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1دورية أكاديمية
المؤلفون: Kodami Badza, Y. M. Soro, Marie Sawadogo
المصدر: Sustainable Environment Research, Vol 33, Iss 1, Pp 1-15 (2023)
مصطلحات موضوعية: Photovoltaic power plant, Life cycle assessment, Energy payback time, Climate change, Resource scarcity, Sub-saharan Africa, Environmental technology. Sanitary engineering, TD1-1066
وصف الملف: electronic resource
العلاقة: https://doaj.org/toc/2468-2039Test
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2دورية أكاديمية
المؤلفون: P. Yu. Mikheev, M. P. Fedorov, A. N. Chusov, N. A. Politaeva, П. Ю. Михеев, М. П. Фёдоров, А. Н. Чусов, Н. А. Политаева
المساهمون: This research was carried out by Peter the Great St. Petersburg Polytechnic University with the support of the Ministry of Science and Higher Education of the Russian Federation within the framework of the megagrant «Technological challenges and socio-economic transformation in the context of energy transitions» (Agreement No. 075-15- 2022-1136 of 07/01/2022), Данное исследование проведено Санкт-Петербургским политехническим университетом Петра Великого при поддержке Министерства науки и высшего образования Российской Федерации в рамках мегагранта «Технологические проблемы и социально-экономические трансформации в контексте энергетических переходов» (Договор № 075-15-2022-1136 от 01. 07. 2022)
المصدر: Alternative Energy and Ecology (ISJAEE); № 4 (2024); 25-41 ; Альтернативная энергетика и экология (ISJAEE); № 4 (2024); 25-41 ; 1608-8298
مصطلحات موضوعية: ветроводородная энергетика, wind farm, wind turbine, energy costs, energy efficiency, energy payback time, energy return on investment, parameter, technical characteristic, element, wind-hydrogen farm, hydrogen, hydrogen storage, hydrogen battery, wind-hydrogen energy, ветроэлектростанция, ветроэнергетическая установка, затраты энергии, энергоэффективность, коэффициент энергетической эффективности, срок энергетической окупаемости, параметр, техническая характеристика, элемент, ветроводородная электростанция, водород, хранение водорода, водородная батарея
وصف الملف: application/pdf
العلاقة: https://www.isjaee.com/jour/article/view/2405/1952Test; Renewables Global Status Report 2022. Available online: https://www.ren21.net/wp-content/up-loads/2019/05/GSR2023_Full_Report.pdfTest (accessed on 13 May 2023).; Sidorenko G. I., Mikheev P. Yu. Analysis of changes in the values of capital investments for the construction of power facilities based on renewable energy sources. Energetic. – 2017. – № 10. – pp. 34-37.; Renewable Power Generation Costs in 2022. Available online: https://www.irena.org/publications/2022/Jul/Renewable-Power-Generation-Costs-in-2021Test (accessed on 13 April 2023).; Sidorenko G. I., Mikheev P. Yu. On the issue of the efficiency of renewable energy facilities. Energy: economics, technology, ecology. – 2018. – № 2. – pp. 9-16.; Fedorov M. P., Okorokov V. R., Okorokov R. V. Energy Technology and Global Economic Development: Past, Present, Future. St. Petersburg: Science. – 2010. – 412 p.; Sidorenko G. I., Mikheev P. Yu. Assessment of energy efficiency of power plant life cycles on the basis of res. International Scientific Journal for Alternative Energy and Ecology, 2017. – № 1-3. – pp. 101-110.; Fonseca L., Carvalho M. Greenhouse gas and energy payback times for a wind turbine installed in the Brazilian Northeast. Frontiers in Sustainability. – 2022. – pp. 1-10.; Gomaa M. R., Rezk H. Mustafa R. J., Al-Dhaifallah M. Evaluating the Environmental Impacts and Energy Performance of a Wind Farm System Utilizing the Life-Cycle Assessment Method: A Practical Case Study. Energies. – № 12. – 2019.; International Organization for Standardization. Environmental management – Life cycle assessment – Re quirements and guidelines. Switzerland: ISO 14044:2006. – 46 p.; International Organization for Standardization. Environmental management – Life cycle assessment – Principles and framework. Switzerland: ISO 14040:2006. – 28 p.; International