This study presents a combined algebraic and power flow model of a microgrid to compare configurations with and without distributed energy storage systems. The microgrid model consists of 5 nodes connected by a transformer representing residential buildings with photovoltaic systems and potential energy storage. Optimization calculates optimal dispatch strategies to minimize costs. Power flow simulation then determines impacts on transformer loading and losses. Results show distributed batteries and a battery plant both reduce transformer loading compared to photovoltaics alone, with distributed batteries performing slightly better by further reducing power line losses. This model provides a tool to evaluate and compare technical impacts of different energy storage configurations in microgrids.
A literature review on industrially accepted MPPT techniques for solar PV systemIJECEIAES
Solar energy is a clean renewable energy and it is available around 89,000 TW on the earth surface. To get maximum power from a solar PV system with minimum power transfer loss is one of the main design objectives of an energy transferring network. Power electronic devices perform a very important character for an efficient PV power tracking system control and either incorporates to transfer the generated power to the ac/dc grid or battery storage system. In this case the duty of the power electronics devices used in PV system is to track maximum power point under different operating conditions of environment, so that power tracking efficiency of solar PV system can be improved. This paper encapsulates based the on performance comparisions on the behavior of MPP under uniform and nonuniform operating conditions and selects the optimum duty cycle for industrially accepted MPPT techniques with their algorithm.
The main objective of this research work is to develop KY conveter topology for renewable energy sources.Solar energy is the readily available and is the cheapest form of energy. It is non-polluting and environment friendly. The development of high static gain DC-DC converters is an important research area due to the crescent demand of this technology for several applications supplied by low DC output voltage power sources. It is used to provide the uninterruptable power supply and battery powered to the system. So here, step-up DC-DC converters based on the KY converter are proposed for LED lighting systems. The proposed topologies present high voltages and high efficiency for low input voltage and high output voltage applications. The simulation results of the proposed topology have been presented using MATLAB/SIMULINK software.
Stand-alone Hybrid systems become appreciating issues that ensure the required electricity to consumers. The development of a stand-alone Hybrid system becomes a necessity for multiple applications The enhance energy security. To achieve this objective, we have proposed an accurate dynamic model using Multi-Agent System (MAS) in which a solar energy System (SES) serves as the main load supply, an energy Backup System (ERS) is based on a fuel cell and Electrolyzer for long-term energy storage and an Ultra Capacitor (UCap) storage system deployed as a short-time storage. To cooperate with all systems, an Intelligent Power Management (IPM) based on a specific MAS is included. Thus, to prove the performance of the system, we tested and simulated it using the Matlab/Simulink environment.
Power quality improvement based on hybrid coordinated design of renewable ene...IJECEIAES
This paper presents a comprehensive analysis of power quality for static synchronous compensator on the distribution power system (DSTATCOM) when different types of energy sources are used to supply the DC link channel of DSTATCOM. These types of power supplies have a different effect on the compensation of DSTATCOM due to operation nature of these sources. The dynamic response of the DSTATCOM has investigated that produced by individual and hybrid energy sources to evaluate the influence of these sources in terms of time response, compensation process and reduce the harmonics of current source. Three cases have been considered in this study. First the photovoltaic (PV) cells alone, second the battery storage alone, and third a hybrid coordinated design between (PV cells with battery storage) is used. A boost DC-DC circuit has connected to a photovoltaic cell with maximum power point tracking (MPPT) while DC-DC buck-boost circuit is used with a battery. High coordination between PV and battery circuits in the hybrid system is used to improve the performance. A synchronous reference frame (SRF) with a unit vector has used to control the DSTATCOM. The simulation results show that the hybrid design has a superiority response compared to the individual sources.
A literature review on industrially accepted MPPT techniques for solar PV systemIJECEIAES
Solar energy is a clean renewable energy and it is available around 89,000 TW on the earth surface. To get maximum power from a solar PV system with minimum power transfer loss is one of the main design objectives of an energy transferring network. Power electronic devices perform a very important character for an efficient PV power tracking system control and either incorporates to transfer the generated power to the ac/dc grid or battery storage system. In this case the duty of the power electronics devices used in PV system is to track maximum power point under different operating conditions of environment, so that power tracking efficiency of solar PV system can be improved. This paper encapsulates based the on performance comparisions on the behavior of MPP under uniform and nonuniform operating conditions and selects the optimum duty cycle for industrially accepted MPPT techniques with their algorithm.
The main objective of this research work is to develop KY conveter topology for renewable energy sources.Solar energy is the readily available and is the cheapest form of energy. It is non-polluting and environment friendly. The development of high static gain DC-DC converters is an important research area due to the crescent demand of this technology for several applications supplied by low DC output voltage power sources. It is used to provide the uninterruptable power supply and battery powered to the system. So here, step-up DC-DC converters based on the KY converter are proposed for LED lighting systems. The proposed topologies present high voltages and high efficiency for low input voltage and high output voltage applications. The simulation results of the proposed topology have been presented using MATLAB/SIMULINK software.
Stand-alone Hybrid systems become appreciating issues that ensure the required electricity to consumers. The development of a stand-alone Hybrid system becomes a necessity for multiple applications The enhance energy security. To achieve this objective, we have proposed an accurate dynamic model using Multi-Agent System (MAS) in which a solar energy System (SES) serves as the main load supply, an energy Backup System (ERS) is based on a fuel cell and Electrolyzer for long-term energy storage and an Ultra Capacitor (UCap) storage system deployed as a short-time storage. To cooperate with all systems, an Intelligent Power Management (IPM) based on a specific MAS is included. Thus, to prove the performance of the system, we tested and simulated it using the Matlab/Simulink environment.
Power quality improvement based on hybrid coordinated design of renewable ene...IJECEIAES
This paper presents a comprehensive analysis of power quality for static synchronous compensator on the distribution power system (DSTATCOM) when different types of energy sources are used to supply the DC link channel of DSTATCOM. These types of power supplies have a different effect on the compensation of DSTATCOM due to operation nature of these sources. The dynamic response of the DSTATCOM has investigated that produced by individual and hybrid energy sources to evaluate the influence of these sources in terms of time response, compensation process and reduce the harmonics of current source. Three cases have been considered in this study. First the photovoltaic (PV) cells alone, second the battery storage alone, and third a hybrid coordinated design between (PV cells with battery storage) is used. A boost DC-DC circuit has connected to a photovoltaic cell with maximum power point tracking (MPPT) while DC-DC buck-boost circuit is used with a battery. High coordination between PV and battery circuits in the hybrid system is used to improve the performance. A synchronous reference frame (SRF) with a unit vector has used to control the DSTATCOM. The simulation results show that the hybrid design has a superiority response compared to the individual sources.
In a distributed generation system, divers renewable agents are connected to the low voltage 3 phase utility grid by an inverter which is used as power condition and must assurance the higher efficiency of the renewable agent. To achieve this level of efficiency, a unitary power factor between the utility grid voltages and the inverter currents is necessary, and a synchronization algorithm is required for the perfect synchronization between the 3-phase utility grid and the renewable agent. The aim of this paper is to present the optimization of the performance of a Synchronization controller for a 3-phase photovoltaic grid-connected system, assessing its accuracy under different conditions and studying their drawbacks and advantages. A grid connected photovoltaic system with a nominal power of 5 kW is used so as to assess the behavior of the synchronization algorithm when the 3 phase utility grid is affected by some disturbances such as voltage unbalances.
This paper discusses about a LabVIEW based controller for the hybrid renewable energy system operated AC-DC microgrid with the major objectives of: i) predicting the power generation potential of the solar–PV and wind generators ii) effective power management iii) load scheduling based on the available power with the renewable sources and iv) grid/islanding mode of operation of the microgrid. In order topredict the output power of wind generator and Solar-PV system, an artificial neural network is developed.The laboratory-scale model of three phase, 400 V, 10 kVA microgrid structure is developed at National Institute of Technology Calicut, India. The developed LabVIEW based controller has been tested successfully for a real-time load and source in the laboratory environment. Test results show that the designed controller is effectively managing the output powerof the primary energy sources under different scenarios.
