Smart Grids as Cyber Physical Systems, 2 Volume Set
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Persons
O. V. Gnana Swathika, PhD received a PhD in electrical engineering from Vellore Institute of Technology University, Chennai, Tamilnadu, India, in 2017. She also completed her post-doctoral studies at the University of Moratuwa, Sri Lanka in 2019. Her current research interests include microgrid protection and energy management systems.
K. Karthikeyan is the chief engineering manager of electrical designs for Larsen and Toubro Construction, a multinational Indian contracting company. He has two decades of experience in electrical design and has contributed to several projects including the Building airports, railway stations and depots, hospitals, and educational buildings in India and abroad. His primary role involves preparing and reviewing complete electrical system designs up to 110KV voltage levels, acting as a point of contact between clients and projects teams, peer review, and project management.
Sanjeevikumar Padmanaban, PhD is a faculty member in the Department of Energy Technology, Aalborg University, Esbjerg, Denmark. He has authored over three hundred scientific papers and an editor for several academic journals. He is a fellow of the Institution of Engineers, India, the Institution of Electronics and Telecommunication Engineers, India, and the Institution of Engineering and Technology, U.K.
Content
Preface xvii
1 Grid Independent Dynamic Charging of EV Batteries Using Solar Energy 1
P. Balamurugan, Tekumalla Lakshmi Sowjanya, Manas Goyan, J.L. Febin Daya and V. Ananthakrishnan
2 RS-11-I Design and Control of Solar-Battery-Based Microgrid System 13
Buddhadeva Sahoo, Subhransu Ranjan Samantaray, PravatKumar Rout and Pritam Bhowmik
3 A Novel Concept of Hybrid Storage Integrated Smart Grid System with Integrated SoC Management Scheme 29
Pritam Bhowmik, Priya Ranjan Satpathy, Soubhik Bagchi and Buddhadeva Sahoo
4 Parameters Sensitivity of Solar Photovoltaic Array Architectures under Incremental Row and Column Shading 41
Priya Ranjan Satpathy, Sudhakar Babu Thanikanti, Belqasem Aljafari and Pritam Bhowmik
5 Controlled Smart Robotic Arm for Optimized Movement in Pharma Application 55
Deepa Thangavelusamy, Kripalakshmi Thiagarajan, S. Angalaeswari, D. Subbulekshmi, A.R. Kalaiarasi, SambitPattnaik and Preetam Singh Chauhan
6 An Exploration of Internet of Everything in Smart Universe 69
Karmel Arockiasamy, Kanimozhi G. and Umamaheswari E.
7 An Intelligent Smart Grid Switching System for an Efficient Load Balancing Through Machine Learning Models 111
Aditya Sundarajan, Jaideepnath Anand S., Ruthul Jindal S. and MaheswariR.
8 Hybrid Energy Storage System for Battery-Powered ElectricVehicles 123
G. Jegadeeswari and D. Lakshmi
9 FPGA-Based Smart Building Access Control 137
Sakthi Ram T., Yogesh L., Vetriashwath S., Nishanth G. and O.V. Gnana Swathika
10 Artificial Hyperintelligence-Enabled Cyber-Physical System Control for Autonomous Vehicles 145
S. Srithar, Vetrimani E., Kumbala Pradeep Reddy, Sarangam Kodati and S. Alagumuthukrishnan
11 FPGA-Based Smart Delivery Bot 163
Sakthi Ram T., Yogesh L., Vetriashwath S., Nishanth G. and O.V. Gnana Swathika
12 Cabin Cooling System for Heavy Commercial Load Vehicle 173
Aditya Burde, Samridhi and P. Sriramalakshmi
13 Renewable Energy and Its Dynamic Value 185
Abhinav Koushik and Milind Shrinivas Dangate
14 Energy Resources and Reliability Assessments 199
Kavinkumar Ravikumar and Milind Shrinivas Dangate
15 Electric Vehicle Charging Stations Effect on Battery Storage Technology 215
Sathya Narayanan and Milind Shrinivas Dangate
16 Photovoltaic Technology and Environmental Impact 227
Kavinkumar Ravikumar and Milind Shrinivas Dangate
17 Transparent Photovoltaics and Environmental Impact 247
Kavinkumar Ravikumar and Milind Shrinivas Dangate
18 Design of Greedy Approach-Based Vulnerability Detection Framework for Smart Grid Systems 275
Manas Kumar Yogi, Sai Pathrudu Lanka Vatapatra, Navya Sri Medapati, Devi Krishna Arumilli and Vaishnavi Lingam
19 Smart Grid Technology Development and Intellectual Property Law Protection: Opportunities and Challenges 295
E. Prema and S. Suganya
20 Architecture for Transactive Energy Management Systems with Different Market Clearing Strategies in Smart Grid 315
