Relevant bibliographies by topics / Electric power distribution. Electric generators

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Academic literature on the topic 'Electric power distribution. Electric generators'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 February 2022

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Journal articles on the topic "Electric power distribution. Electric generators"

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Raschepkin, A. P., I. P. Kondratenko, O. M. Karlov, and R. S. Kryshchuk. "MAGNETO-ELECTRIC ENERGY CONVERTER OF SEA WAVES." Tekhnichna Elektrodynamika 2021, no. 4 (2021): 25–34. http://dx.doi.org/10.15407/techned2021.04.025.

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To convert the energy of sea waves, the use of cylindrical (with a radial magnetic flux) three-phase magnetoelectric generators with a permanent magnet rotor using a mechanical gearbox to increase the rotor speed is considered. Given the real rotor motion, a mathematical model has been developed to calculate the distribution of magnetic fields in the gap of the generator, and functional dependences of the flux linkage of the winding and the electromagnetic moment of the generator on its design and the parameters of permanent magnets have been obtained. For the adopted design, the electromagnetic moment, the distribution of phase currents in the windings, the power and voltage of the generator are determined. A comparison is made of the energy performance of generators with a traditional float drive and using a ratchet to ensure one-sided rotation of the rotor. The expediency of using a ratchet generator to convert the energy of sea waves is considered. References 6, figures 7.
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ARTYUKHOV, Ivan I., Sergey F. STEPANOV, Dmitriy A. BOCHKAREV, Gulsim N. TULEPOVA, and Artem I. ZEMTSOV. "MICROGRID BASED ON A GROUP OF AUTONOMOUS OPERATING SYNCHRONOUS GENERATORS." Urban construction and architecture 7, no. 4 (2017): 127–31. http://dx.doi.org/10.17673/vestnik.2017.04.22.

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The current level of power electronics development allows creating and implementing new technologies for generation, transmission and distribution of electricity. Electric machines with variable shaft speed can be used as an energy source now. The functions of providing the parameters of the generated electric power are transferred to the converter devices. The combination of controlled energy sources and electrical receivers in microgrids allows reducing energy losses, increasing the reliability of electricity supply. The article is devoted to the constructions of a microgrid based on several autonomously operating synchronous generators. As an example, microgrid for power supply of compressor station based on own use generators of gas compressor units is considered.
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Tavlintsev, Alexander, Maria Shorikova, and Sergey Yuferev. "Smoothing the Metropolis Electric Power Consumption Daily Schedule with Mass Use of Electric Vehicles." Advanced Materials Research 953-954 (June 2014): 1402–5. http://dx.doi.org/10.4028/www.scientific.net/amr.953-954.1402.

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In connection with the increasing fuel costs and decreasing incomes during the crisis electric vehicles are becoming more and more popular with drivers. With mass growth of using the electrical vehicles a possibility of transmission congestion can take place. While charging the vehicle by means of residential distribution there is a risk of facing electric power supply degradation and local accident conditions in grids. One of the basic current problems is that of the load curve irregularity, i.e. the existence of the peak hours and minimums in demand of the electric power. In its turn the load curve irregularity can cause unacceptable frequency oscillations in power systems. The development of charging station systems will lead to the increasing of the morning and evening demand of the electric power. It requires key investments in generators designing and improving the distribution networks, which in its turn will cause limitations in the number of charging stations and the electric vehicles expansion. Cost differentiation depending upon charging duration time can become an incentive to use charging stations during the periods of the minimum electric power consumption. A possibility of the electric vehicles usage as a means of smoothing the electric power consumption daily schedule is shown in the article. The evaluation of rationality of the electric vehicles integration as a power component in the network was made as well.
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Olajuyin, E. A., and Olubakinde Eniola. "MICROGRID IN POWER DISTRIBUTION SYSTEM." International Journal of Research -GRANTHAALAYAH 7, no. 8 (2020): 387–93. http://dx.doi.org/10.29121/granthaalayah.v7.i8.2019.687.

