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Ultimate Power Electronics and Electrical Protection Course

Learn about power electronics, electrical protection, and the PLC simulator (LogixPro) for electrical engineering

Provided by Khadija Academy

Summary

Price
£89.99 inc VAT
Or £30.00/mo. for 3 months...
Study method
Online, On Demand What's this?
Duration
51.4 hours · Self-paced
Qualification
No formal qualification
Certificates
  • Reed courses certificate of completion - Free
Additional info
  • Tutor is available to students
1 student purchased this course

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Overview

"Ultimate Power Electronics and Electrical Protection Course"

This magnificent 50-hour course will help you have a kick start in power electronics including rectifiers, AC choppers, DC choppers, and inverters. In addition to the basics of electrical protection such as overcurrent protection, differential protection, distance protection, circuit breakers, and fuses.

Certificates

Reed courses certificate of completion

Digital certificate - Included

Will be downloadable when all lectures have been completed

Curriculum

16
sections
234
lectures
51h 24m
total

    • 1: Ultimate Power Electronics and Protection Course Content 07:17
    • 2: Course Slides 30:00 PDF

    • 3: Introduction to Power Electronics 20:14
    • 4: A Power Electronic Circuit 06:29
    • 5: PN Junction 15:14
    • 6: Diodes in Power Electronics 21:40
    • 7: Types of Power Diodes 12:51
    • 8: Thyristors in Power Electronics 22:37
    • 9: Thyristor Mode of Operation 09:07
    • 10: Natural and Forced Commutation 16:11
    • 11: Types of Thyristors 11:33
    • 12: Bipolar Junction Transistor (BJT) 31:16
    • 13: Gate Turn-Off Thyristor (GTO) 17:51
    • 14: Metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET) 33:13
    • 15: Insulated Gate Bipolar Transistor (IGBT) 16:08
    • 16: Types of Switches 04:50
    • 17: Comparison between Controlled Switches 05:00
    • 18: Power Switch Losses 04:58

    • 19: Introduction to Rectifiers 07:12
    • 20: Single Phase Half-Wave Uncontrolled Rectifiers – R Load 19:23
    • 21: Understanding the Difference between AC and DC Powers 10:41
    • 22: Example 1 08:01
    • 23: Ripple Factor of Half-Wave Rectifier 13:47
    • 24: Efficiency of Half-Wave Rectifier 08:42
    • 25: Form Factor, PIV, and Peak Factor of Half-Wave Rectifier 08:40
    • 26: Example 2 09:38
    • 27: Single Phase Half-Wave Uncontrolled Rectifiers – RL Load 30:47
    • 28: Example 3 08:55
    • 29: How to Solve Numerical Equations Using Calculator 06:40
    • 30: R-L Load with Freewheeling Diode 13:00
    • 31: Example 4 03:26
    • 32: Single Phase Half-Wave Controlled Rectifiers – R Load 17:57
    • 33: Example 5 01:36
    • 34: Example 6 05:08
    • 35: Single Phase Half-Wave Controlled Rectifiers – RL Load 18:27
    • 36: Example 7 04:51
    • 37: Half-Wave Controlled Rectifiers – RL Load with FWD 28:03
    • 38: Example 8 15:55
    • 39: Example 9 08:39
    • 40: Half-Wave Controlled Rectifiers – RLE Load 33:13
    • 41: Example 10 12:21
    • 42: Example 11 06:07

    • 43: Full-Wave Bridge Uncontrolled Rectifier – R Load 32:59
    • 44: Example 1 07:58
    • 45: Full-Wave Bridge Uncontrolled Rectifier – RL Load 13:25
    • 46: Example 2 07:56
    • 47: Full Wave Center-Tapped Uncontrolled Rectifier 26:14
    • 48: Full-Wave Controlled Rectifier – R Load 14:22
    • 49: Example 3 08:07
    • 50: Full-Wave Controlled Rectifier – RL Load – Discontinuous Mode 11:21
    • 51: Example 4 05:35
    • 52: Full-Wave Controlled Rectifier – RL Load – Continuous Mode 24:33
    • 53: Example 5 10:36
    • 54: Example 6 05:51
    • 55: Example 7 04:48
    • 56: Half-Controlled Bridge Rectifier – Type 1 36:47
    • 57: Half-Controlled Bridge Rectifier – Type 2 18:42
    • 58: Example 8 05:46
    • 59: Example 9 04:52

