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Designing a secure communication network for the reliable operation of micro-grids in the power grid

Number of pages: 162 File Format: word File Code: 32256
Year: 2014 University Degree: Master's degree Category: Electrical Engineering
Tags/Keywords: Communication network - Demand side management - electric car - micro network - Network design - Power system - Reliability - Telecommunication system
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  • Summary of Designing a secure communication network for the reliable operation of micro-grids in the power grid

    M.A. Dissertation

    Trend: Power

    Abstract

    Evaluating reliability in power networks is essential. With the discussion of smart grids in traditional power systems, a lot of attention has been paid to the use of renewable resources, smart cars that can be connected to the grid, as well as other types of energy sources such as CHPs[1]. On the other hand, in the smart power system, not only the resources on the production side are relied on, but in such an environment, the use and efficiency of the capabilities of the subscribers on the consumption side is also very important. This issue is important because the response speed of the resources on the consumption side is much higher than the resources on the production side and they do not need investment costs. They also increase the ability to use sources with random production, such as scrap cars, as well as renewable sources. All these facilities that have appeared in the context of smart networks increase the reliability of power systems. In the meantime, telecommunication systems and sampling rates and information transmission can increase the effectiveness of other departments in reliability calculations. The purpose of this research is to design the telecommunication system in order to increase the reliability of the power system. The results show that the telecommunication system has an effective role in reliability calculations.

    Key words: reliability, electric vehicle, telecommunication system, demand side management

    Chapter One:

    Research overview

     

    1-1 Introduction

    Today, the electricity industry is not only faced with providing resources to meet the energy demand of the industries, but on the other hand, minimizing and reducing the effects that humans have on the environment in connection with the production of this energy is also another matter of interest, and the smart grid [2] (SG) is a solution to this challenge, which is very profitable and efficient. has a lot For the consumer, the smart grid means that they can manage their consumption intelligently in order to pay less during peak hours when the price of energy is expensive, and for environmental experts, this grid means using technology to help solve bad climate changes and avoid excessive production of carbon gases, and for colleagues in the electricity industry, it means peaking and making smart decisions and providing accurate information about the status of the grid[1].

    mainly, the most important The requirements that compel distribution companies to move towards smart networks are [1] :

    Self-recovery distribution network

    Self-recovery distribution network refers to a network that has a high reliability factor, inherent security at all levels. In this type of networks, using sensors[3] and measuring devices, there is decentralized control and comprehensiveness on the system parameters.

    Distribution network with the possibility of providing electricity at a low price

    These types of networks mainly have a non-hierarchical distribution of electrical energy production and usually reduce the cost of electricity supply by taking advantage of scattered production sources by consumers. In this type of networks, the involvement of human factors is greatly reduced and the level of automation increases.

    Environment-friendly electricity distribution network

    Definitely, intelligent distribution networks prevent excessive greenhouse gasses from entering the environment by optimizing energy consumption.

    In this research, the aim of investigating the effect of telecommunication infrastructure and smart network platforms in Increasing reliability in the distribution system. For this purpose, by expressing the features of the intelligent distribution system and the communication technologies used in it, we will learn about the infrastructure of the intelligent network. Also, by stating the importance of the issue, we will examine the reason for addressing this issue.

    1-2 statement of the problem and necessity of research

    Today, with the advancements made in communication technology and measuring devices such as PMUs[4] and various sensors, as well as in order to manage energy consumption and reduce environmental pollution, as well as in order to regularly plan network upgrades, smart networks are expanding. Meanwhile, the design of a secure telecommunication platform is of great importance in order to maintain and increase reliability.

    In an intelligent distribution system of electric energy, information and their transmission are of great importance. Because any intelligent system is not able to make a decision without knowing the conditions. In a smart system, the information required by the system is collected from various sources such as smart meters, power plants, feeders, substations and any other components that are related to the network. In this type of network, information transmission is two-way in some cases, that is, for example, not only does the network receive shared data, but the network may send information and commands to the subscriber (for example, a smart meter).