Performance Comparison of PID and Fuzzy Controllers in Distributed MPPTIJPEDS-IAES
With an increase of Green Technology applications, Photovoltaic have
emerged as the most appropriate solution for electricity generation purposes.
However, due to variable temperature and irradiance, under the partial or
shaded conditions Maximum Power Point Tracking is needed to determine
highest efficiency of the system. The paper describes dynamic modeling and
control of variable temperature and irradiance on solar panel in SIMULINKMATLAB
environment. The implementation of Buck Converter is used for
power switching and impedance matching on connecting the panel to the
load. The effectiveness of the model, with enhanced efficiency through
voltage stabilization, is performed using Proportional-Integral-Derivative and
Fuzzy-Logic-Controllers. A comparative study is made for PID and FLC on
the basis of outputs to deal with online set point variations. FLC gives closer
results to Standard Test Conditions when compared with PID. The Fuzzy
system developed, using tested membership functions serve as a platform for
sustainable standalone and grid-based applications using distributed MPPT.
Electric Vehicle as an Energy Storage for Grid Connected Solar Power SystemIAES-IJPEDS
In the past few years the growing demand for electricity and serious concern
for the environment have given rise to the growth of sustainable sources like
wind, solar, tidal, biomass etc. The technological advancement in power
electronics has led to the extensive usage of solar power. Solar power output
varies with the weather conditions and under shading conditions. With the
increasing concerns of the impacts of the high penetration of Photovoltaic
(PV) systems, a technical study about their effects on the power quality of
the utility grid is required. This paper investigates the functioning of a gridtied
PV system along with maximum power point tracking (MPPT)
algorithm. The effects of varying atmospheric conditions like solar irradiance
and temperature are also taken into account. It is proposed in this work that
an Electric Vehicle (EV) can be used as an energy storage to stabilize the
power supplied to the grid from the photovoltaic resources. A coordinated
control is necessary for the EV to obtain desired outcome. The modeling of
the PV and EV system is carried out in PSCAD and the proposed idea is
verified through simulation results utilizing real field data for solar irradiance
and temperature.
Nowadays tremendous increase in renewable energy technologies available in abounding nature energy extracted from sun, wind etc. This Proposed topology gathered maximum power using multi input ky boost converters for hybrid energy. This hybrid topology operates mainly delivered the power from renewable energy sources solar/wind to dc bus. In the absence of any one source, wind or solar supplies power to the dc bus. Without any renewable energy sources battery deliver the power to dc bus.An inverter type module convert the power from dc bus to ac grid. In this paper effectiveness of hybrid renewable energy is simulated through MATLAB/SIMULINK.
Modeling, Control and Power Management Strategy of a Grid connected Hybrid En...IJECEIAES
This paper presents the detailed modeling of various components of a grid connected hybrid energy system (HES) consisting of a photovoltaic (PV) system, a solid oxide fuel cell (SOFC), an electrolyzer and a hydrogen storage tank with a power flow controller. Also, a valve controlled by the proposed controller decides how much amount of fuel is consumed by fuel cell according to the load demand. In this paper fuel cell is used instead of battery bank because fuel cell is free from pollution. The control and power management strategies are also developed. When the PV power is sufficient then it can fulfill the load demand as well as feeds the extra power to the electrolyzer. By using the electrolyzer, the hydrogen is generated from the water and stored in storage tank and this hydrogen act as a fuel to SOFC. If the availability of the power from the PV system cannot fulfill the load demand, then the fuel cell fulfills the required load demand. The SOFC takes required amount of hydrogen as fuel, which is controlled by the PID controller through a valve. Effectiveness of this technology is verified by the help of computer simulations in MATLAB/SIMULINK environment under various loading conditions and promising results are obtained.
Grid Connected Distributed Generation System with High Voltage Gain Cascaded ...IJECEIAES
The paper presents distributed generation (DG) system in grid connected mode of operation with asymmetric multi-level inverter (AMLI) topology. Cascaded type DC-DC converter is employed to feed proposed AMLI topology. The DG output voltage (generally low voltage) is stepped up to the required level of voltage using high-gain DC-DC converter. Proposed AMLI topology consists of capacitors at the primary side. The output of high-gain DC-DC converter is fed to split voltage balance single-input multi-output (SIMO) circuit to maintain voltage balance across capacitors of AMLI topology. Cascaded DC-DC converters (both high-gain converter and SIMO circuit) are operated in closed-loop mode. The proposed AMLI feeds active power to grid converting DC type of power generated from DG to AC type to feed the grid. PWM pattern to trigger power switches of AMLI is also presented. The inverting circuit of MLI topology is controlled using simplified I d -I q control strategy in this paper. With the proposed control theory, the active power fed to grid from DG is controlled and power factor is maintained at unity. The proposed system of DG integration to grid through cascaded DC-DC converters and AMLI structure is validated from fixed active power to grid from DG condition. The proposed system is developed and results are obtained using MATLAB/SIMULINK software.
Open-Switch Fault-Tolerant Control of Power Converters in a Grid-Connected Ph...IAES-IJPEDS
This paper presents the study of an open switch fault tolerant control of a
grid-connected photovoltaic system. The studied system is based on the
classical DC-DC boost converter and a bidirectional 6-pulse DC-AC
converter. The objective is to provide an open-switch fault detection method
and fault-tolerant control for both of boost converter and grid-side converter
(GSC) in a grid-connected photovoltaic system. A fast fault detection method
and a reliable fault-tolerant topology are required to ensure continuity of
service, and achieve a faster corrective maintenance. In this work, the mean
value of the error voltages is used as fault indicator for the GSC, while, for
the boost converter the inductor current form is used as fault indicator. The
fault-tolerant topology was achieved by adding one redundant switch to the
boost converter, and by adding one redundant leg to the GSC. The results of
the fault tolerant control are presented and discussed to validate the proposed
approach under different scenarios and different solar irradiances.
There is need for an energy storage device capable of transferring high power in transient situations
aboard naval vessels. Currently, batteries are used to accomplish this task, but previous research has
shown that when utilized at high power rates, these devices deteriorate over time causing a loss in lifespan.
It has been shown that a hybrid energy storage configuration is capable of meeting such a demand while
reducing the strain placed on individual components. While designing a custom converter capable of
controlling the power to and from a battery would be ideal for this application, it can be costly to develop
when compared to purchasing commercially available products. Commercially available products offer
limited controllability in exchange for their proven performance and lower cost point - often times only
allowing a system level control input without any way to interface with low level controls that are
frequently used in controller design. This paper proposes the use of fuzzy logic control in order to provide
a system level control to the converters responsible for limiting power to and from the battery. A system
will be described mathematically, modeled in MATLAB/Simulink, and a fuzzy logic controller will be
compared with a typical controller.
A Flexible AC Distribution System for a Microgrid with a Photovoltaic System ...IJMTST Journal
This paper presents a FACT ac distribution system device for micro grid applications. The device aims to improve the power quality and reliability of the overall power distribution system that the micro grid is connected to. The control design employs a new model predictive control algorithm which allows faster computational time for large power systems by optimizing the steady-state and the transient control problems separately. Extended Kalman filters are also employed for frequency tracking and to extract the harmonic spectra of the grid voltage and the load currents in the micro grid. Simulation results is verified through different case studies.
