Relevant bibliographies by topics / Dynamic Virtual Power Plants

Academic literature on the topic 'Dynamic Virtual Power Plants'

Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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Journal articles on the topic "Dynamic Virtual Power Plants"

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Adabi, M. Ebrahim, and Bogdan Marinescu. "Direct Participation of Dynamic Virtual Power Plants in Secondary Frequency Control." Energies 15, no. 8 (April 10, 2022): 2775. http://dx.doi.org/10.3390/en15082775.

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This paper proposes a novel control strategy in which Renewable Energy Sources (RES) considered in a new Dynamic Virtual Power Plant (DVPP) concept directly participate to Secondary Frequency Control (SFC). This allows full participation of these generators to SFC, i.e., in the same manner as classic synchronous generators by fulfilling identical specifications from both control and contractual points of view. An internal real-time redispatch has been proposed to account in DVPP in order to determine the amount of active power injection by each RES unit for the provision of frequency support at the secondary level. The whole control scheme is designed to take into account both rapid and slow dynamics of modern power systems which contain both classic synchronous generators and rapid power electronics for renewable energy sources in which DVPP is supposed to be inserted. The performance of secondary frequency control strategy has been validated through simulation studies on a two-area benchmark with mixed wind power plants and classic synchronous generators. This work is part of the H2020 POSYTYF project
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Ren, Zizheng, Gregor Verbič, and Jaysson Guerrero. "Multi-period dynamic tariffs for prosumers participating in virtual power plants." Electric Power Systems Research 212 (November 2022): 108478. http://dx.doi.org/10.1016/j.epsr.2022.108478.

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Zhong, Weilin, Junru Chen, Muyang Liu, Mohammed Ahsan Adib Murad, and Federico Milano. "Coordinated Control of Virtual Power Plants to Improve Power System Short-Term Dynamics." Energies 14, no. 4 (February 23, 2021): 1182. http://dx.doi.org/10.3390/en14041182.

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The paper proposes a coordinated frequency control strategy for Virtual Power Plant (VPPs), with the inclusion of Distributed Energy Resource (DERs), e.g., Solar Photo-Voltaic Generation (SPVG), Wind Generator (WG) as well as Energy Storage System (ESS). The objective is to improve the short-term dynamic response of the overall power system. The robustness of the proposed control is evaluated through a Monte Carlo analysis and a detailed modeling of stochastic disturbances of loads, wind speed, and solar irradiance. The impact of communication delays of a variety of realistic communication networks with different bandwidths is also discussed and evaluated. The case study is based on a modified version of the WSCC 9-bus test system with inclusion of a VPP. This is modeled as a distribution network with inclusion of a variety of DERs.
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Abdollahi, Mostafa, Jose Ignacio Candela, Andres Tarraso, Mohamed Atef Elsaharty, and Elyas Rakhshani. "Electromechanical Design of Synchronous Power Controller in Grid Integration of Renewable Power Converters to Support Dynamic Stability." Energies 14, no. 8 (April 10, 2021): 2115. http://dx.doi.org/10.3390/en14082115.

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Nowadays, modern power converters installed in renewable power plants can provide flexible electromechanical characteristics that rely on the developed control technologies such as Synchronous Power Controller (SPC). Since high renewable penetrated power grids result in a low-inertia system, this electromechanical characteristic provides support to the dynamic stability of active power and frequency in the power generation area. This goal can be achieved through the proper tuning of virtual electromechanical parameters that are embedded in the control layers of power converters. In this paper, a novel mathematical pattern and strategy have been proposed to adjust dynamic parameters in Renewable Static Synchronous Generators controlled by SPC (RSSG-SPC). A detailed dynamic modeling was obtained for a feasible design of virtual damping coefficient and virtual moment of inertia in the electrometrical control layer of RSSG-SPC’s power converters. Mathematical solutions, modal analysis outcomes, time-domain simulation results, and real-time validations of the test in IEEE-14B benchmark confirm that the proposed method is an effective procedure for the dynamic design of RSSG-SPC to provide these dynamic stability supports in grid connection.
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Zhang, Runfan, and Branislav Hredzak. "Distributed Dynamic Clustering Algorithm for Formation of Heterogeneous Virtual Power Plants Based on Power Requirements." IEEE Transactions on Smart Grid 12, no. 1 (January 2021): 192–204. http://dx.doi.org/10.1109/tsg.2020.3020163.

