Design Power Electronic Basic
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       Video Length : 8h00m12s
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       Tasks Number : 42
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       Students Enrolled : 91
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Authors

Kevin Gautama is a systems design and programming engineer with 16 years of expertise in the fields of electrical and electronics and information technology.

He teaches at the Hanoi University of Industry in the period 2003-2011 and he has a certificate of vocational training by the Ministry of Industry and Commerce and the Hanoi University of Industry.

From extensive design experience through numerous engineering projects, the author founded the Enziin Academy.

The Enziin Academy is a startup in the field of educational, it's core goal is to training design engineers in the fields technology related.

The Enziin Academy is headquartered in Stockholm-Sweden with an orientation operating multi-lingual and global.

The author's skills in IT:

  • Implementing the application infrastructure on Amazon's cloud computing platform.
  • Linux server system administration (Sysadmin).
  • Design load balancing and content distribution system.
  • MySQL database administration.
  • C/C++/C# Programming
  • Ruby and Ruby on Rails Programming
  • Python and Django Programming
  • The WPF/C# on the .NET Framework Programming
  • The PHP/JAVA Programming
  • Machine Learning and Expert System.
  • Internet of Things.

The author's skills in the fields of electric and electronic:

  • The design of popular CPU / MCU systems.
  • Design FPGA / CPLD system (Xilinx - Altera).
  • Design and programming of DSP systems (Texas Instruments).
  • Embedded ARM system design.
  • The RTOS Programming
  • Design and programming electronic power systems.
  • PLC - inverter - sensor - electric control cabinet industrial.
  • Control systems distributed connection with Server.

Read more...

  • Curriculum
  • 1. Introduction
    • videocam
      The tasks to do in this course

      11m26s
    • videocam
      Power semiconductor components

      11m26s
    • videocam
      The driver methods

      11m26s
  • 2. Rectifier and varistor in AC
    • videocam
      Rectifiers using Thyristor

      11m26s
    • videocam
      Rectifiers using MOSFET/IGBT

      11m26s
    • videocam
      Varistor using Triac/Thyristor

      11m26s
    • videocam
      Designing rectifier controller

      11m26s
  • 3. The DC-DC Converter
    • videocam
      The Buck converter

      11m26s
    • videocam
      The Boost converter

      11m26s
    • videocam
      The Flyback converter

      11m26s
    • videocam
      The Hybrid converters

      11m26s
    • videocam
      The Forward/Pushpull converter

      11m26s
    • videocam
      The Half/Full-Bridge converter

      11m26s
    • videocam
      Power factor correction PFC

      11m26s
  • 4. The DC-AC Converter
    • videocam
      Pulse Width Modulation PWM

      11m26s
    • videocam
      The DC-AC Inverter converter

      11m26s
  • 5. Soft Magnetic Materials
    • videocam
      Theory of soft magnetic materials

      11m26s
    • videocam
      Classification and selection of materials

      11m26s
  • 6. Designing Rectifier Controller
    • videocam
      Analyze the requirements of the project

      11m26s
    • videocam
      Voltage synchronization controller

      11m26s
    • videocam
      The group pulses generator

      11m26s
    • videocam
      Power pulse amplifier

      11m26s
  • 7. The Flyback power supply
    • videocam
      Analyze the requirements

      11m26s
    • videocam
      Input EMI filter and rectifier

      11m26s
    • videocam
      The Flyback controller

      11m26s
    • videocam
      Design of flyback coils

      11m26s
    • videocam
      Output rectifier and feedback

      11m26s
  • 8. The DC Digital Power Supply
    • videocam
      Analyze the requirements

      11m26s
    • videocam
      Input EMI filter and rectifier

      11m26s
    • videocam
      Design APFC

      11m26s
    • videocam
      Calculating parameters of pulse transformer

      11m26s
    • videocam
      The output rectifier controller

      11m26s
    • videocam
      Center controller and measurement

      11m26s
  • 9. The DC-AC Inverter
    • videocam
      Analyze the requirements

      11m26s
    • videocam
      Design the voltage boost

      11m26s
    • videocam
      Design inverter controller

      11m26s
    • videocam
      Design output filter and protect

      11m26s
  • 10. Solar Power Inverter
    • videocam
      Analyze the requirements

      11m26s
    • videocam
      Design the voltage boost

      11m26s
    • videocam
      Design battery charger

      11m26s
    • videocam
      Design inverter and sync grid AC

      11m26s
    • videocam
      Design center controller

      11m26s
Coverpowerelectronic
Design Power Electronic Basic


Note: This is a module belongs to the classes, billing features separate for this module will be allowed if the content matches. The classes using this module are listed below.

Power electronics is the application of solid-state electronics to the control and conversion of electric power. The first high power electronic devices were mercury-arc valves.

In modern systems the conversion is performed with semiconductor switching devices such as diodes, thyristors and transistors.

In contrast to electronic systems concerned with transmission and processing of signals and data, in power electronics substantial amounts of electrical energy are processed.

An AC/DC converter (rectifier) is the most typical power electronics device found in many consumer electronic devices, e.g. television sets, personal computers, battery chargers, etc.

The power range is typically from tens of watts to several hundred watts. In industry a common application is the variable speed drive (VSD) that is used to control an induction motor. The power range of VSDs start from a few hundred watts and end at tens of megawatts.

The power conversion systems can be classified according to the type of the input and output power

  • AC to DC (rectifier)
  • DC to AC (inverter)
  • DC to DC (DC-to-DC converter)
  • AC to AC (AC-to-AC converter)

DC to AC converters produce an AC output waveform from a DC source. Applications include adjustable speed drives (ASD), uninterruptible power supplies (UPS), Flexible AC transmission systems (FACTS), voltage compensators, and photovoltaic inverters.

Table of Content

1. Introduction

  • The tasks to do in this course
  • Power semiconductor components
  • The driver methods

2. Rectifier and varistor in AC

  • Rectifiers using Thyristor
  • Rectifiers using MOSFET/IGBT
  • Varistor using Triac/Thyristor
  • Designing rectifier controller

3. The DC-DC Converter

  • The Buck converter
  • The Boost converter
  • The Flyback converter
  • The Hybrid converters
  • The Forward/Pushpull converter
  • The Half/Full-Bridge converter
  • Power factor correction PFC

4. The DC-AC Converter

  • Pulse Width Modulation PWM
  • The DC-AC Inverter converter

5. Soft Magnetic Materials

  • Theory of soft magnetic materials
  • Classification and selection of materials

6. Designing Rectifier Controller

  • Analyze the requirements of the project
  • Voltage synchronization controller
  • The group pulses generator
  • Power pulse amplifier

7. The Flyback power supply

  • Analyze the requirements
  • Input EMI filter and rectifier
  • The Flyback controller
  • Design of flyback coils
  • Output rectifier and feedback

8. The DC Digital Power Supply

  • Analyze the requirements
  • Input EMI filter and rectifier
  • Design APFC
  • Calculating parameters of pulse transformer
  • The output rectifier controller
  • Center controller and measurement

9. The DC-AC Inverter

  • Analyze the requirements
  • Design the voltage boost
  • Design inverter controller
  • Design output filter and protect
  • 10. Solar Power Inverter
  • Analyze the requirements
  • Design the voltage boost
  • Design battery charger
  • Design inverter and sync grid AC
  • Design center controller