Search Results - "ЭНЕРГОМЕНЕДЖМЕНТ"

Relation: Актуальные вопросы развития экономики и профессионального образования в современном обществе : материалы XII Международной молодежной научно-практической конференции. Том 2. — Екатеринбург, 2015

Availability: https://elar.uspu.ru/handle/ru-uspu/44842

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8

Conference

Об энергосбережении и повышении энергоэффективности в вузах Свердловской области

Authors: Фоминых, М. Ф.

Subject Terms: ЭНЕРГОЭФФЕКТИВНОСТЬ, ЭНЕРГОСБЕРЕЖЕНИЕ В ВУЗАХ, ПОВЫШЕНИЕ ЭНЕРГОЭФФЕКТИВНОСТИ, ЭНЕРГОМЕНЕДЖМЕНТ, МАТЕРИАЛЫ КОНФЕРЕНЦИЙ, КОНФЕРЕНЦИИ РГППУ, СТУДЕНЧЕСКИЕ КОНФЕРЕНЦИИ

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Relation: Актуальные вопросы развития экономики и профессионального образования в современном обществе : материалы XII Международной молодежной научно-практической конференции. — Екатеринбург, 2015

Availability: https://elar.uspu.ru/handle/ru-uspu/44505

View record from BASE

9

Academic Journal

Evaluation scores of different smart cities in China

Authors: Sapun, Oksana Leonidovna, Shao, Lanjun

Subject Terms: экология, smart transportation systems, умные города, городское планирование, smart cities, energy management, waste reduction, умные транспортные системы, сокращение отходов, eco-friendly urban planning, энергоменеджмент

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Access URL: https://rep.bsatu.by/handle/doc/22042

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10

Academic Journal

INDUSTRIAL MICROGRIDS AS TOOLS FOR MANAGING THE ENERGY EFFICIENCY IN INDUSTRIAL REGIONS ; ПРОМЫШЛЕННЫЕ СИСТЕМЫ РАСПРЕДЕЛЕННОЙ ГЕНЕРАЦИИ КАК ИНСТРУМЕНТ УПРАВЛЕНИЯ ЭНЕРГОЭФФЕКТИВНОСТЬЮ В ПРОМЫШЛЕННЫХ РЕГИОНАХ ; 工业区域中作为能源效率管理工具的分布式发电工业系统

Authors: A. P. Dzyuba, A. V. Semikolenov, А. П. Дзюба, А. В. Семиколенов

Source: Strategic decisions and risk management; Том 15, № 2 (2024); 100-117 ; تصمیمات راهبردی و مدیریت ریسک ها; Том 15, № 2 (2024); 100-117 ; Стратегические решения и риск-менеджмент; Том 15, № 2 (2024); 100-117 ; 战略决策和风险管理; Том 15, № 2 (2024); 100-117 ; 2618-9984 ; 2618-947X ; 10.17747/2618-947X-2024-2

Subject Terms: 工业电力供应、电力成本、工业能源管理、能源消耗、天然气消耗、电力市场, power cost, distributed generation, industrial energy management, energy consumption, natural gas consumption, electricity market, стоимость электроэнергии, промышленный энергоменеджмент, энергопотребление, потребление природного газа, рынок электроэнергии

