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Risk-Based Energy Management

Name: Risk-Based Energy Management
Author: Sayyad Nojavan, Mahdi Shafieezadeh, Noradin Ghadimi, Sayyad Nojavan, Mahdi Shafieezadeh, Noradin Ghadimi

DC, AC and Hybrid AC-DC Microgrids

Sayyad Nojavan, Mahdi Shafieezadeh, Noradin Ghadimi, Sayyad Nojavan, Mahdi Shafieezadeh, Noradin Ghadimi

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eBook - ePub

Risk-Based Energy Management

DC, AC and Hybrid AC-DC Microgrids

Sayyad Nojavan, Mahdi Shafieezadeh, Noradin Ghadimi, Sayyad Nojavan, Mahdi Shafieezadeh, Noradin Ghadimi

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Información del libro

Risk-Based Energy Management: DC, AC and Hybrid AC-DC Microgrids defines the problems and challenges of DC, AC and hybrid AC-DC microgrids and considers the right tactics and risk-based scheduling to tackle them. The book looks at the intermittent nature of renewable generation, demand and market price with the risk to DC, AC and hybrid AC-DC microgrids, which makes it relevant for anyone in renewable energy demand and supply. As utilization of distributed energy resources and the intermittent nature of renewable generations, demand and market price can put the operation of DC, AC and hybrid AC-DC microgrids at risk, this book presents a timely resource.

Discusses both the challenges and solutions surrounding DC, AC and hybrid AC-DC microgrids
Proposes robust scheduling of DC, AC and hybrid AC-DC microgrids under uncertain environments
Includes modeling upstream grid prices, renewable resources and intermittent load in the decision-making process of DC, AC and hybrid AC-DC microgrids

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Información

Editorial

Academic Press

Año

2019

ISBN

9780128174920

Categoría

Tecnología e ingeniería

Categoría

Recursos de energía renovable

Chapter 1

Energy management concept of AC, DC, and hybrid AC/DC microgrids

Sayyad Nojavan¹, Hamed Pashaei-Didani², Arash Mohammadi² and Hamed Ahmadi-Nezamabad², ¹Department of Electrical Engineering, University of Bonab, Bonab, Iran, ²Faculty of Electrical and Computer Engineering, University of Tabriz, Tabriz, Iran

Abstract

By increasing environmental effects of using fossil fuels to generate electric power, development and utilization of renewable energy sources (RESs) including wind turbine and photovoltaic systems are increasing every day, all around the world. To accommodate the traditional power systems with RESs, the concept of microgrid (MG) is provided, defined as a combination of controllable loads and distributed energy resources that can be utilized in grid-connected or islanded modes. In this chapter, first different types of MGs are detailed and then different energy management systems developed in the literature are provided. In addition, different objective functions, constraints, and communication systems utilized in the literature are presented.

Keywords

AC microgrids; DC microgrids; hybrid AC/DC microgrids; energy management systems; renewable energy sources; distributed energy resources

1.1 Introduction

Supplying ever-increasing energy demands considering environmental effects of fossil fuels such as climate change [1] has made developing renewable energy sources (RESs) necessary, as they are environmentally friendly energy sources [2]. Providing clean energy and mitigating emission of greenhouse gases are the main advantages of RESs including wind, solar, hydro, fuel cell, tidal power, and biomass. Among them, solar and wind are considered the most promising energy sources [1]. In the literature, RESs are referred to as distributed energy resources (DERs) [3,4], which are on-site power generation units that do not require any transmission equipment, resulting in a reduction of energy loss in a distribution system. The power generation of DERs, especially wind and solar, are volatile due to their dependency on meteorological factors [5]. Therefore, it is better to couple DERs with energy storage systems (ESSs) and microconventional generation units to cope with uncertain power output of these sources.

To accommodate DERs with traditional power systems, the concept of microgrid (MG) is developed [6]. MGs are defined as a combination of controllable loads and DERs that can be utilized in grid-connected or islanded modes.

Various advantages can be achieved by implementing MGs, including improving voltage profile, implementing demand response programs [7], reducing energy loss, using cogeneration units to supply heat load, and reducing line outages [8]. However, an MG faces different challenges and limitations. High investment cost of DERs, optimal energy management of RESs, and the raised problem of protection issues and lack of regulatory standards can be counted as the most important challenges that an MG faces [9].

