Relevant bibliographies by topics / SELF-EXCITED INDUCTION GENERATOR

Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Academic literature on the topic 'SELF-EXCITED INDUCTION GENERATOR'

Author: Grafiati
Published: 4 June 2021
Last updated: 6 February 2022

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Journal articles on the topic "SELF-EXCITED INDUCTION GENERATOR"

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Saket, R. K., and Lokesh Varshney. "Self Excited Induction Generator and Municipal Waste Water Based Micro Hydro Power Generation System." International Journal of Engineering and Technology 4, no. 3 (2012): 282–87. http://dx.doi.org/10.7763/ijet.2012.v4.366.

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Li, Jia, Xinzhen Wu, Xibo Yuan, and Haifeng Wang. "Load Capacity Analysis of Self-Excited Induction Generators Based on Routh Criterion." Energies 12, no. 20 (October 17, 2019): 3953. http://dx.doi.org/10.3390/en12203953.

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In this paper, the Routh criterion has been used to analyze the stability of a self-excited induction generator-based isolated system which is regarded as an autonomous system. Special focus has been given to the load capacity of the self-excited induction generator. The state matrix of self-excited induction generators with resistor-inductor load has been established based on transient equivalent circuits in the stator stationary reference-frame. The recursive Routh table of self-excited induction generators is established by the characteristic polynomial coefficients of the state matrix. According to the Routh stability criterion, the necessary and sufficient condition to predict the critical loads of self-excited induction generators is deduced, from which the critical load impedance can be calculated. A simple self-excited induction generator-based isolated power system has been built up with a 2.2 kW self-excited induction generator. The theoretical analysis and experiments were all carried out based on this platform. In the range determined by the minimum excitation capacitance (Cmin) and the maximum excitation capacitance (Cmax), the critical loads under various power factors have been calculated. The agreement of the calculated theoretical results and experimental results demonstrate the effectiveness and accuracy of the proposed analysis method. The conclusions achieved lay a foundation for further application of Routh stability criterion in self-excited induction generator-based power systems analysis.
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Kannadhasan, S., M. Saravanapandi, and C. Gurunathan. "Simulation and Analysis of Variable Speed Wind Turbine Coupled With Self-Excited Induction Generator." International Journal of Trend in Scientific Research and Development Volume-2, Issue-3 (April 30, 2018): 1622–25. http://dx.doi.org/10.31142/ijtsrd11387.

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Chauhan, Yogesh K., Vinod K. Yadav, and Bhim Singh. "Optimum utilisation of self‐excited induction generator." IET Electric Power Applications 7, no. 9 (November 2013): 680–92. http://dx.doi.org/10.1049/iet-epa.2013.0038.

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Singh, G. K. "Self-excited induction generator research—a survey." Electric Power Systems Research 69, no. 2-3 (May 2004): 107–14. http://dx.doi.org/10.1016/j.epsr.2003.08.004.

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Tripathy, S. C., M. Kalantar, and N. D. Rao. "Wind turbine driven self-excited induction generator." Energy Conversion and Management 34, no. 8 (August 1993): 641–48. http://dx.doi.org/10.1016/0196-8904(93)90098-u.

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Shridhar, L., B. Singh, C. S. Jha, and B. P. Singh. "Analysis of self excited induction generator feeding induction motor." IEEE Transactions on Energy Conversion 9, no. 2 (June 1994): 390–96. http://dx.doi.org/10.1109/60.300132.

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Zuščak, Jozef, Vladimír Kujan, and František Janíček. "Simulations and measurements on a self-excited induction generator." Journal of Electrical Engineering 69, no. 5 (September 1, 2018): 359–65. http://dx.doi.org/10.2478/jee-2018-0052.

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Abstract Paper deals with the use of an induction machine in the role of a generator. Such an operational mode is called a self-excited induction generator SEIG. It does not require an external power source to create the excitation field, as is the case with traditional synchronous generators. Therefore, it is widely used in power plants with renewable energy as a primary source (wind, water, etc). However, in terms of possible regulation and control of the electrical properties, the excitation process is extremely important. A mathematical model and simulation in Matlab are introduced. The excitation process was experimentally investigated in the laboratory of electric drives and the results are correlated with the expectations.
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Chan, T. F. "Analysis of Self-Excited Induction Generators Using Symbolic Programming." International Journal of Electrical Engineering & Education 29, no. 4 (October 1992): 329–38. http://dx.doi.org/10.1177/002072099202900409.

