Global ETD Search

21	Využití MERS obvodu v silnoproudé elektrotechnice / Utilization of MERS in heavy current engineering Vetiška, Vojtěch January 2011 (has links) This graduation thesis is aimed in usage of MERS circuits in high-current electroengineering. The MERS circuit is a serial variable capacitor which capacity is possible to change by the help of switching of semiconductor components. On beginning of the thesis I shall acquaint you with usage of the MERS circuit. It will be sketched out their basic circuitry, the operating method, possibilities of transistors switching and calculation of the capacity capacitors for particular controlling method. On the prepared device we shall accomplish the predefined measurement. Furthermore we shall create the simulation by means of the Matlab programme. In the end we shall compare the results of the simulation with measured values.
22	Návrh koncepce kompenzace jalového výkonu v průmyslové síti / Design of reactive power compensation in distribution network Popek, Jiří January 2012 (has links) This thesis is about reactive power compensation in industrial network. Task is design reactive power compensation devices, so that the power factor, which is main indicator of power quality, was within the limits required by the distributor. This is applied to wholesale customers of electrical energy. Reactive power consumed by appliances increased the current that flows through the network, transmission losses and voltage drop. Reactive power compensation is a measure reducing load current and ohmic losses in a supply line. Given that the compensation is one of the significant cost-saving measures in electric power distribution. Distributor requires electric power consumption with a lagging power factor in the range from 0,95 to 1. Other values of power factor are penalized.
23	Reaktiv effektkontroll i storskaliga solcellsanläggningar : Analys av växelriktarbaserade kontrollmetoder / REACTIVE POWER CONTROL INSOLAR PV FARMS : Analysis of inverter control method Johansson, Jojje January 2022 (has links) Rapporten redogör för en solcellsanläggnings generering av reaktiv effekt samt för de växelriktarbaserade kontrollmetoderna P(U), Konstant Q, Konstant Cosφ, Cosφ(P), Q(P) samt Q(U) för reaktiv effektkontroll. Rapporten redogör även för möjligheterna till att utnyttja solcellsanläggningen till reaktiv effektkompensation för spänningsreglering för det lokala elnätet. Rapportens syfte är att specificera en eller flera kontrollmetoder som möter både solcellsanläggningens och det lokala elnätets reglerbehov.Rapporten behandlar relevanta elektriska storheter, ger en kort introduktion till Sveriges elnät, elområden samt metoder för frekvens- och spänningsreglering. Solinstrålningens variation samt vanligt förekommande komponenter i en solcellsanläggning kartläggs och rapporten diskuterar även vilka effekter en hög andel solel kan ha på ett elnät.Utgångspunkt för rapporten är HSBs solcellsanläggning i Strängnäs samt Strängnäs lokalnät. Efter samtal med Strängnäs lokalnät konstateras att elnätet inte är i behov av ökad reglerkapacitet för spänningsreglering, dock visar insamlat data att det finns ett reglerbehov för kapacitiv reaktiv effekt. Enligt insamlat data över HSBs solcellsanläggning konstateras att så även är fallet för solcellsanläggningen.Det är därmed fördelaktigt för både HSBs solcellsanläggning och Strängnäs lokalnät med reaktiv effektkompensation med induktiv reaktiv effekt. Eftersom solcellsanläggningen inte behöver ta hänsyn till lokalnätets spänning kan anläggningen välja att styra genereringen av reaktiv effekt med kontrollmetoderna Konstant Q, Konstant Cosφ, Cosφ(P) samt Q(P). Här har kontrollmetoderna Cosφ(P) samt Q(P) fördelen att genereringen av reaktiv effekt baseras på solcellsanläggningens produktion av aktiv effekt och kan därmed implementeras utan risk för att strypa produktionen av aktiv effekt. reactive power reactive power compensation solar PV farm inverter reaktiv effekt reaktiv effektkompensation solel solcellsanläggning växelriktarbaserade kontrollmetoder Energy Engineering Energiteknik
24	Reactive Power Planning And Operation of Power Systems with Wind Farms for Voltage Stability Improvement Moger, Tukaram January 2015 (has links) (PDF) In recent years, the electric power industry around the world is changing continuously due to transformation from regulated market structure to deregulated market structure. The main aim of the transformation of electric supply industry under open access environment is to overcome the some of the limitations faced by the vertically integrated system. It is believed that this transformation will bring in new technologies, integration of other sources of energy such as wind, solar, fuel cells, bio-gas, etc., which are self sustainable and competitive, and better choice for the consumers and so on. As a result, several new issues and challenges have emerged. One of the main issues in power systems is to support reactive power for maintaining the system voltage profile