    • 60: Three-Phase Rectifiers 06:42
    • 61: Three-Phase Half-Wave Uncontrolled Rectifier – R Load 37:09
    • 62: Equations of Three-Phase Half-Wave Uncontrolled Rectifiers 23:25
    • 63: Three-Phase Half-Wave Uncontrolled Rectifiers - HIL 08:35
    • 64: Example 1 10:37
    • 65: Three-Phase Mid-Point 6-Pulse Diode Rectifier 28:13
    • 66: Multiphase Diode Rectifier 11:15
    • 67: Example 2 12:38
    • 68: Example 3 02:56
    • 69: Three-Phase Half-Wave Controlled Rectifier 27:30
    • 70: Example 4 05:47
    • 71: Evolution of the Three-Phase Bridge-Wave Uncontrolled Rectifier 24:51
    • 72: Three-Phase Bridge-Wave Uncontrolled Rectifier 29:37
    • 73: Example 5 08:13
    • 74: Example 6 12:51
    • 75: Example 7 04:24
    • 76: Three-Phase Twelve-Pulse Rectifier 24:44
    • 77: Three-Phase Bridge-Wave Fully-Controlled Rectifier - HIL 34:10
    • 78: Three-Phase Bridge-Wave Fully-Controlled Rectifier – R Load 09:50
    • 79: Example 8 04:17
    • 80: Example 9 08:36
    • 81: Three-Phase Bridge-Wave Half(Semi)-Controlled Rectifier – HIL Load 26:57
    • 82: Example 10 02:24
    • 83: Example 11 11:29

    • 84: Introduction to AC Choppers 02:20
    • 85: Definition of AC Chopper 05:15
    • 86: Switching Techniques in AC Choppers 05:56
    • 87: Applications on AC Choppers 03:11
    • 88: Types of AC Choppers 02:26
    • 89: AC Chopper with R Load 14:13
    • 90: Example 1 on AC Chopper with R Load 05:56
    • 91: Example 2 on AC Chopper with R Load 04:00
    • 92: AC Chopper with L Load Part 1 12:47
    • 93: AC Chopper with L Load Part 2 06:12
    • 94: Example on AC Chopper with L Load 08:02
    • 95: AC Chopper with RL Series Load 19:59
    • 96: Example on AC Chopper with RL Series Load 07:28
    • 97: AC Chopper with RL Parallel Load 24:33
    • 98: Example on AC Chopper with RL Parallel Load 05:43
    • 99: AC Chopper with Pure Capacitive Load 14:17
    • 100: Example on AC Chopper with Pure Capacitive Load 04:23
    • 101: AC Chopper Loaded by Heavy Rectifier 05:41
    • 102: AC Chopper Loaded by an AC Motor with Sinusoidal Back Emf 12:28
    • 103: Example on AC Chopper Loaded by an AC Motor with Sinusoidal Back Emf 08:17
    • 104: Integral Cycle Control 11:04
    • 105: Example on Integral Cycle Control 04:18

    • 106: Introduction to DC Choppers 02:11
    • 107: Definition and Applications of DC Choppers 04:35
    • 108: Step down DC Chopper with R Load 12:05
    • 109: Example on Step Down DC Chopper with R Load 08:28
    • 110: Generation of Duty Cycle 09:18
    • 111: Switching Techniques 03:08
    • 112: Step down DC Chopper with RLE Load Part 1 19:22
    • 113: Step down DC Chopper with RLE Load Part 2 14:46
    • 114: Example 1 on Step down DC Chopper with RLE Load 13:29
    • 115: Example 2 on Step down DC Chopper with RLE Load 02:02
    • 116: Step up DC Chopper with R or RL Load 08:50
    • 117: Step up DC Chopper with RE Load 14:58
    • 118: Example on Step up DC Chopper with RE Load 19:53
    • 119: Buck Regulator Part 1 16:18
    • 120: Buck Regulator Part 2 16:47
    • 121: Example on Buck Regulator 03:13
    • 122: Boost Regulator 23:07
    • 123: Example on Boost Regulator 05:43
    • 124: Buck-Boost Converter 17:28
    • 125: Example on Buck-Boost Converter 04:34