Grid Integration of Large PV Power Systems Using HVDC LinkIJERA Editor
This paper explores the interconnection of large scale Photo-Voltaic (PV) systems to the grid though a High Voltage Direct Current (HVDC) link. HVDC link is recently utilized for transmission lines longer than 50 km. It is usually utilized to interconnect two asynchronous grids with the same or different frequencies while avoiding stability disturbances greatly. A suitable Maximum Power Point Tracking (MPPT) techniques is employed to control the performance of the integrated PV system. The system of the HVDC link has two 12-pulse converter using thyristor-bridges. The delay and the extinction angles at the rectifier and the inverter units control the flow and the quantity of the transmitted power from the PV system into the grid. Fixed capacitors and filters are used to provide the AC side with the required reactive power and reduce the harmonic contents. For evaluation purposes, different simulation investigations are carried out with a detailed modeling using the MATLAB. These tests corroborate the efficacy of HVDC link for integrating large PV systems to electrical grids
COORDINATED CONTROL AND ENERGY MANAGEMENT OF DISTRIBUTED GENERATION INVERTERS...ijiert bestjournal
In modern world,our entire life moves around Computers. Most of our tasks are dependent on the Computers,like Communication,Ticket Reservations,Researches,Printing,and Education etc. When we communicate with each other by using Computers through E Mails,a number of Computers are used for this purpose and the collection of these computers forms a network,which is called a Computer Network. As more and more peoples are going to be connected through the general network (INTERNET),the problem of security arises. Now a day,a number of security issues occur in networks which include Sniffing,Spoofing,Security Attacks,Malwares,Unauthorized Access,etc. This will create havoc for the users,who wants to communicate with each other through these networks. So,to make the communication between two users via the Computer Networks,we have to follow some security measures,which include using the Firewalls,Anti Malicious Software,Intrusion Detection Systems,Cryptography Techniques,et c. This paper is basically focused on how the communication between two users has been performed by using Computer Networks and how to make such a communication
Various demand side management techniques and its role in smart grid–the stat...IJECEIAES
The current lifestyle of humanity relies heavily on energy consumption, thusrendering it an inevitable need. An ever-increasing demand for energy hasresulted from the increasing population. Most of this demand is met by thetraditional sources that continuously deplete and raise significantenvironmental issues. The existing power structure of developing nations isaging, unstable, and unfeasible, further prolonging the problem. The existingelectricity grid is unstable, vulnerable to blackouts and disruption, has hightransmission losses, low quality of power, insufficient electricity supply, anddiscourages distributed energy sources from being incorporated. Mitigatingthese problems requires a complete redesign of the system of powerdistribution. The modernization of the electric grid, i.e., the smart grid, is anemerging combination of different technologies designed to bring about theelectrical power grid that is changing dramatically. Demand sidemanagement (DSM) allow customers to be more involved in contributors tothe power systems to achieve system goals by scheduling their shiftableload. Effective DSM systems require the participation of customers in thesystem that can be done in a fair system. This paper focuses primarily ontechniques of DSM and demand responses (DR), including schedulingapproaches and strategies for optimal savings.
Energy Management Scheme in Photovoltaic Based DC Microgridijtsrd
This paper explores the need for renewable based DC microgrid and proposes characteristic features of a standalone DC microgrid. The need for energy management system and its role in DC microgrid has been emphasized. Renewable generating sources such as wind turbine generator and photovoltaic panel require stringent control for harnessing maximum available energy, energy storage system demands efficient management, and DC link voltage must be maintained constant. Microgrid is a small modular and distributed power generation and distribution system that combines power quality management and enduser energy utilization technology based on distributed power generation technology based on distributed resources or users small scale power plants. The solar based DC Microgrid has been proposed from the following controller and two compensation systems, . It forms a system of three rings, and feeds each load. Load balancing and voltage regulation are the main aspects for designing the model. The voltage is kept constant at 48V in the voltage control loop. Advantages of DC microgrids include easy control, high system efficiency and low energy conversion. The centralized monitoring controller has been designed to control current sharing and voltage regulation together in a PV based DC microgrid. Ovais Ahmad Parray | Mohd Ilyas "Energy Management Scheme in Photovoltaic Based DC Microgrid" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-5 | Issue-5 , August 2021, URL: https://www.ijtsrd.com/papers/ijtsrd45200.pdf Paper URL: https://www.ijtsrd.com/engineering/electrical-engineering/45200/energy-management-scheme-in-photovoltaic-based-dc-microgrid/ovais-ahmad-parray
A Three Phase Multi Level Converter for grid Connected PV SystemIAES-IJPEDS
Photovoltaic energy is a wide kind of green energy. A high performance on these systems is needed to make the most of energy produced by solar cells. Also, there must be a constant adaptation due to the continuous variation of power production. Control techniques for Power Converters like the MPPT algorithm (Maximum Power Point Tracking) present very good results on photovoltaic chains. Nevertheless, losses on power elements reduce global performance and the voltage/current adaptation is not always possible. This paper presents a single-phase 11-level (5 H-bridges) cascade multilevel DC- AC grid-tied inverter. Each inverter bridge is connected to a 200 W solar panel. OPAL-RT lab was used as the hardware in the loop (HIL) real-time control system platform where a Maximum Power Point Tracking (MPPT) algorithm was implemented based on the inverter output power to assure optimal operation of the inverter when connected to the power grid as well as a Phase Locked Loop (PLL) for phase and frequency match. A novel SPWM scheme is proposed in this paper to be used with the solar panels that can account for voltage profile fluctuations among the panels during the day. Simulation and experimental results are shown for voltage and current during synchronization mode and power transferring mode to validate the methodology for grid connection of renewable resources.
GA Based Controller for Autonomous Wind-DG Micro gridIOSRJEEE
A single renewable source of energy when integrated with other sources of energy it is termed as hybrid system. In this paper an active power control strategy has been developed such that when the wind alone is not able to meet the energy demand, without compromising the frequency a transition occurs to wind diesel mode so that the energy demand is met. This work proposes the coordination of WDG(Wind DG), VSC’s are used for two purposes one is frequency control and another is voltage control. PMBLDC generator is used as a wind power generator and the Incremental conductance method is used as MPPT along with boost converter. This output is stored into battery system (BS) and surplus is supplied to the consumer loads. Back propagation feed forward (BPFF) control scheme is used for VF control of VSC. This controller provides harmonics elimination, load leveling and reactive power compensation and also regulates the voltage at PCC. Genetic algorithm is used for the purpose of tuning PI controller of BPFF. The performance and the analysis is done in a user friendly MATLAB/Simulink environment.
A Novel Technique for Enhancing Active and Reactive Power Quality for Renewab...IJMER
Renewable energy resources (RES) are being increasingly connected in distribution systems utilizing power electronic converters. This paper presents a novel control strategy for achieving maximum benefits from these grid-interfacing inverters when installed in 3-phase 4-wire distribution systems. The inverter is controlled to perform as a multi-function device by incorporating active power filter functionality. The inverter can thus be utilized as: 1) power converter to inject power generated from RES to the grid, and 2) shunt APF to compensate current unbalance, load current harmonics, load reactive power demand and load neutral current. All of these functions may be accomplished either individually or simultaneously. With such a control, the combination of grid-interfacing inverter and the 3-phase 4-wire linear/non-linear unbalanced load at point of common coupling appears as balanced linear load to the grid. This new control concept is demonstrated with extensive MATLAB/Simulink simulation studies and results.
In a distributed generation system, divers renewable agents are connected to the low voltage 3 phase utility grid by an inverter which is used as power condition and must assurance the higher efficiency of the renewable agent. To achieve this level of efficiency, a unitary power factor between the utility grid voltages and the inverter currents is necessary, and a synchronization algorithm is required for the perfect synchronization between the 3-phase utility grid and the renewable agent. The aim of this paper is to present the optimization of the performance of a Synchronization controller for a 3-phase photovoltaic grid-connected system, assessing its accuracy under different conditions and studying their drawbacks and advantages. A grid connected photovoltaic system with a nominal power of 5 kW is used so as to assess the behavior of the synchronization algorithm when the 3 phase utility grid is affected by some disturbances such as voltage unbalances.
This paper discusses about a LabVIEW based controller for the hybrid renewable energy system operated AC-DC microgrid with the major objectives of: i) predicting the power generation potential of the solar–PV and wind generators ii) effective power management iii) load scheduling based on the available power with the renewable sources and iv) grid/islanding mode of operation of the microgrid. In order topredict the output power of wind generator and Solar-PV system, an artificial neural network is developed.The laboratory-scale model of three phase, 400 V, 10 kVA microgrid structure is developed at National Institute of Technology Calicut, India. The developed LabVIEW based controller has been tested successfully for a real-time load and source in the laboratory environment. Test results show that the designed controller is effectively managing the output powerof the primary energy sources under different scenarios.
Performance Comparison of PID and Fuzzy Controllers in Distributed MPPTIJPEDS-IAES
With an increase of Green Technology applications, Photovoltaic have
emerged as the most appropriate solution for electricity generation purposes.