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Du, Dong Mei, Chun Shui Zhu, Hong Li, and Qing He. "Dynamic Characteristics of Belt Conveyor Based on Virtual Prototyping." Applied Mechanics and Materials 157-158 (February 2012): 1685–88. http://dx.doi.org/10.4028/www.scientific.net/amm.157-158.1685.

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Belt conveyor is main transportation in coal-fired power plants. The traditional static design method that considering less actual working condition is main method in designing belt conveyor, and the method using the virtual prototype technology to design product can save cost while improving efficiency, but also use dynamics method to improve products. Build belt conveyor basic system that based on a certain type of belt conveyor, it is accomplished by using simulation software and conveyor belt discretization method. It can be obtained that virtual prototype technology is feasible and effective in belt conveyor dynamic design. By discussing the tension characteristics of belt conveyor, obtain the position of maximum tension and the tension distribution which have guiding significance for designing and maintaining belt conveyor.
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Bolbot, Victor, Gerasimos Theotokatos, Rainer Hamann, George Psarros, and Evangelos Boulougouris. "Dynamic Blackout Probability Monitoring System for Cruise Ship Power Plants." Energies 14, no. 20 (October 13, 2021): 6598. http://dx.doi.org/10.3390/en14206598.

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Stringent environmental regulations and efforts to improve the shipping operations sustainability have resulted in designing and employing more complex configurations for the ship power plants systems and the implementation of digitalised functionalities. Due to these systems complexity, critical situations arising from the components and subsystem failures, which may lead to accidents, require timely detection and mitigation. This study aims at enhancing the safety of ship complex systems and their operation by developing the concept of an integrated monitoring safety system that employs existing safety models and data fusion from shipboard sensors. Detailed Fault Trees that model the blackout top event, representing the sailing modes of a cruise ship and the operating modes of its plant, are employed. Shipboard sensors’ measurements acquired by the cruise ship alarm and monitoring system are integrated with these Fault Trees to account for the acquired shipboard information on the investigated power plant configuration and its components operating conditions, thus, facilitating the estimation of the blackout probability time variation as well as the dynamic criticality assessment of the power plant components. The proposed concept is verified by using a virtual simulation environment developed in Matlab/Simulink. This study supports the dynamic assessment of the ship power plants and therefore benefits the decision-making for enhancing the plant safety during operations.
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Bolbot, Victor, Gerasimos Theotokatos, Rainer Hamann, George Psarros, and Evangelos Boulougouris. "Dynamic Blackout Probability Monitoring System for Cruise Ship Power Plants." Energies 14, no. 20 (October 13, 2021): 6598. http://dx.doi.org/10.3390/en14206598.

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Stringent environmental regulations and efforts to improve the shipping operations sustainability have resulted in designing and employing more complex configurations for the ship power plants systems and the implementation of digitalised functionalities. Due to these systems complexity, critical situations arising from the components and subsystem failures, which may lead to accidents, require timely detection and mitigation. This study aims at enhancing the safety of ship complex systems and their operation by developing the concept of an integrated monitoring safety system that employs existing safety models and data fusion from shipboard sensors. Detailed Fault Trees that model the blackout top event, representing the sailing modes of a cruise ship and the operating modes of its plant, are employed. Shipboard sensors’ measurements acquired by the cruise ship alarm and monitoring system are integrated with these Fault Trees to account for the acquired shipboard information on the investigated power plant configuration and its components operating conditions, thus, facilitating the estimation of the blackout probability time variation as well as the dynamic criticality assessment of the power plant components. The proposed concept is verified by using a virtual simulation environment developed in Matlab/Simulink. This study supports the dynamic assessment of the ship power plants and therefore benefits the decision-making for enhancing the plant safety during operations.
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Zhou, Bin, Kuan Zhang, Ka Wing Chan, Canbing Li, Xi Lu, Siqi Bu, and Xiang Gao. "Optimal Coordination of Electric Vehicles for Virtual Power Plants With Dynamic Communication Spectrum Allocation." IEEE Transactions on Industrial Informatics 17, no. 1 (January 2021): 450–62. http://dx.doi.org/10.1109/tii.2020.2986883.

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Baek, Sejin, and Gyunyoung Heo. "Application of Dynamic Fault Tree Analysis to Prioritize Electric Power Systems in Nuclear Power Plants." Energies 14, no. 14 (July 8, 2021): 4119. http://dx.doi.org/10.3390/en14144119.