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Power is a very important instrument to the development of economy of a nation and it must be stable and available and to meet the demand of the consumers at all times. The quest for power supply has introduced a new technology called microgrid. Micro grids are regarded as small power systems that confine electric energy generating facilities, from both renewable energy sources and conventional synchronous.
 Generators, and customer loads with respect to produced electric energy. It can be connected to grid or operate in islanding mode. On the other hand, the grid’s dynamics and its stability rely on the amount of stored energy in the micro grid. In a conventional power system with a large number of synchronous generators as the main sources of energy, the mechanical energy in the generators’ rotors, in the form of kinetic energy, serves as the stored energy and feeds the grids in the event of any drastic load changes or if disturbances occur. Microgrid is an alternative idea to support the grid, it can be applied in a street, estates, community or a locality (towns and villages), organizations and establishments. Load forecasting can be further extended to Organizations, Local Government, State and country to determine the energy consumption.
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Avramenko, A. I. "Review of the actual state of the market for autonomous energy supply systems." Power and Autonomous equipment 1, no. 1 (2018): 6–14. http://dx.doi.org/10.32464/2618-8716-2018-1-1-6-14.

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In connection with the strongest energy dependence of modern mankind and regular accidents in the world's power systems, the use of alternative sources of electricity remains relevant. The article reviews the dynamics of the market of systems of autonomous power supply with electric generators for the last 10 years. The data on import and production of electric generators in the territory of the Russian Federation are presented. The main domestic producers of electric generating sets are given. The main exporting countries in Russia are electric power units. The positive impact of the policy of import substitution on the production of power units in the territory of the Russian Federation was noted. The tendency to growth of manufacture and import of gas manufacture of gas electric generating sets is established.Subject: the subject of the study is the state of the market of autonomous power supply systems with electric generators (EA) designed for professional long-term operation based on primary multi-cylinder engines using diesel fuel and gas. Objectives: the purpose of the study is to analyze the current state of the market of autonomous power supply systems.Materials and methods: in the course of work, a retrospective of the market of autonomous power supply systems with power units was given, dynamics of import and production of electric power units on the territory of the Russian Federation is presented.Results: the article reviews the dynamics of the market of autonomous power supply systems with electric power generators for the last 10 years. The data on import and production of electric generators in the territory of the Russian Federation are presented. The main domestic producers of electric generating sets are given. The main exporting countries in Russia are electric power units. The positive impact of the policy of import substitution on the production of power units in the territory of the Russian Federation was noted. The tendency to growth of manufacture and import of gas manufacture of gas electric generating sets is established. The need for the growth of the market of electric generating sets distribution of producers.Conclusions: forecasts are made on the future of power plants in the Russian Federation.
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Ponnam, V. K. B., and K. Swarnasri. "Multi-Objective Optimal Allocation of Electric Vehicle Charging Stations and Distributed Generators in Radial Distribution Systems using Metaheuristic Optimization Algorithms." Engineering, Technology & Applied Science Research 10, no. 3 (2020): 5837–44. http://dx.doi.org/10.48084/etasr.3517.

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The acceptance rate of Electric Vehicles (EVs) in the transport industry has increased substantially due to the augmented interest towards sustainable transportation initiatives. However, their impact in terms of increased power demand on the electric power market can increase real power losses, decrease voltage profile, and consequently decrease voltage stability margins. It is necessary to install Electric Vehicle Charging Stations (EVCSs) and Distributed Generators (DGs) at optimal locations to decrease the EV load effect in the Radial Distribution System (RDS). This paper addresses a multi-objective optimization technique to obtain simultaneous EVCS & DG placement and sizing. The problem is formulated to optimize real power losses, Average Voltage Deviation Index (AVDI), and Voltage Stability Index (VSI) of the electrical distribution system. Simulation studies were performed on the standard IEEE 33-bus and 69-bus test systems. Harries Hawk Optimization (HHO) and Teaching-Learning Based Optimization (TLBO) algorithms were selected to minimize the system objectives. The simulation outcomes reveal that the proposed approach improved system performance in all aspects. Among HHO and TLBO, HHO is reasonably successful in accomplishing the desired goals.
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Sudarmojo, Yanu Prapto. "Optimization of Placement and Size of Distribution Generators Using Quantum Genetic Algorithms to Improve Power Quality in Bali Distribution Networks." Journal of Electrical, Electronics and Informatics 3, no. 1 (2019): 1. http://dx.doi.org/10.24843/jeei.2019.v03.i01.p01.