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Relation: https://www.jsdrm.ru/jour/article/view/1098/1062; https://www.jsdrm.ru/jour/article/view/1098/1091; Abdulkareem S.A., Haghifam M.R., Ghanizadeh Bolandi T. (2021). A novel approach for distributed generation expansion planning considering its added value compared with centralized generation expansion. Sustainable Energy, Grids and Networks, 25: 100417. DOI:10.1016/j.segan.2020.100417.; Abramovich B.N., Sychev Yu.A. (2016). Methods and means of ensuring the energy safety of industrial enterprises with a continuous technological cycle. Industrial Energy, 9: 18-22. (In Russ.); Anuradha K.B.J., Jayatunga U., Ranjit Perera H.Y. (2021). Loss-voltage sensitivity analysis based battery energy storage systems allocation and distributed generation capacity upgrade. Journal of Energy Storage, 36: 102357. DOI:10.1016/j.est.2021.102357.; Baev I., Dzyuba A., Solovyeva I., Kuzmina N. (2018). Improving the efficiency of using small-distributed generation systems through mechanisms of demand management for electricity and gas. International Journal of Energy Production and Management, 3(4): 277-291. DOI:10.2495/EQ-V3-N4-277-291.; Baghbanzadeh D., Salehi J., Samadi Gazijahani F., Shafie-khah M., Catalão J.P.S. (2021). Resilience improvement of multi-microgrid distribution networks using distributed generation. Sustainable Energy, Grids and Networks, 27: 100503. DOI:10.1016/j.segan.2021.100503.; Belmahdi B., El Bouardi A. (2020). Simulation and optimization of microgrid distributed generation: A case study of University Abdelmalek Essaâdi in Morocco. Procedia Manufacturing, 46: 746-753. DOI:10.1016/j.promfg.2020.03.105.; Beltrán J.C., Aristizábal A.J., López A., Castaneda M., Zapata S., Ivanova Y. (2020). Comparative analysis of deterministic and probabilistic methods for the integration of distributed generation in power systems. Energy Reports, 6(sup. 3): 88-104. DOI:10.1016/j.egyr.2019.10.025.; Chulyukova M.V. (2019). Features of modelling of processes of selection isolated work of power supply systems with distributed generation in emergency conditions. In: Energy: management, quality and efficiency of the use of energy resources. Proceedings of the IX International Scientific and Technical Conference, 212-216. (In Russ.); Craig M.T., Jaramillo P., Hodge B.-M., Williams N.J., Severnini E. (2018). A retrospective analysis of the market price response to distributed photovoltaic generation in California. Energy Policy, 121: 394-403. DOI:10.1016/j.enpol.2018.05.061.; Dormidonov P.V. (2019). Distributed energy using cogeneration technology. In: Youth Scientific Forum. Collected papers of XXXIV Student International Scientific and Practical Conference, 24-26. (In Russ.); Dzyuba A.P. (2020). Theory and methodology of energy demand management in industry: Monograph. Chelyabinsk, SUSU Publishing. (In Russ.); Dzyuba A.P., Semikolenov A.V. (2021a). Management of energy costs of industrial enterprises connected to electric grid of electric power producers. Bulletin of Kemerovo State University. Series: Political, Sociological, and Economic Sciences, 2(20). DOI:10.21603/2500-3372-2021-6-2-198-207. (In Russ.); Dzyuba A.P., Semikolenov A.V. (2021b). The relevance of the use of active energy complexes in the Russian industry. Problems of Economics and Management of Oil and Gas Complex, 9(201): 31-40. DOI:10.33285/1999-6942-2021-9(201)-31-40. (In Russ.); Dzyuba A., Solovyeva I. (2020a). Demand-side management in territorial entities based on their volatility trends. International Journal of Energy Economics and Policy, 10(1): 302-315. DOI:10.32479/ijeep.8682.; Dzyuba A., Solovyeva I. (2020b). Price-based demand-side management model for industrial and large electricity consumers. International Journal of Energy Economics and Policy, 10(4): 135-149. DOI:10.32479/ijeep.8982.; Dzyuba A.P., Solovyeva I.A. (2021a). Energy demand management in the global economic space. Chelyabinsk, SUSU Publishing. (In Russ.); Dzyuba A.P., Solovyeva I.A. (2021b). Prospects for energy demand management in Russian regions. Economy of Region, 2(17): 502-519. DOI:10.17059/ekon.reg.2021-2-11. (In Russ.); Dzyuba A.P., Solovyeva I.A., Semikolenov A.V. (2022). Prospects of introducing