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ramesh kumawat

The document provides an overview of smart grids and their development. It discusses: 1) How today's power grids originated in the late 19th/early 20th century as local grids that grew over time and interconnected for reliability. By the 1960s, grids in developed nations were large, mature networks delivering power from thousands of central power plants. 2) The definition of a smart grid as a digitally enabled electrical grid that gathers, distributes, and acts on information from all participants to improve efficiency, reliability, and sustainability of electricity services. 3) Some key components of smart grids including intelligent appliances, smart meters, smart substations, super conducting cables, integrated communications networks, and phasor measurement units

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i A Seminar report On SMART GRID-FUTURE ELECTRIC GRID Submitted In partial full fillment For the award of the Degree of Bachelor of Technology Department of Electrical Engineering Supervisor: Submitted By: Mr. AMIT TANEJA Mr. DEV PRATAP MAHTO RAMESH KUMAWAT Ms. SHIVANI DWIVEDI (Assistant Professor) GOVT. ENGINEERINGCOLLEGE, AJMER Barliya circle, NH-08, Ajmer (Raj.) Rajasthan Technical University Session 2018-19
i Candidate’s Declaration I hereby declare that the work, which is being presented in the Seminar Report, entitled “Smart Grid-Future Electric Grid” in partial fulfilment for the award of Degree of “Bachelorof Technology” in Department of Electrical Engineering with Specialization in Mr. DEV PRATAP MAHTO, and submitted to the Department of Electrical Engineering, Govt. Engineering college, Ajmer, Rajasthan Technical University is a record of my own investigations carried under the Guidance of Mr. AMIT TANEJA, Mr. DEV PRATAP MAHTO, Ms. SHIVANI AAjmer. I have not submitted the matter presented in this report anywhere for the award of any other Degree. RAMESH KUMAWAT (15EEAEE036) B.Tech VIII SEM. (Electrical Engineering) Mr. AMIT TANEJA Mr.DEV PRATAP MAHTO Ms. SHIVANI DWIVEDI (Assistant Professor)
ii CERTIFICATE This is to certify that RAMESH KUMAWAT of VIII Semester, B.Tech (Electrical Engineering) 2015-2019, has presented a Seminar “Smart Grid-Future Electric Grid” in partial fulfillment for the award of the degree of Bachelor of Technology under Rajasthan Technical University, Kota. Date: 14/03/2019 Ms. SHIVANI DWIVEDI Seminar Co-ordinator Mr. DEV PRATAP MAHTO Supervisor Dr. K.G.SHARMA H.O.D Mr. AMIT TANEJA, Seminar Co-ordinator
iii ACKNOWLEDGMENET I take this opportunity to express my gratitude to all those people who have been directly and indirectly with me during the competition of this Seminar. I pay thank to Mr. DEV PRATAP MAHTO who has given guidance and a light to me during this Seminar. His versatile knowledge about “Smart grid-future Electric Grid” has eased me in the critical times during the span of this Seminar Report. I acknowledge here out debt to those who contributed significantly to one or more steps. Itake full responsibility forany remaining sins ofomission and commission. RAMESH KUMAWAT (15EEAEE036) B.Tech VIII SEM. (Electrical Engineering)
iv ABSTRACT Today's alternating current power grid evolved after 1896, based in part on Nikola Tesla's design published in 1888 (see War of Currents). At that time, the grid was conceived as a centralized unidirectional system of electric power transmission, electricity distribution, and demand-driven control. In the 20th century power grids originated as local grids that grew over time, and were eventually interconnected for economic and reliability reasons. By the1960s, the electric grids of developed countries had become very large, mature and highly interconnected, with thousands of 'central' generation power stations delivering power to major load centres via high capacity power lines which were then branched and divided to provide power to smaller industrial and domestic users over the entire supply area. The topology of the 1960s grid was are sult of the strong economies of scale of the current generation technology: large coal-, gas- and oil-fired power stations in the 1 GW (1000 MW) to 3 GW scale are still found to becost-effective, due to efficiency-boosting features that can be costeffectively added only when the stations become very large. A smart grid is a digitally enabled electrical grid that gathers, distributes, and acts on information about the behavior of all participants (suppliers and consumers) in order to improve the efficiency, importance, reliability, economics, and sustainability of electricity services
v Fig-Smart Grid Electricity Infrastructure
vi Table of Contents Candidate’s Declaration........................................................................................................i CERTIFICATE........................................................................................................................ii ACKNOWLEDGMENET.........................................................................................................iii ABSTRACT.......................................................................................................................... iv CHAPTER:- 1...................................................................................................................................1 INTRODUCTION.............................................................................................................................. 1 1.1 Historical development of the electricity grid.......................................................................... 1 1.2 Smart Grid ............................................................................................................................ 2 1.3 Overview of smart grid .......................................................................................................... 3 1.4 Smart Grid And it’s Need.......................................................................................................4 CHAPTER 2.....................................................................................................................................5 THE SMART GRID: COMPONENTS ....................................................................................................5 2.1 Smart Grid ............................................................................................................................ 5 Definition................................................................................................................................ 5 2.2 Smart Grid Components ........................................................................................................5 2.2.1 IntelligentAppliances:.....................................................................................................6 2.2.2 Smart Power Meters: ......................................................................................................6 2.2.3 Smart Substations:.......................................................................................................... 7 2.2.4 Super Conducting Cables:................................................................................................ 7 2.2.5 Integrated communications:............................................................................................ 8 2.2.6 Phasor Measurement Units (PMU):................................................................................ 10 CHAPTER 3................................................................................................................................... 11 ADVANTAGES AND DISADVANTAGES OF SMART GRID AND APPLICATIONS ..................................... 11 3.1 Benefits of Smart Grid ......................................................................................................... 11
