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Статті в журналах з теми "Energy Systems Integration"

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Автор: Grafiati
Опубліковано: 14 березня 2023

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1

Arent, Douglas J., Clayton Barrows, Steven Davis, Gary Grim, Joshua Schaidle, Ben Kroposki, Mark Ruth, and Brooke Van Zandt. "Integration of energy systems." MRS Bulletin 46, no. 12 (December 2021): 1139–52. http://dx.doi.org/10.1557/s43577-021-00244-8.

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2

Ruth, Mark F., and Benjamin Kroposki. "Energy Systems Integration: An Evolving Energy Paradigm." Electricity Journal 27, no. 6 (July 2014): 36–47. http://dx.doi.org/10.1016/j.tej.2014.06.001.

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3

Hestnes, Anne Grete. "Building Integration Of Solar Energy Systems." Solar Energy 67, no. 4-6 (1999): 181–87. http://dx.doi.org/10.1016/s0038-092x(00)00065-7.

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4

Hairer, E., and C. Lubich. "Energy-diminishing integration of gradient systems." IMA Journal of Numerical Analysis 34, no. 2 (October 3, 2013): 452–61. http://dx.doi.org/10.1093/imanum/drt031.

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5

Byk, F. L., and L. S. Myshkina. "Effects of local intelligent energy systems integration." Power engineering: research, equipment, technology 24, no. 1 (May 23, 2022): 3–15. http://dx.doi.org/10.30724/19989903-2022-24-1-3-15.

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Анотація:
The energy sector of Russia is transforming, followed by total electrification and gasification, which has radically changed the fuel landscape and allowed enterprises in various sectors of the economy to create their energy sources based on gas turbine and gas piston cogeneration plants. There are more and more balanced local intelligent energy systems for various purposes, more often operating autonomously, since the process of their integration with the unified energy system of Russia is impossible without power and energy output, which is contrary to the interests of generating companies, territorial grid organizations and the system operator. Overcoming the administrative and technological barriers and obstacles created by significant players in the electric power industry reduces the technical and economic efficiency of local intelligent energy systems that can bring considerable beneficial systemic effects.THE PURPOSE Substantiation of the obtained system effects from integrating local intelligent energy systems.METHODS. A systematic approach to identify the effects of the integration of local intelligent energy systems with the unified energy system of Russia.RESULTS. Local intelligent energy systems are considered objects of distributed electric power industry that perform certain system functions, which is accompanied by a change in the properties of reliability, efficiency and environmental friendliness of the production and transmission of heat and electricity, which leads to various effects. The presence and size of the effects are determined by the type and type of the local intelligent energy system. It is shown that the integration of communal local intelligent energy systems, created for the energy supply of the population and equivalent consumers, has a certain advantage.CONCLUSION. The integration of communal local intelligent energy systems makes it possible to increase the availability and uninterrupted power supply, reduce the negative impact of off-market surcharges and cross-subsidization, improve the uniformity of load schedules for generating and grid equipment, which increases the efficiency of the unified energy system of Russia.
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6

Gottschalk, Marion, Gerald Franzl, Matthias Frohner, Richard Pasteka, and Mathias Uslar. "From Integration Profiles to Interoperability Testing for Smart Energy Systems at Connectathon Energy." Energies 11, no. 12 (December 2, 2018): 3375. http://dx.doi.org/10.3390/en11123375.

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The project Integrating the Energy System (IES) Austria recognises interoperability as key enabler for the deployment of smart energy systems. Interoperability is covered in the Strategic Energy Technology Plan (SET-Plan) activity A4-IA0-5 and provides an added value because it enables new business options for most stakeholders. The communication of smart energy components and systems shall be interoperable to enable smooth data exchange, and thereby, the on demand integration of heterogeneous systems, components and services. The approach developed and proposed by IES, adopts the holistic methodology from the consortium Integrating the Healthcare Enterprise (IHE), established by information technology (IT) vendors in the health sector and standardised in the draft technical report ISO DTR 28380-1, to foster interoperable smart energy systems. The paper outlines the adopted IES workflow in detail and reports on lesson learnt when trial Integration Profiles based on IEC 61850 were tested at the first Connectathon Energy instalment, organised in conjunction with the IHE Connectathon Europe 2018. The IES methodology is found perfectly applicable for smart energy systems and successfully enables peer-to-peer interoperability testing among vendors. The public specification of required Integration Profiles, to be tested at subsequent Connectathon Energy events, is encouraged.
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7

Anvari-Moghaddam, Amjad, Behnam Mohammadi-ivatloo, Somayeh Asadi, Kim Guldstrand Larsen, and Mohammad Shahidehpour. "Sustainable Energy Systems Planning, Integration, and Management." Applied Sciences 9, no. 20 (October 20, 2019): 4451. http://dx.doi.org/10.3390/app9204451.