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World energy requirement increased significantly, the main energy source from an oil is very limited. This problem drive an enhancement develop which support small scale generator to be connected near distributed network or near load center. Distributed Generator (DG) is a power plant which have a little capacity range between 15 kW to 10 MW. Basically, DG instalation is one way to fix a voltage profile where an installed DG would inject voltage to a transmission system or electric power distribution.
 Bali is a tourism area which it’s electric power source got a supply from Java and some large scale plant which use fuel of oil and gas, which until now still needed more of electric energy. An addition small scale generator for Bali is very helpful where economic profit is distribution cost and transmission cost’s reduction, electric cost and saving fuel energy. Technically a distributor of DG must be done correctly and optimal from it’s size or location so that give a maximum result from economic side, minimalizing electricity loss and increase voltage profile which result an electric power quality is improved. For that, in this research will use heuristic optimation with use Quantum Genetic Alghorithm method to placing distributed generator to Bali Electricity Network. To counting electicity loss and voltage profile, a method which used to solve it is Newton Raphson method.
 The result of this research, DG is installed to feeder which plaed in Abang Sub-District, Karangasem District where Abang Feeder had a total 43a bus which is a part from Bali Distribution System. With using QGA, DG is installed to bus 1, 5, 7, and 302 with each DG capacity is 0,374 MW, 1,894 MW, 1,988 MW and 0,500 MW, after installment of DG, voltage profile can be fixed. Voltage profile for some bus to Abang Feeder could be fixed from 0,83 pu to 0,98 pu. Electricity loss from 1,105 MW become 0,234 MW.
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ZEMTSOV, Artem I. "POWER SUPPLY EFFICIENCY INCREASE OF THE GAS-COMPRESSOR WORKSHOP DUE TO MICROGRID FORMATION ON THE BASIS OF OWN NEED GAS-DISTRIBUTING UNITS GENERATORS." Urban construction and architecture 9, no. 3 (2019): 175–80. http://dx.doi.org/10.17673/vestnik.2019.03.22.

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The possibility of the direct current use in the enterprise intra shop power supply systems for the electric power loss reduction purpose, the power supply reliability and the electromagnetic compatibility problem solution is considered. The structural direct current micro network scheme on the basis of own need generators, equipping gas-distributing units for gas-compressor workshop electrical generating system, is suggested. The use of these generators at changeable shaft speed is analyzed, with a possibility of regulation of gas-distributing unit capacity for the transporting gas optimization mode. The own need generators combination in the micro network for the purpose of energy surplus use for the gas air coolers power supply is essential.
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German, Leonid A., and Aleksander S. Serebryakov. "Reduction of electric power losses by the reactive power compensation unit at the point of AC electric traction network sectioning." Vestnik of the Railway Research Institute 78, no. 5 (2019): 297–302. http://dx.doi.org/10.21780/2223-9731-2019-78-5-302.

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Changes of electric traction network with regulated and not-regulated reactive power compensation units (CU) are required due to switching on the reactive power static generators at the AC electric traction network sectioning points the specifying calculations of the reactive power. The method of calculation of power losses in the traction network with regulated and not-regulated cross capacity compensation units at the sectioning point was developed. The main positive effect of CU at the sectioning point is increasing of the carrying capacity of the railroad sections. However, calculation of CU effectiveness for reduction of electric power losses, as well as calculation of continuously controlled CU requires appropriate calculations. It is demonstrated that CU effectiveness at the sectioning points of reactive power compensation is reduced in connection with distribution of the draft load; CU regulation effectiveness is also reduced as a response to increase of the carrying capacity of the railroad section, which allows assessing the proposed calculation formulae. Presented examples of calculation for the actual baseline data demonstrate that full losses in the traction network (assumed as 100%) can be reduced by using of CU of the sectioning point up to 21% maximum with continuously controlled units and up to 13.4% with uncontrolled CU. As automatics of the reactive power static generator is designed for increasing the carrying capacity of the railroad, its operation frequently complies with the reactive power overcompensation regime when losses in the traction network are increased.
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Elsherif, A., T. Fetouh, and H. Shaaban. "Power Quality Investigation of Distribution Networks Embedded Wind Turbines." Journal of Wind Energy 2016 (April 12, 2016): 1–17. http://dx.doi.org/10.1155/2016/7820825.