vii 3.2 Disadvantages of Smart Grid................................................................................................ 11 3.2.1 Privacy Problems........................................................................................................... 11 3.2.2 Grid Volatility................................................................................................................ 12 3.3 Applications of Smart Grid................................................................................................ 12 3.4 IOT Based Electricity Energy Meter Reading Through Internet............................................... 13 CHAPTER 4................................................................................................................................... 15 SMART GRID IN INDIA................................................................................................................... 15 4.1 India Towards Smart Grid..................................................................................................... 15 4.2 Challenges Smart Grid In India Faced.................................................................................... 17 4.2.1.Environmental Impact:-................................................................................................. 17 4.2.2 Cost:- ........................................................................................................................... 18 4.2.3 Theft Control:-.............................................................................................................. 18 4.3 Need For Smart Grid In India............................................................................................... 18 4.3.1 Current Smart Grid activities in India are: ....................................................................... 19 CONCLUSION..................................................................................................................... 20 REFERENCES...................................................................................................................... 21
viii Table of Figures Fig-Smart Grid Electricity Infrastructure……………………………………..v Fig 1.1-Smart Grid…………………………………………………………….3 Fig 1.2- Power System………………………………………………………...4 Fig 2.1 Smart Grid Components………………………………………………6 fig 2.2 Smart Substations………………………………………………………7 Fig 2.3 Super Conducting Cables……………………………………………...8 Fig 2.4 SCADA………………………………………………………………..8 Fig 3.1 Block Diagram Of Smart Energy Meter Iot-Based Energy Meter……13 Fig 4.1 - Logical Domains and important elements of the Smart Grid………..17 Fig 4.2: - All levels of future Indian market information grid………………19
1 CHAPTER:- 1 INTRODUCTION 1.1 Historical development of the electricity grid Today's alternating current power grid evolved after 1896, based in part on Nikola Tesla's design published in 1888. At that time, the grid was conceived as a centralized unidirectional system of electric power transmission, electricity distribution, and demand-driven control. In the 20th century power grids originated as local grids that grew over time, and were eventually interconnected for economic and reliability reasons. By the1960s, the electric grids of developed countries had become very large, mature and highly interconnected, with thousands of 'central' generation power stations delivering power to major load centre via high capacity power lines which were then branched and divided to provide power to smaller industrial and domestic users over the entire supply area. The topology of the 1960s grid was are sult of the strong economies of scale of the current generation technology: large coal-, gas- and oil-fired power stations in the 1 GW (1000 MW) to 3 GW scale are still found to be cost-effective, due to efficiency-boosting features that can be cost effectively added only when the stations become very large. Power stations were located strategically to be close to fossil fuel reserves(either the mines or wells themselves, or else close to rail, road or port supply lines). Siting of hydro-electric dams in mountain areas also strongly influenced the structure of the emerging grid. Nuclear power plants were sited for availability of cooling water. Finally, fossil-fired power stations were initially very polluting and were sited as far as economically possible from population centres once electricity distribution networks permitted it. By the late
2 1960s, the electricity grid reached the overwhelming majority of the population of developed countries, with only outlying regional areas remaining 'off-grid' 1.2 Smart Grid Smart grid refers to the next generation electric power network that makes use of IT and high technologies. Compared to the telecommunication network, the electric power network has not developed remarkably in terms of creating innovative technologies. However, smart grid by revolutionizing the electric power network and being almost as powerful as the internet, is attracting many attentions among various industries. Smart grid is a system that enables two-way communications in between consumers and electric power companies. In a smart grid system consumer‘s information is received by the electric power companies in order to provide the most efficient electric network operations. In addition to the efficient operations of a power plant, smart grids also make it possible to control power demand and distributed energy, including renewable energies. By installing an intelligent meter (smart meter) on the consumer side, especially households, monitoring the use of energy becomes much easier and even helps to reduce carbon dioxide emissions. A smart grid delivers electricity from supplier to consumers using two- way digital technology to control appliances at consumers‘ homes to save energy, reduce cost and increase reliability and transparency. It overlays the electricity distribution grid with an information and net metering system. Power travels from the power plant to your house through an amazing system called the
3 power distribution grid. Sucha modernized electricity networks is being promoted by many governments as a way of addressing energy independences, global warming and emergency resilience issues. Smart meters may be part of smart grid, but alone do not constitute a smart grid. 1.3 Overview of smart grid A smart grid includes an intelligent monitoring system that keeps track of allelectricity flowing in the system. It also incorporates the use of superconductiv e transmission lines forless power loss, as well as the capability of the integrating renewable electricity such as solar and wind. When power is least expensive the user can allow the smart grid to turn on selected home appliances suchas washing machines orfactory processes that can run at arbitrary hours. At peak times it could turn off selected appliances to reduce demand. Fig1.1-Smart Grid
4 1.4 Smart Grid And it’s Need Understanding the need for smart grid requires acknowledging a few facts about our infrastructure. The power grid is the backbone of the modern civilization, a complex society with often conflicting energy needs-more electricity but fewer fossil fuels, increased reliability yet lower energy costs, more secure distribution with less maintenance, effective new construction and efficient disaster reconstruction. But while demand for electricity has risen drastically, its transmission is outdated and stressed. Thebottomline is that we are exacting more from a grid that is simply not up to the task. Fig1.2- Power System
5 CHAPTER 2 THE SMART GRID: COMPONENTS 2.1 Smart Grid Definition The Smart Grid is the modernization of the electricity delivery system. A smart grid differs from the traditional grid in that it allows two-way communication of electricity data, rather than a one way flow. Smart grids enable real time data collection concerning electricity supply and demand during the transmission and distribution process, making monitoring, generation, consumption and maintenance more efficient. Most electricity grids are based on one-way interaction from the stages of generation to consumption. Smart grids, on the other hand, integrate the action of all users in the power network using computer-based remote control and automation. This two-way interaction is what makes the grid “smart". Like the internet, the Smart Grid consists of controls, computers, automation, telecommunication and equipment that work together, but in this case, these technologies work with the electrical grid to respond digitally to our quickly changing electric demand 2.2 Smart Grid Components To achieve a modernized smart grid, a wide range of technologies should be developed and must be implemented. These technologies generally grouped into following key technology areas as discussed below.