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Analysis of self-excited induction generators using symbolic programming Using the symbolic programming language MACSYMA, the self-excited induction generator may be analysed in a straightforward manner with a high degree of accuracy. Very little manual effort need be spent on algebraic manipulation, numerical analysis and computer programming. Typical program sessions are cited to illustrate the elegance of this approach.
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Santoso, Hari, Rini Nur Hasanah, I. N. G. Wardana, and Budiono Mismail. "Loading Performances of Low-Power Low-Speed Single-Phase Induction Generator with Energy Saving Lamps." Applied Mechanics and Materials 785 (August 2015): 290–94. http://dx.doi.org/10.4028/www.scientific.net/amm.785.290.

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The increasing use of energy saving lamps provides additional benefits to the application of low-power low-speed self-excited induction generators resulted from capacitor motor modification. Reactive power requirement of the generator can be provided from the capacitive nature of the lamps, while at the same time it is delivering active power to loads. Any loading change will automatically increase or reduce reactive power supply to generator. Results of experiments show that low-power low-speed single-phase self-excited induction generator is more robust and suitable for this kind of loads. Generator does not lose its voltage when experiencing abrupt change of loads. This robustness makes the generator suitable for the use in low-capacity hydropower generation in remote areas being commonly not covered by national electricity grid.
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Dissertations / Theses on the topic "SELF-EXCITED INDUCTION GENERATOR"

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Zahir, Bashir Ahmad. "A variable-speed constant-frequency self-excited induction generator." Thesis, Loughborough University, 2005. https://dspace.lboro.ac.uk/2134/35068.

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The thesis describes the design and development of a stand-alone variable-speed constant-frequency self-excited induction generator, using field-oriented control techniques to provide the necessary voltage and frequency control. Open- and closed-loop models are developed for the generator using tensor techniques and these are subsequently used in the control system design and simulation. For the closed-loop system, both conventional and field-oriented control strategies are developed. A laboratory-scale system was designed and built, to illustrate the system performance. The generator is driven by a separately-excited DC motor to simulate a variable-speed wind turbine and a 2.2kW wound rotor induction machine is used as the generator. The generator excitation current is provided by a current-controlled voltage-source inverter.
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Bell, Peter Alan. "An induction machine model for optimisation of self-excited induction generator windings." Thesis, Nottingham Trent University, 1995. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.309819.

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Caliskan, Ahmet. "Constant Voltage, Constant Frequency Operation Of A Self-excited Induction Generator." Master's thesis, METU, 2005. http://etd.lib.metu.edu.tr/upload/12606678/index.pdf.

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In this thesis, control schemes for the self-excited induction generator are developed with Matlab/Simulink. Self-excited induction generator is considered as a constant voltage-constant frequency supply for an isolated load. A wind turbine is assumed to be the variable-speed drive of the induction generator. Control schemes aim to ensure a constant voltage-constant frequency operation of the induction generator in case of the variations in the wind speed and/or the load. From the general model of the self-excited induction generator, the characteristics of the system and the dynamic responses of the system in case of any disturbance are examined. Next, the control strategies are developed both for the squirrel-cage rotor induction generator and for the wound-rotor induction generator. Two control loops are necessary for constant voltage-constant frequency operation of a variable speed induction generator, one for the voltage regulation and the other for the frequency regulation. After developing the control loops, constant voltage-constant frequency operation of the self-excited induction generator is simulated with a cage type saturation adaptive induction generator, a fixed capacitor with thyristor controlled reactor (TCR) used for frequency regulation and switched external resistors connected to the stator terminals used for voltage regulation.
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Ma, Dandan. "Self-excited induction generator : a study based on nonlinear dynamic methods." Thesis, University of Newcastle Upon Tyne, 2012. http://hdl.handle.net/10443/1478.