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In recent years a multitude of events have created a new environment for the electric power infrastructure. The presence of small-scale generation near load spots is becoming common especially with the advent of renewable energy sources such as wind power energy. This type of generation is known as distributed generation (DG). The expansion of the distributed generators- (DGs-) based wind energy raises constraints on the distribution networks operation and power quality issues: voltage sag, voltage swell, voltage interruption, harmonic contents, flickering, frequency deviation, unbalance, and so forth. Consequently, the public distribution network conception and connection studies evolve in order to keep the distribution system operating in optimal conditions. In this paper, a comprehensive power quality investigation of a distribution system with embedded wind turbines has been carried out. This investigation is carried out in a comparison aspect between the conventional synchronous generators, as DGs are widely in use at present, and the different wind turbines technologies, which represent the foresightedness of the DGs. The obtained results are discussed with the IEC 61400-21 standard for testing and assessing power quality characteristics of grid-connected wind energy and the IEEE 1547-2003 standard for interconnecting distributed resources with electric power systems.
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Dissertations / Theses on the topic "Electric power distribution. Electric generators"

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Park, Ju-chirl. "Modeling and simulation of selected distributed generation sources and their assessment." Morgantown, W. Va. : [West Virginia University Libraries], 1999. http://etd.wvu.edu/templates/showETD.cfm?recnum=1104.

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Thesis (M.S.)--West Virginia University, 1999.<br>Title from document title page. Document formatted into pages; contains v, 99 p. : ill. (some col.). Includes abstract. Includes bibliographical references (p. 88-91).
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Malinga, Bongani. "Modeling and control of a wind turbine as a distributed resource in an electric power system." Morgantown, W. Va. : [West Virginia University Libraries], 2001. http://etd.wvu.edu/templates/showETD.cfm?recnum=2110.

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Thesis (M.S.)--West Virginia University, 2001.<br>Title from document title page. Document formatted into pages; contains xiv, 106 p. : ill. (some col.). Includes abstract. Includes bibliographical references (p. 90-92).
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Palu, Ivo. "Impact of wind parks on power system containing thermal power plants = Tuuleparkide mõju soojuselektrijaamadega energiasüsteemile /." Tallinn : TUI Press, 2009. http://digi.lib.ttu.ee/i/?443.

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Khushalani, Sarika. "Development of power flow with distributed generators and reconfiguration for restoration of unbalanced distribution systems." Diss., Mississippi State : Mississippi State University, 2006. http://sun.library.msstate.edu/ETD-db/ETD-browse/browse.

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Solanki, Jignesh M. "Multi-agent based control and reconfiguration for restoration of distribution systems with distributed generators." Diss., Mississippi State : Mississippi State University, 2006. http://sun.library.msstate.edu/ETD-db/ETD-browse/browse.

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Sklar, Akiva A. "A Numerical Investigation of a Thermodielectric Power Generation System." Diss., Georgia Institute of Technology, 2005. http://hdl.handle.net/1853/14020.

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The performance of a novel micro-thermodielectric power generation device (MTDPG) was investigated in order to determine if thermodielectric power generation can compete with current portable power generation technologies. Thermodielectric power generation is a direct energy conversion technology that converts heat directly into high voltage direct current. It requires dielectric (i.e., capacitive) materials whose charge storing capabilities are a function of temperature. This property is exploited by heating these materials after they are charged; as their temperature increases, their charge storage capability decreases, forcing them to eject a portion of their surface charge to an appropriate electronic storage device. Previously, predicting the performance of a thermodielectric power generator was hindered by a poor understanding of the materials thermodynamic properties and the affect unsteady heat transfer losses have on system performance. In order to improve predictive capabilities in this study, a thermodielectric equation of state was developed that describes the relationship between the applied electric field, the surface charge stored by the thermodielectric material, and its temperature. This state equation was then used to derive expressions for the material's thermodynamic states (internal energy, entropy), which were subsequently used to determine the optimum material properties for power generation. Next, a numerical simulation code was developed to determine the heat transfer capabilities of a micro-scale parallel plate heat recuperator (MPPHR), a device designed specifically to a) provide the unsteady heating and cooling necessary for thermodielectric power generation and b) minimize the unsteady heat transfer losses of the system. The previously derived thermodynamic equations were then incorporated into the numerical simulation code, creating a tool capable of determining the thermodynamic performance of an MTDPG, in terms of the thermal efficiency, percent Carnot efficiency, and energy/power density, when the material properties and the operating regime of the MPPHR were varied. The performance of the MTDPG was optimized for an operating temperature range of 300 500 K. The optimization predicted that the MTDPG could provide a thermal efficiency of 29.7 percent. This corresponds to 74.2 percent of the Carnot efficiency. The power density of this MTDPG depends on the operating frequency and can exceed 1,000,000 W/m3.
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Choi, Sungyun. "Autonomous state estimation and its application to the autonomous operation of the distribution system with distributed generations." Diss., Georgia Institute of Technology, 2013. http://hdl.handle.net/1853/50250.