    Information transmission in such networks has special features The information sent must have high security and reliability and, in addition, have a high sending speed. For example, in a smart network, when a command is issued to cut off a feeder or enter a unit from a power plant, the entire network must ensure that the command is received and executed with full accuracy and speed. Therefore, the communication infrastructure in a smart network, which is considered one of the most important and basic parts of a smart network, must have special features such as speed, security and high reliability. On the other hand, due to the large size of distribution networks and the large number of terminals, it is impossible to imagine creating a separate network for data transmission next to the distribution network. Therefore, this data transmission network must somehow use the capabilities and capacities of the distribution network itself. Intelligent electric energy distribution networks are one of the latest technologies in the world and the result of specialized efforts to modernize distribution networks and enter the digital century. The main goal is to provide reliable electricity and respond to the growing needs of customers with minimal damage to the environment. The world's first smart network was introduced in March 2008, and the city of Balder, Colorado, USA, was awarded the title of the first city with a smart electricity distribution network. The goal of the designers is to use smart technology around the three main axes of subscribers, equipment and communication. Smart technology has the ability to make fundamental changes in the production, transmission, distribution and use of electrical energy along with economic and environmental benefits, which ultimately ends in meeting the needs of customers and the availability of reliable and stable electricity [2]. On the other hand, the intelligent power system does not rely only on resources on the production side; Rather, in such an environment, the use and efficiency of subscribers' capabilities on the consumption side is also very important. This issue is important because the response speed of the resources on the consumption side is much higher than the resources on the production side, they also do not need investment costs, and they also increase the ability to use resources with random production, such as scrap cars, as well as renewable resources. Among the solutions that are implemented on the consumption side, we can refer to the efficiency or energy response solutions. For the consumer side, the smart grid means that they can manage their consumption intelligently to pay less during peak hours when the price of energy is expensive. Reducing the power consumption of subscribers during peak hours can also help to improve the environmental conditions, which is one of the goals of smart networks.

    Now that the importance of efficiency from consumption side resources has been determined, it is necessary to build a secure communication infrastructure with high reliability in the smart network; In other words, the discussion of intelligentizing the power grid is not only a discussion related to power systems, but issues related to communication, information technology, and intelligent processing should also be considered in it.

  • Contents & References of Designing a secure communication network for the reliable operation of micro-grids in the power grid

    List:

    Abstract 1

    Chapter One: General Research

    1-1 Introduction 3

    1-2 State the problem and necessity of research. 4

    1-3 concept of reliability in power system. 7

    1-3-1 levels of assurance. 8

    1-3-1-1 ability to ensure HLI level 9

    1-3-1-2 ability to ensure HLII level 9

    1-3-1-3 ability to ensure HLIII level 10

    1-3-2 criteria of ability to ensure the ability of power systems. 10

    1-3-3 evaluation indicators that can be ensured. 13

    1-3-4 assessment methods of assurance. 15

    1-3-4-1 analytical methods. 15

    1-3-4-2 simulation methods. 18

    1-4 Introduction to Smart Bakh. 24

    1-4-1 Advantages of smart grids[1] 25

    1-4-2 Comparison of smart grid with traditional grid. 27

    1-4-3 Infrastructure of smart grid cases. 30

    1-4-3-1 communication and measuring equipment. 30

    1-4-3-2 distributed power monitoring infrastructures 31

    1-4-3-3 are smart feeders. 31

    1-4-3-4 communications in smart networks. 32

    1-5 Khudrobargdeh 34

    1-6 Accountability 36

    1-6-1 Introduction. 36

    1-6-2 load response 39

    1-6-3 definition of load response programs 40

    1-6-4 types of load response programs 41

    1-6-4-1 incentive load response programs (IBP) 41

    1-6-4-2 Time Based Response Programs/Time Tariff (TBRP) 42

    1-6-4-3 Direct Load Control (DLC) 44

    1-6-4-4 Interruption/Reduction (I/C) 44

    1-6-4-5 Sell Demand/Repurchase Programs (DB) 45

    1-6-4-6 The impact of DB program on market price change 45

    1-6-4-7 Emergency response programs (EDRP) 46

    1-6-4-8 Capacity market programs (CAP) 47

    1-6-4-9 Ancillary service programs (A/S) 47

    1-6-4-10 Time of use (TOU) pricing plans 47

    1-6-4-11 Real-time pricing plans (RTP) 48

    1-6-4-12 Critical peak time (CPP) pricing plans 48

    1-6-5 Benefits of customer presence in the market 50

    1-6-5-1 Customer benefits. 50

    1-6-5-2 advantages of the network. 50

    1-6-5-3 additional benefits. 53

    1-6-6 The effect of the execution of accountability programs on the power system. 54

    1-6-7 The role of accountability resources on exploiting the power system. 54

    1-6-8 Problems of sources of answers 55

    1-7 Hypotheses and questions about the authenticity of the truth. 55

    8-1 56

    The second chapter is an overview of the conducted research (literature and documents, frameworks and basis, history and background of the research)

    2-1 Introduction ..58

    2-2 Researches carried out in the field of electric cars. 58

    2-3 review of the research conducted in studies on the effect of distributed generation resources on reliability 67