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8

Han, Ying Hua. "Grid Integration of Wind Energy Conversion Systems." Renewable Energy 21, no. 3-4 (November 2000): 607–8. http://dx.doi.org/10.1016/s0960-1481(00)00042-2.

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9

Cambini, Carlo, Raffaele Congiu, Tooraj Jamasb, Manuel Llorca, and Golnoush Soroush. "Energy Systems Integration: Implications for public policy." Energy Policy 143 (August 2020): 111609. http://dx.doi.org/10.1016/j.enpol.2020.111609.

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10

Garside, A. J. "Alternative energy systems. Electrical integration and utilisation." Endeavour 9, no. 2 (January 1985): 106. http://dx.doi.org/10.1016/0160-9327(85)90049-3.

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11

O'Malley, Mark, and Benjamin Kroposki. "Unlocking Flexibility: Energy Systems Integration [Guest Editorial]." IEEE Power and Energy Magazine 15, no. 1 (January 2017): 10–14. http://dx.doi.org/10.1109/mpe.2016.2629703.

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12

Schulz, Julia, Valerie M. Scharmer, and Michael F. Zaeh. "Energy self-sufficient manufacturing systems – integration of renewable and decentralized energy generation systems." Procedia Manufacturing 43 (2020): 40–47. http://dx.doi.org/10.1016/j.promfg.2020.02.105.

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13

Majdi Nasab, Navid, Jeff Kilby, and Leila Bakhtiaryfard. "Integration of wind and tidal turbines using spar buoy floating foundations." AIMS Energy 10, no. 6 (2022): 1165–89. http://dx.doi.org/10.3934/energy.2022055.

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Анотація:
<abstract> <p>Floating platforms are complex structures used in deep water and high wind speeds. However, a methodology should be defined to have a stable offshore structure and not fail dynamically in severe environmental conditions. This paper aims to provide a method for estimating failure load or ultimate load on the anchors of floating systems in integrating wind and tidal turbines in New Zealand. Using either wind or tidal turbines in areas with harsh water currents is not cost-effective. Also, tidal energy, as a predictable source of energy, can be an alternative for wind energy when cut-in speed is not enough to generate wind power. The most expensive component after the turbine is the foundation. Using the same foundation for wind and tidal turbines may reduce the cost of electricity. Different environment scenarios as load cases have been set up to test the proposed system's performance, capacity and efficiency. Available tidal records from the national institute of Water and Atmospheric Research (NIWA) have been used to find the region suitable for offshore energy generation and to conduct simulation model runs. Based on the scenarios, Terawhiti in Cook Strait with 110 m water height was found as the optimized site. It can be seen that the proposed floating hybrid system is stable in the presence of severe environmental conditions of wind and wave loadings in Cook Strait and gives a procedure for sizing suction caisson anchors.</p> </abstract>
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14

Marczinkowski, Hannah, Poul Alberg Østergaard, and Søren Roth Djørup. "Transitioning Island Energy Systems—Local Conditions, Development Phases, and Renewable Energy Integration." Energies 12, no. 18 (September 10, 2019): 3484. http://dx.doi.org/10.3390/en12183484.