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The objective of this thesis is to propose guidelines for advanced operation, control, and protection of the restructured distribution system by designing the architecture and functionality for autonomous operation of the distribution system with DGs. The proposed architecture consists of (1) autonomous state estimation and (2) applications that enable autonomous operation; in particular, three applications are discussed: setting-less component protection, instant-by-instant management, and short-term operational planning. Key elements of the proposed approach have been verified: (1) the proposed autonomous state estimation has been experimentally tested using laboratory test systems and (2) the feasibility of the setting-less component protection has been tested with numerical simulations.
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Al-Agele, Saif. "Electrical Power and Storage for NASA Next Generation Aircraft." Wright State University / OhioLINK, 2017. http://rave.ohiolink.edu/etdc/view?acc_num=wright1515632677356171.

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Salles, Corrêa Diogo. "Metodologias para analise do risco de ocorrencia de ilhamentos não intencionais de geradores sincronos distribuidos." [s.n.], 2008. http://repositorio.unicamp.br/jspui/handle/REPOSIP/259998.

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Orientadores: Walmir de Freitas Filho, Jose Carlos de Melo Vieira Junior<br>Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Eletrica e de Computação<br>Made available in DSpace on 2018-08-11T06:20:40Z (GMT). No. of bitstreams: 1 SallesCorrea_Diogo_M.pdf: 1373306 bytes, checksum: a6a2357bf0c337089786c03c519bbd7d (MD5) Previous issue date: 2008<br>Resumo: Geradores síncronos conectados em redes de distribuição de energia elétrica estão sujeitos a operarem de forma ilhada após contingências como, por exemplo, curtos-circuitos. Ilhamento ocorre quando uma parte da rede de distribuição opera eletricamente isolada da subestação da concessionária, mas continua a ser energizada por geradores distribuídos. Devido a um conjunto de implicações técnicas e de segurança, a prática atualmente utilizada pelas concessionárias e recomendada pelos principais guias técnicos é desconectar todos os geradores da rede isolada tão logo ocorra um ilhamento. Existem diversas técnicas de proteção desenvolvidas para detectar ilhamentos e a maioria delas possui limitações técnicas e são propensas a falharem em determinadas situações. Neste contexto, torna-se importante conhecer a probabilidade ou risco da proteção falhar na detecção de ilhamentos em sistemas de distribuição de energia elétrica com geradores distribuídos e, por conseguinte, decidir se o sistema de proteção utilizado é adequado ou não. A falha da detecção de uma situação de ilhamento é tecnicamente denominada ilhamento não intencional. Esta dissertação de mestrado apresenta uma série de metodologias desenvolvidas para analisar o risco da ocorrência de ilhamentos não intencionais devido à falha do sistema de proteção de geradores síncronos. O sistema de proteção antiilhamento considerado neste trabalho é composto por relés baseados em medidas de freqüência e/ou tensão visto que atualmente estes são considerados os dispositivos mais eficientes para realizar tal tarefa. Como os desempenhos desses relés estão fortemente relacionados aos desbalanços de potência ativa e reativa na rede ilhada, respectivamente, as metodologias desenvolvidas baseiam-se nas curvas de carga do sistema de distribuição, nos patamares de geração de potência ativa e reativa e no cálculo de um índice numérico que indica o risco de falha da proteção antiilhamento. Diversos métodos eficientes foram desenvolvidos para calcular diretamente este índice de risco sem a necessidade de executar numerosas simulações de transitórios eletromagnéticos. Ressalta-se que os principais fatores que afetam o desempenho do sistema de proteção antiilhamento podem ser prontamente determinados com a aplicação das metodologias desenvolvidas. Os resultados obtidos mostraram-se precisos quando comparados aos obtidos por meio de repetidas simulações do tipo de transitórios eletromagnéticos<br>Abstract: Distributed synchronous generators connected to distribution power systems are prone to operate islanded after contingencies such as short circuits. Islanding occurs when a portion of the distribution network operates electrically isolated from the utility grid substation, yet continues to be energized by local distributed generators connected to the isolated system. Due to a number of technical and safety concerns, the procedure currently adopted by utilities and recommended by the main technical guides is to disconnect all the generators immediately after an islanding event. There are several anti-islanding techniques and the majority of them present technical limitations so that they are likely to fail in certain situations. In this context, it becomes important to know the probability or the risk of the protection scheme to fail in the detection of islanding events in distribution power systems containing distributed generators and, ultimately, determine whether the protection scheme under study is adequate or not. The failure of islanding detection is technically denominated non intentional islanding. This work presents a number of methodologies developed to evaluate the risk of occurrence of non intentional islanding due to the failure of synchronous generators protection systems. The anti-islanding protection system considered in this work is composed of relays based on measures of frequency and/or voltage, since these are considered to be the most efficient methods to perform this task. As the performance of these relays is strongly dependent on the active and reactive power imbalances in the islanded system, respectively, the methodologies are based on the distribution network feeder load curves, the active and reactive power generation levels and on the calculation of numerical index to quantify the risk level of protection system failure. Efficient methods were developed to directly calculate these risk indexes without performing several electromagnetic transient simulations. Through these methods, the main factors impacting on the performance of the antiislanding protection schemes can be determined. The results obtained by the usage of the proposed methodologies presented a very good match with those obtained by electromagnetic transient simulations<br>Mestrado<br>Energia Eletrica<br>Mestre em Engenharia Elétrica
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Aljaism, Wadah A., University of Western Sydney, and School of Engineering and Industrial Design. "Control method for renewable energy generators." THESIS_XXX_EID_Aljaism_W.xml, 2002. http://handle.uws.edu.au:8081/1959.7/796.