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Because the scope of risk assessments at nuclear power plants (NPPs) is being extended both spatially and temporally, conventional, or static fault trees might not be able to express failure mechanisms, or they could be unnecessarily conservative in their expression. Therefore, realistic assessment techniques are needed to adequately capture accident scenarios. In multi-unit probabilistic safety assessment (PSA), fault trees naturally become more complex as the number of units increases. In particular, when considering a shared facility between units of the electric power system (EPS), static fault trees (SFTs) that prioritize a specific unit are limited in implementing interactions between units. However, dynamic fault trees (DFTs) can be available without this limitation by using dynamic gates. Therefore, this study implements SFTs and DFTs for an EPS of two virtual NPPs and compares their results. In addition, to demonstrate the dynamic characteristics of the shared facilities, a station blackout (SBO), which causes the power system to lose its function, is assumed—especially with an inter-unit shared facility, AAC DG (Alternate AC Diesel Generator). To properly model the dynamic characteristics of the shared EPS in DFTs, a modified dynamic gate and algorithm are introduced, and a Monte Carlo simulation is adopted to quantify the DFT models. Through the analysis of the DFT, it is possible to confirm the actual connection priority of AAC DG according to the situation of units in a site. In addition, it is confirmed that some conservative results presented by the SFT can be evaluated from a more realistic perspective by reflecting this.
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Dissertations / Theses on the topic "Dynamic Virtual Power Plants"

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Newman, Guy. "Characterisation of virtual power plants." Thesis, University of Manchester, 2010. https://www.research.manchester.ac.uk/portal/en/theses/characterisation-of-virtual-power-plants(5e647750-5a44-40f0-8a33-763361d3a50b).html.

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The growing number of micro generation devices in the electrical network is leading many to consider that these devices can no longer be considered as fit and forget, but should instead be considered as having a demonstrable network impact which should be predicted and utilised. One of the techniques for considering the impacts of these devices is the Virtual Power Plant (VPP). The VPP is the aggregation of all the Distributed Generation (DG) connected into the network up to and including the connection voltage of the VPP, such that the cumulative power up the voltage levels can be seen in the single VPP unit, rather than across a broad spread of devices. One of the crucial tasks in characterising the VPP, developed in this work, is the ability to correctly predict and then aggregate the behaviour of several technology types which are weather driven, as a large proportion of DG is weather driven. Of this weather driven DG, some can only typically be dispatched with modification and the rest cannot be dispatched at all. The aggregation of the VPP as part of the electrical network is also developed, as the constraints of the network and the reliability of the network cannot be overlooked when considering the aggregation of the VPP. From a distribution network operator's (DNO) perspective, these characterisation models can be used to highlight problems in the network introduced by the addition of DG, but are also generally utilitarian in their role of predicting the power output (or negative load) found throughout the network due to DG. For a commercial agent interested in selling energy, these models allow for accurate predictions of energy to be determined for the trading period. A VPP agent would also be adversely affected by line failure in the network, leading to the development of an N-1 analysis based upon reliability rates of the network, which is used as the basis for a discussion on the impacts of single line failure and the mitigation available through feedback from the DNO.
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Squillaci, Carmen. "Gestione dell’energia in Virtual Power Plants." Master's thesis, Alma Mater Studiorum - Università di Bologna, 2017.

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I confini delle risorse di energia distribuita sono in continua espansione negli ultimi anni con conseguenti cambiamenti nella gestione ottimizzata di energia nelle Smart Grid per soddisfare la domanda di energia, apportare miglioramenti alle condizioni ambientali e minimizzare i prezzi. Per raggiungere questo obiettivo si utilizza un Virtual Power Plant con al suo interno un gestore di energia che coordina le unit`a distribuite relative al sistema di energia elettrico. Questo lavoro di tesi sviluppa un modello per la gestione energetica all’interno di un Virtual Power Plant per decidere come e con quali fonti energetiche soddisfare la domanda di energia elettrica. Le decisioni riguardanti le quantita` ed il tipo di risorse energetiche utilizzate ad intervalli orari nell’arco di una giornata avvengono dinamicamente e dipendono da fattori variabili provenienti dalla disponibilit`a delle risorse di energia rinnovabili, dal costo dell’energia elettrica acquistata dalla rete esterna, dal costo del diesel, dai carichi associati ad utenze domestiche e dalla possibilit`a di immagazzinare o rilasciare energia all’interno dell’unit`a di storage. La soluzione `e calcolata mediante l’utilizzo di una funzione costo minimizzata la quale prende in considerazione solo i costi diretti relativi all’impianto VPP. Le conclusioni teoriche e le aspettative sono verificate mediante una simulazione di uno scenario reale.
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Hakobyan, Aram P. "Severe accident analysis using dynamic accident progression event trees." Columbus, Ohio : Ohio State University, 2006. http://rave.ohiolink.edu/etdc/view?acc%5Fnum=osu1158672136.

