of faults namely;
1) Balanced Fault - one which affects the whole parts of the system and
2) Unbalanced fault - one which doesn't affect the whole part of the system.
Balanced faults are analysed using single phase equivalent circuit in the power system. Unbalanced fault are analysed using symmetrical components.
- Symmetrical Components are a set of balanced Phasors which can be used to represent or resolve am unbalanced system of n related phasors into n systems of balanced phasors
There are 3 major types of symmetrical components namely
1) Positive Sequence component
2) Negative sequence component
3) Zero sequence component.
- Stability Studies: Is simply the study to check if a power system will retain synchronism after perturbation or a disturbance..
- There are 3 types of Stability Studies namely;
- Load flow analysis: is simply the study of the power system with the view of knowing the voltages at the various buses.
There are two main types:
1) Newton Raphson iterative method
2) Gauss seidel iterative method
Name Ugwu Augustine Okechukwu
ReplyDeleteReg ESUT/2012/137708
Dept Electrical and Electronics Engineering
Level 500
Course EEE 554 quiz
Date 29/03/2017
What I have learned so far
Load flow analysis is the study of the power system with a view of knowing the voltages at various buses using configuration loading at each buses.
TYPES OF FAULT ANALYSIS:
1. BALANCED FAULTS: I learnt that in balanced fault, we simply analyze or solve the single phase equivalent circuit when a fault has affected the whole part of the system.
2. UNBALANCED FAULTS: I learnt that in unbalanced fault symmetrical components are used for the analysis.
Fault analysis is the study of a power system after a fault with the view the purpose for the analyzing the fault
Stability studies: this is the study of a system to know if a system will retain synchronism after perturbation or disturbance.
Types of stability studies
1. Transient 2. Dynamic 3. Steady state
STEPS IN ANALYZING FAULTS
step 1: Write down the terminal conditions
step 2:Simplify the terminal conditions
step 3:Re-write this simplified terminal conditions
step 4:Simplify the resulting expression i.e bringing like terms together.
step 5:Simplify the resulted expression.
step 6:Using three equations to draw the symmetrical component inter connection that will satisfy these equation simultaneously.
Name Ugwu Augustine Okechukwu
ReplyDeleteReg ESUT/2012/137708
Dept Electrical and Electronics Engineering
Level 500
Course EEE 554 quiz
Date 29/03/2017
What I have learned so far
Load flow analysis is the study of the power system with a view of knowing the voltages at various buses using configuration loading at each buses.
TYPES OF FAULT ANALYSIS:
1. BALANCED FAULTS: I learnt that in balanced fault, we simply analyze or solve the single phase equivalent circuit when a fault has affected the whole part of the system.
2. UNBALANCED FAULTS: I learnt that in unbalanced fault symmetrical components are used for the analysis.
Fault analysis is the study of a power system after a fault with the view the purpose for the analyzing the fault
Stability studies: this is the study of a system to know if a system will retain synchronism after perturbation or disturbance.
Types of stability studies
1. Transient 2. Dynamic 3. Steady state
STEPS IN ANALYZING FAULTS
step 1: Write down the terminal conditions
step 2:Simplify the terminal conditions
step 3:Re-write this simplified terminal conditions
step 4:Simplify the resulting expression i.e bringing like terms together.
step 5:Simplify the resulted expression.
step 6:Using three equations to draw the symmetrical component inter connection that will satisfy these equation simultaneously.
Name Okeiji Chukwunonso Kennedy
ReplyDeleteReg ESUT/2012/137613
Dept Electrical and Electronics Engineering
Level 500
Course EEE 554 quiz
Date 31/03/2017
What I have learned so far
1. Fault analysis is the analysis of an electrical system after the occurrence of a fault
TYPES OF FAULT ANALYSIS:
1. BALANCED FAULTS: I learnt that in balanced fault, we simply analyze or solve the single phase equivalent circuit when a fault has affected the whole part of the system.
2. UNBALANCED FAULTS: I learnt that in unbalanced fault symmetrical components are used for the analysis.
LOAD FLOW ANALYSIS is the study of the power system with a view of knowing the voltages at various buses using configuration loading at each buses.
Symmetrical components: These are set balanced phasors which can be used to represent or resolve an unbalanced system of ‘n’ related phasor into ‘n’ systems of balanced phasors. The symmetrical components have both length and angle between them equal.
Types of symmetrical components
1 Positive sequence components
2 Negative sequence components 3. Zero sequence components
TOOLS FOR LOAD FLOW ANALYSIS
1. BUS SYSTEM TOPOLOGY
2. SYSTEM PARAMETERS
THE TWO TYPE OF SYSTEM LOAD FLOW ANALYSIS ARE:
1 NEWTON RAPHSON ITERATIVE METHOD: Newton Raphson method is the method based on Taylor series expansion of a power system, ignoring second derivative and higher derivatives. Error analysis is applied to Taylor series to correct or improve the guess voltage value.
2 GAUSS SEIDEL ITERATIVE METHOD: Gauss Seidel iterative method is based on the algebraic system.
Name Aka Chibundu Henry
ReplyDeleteReg ESUT/2012/137643
Dept Electrical and Electronics Engineering
Level 500
Course EEE 554 quiz
Date 01/04/2017
What I have learned so far
Stability studies: this is the study of a system to know if a system will retain synchronism after perturbation or disturbance.
Types of stability studies
1. Transient 2. Dynamic 3. Steady state
Symmetrical components: These are set balanced phasors which can be used to represent or resolve an unbalanced system of ‘n’ related phasor into ‘n’ systems of balanced phasors. The symmetrical components have both length and angle between them equal.
FAULT ANALYSIS IS: Fault analysis is the study of power system after a fault, with a view of finding the voltages and currents distribution.
THERE ARE TWO MAIN TYPES OF FAULT ANALYSIS NAMELY:
1. BALANCED FAULTS: I learnt that in balanced fault, we simply analyze or solve the single phase equivalent circuit when a fault has affected the whole part of the system.
2. UNBALANCED FAULTS: I learnt that in unbalanced fault symmetrical components are used for the analysis.
TYPES OF STABILITY STUDIES.
DYNAMIC
STEADY STATE AND TRANSIENT .
STEPS IN ANALYZING FAULTS
step 1: Write down the terminal conditions
step 2:Simplify the terminal conditions
step 3:Re-write this simplified terminal conditions
step 4:Simplify the resulting expression i.e bringing like terms together.
step 5:Simplify the resulted expression.
step 6:Using three equations to draw the symmetrical component inter connection that will satisfy these equation simultaneously.