DESIGN, OPTIMIZATION AND CONTROL OF STAND-ALONE POWER SYSTEMS USING RENEWABLE ENERGY SOURCES AND HYDROGEN PRODUCTION

DESIGN, OPTIMIZATION AND CONTROL OF STAND-ALONE POWER SYSTEMS USING RENEWABLE ENERGY SOURCES AND HYDROGEN PRODUCTION

LIBRARY OF CONGRESS CATALOGING-IN-PUBLICATION DATA

CONTENTS

PREFACE

Chapter 1: SYSTEM OPERATING PRINCIPLES

1.1. INTRODUCTION

1.2. POWER SYSTEM DESCRIPTION

1.2.1. Photovoltaic System

1.2.2. Wind Generators

1.2.3. Batteries

1.2.4. Electrolyzers

Alkaline Electrolyzers

PEM Electrolyzers

1.2.5. Hydrogen Storage

Hydrogen Storage at High-Pressure

1.2.6. Fuel Cells

1.2.7. Power Electronic Converters

REFERENCES

Chapter 2: MATHEMATICAL MODELS

2.1. GENERAL MODELING PRINCIPLES

2.2. PHOTOVOLTAIC SYSTEM

2.3. WIND TURBINE

2.4. LEAD ACID ACCUMULATOR

2.5. PEM ELECTROLYZER

2.6. HYDROGEN STORAGE

2.7. PEM FUEL CELL

REFERENCES

Chapter 3: SYSTEM INTEGRATION

3.1. INTEGRATED SYSTEM

3.2. OPERATING PRINCIPLES

3.2.1. Description

3.2.2. Main Operating Rules

Rule 1. The Load Demand Should Always be Satisfied

Rule 2. The Electrolyzer and the Fuel Cell Should not Operate Simultaneously

Rule 3. The Electrolyzer and the Fuel Cell Should Operate within the Technical Specifications Set by the Unit Manufacturer

Rule 4. The Accumulator SOC Must be Maintained within Limits

Rule 5. During Power Surplus (State I), an Extra Load can be Attached, Where as During Power Deficit (State II) a Back-Up Power Generation Unit can be Utilized

3.3. POWER MANAGEMENT STRATEGIES

Power Management Strategy 1 (PMS1)

Power Management Strategy 2 (PMS2)

Power Management Strategy 3 (PMS3)

3.4. PARAMETRIC SENSITIVITY STUDIES

Effect of SOCmin

Effect of Load Demand

REFERENCES

Chapter 4: SYSTEM DESIGN AND OPTIMIZATION

4.1. INTRODUCTION

4.2. DESIGN AND OPTIMIZATION OF ENGINEERING SYSTEMS

4.2.1. Conventional and Optimization-Based Design

4.2.2. Generic Optimization-Based Design Framework

Model Development

Design Variables

Objective Function

Constraints

Uncertainty

Optimization Algorithms

4.3. PREVIOUS RESEARCH DEVELOPMENTS IN THE DESIGN OF RES-BASED POWER GENERATION SYSTEMS

4.4. SOURCES OF DESIGN COMPLEXITY

4.4.1. Integration of Sub-Systems

4.4.2. Alternatives for Power Utilization

4.4.3. Uncertain Behavior

4.5. DESIGN AND OPTIMIZATION OF RES-BASED POWER GENERATION SYSTEMS

4.5.1. Problem Formulation

4.5.2. Optimization-Based Design Framework

4.5.3. Incorporation of Uncertainty

4.5.4. Optimization Algorithms

Simulated Annealing

Stochastic Annealing

4.6. DESIGN APPLICATION

4.6.1. Problem Formulation

4.6.2. Design Variables

4.6.3. Uncertain Parameters

4.6.4. Constraints in the Form of a Power Management Strategy

4.6.5. Objective Function

4.6.6. Results and Discussion

REFERENCES

Chapter 5: SYSTEM AUTOMATION AND CONTROL

5.1. INFRASTRUCTURE AND SUBSYSTEMS

5.1.1. Interaction of Components and System Architecture

5.1.2. Basic Technical Data

5.1.3. System Integration

5.1.3.1 Electrical System

Photovoltaic (PV) Panels

Wind Generators (WG)

Battery

DC/AC Converters (Inverters)

5.1.3.2. Electrochemical System and Power Backup

Electrolyzer (EL)

Hydrogen Buffer Tank and Compression System

Fuel Cell (FC)

Fuel Cell Converter

Diesel Generator (DG)

5.2. PROCESS MONITORING AND CONTROL

5.2.1. Monitoring and Control

5.2.2. Technical Challenges - Protocol Integration

5.2.3. Automated Procedure

CONCLUSIONS

REFERENCES

ABOUT THE AUTHORS

INDEX