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Yang, Weijia. "Dynamic Processes and Active Power Control of Hydropower Plants." Licentiate thesis, Uppsala universitet, Elektricitetslära, 2015. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-262768.

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Hydro-electricity plays an important role in the safe, stable and efficient operation of electric power systems. Frequency stability of power systems refers to the ability to maintain steady frequency following a severe system upset resulting in a significant imbalance between generation and load. In order to suppress power grid frequency fluctuations, generating units change their power output automatically according to the change of grid frequency, to make the active power balanced again. This is the primary frequency control (PFC). PFC of electrical power grids is commonly performed by units in hydropower plants (HPPs), because of the great rapidity and amplitude of their power regulation. A hydropower generation system is a complex nonlinear power system including hydraulic, mechanical, electrical and magnetic subsystems. Nowadays, the size of HPPs and the structure complexity of systems have been increasing, especially in China. The proportion of electricity generated by intermittent renewable energy sources have also been growing. Therefore, the performance of HPPs in terms of frequency control is more and more important. The research on control strategies and dynamic processes of HPPs is of great importance. The frequency stability of hydropower units is a critical factor of power system security and power quality. The power response time for evaluating the frequency regulation quality, is also a key indicator. In recent years, there is a tendency that the new turbines experience fatigue to a greater extent than what seem to be the case for new runners decades ago, due to more regulation movements caused by increasingly more integration of intermittent renewable energy sources. In some countries, as in Sweden, PFC is a service that the transmission system operator buys from the power producers. In other countries, as in Norway and China, there is also an obligation for the producers to deliver this service, free of charge. However, there are costs related to this, e.g. due to design constraints and auxiliary equipment when purchasing a new unit or system, and due to wear and tear which affects the expected life time and maintenance intervals. Hence the specific research on wear and tear of hydro units due to PFC is exceedingly necessary.
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Rousseau, Jean-Pierre. "Dynamic evaluation of the solar chimney." Thesis, Link to the online version, 2005. http://hdl.handle.net/10019/1184.

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Kim, Tae-Kyung. "Dynamic analysis of sulfur dioxide monthly emissions in U.S. power plants." Columbus, Ohio : Ohio State University, 2004. http://rave.ohiolink.edu/etdc/view?acc%5Fnum=osu1086195964.

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Thesis (Ph. D.)--Ohio State University, 2004.
Title from first page of PDF file. Document formatted into pages; contains xviii, 218 p.; also includes graphics. Includes abstract and vita. Advisor: Jean Michael Guldmann, City and Regional Planning Graduate Program. Includes bibliographical references (p. 130-133).
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Khamis, Ibrahim Ahmad 1956. "DYNAMIC SIMULATION OF A PROCESS INHERENT ULTIMATE SAFETY POWER PLANT (PIUS)." Thesis, The University of Arizona, 1986. http://hdl.handle.net/10150/275565.

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Wang, Shuwen. "Dynamic reliability using entry-time approach for maintenance of nuclear power plants." [College Station, Tex. : Texas A&M University, 2008. http://hdl.handle.net/1969.1/ETD-TAMU-2790.

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Delgado-Loperena, Dharma. "A stochastic dynamic model for human error analysis in nuclear power plants /." free to MU campus, to others for purchase, 2004. http://wwwlib.umi.com/cr/mo/fullcit?p3137693.

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Merante, Marco. "Application of dynamic rating to improve transportation capability of the power systems connected to wind power plants." Thesis, KTH, Skolan för elektro- och systemteknik (EES), 2016. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-200930.