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This thesis presents a study on the design method to optimise the performance for producing green power from multiple renewable energy generators. The design method is presented through PLC (Programmable Logic Controller) theory. All the digital and analogue inputs are connected to the input cards. According to different operations conditions for each generator, the PLC will image all the inputs and outputs, from these images; a software program has been built to create a control method for multiple renewable energy generators to optimise production of green power. A control voltage will supply the output contractor from each generator via an interface relay. Three renewable generators (wind, solar, battery bank) have been used in the model system and the fourth generator is the back up diesel generator. The priority is for the wind generator due to availability of wind 24 hours a day, then solar, battery bank, and LPG or Diesel generators. Interlocking between the operations of the four contractors has been built to prevent interface between them. Change over between contractors, according to the generator's change over has also been built, so that it will delay supplying the main bus bar to prevent sudden supply to the load. Further study for controlling multiple renewable energy generators for different conditions such as controlling the multi-renewable energy generators from remote, or supplying weather forecast data from bureau of meteorology to the PLC directly as recommended.<br>Master of Electrical Engineering (Hons)
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Books on the topic "Electric power distribution. Electric generators"

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Palu, Ivo. Impact of wind parks on power system containing thermal power plants =: Tuuleparkide mõju soojuselektrijaamadega energiasüsteemile. TUI Press, 2009.

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Electric power distribution handbook. CRC Press, 2004.

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Electric power distribution reliability. 2nd ed. Marcel Dekker, 2009.

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E, Brown Richard. Electric Power Distribution Reliability. Marcel Dekker, Inc., 2003.

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Electric power distribution reliability. Marcel Dekker, 2002.

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Brown, Richard E. Electric power distribution reliability. Marcel Dekker, 2003.

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Electric distribution systems. Wiley-IEEE Press, 2010.

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Electrical power: Motors, controls, generators, transformers. Goodheart-Willcox Co., 1991.

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Kaiser, Joe. Electrical power: Motors, controls, generators, transformers. Goodheart-Willcox, 1998.

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C, Payne John. Understanding boat AC power systems: (generators, inverters, shore power). Sheridan House, 2008.