Organization for Standardization. Greenhouse gases – Carbon footprint of products – Requirements and guidelines for quantification. Switzerland: ISO 14067:2018. – 42 p.; International Organization for Standardization. Environmental management – Life cycle assessment – Critical review processes and reviewer competencies: Ad ditional requirements and guidelines to ISO 14044:2006. Switzerland: ISO/TS 14071:2014. – 11 p.; Wind Technologies Market Report 2018. U. S. Department of Energy. Office Energy Efficiency and Renewable Energy. Available online: https://wwwTest.energy.gov/sites/prod/files/2019/08/f65/2018%20Wind%20Technologies%20Market%20Report%20FINAL.pdf (accessed on 13 April 2022).; Land-Based Wind Market Report: 2021 Edition. U. S. Department of Energy. Office of Energy Efficiency and Renewable Energy. Available online: https://wwwTest.energy.gov/sites/default/files/2021-08/Land-Based%20Wind%20Market%20Report%202021%20Edition_Full%20Report_FINAL.pdf (accessed on 13 April 2022).; Land-Based Wind Market Report: 2022 Edition. U. S. Department of Energy. Office of Energy Efficiency and Renewable Energy. Available online: https://wwwTest.energy.gov/sites/default/files/202208/land_based_wind_market_report_2202.pdf (accessed on 13 April 2022).; Sidorenko G. I., Mikheev P. Yu. Influence of parameters and technical characteristics of wind turbine elements on financial costs, energy costs and emissions of pollutants. Industrial Energy. – 2018. – № 4. – pp. 101–110.; Garrett P., Ronde K. Life cycle assessment of electricity production from an onshore V100-1.8 MW wind plant. Vestas Wind Systems A/S. – 2011. – 105 p.; Garrett P., Ronde K. Life cycle assessment of electricity production from a V80-2.0 MW gridstreamer wind plant. Vestas Wind Systems A/S. – 2011. – 104 p.; Garrett P., Ronde K. Life cycle assessment of electricity production from a V90-2.0 MW gridstreamer wind plant. Vestas Wind Systems A/S. – 2011. – 105 p.; Garrett P., Priyanka R. Life cycle assessment of electricity production from an onshore V100-2.0 MW wind plant. Vestas Wind Systems A/S. – 2015. – 130 p.; Garrett P., Priyanka R. Life cycle assessment of electricity production from an onshore V110-2.0 MW Wind Plant. Vestas Wind Systems A/S. – 2015. – 129 p.; Garrett P., Priyanka R. Life cycle assessment of electricity production from an onshore V116-2.0 MW wind plant. Vestas Wind Systems A/S. – 2018. – 134 p.; Garrett P., Priyanka R. Life cycle assessment of electricity production from an onshore V120-2.0 MW wind plant. Vestas Wind Systems A/S. – 2018. – 133 p.; Garrett P., Ronde K. Life cycle assessment of electricity production from an onshore V100-2.6 MW wind plant. Vestas Wind Systems A/S. – 2013. – 107 p.; Garrett P., Ronde K. Life cycle assessment of electricity production from an onshore V90-3.0 MW wind plant. Vestas Wind Systems A/S. – 2013. – 106 p.; Garrett P., Ronde K. Life cycle assessment of electricity production from an onshore V105-3.3 MW wind plant. Vestas Wind Systems A/S. – 2014. – 116 p.; Garrett P., Ronde K. Life cycle assessment of electricity production from an onshore V112-3.3 MW wind plant. Vestas Wind Systems A/S. – 2015. – 141 p.; Garrett P., Ronde K. Life cycle assessment of electricity production from an onshore V117-3.3 MW wind plant. Vestas Wind Systems A/S. – 2014. – 117 p.; Garrett P., Ronde K. Life cycle assessment of electricity production from an onshore V126-3.3 MW wind plant. Vestas Wind Systems A/S. – 2014. – 116 p.; Garrett P., Priyanka R. Life cycle assessment of electricity production from an onshore V105-3.45 MW wind plant. Vestas Wind Systems A/S. – 2017. – 134 p.; Garrett P., Priyanka R. Life cycle assessment of electricity production from an onshore V112-3.45 MW wind plant. Vestas Wind Systems A/S. – 2017. – 137 p.; Garrett P., Priyanka R. Life cycle assessment of electricity production from an onshore V117-3.45 MW wind plant. Vestas Wind Systems A/S. – 2017. – 134 p.; Garrett P., Priyanka R. Life cycle assessment of electricity production