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Анотація:
Islands typically have sensitive energy systems depending on natural surroundings, but innovative technologies and the exploitation of renewable energy (RE) sources present opportunities like self-sufficiency, but also challenges, such as grid instability. Samsø, Orkney, and Madeira are in the transition to increase the RE share towards 100%—however, this is addressed in different ways depending on the local conditions and current development phases in the transition. Scenarios focusing on the short-term introduction of new technologies in the energy systems are presented, where the electricity sector is coupled with the other energy sectors. Here, both smart grid and sector-integrating solutions form an important part in the next 5–15 years. The scenarios are analyzed using the modeling tool EnergyPLAN, enabling a comparison of today’s reference scenarios with 2030 scenarios of higher RE share. By including three islands across Europe, different locations, development stages, and interconnection levels are analyzed. The analyses suggest that the various smart grid solutions play an important part in the transition; however, local conditions, sector integration, and balancing technologies even more so. Overall, the suggestions complement each other and pave the way to reach 100% RE integration for both islands and, potentially, other similar regions.
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15

Fokaides, Paris A., Angeliki Kylili, Andri Pyrgou, and Christopher J. Koroneos. "Integration Potentials of Insular Energy Systems to Smart Energy Regions." Energy Technology & Policy 1, no. 1 (January 2014): 70–83. http://dx.doi.org/10.1080/23317000.2014.969455.

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16

Zhou, Yue. "Guest Editorial : Local energy markets for local energy systems integration." IET Energy Systems Integration 4, no. 4 (November 11, 2022): 421–22. http://dx.doi.org/10.1049/esi2.12083.

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17

Fu, Peng, Danny Pudjianto, Xi Zhang, and Goran Strbac. "Integration of Hydrogen into Multi-Energy Systems Optimisation." Energies 13, no. 7 (April 1, 2020): 1606. http://dx.doi.org/10.3390/en13071606.

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Анотація:
Hydrogen presents an attractive option to decarbonise the present energy system. Hydrogen can extend the usage of the existing gas infrastructure with low-cost energy storability and flexibility. Excess electricity generated by renewables can be converted into hydrogen. In this paper, a novel multi-energy systems optimisation model was proposed to maximise investment and operating synergy in the electricity, heating, and transport sectors, considering the integration of a hydrogen system to minimise the overall costs. The model considers two hydrogen production processes: (i) gas-to-gas (G2G) with carbon capture and storage (CCS), and (ii) power-to-gas (P2G). The proposed model was applied in a future Great Britain (GB) system. Through a comparison with the system without hydrogen, the results showed that the G2G process could reduce £3.9 bn/year, and that the P2G process could bring £2.1 bn/year in cost-savings under a 30 Mt carbon target. The results also demonstrate the system implications of the two hydrogen production processes on the investment and operation of other energy sectors. The G2G process can reduce the total power generation capacity from 71 GW to 53 GW, and the P2G process can promote the integration of wind power from 83 GW to 130 GW under a 30 Mt carbon target. The results also demonstrate the changes in the heating strategies driven by the different hydrogen production processes.
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18

Liu, Chao, and Jing Wang. "Analysis on Integration of Wave Energy Converter Systems." IARJSET 5, no. 8 (August 30, 2018): 1–4. http://dx.doi.org/10.17148/iarjset.2018.581.

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19

Li, Yunwei Ryan, and William Gerard Hurley. "Editorial Special Issue on Sustainable Energy Systems Integration." IEEE Journal of Emerging and Selected Topics in Power Electronics 3, no. 4 (December 2015): 854–57. http://dx.doi.org/10.1109/jestpe.2015.2481958.

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20

Lens, Elisabet V., Alberto Cardona, and Michel Géradin. "Energy Preserving Time Integration for Constrained Multibody Systems." Multibody System Dynamics 11, no. 1 (February 2004): 41–61. http://dx.doi.org/10.1023/b:mubo.0000014901.06757.bb.

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21

Havlik, Jan, and Tomas Dlouhy. "Integration of Biomass Indirect Dryers into Energy Systems." Journal of Chemical Engineering of Japan 50, no. 10 (2017): 792–98. http://dx.doi.org/10.1252/jcej.16we322.

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22

Whittaker, T. J. T., D. Thornhill, S. Lu, and D. Mitchell. "Integration of design systems for energy related applications." Design Studies 16, no. 4 (October 1995): 415–28. http://dx.doi.org/10.1016/0142-694x(95)00018-m.

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23

Bačeković, Ivan, and Poul Alberg Østergaard. "Local smart energy systems and cross-system integration." Energy 151 (May 2018): 812–25. http://dx.doi.org/10.1016/j.energy.2018.03.098.