However, due to variable temperature and irradiance, under the partial or
shaded conditions Maximum Power Point Tracking is needed to determine
highest efficiency of the system. The paper describes dynamic modeling and
control of variable temperature and irradiance on solar panel in SIMULINKMATLAB
environment. The implementation of Buck Converter is used for
power switching and impedance matching on connecting the panel to the
load. The effectiveness of the model, with enhanced efficiency through
voltage stabilization, is performed using Proportional-Integral-Derivative and
Fuzzy-Logic-Controllers. A comparative study is made for PID and FLC on
the basis of outputs to deal with online set point variations. FLC gives closer
results to Standard Test Conditions when compared with PID. The Fuzzy
system developed, using tested membership functions serve as a platform for
sustainable standalone and grid-based applications using distributed MPPT.
Electric Vehicle as an Energy Storage for Grid Connected Solar Power SystemIAES-IJPEDS
In the past few years the growing demand for electricity and serious concern
for the environment have given rise to the growth of sustainable sources like
wind, solar, tidal, biomass etc. The technological advancement in power
electronics has led to the extensive usage of solar power. Solar power output
varies with the weather conditions and under shading conditions. With the
increasing concerns of the impacts of the high penetration of Photovoltaic
(PV) systems, a technical study about their effects on the power quality of
the utility grid is required. This paper investigates the functioning of a gridtied
PV system along with maximum power point tracking (MPPT)
algorithm. The effects of varying atmospheric conditions like solar irradiance
and temperature are also taken into account. It is proposed in this work that
an Electric Vehicle (EV) can be used as an energy storage to stabilize the
power supplied to the grid from the photovoltaic resources. A coordinated
control is necessary for the EV to obtain desired outcome. The modeling of
the PV and EV system is carried out in PSCAD and the proposed idea is
verified through simulation results utilizing real field data for solar irradiance
and temperature.
Nowadays tremendous increase in renewable energy technologies available in abounding nature energy extracted from sun, wind etc. This Proposed topology gathered maximum power using multi input ky boost converters for hybrid energy. This hybrid topology operates mainly delivered the power from renewable energy sources solar/wind to dc bus. In the absence of any one source, wind or solar supplies power to the dc bus. Without any renewable energy sources battery deliver the power to dc bus.An inverter type module convert the power from dc bus to ac grid. In this paper effectiveness of hybrid renewable energy is simulated through MATLAB/SIMULINK.
Modeling, Control and Power Management Strategy of a Grid connected Hybrid En...IJECEIAES
This paper presents the detailed modeling of various components of a grid connected hybrid energy system (HES) consisting of a photovoltaic (PV) system, a solid oxide fuel cell (SOFC), an electrolyzer and a hydrogen storage tank with a power flow controller. Also, a valve controlled by the proposed controller decides how much amount of fuel is consumed by fuel cell according to the load demand. In this paper fuel cell is used instead of battery bank because fuel cell is free from pollution. The control and power management strategies are also developed. When the PV power is sufficient then it can fulfill the load demand as well as feeds the extra power to the electrolyzer. By using the electrolyzer, the hydrogen is generated from the water and stored in storage tank and this hydrogen act as a fuel to SOFC. If the availability of the power from the PV system cannot fulfill the load demand, then the fuel cell fulfills the required load demand. The SOFC takes required amount of hydrogen as fuel, which is controlled by the PID controller through a valve. Effectiveness of this technology is verified by the help of computer simulations in MATLAB/SIMULINK environment under various loading conditions and promising results are obtained.
Grid Connected Distributed Generation System with High Voltage Gain Cascaded ...IJECEIAES
The paper presents distributed generation (DG) system in grid connected mode of operation with asymmetric multi-level inverter (AMLI) topology. Cascaded type DC-DC converter is employed to feed proposed AMLI topology. The DG output voltage (generally low voltage) is stepped up to the required level of voltage using high-gain DC-DC converter. Proposed AMLI topology consists of capacitors at the primary side. The output of high-gain DC-DC converter is fed to split voltage balance single-input multi-output (SIMO) circuit to maintain voltage balance across capacitors of AMLI topology. Cascaded DC-DC converters (both high-gain converter and SIMO circuit) are operated in closed-loop mode. The proposed AMLI feeds active power to grid converting DC type of power generated from DG to AC type to feed the grid. PWM pattern to trigger power switches of AMLI is also presented. The inverting circuit of MLI topology is controlled using simplified I d -I q control strategy in this paper. With the proposed control theory, the active power fed to grid from DG is controlled and power factor is maintained at unity. The proposed system of DG integration to grid through cascaded DC-DC converters and AMLI structure is validated from fixed active power to grid from DG condition. The proposed system is developed and results are obtained using MATLAB/SIMULINK software.
Open-Switch Fault-Tolerant Control of Power Converters in a Grid-Connected Ph...IAES-IJPEDS
This paper presents the study of an open switch fault tolerant control of a
grid-connected photovoltaic system. The studied system is based on the
classical DC-DC boost converter and a bidirectional 6-pulse DC-AC
converter. The objective is to provide an open-switch fault detection method
and fault-tolerant control for both of boost converter and grid-side converter
(GSC) in a grid-connected photovoltaic system. A fast fault detection method
and a reliable fault-tolerant topology are required to ensure continuity of
service, and achieve a faster corrective maintenance. In this work, the mean
value of the error voltages is used as fault indicator for the GSC, while, for
the boost converter the inductor current form is used as fault indicator. The
fault-tolerant topology was achieved by adding one redundant switch to the
boost converter, and by adding one redundant leg to the GSC. The results of
the fault tolerant control are presented and discussed to validate the proposed
approach under different scenarios and different solar irradiances.
There is need for an energy storage device capable of transferring high power in transient situations
aboard naval vessels. Currently, batteries are used to accomplish this task, but previous research has
shown that when utilized at high power rates, these devices deteriorate over time causing a loss in lifespan.
It has been shown that a hybrid energy storage configuration is capable of meeting such a demand while
reducing the strain placed on individual components. While designing a custom converter capable of
controlling the power to and from a battery would be ideal for this application, it can be costly to develop
when compared to purchasing commercially available products. Commercially available products offer
limited controllability in exchange for their proven performance and lower cost point - often times only
allowing a system level control input without any way to interface with low level controls that are
frequently used in controller design. This paper proposes the use of fuzzy logic control in order to provide
a system level control to the converters responsible for limiting power to and from the battery. A system
will be described mathematically, modeled in MATLAB/Simulink, and a fuzzy logic controller will be
compared with a typical controller.
A Flexible AC Distribution System for a Microgrid with a Photovoltaic System ...IJMTST Journal
This paper presents a FACT ac distribution system device for micro grid applications. The device aims to improve the power quality and reliability of the overall power distribution system that the micro grid is connected to. The control design employs a new model predictive control algorithm which allows faster computational time for large power systems by optimizing the steady-state and the transient control problems separately. Extended Kalman filters are also employed for frequency tracking and to extract the harmonic spectra of the grid voltage and the load currents in the micro grid. Simulation results is verified through different case studies.
