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Smart Grid and Enabling Technologies
Shady S. Refaat, Omar Ellabban, Sertac Bayhan, Haitham Abu-Rub, Frede Blaabjerg, Miroslav M. Begovic
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eBook - ePub
Smart Grid and Enabling Technologies
Shady S. Refaat, Omar Ellabban, Sertac Bayhan, Haitham Abu-Rub, Frede Blaabjerg, Miroslav M. Begovic
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SMART GRID AND ENABLING TECHNOLOGIES
Discover foundational topics in smart grid technology as well as an exploration of the current and future state of the industry
As the relationship between fossil fuel use and climate change becomes ever clearer, the search is on for reliable, renewable and less harmful sources of energy. Sometimes called the "electronet" or the "energy Internet, " smart grids promise to integrate renewable energy, information, and communication technologies with the existing electrical grid and deliver electricity more efficiently and reliably.
Smart Grid and Enabling Technologies delivers a complete vision of smart grid technology and applications, including foundational and fundamental technologies, the technology that enables smart grids, the current state of the industry, and future trends in smart energy. The book offers readers thorough discussions of modern smart grid technology, including advanced metering infrastructure, net zero energy buildings, and communication, data management, and networks in smart grids.
The accomplished authors also discuss critical challenges and barriers facing the smart grid industry as well as trends likely to be of importance in its future development. Readers will also benefit from the inclusion of:
- A thorough introduction to smart grid architecture, including traditional grids, the fundamentals of electric power, definitions and classifications of smart grids, and the components of smart grid technology
- An exploration of the opportunities and challenges posed by renewable energy integration
- Practical discussions of power electronics in the smart grid, including power electronics converters for distributed generation, flexible alternating current transmission systems, and high voltage direct current transmission systems
- An analysis of distributed generation
Perfect for scientists, researchers, engineers, graduate students, and senior undergraduate students studying and working with electrical power systems and communication systems. Smart Grid and Enabling Technologies will also earn a place in the libraries of economists, government planners and regulators, policy makers, and energy stakeholders working in the smart grid field.
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1
Smart Grid Architecture Overview
The electric power system is the largest and best engineering invention and achievement in human history. However, this grid paradigm faces serious challenges with regard to the increasing demand for electricity, the expanding penetration of intermittent renewable energies, and the need to respond to emerging needs such as wide usage of electric vehicles. The newly faced and expected challenges and expectations from the grid are forcing drivers to transform the current power system into a smarter grid. Smart grid (SG) is a new paradigm shift that combines the electricity, information, and communication infrastructures to create a more reliable, stable, accessible, flexible, clean, and efficient electric energy system. The SG comprises two main parts, SG infrastructure, and smart applications and operation. SG infrastructure entails a smart power system, information technology (IT), and communication system, while SG applications and operation are categorized into fundamental and emerging areas. The fundamental ones refer to energy management strategies, reliability models, security, privacy, and demandâside management (DSM). Emerging applications include the wide deployment of electric vehicles and mobile charging and storage stations. All this indicates that SGs are characterized by automated energy generation, delivery, monitoring, and consumption with stakeholders from smart utilities, markets, and customers.
Initially in this chapter, the principles of current electrical power systems will be briefly discussed. After that, the implications of the transformation trend toward SG architecture will be investigated. Following this, SGs are addressed in greater depth, covering fundamentally diverse concepts and classifications. Lastly, some SG architectures will be highlighted and the future challenges and directions will be addressed.
1.1 Introduction
Today, power grids are being challenged to meet the everâgrowing energy demands of the twentyâfirst century. Energy usage is projected to rise by 50% by 2050, according to the Energy Information Administration [1]. Today's grid is an aging infrastructure, combined with the growth of distributed energy resources (DERs), it is therefore more prone to outages and disturbances leading to poor reliability and power quality. These factors present a significant challenge for distributed renewable energy integration to the grid with unidirectional power flow [2]. The current grid is characterized by oneâdirectional electricity flow, lack of information exchange, centralized bulk generation, lack of flexibility to directly trade in electricity markets, inefficient monitoring and control of the power distribution networks, lack of flexibility and accessibility to new innovative solutions such as flexible loads, accommodating large scale of fluctuating energy resources, electric vehicles wide usage, etc. The SG is designed to tackle all these challenges by integrating and smartly utilizing the electricity, information, and communication infrastructures.
The SG is the solution to overcome the aforementioned challenges while also responding to the current and future humanity energy expectations. SG's implementation will not only have environmental benefits through high penetration of renewable sources, but will also have significant regional, national, and global impacts related to achieving a more reliable, efficient, and economic energy system. The SG paradigm integrates a variety of modern advanced technologies such as smart sensors and measurements, advanced communication and information, edge computing and control. This paradigm allows a flexible and reliable electricity system with biâdirectional power and information flows [3]. The structures of the SG anticipate and respond to electric system disturbances, optimize asset utilization, and operate efficiently. SG houses all generation and storage options, which hinders the dependency on peak demand backâup power stations â thus, cutting significant costs related to the generation, transmission, and distribution. Furthermore, SG enables active participation of customers, new products, services, and markets â thus can support the uptake of new industries. SG functions resiliently against attacks and natural disasters, delivers power quality for the digital economyâ thus, creating new jobs and regenerating the economy at a time of financial crisis. The SG is a power network that contains distributed nodes, which operate under the pervasive control of smart subsystems, soâcalled smart microgrids. A microgrid is a smallâscale version of the electric grid, however possessing distributed generation and potentially energy storage (ES). Microgrids can operate in a gridâconnected mode, islanded mode, or in both modes which improve the grid's reliability, controllability, and efficiency. Widespread installations of microgrids enable a faster transformation to the SG paradigm from the current grid infrastructure [4].
1.2 Fundamentals of a Current Electric Power System
The two main characteristics of conventional electrical power systems are: centralized energy generation and unidirectional power delivery systems. This means that electric power is first produced by bulk power generation and then transmitted across the electricity grid to the distribution layer, and finally to the end users. The flow of electricity in the grid is from top (highâvoltage network) to bottom (lowâvoltage network). Figure 1.1 shows the three main stages of generation, transmission, and distribution [5]. Those grid elements are briefly explained in the next subâsections.
1.2.1 Electrical Power Generation
Traditional power plants burn the fossil fuel to generate electricity therefore they contribute in significant amount of greenhouse gas emission to the environment. The crucial need to adopt powerâgeneration approaches that have fewer environmental impacts is an essential requirement for modern power grids, which means moving toward more renewable energy systems. Among ...