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24

Uhlar, Stefan, and Peter Betsch. "Energy-consistent integration of multibody systems with friction." Journal of Mechanical Science and Technology 23, no. 4 (April 2009): 901–9. http://dx.doi.org/10.1007/s12206-009-0309-4.

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25

Guerin, J. T., and Andrew Leutheuser. "Vehicle integration issues for hybrid energy storage systems." International Journal of Energy Research 34, no. 2 (November 25, 2009): 164–70. http://dx.doi.org/10.1002/er.1656.

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26

Uhlar, Stefan, and Peter Betsch. "Energy consistent time integration of planar multibody systems." PAMM 6, no. 1 (December 2006): 119–20. http://dx.doi.org/10.1002/pamm.200610040.

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27

Nair, Nirmal-Kumar C., and Niraj Garimella. "Battery energy storage systems: Assessment for small-scale renewable energy integration." Energy and Buildings 42, no. 11 (November 2010): 2124–30. http://dx.doi.org/10.1016/j.enbuild.2010.07.002.

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28

Østergaard, Poul Alberg. "Reviewing optimisation criteria for energy systems analyses of renewable energy integration." Energy 34, no. 9 (September 2009): 1236–45. http://dx.doi.org/10.1016/j.energy.2009.05.004.

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29

Uyar, Tanay Sıdkı, and Doğancan Beşikci. "Integration of hydrogen energy systems into renewable energy systems for better design of 100% renewable energy communities." International Journal of Hydrogen Energy 42, no. 4 (January 2017): 2453–56. http://dx.doi.org/10.1016/j.ijhydene.2016.09.086.

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30

Elbakheit, Abdel Rahman. "A FRAMEWORK TOWARDS ENHANCED SUSTAINABLE SYSTEMS INTEGRATION INTO TALL BUILDINGS DESIGN." International Journal of Architectural Research: ArchNet-IJAR 12, no. 1 (March 29, 2018): 251. http://dx.doi.org/10.26687/archnet-ijar.v12i1.1272.

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Анотація:
Sustainable tall buildings are increasingly under rapid development and scrutiny worldwide. This will pave the way to a new generation of buildings designed in a unique form of Architectural systems integration. That is to say, finding new ways to integrate the systems, finding new common grounds and perhaps more comprehensive optimizations. The significance of integrating sustainable systems within tall buildings is the corner stone in delivering sustainable tall buildings globally. The paper looks into ways and means to better integrate passive and active renewable energy technologies and systems, green and sustainability measures into tall building’s design. Other issues such as architectural Iconography, and heritage and cultural influences on tall building’s design are also mentioned. The objective is to develop a framework for sustainable systems integration in buildings, proposing areas of further integrations customizable to any particular site context. The focus is on key sustainability strategies that drive design solutions to obtain maximum natural lighting, ventilation, heating and cooling, solar electricity/heat generation, possibility of wind energy generation and ground sourced amenities. Some design cases are presented exhibiting these strategies and design options, which clearly demonstrates the potential of tall buildings in creating a promising dense and sustainable future for cities around the globe.
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31

Vlad, Ciprian, and Cristian Victor Lungu. "Considerations regarding PV systems." Annals of the ”Dunarea de Jos” University of Galati Fascicle II Mathematics Physics Theoretical Mechanics 45, no. 2 (December 12, 2022): 126–32. http://dx.doi.org/10.35219/ann-ugal-math-phys-mec.2022.2.14.

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Анотація:
The integration of renewable power supplies in urban areas and their integration in everyday life is the new trend for the latest research. By using renewable power supplies combined with the latest improvements regarding energy efficiency can help reduce energy consumption, greenhouse gas effect and toxic emissions. This paper presents the latest research in PV systems integration within cities. Urban areas have an unexplored potential for decentralized power production. PV systems are affordable and require minimal maintenance, thus making them suitable for such applications.
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32

Mou, Min, Yuhao Zhou, Wenguang Zheng, and Yurong Xie. "Integration and Modeling of Multi-Energy Network Based on Energy Hub." Complexity 2022 (September 5, 2022): 1–11. http://dx.doi.org/10.1155/2022/2698226.