Grid Integration of Large PV Power Systems Using HVDC LinkIJERA Editor
This paper explores the interconnection of large scale Photo-Voltaic (PV) systems to the grid though a High Voltage Direct Current (HVDC) link. HVDC link is recently utilized for transmission lines longer than 50 km. It is usually utilized to interconnect two asynchronous grids with the same or different frequencies while avoiding stability disturbances greatly. A suitable Maximum Power Point Tracking (MPPT) techniques is employed to control the performance of the integrated PV system. The system of the HVDC link has two 12-pulse converter using thyristor-bridges. The delay and the extinction angles at the rectifier and the inverter units control the flow and the quantity of the transmitted power from the PV system into the grid. Fixed capacitors and filters are used to provide the AC side with the required reactive power and reduce the harmonic contents. For evaluation purposes, different simulation investigations are carried out with a detailed modeling using the MATLAB. These tests corroborate the efficacy of HVDC link for integrating large PV systems to electrical grids
COORDINATED CONTROL AND ENERGY MANAGEMENT OF DISTRIBUTED GENERATION INVERTERS...ijiert bestjournal
In modern world,our entire life moves around Computers. Most of our tasks are dependent on the Computers,like Communication,Ticket Reservations,Researches,Printing,and Education etc. When we communicate with each other by using Computers through E Mails,a number of Computers are used for this purpose and the collection of these computers forms a network,which is called a Computer Network. As more and more peoples are going to be connected through the general network (INTERNET),the problem of security arises. Now a day,a number of security issues occur in networks which include Sniffing,Spoofing,Security Attacks,Malwares,Unauthorized Access,etc. This will create havoc for the users,who wants to communicate with each other through these networks. So,to make the communication between two users via the Computer Networks,we have to follow some security measures,which include using the Firewalls,Anti Malicious Software,Intrusion Detection Systems,Cryptography Techniques,et c. This paper is basically focused on how the communication between two users has been performed by using Computer Networks and how to make such a communication
Various demand side management techniques and its role in smart grid–the stat...IJECEIAES
The current lifestyle of humanity relies heavily on energy consumption, thusrendering it an inevitable need. An ever-increasing demand for energy hasresulted from the increasing population. Most of this demand is met by thetraditional sources that continuously deplete and raise significantenvironmental issues. The existing power structure of developing nations isaging, unstable, and unfeasible, further prolonging the problem. The existingelectricity grid is unstable, vulnerable to blackouts and disruption, has hightransmission losses, low quality of power, insufficient electricity supply, anddiscourages distributed energy sources from being incorporated. Mitigatingthese problems requires a complete redesign of the system of powerdistribution. The modernization of the electric grid, i.e., the smart grid, is anemerging combination of different technologies designed to bring about theelectrical power grid that is changing dramatically. Demand sidemanagement (DSM) allow customers to be more involved in contributors tothe power systems to achieve system goals by scheduling their shiftableload. Effective DSM systems require the participation of customers in thesystem that can be done in a fair system. This paper focuses primarily ontechniques of DSM and demand responses (DR), including schedulingapproaches and strategies for optimal savings.
Energy Management Scheme in Photovoltaic Based DC Microgridijtsrd
This paper explores the need for renewable based DC microgrid and proposes characteristic features of a standalone DC microgrid. The need for energy management system and its role in DC microgrid has been emphasized. Renewable generating sources such as wind turbine generator and photovoltaic panel require stringent control for harnessing maximum available energy, energy storage system demands efficient management, and DC link voltage must be maintained constant. Microgrid is a small modular and distributed power generation and distribution system that combines power quality management and enduser energy utilization technology based on distributed power generation technology based on distributed resources or users small scale power plants. The solar based DC Microgrid has been proposed from the following controller and two compensation systems, . It forms a system of three rings, and feeds each load. Load balancing and voltage regulation are the main aspects for designing the model. The voltage is kept constant at 48V in the voltage control loop. Advantages of DC microgrids include easy control, high system efficiency and low energy conversion. The centralized monitoring controller has been designed to control current sharing and voltage regulation together in a PV based DC microgrid. Ovais Ahmad Parray | Mohd Ilyas "Energy Management Scheme in Photovoltaic Based DC Microgrid" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-5 | Issue-5 , August 2021, URL: https://www.ijtsrd.com/papers/ijtsrd45200.pdf Paper URL: https://www.ijtsrd.com/engineering/electrical-engineering/45200/energy-management-scheme-in-photovoltaic-based-dc-microgrid/ovais-ahmad-parray
A Three Phase Multi Level Converter for grid Connected PV SystemIAES-IJPEDS
Photovoltaic energy is a wide kind of green energy. A high performance on these systems is needed to make the most of energy produced by solar cells. Also, there must be a constant adaptation due to the continuous variation of power production. Control techniques for Power Converters like the MPPT algorithm (Maximum Power Point Tracking) present very good results on photovoltaic chains. Nevertheless, losses on power elements reduce global performance and the voltage/current adaptation is not always possible. This paper presents a single-phase 11-level (5 H-bridges) cascade multilevel DC- AC grid-tied inverter. Each inverter bridge is connected to a 200 W solar panel. OPAL-RT lab was used as the hardware in the loop (HIL) real-time control system platform where a Maximum Power Point Tracking (MPPT) algorithm was implemented based on the inverter output power to assure optimal operation of the inverter when connected to the power grid as well as a Phase Locked Loop (PLL) for phase and frequency match. A novel SPWM scheme is proposed in this paper to be used with the solar panels that can account for voltage profile fluctuations among the panels during the day. Simulation and experimental results are shown for voltage and current during synchronization mode and power transferring mode to validate the methodology for grid connection of renewable resources.
GA Based Controller for Autonomous Wind-DG Micro gridIOSRJEEE
A single renewable source of energy when integrated with other sources of energy it is termed as hybrid system. In this paper an active power control strategy has been developed such that when the wind alone is not able to meet the energy demand, without compromising the frequency a transition occurs to wind diesel mode so that the energy demand is met. This work proposes the coordination of WDG(Wind DG), VSC’s are used for two purposes one is frequency control and another is voltage control. PMBLDC generator is used as a wind power generator and the Incremental conductance method is used as MPPT along with boost converter. This output is stored into battery system (BS) and surplus is supplied to the consumer loads. Back propagation feed forward (BPFF) control scheme is used for VF control of VSC. This controller provides harmonics elimination, load leveling and reactive power compensation and also regulates the voltage at PCC. Genetic algorithm is used for the purpose of tuning PI controller of BPFF. The performance and the analysis is done in a user friendly MATLAB/Simulink environment.
A Novel Technique for Enhancing Active and Reactive Power Quality for Renewab...IJMER
Renewable energy resources (RES) are being increasingly connected in distribution systems utilizing power electronic converters. This paper presents a novel control strategy for achieving maximum benefits from these grid-interfacing inverters when installed in 3-phase 4-wire distribution systems. The inverter is controlled to perform as a multi-function device by incorporating active power filter functionality. The inverter can thus be utilized as: 1) power converter to inject power generated from RES to the grid, and 2) shunt APF to compensate current unbalance, load current harmonics, load reactive power demand and load neutral current. All of these functions may be accomplished either individually or simultaneously. With such a control, the combination of grid-interfacing inverter and the 3-phase 4-wire linear/non-linear unbalanced load at point of common coupling appears as balanced linear load to the grid. This new control concept is demonstrated with extensive MATLAB/Simulink simulation studies and results.
International Journal of Engineering Research and Applications (IJERA) is an open access online peer reviewed international journal that publishes research and review articles in the fields of Computer Science, Neural Networks, Electrical Engineering, Software Engineering, Information Technology, Mechanical Engineering, Chemical Engineering, Plastic Engineering, Food Technology, Textile Engineering, Nano Technology & science, Power Electronics, Electronics & Communication Engineering, Computational mathematics, Image processing, Civil Engineering, Structural Engineering, Environmental Engineering, VLSI Testing & Low Power VLSI Design etc.
Implementation Of A High-Efficiency, High-Lifetime, And Low-Cost Converter Us...irjes
This paper proposes a new converter for photovoltaic water pumping and treatment systems without
the use of storage elements. The converter is designed to drive a three-phase induction motor directly from PV
solar energy. The use of this motor has the objective of presenting a better solution to the standard DC motor
water pumping system. The development is oriented to achieve a commercially viable solution and a market
friendly product. The converter topology is based on a Resonant Two Inductor Boost converter and a Threephase
Voltage Source inverter achieving 90% efficiency at a rated power of 210W.