6 2.2.1 Intelligent Appliances: Intelligent appliances have capable of deciding when to consume energy based on customer pre-set preferences. This can lead to going away along toward reducing peak loads which have an impact on electricity generation costs. For example, smart sensors, like temperature sensorwhich is used in thermal stations to control the boiler temperature based on predefined temperature levels. 2.2.2 Smart Power Meters: The smart meters provide two-way communication between power providers and the end user consumers to automate billing data collections, detect device failures and dispatch repair crews to the exact location much faster. Fig 2.1 Smart Grid Components
7 2.2.3 Smart Substations: substations are included monitoring and control non-critical and critical operational data suchas powerstatus, power factor performance, breaker, security, transformer status, etc. substations are used to transform voltage at several times in many locations, that providing safe and reliable delivery of energy. Smart substations are also necessary for splitting the path of electricity flow into many directions. Substations require large and very expensive equipment to operate, including transformers, switches, capacitor banks, circuit breakers, a network protected relays and several others. fig 2.2 Smart Substations 2.2.4 Super Conducting Cables: These are used to provide long distance power transmission, and automated monitoring and analysis tools capable of detecting faults itself or even predicting cable and failures based on real-time data weather, and the outage history.
8 Fig 2.3 Super Conducting Cables 2.2.5 Integrated communications: The key to a smart grid technology is integrated communications. It must be as fast as enough to real-time needs of the system. Depending upon the need, Many different technologies are used in smart grid communication like Programmable Logic Controller (PLC), wireless, cellular, SCADA (Supervisory Control and Data Acquisition), and BPL. Key Considerations for Integrated Communication. Fig 2.4 SCADA Key Considerations for Integrated Communication
9  Ease of deployment  Latency  Standards  Data carrying capacity  Secure  Network coverage capability Table 2.1 Key Considerations for Integrated Communication
10 2.2.6 Phasor Measurement Units (PMU): This is used to measure the electrical waves on an electricity grid using a common time sourcefor synchronization. The time synchronizer allows synchronized real- time measurements of multiple remote measurement points on the grid.
11 CHAPTER 3 ADVANTAGES AND DISADVANTAGES OF SMART GRID AND APPLICATIONS 3.1 Benefits of Smart Grid  Integrate isolated technologies: smart grid enables better energy management  Protective management of electrical network during emergency situation  Better demand, supply/ demand response  Better power quality  Reduce carbonemissions  Increased demand for energy: Requires more complex and critical solutions with better energy management  Renewables Integration 3.2 Disadvantages of Smart Grid 3.2.1 Privacy Problems The biggest concern is Security in a smart grid system. Grid system uses some smart meters, which are automated and provides communication between power provider and customer. Here some type of the smart meters can be easily hacked and they may control the power supply of a single building or an entire neighborhood.
12 3.2.2 Grid Volatility Smart Grid network has much intelligence at its edges; that is, at the entry point and at the end user’s meter. But the grid has insufficient intelligence in the middle, governing the switching functions. This lack of integrated development makes the grid a volatile network. Engineering resources have been poured into power generation and consumer energy consumption, which are the edges ofthe network. However, if too many nodes are added to the network before developing the software intelligence to control it, the conditions will lead to a volatile smart grid 3.3 Applications of Smart Grid Smart grid plays an important role in modern smart technologies. Following are the most common applications of smart grid technology. Future Applications and Services Real Time Market Business and customer care Application data flow to/ from end-user energy management systems Smart charging of PHEVs and V2G Application data flow for PHEVs Distributed generation and storage Monitoring of distributed assets Grid optimization Self-healing grid: fault protection, outage management, dynamic control of voltage, weather data integration, centralized capacitor bank control, distribution and substation automation, advanced sensing, automated feeder reconfiguration. Demand response Advanced demand maintenance and demand response, load forecasting, and shifting. AMI (Advanced metering infrastructure) Provides remote meter reading, theft detection, customer prepay, mobile workforce management
13 3.4 IOT Based Electricity Energy Meter Reading Through Internet The main objective of this project is to develop an IOT (internet of things) based energy meter reading displayed for units consumed and costforconsumption, over the internet in the chart and gauge format. In this project, we had taken a digital energy meter whose blinking LED signal is interfaced to a microcontroller of 8051 families through an LDR. Per 1 unit, The blinking LED flashes 3200 times. The LDR sensorgives an interrupt to the programmed microcontroller, at each time of the meter LED flashes. Fig 3.1 Block Diagram Of Smart Energy Meter Iot-Based Energy Meter The microcontroller takes this reading and displays it on an LCD duly interfaced to the microcontroller. This reading of the energy meter is also sent to a GSM modem being fed bythe microcontroller via level shifter IC and RS232 link. A SIM used in the modem being internet enabled transmits the data directly to a
14 dedicated web page for display or to the customer mobile phone, anywhere in the world in multi-level graphical format.
15 CHAPTER 4 SMART GRID IN INDIA 4.1 India Towards Smart Grid A "smart grid" is a concept for transforming a power grid, with the modern communication, automated checks and other forms of information technology. It integrates new, innovative tools and technologies of generation, transmission and distribution to home appliances and equipment. The urgency for Smart Grids in India arises from the challenges that the industry is currently in front. India operates the third largest transmission and distribution network in the world, still faces a number of challenges, such as: inadequate access to electricity supply shortages (peak and energy), high network losses, poorquality and reliability and rampant theft. The development towards Smart Grid would address these issues and to transform the existing network in an efficient, reliable, safe and less restricted grid that would help, access to electricity for all. Smart Grid integrated energy infrastructure, processes, devices, information and markets a coordinated and collaborative process that generates energy, distributed and can be used effectively and efficiently. A smart grid delivers electricity from suppliers to consumers using two-way digital technology to control appliances at consumers homes to save energy, reduce costs and increase reliability and transparency. It overlays the electricity distribution grid with an information and net metering system. Power travels from the power plant to your house through an amazing system called the power grid. As a modernized electricity network is being promoted by many governments, including the Government of India as a way of
16 addressing energy independence were, global warming and emergency resilience issues. Demand Side Management (DSM) is essential for an optimized and efficient use of electricity. Given limited resources, the main problem DSM is in the Indian system, where the demand is the identifies of the available generation, leading to reductions inevitably invite. DSM is the implementation of measures that effectively electricity to help the customers by using their peak load pattern. DSM can be achieved by: 1. Development and promotion of energy efficient technologies. 2. Improving the efficiency of various end use through increased energy utility correction leaks, system conversion. losses, etc. 3. Demand management through the introduction of softoptions like higher prices during peakperiods, at preferential rates during off-peak seasonrates, interruptible tariffs, etc. Advent of smart grid are performed for Indian markets for future; 1. Data management system that includes data standards and data management. 2. Secure Communications and standard protocols. 3. Retail player rising priorities and introduction to the services on the basis of network quality.
