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Journal articles on the topic 'Hydrogen Power'

Author: Grafiati
Published: 4 June 2021
Last updated: 9 February 2022

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1

Kuliyev, S., and S. Fettah. "CATALYTIC HYDROGEN PRODUCTION SYSTEMS FOR PORTABLE POWER APPLICATION." Chemical Problems 17, no. 3 (2019): 393–402. http://dx.doi.org/10.32737/2221-8688-2019-3-393-402.

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2

Ponomarev-Stepnoi, N. N. "Nuclear-Hydrogen Power." Atomic Energy 96, no. 6 (June 2004): 375–85. http://dx.doi.org/10.1023/b:aten.0000041203.24874.65.

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3

He, Guoxin, Hongshui Lv, and Dongmei Yang. "Economic Analysis on Electrolytic Hydrogen Production by Abandoned Wind Power." Journal of Clean Energy Technologies 6, no. 3 (May 2018): 204–8. http://dx.doi.org/10.18178/jocet.2018.6.3.460.

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4

Ponomarev-Stepnoi, N. N. "Atomic-Hydrogen Power Engineering." Herald of the Russian Academy of Sciences 91, no. 3 (May 2021): 297–310. http://dx.doi.org/10.1134/s1019331621030138.

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5

Solovey, V., L. Kozak, A. Shevchenko, M. Zipunnikov, R. Campbell, and F. Seamon. "Hydrogen technology of energy storage making use of wind power potential." Journal of Mechanical Engineering 20, no. 1 (March 31, 2017): 62–68. http://dx.doi.org/10.15407/pmach2017.01.062.

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6

Ono, K. "Hydrogen redox electric power and hydrogen energy generators." International Journal of Hydrogen Energy 41, no. 24 (June 2016): 10284–91. http://dx.doi.org/10.1016/j.ijhydene.2015.07.055.

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7

Brandon, N. P., and Z. Kurban. "Clean energy and the hydrogen economy." Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 375, no. 2098 (June 12, 2017): 20160400. http://dx.doi.org/10.1098/rsta.2016.0400.

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In recent years, new-found interest in the hydrogen economy from both industry and academia has helped to shed light on its potential. Hydrogen can enable an energy revolution by providing much needed flexibility in renewable energy systems. As a clean energy carrier, hydrogen offers a range of benefits for simultaneously decarbonizing the transport, residential, commercial and industrial sectors. Hydrogen is shown here to have synergies with other low-carbon alternatives, and can enable a more cost-effective transition to de-carbonized and cleaner energy systems. This paper presents the opportunities for the use of hydrogen in key sectors of the economy and identifies the benefits and challenges within the hydrogen supply chain for power-to-gas, power-to-power and gas-to-gas supply pathways. While industry players have already started the market introduction of hydrogen fuel cell systems, including fuel cell electric vehicles and micro-combined heat and power devices, the use of hydrogen at grid scale requires the challenges of clean hydrogen production, bulk storage and distribution to be resolved. Ultimately, greater government support, in partnership with industry and academia, is still needed to realize hydrogen's potential across all economic sectors. This article is part of the themed issue ‘The challenges of hydrogen and metals’.
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8

Auweter-Kurtz, Monika, Thomas Golz, Harald Habiger, Frank Hammer, Helmut Kurtz, Martin Riehle, and Christian Sleziona. "High-Power Hydrogen Arcjet Thrusters." Journal of Propulsion and Power 14, no. 5 (September 1998): 764–73. http://dx.doi.org/10.2514/2.5339.

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9

Bichsel, Hans. "Stopping power of hydrogen atoms." Physical Review A 43, no. 7 (April 1, 1991): 4030–31. http://dx.doi.org/10.1103/physreva.43.4030.

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10

Shalimov, Yu N., A. V. Astakhov, N. V. Brysenkova, and A. V. Russu. "HYDROGEN POWER PLANTS FOR AIRCRAFT." Alternative Energy and Ecology (ISJAEE), no. 19-21 (October 18, 2018): 62–71. http://dx.doi.org/10.15518/isjaee.2018.19-21.062-071.

