Residential Microgrids and Rural Electrifications contains an overview of microgrids' architecture, load assessments, designing of microgrids for residential systems, and rural electrifications to help readers understand the fundamentals. Including many new topics in the field of home automation and the application of IoT for microgrids monitoring and control, the book includes sections on the infrastructure necessary for charging Electric Vehicles in residential systems and rural electrifications and how to estimate the energy and cost of various combinations of energy resources. Many examples and practical case studies are included to enhance and reinforce learning objective goals.
Those in engineering research and technical professions will be able to perform energy and cost analyses of various combinations of energy sources by using advanced, real simulation tools.
Author(s): Sanjeevikumar Padmanaban, C. Sharmeela, P. Sivaraman, Jens Bo Holm-Nielsen
Publisher: Academic Press
Year: 2021
Language: English
Pages: 352
City: London
Front Cover
Residential Microgrids and Rural Electrifications
Copyright Page
Contents
List of contributors
Preface
Acknowledgments
1 Microgrids planning for residential electrification in rural areas
Chapter Outline
1.1 Introduction
1.2 Microgrids in rural areas
1.2.1 Microgrids structure
1.2.2 Microgrid configurations
1.2.3 Microgrids components
1.2.3.1 Diesel generators
1.2.3.2 Renewable energy resources
1.2.3.3 Energy storage systems
1.2.4 Issues related to microgrids in rural areas
1.3 Planning of residential microgrids
1.3.1 Problem identification
1.3.2 Input data
1.3.2.1 Weather data
1.3.2.2 Load data
1.3.2.3 Electricity rates and grid technical data
1.3.2.4 Technical and economic data of components
1.3.3 Objective functions
1.3.3.1 Economic objectives
1.3.3.2 Technical objectives
1.3.4 Design constraints
1.3.4.1 Generation storage component constraints
1.3.4.2 Technical constraints
1.3.5 How to solve the microgrids planning problem
1.3.5.1 Algorithms
1.3.5.2 Software
1.4 HOMER software
1.4.1 Software introduction
1.4.2 Equipment models in HOMER
1.4.2.1 Load model
1.4.2.2 Generation units model
1.4.2.3 Energy storage model
1.4.3 Optimization in HOMER
1.4.4 Output results by HOMER
1.4.5 Sensitivity analysis in HOMER
1.4.6 HOMER deficiencies
1.5 Conclusion
References
2 Overview of microgrids in the modern digital age: an introduction and fundamentals
Chapter Outline
2.1 Introduction
2.2 Microgrid fundamentals
2.3 Microgrid impacts
2.4 Microgrid for rural electrification
2.5 Discussion
2.6 Trends
2.7 Conclusions
References
3 Sources of a microgrid for residential systems and rural electrification
Chapter Outline
3.1 Introduction
3.2 Solar photovoltaic cells
3.2.1 Generation of charge carriers because of the absorption of photons within the materials that develop a junction
3.2.2 Resulting separation of photo-generated charge carriers within the junction
3.2.3 Assortment of photo-generated charge carriers at the terminals of the junction
3.2.4 Components of solar PV system
3.2.4.1 Solar panels
3.2.5 Types of solar panels
3.2.6 Solar inverter
3.2.7 Types of solar inverters
3.2.8 Batteries
3.2.9 Charge controllers
3.2.10 Advantages of solar energy
3.3 Biomass and biochemical
3.3.1 Thermochemical
3.3.2 Biochemical
3.3.2.1 Aerobic digestion
3.3.2.2 Anaerobic digestion
3.3.2.3 Biophotolysis
3.3.3 Agrochemical
3.3.3.1 Fuel extraction
3.3.3.2 Biodiesel and esterification
3.3.4 Benefits of biomass energy