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An induction generator offers advantages in terms of its low cost, simplicity, robust construction, nature protection against short circuits and ease of maintenance in today’s renewable energy industry. However, the need for an external supply of reactive power (to produce a rotating magnetic flux wave) limits the application of an induction machine as a standalone generator. It is possible for an induction machine to operate as a Self-excited Induction Generator (SEIG) if capacitors are connected to the stator terminals in order to supply the necessary reactive power to achieve generating electrical energy in remote areas. Poor voltage and frequency regulation is the main drawback of a SEIG as the system is highly dynamic under variable load conditions. The regulation of speed and voltage does not result in a satisfactory level although many studies have been focused on this topic in the past. Therefore, the aim of the thesis is to provide a better understanding of the behaviour of a smooth airgap, selfexcited, squirrel cage induction generator as a nonlinear dynamic system when operating under a variety of load conditions, which would hopefully contribute to the development of a better regulated/controlled, viable SEIG system. Allowing for the cross-saturation nonlinear effect, a mathematical Simulink, d -q axis model of the SEIG system utilising currents as state space variables is developed and verified by both the experimental results and numerical analysis. The SEIG computer model is constructed and tested using Matlab/Simulink R2010b throughout the thesis. The self-autonomous system is shown to exhibit a transition from a stable periodic orbit to a quasi-periodic orbit (leading to likely chaotic motion) through a Neimark bifurcation, as a result of small changes in the values of system parameters (such as load resistance, load inductance, rotational speed and self-excitation capacitance). This characteristic dynamic behaviour of the SEIG system is firstly identified in this work and is verified experimentally using a laboratory test rig. The stability of the periodic and quasi-periodic orbits exhibited by the SEIG system when feeding an inductive load ( RL) is numerically analysed and the movement of the eigenvalues of the system’s characteristic matrix when changing a system parameter is presented to verify the qualitative change in system behaviour from a stable period-one orbit to unstable quasi-periodicity. Eigenvalue technique is successfully applied to assess the stability of the period-one and quasi-periodic orbits of the SEIG when feeding variable load conditions.
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Seyoum, Dawit Electrical Engineering &amp Telecommunications Faculty of Engineering UNSW. "The dynamic analysis and control of a self-excited induction generator driven by a wind turbine." Awarded by:University of New South Wales. School of Electrical Engineering & Telecommunications, 2003. http://handle.unsw.edu.au/1959.4/22008.

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This thesis covers the analysis, dynamic modelling and control of an isolated selfexcited induction generator (SEIG) driven by a variable speed wind turbine. The voltage build up process of an isolated induction generator excited by AC capacitors starts from charge in the capacitors or from a remnant magnetic field in the core. A similar voltage build up is obtained when the isolated induction generator is excited using an inverter/rectifier system with a single DC capacitor on the DC link of the converter. In this type of excitation the voltage build up starts from a small DC voltage in the DC link and is implemented using vector control. The dynamic voltage, current, power and frequency developed by the induction generator have been analysed, simulated and verified experimentally for the loaded and unloaded conditions while the speed was varied or kept constant. Results which are inaccessible in the experimental setup have been predicted using the simulation algorithm. To model the self excited induction generator accurate values of the parameters of the induction machine are required. A detailed analysis for the parameter determination of induction machines using a fast data acquisition technique and a DSP system has been investigated. A novel analysis and model of a self-excited induction generator that takes iron loss into account is presented in a simplified and understandable way. The use of the variation in magnetising inductance with voltage leads to an accurate prediction of whether or not self-excitation will occur in a SEIG for various capacitance values and speeds in both the loaded and unloaded cases. The characteristics of magnetising inductance, Lm, with respect to the rms induced stator voltage or magnetising current determines the regions of stable operation as well as the minimum generated voltage without loss of self-excitation. In the SEIG, the frequency of the generated voltage depends on the speed of the prime mover as well as the condition of the load. With the speed of the prime mover of an isolated SEIG constant, an increased load causes the magnitude of the generated voltage and frequency to decrease. This is due to a drop in the speed of the rotating magnetic field. When the speed of the prime mover drops with load then the decrease in voltage and frequency will be greater than for the case where the speed is held constant. Dynamic simulation studies shows that increasing the capacitance value can compensate for the voltage drop due to loading, but the drop in frequency can be compensated only by increasing the speed of the rotor. In vector control of the SEIG, the reference flux linkage varies according to the variation in rotor speed. The problems associated with the estimation of stator flux linkage using integration are investigated and an improved estimation of flux linkage is developed that compensates for the integration error. Analysis of the three-axes to two-axes transformation and its application in the measurement of rms current, rms voltage, active power and power factor from data obtained in only one set of measurements taken at a single instant of time is discussed. It is also shown that from measurements taken at two consecutive instants in time the frequency of the three-phase AC power supply can be evaluated. The three-axes to twoaxes transformation tool simplifies the calculation of the electrical quantities.
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Shokrollah-Timorabadi, Hamid. "Voltage source inverter for voltage and frequency control of a stand-alone self-excited induction generator." Thesis, National Library of Canada = Bibliothèque nationale du Canada, 1998. http://www.collectionscanada.ca/obj/s4/f2/dsk2/tape17/PQDD_0009/MQ34139.pdf.