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11

IKI, Norihiko, and Hirohide FURUTANI. "Hydrogen Fired Power Generation System." Journal of the Society of Mechanical Engineers 112, no. 1085 (2009): 296–98. http://dx.doi.org/10.1299/jsmemag.112.1085_296.

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12

VARKARAKI, E., N. LYMBEROPOULOS, E. ZOULIAS, D. GUICHARDOT, and G. POLI. "Hydrogen-based uninterruptible power supply." International Journal of Hydrogen Energy 32, no. 10-11 (July 2007): 1589–96. http://dx.doi.org/10.1016/j.ijhydene.2006.10.036.

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13

Rusanov, V. D. "Hydrogen in the power industry." Atomic Energy 81, no. 2 (August 1996): 559–65. http://dx.doi.org/10.1007/bf02415656.

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14

KOLBENEV, I. "Hydrogen in small power engineering☆." International Journal of Hydrogen Energy 19, no. 9 (September 1994): 765–70. http://dx.doi.org/10.1016/0360-3199(94)90241-0.

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15

Lasseigne-Jackson, A. N., A. Zamarron, I. Ashraf, Brajendra Mishra, and D. L. Olson. "Thermoelectric Power Hydrogen Sensors for Reversible Hydrogen Storage Materials." Materials Science Forum 561-565 (October 2007): 1633–36. http://dx.doi.org/10.4028/www.scientific.net/msf.561-565.1633.

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Thermoelectric power has demonstrated a capability for rapid hydrogen assessment and can achieve the equivalent of the pressure-composition-temperature (activity) diagram. Effective use of hydrogen storage materials occurs in the alpha+beta two-phase region of the activity diagram. A thorough assessment of the content of each phase in this two-phase region can optimize the performance of hydrogen storage materials. The use of thermoelectric power measurements as a hydrogen sensor for reversible batteries is discussed.
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16

Shokri, Alireza, Jacob Schmidt, Xue-Bin Wang, and Steven R. Kass. "Hydrogen Bonded Arrays: The Power of Multiple Hydrogen Bonds." Journal of the American Chemical Society 134, no. 4 (January 19, 2012): 2094–99. http://dx.doi.org/10.1021/ja2081907.

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17

Zhuk, A., N. Novikov, A. Novikov, and V. Frolov. "Hydrogen and aluminum-hydrogen storage in the power industry." Энергетическая политика, no. 5 (2021): 64–79. http://dx.doi.org/10.46920/2409-5516_2021_5159_64.

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18

Kolb, Gregory J., Richard B. Diver, and Nathan Siegel. "Central-Station Solar Hydrogen Power Plant." Journal of Solar Energy Engineering 129, no. 2 (April 13, 2006): 179–83. http://dx.doi.org/10.1115/1.2710246.

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Solar power towers can be used to make hydrogen on a large scale. Electrolyzers could be used to convert solar electricity produced by the power tower to hydrogen, but this process is relatively inefficient. Rather, efficiency can be much improved if solar heat is directly converted to hydrogen via a thermochemical process. In the research summarized here, the marriage of a high-temperature (∼1000°C) power tower with a sulfuric acid∕hybrid thermochemical cycle was studied. The concept combines a solar power tower, a solid-particle receiver, a particle thermal energy storage system, and a hybrid-sulfuric-acid cycle. The cycle is “hybrid” because it produces hydrogen with a combination of thermal input and an electrolyzer. This solar thermochemical plant is predicted to produce hydrogen at a much lower cost than a solar-electrolyzer plant of similar size. To date, only small lab-scale tests have been conducted to demonstrate the feasibility of a few of the subsystems and a key immediate issue is demonstration of flow stability within the solid-particle receiver. The paper describes the systems analysis that led to the favorable economic conclusions and discusses the future development path.
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19

Ye, Jun, and Rongxiang Yuan. "Stochastic scheduling of integrated electricity-heat-hydrogen systems considering power-to-hydrogen and wind power." Journal of Renewable and Sustainable Energy 10, no. 2 (March 2018): 024104. http://dx.doi.org/10.1063/1.5024135.