The MGs can be classified from the different point of views. For example, according to operational frequency, MGs are grouped as AC, DC, and hybrid AC/DC, each of which will be detailed in the following chapters. In another classification, as mentioned earlier, MGs are divided into two groups, grid-connected and islanded; more information about these groups is provided in the following section.

Developing energy management systems (EMSs) for MGs is one of the most important research areas due to high penetration of renewable energy resources. EMSs should provide a balance between load and supply, and satisfy different operational and economic constraints of the system.

1.2 Classification of microgrids

Fig. 1.1 presents the classification of MGs including operating mode, power type, phase, application, and control topics. As it can be seen, the phase is divided into two subgroups, single phase and three phases, and the control is grouped as centralized and decentralized. According to Fig. 1.1, the MGs can be classified considering their application, which is categorized as residential/commercial/industrial and utility and military.

Figure 1.1 Classification of microgrids.

In one division, the MGs are classified as grid-connected or islanded modes, each with its own advantages and disadvantages. In each mode, utilized DERs in the MG are connected to a power electronic interface to satisfy protection, metering, and control objectives. In the grid-connected mode, MGs can exchange energy, which can make profit by selling energy to the upstream grid during high-price periods. On the other hand, the grid-connected MGs should switch to islanded mode when there is a failure in the upstream grid. Finally, it should be noted that to improve the system operation, optimal management of the MGs is necessary in this mode. Optimal operation of different AC, DC, and hybrid AC/DC MGs is detailed in the following chapters.

AC MGs are the most common type of MGs because of direct implementation of distributed generation power sources in the system. In DC MGs, considerable energy saving is achieved due to fewer converters compared with AC MGs. By increasing DC loads in the system and in order to benefit from advantages of both AC and DC MGs, hybrid AC/DC MGs have drawn more attention recently. Fig. 1.2 depicts the structure of AC, DC, and hybrid AC/DC MGs.

Figure 1.2 Structure of (A) AC microgrid, (B) DC microgrid, and (C) hybrid AC/DC microgrid.

1.3 Operation strategies and constraints

To get optimal energy management of any type of MG, different strategies can be taken into account including operation and loss cost, emission cost, demand response incentives, interruption and outage cost, energy transaction cost, and so on. Fig. 1.3 provides most common strategies in MG operation.

Figure 1.3 Strategies in microgrid operation.

Each of these strategies should provide optimal operation of MGs subjected to different constraints including energy balance, network constraints, demand response, reactive power support, reliability, limits of ESSs, and constraints of the generating units. Fig. 1.4 provides the most important constraints of the system.

Figure 1.4 Constraints in microgrid operation.

1.4 Communication system

In MGs, communication infrastructure is required to coordinate different DERs and implement demand response programs by sharing information with each other. To do so, a reliable, continuous, accurate, fast communication infrastructure, without any disconnections and disturbances, is necessary to transfer data between local controllers, MG central controller, and sensors. Such infrastructures may impose a high investment cost, however, according to the number of required repeaters to cover the geographical area of the MG and improve transmitted signal quality.

For a safe, reliable, and effective connection between different parts of an MG, various wireless and wired communication technologies have been proposed in the literature. Coverage area, latency, quality of service, coverage area, power consumption, and reliability are the most important criteria that should be taken into account to choose the optimal selection among the developed wireless and wired technologies. By taking data rate and coverage area into account, WiMAX [10], 4G [11], and passive potential networks can be considered the most powerful communication structures; followed by 2G [12], narrowband power line communication, and coaxial cables; and finally, Bluetooth [13], Z-wave [14], and Zigbee [13] are among the weakest communication technologies. It is obvious that by increasing data rate and coverage area, the investment cost of the communication system will be increased.

1.5 Energy management system

To get optimal energy management of MGs, developing an EMS has been defined as “a computer system comprising a software platform providing basic support services and a set of applications providing the functionality needed for the effective operation of electrical generation and transmission facilities so as to assure adequate security of energy supply at minimum cost” by the International Electro-technical Commission in the standard IEC 61970. To develop the EMS for different types of MGs, various classic and heuristic method...