17 Fig4.1 - Logical Domains and important elements of the Smart Grid There are severalcompanies who take the initiatives for smart grid in India: a).Crompton Greaves smart grid initiatives. b).North Delhi Power Limited (NDPL) Smart Grid initiatives. c).Bangalore Electricity Supply Company. 4.2 Challenges Smart Grid In India Faced 4.2.1.Environmental Impact:- Smart Grid development in a very fast pace becauseof the wide interest of politics and utilities in reducing the adverse impact that happens the energy consumption on the environment. Since the maximum generation today in greenhouse gas
18 emissions, smart grids reduces the results of air pollution and plays a significant role in the fight against global climate change issue. 4.2.2 Cost:- The ability to bypass the cost of the plant and network expansion is a great advantage, both the utilities and customers and smart grids will not reduce fund expansion, of course; therefore invested heavily to set up a connection between the customer and the smart grid required. Energy efficiency would be the second priority in order to save the costs in terms of customer. 4.2.3 Theft Control:- This is not a problem in developed countries such as USA, but in developing countries like India, where people a glimpse of the grid and higher poverty rate, the electricity theft is quite common. With the development of smart grid electricity theft can be controlled to a greater extent, thereby improving the efficiency ofour distribution system. So Grids to create higher quality and reliable power supply, and it will be less power outages. 4.3 Need For Smart Grid In India According to the Ministry of Energy, the transmission and distribution losses in India among the highest in the world, averaging 26 percent of total electricity production, and as high as 62 percent in some states. These losses do not include non-technical losses such as theft etc.; If these losses are present, the average loss of 50 percent. Some of the technical deficiencies in the Indian power grid are - it is a poorly planned distribution network, there is an overload of the system components, it is the lack of reactive power supportand regulation services. India is rapidly venturing into renewable energy (RE) resources suchas wind and solar.
19 The government will also provideincentives for solar powergeneration in the form of subsidies for various solar applications. A gap of renewable raw materials is that their supply may be interrupted, ie the offer may only during a certain time of the day, these conditions can not be controlled be harnessed. For this reason, it is necessary to have a grid that is very adaptable (in terms of supply and demand) to have. Therefore, the opportunities for the development of smart grids in India are immense, like a good power supply is one of the most important infrastructure requirements to support the overall development. 4.3.1 Current Smart Grid activities in India are: 1.DRUM India - Distribution Reform upgrade management. 2. Four pilot sites (North Delhi, Bangalore, Gujarat, Maharashtra). 3. Smart Grid Vision for India. 4. Smart Grid Task Force - headed by Sam Pitroda. 5. Project BESCOM- Bangalore- integration of renewable and decentralized energy sources in power grid. Fig4.2: - All levels of future Indian market information grid
20 CONCLUSION With the growing world population and thus increasing demand and the need for resource-depleting intelligent and efficient in our energy consumption has to have become an imperative. Implementation of the smart grid concept would go a long way in solving many of today's energy issues and problems. The entire network needs to be improved to meet the requirements, ie transmission and distribution level requirements. Research continue to find to make all the desired properties possiblethe optimal solution and new technologies. Through the use of smart grid technology, energy can be used up to and would not be wasted. This technology also helps to save the earth from global warming. It refers to the modernized version of the earlier traditional methods of energy supply. Smart meters, Smart Homes, Smart City and so would make the Smart Grid. As the new technologies would be invented and strengthened existing ones to the desired specifications meet the Smart Grid would be reality and change the whole pattern of energy in the world.
21 REFERENCES [1]. Y. Pradeep, S. A. Khaparde, R. Kumar, “Intelligent Grid Initiatives in India,” IEEE Intl. Conf. on Intelligent Systems Applications to Power Systems, pp. 1-6, Nov. 2007. [2]. Forthcoming: Future Energy,” Improved, Sustainableand Clean Optionsfor our Planet”, Elsevier Science; 2 edition (January 7, 2014). [3]. Galen Koepke (chair),”Electromagnetic Compatibilityand SmartGrid Interoperability Issues”, December 5,2012. [4]. Power Trends:2013,”Alternating Currents”, New York Independent System Operator. [5]. V S K Murthy Balijepalli, S.A Khaparde, R.P Gupta, Yemula Pradeep, “SmartGrid Initiatives and Power Market in India”, IEEE transactions on electronics with Crompton Greaves, 2010. [6]. V S K Murthy Balijepalli, S A Khaparde, R P Gupta, “TowardsIndian Smart Grid”, IEEE transactions on Smart Grid, vol. 2, no. 1, pp. 110-120, March 2011. [7]. David J. Leeds, “TheSmartGrid in 2010:Market Segments, Applications and Industry Players”, GTM Research, July 2009. [8]. Vikas Pawar, Amit Manocha, Dr. H.M Rai, “SmartGrid- Internet of Future Technology for Electrical Energy”, International Journal of Applied Engineering Research, ISSN 0973-4562 vol..7 No.11 (2012). [9]. Robert Moreo, Yuchen Mao, “TheSmartGrid: A Business Sector Studyand Economic Development Opportunitiesfor Michigan”, Wayne State University, State, Regional and Local Economic Development- UP6550, May 04,2010. [10].“SmartGrid System Report”, U.S Department of Energy, July 2009.