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Mayer, Giovano. "Condições de existência de autoexcitação em geradores de indução conforme suas condições operativas." Universidade Estadual do Oeste do Parana, 2012. http://tede.unioeste.br:8080/tede/handle/tede/1088.

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Made available in DSpace on 2017-07-10T17:11:51Z (GMT). No. of bitstreams: 1 Giovano Mayer.pdf: 9964402 bytes, checksum: fa8e2023cd08bf7b10d7d806375b1277 (MD5) Previous issue date: 2012-12-10
The use of alternative sources of energy requires electromechanical conversion equipments that exhibit low installation, operating and maintenance costs. In such way, small energy resources that are not connect to the power system (PS) can be benefited by the use of squirrel-cage induction generators (IG) which show such characteristics. When operating in an isolated mode, the IG is called SEIG - Self Excited Induction Generator, and in this configuration its self excitation is promoted through the connection of appropriate capacitors to the terminals of the machine stator. The existence of self-excitation in the IG depends on the value of the capacitor connected to the stator, the mechanical velocity and the load. This work aims to study the conditions of existence of self-excitation in induction generators having in mind applications in isolated generators systems. Towards this goal, initially the conditions for the existence of self-excitation are stated in terms of appropriate parameters, units and quantities, so as to highlight its relations with the operative characteristics of the machine. It is considered that the induction generator is connected to a load that contains both reactive and active components, parameterized in terms of its rated power. The self-excitation capacitors are represented by its reactive power, called self-excitation reactive power (PRAE). Self-excitation existence regions are defined which explicitate conditions for the existence and maintenance of self-excitation over, a region of operating conditions (OR) of the generator. Through the analysis of the existence of the self-excitation over the OR and the parameterization of the PRAE and the load in terms or rated power, procedures for SEIG design are established. With these procedures, the design of the SEIG is defined by the maximum load power, the worse load power factor condition, and the minimum self-excitation speed of the generator. The process of self-excitation of the generator and the design procedures are analyzed with the aid of dynamic simulations of the SEIG complete model, including the non linear model of the magnetizing inductance representing the magnetic saturation. A laboratorial bench was developed to allow studies with asynchronous generation, in particular with the SEIG. The parameters of the generator were identified experimentally and used all along the work, especially in the dynamic simulations showed. The results were also compared with experimental data collected from self-excitation tests performed with the developed laboratory bench.
A utilização de fontes alternativas de energia requer equipamentos de conversão eletromecânica que apresentem baixos custos de implantação, operação e manutenção. Desta forma, pequenos recursos energéticos não ligados ao sistema elétrico de potência (SEP) podem ser beneficiados pelo emprego do gerador de indução (GI) com rotor em gaiola, que apresenta tais características. Quando operado de forma isolada, o GI é denominado de SEIG Self Excited Induction Generator, e nesta configuração sua autoexcitação é promovida através do acoplamento de capacitores apropriados aos terminais do estator da máquina. A existência da autoexcitação no GI depende do valor do capacitor conectado ao estator, da velocidade mecânica e da carga. Este trabalho tem por objetivo estudar as condições de existência da autoexcitação em geradores de indução visando sua aplicação em sistemas isolados de geração. Neste sentido, inicialmente as condições de existência de autoexcitação são colocadas em termos de parâmetros, unidades e grandezas apropriadas, a fim de explicitar as relações com as características operativas da máquina. Também é considerado que o gerador de indução é acoplado a uma carga que contém componentes tanto ativos quanto reativos parametrizados em termos de potência. Os capacitores de autoexcitação são representados por sua potência reativa denominada de potência reativa de autoexcitação (PRAE). São definidas regiões de existência de autoexcitação explicitando condições para a existência e a manutenção da autoexcitação em torno de regiões operativas (RO) do gerador. Através da análise da existência da autoexcitação em torno da RO e da representação da PRAE e da carga em termos de potência, são estabelecidos procedimentos de projeto do SEIG. Com estes procedimentos, o dimensionamento do SEIG fica em função da carga máxima a ser acionada, da pior condição de fator de potência da mesma e da velocidade mínima de autoexcitação do gerador. O processo de autoexcitação do gerador e os procedimentos de projeto são analisados com o auxílio de simulações dinâmicas do modelo completo do SEIG, incluindo o modelo não linear da indutância de magnetização representando a saturação magnética. Uma bancada laboratorial foi desenvolvida para possibilitar estudos com geração assíncrona, em particular com o SEIG. Os parâmetros do gerador foram levantados experimentalmente e utilizados em todo o trabalho, inclusive nas simulações dinâmicas apresentadas. Os resultados foram confrontados também com dados experimentais de testes de autoexcitação obtidos com a bancada desenvolvida.
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Herrera, Victoria Alejandra Salazar. "Diagnóstico de falhas e determinação de eficiência em sistemas geradores isolados baseados em gerador de indução auto-excitado." reponame:Repositório Institucional da UFABC, 2016.