Control for Grid Connected and Intentional Islanding of Distributed Power Gen...ijtsrd
As the demand for more reliable and secure power system with greater power quality increases, the concept of distributed generation DG have become more popular. This popularity of DG concept has developed simultaneously with the decrease in manufacturing costs associated with clean and alternative technologies like fuel cells, biomass, micro turbine and solar cell systems. Intentional islanding is the purposeful sectionalisation of the utility system during widespread disturbances to create power “islandâ€. This island can be designed to maintain a continuous supply of power during disturbances of the main distribution system. Ruchali Borkute | Nikita Malwar ""Control for Grid Connected and Intentional Islanding of Distributed Power Generation"" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-3 | Issue-4 , June 2019, URL: https://www.ijtsrd.com/papers/ijtsrd23679.pdf
Paper URL: https://www.ijtsrd.com/engineering/electrical-engineering/23679/control-for-grid-connected-and-intentional-islanding-of-distributed-power-generation/ruchali-borkute
Operation and Control of Grid Connected Hybrid AC/DC Microgrid using Various RESIAES-IJPEDS
This paper proposes a Hybrid AC/DC Microgrid in alliance with Photo Voltaic (PV) energy, Wind Energy and Proton Exchange Membrane (PEM) Fuel cells. Microgrids are becoming increasingly attractive to the researchers because of the less greenhouse gases, low running cost, and flexibility to operate in connection with utility grid. The Hybrid AC/DC Microgrid constitutes independent AC and DC subgrids, where all the corresponding sources and loads are connected to their respective buses and these buses are interfaced using an interfacing converter. The Hybrid AC/DC Microgrid increases system efficiency by reducing the multiple reverse conversions involved in conventional RES integration to grid. A Small Hybrid AC/DC Microgrid in grid connected mode was modeled and simulated in MATLAB- SIMULINK environment. The simulation results prove the stable operation considering the uncertainty of generations and loads.
Intelligent control of battery energy storage for microgrid energy management...IJECEIAES
In this paper, an intelligent control strategy for a microgrid system consisting of Photovoltaic panels, grid-connected, and li-ion battery energy storage systems proposed. The energy management based on the managing of battery charging and discharging by integration of a smart controller for DC/DC bidirectional converter. The main novelty of this solution are the integration of artificial neural network (ANN) for the estimation of the battery state of charge (SOC) and for the control of bidirectional converter. The simulation results obtained in the MATLAB/Simulink environment explain the performance and the robust of the proposed control technique.
Reactive Power Sharing Droop Control Strategy for DG Units in an Islanded Mic...IJMTST Journal
The proposed method mainly includes two important operations: error reduction operation and voltage
recovery operation. The sharing accuracy is improved by the sharing error reduction operation, which is
activated by the low-bandwidth synchronization signals. However, the error reduction operation will result in
a decrease in output voltage amplitude. Therefore, the voltage recovery operation is proposed to compensate
the decrease., due to increasing the demand of electricity as well as rapid depletion of fossil fuels, and the
government policies on reduction of greenhouse gas emissions , renewable energy technologies are more
attractive and various types of distributed generation sources, such as wind turbine generators and solar
photo voltaic panels are being connected to low-voltage distribution networks. Micro grid is an integrated
system that contain in s distributed generation sources, control systems, load management, energy storage
and communication infrastructure capability to work in both grid connected and island mode to optimize
energy usage. The paper presents a advanced control technique for a micro grid system which works
efficiently under a decentralized control system.
Performance Analysis of DC Micro Grid with PV-Fuel Cell Hybrid GenerationIJMREMJournal
Conventional energy resources are being replaced by Renewable energy sources mainly due to increasing
environmental concerns. Photovoltaic (PV) and Fuel cell (FC) are suitable to be used in modern DC microgrids
due to their DC output. In this research work, a DC microgrid structure is proposed for small residential areas
using hybrid PV and FC generation. Power Electronic converters are used to regulate generated voltage of the
two sources for integration to a common DC bus. Proposed system is simulated using MATLAB SIMULINK to
observe its performance. Simulation results show that output voltage is properly maintained at different DC
Battery energy storage systems are becoming more and more popular solution in the household applications, especially, in combination with renewable energy sources. The bidirectional AC-DC power electronic converter have great impact to the overall efficiency, size, mass and reliability of the storage system. This paper reviews the literature that deals with high efficiency converter technologies for connecting low voltage battery energy storage to an AC distribution grid. Due to low voltage of the battery isolated bidirectional AC-DC converter or a dedicated topology of the non isolated converter is required. Review on single stage, two stage power converters and integrated solutions are done in the paper.
PV Hybrid System with DSTATCOM for Residential ApplicationsIDES Editor
Now a days PV based energy systems are playing a
vital role among all the renewable energy sourcesin our day
to day life.Proper control should be required to meet the exact
load conditions such that it should satisfy the non-linear
nature of both the solar irradiance and load. In this paper, a
battery is also incorporated along with the PV system to meet
the necessary drop due to change in weather conditions. Here,
a proper control is achieved by using DSTATCOM to
compensate the reactive power. This paper proposes an
advanced technique of PWM to generate the gating pulses
and applied to a Cascaded H-Bridge multilevel inverter to
improve the voltage quality. Here, the entire system is designed
to meet the load of Mogulthur (W.G.Dt. Andhra Pradesh).
Simulation results are presented through Matlab/Simulink
by taking different cases into consideration.
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SVC PLUS Frequency Stabilizer Frequency and voltage support for dynamic grid...Power System Operation
SVC PLUS
Frequency Stabilizer
Frequency and voltage support for dynamic grid stability
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The Need for Enhanced Power System Modelling Techniques & Simulation Tools Power System Operation
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Final project report on grocery store management system..pdfKamal Acharya
In today’s fast-changing business environment, it’s extremely important to be able to respond to client needs in the most effective and timely manner. If your customers wish to see your business online and have instant access to your products or services.
Online Grocery Store is an e-commerce website, which retails various grocery products. This project allows viewing various products available enables registered users to purchase desired products instantly using Paytm, UPI payment processor (Instant Pay) and also can place order by using Cash on Delivery (Pay Later) option. This project provides an easy access to Administrators and Managers to view orders placed using Pay Later and Instant Pay options.
In order to develop an e-commerce website, a number of Technologies must be studied and understood. These include multi-tiered architecture, server and client-side scripting techniques, implementation technologies, programming language (such as PHP, HTML, CSS, JavaScript) and MySQL relational databases. This is a project with the objective to develop a basic website where a consumer is provided with a shopping cart website and also to know about the technologies used to develop such a website.
This document will discuss each of the underlying technologies to create and implement an e- commerce website.
Cosmetic shop management system project report.pdfKamal Acharya
Buying new cosmetic products is difficult. It can even be scary for those who have sensitive skin and are prone to skin trouble. The information needed to alleviate this problem is on the back of each product, but it's thought to interpret those ingredient lists unless you have a background in chemistry.
Instead of buying and hoping for the best, we can use data science to help us predict which products may be good fits for us. It includes various function programs to do the above mentioned tasks.
Data file handling has been effectively used in the program.
The automated cosmetic shop management system should deal with the automation of general workflow and administration process of the shop. The main processes of the system focus on customer's request where the system is able to search the most appropriate products and deliver it to the customers. It should help the employees to quickly identify the list of cosmetic product that have reached the minimum quantity and also keep a track of expired date for each cosmetic product. It should help the employees to find the rack number in which the product is placed.It is also Faster and more efficient way.
About
Indigenized remote control interface card suitable for MAFI system CCR equipment. Compatible for IDM8000 CCR. Backplane mounted serial and TCP/Ethernet communication module for CCR remote access. IDM 8000 CCR remote control on serial and TCP protocol.
• Remote control: Parallel or serial interface.
• Compatible with MAFI CCR system.
• Compatible with IDM8000 CCR.
• Compatible with Backplane mount serial communication.
• Compatible with commercial and Defence aviation CCR system.
• Remote control system for accessing CCR and allied system over serial or TCP.
• Indigenized local Support/presence in India.
• Easy in configuration using DIP switches.
Technical Specifications
Indigenized remote control interface card suitable for MAFI system CCR equipment. Compatible for IDM8000 CCR. Backplane mounted serial and TCP/Ethernet communication module for CCR remote access. IDM 8000 CCR remote control on serial and TCP protocol.
Key Features
Indigenized remote control interface card suitable for MAFI system CCR equipment. Compatible for IDM8000 CCR. Backplane mounted serial and TCP/Ethernet communication module for CCR remote access. IDM 8000 CCR remote control on serial and TCP protocol.
• Remote control: Parallel or serial interface
• Compatible with MAFI CCR system
• Copatiable with IDM8000 CCR
• Compatible with Backplane mount serial communication.