22 [11 ]. Jerry Jackson, “SmartGrid:An Optimized Electric Power System”, Forthcoming: Future Energy, Second Edition: Improved, Sustainable and Clean options for our Planet, Elsevier Science; 2nd edition, January 7,2014

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smart grid seminar report

  • 1. i A Seminar report On SMART GRID-FUTURE ELECTRIC GRID Submitted In partial full fillment For the award of the Degree of Bachelor of Technology Department of Electrical Engineering Supervisor: Submitted By: Mr. AMIT TANEJA Mr. DEV PRATAP MAHTO RAMESH KUMAWAT Ms. SHIVANI DWIVEDI (Assistant Professor) GOVT. ENGINEERINGCOLLEGE, AJMER Barliya circle, NH-08, Ajmer (Raj.) Rajasthan Technical University Session 2018-19
  • 2. i Candidate’s Declaration I hereby declare that the work, which is being presented in the Seminar Report, entitled “Smart Grid-Future Electric Grid” in partial fulfilment for the award of Degree of “Bachelorof Technology” in Department of Electrical Engineering with Specialization in Mr. DEV PRATAP MAHTO, and submitted to the Department of Electrical Engineering, Govt. Engineering college, Ajmer, Rajasthan Technical University is a record of my own investigations carried under the Guidance of Mr. AMIT TANEJA, Mr. DEV PRATAP MAHTO, Ms. SHIVANI AAjmer. I have not submitted the matter presented in this report anywhere for the award of any other Degree. RAMESH KUMAWAT (15EEAEE036) B.Tech VIII SEM. (Electrical Engineering) Mr. AMIT TANEJA Mr.DEV PRATAP MAHTO Ms. SHIVANI DWIVEDI (Assistant Professor)
  • 3. ii CERTIFICATE This is to certify that RAMESH KUMAWAT of VIII Semester, B.Tech (Electrical Engineering) 2015-2019, has presented a Seminar “Smart Grid-Future Electric Grid” in partial fulfillment for the award of the degree of Bachelor of Technology under Rajasthan Technical University, Kota. Date: 14/03/2019 Ms. SHIVANI DWIVEDI Seminar Co-ordinator Mr. DEV PRATAP MAHTO Supervisor Dr. K.G.SHARMA H.O.D Mr. AMIT TANEJA, Seminar Co-ordinator
  • 4. iii ACKNOWLEDGMENET I take this opportunity to express my gratitude to all those people who have been directly and indirectly with me during the competition of this Seminar. I pay thank to Mr. DEV PRATAP MAHTO who has given guidance and a light to me during this Seminar. His versatile knowledge about “Smart grid-future Electric Grid” has eased me in the critical times during the span of this Seminar Report. I acknowledge here out debt to those who contributed significantly to one or more steps. Itake full responsibility forany remaining sins ofomission and commission. RAMESH KUMAWAT (15EEAEE036) B.Tech VIII SEM. (Electrical Engineering)
  • 5. iv ABSTRACT Today's alternating current power grid evolved after 1896, based in part on Nikola Tesla's design published in 1888 (see War of Currents). At that time, the grid was conceived as a centralized unidirectional system of electric power transmission, electricity distribution, and demand-driven control. In the 20th century power grids originated as local grids that grew over time, and were eventually interconnected for economic and reliability reasons. By the1960s, the electric grids of developed countries had become very large, mature and highly interconnected, with thousands of 'central' generation power stations delivering power to major load centres via high capacity power lines which were then branched and divided to provide power to smaller industrial and domestic users over the entire supply area. The topology of the 1960s grid was are sult of the strong economies of scale of the current generation technology: large coal-, gas- and oil-fired power stations in the 1 GW (1000 MW) to 3 GW scale are still found to becost-effective, due to efficiency-boosting features that can be costeffectively added only when the stations become very large. A smart grid is a digitally enabled electrical grid that gathers, distributes, and acts on information about the behavior of all participants (suppliers and consumers) in order to improve the efficiency, importance, reliability, economics, and sustainability of electricity services
  • 7. vi Table of Contents Candidate’s Declaration........................................................................................................i CERTIFICATE........................................................................................................................ii ACKNOWLEDGMENET.........................................................................................................iii ABSTRACT.......................................................................................................................... iv CHAPTER:- 1...................................................................................................................................1 INTRODUCTION.............................................................................................................................. 1 1.1 Historical development of the electricity grid.......................................................................... 1 1.2 Smart Grid ............................................................................................................................ 2 1.3 Overview of smart grid .......................................................................................................... 3 1.4 Smart Grid And it’s Need.......................................................................................................4 CHAPTER 2.....................................................................................................................................5 THE SMART GRID: COMPONENTS ....................................................................................................5 2.1 Smart Grid ............................................................................................................................ 5 Definition................................................................................................................................ 5 2.2 Smart Grid Components ........................................................................................................5 2.2.1 IntelligentAppliances:.....................................................................................................6 2.2.2 Smart Power Meters: ......................................................................................................6 2.2.3 Smart Substations:.......................................................................................................... 7 2.2.4 Super Conducting Cables:................................................................................................ 7 2.2.5 Integrated communications:............................................................................................ 8 2.2.6 Phasor Measurement Units (PMU):................................................................................ 10 CHAPTER 3................................................................................................................................... 11 ADVANTAGES AND DISADVANTAGES OF SMART GRID AND APPLICATIONS ..................................... 11 3.1 Benefits of Smart Grid ......................................................................................................... 11