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Current flow in the electrical grid is changing due to the introduction of new generators and loads.Specifically, weak Overhead lines, are a constraint for the introduction of wind farms located farfrom the central network. The current situation requires smart solutions to improve the transportationcapabilities of these grid’s components. Among the different possibilities, Dynamic Line Rating(DLR), is emerging as the most interesting solution from both the economic and technical points ofview. The presented Thesis work investigates the performance of DLR from both the theoretical andpractical perspectives.The theory behind DLR is based on the development of a thermal model able to estimate the precisetemperature experienced by OHLs conductor under different climate conditions. Since 1972, whenthe first investigation on DLR have been published, different thermal models have been developed,each with a different precision level. The first part of the thesis concerns the investigation of IEEE738 standard accuracy.The standard analysis highlighted weaknesses on the theoretical approach employed on the forcedconvective cooling calculation. Specifically the wind direction effect is estimated as the conductorwas a perfect cylinder. A wind tunnel test has been performed in order to verify the effect of theconductor’s strands on the total thermal equilibrium. The results show that an inclined wind-conductor relative direction can have a more important impacton the line rating than foreseen with the IEEE thermal model. Since the wind tunnel test has been thefirst experience of this kind pursued at KTH, the presence of few different laboratory set-updeficiencies did not allow to draw a definitive and precise conclusion on the necessary IEEE formulacorrection.The practical side of the Thesis project includes an extensive literature research on the differentdevices that can be employed for dynamic line rating and a real-case study analysis. The analysis isperformed in order to evaluate which can be the best solution when the introduction of new windenergy supply increase the load on a pre-existent OHL. Results show that, in the selected region,Värmland, in the southwestern Sweden, DLR has the prerequisites to allow the exploitation of thehigh wind energy resource at the lower expenses. Wind energy production is often associated with anincreased cooling on the line’s conductors. This means that higher current levels can be withstoodavoiding the need for expensive lines’ upgrading. For the selected hot-spot, in 2015, DLR wouldhave allowed a transport capability improvement of 69.6% during the summer and of 26.7% duringthe winter. It is also reported that a load equal to the SLR during the winter period would have causedserious overheating transients of the conductor. Overall DLR proved to allow technical and economicbenefit for the system operator.
Flödet genom elnätet förändras på grund av införandet av ny generering och nya typer av laster.Specifikt är svaga luftledningar en begränsning för installation av vindkraft som ligger långt fråndet centrala nätet. Den nuvarande situationen kräver smarta lösningar för att förbättratransportkapaciteten i elnätet. Bland de olika möjligheterna finns Dynamic Line Rating (DLR) somframstår som den mest intressanta lösningen från både ekonomiska och tekniska synvinklar. Det härexamensarbetet behandlar resultatet av DLR från både teoretiska och praktiska perspektiv.Den teoretiska grunden för DLR är baserad på utvecklingen av en termisk modell som kan skattatemperaturen i luftledningar under olika klimatförhållanden. Examensarbetets första del behandlaren undersökning av IEEE 738 standarden (DLR standard). IEEE 738 standarden utgår från ledarensom en perfekt cylinder. Något som har en effekt bland annat i effekten av vindriktning. Ettvindtunnel test har utförts för att verifiera effekten av fler kardelers effekt på den totala termiskajämvikten. Resultaten visar att antalet kardeler har en betydande effekt på den termiska jämviktenoch då alltså även på DLR.Den andra delen av examensarbetet innehåller en omfattande litteratursökning på de olikaapparaterna som kan användas till DLR samt en praktik undersökning/analys. Analysen utförs föratt utvärdera vilken lösning som kan vara den bästa vid införandet av mer vindkraft, som ökarbelastningen på en redan existerande luftledning. Resultaten visar att, i det valda området,Värmland, i sydvästra Sverige, har DLR förutsättningar för att medge ökat utnyttjandet av den storavindkraft resurs som finns där till relativt låga kostnader. Slutsatsen av examensarbetet är att DLR ger tekniska och ekonomiska fördelar tillsystemoperatören.
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Books on the topic "Dynamic Virtual Power Plants"

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Baringo, Luis, and Morteza Rahimiyan. Virtual Power Plants and Electricity Markets. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-47602-1.

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Jia, Heping, Xuanyuan Wang, Xian Zhang, and Dunnan Liu. Business Models and Reliable Operation of Virtual Power Plants. Singapore: Springer Nature Singapore, 2023. http://dx.doi.org/10.1007/978-981-19-7846-3.

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Hirst, Eric. Ancillary-service details: Dynamic scheduling. Oak Ridge, Tenn: Oak Ridge National Laboratory, 1997.

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Kauppi, Olli. A model of imperfect dynamic competition in the Nordic power market. Helsinki: Helsinki School of Economics, 2009.

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Kauppi, Olli. A model of imperfect dynamic competition in the Nordic power market. Helsinki: Helsinki School of Economics, 2009.

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Fomichev, M. S. Ėksperimentalʹnai͡a︡ gidrodinamika I͡A︡ĖU. Moskva: Ėnergoatomizdat, 1989.

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Benini, Luca. Dynamic power management: Design techniques and CAD tools. Boston: Kluwer, 1998.

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Vittal, Vijay. Grid Integration and Dynamic Impact of Wind Energy. New York, NY: Springer New York, 2013.