with an acceptable margin of security and reliability required for system operation. In this context, the thesis addresses some of the problems related to planning and operation of reactive power in power systems. Studies are mainly focused on steady state operation of grid systems, grid connected wind farms and distribution systems as well. The reactive power support and loss allocation using Y-bus approach is proposed. It computes the reactive power contribution from various reactive sources to meet the reactive load demand and losses. Further, the allocation of reactive power loss to load or sink buses is also computed. Detailed case studies are carried out on 11-bus equivalent system of Indian southern region power grid under different loading conditions and also tested on 259-bus equivalent system of Indian western region power grid. A comparative analysis is also carried out with the proportional sharing principle and one of the circuit based approach in the literature to highlight the features of the proposed approach. A new reactive power loss index is proposed for identification of weak buses in the system. The new index is computed from the proposed Y-bus approach for the system under intact condition as well as some severe contingencies cases. Fuzzy logic approach is used to select the important and severe line contingencies from the contingency list. The validation of weak load buses identification from the proposed reactive power loss index with that from other well known existing methods in the literature such as Q-V sensitivity based modal analysis and continuation power flow method is carried out to demonstrate the effectiveness of the proposed index. Then, a short-term reactive power procurement/optimal reactive power dispatch analysis is also carried out to determine the optimum size of the reactive compensation devices to be placed at the weak buses for reactive compensation performance analysis in the system. The proposed approach is illustrated on a sample 5-bus system, and tested on sample 10-bus equivalent system and 72-bus equivalent system of Indian southern region power grid. A comprehensive power flow analysis of PQ type models for wind turbine generating units is presented. The diﬀerent PQ type models of fixed/semi-variable speed wind turbine generating units are considered for the studies. In addition, the variable speed wind turbine generating units are considered in fixed power factor mode of operation. Based on these models, a comparative analysis is carried out to assess the impact of wind generation on distribution and transmission systems. 27-bus equivalent distribution test system, 93-bus equivalent test system and SR 297-bus equivalent grid connected wind system are considered for the studies. Lastly, reactive power coordination for voltage stability improvement in grid connected wind farms with different types of wind turbine generating units based on fuzzy logic approach is presented. In the proposed approach, the load bus voltage deviation is minimized by changing the reactive power controllers according to their sensitivity using fuzzy set theory. The fixed/semi-variable speed wind turbine generating units are also considered in the studies because of its impact on overall system voltage performance even though they do not support the system for voltage unlike variable speed wind generators. 297-bus equivalent and 417-bus equivalent grid connected wind systems are considered to present the simulation results. A comparative analysis is also carried out with the conventional linear programming based reactive power optimization technique to highlight the features of the proposed approach. Reactive Power Wind Power Wind Farms Grid Connected Wind Farms Distributed Power Generation Power System Stability Reactive Power Planning Voltage Stability Analysis Reactive Power Support Power Flow Analysis Power Loss Allocation Wind Generator Unit Wind Turbine Generating Unit Electrical Engineering
25	Kompenzace přetoků jalového výkonu do VN soustavy / Compensation of reactive power to avoid its overflow into the MV system Jurák, Viktor January 2019 (has links) This master thesis is focused on analysis of reactive power flow in LV and MV networks. In the first part there is a definition of reactive power and description of individual parts of electrical networks that contribute with their reactive power to distribution network. The second part is dedicated to calculation of power flow in simulation software PSS® Sincal where on numerical models of network different types of network configuration are tested and consequently its influence on reactive power flow is evaluated. A more detailed analysis is dedicated to reactive power compensation in networks with distributed generation equipped with Volt-Var regulation and its possible negative mutual influence. This thesis also includes general recommendation on the basis of network simulation analysis concerning installation of compensating systems in distribution transformer station.