    • 126: Introduction to Inverters 02:16
    • 127: Definition of Inverter 03:33
    • 128: Importance and Applications of Inverters 08:29
    • 129: Single Phase Half Bridge R-Load 15:28
    • 130: Single Phase Half Bridge RL-Load 08:13
    • 131: Performance Parameters of an Inverter 04:49
    • 132: Example on Single Phase Half Bridge 10:22
    • 133: Single Phase Bridge Inverter R-Load 05:40
    • 134: Single Phase Bridge Inverter RL-Load 06:55
    • 135: Example on Single Phase Bridge Inverter 06:08
    • 136: Three Phase Inverters and Obtaining The Line Voltages 14:50
    • 137: Three Phase Inverters and Obtaining The Phase Voltages 16:57
    • 138: Example on Three Phase Inverters 16:10
    • 139: Single Pulse Width Modulation 13:20
    • 140: Multiple Pulse Width Modulation 12:53
    • 141: Example on Multiple Pulse Width Modulation 04:25
    • 142: Sinusoidal Pulse Width Modulation 16:28
    • 143: Industrial Inverter 03:15

    • 144: Simulation of Half Wave Controlled Rectifier in MATLAB 25:33
    • 145: Simulation of Bridge Controlled Rectifier in MATLAB 16:18
    • 146: Simulation of AC Chopper with R and RL Loads 10:46
    • 147: Simulation of Buck Regulator in MATLAB 14:05
    • 148: Simulation of Boost Regulator in MATLAB 12:11
    • 149: Simulation of Buck-Boost Regulator in MATLAB 09:22
    • 150: Simulation of Single Phase Half Bridge Inverter in MATLAB 17:30
    • 151: Simulation of Single Phase Bridge Inverter 09:53
    • 152: Simulation of Three Phase Inverter in MATLAB 17:03

    • 153: Introduction to Protection of Electrical Power System 16:40
    • 154: Components of Protection System, Trip Circuit and Zones of Protection 22:11
    • 155: Primary and Backup Protection 19:15
    • 156: Characteristics of Measuring Relay Performance 20:21
    • 157: Fault Clearing Time and Time Lag 16:07
    • 158: Types of Relays and Electromagnetic Relays 28:20
    • 159: Directional Power Relay and It's Applications 25:11

    • 160: Introduction to Overcurrent Protection 16:58
    • 161: Settings of Overcurrent Relay and Applications of Overcurrent Relay 16:51
    • 162: Overcurrent Relay - Solved Example 1 05:41
    • 163: Overcurrent Relay - Solved Example 2 10:17

    • 164: Introduction to Distance Protection 06:28
    • 165: Construction and Operation of Distance Relay 14:59
    • 166: Plain Impedance Relay 12:41
    • 167: Operating Characteristics and R-X Diagram of an Impedance Relay 10:37
    • 168: Stepped Distance Protection 13:43
    • 169: Solved Example 1 on Stepped Distance Protection 13:19
    • 170: Solved Example 2 on Stepped Distance Protection 18:22
    • 171: Transmission Line Protection and Directional Impedance Relay 32:16
    • 172: Modified Impedance - Type Distance Relay 04:22
    • 173: Reactance -Type Distance Relay 14:41
    • 174: Mho or Admittance Distance Relay 11:17

    • 175: Introduction to Differential Protection 06:29
    • 176: Current Balance Differential Protection 16:18
    • 177: Voltage Balance Differential Protection 08:18
    • 178: Percentage Differential Current Relay 18:49
    • 179: Solved Example 1 05:30
    • 180: Solved Example 2 11:05

    • 181: Principle of Operation and Selection of Low Voltage Circuit Breakers 25:50
    • 182: Principle of Operation of Earth Leakage Circuit Breaker 12:09
    • 183: Selection of Medium Voltage Circuit Breakers 15:49
    • 184: Types of Low Voltage and High Voltage Fuses 18:46

    • 185: Introduction to ETAP Course 15:16
    • 186: Drawing Single Line Diagram in ETAP 11:34
    • 187: Adding Ratings to Components in ETAP 21:33
    • 188: Load Flow and Types of Buses 05:28
    • 189: Load Flow Analysis Using ETAP 19:02
    • 190: Load Flow Analysis at Different Loading Categories 08:31
    • 191: Short Circuit Analysis Using ETAP 14:09
    • 192: Arc Flash Studies 16:03
    • 193: Arc Flash Studies Using ETAP Program 17:05
    • 194: Transient Stability Using ETAP 18 23:18
    • 195: Definition of Harmonics 22:44
    • 196: Harmonic Analysis Using ETAP 22:58
    • 197: Harmonic Filter Using ETAP 13:52
    • 198: PV System Simulation Using ETAP 24:27
    • 199: ETAP Motor Acceleration Analysis - Static Motor Starting 16:33
    • 200: ETAP Motor Acceleration Analysis - Dynamic Motor Starting 11:33
    • 201: How to add a Starting Method to Motor in ETAP 09:43
    • 202: VFD - Variable Frequency Drive Control of Motor in ETAP 09:15