from an onshore V126-3.45 MW wind plant. Vestas Wind Systems A/S. – 2017. – 134 p.; Garrett P., Priyanka R. Life cycle assessment of electricity production from an onshore V136-3.45 MW wind plant. Vestas Wind Systems A/S. – 2017. – 136 p.; Garrett P., Priyanka R. Life cycle assessment of electricity production from an onshore V117- 4.2 MW wind plant. Vestas Wind Systems A/S. – 2022. – 134 p.; Sagar M., Garrett P. Life cycle assessment of electricity production from an onshore V136-4.2 MW wind plant. Vestas Wind Systems A/S. – 2022. – 133 p.; Sagar M., Garrett P. Life cycle assessment of electricity production from an onshore V150-4.2 MW wind plant. Vestas Wind Systems A/S. – 2022. – 134 p.; Mikheev P. Yu., Sidorenko G., Okorokov R. V., Timofeeva A. Determination of Energy Costs of Wind Farms at All Life Cycle Stages. Advances in Intelligent Systems and Computing. 2020. – Т. 982. – pp. 242-256.; Sidorenko G. I., Mikheev P. Yu. Energy efficiency estimates of the life cycles of onshore wind farms. Energy Management Abroad. – 2019. – № 3. – pp. 20-31.; Mikheev P. Yu. Determination of emissions of pollutants in the production of elements of wind turbines and wind farms by aggregated data. Energy: economics, technology, ecology. – 2023. – № 5. – pp. 38-52.; Technical specifications wind turbine Vestas V110-2MW. Available online: https://www.vestas.com/en/products/2-mw-platform/V110-2-0-mwTest (accessed on 27 April 2022).; Technical specifications wind turbines Vestas V136-3,45 MW. Available online: https://www.vestas.com/en/products/4-mw-platform/V136-3-45-MWTest (accessed on 27 April 2022).; Cryogenic Tank. Gusev A. L., Kudryavtsev I. I., Kupriyanov V. I., Kryakovkin V. P., Terekhov A. S. – Application. 13.11.91, no. 5009089/25, Publ. BI no. 18, 1997, INN: F17C3/08.; Patent of the Russian Federation № 2082910. Cryogenic Tank and Method for Activation of a Chemical Absorbent before Placing it in the Thermal Insulation Cavity of a Cryogenic Tank. Gusev A. L., Kudryavtsev I. I., Kupriyanov V. I., Kryakovkin V. P., Terekhov A. S. – claimed. – No. 5009266/26, Op. BI No. 18, 1997, INN: F17C3/00, 13/00.; Patent of the Russian Federation № 2052158. Method for the Operation of a Vacuum Cryoadsorption Device in the Thermal Insulation Cavity of a Cryogenic Tank. Gusev A. L., Isaev A. V., Kupriyanov V. I., Makarov A. A., Terekhov A. S. – Application. 13.11.91, No.5009136/06, Publ. BI № 1, 1996, I. C. F04B37/02.; Patent of Russian Federation № 2047813. Cryogenic Tank. Gusev A. L., Kudryavtsev I. I., Kryakovkin V. P., Kupriyanov V. I., Terekhov A. S., Garkusha A. P. – applied for. 10.12.91., № 5015702/26.; Patent of Russian Federation № 2103598. Cryogenic pipeline. Gusev A. L. – Application. 5.12.95, № 95120543/06, publ. in BI#3, 1998, ITC F17D5/00, F16L59/06.; Patent of the Russian Federation № 2113871. A method for preventing fire in closed containers and pipelines and a cryogenic pipeline. Gusev A. L., Belousov V. M., Kupriyanov V. I., Kudryavtsev I. I., Kryakovkin V. P., Lyashenko L. V., Bocharikova I. V., Rozhkova E. V., Vysotsky A. F., Schwanke D. V. – Appl. 4.01.96., № 96100184/12, publ. in BI No. 18, MKI A62S2/00.3/ 00.; Patent RF 2113871. Methods of preventing fires in closed vessels and pipelines and a cryogenic pipe-line. IC 1 A62C2/00,3/00. BI 1 18, 1998. Gusev A. L., Belousov V. M., Kupriyanov V. I. et al., 1998.; Patent RF 2103598. Cryogenic pipeline. IC F17D5/00, F16L59/06. BI 1 3, 1998. Gusev A. L., Kudryavtsev I. I., Turundaev A. R., 1995.; Gusev A. L. Project Proposal #1580 «Hydrogen Detectors» // International Scientific Journal for Alternative Energy and Ecology, Issue1, pp. 222-226, 2000.; Gusev A. L. Brief information on the project: «Alternative energy and ecology in ISTC projects» // International scientific journal «Alternative energy and ecology». 