  • 8. vii 3.2 Disadvantages of Smart Grid................................................................................................ 11 3.2.1 Privacy Problems........................................................................................................... 11 3.2.2 Grid Volatility................................................................................................................ 12 3.3 Applications of Smart Grid................................................................................................ 12 3.4 IOT Based Electricity Energy Meter Reading Through Internet............................................... 13 CHAPTER 4................................................................................................................................... 15 SMART GRID IN INDIA................................................................................................................... 15 4.1 India Towards Smart Grid..................................................................................................... 15 4.2 Challenges Smart Grid In India Faced.................................................................................... 17 4.2.1.Environmental Impact:-................................................................................................. 17 4.2.2 Cost:- ........................................................................................................................... 18 4.2.3 Theft Control:-.............................................................................................................. 18 4.3 Need For Smart Grid In India............................................................................................... 18 4.3.1 Current Smart Grid activities in India are: ....................................................................... 19 CONCLUSION..................................................................................................................... 20 REFERENCES...................................................................................................................... 21
  • 9. viii Table of Figures Fig-Smart Grid Electricity Infrastructure……………………………………..v Fig 1.1-Smart Grid…………………………………………………………….3 Fig 1.2- Power System………………………………………………………...4 Fig 2.1 Smart Grid Components………………………………………………6 fig 2.2 Smart Substations………………………………………………………7 Fig 2.3 Super Conducting Cables……………………………………………...8 Fig 2.4 SCADA………………………………………………………………..8 Fig 3.1 Block Diagram Of Smart Energy Meter Iot-Based Energy Meter……13 Fig 4.1 - Logical Domains and important elements of the Smart Grid………..17 Fig 4.2: - All levels of future Indian market information grid………………19
  • 10. 1 CHAPTER:- 1 INTRODUCTION 1.1 Historical development of the electricity grid Today's alternating current power grid evolved after 1896, based in part on Nikola Tesla's design published in 1888. At that time, the grid was conceived as a centralized unidirectional system of electric power transmission, electricity distribution, and demand-driven control. In the 20th century power grids originated as local grids that grew over time, and were eventually interconnected for economic and reliability reasons. By the1960s, the electric grids of developed countries had become very large, mature and highly interconnected, with thousands of 'central' generation power stations delivering power to major load centre via high capacity power lines which were then branched and divided to provide power to smaller industrial and domestic users over the entire supply area. The topology of the 1960s grid was are sult of the strong economies of scale of the current generation technology: large coal-, gas- and oil-fired power stations in the 1 GW (1000 MW) to 3 GW scale are still found to be cost-effective, due to efficiency-boosting features that can be cost effectively added only when the stations become very large. Power stations were located strategically to be close to fossil fuel reserves(either the mines or wells themselves, or else close to rail, road or port supply lines). Siting of hydro-electric dams in mountain areas also strongly influenced the structure of the emerging grid. Nuclear power plants were sited for availability of cooling water. Finally, fossil-fired power stations were initially very polluting and were sited as far as economically possible from population centres once electricity distribution networks permitted it. By the late
  • 11. 2 1960s, the electricity grid reached the overwhelming majority of the population of developed countries, with only outlying regional areas remaining 'off-grid' 1.2 Smart Grid Smart grid refers to the next generation electric power network that makes use of IT and high technologies. Compared to the telecommunication network, the electric power network has not developed remarkably in terms of creating innovative technologies. However, smart grid by revolutionizing the electric power network and being almost as powerful as the internet, is attracting many attentions among various industries. Smart grid is a system that enables two-way communications in between consumers and electric power companies. In a smart grid system consumer‘s information is received by the electric power companies in order to provide the most efficient electric network operations. In addition to the efficient operations of a power plant, smart grids also make it possible to control power demand and distributed energy, including renewable energies. By installing an intelligent meter (smart meter) on the consumer side, especially households, monitoring the use of energy becomes much easier and even helps to reduce carbon dioxide emissions. A smart grid delivers electricity from supplier to consumers using two- way digital technology to control appliances at consumers‘ homes to save energy, reduce cost and increase reliability and transparency. It overlays the electricity distribution grid with an information and net metering system. Power travels from the power plant to your house through an amazing system called the
  • 12. 3 power distribution grid. Sucha modernized electricity networks is being promoted by many governments as a way of addressing energy independences, global warming and emergency resilience issues. Smart meters may be part of smart grid, but alone do not constitute a smart grid. 1.3 Overview of smart grid A smart grid includes an intelligent monitoring system that keeps track of allelectricity flowing in the system. It also incorporates the use of superconductiv e transmission lines forless power loss, as well as the capability of the integrating renewable electricity such as solar and wind. When power is least expensive the user can allow the smart grid to turn on selected home appliances suchas washing machines orfactory processes that can run at arbitrary hours. At peak times it could turn off selected appliances to reduce demand. Fig1.1-Smart Grid
  • 13. 4 1.4 Smart Grid And it’s Need Understanding the need for smart grid requires acknowledging a few facts about our infrastructure. The power grid is the backbone of the modern civilization, a complex society with often conflicting energy needs-more electricity but fewer fossil fuels, increased reliability yet lower energy costs, more secure distribution with less maintenance, effective new construction and efficient disaster reconstruction. But while demand for electricity has risen drastically, its transmission is outdated and stressed. Thebottomline is that we are exacting more from a grid that is simply not up to the task. Fig1.2- Power System
  • 14. 5 CHAPTER 2 THE SMART GRID: COMPONENTS 2.1 Smart Grid Definition The Smart Grid is the modernization of the electricity delivery system. A smart grid differs from the traditional grid in that it allows two-way communication of electricity data, rather than a one way flow. Smart grids enable real time data collection concerning electricity supply and demand during the transmission and distribution process, making monitoring, generation, consumption and maintenance more efficient. Most electricity grids are based on one-way interaction from the stages of generation to consumption. Smart grids, on the other hand, integrate the action of all users in the power network using computer-based remote control and automation. This two-way interaction is what makes the grid “smart". Like the internet, the Smart Grid consists of controls, computers, automation, telecommunication and equipment that work together, but in this case, these technologies work with the electrical grid to respond digitally to our quickly changing electric demand 2.2 Smart Grid Components To achieve a modernized smart grid, a wide range of technologies should be developed and must be implemented. These technologies generally grouped into following key technology areas as discussed below.