• Compatible with commercial and Defence aviation CCR system.
• Remote control system for accessing CCR and allied system over serial or TCP.
• Indigenized local Support/presence in India.
Application
• Remote control: Parallel or serial interface.
• Compatible with MAFI CCR system.
• Compatible with IDM8000 CCR.
• Compatible with Backplane mount serial communication.
• Compatible with commercial and Defence aviation CCR system.
• Remote control system for accessing CCR and allied system over serial or TCP.
• Indigenized local Support/presence in India.
• Easy in configuration using DIP switches.
CFD Simulation of By-pass Flow in a HRSG module by R&R Consult.pptxR&R Consult
CFD analysis is incredibly effective at solving mysteries and improving the performance of complex systems!
Here's a great example: At a large natural gas-fired power plant, where they use waste heat to generate steam and energy, they were puzzled that their boiler wasn't producing as much steam as expected.
R&R and Tetra Engineering Group Inc. were asked to solve the issue with reduced steam production.
An inspection had shown that a significant amount of hot flue gas was bypassing the boiler tubes, where the heat was supposed to be transferred.
R&R Consult conducted a CFD analysis, which revealed that 6.3% of the flue gas was bypassing the boiler tubes without transferring heat. The analysis also showed that the flue gas was instead being directed along the sides of the boiler and between the modules that were supposed to capture the heat. This was the cause of the reduced performance.
Based on our results, Tetra Engineering installed covering plates to reduce the bypass flow. This improved the boiler's performance and increased electricity production.
It is always satisfying when we can help solve complex challenges like this. Do your systems also need a check-up or optimization? Give us a call!
Work done in cooperation with James Malloy and David Moelling from Tetra Engineering.
More examples of our work https://www.r-r-consult.dk/en/cases-en/
Student information management system project report ii.pdfKamal Acharya
Our project explains about the student management. This project mainly explains the various actions related to student details. This project shows some ease in adding, editing and deleting the student details. It also provides a less time consuming process for viewing, adding, editing and deleting the marks of the students.
Optimized Power Flows in Microgrid with and without Distributed Energy Storage Systems
1. jozef.bendik@stuba.sk
21, rue d’Artois, F-75008 PARIS CIGRE US National Committee
http://www.cigre.org 2019 Grid of the Future Symposium
Optimized Power Flows in Microgrid with and without Distributed Energy
Storage Systems
M. CHUDY, J. BENDIK, M. CENKY
Slovak University of Technology-Bratislava
Slovakia
SUMMARY
This study presents a combined algebraic and power flow model of a microgrid. The aim of
this study is to introduce a strong tool which is capable to compare physical parameters of a
microgrid which are hardly possible to calculate only by common algebraic optimization
methods. Especially interesting is comparison between microgrids without energy storage,
with a single bigger battery plant and with distributed batteries. This study focuses mainly on
high voltage (HV) part of a transformer, inductive power and power losses in microgrids.
Modelled microgrid consists of five robust nodes (which can represent living quarters with
renewable energy production and energy storage) connected into a single transformer node,
which later leads to the transmission system.
KEYWORDS
Energy storage, OpenDSS, GAMS, Microgrid, Steady state simulation, Battery, Optimization
2. 2
1. Introduction
Adopting stochastic power sources such as solar and wind brings strong need of extensive
energy storage capacities and new innovative concepts in the future grid architecture.
Distributed energy storage systems and microgrids are getting great attention in recent years.
These systems have strong potential to play leading role in demand & response management
of the future grids. There are numerous different concepts utilizing strong multifunctionality
of such systems.
These energy storage capacities can be placed behind-the-meter (on the customer side) or in
front of the meter (utility side). If there is no energy storage on the customer side, the
customer must rely on grid operator. Grid operator might be able to buy produced surplus
energy back into the grid by Net metering programs. These policies are often called “virtual
battery” as they do the same functionality for customers as otherwise installed behind-the-
meter battery. However; the term virtual battery is usually used for a different concept.
Therefore, we define some most common terms for the purpose of this paper. They are
usually understood in the same way in numerous other publications as well.
Virtual Energy Storage (virtual battery) [3]–[7]: Distributed behind-the-meter assets
which are able to adopt some roles of energy storage. These assets are used for demand &
response management by grid operator, even though their owners are electricity customers.
The assets are aggregated and controlled as a system. The assets can be real batteries but also
other assets with controlled loads e.g. AC units, refrigerators. Virtual energy storage
represents also upgraded version of distributed batteries.
Net metering programs [8], [9]: Net metering programs represent opposite philosophy to the
Virtual Energy Storage concept. If electricity customer (prosumer) produces more electricity
than consumes, the electricity is fed back to the power grid. In the time when the customer
needs electricity from the grid, it can be purchased back. From customer (prosumer) point of
view the grid represents a battery with unlimited capacity. Net metering programs define
conditions of selling and buying electricity. In this case, the energy storage asset is placed on
the utility side – in-front-of-the meter. However, the utility does not necessarily require
battery plant or different high capacity energy storage system. All these services can be
supplied by different ancillary services e.g. flexible generators.
Battery plant: It is usually bigger, compact facility with battery energy storage of high
capacity. It is placed in-front-of-the-meter and used for peak shaving and frequency regulation
in distribution grids.
Distributed batteries: This term represents smaller energy storage units (batteries)
distributed throughout distribution grid on multiple locations. For the purpose of this study,
the term is understood that batteries are placed always behind-the-meter. Although in many
publications this is not specifically written [1], [2], distributed energy storage is usually meant
to be behind-the-meter.
Microgrids with flexible assets and batteries have potential to be part of virtual energy
storage. Therefore, it is interesting to compare microgrids without energy storage and fully
dependent on Net metering programs, containing a battery plant or distributed batteries.
3. 3
2. System Description
Presented model describes microgrid of a living quarter. It contains five identical residential
buildings with installed different volumes of photovoltaics generating electricity according to
the real PV GIS [10] measured data (localized to Los Angeles). The model calculates cases
without energy storage, with a battery plant and with distributed batteries which are installed
at all buildings.
Microgrid
Modelled microgrid is a low voltage radial network operating on 0.48kV voltage level
consisting of 5 loads, 5 photovoltaic generators and inverters, 5 power lines and the main
transformer as shown in Fig.1.
Fig. 1: Sketch of modelled small distribution grid. Case 1 - Red B represents distributed
batteries, Case 2 - Green B represents Battery plant.
The grid is connected to the distribution network through this main two winding transformer;
TS1 (1000kW, 34/0.48kV, delta/wye connection). Transformer percent losses at rated voltage
are 0.81%, percent no load losses at nominal voltage are 0.15%, magnetizing current is 0.5%.
TS1 is connected from low voltage side to the TBus, which has five separate feeders. Loads
connected to buses B01- B05 are connected to TBus through AYKY cable conductors
(parameters in Table 1). All lines have the same length of 0.3km.
Tab. 1: Power line parameters
Every building has the same load curve with maximum fixed at 90 kW. Power factor was set
to 0.98. The daily consumption loads, which were generated for this case study correspond to
the daily load patterns for residential buildings in California according to [11]. The model
Power line Resistance Reactance Length
Type Marking R1 [Ω/km] X1 [Ω/km] L [km]
AYKY 240 L1-L5 0.125 0.0785 0.3
4. 4
input loads were generated with 1h resolution representing 7 typical days (Fig. 2). The
microgrid is managed by an entity which is obliged to define reserved peak load on the
transformer. By the transformer low voltage site (Tbus), there is a meter measuring all power
flows entering and leaving the microgrid.
Fig. 2: Per unit load in 1h resolution representing 7 typical days.
PV systems
Photovoltaic system consisting of PV panels and the inverters is connected to the buses B01-
B05. The installed power capacity of each PV system is different and listed in Tab 2.