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Subudhi, M. Seismic and dynamic qualification of safety related electrical and mechanical equipment. Washington, D.C: Division of Engineering, Office of Nuclear Reactor Regulation, U.S. Nuclear Regulatory Commission, 1986.

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Weidenhamer, G. H. Program plan for environmental qualification of mechanical and dynamic (including seismic) qualification of mechanical and electrical equipment program (EDQP). Washington, D.C: Division of Engineering Technology, Office of Nuclear Regulatory Research, U.S. Nuclear Regulatory Commission, 1986.

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Book chapters on the topic "Dynamic Virtual Power Plants"

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Mihailescu, Radu-Casian, Matteo Vasirani, and Sascha Ossowski. "Dynamic Coalition Adaptation for Efficient Agent-Based Virtual Power Plants." In Multiagent System Technologies, 101–12. Berlin, Heidelberg: Springer Berlin Heidelberg, 2011. http://dx.doi.org/10.1007/978-3-642-24603-6_11.

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Balduin, Stephan, Dierk Brauer, Lars Elend, Stefanie Holly, Jan Korte, Carsten Krüger, Almuth Meier, et al. "Dynamic Portfolio Optimization for Distributed Energy Resources in Virtual Power Plants." In Progress in IS, 131–42. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-44711-7_11.

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Jia, Heping, Xuanyuan Wang, Xian Zhang, and Dunnan Liu. "Dynamic Pricing Strategy of Virtual Power Plants Based on DDPG Reinforcement Learning Algorithm." In Business Models and Reliable Operation of Virtual Power Plants, 91–108. Singapore: Springer Nature Singapore, 2023. http://dx.doi.org/10.1007/978-981-19-7846-3_7.

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Dethlefs, Tim, Thomas Preisler, and Wolfgang Renz. "Dynamic Aggregation of Virtual Power Plants with a Registry System for Distributed Energy Resources." In IFIP Advances in Information and Communication Technology, 65–77. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-66553-5_5.

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Baringo, Luis, and Morteza Rahimiyan. "Virtual Power Plants." In Virtual Power Plants and Electricity Markets, 1–7. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-47602-1_1.

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Morales, Juan M., Antonio J. Conejo, Henrik Madsen, Pierre Pinson, and Marco Zugno. "Virtual Power Plants Virtual power plant." In International Series in Operations Research & Management Science, 243–87. Boston, MA: Springer US, 2013. http://dx.doi.org/10.1007/978-1-4614-9411-9_8.

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Bilbao, Javier, Eugenio Bravo, Carolina Rebollar, Concepcion Varela, and Olatz Garcia. "Virtual Power Plants and Virtual Inertia." In Power Systems, 87–113. Cham: Springer International Publishing, 2019. http://dx.doi.org/10.1007/978-3-030-23723-3_5.

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Baringo, Luis, and Morteza Rahimiyan. "Virtual Power Plant Model." In Virtual Power Plants and Electricity Markets, 9–37. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-47602-1_2.

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Adu-Kankam, Kankam O., and Luis M. Camarinha-Matos. "Towards Collaborative Virtual Power Plants." In IFIP Advances in Information and Communication Technology, 28–39. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-78574-5_3.

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Baringo, Luis, and Morteza Rahimiyan. "Price-Maker Virtual Power Plants." In Virtual Power Plants and Electricity Markets, 255–312. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-47602-1_6.

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Conference papers on the topic "Dynamic Virtual Power Plants"

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Nieße, Astrid, Sebastian Beer, Jörg Bremer, Christian Hinrichs, Ontje Lünsdorf, and Michael Sonnenschein. "Conjoint Dynamic Aggregation and Scheduling Methods for Dynamic Virtual Power Plants." In 2014 Federated Conference on Computer Science and Information Systems. IEEE, 2014. http://dx.doi.org/10.15439/2014f76.

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Bremer, Jorg, and Michael Sonnenschein. "Parallel tempering for constrained many criteria optimization in dynamic virtual power plants." In 2014 IEEE Symposium on Computational Intelligence Applications in Smart Grid (CIASG). IEEE, 2014. http://dx.doi.org/10.1109/ciasg.2014.7011551.

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Dagdougui, Hanane, Ahmed Ouammi, and Roberto Sacile. "Distributed optimal control of a network of virtual power plants with dynamic price mechanism." In 2014 8th Annual IEEE Systems Conference (SysCon). IEEE, 2014. http://dx.doi.org/10.1109/syscon.2014.6819231.