26	[en] ACTUAL REACTIVE POWER CAPABILITY EVALUATION IN AN ELECTRICAL POWER PLANT / [pt] AVALIAÇÃO DA CAPACIDADE REAL DE GERAÇÃO DE POTÊNCIA REATIVA EM UMA USINA DE GERAÇÃO DE ENERGIA ELÉTRICA FRANCISCO CARLOS SANTANNA DA SILVA 26 March 2002 (has links) [pt] As curvas de capacidade de geração de potência reativa fornecidas pelos fabricantes são elaboradas em função dos parâmetros de projeto do gerador, e geralmente não consideram as condições de operação da planta e do sistema como fatores limitantes. É sabido que as condições de operação da planta, tais como tensões nominais do terminal do gerador e das barras auxiliares, valores limites dos reguladores de tensão, potência máxima da turbina e dispositivos de limitação e proteção de sub e sobreexcitação podem ser fatores limitantes da capacidade de geração e absorção de potência reativa. Neste trabalho foi elaborado um método e desenvolvida uma ferramenta computacional para identificar a curva de capacidade real de geração de potência reativa para qualquer ponto de operação. Este trabalho pode ser estendido para qualquer gerador, conhecidas as características da usina. Nos estudos de caso apresentados pôde-se verificar que é possível ampliar a capacidade de geração reativa da usina apenas conhecendo seus reais limites, não necessitando portanto, de grandes investimentos para o aumento dessa capacidade. / [en] They show that different generator loads produce greater heating in different parts of generator. A method is described and a software is presented to evaluate the actual reactive power capability curve considering the operating condition.This paper shows that it is possible to enlarge the reactive power capability only by knowing the actual capability limitations, without raising costs and keeping operation safe.It is important to the generator agent to know its capabilities if it is desidered to provide reactive support as an ancillary service in the new competitive environment. [pt] SUPORTE DE POTENCIA REATIVA [en] REACTIVE POWER SUPPORT [pt] CONTROLE DE TENSAO [en] VOLTAGE CONTROL [pt] LIMITE DE CAPACIDADE REAL [en] REACTIVE POWER RESOURCES [pt] DISPONIBILIDADE DE POTENCIA REATIVA [en] ACTUAL CAPABILITY LIMITATIONS
27	Reactive power compensation of the electricity grid with large-scale offshore wind farms in Sweden : Technical capabilities, grid codes and economic incentives Bråve, Agnes, Särnblad, Sara January 2022 (has links) Year 2040 the goal is to have a 100 % renewable Swedish energy system. Svenska kraftnät (Svk) predicts fully decommissioned nuclear power plants and an increased amount of connected wind power plants, especially offshore, year 2045. These kind of renewable power plants are non-synchronous and do not provide the grid with the same system stability services naturally as synchronous generators, such as nuclear power plants. With the increased number of renewables connected, one future challenge is to maintain the stability of the power grid. Grid stability can be divided into voltage-, frequency- and rotor angle stability.This thesis has investigated how large-scale offshore wind power plants (OWPPs) can contribute with reactive power compensation and in turn voltage stability to a nearby onshore power grid in Sweden. The evaluation has been done from the perspective of the TSO and the OWPP owner interests, with a focus on grid codes, economic incentives and technical capabilities.This project has been made in three parts. First, a comparison of voltage stability control requirements in different European grid codes was made. Secondly, static power flow simulations of a case study of a 1000 MW OWPP have been performed in PowerWorld Simulator, testing the OWPP’s reactive power outputs under different circumstances. Thirdly, a market opportunity analysis has been completed, analyzing reactive power market opportunities for OWPPs as well as for TSOs.The study shows that the reactive power capabilities of the simulated OWPP is considerable higher than the Swedish grid codes requires. Thus, an opportunity is to make the grid codes stricter, in combination with economic incentives. The case study showed that the distance offshore has an impact of the reactive power reaching the grid onshore. Though, the OWPP’s contribution to local voltage stability onshore is considered as good. Finally, with short- and long-term contracts, a reactive power market can be favorable for both the OWPP owner and the TSO. Wind power offshore wind farm reactive power reactive power market grid code RfG voltage stability Vindkraftspark havsbaserad vindkraft reaktiv effekt reaktiv effektmarknad nätkod spänningsstabilitet Engineering and Technology Teknik och teknologier
28	Development of intelligent systems for evaluating voltage profile and collapse under contingency operation Mohammed, Mahmoud M. Jr. January 1900 (has links) Doctor of Philosophy / Department of Electrical and Computer Engineering / Shelli K. Starrett / Monitoring and control of modern power systems have become very complex tasks due to the interconnection of power grids. These large-scale power grids confront system operators with a huge set of system inputs and control parameters. This work develops and compares intelligent systems-based algorithms which may be considered by power system operators or planners to help manage, process, and evaluate large amounts of data due to varying conditions within the system. The methods can be used to provide assistance in making operational control and planning decisions for the system in a timely manner. The effectiveness of the proposed algorithms is tested and validated on four different power systems. First, Artificial Neural Network (ANN) models are developed and compared for two different voltage collapse indices and utilizing two different-sized sets of inputs. The ANNs monitor and evaluate the voltage profile of a system and generate intelligent conclusions regarding the status of the system from a voltage stability perspective. A feature reduction technique, based on the analysis of generated data, is used to decrease the number of inputs fed to the ANN, decreasing the number of physical quantities that need to be measured. The major contribution of this work is the development of four different algorithms to control the VAR resources in a system. Four different objectives were