  • 15. 6 2.2.1 Intelligent Appliances: Intelligent appliances have capable of deciding when to consume energy based on customer pre-set preferences. This can lead to going away along toward reducing peak loads which have an impact on electricity generation costs. For example, smart sensors, like temperature sensorwhich is used in thermal stations to control the boiler temperature based on predefined temperature levels. 2.2.2 Smart Power Meters: The smart meters provide two-way communication between power providers and the end user consumers to automate billing data collections, detect device failures and dispatch repair crews to the exact location much faster. Fig 2.1 Smart Grid Components
  • 16. 7 2.2.3 Smart Substations: substations are included monitoring and control non-critical and critical operational data suchas powerstatus, power factor performance, breaker, security, transformer status, etc. substations are used to transform voltage at several times in many locations, that providing safe and reliable delivery of energy. Smart substations are also necessary for splitting the path of electricity flow into many directions. Substations require large and very expensive equipment to operate, including transformers, switches, capacitor banks, circuit breakers, a network protected relays and several others. fig 2.2 Smart Substations 2.2.4 Super Conducting Cables: These are used to provide long distance power transmission, and automated monitoring and analysis tools capable of detecting faults itself or even predicting cable and failures based on real-time data weather, and the outage history.
  • 17. 8 Fig 2.3 Super Conducting Cables 2.2.5 Integrated communications: The key to a smart grid technology is integrated communications. It must be as fast as enough to real-time needs of the system. Depending upon the need, Many different technologies are used in smart grid communication like Programmable Logic Controller (PLC), wireless, cellular, SCADA (Supervisory Control and Data Acquisition), and BPL. Key Considerations for Integrated Communication. Fig 2.4 SCADA Key Considerations for Integrated Communication
  • 18. 9  Ease of deployment  Latency  Standards  Data carrying capacity  Secure  Network coverage capability Table 2.1 Key Considerations for Integrated Communication
  • 19. 10 2.2.6 Phasor Measurement Units (PMU): This is used to measure the electrical waves on an electricity grid using a common time sourcefor synchronization. The time synchronizer allows synchronized real- time measurements of multiple remote measurement points on the grid.
  • 20. 11 CHAPTER 3 ADVANTAGES AND DISADVANTAGES OF SMART GRID AND APPLICATIONS 3.1 Benefits of Smart Grid  Integrate isolated technologies: smart grid enables better energy management  Protective management of electrical network during emergency situation  Better demand, supply/ demand response  Better power quality  Reduce carbonemissions  Increased demand for energy: Requires more complex and critical solutions with better energy management  Renewables Integration 3.2 Disadvantages of Smart Grid 3.2.1 Privacy Problems The biggest concern is Security in a smart grid system. Grid system uses some smart meters, which are automated and provides communication between power provider and customer. Here some type of the smart meters can be easily hacked and they may control the power supply of a single building or an entire neighborhood.
  • 21. 12 3.2.2 Grid Volatility Smart Grid network has much intelligence at its edges; that is, at the entry point and at the end user’s meter. But the grid has insufficient intelligence in the middle, governing the switching functions. This lack of integrated development makes the grid a volatile network. Engineering resources have been poured into power generation and consumer energy consumption, which are the edges ofthe network. However, if too many nodes are added to the network before developing the software intelligence to control it, the conditions will lead to a volatile smart grid 3.3 Applications of Smart Grid Smart grid plays an important role in modern smart technologies. Following are the most common applications of smart grid technology. Future Applications and Services Real Time Market Business and customer care Application data flow to/ from end-user energy management systems Smart charging of PHEVs and V2G Application data flow for PHEVs Distributed generation and storage Monitoring of distributed assets Grid optimization Self-healing grid: fault protection, outage management, dynamic control of voltage, weather data integration, centralized capacitor bank control, distribution and substation automation, advanced sensing, automated feeder reconfiguration. Demand response Advanced demand maintenance and demand response, load forecasting, and shifting. AMI (Advanced metering infrastructure) Provides remote meter reading, theft detection, customer prepay, mobile workforce management
  • 22. 13 3.4 IOT Based Electricity Energy Meter Reading Through Internet The main objective of this project is to develop an IOT (internet of things) based energy meter reading displayed for units consumed and costforconsumption, over the internet in the chart and gauge format. In this project, we had taken a digital energy meter whose blinking LED signal is interfaced to a microcontroller of 8051 families through an LDR. Per 1 unit, The blinking LED flashes 3200 times. The LDR sensorgives an interrupt to the programmed microcontroller, at each time of the meter LED flashes. Fig 3.1 Block Diagram Of Smart Energy Meter Iot-Based Energy Meter The microcontroller takes this reading and displays it on an LCD duly interfaced to the microcontroller. This reading of the energy meter is also sent to a GSM modem being fed bythe microcontroller via level shifter IC and RS232 link. A SIM used in the modem being internet enabled transmits the data directly to a
  • 23. 14 dedicated web page for display or to the customer mobile phone, anywhere in the world in multi-level graphical format.
  • 24. 15 CHAPTER 4 SMART GRID IN INDIA 4.1 India Towards Smart Grid A "smart grid" is a concept for transforming a power grid, with the modern communication, automated checks and other forms of information technology. It integrates new, innovative tools and technologies of generation, transmission and distribution to home appliances and equipment. The urgency for Smart Grids in India arises from the challenges that the industry is currently in front. India operates the third largest transmission and distribution network in the world, still faces a number of challenges, such as: inadequate access to electricity supply shortages (peak and energy), high network losses, poorquality and reliability and rampant theft. The development towards Smart Grid would address these issues and to transform the existing network in an efficient, reliable, safe and less restricted grid that would help, access to electricity for all. Smart Grid integrated energy infrastructure, processes, devices, information and markets a coordinated and collaborative process that generates energy, distributed and can be used effectively and efficiently. A smart grid delivers electricity from suppliers to consumers using two-way digital technology to control appliances at consumers homes to save energy, reduce costs and increase reliability and transparency. It overlays the electricity distribution grid with an information and net metering system. Power travels from the power plant to your house through an amazing system called the power grid. As a modernized electricity network is being promoted by many governments, including the Government of India as a way of
  • 25. 16 addressing energy independence were, global warming and emergency resilience issues. Demand Side Management (DSM) is essential for an optimized and efficient use of electricity. Given limited resources, the main problem DSM is in the Indian system, where the demand is the identifies of the available generation, leading to reductions inevitably invite. DSM is the implementation of measures that effectively electricity to help the customers by using their peak load pattern. DSM can be achieved by: 1. Development and promotion of energy efficient technologies. 2. Improving the efficiency of various end use through increased energy utility correction leaks, system conversion. losses, etc. 3. Demand management through the introduction of softoptions like higher prices during peakperiods, at preferential rates during off-peak seasonrates, interruptible tariffs, etc. Advent of smart grid are performed for Indian markets for future; 1. Data management system that includes data standards and data management. 2. Secure Communications and standard protocols. 3. Retail player rising priorities and introduction to the services on the basis of network quality.