    • 203: Introduction to This Course 02:04
    • 204: What Is LogixPro? 04:08
    • 205: Overview on PLC 33:45
    • 206: Important Symbols 05:16
    • 207: Normally Opened, Normally Closed and Output Coils in Ladder Diagram 14:16
    • 208: Start-Stop Circuit 16:35
    • 209: Task 1 in Batch Simulator 11:52
    • 210: Task 2 in Batch Simulator 11:29
    • 211: Task 1 in Door Simulator 13:14
    • 212: Scan Cycle and Markers 09:55
    • 213: Task 3 in Batch Simulator Part 1 14:07
    • 214: Task 3 in Batch Simulator Part 2 10:57
    • 215: Task 4 in Batch Simulator Part 1 12:58
    • 216: Task 4 in Batch Simulator Part 2 09:05
    • 217: Latched and Unlatched Output in Ladder Diagram 06:16
    • 218: Task 5 in Batch Simulator 15:23
    • 219: Task 6 in Batch Simulator Part 1 13:29
    • 220: Task 6 in Batch Simulator Part 2 12:07
    • 221: Timers in PLC 12:21
    • 222: Task 2 in I/O Simulator 07:36
    • 223: Task 3 in I/O Simulator 09:05
    • 224: Task 4 in I/O Simulator 07:51
    • 225: Task 7 in Batch Simulator Part 1 26:38
    • 226: Task 7 in Batch Simulator Part 2 05:59
    • 227: Counters in PLC 04:46
    • 228: Task 5 in I/O Simulator 14:42
    • 229: Task 1 in Silo Simulator 23:01
    • 230: Task 6 in I/O Simulator 08:45
    • 231: Task 7 in I/O Simulator 08:23
    • 232: Task 2 in Door Simulator 12:09
    • 233: Task 8 in Batch Simulator Part 1 25:21
    • 234: Task 8 in Batch Simulator Part 2 11:17

Course media

Description

Throughout the power electronics course, you will learn:

  • The applications of power electronics and the definition of a power electronic circuit.

  • Different types of switches such as diodes, thyristors, GTO, BJT, IGBT, Mosfet, etc.

  • The different AC/DC converters (rectifiers) such as half-wave and full-wave rectifier single-phase circuits in uncontrolled, half, and fully controlled bridges. In addition to the different three-phase rectifier circuits.

  • AC chopper circuits or AC/AC converters in the case of R load, L load, RL parallel, RL series load, and capacitive loads. In addition to the integral cycle control of an AC chopper.

  • DC choppers or DC/DC converters such as the step-down DC chopper with R and R-L-E load, and the step-up DC chopper with R, RL, and RE loads. Moreover, the buck, boost, and buck-boost regulator circuits.

  • Inverter or DC/AC converters including single-phase half-bridge R-load, single-phase half-bridge RL-load, single-phase bridge inverter R-load, single-phase bridge inverter RL-load, and the three-phase inverters. Furthermore, the single, multiple, and sinusoidal pulse width modulations.

You will learn also the simulation using the MATLAB Simulink program:

  • Single-phase half-wave controlled and bridge-controlled rectifiers.

  • Single-phase AC chopper with R and RL load

  • DC-DC converters such as buck, boost, and buck-boost regulators.

  • Single-phase half-bridge, bridge inverters, and three-phase inverters.

Throughout the electrical protection course, you will learn:

  • The different components of the electrical protection system, zones of protection, the trip circuit of the electrical system, the primary and backup protection, and the fault clearing time.

  • The different types of relays such as directional power relays, overcurrent relays, distance relays, plain impedance relays, directional impedance relays, modified impedance-type distance relays, reactance-type distance relays, Mho or admittance distance relays, and more.

  • The principle of operation and selection of low-voltage circuit breakers

  • The principle of operation of earth leakage circuit breaker or residual current CB

  • The selection of medium voltage circuit breakers

  • The types of low voltage and high voltage fuses

In addition to the LogixPro course:

This is the only course out there that can teach you the basics of PLC programming with fun and awesome simulations.

