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TRAINING FUEL CELL POWER CONDITIONING SYSTEMS

TRAINING ADVANCED FUEL CELL POWER CONDITIONING SYSTEMS

TRAINING SISTEM PENGKONDISI TENANGA BAHAN BAKAR

TRAINING SISTEM PENGKODISIAN TENAGA

TRAINING FUEL CELL POWER CONDITIONING SYSTEMS

COURSE DESCRIPTION:

Power conditioning is the enabling technology necessary for interfacing various distributed generator (DG) systems to electric utility and to power stand-alone loads. Power semiconductor devices are examined from an application perspective. After examining the basic conversion blocks, the course delves into suitable power conversion architectures (topologies). Examples include: (a) Fuel Cell power conversion system with battery/super-capacitor type energy storage for powering stand-alone residential loads with an option to interface to electric utility; (b) Power conversion architectures for a high speed gas turbine (microturbine) type DG; (c) Suitable converters for fuel cell turbine hybrid will also be considered.

Power electronics is an enabling technology for almost all electrical applications. The field is growing rapidly because electrical devices need electronic circuits to process their energy. Elements of Power Electronics, the first book to discuss this subject in a conceptual framework, provides comprehensive coverage of power electronics at a level suitable for novices in the field. It aims to establish a fundamental engineering basis for power electronics analysis, design, and implementation. More than 160 examples and 350 chapter problems support the presented concepts.

OUTLINE:

To study in-depth fundamentals of modern power conditioning approaches (topologies) suitable for fuel cell powered systems, for stand-alone and/or utility interface.

Unit 1: Introduction to Fuel Cell Power Conditioning
* System configurations

1.  Fuel cell power source for standalone system applications
2.  Fuel cell power source for utility intertie applications
3. Microturbine or gas turbine power source system configuration
4. Hybrid fuel cell with microturbine system configuration

* Example systems and their features

1.  Individual components in the example systems
2. Specifications

* Overview of power converters and two-day course contents

Unit 2: Multiple-Switches DC-DC Converters with Isolation
* Half-Bridge Converter

1. PWM and converter operating modes
2. Discussion of voltage and current waveforms

* Push-Pull Bridge Converter

1.  PWM and converter operating modes
2.  Discussion of voltage and current waveforms

* Full Bridge Converter

1. PWM and output voltage relationship
2. Discussion of voltage and current waveforms with PWM
3.  Phase-shift-modulation (PSM) Method
4.  Discussion of voltage and current waveform with PSM

Unit 3: Isolated DC-DC Converter Controller Design Example
* Full-bridge (or Flyback) Converter Design Example

1. Power stage design with device and component selection
2. Construction of open-loop transfer function

* Current- and Voltage-Loop Controllers Design

1.  Compensator design
2.  Bode plots for stability test
3.  Closed-loop responses

* Realization of Compensator Circuit

1.  PI compensator realization with op amp circuits
2.  PID compensator realization with op amp circuits

* Commercial-IC Controllers

1.  Complete circuit diagram for the design example
2. Simulation (and/or) experimental results

Unit 4: Design of Single-Phase DC-AC Inverters
* Power Stage Design

1. DC bus voltage requirement
2. Power device ratings
3. DC bus capacitor requirement
4. Power bus bar requirement
5. Design example

* PWM Switching Design

1. Complementary PWM technique in full-bridge inverter
2. Dead time requirement
3. Short-pulse elimination requirement
4. Design example

* Output Filter Design

1. Sizing ac filter inductor and capacitor
2. Design example

Unit 5: Fuel-Cell Powered System with Single-Phase AC Output Loads
* System Architectures

1.  Isolation requirement and options
2. Low-voltage energy storage design method
3.  High-voltage energy storage design method

* Critical Evaluation of DC-DC converter options

1.  Device voltage and current requirements
2.  Matrix comparison of dc-dc converters for fuel cell source

* Critical Evaluation of DC-AC converter options

1. Device voltage and current requirement
2.  Matrix comparison of dc-ac inverters for single-phase outputs

Unit 6: Design of a 10-kW Design Example with 48-V DC Input and 120/240 V AC Output
* Inverter Circuit Topologies Dealing with Unbalanced Loads