also considered in this part of the work, namely: minimization of the number of control changes needed, minimization of the system power losses, minimization of the system's voltage deviations, and consideration of the computational time required. Each of the algorithms is iterative in nature and is designed to take advantage of a method of decoupling the load flow Jacobian matrix to decrease the time needed per iteration. The methods use sensitivity information derived from the load flow Jacobian and augmented with equations relating the desired control and dependent variables. The heuristic-sensitivity based method is compared to two GA-based methods using two different objective functions. In addition, a FL algorithm is added to the heuristic-sensitivity algorithm and compared to a PS-based algorithm. The last part of this dissertation presents the use of one of the GA-based algorithms to identify the size of shunt capacitor necessary to enhance the voltage profile of a system. A method is presented for utilizing contingency cases with this algorithm to determine required capacitor size. Voltage collapse Reactive power control Static voltage stability analysis Artificial intelligence Contingency Deregulation Electrical Engineering (0544)
29	Simulation and modeling of wind power plants : a pedagogical approach Vyas, Mithunprakash G 25 October 2010 (has links) This thesis report describes the modeling procedure for available the wind turbine generator (WTG) technologies. The models are generic in nature and manufacturer independent. These models are implemented on commercially available dynamic simulation software platforms like PSCAD/EMTDC and MATLAB/SIMULINK. A brief introduction to the available WTG types is provided to understand the technological differences and their key features. The related theoretical concepts to the working of a WTG are explained, which acts as an aid for model development and implementation. Using the theoretical concepts as basis, a WTG model is divided into four parts : 1. Aerodynamic model 2. Mechanical drive train model 3. Electrical machine model 4. Controller model Once the different parts of a WTG are introduced, a groundwork for model implementation on the software platforms is laid. A step-by-step process of implementing a PSCAD or MATLAB model of a WTG is introduced in this thesis. Starting with the most fundamental WTG technology such as fixed-speed also known as direct-connect wind turbine. The model implementation is adanvced to other superior technology like the dynamic rotor resistance control (DRR) and the doubly-fed induction generator (DFIG). To better understand the working of a DFIG, a current-source regulated model (without electrical machine) emulating the DFIG is built on both PSCAD and MATLAB. A full blown converter model of the DFIG with back-to-back converter is then built in PSCAD/EMTDC. An approach to determine the reactive power capability (Q limits) of a DFIG is described. Rotor current limitation and stator current limitation of the DFIG are considered in determining the minimum and maximum reactive power delievered by the DFIG. Variation in the Q limits of a DFIG for change in wind speed is analysed with two different wind speed scenarios. 1. Wind speed from cut-in to rated i.e. 6 m/s - 14 m/s. 2. Wind speed above rated to cut-out i.e. 14 m/s - 20 m/s. Such an analysis, is useful in determining the operating mode of the DFIG. At low wind speeds (below rated), the DFIG can be operated as a STATCOM for exporting and importing reactive power (similar to synchronous machines). While above rated wind speeds, the DFIG can be set to produce maximum active power. Using the DFIG current-source model implemented in MATLAB/SIMULINK, laboratory experiments to plot the power profile of the DFIG is explained. Another experiment to perform independent P-Q control of the DFIG is also included in this report. / text Wind turbine generator Induction machine Active power Reactive power compensation DFIG Modeling Implementation
30	Adaptive control for active distribution networks Sansawatt, Thipnatee Punim January 2012 (has links) Rise of the global environmental awareness and climate change impacts caused by greenhouse gases emissions brings about a revolution in the power and energy industries to reduce fossil fuels and promote low-carbon and renewable distributed generation (DG). The new dimensions, mainly encouraged by the governments’ legislative targets and incentives, have allowed the development of DG worldwide. In the U.K., renewable DG especially wind is being connected on distribution networks and ranges widely in scales. Despite the growing number of potential DG sites, the surplus generation present on the passive networks can lead to some technical problems. In particular, rural networks where wind farms exist are prone to voltage rise and line thermal constraints. In order to accommodate new DG and ensure security of supply and network reliability, active management to mitigate these issues are required. In addition, the duties to provide cost-effective DG connections at avoided expensive investment incurred from conventional solutions, e.g., reinforcement and maintain robust network are a major challenge for Distribution Network Operators (DNOs). This thesis endeavours to develop an adaptive control scheme that provides local and real-time management against voltage variations and line capacity overload at the point of wind connections on rural distribution networks. Taking into account maximising power exports and providing an economically-viable control scheme, the wind turbine’s capability, comprising reactive power control and active power curtailment, is used. Whilst the thesis concentrates on the decentralised control applying several different algorithms, in addition, semi-coordinated and centralised approaches that adopt on-load tap changing transformers’ regulation and Optimal Power Flow tool are developed. Comparisons of these approaches based upon measures, i.e., economics, DG penetration and performance are determined. As an outcome, the developed scheme can enable growing integration of renewable DG on distribution networks and can be seen as an interim solution for the DNOs towards Smart Distribution Networks. 621.31

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