Arun S. L. and Vijayapriya Ramachandran
21 Recommending Medical Specialist and Detecting Point of Discomfort Using Computer Vision and Machine Learning 337
Shourya Gupta, Ritik Vashist, Ridhika Sahni, Kshitij Dwivedi, Sam Methuselah Penumala and Karmel Arockiasamy
22 Reliability Assessment and Reliability Improvement of System by High Renewable Penetration 349
Satyaki Biswas, Sadasiva Behera and Nalin. B. Dev Choudhury
23 Distance Measurement Using Ultrasonic Sensor 369
Rajesh Babu Damala, Rajesh Kumar Patnaik and Praveen Korla
References 376
Index 377
1
Grid Independent Dynamic Charging of EV Batteries Using Solar Energy
P. Balamurugan1*, Tekumalla Lakshmi Sowjanya2, Manas Goyan2, J.L. Febin Daya1 and V. Ananthakrishnan3
1eVITRC, Vellore Institute of Technology - Chennai, Tamil Nadu, India
2VIT-Bhopal University, Madhya Pradesh, India
3School of Electrical Engineering, Vellore Institute of Technology - Chennai, Tamil Nadu, India
Abstract
This research aims to utilize energy emitted by the sun as a source to charge an electric car and to eliminate the need for installing more charging stations to save electricity. The proposed concept of dynamic charging from solar source minimizes carbon footprint. The concept can be applied in a wide range by installing flexible solar panels that are available commercially in the market. This concept enables embedding the flexible panels during the manufacturing stage and widespread utilization of available solar energy surplus. This will reduce the consumption of electricity generated from conventional energy sources to charge the electric vehicles. The dynamic charging will also extend the range provided by the battery per charge cycle improving the reliability of the electric vehicle.
Keywords: EV charging, dynamic charging, flexible PV panels, boost converter
1.1 Introduction
Climate changes due to emission of CO2 from remnant fuels is a major concern in recent years. This enabled electrical engineers and researchers to look out for alternate sources of energy like solar farms, wind farms, and other sources like biomass. Vehicles are the primary sources where the CO2 emission is present everywhere compared to large industries where it is localized and regulated. Hence, electric vehicles (EV) came into picture, resulting in rapid manufacturing and production of EVs. The use of additional battery storage in automotive systems for supplying the power train and internal utilities extending the range of operation influencing economic challenges is the next challenge. As a promising technology and preference, harvesting renewable energy resources is a boon for both EV industries and the transportation sector. Charging batteries and similar storage systems directly from renewable resources increases the reliability of the battery-operated vehicles. Utilizing energy from alternative energy resources as an alternative to conventional electric network to run the EV is perceived to expand the complete system efficacy and diminish carbon footprint.
Energy from photovoltaic (PV) panels are progressively competing with other forms of renewable sources of energy due to its splendid nature and is easily extractable. Hence, the adaptability of e-transportation is facilitated much by PV sources. In recent days, utilizing PV as a primary source of energy is adapted from small scale to large industries, airports, and residential applications. Since it exhibits lesser maneuver cost and maintenance, low greenhouse gas emanations, and self-governing capability, PV is adopted everywhere. Vast exploration of technology has been adopted lately to charge EV with energy from solar. Many countries have initiated design standards for PV systems.
Analyzing the current scenario and forthcoming challenges in the implementation of EV and charging systems, it is essential to adopt operation of EVs independent on conventional grid for charging. Several agencies analyzed the challenges and deployed several universal standards and codes for charging EVs. Considering wide-spread applications and situations, batteries are charged by PVs which are installed on the vehicles, causing the reduction in the installation of charging stations.