Logixpro program is an interesting and useful simulator for the simulation of different procedures such as moving belts, garage openings, and closing, a mixer that consists of a tank in addition to some pipes of different liquids, and many more!

This program helps learn ladder programming and PLC with an easy and interactive simulation method.

Take this bundle if you've been looking for ONE COURSE BUNDLE with in-depth insight into power electronics, electrical protection, ETAP, and PLC basics.

Who is this course for?

  • Anyone who is interested in understanding power electronics.
  • This bundle is designed for complete beginners with zero knowledge of power electronics.
  • Electrical engineers who want to learn about power electronics.
  • Students who want to learn about power electronics.
  • Anyone who wants to know about different converters and how rectifiers work in power electronics.
  • Beginner course for electrical engineering students and for those who want to gain knowledge about AC Choppers in power electronics.
  • Electrical engineers and electrical power engineering students who want to learn about DC choppers in power electronics.
  • Electrical engineers or electrical power electronics students who want to learn more about inverters in power electronics.
  • Anyone who wants to learn about electrical protection.
  • Anyone who wants to learn about the LogixPro simulator that helps in learning about PLC.

Requirements

  • Basics of electric circuits.

  • Passion to learn!

Questions and answers

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Provider

Khadija Academy

Khadija Academy was founded by engineer Ahmed Mahdy who is an electrical power engineer and a researcher. He is also an electrical bestselling instructor at more than 30 platforms, teaching electrical engineering, and has helped more than 80,000 students from 198 countries achieve career success with simple and easy courses.​ He is currently the top-ranked (1st) in the engineering sector of Udemy. 

He had received the award for the best master's thesis in the Faculty of Engineering - Ain Shams University for 2022/2023.


Some of his published research works in the top electrical engineering journals worldwide:


1- ​Transient stability improvement of wave energy conversion systems connected to power grid using anti-windup-coot optimization strategy - Energy Journal - Impact Factor of 9.0.


2-  Nonlinear Modeling and Real-Time Simulation of a Grid-Connected AWS Wave Energy Conversion System - IEEE Transactions on Sustainable Energy - Impact Factor of 8.8.


3- Modeling and optimal operation of hybrid wave energy and PV system feeding supercharging stations based on golden jackal optimal control strategy -  Energy Journal - Impact Factor of 9.​0.


4- State-of-the-Art of the most commonly adopted wave energy conversion systems - Ain Shams Engineering Journal - Impact Factor of 6.0.


5- Optimal Design of Fractional-Order PID Controllers for a Nonlinear AWS Wave Energy Converter Using Hybrid Jellyfish Search and Particle Swarm Optimization - Fractal and Fractional - Impact Factor of 5.4


6- Dynamic performance enhancement of nonlinear AWS wave energy systems based on optimal super-twisting control strategy - Ain Shams Engineering Journal - Impact Factor of 6.0.

 

View Khadija Academy profile

Legal information

This course is advertised on Reed.co.uk by the Course Provider, whose terms and conditions apply. Purchases are made directly from the Course Provider, and as such, content and materials are supplied by the Course Provider directly. Reed is acting as agent and not reseller in relation to this course. Reed's only responsibility is to facilitate your payment for the course. It is your responsibility to review and agree to the Course Provider's terms and conditions and satisfy yourself as to the suitability of the course you intend to purchase. Reed will not have any responsibility for the content of the course and/or associated materials.

FAQs

Study method describes the format in which the course will be delivered. At Reed Courses, courses are delivered in a number of ways, including online courses, where the course content can be accessed online remotely, and classroom courses, where courses are delivered in person at a classroom venue.

CPD stands for Continuing Professional Development. If you work in certain professions or for certain companies, your employer may require you to complete a number of CPD hours or points, per year. You can find a range of CPD courses on Reed Courses, many of which can be completed online.

A regulated qualification is delivered by a learning institution which is regulated by a government body. In England, the government body which regulates courses is Ofqual. Ofqual regulated qualifications sit on the Regulated Qualifications Framework (RQF), which can help students understand how different qualifications in different fields compare to each other. The framework also helps students to understand what qualifications they need to progress towards a higher learning goal, such as a university degree or equivalent higher education award.

An endorsed course is a skills based course which has been checked over and approved by an independent awarding body. Endorsed courses are not regulated so do not result in a qualification - however, the student can usually purchase a certificate showing the awarding body's logo if they wish. Certain awarding bodies - such as Quality Licence Scheme and TQUK - have developed endorsement schemes as a way to help students select the best skills based courses for them.
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