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"CONSTANT VOLTAGE, CONSTANT FREQUENCY OPERATION OF A SELF-EXCITED INDUCTION GENERATOR." Master's thesis, METU, 2005. http://etd.lib.metu.edu.tr/upload/12606678/index.pdf.

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Cheng, Kuang-Hsiung, and 鄭光雄. "Analyses of Three-Phase Self-Excited Induction Generator under unbalanced load conditions." Thesis, 2004. http://ndltd.ncl.edu.tw/handle/b85w3y.

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碩士
崑山科技大學
電機工程研究所
92
This thesis analyses the steady-state and dynamic characteristics of a three-phase self excited induction generator (SEIG) under static loading conditions. This thesis employs eigenvalue and eigenvalue sensitivity to determine minimum values of excitation capacitance of the studied induction generator under different operating conditions. Since the examined induction generator is under either balanced or unbalanced three-phase conditions, five different operating modes, i.e., three phase load perturbation, three phase short circuit and fault clearing, line-to-line short circuit, single phase capacitor opening and load rejection, single-line opening at capacitor bank, are respectively investigated, the three-phase induction machine model based on q-d-0 variables in a stationary reference frame is employed. Finally, experimental results obtained from a laboratory 1-hp induction machine set is compared with the simulated results to validate the effectiveness and feasibility of the proposed schemes.
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Books on the topic "SELF-EXCITED INDUCTION GENERATOR"

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Shokrollah-Timorabadi, Hamid. Voltage source inverter for voltage and frequency control of a stand-alone self-excited induction generator. Ottawa: National Library of Canada, 1998.

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Rajakaruna Mohotti Appuhamilage Sumedha Rajakaruna. Control of a stand-alone self-excited induction generator driven by an unregulated turbine. 1993.

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... Self-Excited Polyphase Asynchronous Generators. Franklin Classics, 2018.

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Book chapters on the topic "SELF-EXCITED INDUCTION GENERATOR"

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Touti, Ezzeddine, Remus Pusca, J. Francois Brudny, and Abdelkader Chaari. "Self-excited Induction Generator in Remote Site." In Power Systems, 517–45. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-51118-4_13.

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Zouggar, S., Y. Zidani, M. L. ELhafyani, T. Ouchbel, M. Seddik, and M. Oukili. "Neural Control of the Self-Excited Induction Generator for Variable-Speed Wind Turbine Generation." In Sustainability in Energy and Buildings, 213–23. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012. http://dx.doi.org/10.1007/978-3-642-27509-8_17.

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Sathyakala, M., and M. Arutchelvi. "Design and Development of Controller for Stand-Alone Wind Driven Self-excited Induction Generator." In Mobile Communication and Power Engineering, 298–304. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013. http://dx.doi.org/10.1007/978-3-642-35864-7_43.

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Gupta, Ashish, and Arvind Kumar Jain. "Steady-State Analysis of Self-excited Induction Generator to Enhance Reliability in Isolated Mode." In Lecture Notes in Mechanical Engineering, 521–32. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-3746-2_48.

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Calgan, Haris, José Manuel Andrade, and Metin Demirtas. "RSM-Based Optimization of Excitation Capacitance and Speed for a Self-Excited Induction Generator." In Mathematical Modelling and Optimization of Engineering Problems, 139–55. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-37062-6_7.

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Chaurasia, Ravi, Rajkumar Viral, Divya Asija, and Tarannum Bahar. "Performance Analysis of Self-Excited Induction Generator (SEIG) with ELC for the Wind Energy System." In Lecture Notes in Electrical Engineering, 219–36. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-4692-1_17.