This work, "Solar Powered 4-Wheeler" is a dynamic system, wherein the energy from the sun is transformed into the electrical energy using the required number of solar panels of sufficient area mounted on the EV, to power up the lead-acid battery, which is used in the 4-wheeler [1].
As this is a dynamic system, due to weather conditions, the charging is influenced by parameters like irradiance and temperature. The unregulated output of the PV panel is regulated using DC-DC charge controller that is capable of boosting or stepping down the PV output with simultaneous tracking of maximum power output from the panel. The maximum power point tracking (MPPT) controller is better for the high-power range applications rather than the pulse width modulation (PWM) controller to measure the maximum power point (MPP) and keep the battery in charging mode whenever the variable parameters get changed [2]. Solar cells are implemented on the surface of the scooter by calculating the parameters of the single cell and connect those cells in the series and parallel to get the output that is helpful to charge the battery [3]. The battery plays a major role in electric vehicles. Knowing the total energy left in a battery and the driving conditions, the control system notifies the user, and the range for which the battery will perform until the next recharge, which is a measure of the intermittent ability of the battery [4]. The state-of-charge (SOC) of the battery can be resolute from the discharging characteristics of the battery. An SOC of 100% is a measure of area under the discharge characteristics of a battery from 100% charge to 0% charge in the battery [5]. The battery charging is done using three stages of charging of the battery to maintain the standard and charging takes place with respect to the SOC of battery by constant-current and constant-voltage methods [6].
1.2 Proposed Methodology
In this proposed methodology, flexible solar panels will be mounted on car surfaces, where maximum light will fall. Since the PV panels are flexible, their size and power ratings are not regular. Hence, the power rating of the panel must be calculated using the number of cells present in the section and the data sheet of the PV panel. Based on the efficiency of solar panel, the size and power are finalized. From the data sheet, the power output of a single cell is computed and based on the area of the panel, the total power of the PV is calculated. To get the desired amount of power generation, many such cells will be connected in series and parallel. Once the PV panels are designed, then it requires a DC-DC converter to extract power from the PV panel. In this work, a boost converter is chosen to extract power from the PV. The boost converter provides necessary charging current at desired voltage to the battery present in EV. The power output of PV varies depending on cell temperature and irradiance falling on the panel. Hence, it is necessary to regulate and extract maximum power output from PV with suitable control technique using boost converter. Maximum power point tracking (MPPT) is one of the classical approaches that aims at tracking and extracting the maximum power output from the PV panel and feeds the connected loads. For tracking the maximum power, the perturb and observe (P&O) algorithm is applied. The energy output of the boost converter will be given to the battery for storage or an inverter to convert the DC to AC. The algorithm for the charge controller will adjust the current and voltage with respect to the SOC of the battery. Based on the current from the boost converter, the charging time of the battery can be computed. The functional illustration of the planned system is depicted in Figure 1.1.
Figure 1.1 Functional illustration of the proposed system.
The specifications of Renogy UK monocrystalline flexible solar panels are provided in Table 1.1. The image of Renogy UK monocrystalline flexible PV panel is shown in Figure 1.2 for reference along with its dimensions specified.
Single solar cell parameters from the selected manufacturer solar panel
- Cell area = 6.5 * 3.3 in = 16.51 * 8.382 cm2 = 138.39 cm2 = 13,839 mm2
- Open circuit voltage from the single cell = Voc of solar panel/ No. of cells in panel
- No. of cells connected in series = PV module voltage / voltage at the operating condition
- Here, PV module voltage is 52 because we need 52 V from the source to charge 48 V
Table 1.1 Renogy UK monocrystalline flexible PV panel specifications.
Parameter Values Maximum power 100 W Open circuit voltage (Voc) 23.5 V Voltage at maximum power point 19.4 V Temperature coefficient (Voc, Isc, Pmax) -0.29%, 0.05%, -0.38% Short circuit current (ISC) 5.51 A Current at maximum power point 5.2 A Irradiance and nominal temperature 1000 W/m2 and 25°C Panel dimensions in mm 1093 × 582 No. of cells 36Figure 1.2 Renogy UK monocrystalline flexible PV panel.
- Light generated current (IL) = 5.5453 A
- Diode saturation current (I0) = 12.358 pA
- Diode ideality factor = 0.94781
- Shunt resistance = 185.7255 O
- Series resistance = 0.26886 O
- Series connected...