  • 26. 17 Fig4.1 - Logical Domains and important elements of the Smart Grid There are severalcompanies who take the initiatives for smart grid in India: a).Crompton Greaves smart grid initiatives. b).North Delhi Power Limited (NDPL) Smart Grid initiatives. c).Bangalore Electricity Supply Company. 4.2 Challenges Smart Grid In India Faced 4.2.1.Environmental Impact:- Smart Grid development in a very fast pace becauseof the wide interest of politics and utilities in reducing the adverse impact that happens the energy consumption on the environment. Since the maximum generation today in greenhouse gas
  • 27. 18 emissions, smart grids reduces the results of air pollution and plays a significant role in the fight against global climate change issue. 4.2.2 Cost:- The ability to bypass the cost of the plant and network expansion is a great advantage, both the utilities and customers and smart grids will not reduce fund expansion, of course; therefore invested heavily to set up a connection between the customer and the smart grid required. Energy efficiency would be the second priority in order to save the costs in terms of customer. 4.2.3 Theft Control:- This is not a problem in developed countries such as USA, but in developing countries like India, where people a glimpse of the grid and higher poverty rate, the electricity theft is quite common. With the development of smart grid electricity theft can be controlled to a greater extent, thereby improving the efficiency ofour distribution system. So Grids to create higher quality and reliable power supply, and it will be less power outages. 4.3 Need For Smart Grid In India According to the Ministry of Energy, the transmission and distribution losses in India among the highest in the world, averaging 26 percent of total electricity production, and as high as 62 percent in some states. These losses do not include non-technical losses such as theft etc.; If these losses are present, the average loss of 50 percent. Some of the technical deficiencies in the Indian power grid are - it is a poorly planned distribution network, there is an overload of the system components, it is the lack of reactive power supportand regulation services. India is rapidly venturing into renewable energy (RE) resources suchas wind and solar.
  • 28. 19 The government will also provideincentives for solar powergeneration in the form of subsidies for various solar applications. A gap of renewable raw materials is that their supply may be interrupted, ie the offer may only during a certain time of the day, these conditions can not be controlled be harnessed. For this reason, it is necessary to have a grid that is very adaptable (in terms of supply and demand) to have. Therefore, the opportunities for the development of smart grids in India are immense, like a good power supply is one of the most important infrastructure requirements to support the overall development. 4.3.1 Current Smart Grid activities in India are: 1.DRUM India - Distribution Reform upgrade management. 2. Four pilot sites (North Delhi, Bangalore, Gujarat, Maharashtra). 3. Smart Grid Vision for India. 4. Smart Grid Task Force - headed by Sam Pitroda. 5. Project BESCOM- Bangalore- integration of renewable and decentralized energy sources in power grid. Fig4.2: - All levels of future Indian market information grid
  • 29. 20 CONCLUSION With the growing world population and thus increasing demand and the need for resource-depleting intelligent and efficient in our energy consumption has to have become an imperative. Implementation of the smart grid concept would go a long way in solving many of today's energy issues and problems. The entire network needs to be improved to meet the requirements, ie transmission and distribution level requirements. Research continue to find to make all the desired properties possiblethe optimal solution and new technologies. Through the use of smart grid technology, energy can be used up to and would not be wasted. This technology also helps to save the earth from global warming. It refers to the modernized version of the earlier traditional methods of energy supply. Smart meters, Smart Homes, Smart City and so would make the Smart Grid. As the new technologies would be invented and strengthened existing ones to the desired specifications meet the Smart Grid would be reality and change the whole pattern of energy in the world.
  • 30. 21 REFERENCES [1]. Y. Pradeep, S. A. Khaparde, R. Kumar, “Intelligent Grid Initiatives in India,” IEEE Intl. Conf. on Intelligent Systems Applications to Power Systems, pp. 1-6, Nov. 2007. [2]. Forthcoming: Future Energy,” Improved, Sustainableand Clean Optionsfor our Planet”, Elsevier Science; 2 edition (January 7, 2014). [3]. Galen Koepke (chair),”Electromagnetic Compatibilityand SmartGrid Interoperability Issues”, December 5,2012. [4]. Power Trends:2013,”Alternating Currents”, New York Independent System Operator. [5]. V S K Murthy Balijepalli, S.A Khaparde, R.P Gupta, Yemula Pradeep, “SmartGrid Initiatives and Power Market in India”, IEEE transactions on electronics with Crompton Greaves, 2010. [6]. V S K Murthy Balijepalli, S A Khaparde, R P Gupta, “TowardsIndian Smart Grid”, IEEE transactions on Smart Grid, vol. 2, no. 1, pp. 110-120, March 2011. [7]. David J. Leeds, “TheSmartGrid in 2010:Market Segments, Applications and Industry Players”, GTM Research, July 2009. [8]. Vikas Pawar, Amit Manocha, Dr. H.M Rai, “SmartGrid- Internet of Future Technology for Electrical Energy”, International Journal of Applied Engineering Research, ISSN 0973-4562 vol..7 No.11 (2012). [9]. Robert Moreo, Yuchen Mao, “TheSmartGrid: A Business Sector Studyand Economic Development Opportunitiesfor Michigan”, Wayne State University, State, Regional and Local Economic Development- UP6550, May 04,2010. [10].“SmartGrid System Report”, U.S Department of Energy, July 2009.
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