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20

Yao, B., V. L. Kuznetsov, T. Xiao, X. Jie, S. Gonzalez-Cortes, J. R. Dilworth, H. A. Al-Megren, S. M. Alshihri, and P. P. Edwards. "Fuels, power and chemical periodicity." Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 378, no. 2180 (August 17, 2020): 20190308. http://dx.doi.org/10.1098/rsta.2019.0308.

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The insatiable—and ever-growing—demand of both the developed and the developing countries for power continues to be met largely by the carbonaceous fuels comprising coal, and the hydrocarbons natural gas and liquid petroleum. We review the properties of the chemical elements, overlaid with trends in the periodic table, which can help explain the historical—and present—dominance of hydrocarbons as fuels for power generation. However, the continued use of hydrocarbons as fuel/power sources to meet our economic and social needs is now recognized as a major driver of dangerous global environmental changes, including climate change, acid deposition, urban smog and the release of many toxic materials. This has resulted in an unprecedented interest in and focus on alternative, renewable or sustainable energy sources. A major area of interest to emerge is in hydrogen energy as a sustainable vector for our future energy needs. In that vision, the issue of hydrogen storage is now a key challenge in support of hydrogen-fuelled transportation using fuel cells. The chemistry of hydrogen is itself beautifully diverse through a variety of different types of chemical interactions and bonds forming compounds with most other elements in the periodic table. In terms of their hydrogen storage and production properties, we outline various relationships among hydride compounds and materials of the chemical elements to provide some qualitative and quantitative insights. These encompass thermodynamic and polarizing strength properties to provide such background information. We provide an overview of the fundamental nature of hydrides particularly in relation to the key operating parameters of hydrogen gravimetric storage density and the desorption/operating temperature at which the requisite amount of hydrogen is released for use in the fuel cell. While we await the global transition to a completely renewable and sustainable future, it is also necessary to seek CO 2 mitigation technologies applied to the use of fossil fuels. We review recent advances in the strategy of using hydrocarbon fossil fuels themselves as compounds for the high capacity storage and production of hydrogen without any CO 2 emissions. Based on these advances, the world may end up with a hydrogen economy completely different from the one it had expected to develop; remarkably, with ‘Green hydrogen' being derived directly from the hydrogen-stripping of fossil fuels. This article is part of the theme issue ‘Mendeleev and the periodic table'.
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21

Borruto, A. "Hydrogen–steel interaction: hydrogen embrittlementin pipes for power former plant effluents." International Journal of Hydrogen Energy 24, no. 7 (July 1, 1999): 651–59. http://dx.doi.org/10.1016/s0360-3199(98)00106-2.

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22

Takeda, Minoru. "Seawater Magnetohydrodynamics Power Generator / Hydrogen Generator." Advances in Science and Technology 75 (October 2010): 208–14. http://dx.doi.org/10.4028/www.scientific.net/ast.75.208.

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A seawater magnetohydrodynamics (MHD) power generator / hydrogen generator is expected to become popular with the development of superconducting technology because of low loss and high efficiency. We have designed a new helical-type seawater MHD generator using a solenoid superconducting magnet, by considering the experimental results for a helical-type MHD ship. The experimental and computational results for the helical-type generator including the results of a recent study on hydraulic characteristics are discussed.
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23

STOKES, P. R. "Hydrogen Peroxide for Power and Propulsion." Transactions of the Newcomen Society 69, no. 1 (January 1997): 69–96. http://dx.doi.org/10.1179/tns.1997.004.

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24

Kramer, David. "Could hydrogen bail out nuclear power?" Physics Today 73, no. 8 (August 1, 2020): 20–21. http://dx.doi.org/10.1063/pt.3.4543.

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25

Wu, Corinna. "Power Plants: Algae Churn out Hydrogen." Science News 157, no. 9 (February 26, 2000): 134. http://dx.doi.org/10.2307/4012110.