microgrids in Russian industry. Journal of New Economy, 23(2): 80-101. DOI:10.29141/2658-5081-2022-23-2-5.; Eljrushi G.S., Alrtami R.S., Ben-Gheshir O.M., Elhaddad O.I. (2019). Distributed power generation for scattered population. Alternative Energy and Ecology, 19-21(303-305): 12-16. (In Russ.); Garlet B.T., Duarte Ribeiro J.L., Souza Savian F., Siluk J.C.M. (2019). Paths and barriers to the dffusion of distributed generation of photovoltaic energy in Southern Brazil. Renewable and Sustainable Energy Reviews, 111: 157-169. DOI:10.1016/j.rser.2019.05.013.; Howlader H.O.R., Matayoshi H., Senjyu T. (2015). Distributed generation incorporated with the thermal generation for optimum operation of a smart grid considering forecast error. Energy Conversion and Management, 96: 303-314. DOI:10.1016/j.enconman.2015.02.087.; Howlader H.O.R., Matayoshi H., Senjyu T. (2016). Distributed generation integrated with thermal unit commitment considering demand response for energy storage optimization of smart grid. Renewable Energy, 99: 107-117. DOI:10.1016/j.renene.2016.06.050.; Ilyushin P.V., Berezovsky P.K., Filippov S.P. (2019). Formation of technical requirements for generating settings of distributed generation to participate in voltage regulation. In: Voropai N.I. (ed). Methodological issues of studying the reliability of large energy systems. Irkutsk, L.A. Melentyev Energy Systems Institute of the Siberian Branch of RAS, 64-73. (In Russ.); Kakran S., Chanana S. (2018). Smart operations of smart grids integrated with distributed generation: A review. Renewable and Sustainable Energy Reviews, 81, part 1: 524-535. DOI:10.1016/j.rser.2017.07.045.; Khudyakov K.I., Chirov D.A., Smirnov A.Yu., Yakovlev S.O. (2020). Problems of integration of distributed generation and centralised power supply system. In: Priority directions of the innovation activity in the industry. Collection of scientific articles upon the results of the Third International Scientific Conference, 162-164. (In Russ.); Kuchin P.G., Ragutkin A.V., Shigaev I.A. (2010). Distributed generation as a way of effective power supply to consumers. In: Energy and resource conservation - XXI century. A collection of materials of the VIII International Scientific and Practical Internet Conference, 68-69. (In Russ.); Kumar M., Kumar A., Sandhu K.S. (2018). Impact of distributed generation on nodal prices in hybrid electricity market. International Conference on Processing of Materials, Minerals and Energy, 5(1), part 1: 830-840. 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The operating modes of intellectual energy systems, with a high share of distributed generation. In: Innovative scientific research: Theory, methodology, practice. Collection of articles of the XXI International Scientific and Practical Conference, 34-36. (In Russ.); Makarova A.S., Pankeshina T.G., Khorshev A.A. (2018). Approaches to assessing the competitiveness of distributed cogeneration sources in comparison with large thermal power plants. In: Management of large-scale system development. Proceedings of 2018 11th International Conference ‘Under the general editorship’, 468-469. (In Russ.); Martínez S.D.F., Campos A., Villar J., Rivier M. (2021). Joint energy and capacity equilibrium model for centralized and behind-the-meter distributed generation. International Journal of Electrical Power & Energy Systems, 131: 107055. DOI:10.1016/j.ijepes.2021.107055.; Matos S.P.S., Vargas M.C., Fracalossi L.G.V., Encarnação L.F., Batista O.E. (2021). Protection philosophy for distribution grids with high penetration of distributed generation. Electric Power Systems Research, 196: 107203. DOI:10.1016/j.epsr.2021.10720.; Menke J.