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Raveduto, Giuseppe, Vincenzo Croce, Marcel Antal, Claudia Pop, Ionut Anghel, and Tudor Cioara. "Dynamic Coalitions of Prosumers in Virtual Power Plants for Energy Trading and Profit Optimization." In 2020 IEEE 20th Mediterranean Electrotechnical Conference ( MELECON). IEEE, 2020. http://dx.doi.org/10.1109/melecon48756.2020.9140601.

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Provost, Graham T., Stephen E. Zitney, Richard A. Turton, Michael R. Erbes, and Herman P. Stone. "NETL Virtual Reality Dynamic Simulation Research and Training Center Promotes IGCC Technology With CO2 Capture." In ASME 2010 Power Conference. ASMEDC, 2010. http://dx.doi.org/10.1115/power2010-27249.

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To meet increasing demand for education and experience with commercial-scale, coal-fired, integrated gasification combined cycle (IGCC) plants with CO2 capture, the Department of Energy’s (DOE) National Energy Technology Laboratory (NETL) is leading a project to deploy a generic, full-scope, real-time IGCC dynamic plant simulator for use in establishing a world-class research and training center, and to promote and demonstrate IGCC technology to power industry personnel. The simulator, being built by Invensys Process Systems (IOM), will be installed at two separate sites, at NETL and West Virginia University (WVU), and will combine a process/gasification simulator with a power/combined-cycle simulator together in a single dynamic simulation framework for use in engineering research studies and training applications. The simulator, scheduled to be launched in mid-year 2010, will have the following capabilities: • High-fidelity, dynamic model of process-side (gasification and gas cleaning with CO2 capture) and power-block-side (combined cycle) for a generic IGCC plant fueled by coal and/or petroleum coke. • A fully integrated virtual reality Immersive Training System which allows for training of field personnel using a full scale three dimensional IGCC plant environment that is tied to the simulation and emulated DCS. • Highly flexible configuration that allows concurrent training on separate gasification and combined cycle simulators, or up to two IGCC simulators. • Ability to enhance and modify the plant model to facilitate studies of changes in plant configuration, equipment, and control strategies to support future R&D efforts. • Training capabilities including startup, shutdown, load following and shedding, response to fuel and ambient condition variations, control strategy analysis (turbine vs. gasifier lead, etc.), representative malfunctions/trips, alarms, scenarios, trending, snapshots, data historian, etc.
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Wang, Ning, Xiangyu Kong, Guoqing Li, Xiaofei Li, Xiufen Li, and Zehao Li. "Dynamic Aggregation Response Strategy of Adjustable Resources of Virtual Power Plants in Power Grid Balance Adjustment Scenario." In 2022 25th International Conference on Electrical Machines and Systems (ICEMS). IEEE, 2022. http://dx.doi.org/10.1109/icems56177.2022.9983257.

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Zhang, Zhong, Minho Shin, and Hyuk-Soo Jang. "Fairness-aware Distributed Scheduling of Charging and Discharging Electric Vehicles in Dynamic Virtual Power Plants." In 2019 IEEE Transportation Electrification Conference and Expo, Asia-Pacific (ITEC Asia-Pacific). IEEE, 2019. http://dx.doi.org/10.1109/itec-ap.2019.8903634.

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Muuss, Fridolin, Nasser G. A. Hemdan, Michael Kurrat, Daniel Unger, and Bernd Engel. "Dynamic virtual reactive power plant in active distribution networks." In 2015 IEEE Eindhoven PowerTech. IEEE, 2015. http://dx.doi.org/10.1109/ptc.2015.7232356.

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Verkoyen, Torsten, Rene´ von Dombrowski, and Hubertus Murrenhoff. "Virtual Development Environment for Fluid Power Mechatronic Systems." In ASME 2009 Dynamic Systems and Control Conference. ASMEDC, 2009. http://dx.doi.org/10.1115/dscc2009-2654.

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In this paper the results of the German state-funded research project “Fluidtronic”, that deals with a virtual development environment for fluid technical mechatronic systems, is presented. Firstly the conventional development process of a fluid technical mechatronic system is introduced. The conventional development process typically takes a long time because design failures are often only identified during the plant commissioning. Secondly the new virtual development environment, which is worked out in the “Fluidtronic” project is presented. It shows how both the system performance can be optimized and also how the commissioning time can be reduced extensively, if the interactions between mechanical, electrical and fluid power parts are tested at an early point of time in the development process. Optimizations in the development process are realized with the help of new and improved simulation models as well as soft- and hardware in the loop simulations.
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McCorkle, Douglas S., Kenneth M. Bryden, and David A. Swensen. "Using Virtual Engineering Tools to Reduce NOx Emissions." In ASME 2004 Power Conference. ASMEDC, 2004. http://dx.doi.org/10.1115/power2004-52021.