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Book chapters on the topic "Electric power distribution. Electric generators"

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Wang, Lingyun, Xuanqing Zhou, and Yuan Liu. "Power Flow Calculation for Weakly Meshed Distribution Network with Distributed Generations and Electric Vehicles." In Proceedings of the Second International Conference on Mechatronics and Automatic Control. Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-13707-0_20.

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Morris, Noel M. "Electrical Generators and Power Distribution." In Mastering Electrical Engineering. Macmillan Education UK, 1991. http://dx.doi.org/10.1007/978-1-349-12230-1_8.

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Morris, Noel M. "Electrical Generators and Power Distribution." In Mastering Electrical Engineering. Macmillan Education UK, 1985. http://dx.doi.org/10.1007/978-1-349-18015-8_8.

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Thacher, Eric Forsta. "Electric Power Conversion and Distribution." In A Solar Car Primer. Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-17494-5_6.

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Kumar, Kamlesh, and Mahesh Kumar. "Impacts of Distributed Generations on Power System." In Handbook of Research on New Solutions and Technologies in Electrical Distribution Networks. IGI Global, 2020. http://dx.doi.org/10.4018/978-1-7998-1230-2.ch010.

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With increasing population and urbanization, the demand of electricity also increases day by day; to fulfill this demand, clean and environment-friendly distributed generations are being installed, but these have some issues in power section. With the integration of DG load curve is levelized, feeder voltage is improved; loading effect on the transformer and branches is reduced, and provides electricity with no pollution. This chapter investigates impacts of DGs to the power system; distributed generation means to generate electric power near the power consumption point. Power quality and reliability can be enhanced by the interconnection of distribution generation to an existing distribution system. However, there are so many effects of distributed generation e.g. changing of load losses, increasing of short circuit levels, voltage transient, congestions in the system branches, power quality, and reliability and network protection issues such as false tripping, nuisance tripping, unintentional islanding, neutral shifting is mainly affected.
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"Generators." In Electric Power Systems. John Wiley & Sons, Inc., 2006. http://dx.doi.org/10.1002/0470036427.ch4.

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"Electric Generators." In Combined Heating, Cooling & Power Handbook. Fairmont Press, 2002. http://dx.doi.org/10.1201/9780203912218.ch25.

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Petchers, Neil. "Electric Generators." In Combined Heating, Cooling & Power Handbook: Technologies & Applications. River Publishers, 2020. http://dx.doi.org/10.1201/9781003151692-34.

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"Interconnecting Electric Generators." In Combined Heating, Cooling & Power Handbook. Fairmont Press, 2002. http://dx.doi.org/10.1201/9780203912218.ch28.

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Petchers, Neil. "Interconnecting Electric Generators." In Combined Heating, Cooling & Power Handbook: Technologies & Applications. River Publishers, 2020. http://dx.doi.org/10.1201/9781003151692-37.

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Conference papers on the topic "Electric power distribution. Electric generators"

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Yu, Peng, and B. Venkatesh. "Triangular approximate distribution model of wind electric generators." In 2012 10th International Power & Energy Conference (IPEC). IEEE, 2012. http://dx.doi.org/10.1109/asscc.2012.6523255.

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Ahmadi, Bahman, Oguzhan Ceylan, and Aydogan Ozdemir. "Cuckoo search algorithm for optimal siting and sizing of multiple distributed generators in distribution grids." In 2019 Modern Electric Power Systems (MEPS). IEEE, 2019. http://dx.doi.org/10.1109/meps46793.2019.9395018.

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Kawai, Masaki, Yuta Sakai, Hironori Sugiyama, and Hisao Taoka. "Frequency improvement in power system by Synchronization Inverter-based distributed generators." In 2015 International Symposium on Smart Electric Distribution Systems and Technologies (EDST). IEEE, 2015. http://dx.doi.org/10.1109/sedst.2015.7315189.

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Nazari, M. Honarvar, and M. Ilic. "Technical challenges in modernizing distribution electric power systems with large number of distributed generators." In 2009 IEEE Bucharest PowerTech (POWERTECH). IEEE, 2009. http://dx.doi.org/10.1109/ptc.2009.5282244.

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Aysheh, Nour Ghalib Abu, Tamer Khattab, and Ahmed Massoud. "Cyber-Attacks Against Voltage Profile In Smart Distribution Grids With Highly-Dispersed PV Generators: Detection and Protection." In 2020 IEEE Electric Power and Energy Conference (EPEC). IEEE, 2020. http://dx.doi.org/10.1109/epec48502.2020.9320055.