-H., Bornhorst N., Braun M. (2019). Distribution system monitoring for smart power grids with distributed generation using artificial neural networks. International Journal of Electrical Power & Energy Systems, 113: 472-480. DOI:10.1016/j.ijepes.2019.05.057.; Myshkina L.S. (2019). Modeling the regional electric network and increasing reliability due to new technologies. Chief Power Engineer, 9: 17-24. (In Russ.); Nakada T., Shin K., Managi S. (2016). The effect of demand response on purchase intention of distributed generation: Evidence from Japan. Energy Policy, 94: 307-316. DOI:10.1016/j.enpol.2016.04.026.; Nalbandian G.G., Zholnerchik S.S. (2018). Key factors of effective application of distributed generation technologies in industry. Strategic Decisions and Risk Management, 1(104): 80-87. (In Russ.); Nejad H.C., Tavakoli S., Ghadimi N., Korjani S., Nojavan S., Pashaei-Didani H. (2019). Reliability based optimal allocation of distributed generations in transmission systems under demand response program. Electric Power Systems Research, 176: 105952. DOI:10.1016/j.epsr.2019.105952.; Nepomnyashchiy V.A., Ilyushin P.V. (2013). New approaches to ensure the reliability of power supply to consumers of electric energy. Safety and Reliability of Power Industry, 4(23): 14-25. (In Russ.); Nurmukhametov A.F. (2020). Distributed generation. Operating modes of autonomous power supply systems. In: Problems and prospects for the development of the electric power industry and electrical engineering. Materials of the II All-Russian Scientific and Practical Conference, 355-358. (In Russ.); Pivnyuk V.A. (2008). Innovative energy technologies for transforming energy and distributed cogeneration - The basis of the energy of the future. Integral, 3: 42-43. (In Russ.); Pogodin A.A. (2019). Distributed generation in power supply schemes for industrial production. In: Current trends in the development of engineering and technology in Russia and abroad: Realities, opportunities, prospects. Nizhny Novgorod, State Engineering and Economic Institute (Knyaginino), 2: 230-232. (In Russ.); Poudineh R., Jamasb T. (2014). Distributed generation, storage, demand response and energy efficiency as alternatives to grid capacity enhancement. Energy Policy, 67: 222-231. DOI:10.1016/j.enpol.2013.11.073.; Ragutkin A.V. (2013). Distributed generation as a way of effective and reliable power supply to consumers. Electrical Equipment: Operation and Repair, 7: 17-19. (In Russ.); Rahiminejad A., Vahidi B., Hejazi M.A., Shahrooyan S. (2016). Optimal scheduling of dispatchable distributed generation in smart environment with the aim of energy loss minimization. Energy, 116, part 1: 190-201. DOI:10.1016/j.energy.2016.09.111.; Rytsova A.V. (2018). Influence of distributed generation on the mode of operation of the power system. Bulletin of Modern Research, 12.5(27): 247-249. (In Russ.); Safonov A.I., Lipikhin E.G., Shevelev D.V. (2016). Overview of the market for low-power cogeneration plants. Actual Problems of the Humanities and Natural Sciences, 1(11): 94-99. (In Russ.); Samper M., Coria G., Facchini M. (2021). Grid parity analysis of distributed PV generation considering tariff policies in Argentina. Energy Policy, 157: 112519. DOI:10.1016/j.enpol.2021.112519.; Sandhya K., Chatterjee K. (2021). A review on the state of the art of proliferating abilities of distributed generation deployment for achieving resilient distribution system. Journal of Cleaner Production, 287: 125023. DOI:10.1016/j.jclepro.2020.125023.; Sichevsky A.S., Dolgopol T.L. (2020). Renewable energy as distributed generation of remote settlements. In: Problems and prospects for the development of the electric power industry and electrical engineering. Materials of the II All-Russian Scientific and Practical Conference, 391-394. (In Russ.); Tepchikov R.B., Stashko V.I. (2019). Distributed generation in electric power systems. In: Science and Youth. Materials of XVI All-Russian Scientific and Technical Conference of Students, Post-graduates and Young Scientists, 1109-1111. (In Russ.); Valencia A., Hincapie R.A., Gallego R.A. (2021). Optimal location, selection, and operation of battery energy storage systems and renewable distributed generation in medium-low voltage distribution networks. Journal of Energy Storage, 34: 102158. DOI:10.1016/j.est.2020.102158.; Wang Y., Huang Y., Wang Y., Zeng M., Li F., Wang Y., Zhang Y. (2018). Energy management of smart micro-grid with response loads and distribute generation considering demand response. Journal of Cleaner Productin, 197, part 1: 1069-1083. DOI:10.1016/j.jclepro.2018.06.271.; Yanine F., Sanchez-Squella A., Parejos A., Barrueto A., Rother H., Kumar Sahoo S. (2019). 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https://doi.org/10.17747/2618-947X-2024-2-100-117