3.3.5 Hydropower plant
3.3.6 Water turbine
3.3.6.1 Impulse turbine
3.3.6.2 Pelton wheel
3.3.6.3 Cross-flow
3.3.6.4 Reaction turbine
3.3.6.5 Propeller
3.3.7 Advantages of hydropower
3.4 Fuel cell technology
3.4.1 Fuel cell application in microgrid arrangements
3.4.1.1 Grid-connected
3.4.1.2 Grid-parallel
3.4.1.3 Direct current microgrid
3.4.2 Comparison of FC microgrid application
3.4.3 Advantages of FCs in microgrids
3.5 Wind power
3.5.1 Wind turbine components
3.5.2 Application of wind power in microgrids
3.5.3 Advantages of wind power
3.6 Diesel generator
3.6.1 Parts of a diesel generator
3.6.2 Advantages of a diesel generator
3.7 Conclusion
References
4 Overview of sources of microgrids for residential and rural electrification: a panorama in the modern age
Chapter Outline
4.1 Introduction
4.2 Microgrid concepts
4.3 Solar energy
4.4 Discussion
4.5 Trends
4.6 Conclusions
References
5 Design of microgrids for rural electrification
Chapter Outline
5.1 DC microgrid
5.1.1 Overview of the system and working methods
5.1.2 DC-DC boost converter design
5.2 Logic behind the system
5.2.1 Source side management approach
5.2.2 Demand-side management approach
5.3 Results and discussion
5.3.1 Source-side management
5.4 AC microgrid
5.4.1 Introduction to the system
5.4.2 Indicators of sustainability
5.5 Hybrid microgrid
5.6 Case study of a hybrid microgrid system
5.6.1 Electrical load survey of the communities
5.6.2 Size of the solar energy system
5.6.3 Inverter sizing and system voltage
5.6.4 Sizing the PV array
5.6.5 Battery energy storage system
5.6.6 Charge controller sizing
5.6.7 PV energy system installation and commissioning
5.6.8 Installation of electric poles
5.6.9 Motorized borehole for irrigation purposes
5.6.10 Metering of customers
5.6.11 Social and economic impact of the project on the communities
5.7 Conclusion
References
6 Stand-alone microgrid concept for rural electrification: a review
Chapter Outline
6.1 Introduction
6.2 Renewable energy: the clean facts
6.3 Microgrid: a complete rural electrification solution
6.3.1 Electrification in remote regions
6.3.2 Benefits and drawbacks of a photovoltaic system
6.3.3 Solar panel flexibility for a rural home
6.4 Example
6.5 India’s latest rural electrification schemes and initiatives
6.5.1 Scheme 1: power for all
6.5.2 Scheme 2: Saubhagya
6.5.3 Scheme 3: DeenDayal Upadhyaya Gram Jyoti Yojana
6.6 Rural electrification for home and industry
6.6.1 Issues in microgrids
6.6.1.1 Power quality
6.6.1.2 Stability
6.7 Modeling of a solar cell
6.8 Battery storage
6.9 Simulation analysis of the photovoltaic connected load
6.10 Conclusion
References
7 Rural and residential microgrids: concepts, status quo, model, and application
Chapter Outline
7.1 Introduction
7.2 What is energy poverty?
7.2.1 Indexes to evaluate energy poverty in Europe
7.2.1.1 The 10% index
7.2.1.2 Minimum income standard–based index
7.2.1.3 Low-income–high-cost index
7.3 The 5D evolution in energy systems
7.3.1 Decentralization
7.3.2 Decarbonization
7.3.3 Democratization
7.3.4 Deregulation
7.3.5 Digitalization
7.4 The role of microgrids in the 5D evolution in energy systems and fighting energy poverty
7.4.1 Microgrids and decentralization
7.4.2 Microgrids and decarbonization
7.4.3 Microgrids and democratization
7.4.4 Microgrids and digitalization
7.4.5 Microgrids and deregulation
7.4.6 The role of microgrids in fighting energy poverty
7.5 Rural versus residential microgrids
7.5.1 Definition of microgrids
7.5.2 Types of microgrids