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Hongbin Wu and Ming Ding. "Modeling and control of distribution system with wind turbine generators." In 2008 Third International Conference on Electric Utility Deregulation and Restructuring and Power Technologies. IEEE, 2008. http://dx.doi.org/10.1109/drpt.2008.4523831.

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Xinjia Wu, Yuping Lu, and Jiao Du. "Wide-area current protection for distribution feeders with Distributed Generators." In 2008 Third International Conference on Electric Utility Deregulation and Restructuring and Power Technologies. IEEE, 2008. http://dx.doi.org/10.1109/drpt.2008.4523842.

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Misra, Ritam, and Sumit Paudyal. "Analysis and reduction of total harmonic distortions in distribution system with electric vehicles and wind generators." In 2015 IEEE Power & Energy Society General Meeting. IEEE, 2015. http://dx.doi.org/10.1109/pesgm.2015.7286342.

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Chiradeja, Pathomthat, Suntiti Yoomak, and Atthapol Ngaopitakkul. "The study of economic effects when different distributed generators (DG) connected to a distribution system." In 2018 19th International Scientific Conference on Electric Power Engineering (EPE). IEEE, 2018. http://dx.doi.org/10.1109/epe.2018.8395962.

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Bartel, Timothy W. "Operating Experience with an Induction Wind Generator On a 12.5 kV Distribution System." In 2007 51st Rural Electric Power Conference. IEEE, 2007. http://dx.doi.org/10.1109/repcon.2007.369548.

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Reports on the topic "Electric power distribution. Electric generators"

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Bass, Robert, and Nicole Zimmerman. Impacts of Electric Vehicle Charging on Electric Power Distribution Systems. Portland State University Library, 2013. http://dx.doi.org/10.15760/trec.145.

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Glass, Jim, Alexander M. Melin, Michael R. Starke, and Ben Ollis. Chattanooga Electric Power Board Case Study Distribution Automation. Office of Scientific and Technical Information (OSTI), 2016. http://dx.doi.org/10.2172/1329733.

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Barnes, P. R. The Integration of Renewable Energy Sources into Electric Power Distribution Systems. Office of Scientific and Technical Information (OSTI), 1994. http://dx.doi.org/10.2172/814204.

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Barnes, P. R., J. W. Van Dyke, F. M. Tesche, and H. W. Zaininger. The integration of renewable energy sources into electric power distribution systems. Volume 1: National assessment. Office of Scientific and Technical Information (OSTI), 1994. http://dx.doi.org/10.2172/10171039.

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Zaininger, H. W. The Integration of Renewable Energy Sources into Electric Power Distribution Systems, Vol. II Utility Case Assessments. Office of Scientific and Technical Information (OSTI), 1994. http://dx.doi.org/10.2172/814519.

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Zaininger, H. W., P. R. Ellis, and J. C. Schaefer. The integration of renewable energy sources into electric power distribution systems. Volume 2, Utility case assessments. Office of Scientific and Technical Information (OSTI), 1994. http://dx.doi.org/10.2172/10170818.

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Gerkensmeyer, Clint, Michael CW Kintner-Meyer, and John G. DeSteese. Technical Challenges of Plug-In Hybrid Electric Vehicles and Impacts to the US Power System: Distribution System Analysis. Office of Scientific and Technical Information (OSTI), 2010. http://dx.doi.org/10.2172/974954.

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None, None. Interconnection Standards for Combined Heat and Power (CHP) - State Standards that Impact Interconnection to the Electric Distribution Grid. Office of Scientific and Technical Information (OSTI), 2020. http://dx.doi.org/10.2172/1643231.

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FitzPatrick, Gerald J., James K. Olthoff, and Ronald M. Powell. Measurement support for the U. S. electric-power industry in the era of deregulation, with focus on electrical measurements for transmission and distribution. National Institute of Standards and Technology, 1997. http://dx.doi.org/10.6028/nist.ir.6007.

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New technology for America`s electric power industry. Diagnosis and control of flow-induced tube vibration in heat exchangers and steam generators. Office of Scientific and Technical Information (OSTI), 1995. http://dx.doi.org/10.2172/29402.

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