    2-4 research conducted in the field of smart grids. 72

    Chapter 3: Research implementation method

    3-1 Introduction..77

    3-2 Communication technologies for smart network [41] 77

    3-2-1 OSI/ISO layers [44]: 79

    3-2-2 Communication technologies. 80

    3-2-2-1 IEEE 802 series technology. 80

    3-2-2-2 Mobile communication technologies: 92

    3-2-2-3 Multiple High Switching Protocol (MPLS) technology: 93

    3-2-2-4 Power line communication technology [41]: 94

    3-3 standards for information exchange [41] 96

    3-3-1 standards for smart meters. 96

    3-3-2 Modbus (Modbus) [48]: 97

    3-3-3 or network protocol distribution [49] 98

    3-3-4 IEC 61850 99

    3-4 generations of mobile systems. 99

    3-4-1 types of generations of mobile systems [55] 101

    3-4-1-1 Characteristics of second-generation systems: 102

    3-4-1-2 GPRS (General Packet Radio Service) generation 5/2 systems 102

    3-4-1-3 Features of third generation. 103

    3-4-1-4 characteristics of the fourth generation. 104

    3-4-1-5 benefits of using the GSM network. 107

    3-4-1-6 GSM structure: 108

    3-4-2 Network Management Center NMC (Network Management System) 115

    3-4-3 Summary 115

    3-5 Microgrid (microgrid) 116

    3-6 Electric Vehicle Modeling. 118

    7-3 methods of reliability evaluation in distribution system. 119

    3-8 methods used for designing communication systems. 119

    3-8-1 related assumptions 120

    3-8-2 description of the proposed framework. 121

    Chapter Four: Implementation and Results

    4-1 Introduction. 124

    4-2 Design considerations for the communication system in this thesis. 124

    4-2-1 How to model and consider the communication system. 125

    4-3125

    3-4 cases under study. 125

    4-4 network studied in this research. 126

    4-5 proposed method for evaluating the reliability. 129

    4-6 Collected information 129

    4-7 The scenarios under study. 133

    4-7-1 First scenario: Absence of communication system. 133

    2-4-7-2 scenario: the presence of the communication system in the middle of low information exchange. 133

    Scenario 8-4: The existence of a telecommunication system for exchanging information on the network. 135

    4-9 Conclusion. 135

    Chapter Five: Conclusions and Suggestions

    5-1 Introduction. 138

    2-5 Conclusion. 138

    3-5 suggestions. 139

    Sources

    Persian sources. 141

    Non-Persian sources. 141

    English summary. 151

    Source:

    Articles:

    ]1[- Hosseinzadeh, Fardin, Porakbari Kasmai, Mehdi , intelligent electricity grids and its application in distribution networks, the 14th electricity conference. [9] Rezaian, Meisham, Gad, Shahram. (2009). Investigating the effect of the simultaneous production of electricity and heat in reducing the cost of microgrid operation and pollution using a multi-objective genetic algorithm, the 25th international electricity conference. Bar" 2nd Smart Electric Networks Conference, Amirkabir University of Technology, Khordad 1391. [98] Kamran Qavami, Dolat Jamshidi, "Security of cellular communication systems for use in smart networks of the electric power industry", 26th International Electric Conference.

    Dissertation:

    ]8 [Zanganeh, Ali. (1388). Development Planning Distributed production resources considering uncertainties using multi-criteria decision making method, PhD dissertation, Iran University of Science and Technology.

    Non-Persian sources:

    [2] James G. Cupp, PE, and Mike E. Beehler, "Implementing Smart Grid Communications", Burns and Mcdonnell, No. 4, 2008.

    [3] D. S. Kirschen and G. Strbac, "Fundamentals of power system economics", John Wiley & Sons, 2004

    [4] Ruofei Ma, Hsiao-Hwa Chen, Fellow, IEEE, Yu-Ren Huang, and Weixiao Meng, Senior Member, IEEE "Smart Grid Communication: Its Challenges and Opportunities" IEEE TRANSACTIONS ON SMART GRID, VOL. 4, NO. 1, MARCH 2013

    [5] V. Pothamsetty, S. Malik, "Smart Grid:Leveraging Intelligent Communication to Transform the Power Infrastructure", Cisco, February, 2009.

    [6] Donald J. Marihart, "Communications Technology Guidelines for EMS/SCADA Systems", IEEE Transactions on Power Delivery, Vol. 16, No. 2, April 2001.

    [7] Alfredo Vaccaro, Domenico Villacci, "Performance analysis of low earth orbit satellites for power system communication", Power System Research Group, University of Sannio, Department of Engineering, April 2004.

    [10] Strunz, K. Fletcher, R. H. Campbell, R. Gao, F. (2009). "Developing Benchmark Models for Low-voltage Distribution Feeders". IEEE power engineering society general meeting, Calgary, Canada. 27, NO. 4, NOVEMBER 2012

    [14] D. S. Kirschen and G. Strbac, "Fundamentals of power system economics", John Wiley & Sons, 2004

     

    [15] IEA, "Strategic Plan for the IEA Demand Side Management Program 2004-2009", www.iea.org

    [16] D. S. Kirschen, "Demand-Side View of Electricity Markets", IEEE, Transactions On Power.

    [17] Federal Energy Regulatory Commission Staff, "Assessment of Demand Response and Advance Metering", Federal Energy Regulatory Commission, FERC, Aug 2006 to 2009. [18] B. J. Kirby, "Load Response Fundamentally Matches Power System Reliability Requirements", IEEE Power Engineering Society General Meeting, June 2007.

Designing a secure communication network for the reliable operation of micro-grids in the power grid
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