1. Two full-bridge inverters
2. Two half-bridge inverters
3. Three-leg inverter

* Power stage design

1.  Power device voltage and current ratings
2.  Passive component voltage and current ratings

* Sensor and Sensor Conditioning

1. Voltage and current sensors
2.  Temperature sensors
3.  Signal conditioning and scaling

* Controller Implementation

1.  Analog implementation
2.  Digital signal processor (DSP) and Interface
3.  Communication with fuel cell controller

Unit 7: Microturbine Power Conversion Systems
* System Architecture of microturbine

1.  Block diagrams of microturbine systems
2.  Electronic actuator and hydraulic controllers
3.  Three-phase or multi-phase permanent magnet (PM) generators
4. Three-phase ac output with and without power electronics

* Generator Output AC-DC Stage Rectification

1. Three-phase diode rectifier for ac-dc rectification
2. Three-phase active-front-end rectification

* DC-AC Inverter for Standalone and Utility Interconnects

1.  Three-phase diode rectifier for ac-dc rectification
2. Three-phase active-front-end rectifier

OBJECTIVE

Completion of this course will provide participants with both a review of and discussion of the specific design issues most likely to be encountered in designing Power Conditioning systems for fuel cell, microturbine, and hybrid Distributed Generation power plants. Understanding these issues will allow the participants to properly address them with the most appropriate cost-effective technical solutions.

Instructor :

Dr. Yulianto ST. MT. And Tim

Expert in Electrical Engineering and Building Maintenance.

Jadwal pelatihan trainingmekatronika.com tahun 2024 :

  • Batch 1 : 03 – 04 Januari 2024 | 16 – 17 Januari 2024
  • Batch 2 : 07 – 08 Februari 2024 | 20 – 21 Februari 2024
  • Batch 3 : 05 – 06 Maret 2024 | 19 – 20 Maret 2024
  • Batch 4 : 09 – 10 April 2024 | 13 – 24 April 2024
  • Batch 5 : 07 – 08 Mei 2024 | 22 – 23 Mei 2024
  • Batch 6 : 05 – 06 Juni 2024 | 25 – 29 Juni 2024
  • Batch 7 : 09 – 10 Juli 2024 | 23 – 24 Juli 2024
  • Batch 8 : 06 – 07 Agustus 2024 | 20 – 21 Agustus 2024
  • Batch 9 : 04 – 05 September 2024 | 18 – 19 September 2024
  • Batch 10 : 18 – 19 Oktober 2024 | 15 – 16 Oktober 2024
  • Batch 11 :06 – 07 November 2024 | 26 – 27 November 2024
  • Batch 12 : 04 – 05 Desember 2024 | 18 – 19 Desember 2024

Catatan : Jadwal tersebut dapat disesuaikan dengan kebutuhan calon peserta training power conditioning system pasti jalan

Invetasi dan Lokasi pelatihan sistem pengkodisian tenaga di jakarta :

· Yogyakarta,

· Jakarta,

· Bandung,

· Bali,

· Surabaya,

· Lombok,

Catatan : Apabila perusahaan membutuhkan paket in house training, anggaran investasi pelatihan dapat menyesuaikan dengan anggaran perusahaan.

Fasilitas  pelatihan power conditioning system di jakarta :

  • FREE Airport pickup service (Gratis Antar jemput Hotel/Bandara/Stasiun/Terminal)
  • FREE Akomodasi ke tempat pelatihan bagi peserta training sistem pengkodisian tenaga jakarta pasti running
  • Module / Handout training sistem pengkondisi tenanga bahan bakar jakarta fixed running
  • FREE Flashdisk
  • Sertifikat training advanced fuel cell power conditioning systems di jakarta murah
  • FREE Bag or bagpackers (Tas Training)
  • Training Kit (Dokumentasi photo, Blocknote, ATK, etc)
  • 2xCoffe Break & 1 Lunch, Dinner
  • FREE Souvenir Exclusive
  • Training room full AC and Multimedia

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