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Paliwal, Swati, Sanjay Kumar Sinha, and Yogesh Kumar Chauhan. "Frequency Control of 5 kW Self-excited Induction Generator Using Gravitational Search Algorithm and Genetic Algorithm." In Studies in Infrastructure and Control, 75–88. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-16-1011-0_8.

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Ray, Sambaran, Himadri Sekhar Chatterjee, Dipanjan Samajpati, Sankar Narayan Mahato, and Nirmal Kumar Roy. "Two-Port Network-Based Modeling and Analysis of Three-Phase Self-excited Induction Generator Used in Renewable Energy Systems." In Advances in Smart Grid Automation and Industry 4.0, 411–18. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-15-7675-1_41.

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Balow, Writwik, Arabinda Das, Amarnath Sanyal, and Raju Basak. "Optimal Value of Excitation of Self-excited Induction Generators by Simulated Annealing." In Advances in Intelligent Systems and Computing, 171–78. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-74808-5_15.

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"Self-Excited Induction Generator." In Alternative Energy Systems, 85–102. CRC Press, 2007. http://dx.doi.org/10.1201/9781420055344-7.

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Conference papers on the topic "SELF-EXCITED INDUCTION GENERATOR"

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Sowndarya, K., Essaki Raj R., and C. Kamalakannan. "Voltage control of Self-Excited Induction Generator." In 2014 IEEE 2nd International Conference on Electrical Energy Systems (ICEES). IEEE, 2014. http://dx.doi.org/10.1109/icees.2014.6924182.

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Dalei, Jyotirmayee, and Kanungo Barada Mohanty. "Fault detection of self excited induction generator." In 2015 International Conference on Energy, Power and Environment: Towards Sustainable Growth (ICEPE). IEEE, 2015. http://dx.doi.org/10.1109/epetsg.2015.7510063.

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Khan, M. Faisal, and M. Rizwan Khan. "Self regulating three phase-self excited induction generator for standalone generation." In 2013 Annual IEEE India Conference (INDICON). IEEE, 2013. http://dx.doi.org/10.1109/indcon.2013.6726124.

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Singh, Sunil, Murari Lal Azad, and Atul Kumar. "Electronic load controllers for self excited induction generator." In 2016 International Conference on Innovation and Challenges in Cyber Security (ICICCS-INBUSH). IEEE, 2016. http://dx.doi.org/10.1109/iciccs.2016.7542354.

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Mekkaoui, N., M. S. Nait-Said, and S. Drid. "Steady-state analysis of Self -Excited Induction Generator." In 2011 International Conference on Communications, Computing and Control Applications (CCCA). IEEE, 2011. http://dx.doi.org/10.1109/ccca.2011.6031528.

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Ors, Marton. "Voltage control of a self-excited induction generator." In 2008 IEEE International Conference on Automation, Quality and Testing, Robotics. IEEE, 2008. http://dx.doi.org/10.1109/aqtr.2008.4588928.

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Ma, D. D., B. Zahawi, D. Giaouris, S. Banerjee, and V. Pickert. "Nonlinear Behavior of Self-excited Induction Generator Feeding an Inductive Load." In 2006 International Conference on Power Electronic, Drives and Energy Systems. IEEE, 2006. http://dx.doi.org/10.1109/pedes.2006.344340.

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Ganesh Kumar, S., S. Abdul Rahman, and G. Uma. "Operation of self-excited induction generator through Matrix Converter." In 2008 IEEE Applied Power Electronics Conference and Exposition - APEC 2008. IEEE, 2008. http://dx.doi.org/10.1109/apec.2008.4522843.

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9

Palwalia, D. K., and S. P. Singh. "Design and implementation of induction generator controller for single phase self excited induction generator." In 2008 3rd IEEE Conference on Industrial Electronics and Applications (ICIEA). IEEE, 2008. http://dx.doi.org/10.1109/iciea.2008.4582547.

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Nounou, Kamel, Khoudir Marouani, Mohamed Benbouzid, and Bekheira Tabbache. "Six-phase induction machine operating as a standalone self-excited induction generator." In 2014 International Conference on Green Energy. IEEE, 2014. http://dx.doi.org/10.1109/icge.2014.6835415.

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Reports on the topic "SELF-EXCITED INDUCTION GENERATOR"

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Muljadi, E., P. W. Carlin, and R. M. Osgood. Circle diagram approach for self excited induction generators. Office of Scientific and Technical Information (OSTI), May 1993. http://dx.doi.org/10.2172/10161179.

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