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11

Academic Journal

The impact of information technologies in increasing the efficiency of the operational management of electrical networks case study based on ldquo;Red-Nordrdquo; JS Company

Authors: Suslenco, A., Corbu, V.E., Cozniuc, O.I.

Source: Journal of Research on Trade, Management and Economic Development 19 (1) 49-69

Subject Terms: оперативное управление электрическими сетями, информационные технологии, energy management, energie electrică, электроэнергетика, management energetic, information technologies, electricity, энергоменеджмент, operational management of electrical networks, tehnologii informaţionale, gestiune operativă a rețelelor electrice

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Access URL: https://ibn.idsi.md/vizualizare_articol/184529

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12

Мультиагентное моделирование в системе энергоменеджмента микросети: выпускная квалификационная работа магистра

Subject Terms: языковые модели, energy management, взаимодействие агентов, мультиагентные системы, моделирование, simulation, bat algorithm, development tools, инструменты разработки, алгоритм BAT, language models, agent interaction, эволюционные алгоритмы, энергоменеджмент, multi-agent systems, evolutionary algorithms

13

Academic Journal

Энергоменеджмент: цели, функции, методы ; Energomenedzhment: tseli, funktsii, metody

Authors: Микаева Анжела Сергеевна, ФГБОУ ВО «МИРЭА – Российский технологический университет», Anzhela S. Mikaeva, FGBOU VO "MIREA - Rossiiskii tekhnologicheskii universitet", Чумаченко Дмитрий Артёмович, ФГБОУ ВО «Российская академия народного хозяйства и государственной службы при Президенте РФ», Dmitrii A. Chumachenko, The Russian Presidential Academy of National Economy and Public Administration

Source: Law, Economics and Management; 147-151 ; Право, экономика и управление: состояние, проблемы и перспективы; 147-151

Subject Terms: энергосбережение, энергоэффективность, энергоресурсы, энергоменеджмент

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Relation: info:eu-repo/semantics/altIdentifier/isbn/978-5-907688-42-1; https://phsreda.com/e-articles/10507/Action10507-107063.pdf; Уланов В.Л. Организационное развитие компаний энергетического и сырьевого секторов экономики: учебник для вузов / В.Л. Уланов. – М.: Юрайт, 2023. – 312 с. EDN LPQLVE; Коршунова Л.А. Роль энергетического аудита в системе энергетического менеджмента / Л.А. Коршунова, Н.Г. Кузьмина [Электронный ресурс]. – Режим доступа: https://cyberleninka.ru/article/n/rol-energeticheskogo-audita-v-sisteme-energeticheskogo-menedzhmenta (дата обращения: 22.05.2023).; Киямов И.К. Ключевые принципы энергетического менеджмента в энергосбережении / И.К. Киямов, И.Г. Альфузов // Вестник экономики, права и социологии. – 2016. – №1. EDN VSCYMH; Энергетический менеджмент: монография / И.Г. Ахметова, Л.Р. Мухаметова, Н.А. Юдина. – Казань: Казан. гос. энерг. ун-т, 2016. – 146 с.; https://phsreda.com/article/107063/discussion_platform

Availability: https://phsreda.com/article/107063/discussion_platform
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https://doi.org/10.31483/r-107063

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14

Academic Journal