2000. №1, pp. 227-228.; Gusev A. L. Low-temperature sensors and hydrogen absorbers. // Alternative energy and ecology, Special issue, 2003, 110-114, pp., 172 p.; Gusev A. L., Kudel’kina E. V., Chaban P.A., Ivkin A. V., Veziroglu T. N., Hampton M. D. Hydrogen sensors for hydrogen transport. The Proceedings for the 30sup>th ISTC Japan Workshop on Advanced Catalysis Technologies in Russia, April 12-19, 2004, Visits to Companies in Japan, Sponsor: Ministry of Education, Culture, Sports, Science and Technology (MEXT), Japan-Rissia Business Cooperation committee; International Science and Technology Center (ISTC). – pp. 232-233.; Gusev A. L., Kudel’kina E. V., Chaban P. A., Ivkin A. V., Veziroglu T. N., Hampton M. D. «Edel’weis-001» standardized unit for testing hydrogen transport sensors. The Proceedings for the 30sup>th ISTC Japan Workshop on Advanced Catalysis Technologies in Russia, April 12-19, 2004, Visits to Companies in Japan, Sponsor: Ministry of Education, Culture, Sports, Science and Technology (MEXT), Japan-Rissia Business Cooperation committee; International Science and Technology Center (ISTC). – pp. 234-235.; Gusev A. L., Kudel’kina E. V., Chaban P. A., Ivkin A. V., Veziroglu T. N., Hampton M. D. Hydrogen sensors for hydrogen transport. Collection of abstracts Conference EuroSun 2004 and 14sup>th International ForumSun (14 Internationales Sonnenforum of DGS e. V.) – June 20-23, 2004 (Freiburg, Germany) and Intersolar 2004, June 24-26, 2004 (Freiburg, Germany). Germany.; Gusev A. L., Kudelkina E. V., Chaban P. A., Ivkin A.V., Hampton M. D., Veziroglu T. N. Unified stand «Edelweiss-001» for testing sensors of hydrogen transport. Collection of abstracts Conference EuroSun 2004 and 14sup>th International ForumSun (14 Internationales Son- nenforum of DGS e. V.) – June 20-23, 2004 (Freiburg, Germany) and Intersolar 2004, June 24-26, 2004 (Freiburg, Germany).; Garelina S. A., Gusev A. L., Zakharyan R. A., Kazaryan M. A., Feofanov I.N. Evaluation of the perspective of application of the new gas analyzer «Megakon 10k» in emercom of Russia // International scientific journal Alternative energy and ecology. – 2014. – No. 22. – P. 46.; Patent for invention RUS 2389992 28.01.2009. Method for determining local and integrated leakage of products and device for its implementation. Gusev A. L., Zababurkin D. I., Kondyrina T. N., Nemyshev V. N.; Patent for invention RUS 2390008 06.10.2008 Gusev A. L., Zababurkin D. I., Popkova V. Ya., Dobrovolsky Yu. A. Gasalarm.; Gusev A. L., Zababurkin D. I. Multi-channel leak detectors for monitoring the level of combustible, toxic and explosive gases // International scientific journal Alternative energy and ecology. – 2010. – No. 10. – pp. 10-15.; Gusev A. L., Zababurkin D. I. Highly sensitive sensors for special applications. // International scientific journal Alternative energy and ecology. – 2010. – No. 10. – pp. 23-30.; Zababurkin D. I., Gusev A. L., Nemyshev V. I. Hydrogen leak detectors and leak indicators // International scientific journal Alternative energy and ecology. – 2010. – No. 6. – pp. 33-42.; Patent for invention RUS 2368882 21.04.2008. Explosive hydrogen sensor. Gusev A. L., Gudilin E. A., Dobrovolsky Yu. A., Nemyshev V. I., Gusakov V. I.; Patent for invention RUS 2371708 05.05.2008. Gusev A. L., Gudilin E. A., Dobrovolsky Yu. A., Kondyrina T. N. Explosive hydrogen sensor.; Patent for invention RUS 2371710 21.07.2008. Hydrogen gas analyzer. Gusev A. L., Gudilin E. A., Dobrovolsky Yu. A., Nemyshev V. N., Kondyrina T. N., Zababurkin D. I.; Patent for invention RUS 2375790 21.07.2008. Piezoresonance hydrogen sensor. Gusev A. L., Gudilin E. A., Dobrovolsky Yu. A., Zababurkin D. I.; Gusev A. L., Zababurkin D. I., Nemyshev V. N. Hydrogen meter. Utility model patent RUS 84988 03.03.2009.; Patent for invention RUS 2362991 03.03.2008. Method for measuring hydrogen content in cryogenic vacuum thermal insulation. Penkov M. M., Naumchik I. V., Vedernikov M. V., Gribakin V. A., Gusev A. L.; Galinov I. V., Gladkov V. S., Gusev A. L., Zababurkin D. I. A Method for calibrating hydrogen sensors by the pressure chamber method // Alternative energy and ecology. – 2009. – No. 11. – pp. 25-29.; Babkina I. V., Gabriels