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26

Doucet, Guillaume, Claude Etiévant, Christophe Puyenchet, Serguey Grigoriev, and Pierre Millet. "Hydrogen-based PEM auxiliary power unit." International Journal of Hydrogen Energy 34, no. 11 (June 2009): 4983–89. http://dx.doi.org/10.1016/j.ijhydene.2008.12.029.

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27

Petrescu, Relly Victoria V., Abniel Machín, Kenneth Fontánez, Juan C. Arango, Francisco M. Márquez, and Florian Ion T. Petrescu. "Hydrogen for aircraft power and propulsion." International Journal of Hydrogen Energy 45, no. 41 (August 2020): 20740–64. http://dx.doi.org/10.1016/j.ijhydene.2020.05.253.

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28

TARNAY, D. "Hydrogen production at hydro-power plants." International Journal of Hydrogen Energy 10, no. 9 (1985): 577–84. http://dx.doi.org/10.1016/0360-3199(85)90032-1.

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29

Dayal, R. K., and N. Parvathavarthini. "Hydrogen embrittlement in power plant steels." Sadhana 28, no. 3-4 (June 2003): 431–51. http://dx.doi.org/10.1007/bf02706442.

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30

Soroudi, Alireza, and Soheil Jafari. "Power to air transportation via hydrogen." IET Renewable Power Generation 14, no. 17 (December 2020): 3384–92. http://dx.doi.org/10.1049/iet-rpg.2020.0414.

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31

Filimonova, Antonina, Andrey Chichirov, Natalya Chichirova, Artem Filimonov, and Alexandr Pechenkin. "Directions Of Hydrogen Power Development In Tatarstan Republic." E3S Web of Conferences 288 (2021): 01074. http://dx.doi.org/10.1051/e3sconf/202128801074.

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Green hydrogen is a promising solution for a decarbonized energy system, and in 2020 the use of hydrogen has increased dramatically around the world. In order to draw attention to the problem of hydrogen energy in Russia and the Republic of Tatarstan, the article analyzes the development paths and main opportunities for the production, transportation, and use of hydrogen at the enterprises of Tatarstan, and calculates the economic efficiency of the “green” hydrogen production by electrolysis at TPPs with CCGTs in Tatarstan. METHODS. Research methods are based on the analysis of literature data and mathematical calculations. RESULTS. Tatarstan, as one of the leading economically developed regions of Russia, could take part in the “green” hydrogen production, the electrochemical equipment design for its production, the development of technologies for the fuel cells use, research and training of highly qualified specialists in the field of hydrogen energy. According to the calculations, the production of the most environmentally friendly hydrogen at TPPs with CCGT in Tatarstan will currently cost an average of 2 euros per kilogram, which is significantly lower than the existing market value. CONCLUSION. Tatarstan can become a competitive region for the “green” hydrogen production and distribution. The main areas of activity should be the pure hydrogen production, the industrial production of freight transport on fuel cells, the production of megawatt-class electrolysers, the utilization of hydrogen-containing petroleum gases at TPPs in gas turbines or in combined cycle power plants with fuel cells.
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32

WANG, Juan, Minghai LI, Yaochao WANG, and Fanhua MA. "E210 THE SIMULATION RESEARCH ON THE NATURAL GAS/HYDROGEN ENGINE'S PERFORMANCE(Power System-2)." Proceedings of the International Conference on Power Engineering (ICOPE) 2009.2 (2009): _2–411_—_2–413_. http://dx.doi.org/10.1299/jsmeicope.2009.2._2-411_.

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33

Li, Zheng, Yan Qin, Xin Cao, Shaodong Hou, and Hexu Sun. "Wind-Solar-Hydrogen Hybrid Energy Control Strategy Considering Delayed Power of Hydrogen Production." Electrotehnica, Electronica, Automatica 69, no. 2 (May 15, 2021): 5–12. http://dx.doi.org/10.46904/eea.21.69.2.1108001.