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The use of computational fluid dynamics (CFD) to improve an engineer’s understanding of methods to reduce NOxemissions is becoming more prevalent as high-end computational resources become more economically accessible. These trends have allowed engineers to better design and improve the efficiency of power plants and thus reduce NOx. While these computational models have proven very useful over the past few years, the full extent to which they can be used to gain a better intuition about a design has not been fully explored. One such way to extract more information from these simulations is to use virtual engineering tools to interrogate these models. Currently, there are many virtual engineering tools that are being developed to facilitate the investigation of power plant systems. One such suite of virtual engineering tools is called Virtual Engineering Suite (VE-Suite). The capabilities of this suite include rapid CFD recalculation, optimization routines for large thermal fluids systems, coupling of multiple computational resources, hybrid CFD solvers, interaction with multiple CFD data sets, and manipulation of system geometry. VE-Suite is discussed as an initial platform for this integrated hierarchy of models that can provide a foundation for virtual engineering. VE-Suite has an extensible software architecture and is composed of several tools including VE-Builder, VE-Conductor, VE-Explorer, VE-Designer, and a Computational Engine. One example of the potential use of these virtual engineering tools in the reduction of NOx is presented. In addition, the factors for successful implementation of future virtual engineering tools for the reduction of NOx are proposed.
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Reports on the topic "Dynamic Virtual Power Plants"

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Johnson, Jay Tillay. Full State Feedback Control for Virtual Power Plants. Office of Scientific and Technical Information (OSTI), September 2017. http://dx.doi.org/10.2172/1395431.

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Singh, Mohit, and Surya Santoso. Dynamic Models for Wind Turbines and Wind Power Plants. Office of Scientific and Technical Information (OSTI), October 2011. http://dx.doi.org/10.2172/1028524.

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Popov, Oleksandr O., Anna V. Iatsyshyn, Andrii V. Iatsyshyn, Valeriia O. Kovach, Volodymyr O. Artemchuk, Viktor O. Gurieiev, Yulii G. Kutsan, et al. Immersive technology for training and professional development of nuclear power plants personnel. CEUR Workshop Proceedings, July 2021. http://dx.doi.org/10.31812/123456789/4631.

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Training and professional development of nuclear power plant personnel are essential components of the atomic energy industry’s successful performance. The rapid growth of virtual reality (VR) and augmented reality (AR) technologies allowed to expand their scope and caused the need for various studies and experiments in terms of their application and effectiveness. Therefore, this publication studies the peculiarities of the application of VR and AR technologies for the training and professional development of personnel of nuclear power plants. The research and experiments on various aspects of VR and AR applications for specialists’ training in multiple fields have recently started. The analysis of international experience regarding the technologies application has shown that powerful companies and large companies have long used VR and AR in the industries they function. The paper analyzes the examples and trends of the application of VR technologies for nuclear power plants. It is determined that VR and AR’s economic efficiency for atomic power plants is achieved by eliminating design errors before starting the construction phase; reducing the cost and time expenditures for staff travel and staff training; increasing industrial safety, and increasing management efficiency. VR and AR technologies for nuclear power plants are successfully used in the following areas: modeling various atomic energy processes; construction of nuclear power plants; staff training and development; operation, repair, and maintenance of nuclear power plant equipment; presentation of activities and equipment. Peculiarities of application of VR and AR technologies for training of future specialists and advanced training of nuclear power plant personnel are analyzed. Staff training and professional development using VR and AR technologies take place in close to real-world conditions that are safe for participants and equipment. Applying VR and AR at nuclear power plants can increase efficiency: to work out the order of actions in the emergency mode; to optimize the temporary cost of urgent repairs; to test of dismantling/installation of elements of the equipment; to identify weaknesses in the work of individual pieces of equipment and the working complex as a whole. The trends in the application of VR and AR technologies for the popularization of professions in nuclear energy among children and youth are outlined. Due to VR and AR technologies, the issues of “nuclear energy safety” have gained new importance both for the personnel of nuclear power plants and for the training of future specialists in the energy sector. Using VR and AR to acquaint children and young people with atomic energy in a playful way, it becomes possible to inform about the peculiarities of the nuclear industry’s functioning and increase industry professions’ prestige.
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