7.5.2.1 Classification of microgrids based on electrical characteristics
7.5.2.2 Classification of microgrids based on deployment
7.6 Technical and economic benefits of microgrids
7.6.1 Environmental issues
7.6.2 Investment and operation issues
7.6.3 Power quality and reliability improvements
7.6.4 Economic advantages
7.6.5 Market benefits
7.7 Challenges of microgrids
7.7.1 High costs of distributed energy resources
7.7.2 Technical problems
7.7.3 Market monopoly
7.8 Load characteristics of microgrids
7.9 Microgrid configuration
7.10 Literature review
7.11 Energy management of microgrids
7.11.1 Mathematical modeling
7.11.1.1 Grid-connected operation
7.11.1.2 Islanded mode operation
7.11.2 Optimization approach
7.12 Concluding remarks and outlook
References
8 Load prediction of rural area Nordic holiday resorts for microgrid development
Chapter Outline
8.1 Introduction
8.2 Load profile behavior
8.2.1 Time-series analysis of load profile
8.3 Rural area holiday resorts load analysis
8.4 Combination of forecasts
8.5 Learning systems and ensemble methods
8.6 Tree learning as variance reduction
8.6.1 Random forest regression
8.7 Case study: Rural area electric energy load prediction
8.8 Double-stacking algorithm
8.8.1 First step: Time organizing
8.8.2 Second step: Algorithm development and hyperparameter tuning
8.8.3 Third step: Choosing first layer estimators
8.9 Results and discussion
8.9.1 Case study: Nordic rural area
8.10 Conclusion
References
9 Novel power management strategy for a solar biomass off-grid power system
Chapter Outline
9.1 Introduction
9.2 Modeling
9.2.1 Dataset
9.2.2 Solar photovoltaic system
9.2.3 Biomass power system
9.2.3.1 Calorific value
9.2.3.2 Producer gas
9.2.4 Inverter
9.2.5 Design of battery bank
9.3 Problem formulation
9.3.1 Loss of power supply probability
9.3.2 Dump load
9.3.3 Cost of electricity
9.4 Optimization
9.4.1 Firefly algorithm
9.4.2 Invasive weed optimization
9.5 Results and discussion
9.5.1 Strategies for power management
9.5.1.1 Running the system by photovoltaic alone
9.5.1.2 Running the system by biomass alone
9.5.1.3 Running the system by both photovoltaic and biomass
9.5.1.4 Practical case with photovoltaic during the day and biomass during the night
9.5.2 Comparative analysis of optimization algorithms
9.5.2.1 Optimizing the loss of power supply probability
9.5.2.2 Optimizing the dump load
9.5.2.3 Optimizing the cost of electricity
9.5.3 Sensitivity analysis
9.5.3.1 Variation in number of houses
9.5.3.2 Variation in number of batteries
9.5.3.3 Variation in biomass feedstock
9.5.3.3.1 Wheat straw
9.5.3.3.2 Coconut shells
9.5.3.3.3 Crushed sugarcane
9.5.3.3.4 Corncobs
9.5.3.3.5 Rice hulls
9.5.3.3.6 Cotton stalks
9.5.3.4 Variation in penetration level
9.6 Conclusion
References
10 Modeling and analysis of an islanded hybrid microgrid for remote off-grid communities
Chapter Outline
10.1 Introduction
10.2 Site location: study area
10.2.1 Location of case study
10.2.2 Load data of site
10.2.3 Solar photovoltaic irradiance data of site
10.3 Microgrid modeling and frequency stability study under dynamic conditions
10.3.1 Microgrid parameters
10.3.2 Primary frequency response through the battery
10.4 Economic analysis through HOMER
10.5 Results and discussion
10.5.1 Frequency response
10.5.2 HOMER cost of energy analysis
10.6 Conclusion
References
11 Performance analysis of a DC stand-alone microgrid with an efficient energy management system
Chapter Outline
11.1 Introduction
11.2 DC microgrid architecture