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Анотація:
The energy conversion units and energy storage equipment connected to the multi-energy system are becoming diversified, and the uncertain factors brought by distributed wind power and photovoltaic power generation make the system energy flow structure more complex, which brings great difficulties to the modeling and application of traditional energy hub modeling methods. This study deeply analyzes the multi-energy flow coupling structure and operation mechanism of multi-energy systems, and carries out the power flow calculation and analysis of multi-energy systems based on an energy hub, so as to ensure the safe and stable operation of regional energy. Based on the physical characteristics of energy systems such as power systems, thermal systems, and gas systems, this article studies the comprehensive power flow model including the electric-gas-thermal multi-energy coupling network and proposes the power flow decomposition of the energy supply subsystem and its applicable equation based on Newton–Raphson method. The effectiveness of the proposed method under different operation modes is verified by case studies. The calculation results show that under constant load, the energy hub running in fixing thermal by electricity (FEL) and fixing electricity by thermal (FTL) mode has little influence on the voltage of each node in the power sub-network. Within the constraint range, the natural gas flow obtained from the natural gas subsystem is coupled with the power subsystem to meet the load demand. The influence on the power flow at each node of the heat network is not obvious.
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33

Rakushev, Mikhail. "A METHOD FOR PREDICTING ENERGY-STABILIZED MOTION OF SPACECRAFT BASED ON DIFFERENTIAL TAYLOR TRANSFORMATIONS." Journal of Automation and Information sciences 2 (March 1, 2021): 119–28. http://dx.doi.org/10.34229/1028-0979-2021-2-11.

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Анотація:
To predict the motion of spacecrafts, a numerical-analytical method for integrating the differential equation of the orbital motion of a spacecraft stabilized by the Baumgart differential method is proposed. The stabilization of the differential equation of motion by the Baumgart method is carried out according to the energy of the spacecraft. Stabilization is carried out to reduce the influence of the Lyapunov instability on the accumulation of numerical errors in the integration of the differential equation, which is effective when conducting a long-term numerical prediction of the motion of spacecraft. Integration of the stabilized equation is based on differential Taylor transformations. Computational schemes with a constant step and an integration order are considered, as well as schemes with adaptation by an integration step and order. For adaptive schemes, the results of forecasting the motion of spacecraft according to the criterion “accuracy-computational complexity» for a given relative error of integration with respect to integration phase variables and spacecraft energy are presented. It is shown that both options require setting various internal adaptation parameters, but they have comparable efficiency. Recommendations are proposed on the use of the developed method for integrating energy-stabilized equations for predicting the motion of spacecraft in the near space in the Greenwich rectangular coordinate system.
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34

Winterscheid, C., S. Holler, and J. O. Dalenbäck. "Integration of solar thermal systems into existing district heating systems." Energy Procedia 116 (June 2017): 158–69. http://dx.doi.org/10.1016/j.egypro.2017.05.064.

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35

ZHEN, YI, LIU ZHAO, and ZHANYING YANG. "INTEGRATING SUPER-LIOUVILLE SYSTEM WITHOUT INTEGRATION." Modern Physics Letters A 15, no. 09 (March 21, 2000): 617–28. http://dx.doi.org/10.1142/s0217732300000621.

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Анотація:
Explicit solutions of super-Liouville equation are obtained by the use of a super-extension of the so-called Drinfeld–Sokolov construction. Such solutions can be proved to be local and super-periodic using earlier results of Toppan on exchange algebras based on super-Drinfeld–Sokolov linear systems and of Babelon et al. on the proof of locality and periodicity of ordinary Toda field theories.
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36

Nastasi, Benedetto, Stefano Mazzoni, Daniele Groppi, Alessandro Romagnoli, and Davide Astiaso Garcia. "Optimized integration of Hydrogen technologies in Island energy systems." Renewable Energy 174 (August 2021): 850–64. http://dx.doi.org/10.1016/j.renene.2021.04.137.

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37

Le, D. D., and N. T. A. Nguyen. "Stochastic Sizing of Energy Storage Systems for Wind Integration." Engineering, Technology & Applied Science Research 8, no. 3 (June 19, 2018): 2901–6. http://dx.doi.org/10.48084/etasr.2005.