K. S., Gusev A. L., Kalinin Yu. E., Kondrat’eva N. A., Sitnikov A. V., Kushchev S. Structure, electric and gas sensitive properties of nano-crystalline film composites based on IN-Y-O-C. // Alternative Energy and Ecology. – 2009. – No. 8. – pp. 58-66.; Gusev A. L., Naumchik I. V., Penkov M. M. Choice of conditions for application of metal oxide detectors of hydrogen in systems of control of the gas medium of cryogenic hydrogen complexes // Proceedings of the St. Petersburg State University of Low Temperature and Food Technologies. – 2009. – No. 1. – pp. 65-69.; Gusev A. L. Universal scientific research complex «CLEOPATRA». //Alternative energy and ecology. – 2008. – No. 4. – pp. 114-121.; https://www.isjaee.com/jour/article/view/2405Test
الإتاحة: https://doi.org/10.15518/isjaee.2024.04.025-041Test
https://www.isjaee.com/jour/article/view/2405Test -
3دورية أكاديمية
المؤلفون: Ching-Feng CHEN
المصدر: AIMS Energy, Vol 11, Iss 3, Pp 540-554 (2023)
مصطلحات موضوعية: energy return, energy return on investment, life cycle analysis, life cycle energy analysis, offshore floating photovoltaics, energy payback time, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Renewable energy sources, TJ807-830
وصف الملف: electronic resource
العلاقة: https://doaj.org/toc/2333-8334Test
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4دورية أكاديمية
المؤلفون: Hamad Hussain Shah, Piero Bareschino, Erasmo Mancusi, Francesco Pepe
المصدر: Energies, Vol 16, Iss 17, p 6400 (2023)
مصطلحات موضوعية: solar energy, environmental assessment, photovoltaic energy, energy payback time, environmental impacts, Technology
وصف الملف: electronic resource
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5دورية أكاديمية
المصدر: Renewable and Sustainable Energy Reviews 186
مصطلحات موضوعية: Thin-film solar cells, Life cycle assessment, Energy payback time, Global warming potential, Market share, Benchmarking
العلاقة: https://zenodo.org/record/8410589Test; https://doi.org/10.1016/j.rser.2023.113652Test; oai:zenodo.org:8410589
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6دورية أكاديمية
المؤلفون: Himani Nagar
المصدر: Journal of Housing and Advancement in Interior Designing 6(1) 8-15
مصطلحات موضوعية: PV generations, environmental impacts, energy impacts, life cycle assessment (LCA): Energy Payback Time (EPBT): Positive Energy Demand (PED)
العلاقة: https://zenodo.org/communities/civilpubTest; https://zenodo.org/record/7851436Test; https://doi.org/10.5281/zenodo.7851436Test; oai:zenodo.org:7851436
الإتاحة: https://doi.org/10.5281/zenodo.7851436Test
https://doi.org/10.5281/zenodo.7851435Test
https://zenodo.org/record/7851436Test -
7دورية أكاديمية
المساهمون: Department of Civil and Environmental Engineering
مصطلحات موضوعية: Energy payback time, Life-cycle assessment, Microgrid
العلاقة: http://hdl.handle.net/10397/101154Test; 760; 775; 250; 2-s2.0-85065400247; CEE-1261
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8دورية أكاديمية
المصدر: Processes; Volume 11; Issue 3; Pages: 832
مصطلحات موضوعية: cooling PV module, life cycle assessment, cumulative energy demand, total energy requirement, energy payback time
جغرافية الموضوع: agris
وصف الملف: application/pdf
العلاقة: Energy Systems; https://dx.doi.org/10.3390/pr11030832Test
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9دورية أكاديمية
المؤلفون: Masakazu ITO, Ryuto SHIGENOBU, Sari Takahashi, 伊藤 雅一, 重信 颯人, 高橋 沙里
المصدر: Proceedings of JSES conference. 2022, :223
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10دورية أكاديمية
المؤلفون: Emad Ghandourah, Hitesh Panchal, Othman Fallatah, Haitham M. Ahmed, Essam B. Moustafa, Ammar H. Elsheikh
المصدر: Case Studies in Thermal Engineering, Vol 35, Iss , Pp 101966- (2022)
مصطلحات موضوعية: Conventional solar still, Pyramid solar still, Yield, Efficiency, Energy payback time, Engineering (General). Civil engineering (General), TA1-2040
وصف الملف: electronic resource
العلاقة: http://www.sciencedirect.com/science/article/pii/S2214157X2200212XTest; https://doaj.org/toc/2214-157XTest