11.2.1 Energy management system
11.3 Simulation and analysis
11.3.1 Scenario 1: system with PV, battery, and load
11.3.1.1 Fixed load and varying input
11.3.1.2 Varying load and fixed input
11.3.1.3 Varying load and varying input
11.3.2 Scenario 2: system with wind power, battery, and load
11.3.2.1 Fixed load and varying input
11.3.2.2 Varying load and fixed input
11.3.2.3 Varying load and varying input
11.3.3 Scenario 3: system with PV power, wind power, battery, and load
11.3.3.1 Load is met by renewable resources only (PL=Ppv+PW)
11.3.3.2 Excess power from renewable sources is stored in battery (Ppv+Pw=PL+PB)
11.3.3.3 Load is met by the renewable sources and battery storage (PL=Ppv+PW+PB)
11.3.4 Load priority based on the SOC of battery
11.4 Conclusion
References
12 Microgrids with Distributed Generation and Electric Vehicles
Chapter Outline
12.1 Introduction
12.2 Microgrid
12.3 Types of microgrids
12.3.1 Hybrid microgrid with an AC bus system
12.3.2 Hybrid microgrid with a DC bus system
12.3.3 Hybrid microgrid with an AC and DC bus system
12.4 Applications and benefits of microgrids
12.4.1 Applications
12.4.2 Benefits
12.5 The electric vehicle market
12.6 Microgrids with electric vehicle charging
12.7 Power management and control for hybrid microgrids
12.7.1 Hybrid microgrid with an AC bus system
12.7.2 Hybrid microgrid with a DC bus system
12.7.3 Hybrid microgrid with an AC and DC bus system
12.8 Significant ideas for the enhancement of a microgrid
12.8.1 Infrastructure of a hybrid microgrid with an AC and DC bus system
12.8.2 Power quality problems
12.8.3 Parallel operation of interfacing or interlinking converters
12.8.4 Communication system implementation in a microgrid
12.8.5 Transient operating mode
12.8.6 Semiconductor device implementation in a microgrid
12.8.7 Cost of the system
12.8.8 Future of charging stations
12.9 Conclusion
References
13 Intelligent algorithms for microgrid energy management systems
Chapter Outline
13.1 Introduction
13.2 Overview of optimization algorithms
13.2.1 Important parameters for the energy management system of the grid
13.2.2 Genetic algorithm
13.2.2.1 Minimizing the cost of energy production using a genetic algorithm
13.2.2.1.1 Cost of the photovoltaic system
13.2.2.1.2 Cost of the battery system
13.2.2.1.3 Cost of the wind turbine
13.2.2.1.4 Factors of constraints
13.2.2.1.5 Simulation results
13.2.3 Fish swarm optimization algorithm
13.2.3.1 Minimization of cost using the fish swarm optimization algorithm
13.2.3.2 Simulation results
13.2.4 Bat algorithm
13.2.5 Most valuable player algorithm
13.2.6 Other algorithms
13.3 Conclusion
References
14 Electrical safety for residential and rural microgrids
Chapter Outline
14.1 Introduction
14.2 Technical terms
14.2.1 AC and DC
14.2.2 Arc flash
14.2.3 Authorized person or qualified electrical workers
14.2.4 Earthing, grounding, and bonding
14.2.5 Cardiac arrest
14.2.6 Cardiopulmonary resuscitation
14.2.7 Confined space
14.2.8 Energize
14.2.9 Hazard
14.2.10 Isolated or deenergized
14.2.11 Lockout-tagout
14.2.12 Permit to work
14.2.13 Step voltage
14.2.14 Touch voltage
14.2.15 Transferred voltage
14.2.16 Ground electrode
14.3 Causes of electrical accidents
14.4 Effects of electrical current
14.5 Significance of body resistance and current
14.5.1 Case study for microgrid fault analysis
14.6 Earthing system in microgrids
14.6.1 Estimation of earthing system
14.7 Hazard mitigation methods
14.8 Electrical safety audit
14.9 Conclusions
References
Index
Back Cover