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Анотація:
In this paper, we present an optimal capacity decision model for energy storage systems (ESSs) in combined operation with wind energy in power systems. We use a two-stage stochastic programming approach to take into account both wind and load uncertainties. The planning problem is formulated as an AC optimal power flow (OPF) model with the objective of minimizing ESS installation cost and system operation cost. Stochastic wind and load inputs for the model are generated from historical data using clustering technique. The model is tested on the IEEE 39-bus system.
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38

Yu, F., Peng Zhang, Weidong Xiao, and Paul Choudhury. "Communication systems for grid integration of renewable energy resources." IEEE Network 25, no. 5 (September 2011): 22–29. http://dx.doi.org/10.1109/mnet.2011.6033032.

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39

Eriksson, E. L. V., and E. MacA Gray. "Optimisation and Integration of Hybrid Renewable Energy Storage Systems." IOP Conference Series: Earth and Environmental Science 73 (July 2017): 012001. http://dx.doi.org/10.1088/1755-1315/73/1/012001.

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40

Deur, Joško, Branimir Škugor, and Mihael Cipek. "Integration of Electric Vehicles into Energy and Transport Systems." Automatika 56, no. 4 (January 2015): 395–410. http://dx.doi.org/10.1080/00051144.2015.11828654.

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41

Dinh, Ngoc-Thanh, and Younghan Kim. "An Energy Efficient Integration Model for Sensor Cloud Systems." IEEE Access 7 (2019): 3018–30. http://dx.doi.org/10.1109/access.2018.2886806.

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42

SIDDHARTHA BHATT, M., R. P. MANDI, and V. N. NANDA KUMAR. "Integration of Energy Systems in the Small-Capacity Range." Energy Sources 20, no. 4-5 (May 1998): 407–26. http://dx.doi.org/10.1080/00908319808970069.

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43

CRESSWELL, D., and I. METCALFE. "Energy integration strategies for solid oxide fuel cell systems." Solid State Ionics 177, no. 19-25 (October 15, 2006): 1905–10. http://dx.doi.org/10.1016/j.ssi.2006.02.028.

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44

Fu, Jing-Li, Wei-Jia Zhao, and Ben-Yong Chen. "Energy–work connection integration schemes for mechanico-electrical systems." Nonlinear Dynamics 70, no. 1 (June 23, 2012): 755–65. http://dx.doi.org/10.1007/s11071-012-0492-1.

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Olken, Mel. "More Than Electricity: Energy Systems Integration [From the Editor]." IEEE Power and Energy Magazine 11, no. 5 (September 2013): 4–8. http://dx.doi.org/10.1109/mpe.2013.2268892.

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Orths, Antje, C. Lindsay Anderson, Tom Brown, Joseph Mulhern, Danny Pudjianto, Bernhard Ernst, Mark O'Malley, James McCalley, and Goran Strbac. "Flexibility From Energy Systems Integration: Supporting Synergies Among Sectors." IEEE Power and Energy Magazine 17, no. 6 (November 2019): 67–78. http://dx.doi.org/10.1109/mpe.2019.2931054.

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Chirapongsananurak, Pisitpol, and Surya Santoso. "Inventions and Innovation in Integration of Renewable Energy Systems." Inventions 3, no. 2 (May 17, 2018): 28. http://dx.doi.org/10.3390/inventions3020028.

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Xian-Jun, Wang, and Fu Jing-Li. "Energy-Work Connection Integration Scheme for Nonholonomic Hamiltonian Systems." Communications in Theoretical Physics 50, no. 5 (November 2008): 1041–46. http://dx.doi.org/10.1088/0253-6102/50/5/05.

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Anvari-Moghaddam, Amjad, Behnam Mohammadi-ivatloo, Somayeh Asadi, and Mohammad Shahidehpour. "Sustainable Energy Systems Planning, Integration and Management (Volume II)." Applied Sciences 12, no. 21 (October 27, 2022): 10914. http://dx.doi.org/10.3390/app122110914.

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Egarter, Dominik, Andrea Monacchi, Tamer Khatib, and Wilfried Elmenreich. "Integration of legacy appliances into home energy management systems." Journal of Ambient Intelligence and Humanized Computing 7, no. 2 (August 4, 2015): 171–85. http://dx.doi.org/10.1007/s12652-015-0312-9.

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