Tab. 2: Parameters of installed PV systems
Installed PV capacity [kWp] Inverter rating [kVA] Bus connection
20 25 B01
40 45 B02
60 65 B03
80 80 B04
100 105 B05
Comprehensive and highly precise method using OpenDSS software was applied for PV
power outputs calculation. OpenDSS is a publicly available power flow software. OpenDSS is
primarily designed to simulate utility distribution systems in arbitrary detail for most types of
analysis related to distribution planning [12]. Photovoltaic modules in the model are
considered as building mounted. Installed capacity varies in every generation node
representing living quarter; however, as the nodes are relatively close, all of them receive
exactly same radiation levels and spot temperature at all the nodes is also identical. For the
exact estimation of generated power from the photovoltaic panels, a PV-GIS online tool was
used. [10]. As PV output is apart from solar irradiation strongly dependent on temperature of
the panels, temperature of the panels is included in the calculations. Dependency of power
output on the panel temperature and inverter efficiency is shown in Figure 3.
5. 5
Fig. 3: Per unit variation of Pmpp (max power point) vs. temperature of the panel at 1 kW/m2
irradiance (left). Efficiency curve for the inverter, per unit efficiency vs per unit power (right).
The required panel temperature was calculated from the ambient temperature and wind speed
using simple empirical approximation [13], [14]:
The calculated module temperature for considered time interval together with gathered
meterological (typical week in LA, in Februari) data is shown in Fig. 4.
Fig. 4: Metrological data and panel temperature.
Finally, the PV generation was calculated using a simple OpenDSS model. Fig. 5 shows
calculated PV solar production per unit from all the solar systems.
Fig. 5: PV generation per unit.
6. 6
3. The model and calculations
The Model presented in this study combines algebraic optimization (GAMS) and power flow
simulation (OpenDSS). The flow chart of the model is shown in Fig. 6. The main benefit of
this model is very comprehensive output which gives optimal dispatching sequence for the
batteries but also complete information about the system such as spot voltages, power flows
and power losses in each part of the microgrid. This hybrid model is capable to calculate real
time power flows, voltages and losses in the microgrid with optimal dispatching strategy of
energy storage. Presented microgrid was modelled in scenarios without PV and energy
storage, With PV and without energy storage, with a battery plant placed at TBus (250 kWh
and a 3phase inverter of 125 kW) and with 5 identical distributed batteries of capacity 50
kWh and 3 phase inverter of 25 kW placed on each BUS according to Fig.1.
Fig. 6: Model flow chart.
Algebraic optimization tool GAMS was used for calculation of the optimal dispatch strategy
for the batteries. Optimal dispatching strategy of installed energy storage is determined by
minimizing costs of electricity which consists of peak load cost and energy cost. Optimization
algorithm was designed similar as described in [13] with objective function.
Minimize
Where, PL – peak load cost, ECt – cost of supplied energy from main grid per time unit, SCn –
storage cost of battery n , n – bus index , t – time index
For calculation parameters in objective equation, following input data were used.
PDu - load of each building as shown in Fig. 2
u – building index
PL_y – peak load cost per unit per year (defined as 55 000 USD/MW/year)
EC_kwh - Energy cost is set to 0.04245 USD/kWh (6am-12am) and 0.036 USD/kWh (12am-
6am)
BAT_lif – lifetime of lithium batteries (set to 15 years)
Bat_E_C – purchasing cost of battery storage per kWh (set to 300 USD/kWh)
Bat_P_C – purchasing cost of battery per kW (set to 200 USD/kW)
7. 7
Optimal battery according to defined parameters was calculated to 178.41 kWh with 96.12
kW inverter. Algebraic model does not consider power flows and losses in the microgrid. The
microgrid is designed in the way that every battery can be charged or discharged to every
node which is solution with the best resiliency. If batteries distributed in each of 5 nodes, the
sum of all distributed battery capacities and sum of inverter powers corresponds to the values
presented for a single battery (178.41 kWh, 96.12 kW). As real-life applications must
consider some reserve for battery capacity and also inverter power, reasonable real-life energy
storage system would have higher parameters. Aging of the battery and also the fact that
lithium batteries are recommended to operate between 10%-90% are the main factors to be
counted. Therefore, for purpose of this study battery of size 250 kWh, 125 kW (case 2 model)
was chosen as reasonable real-life option considering the result of algebraic calculations. If
considering distributed batteries, five units of 50 kWh, 25 kW (case1 model) batteries were
distributed on each node together with buildings.
Calculated optimal dispatch strategy for battery pool is shown in Fig.7. similar results were
calculated for distributed batteries. According this dispatch strategy, calculations for high
voltage (HV) part of the transformer bring following results (Fig.8).
Fig 7. Calculated optimal dispatch strategy for single battery
a) – no PV and no storage
b) – PV and no storage
8. 8
c) – case 1 : battery plant
d) – case 2 : disributed batteries
Fig 8. HV site of the transformer bus : a)No PV and no energy storage, b)PV , no energy storage
c) single battery 250 kWh, 125 kW inverter d) distributed batteries 50kWh with 25kW inverters
Fig.9. shows comparison of active and reactive power generation in the microgrid with energy
storage. In the case of energy storage is present in the microgrid, microgrid cannot feed
electricity back to the TS. Therefore, PV generation must be limited in the case no load or
storage capacity is available.
a) – case 1 generation
b) – case 2 generation
Fig.9. Active and reactive power generation in the microgrid a) battery plant case b) distributed
batteries case.
9. 9
Fig.10 compares HV part of the transformer with PV and without PV and cases with the
battery plant and distributed batteries. Just real P was taken for this comparison.
a)
b)
Fig.10 : HV transforrmer part. a) comparison microgrid with PV and without PV – no energy
storage, b) Comparison scenario with one 250 kWh 125kW battery and five distributed batteries
of 50kWh and 25 kW.
Other important parameters of the microgrid calculated by presented OpenDSS model are
presented in following tables. As it can be seen from Tab 3. The active power flow into grid
was reduces by implementing PV but also battery storages. In addition, the model does not
optimize reactive power flows. It is important to note that storage systems reduced the power
flow into the grid by circa 3.4 % for both cases. This only shows the main benefit of energy
battery storage.
Tab. 3 : Transformer power flows
Into the grid Out of the grid
P [kWh] Q [kVArh] P [kWh] Q [kVArh]
no PV 31477.33 7558.02 0.00 0.00
PV 22360.10 5009.73 1583.41 1082.91
PV+ storage case 1 21645.09 4999.34 192.85 904.33
PV+ storage case 2 21617.30 4991.30 128.60 906.73
Calculated losses in the microgrid are shown in Tab. 4. In general power losses on
transformer were lower for both storage cases. In case of distributed storage (case 2), lower
power line loses were calculated compared to the system with battery plant (case1). This is
result of reducing the necessary power flows between storages as in the case of central battery
plant generated unused energy must be always stored away from the source.
10. 10
Tab 4 : Calculated losses in the microgrid.
Lines Transformer
ΔP [kWh]
no PV 260.00 321.00
PV 194.00 194.00
PV+ storage case 1 188.00 296.00
PV+ storage case 2 180.00 180.00
Tab.5 shows calculated maximum transmission loading of the transformer. This was reduced
significantly by implementing energy storage. It is interesting to note that optimally regulated
distributed batteries performed better than central battery plant and created additional 6.57
kW load reduction.
Tab 5 : Maximum transmission loading of transformer.
P [kW] Q [kVar] S [kVA]
no PV 451.14 106.34 463.51
PV 439.08 101.89 439.08
PV+ storage case 1 333.68 98.66 347.95
PV+ storage case 2 327.11 96.67 341.09
4. CONCLUSION
Comprehensive model of a microgrid using algebraic optimization and OpenDSS was
presented in this paper. The model was demonstrated by a study of a microgrid without
energy storage, with a single energy storage unit – battery plant and with distributed batteries.
It is widely known that distributed batteries are more resilient but also more expensive
solution. However; there are other crucial parameters in the microgrid operation which need
to be evaluated in order to decide which option is more favorable. Presented model is tailored
for this purpose as only scenarios with optimal operation od energy storage assets are
evaluated because the model uses advanced algebraic optimization methods. In the following,
parameters such as maximal loading of the transformer and power losses in the microgrid can
be than calculated by OpenDSS functions. Presented case study shows important comparison
between these parameters which can be easily financially valuated and help decision makers
to choose the most reasonable structure of the microgrid.
11. 11
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