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In order to meet the load demand of power system, BP based on genetic algorithm is applied to the typical daily load forecasting in summer. The demand change of summer load is analysed. Simulation results show the accuracy of the algorithm. In terms of power supply, the reserves of fossil energy are drying up. According to the prediction of authoritative organizations, the world's coal can be mined for 216 years. As a renewable energy, wind power has no carbon emissions compared with traditional fossil energy. At present, it is generally believed that wind energy and solar energy are green power in the full sense, and they are inexhaustible clean power. The model of wind power solar hydrogen hybrid energy system is established. The control strategy of battery power compensation for delayed power of hydrogen production is adopted, and different operation modes are divided. The simulation results show that the system considering the control strategy can well meet the load demand. Battery energy storage system is difficult to respond to short-term peak power fluctuations. Super capacitor is used to suppress it. This paper studies the battery supercapacitor complementary energy storage system and its control strategy. When the line impedance of each generation unit in power grid is not equal, its output reactive power will be affected by the line impedance and distributed unevenly. A droop coefficient selection method of reactive power sharing is proposed. Energy storage device is needed to balance power and maintain DC voltage stability in the DC side of microgrid. Therefore, a new droop control strategy is proposed. By detecting the DC voltage, dynamically translating the droop characteristic curve, adjusting the output power, maintaining the DC voltage in a reasonable range, reducing the capacity of the DC side energy storage device. Photovoltaic grid connected inverter chooses the new droop control strategy.
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34

S, Mohanraj, Divyapriya S, Amudha A, Emayavaramban G, Viyathukattuva S, and Siva Ramkumar M. "Technical and Economical Analysis of Power Management System for Electric and Hydrogen Vehicles Charging Station Using Solar Powered, Hydrogen and Fuel Cell Technology." International Journal of Psychosocial Rehabilitation 23, no. 4 (December 20, 2019): 582–98. http://dx.doi.org/10.37200/ijpr/v23i4/pr190393.

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35

Aminov, R. Z., and A. N. Egorov. "HYDROGEN-OXYGEN STEAM GENERATOR FOR A CLOSED HYDROGEN COMBUSTION CYCLE." Alternative Energy and Ecology (ISJAEE), no. 13-15 (August 11, 2018): 68–79. http://dx.doi.org/10.15518/isjaee.2018.13-15.068-079.

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The paper analyzes the problems of combustion hydrogen in an oxygen medium for produce high-temperature steam that can be used to produce electricity at various power plants. For example, at the nuclear power plants, the use of a H2-O2 steam generator as part of a hydrogen energy complex makes it possible to increase its power and efficiency in the operational mode due to steam-hydrogen overheating of the main working fluid of a steam-turbine plant. In addition, the use of the hydrogen energy complex makes it possible to adapt the nuclear power plants to variable electric load schedules in conditions of increasing the share of nuclear power plants and to develop environmentally friendly technologies for the production of electricity. The paper considers a new solution of the problem of effective and safe use of hydrogen energy at NPPs with a hydrogen energy complex.Technical solutions for the combustion of hydrogen in the oxygen medium using direct injection of cooling water or steam in the combustion products have a significant drawback – the effect of “quenching” when injecting water or water vapor which leads to a decrease in the efficiency of recombination during cooling of combustion products that is expressed in an increase fraction of non-condensable gases. In this case, the supply of such a mixture to the steam cycle is unsafe, because this can lead to a dangerous increase in the concentration of unburned hydrogen in the flowing part of the steam turbine plant. In order to solve this problem, the authors have proposed a closed hydrogen cycle and a hydrogen vapor overheating system based on it, and carried out a study of a closed hydrogen combustion system which completely eliminates hydrogen from entering the working fluid of the steam cycle and ensures its complete oxidation due to some excess of circulating oxygen.The paper considers two types of hydrogen-oxygen combustion chambers for the system of safe generating of superheated steam using hydrogen in nuclear power plant cycle by using a closed system for burning hydrogen in an oxygen medium. As a result of mathematical modeling of combustion processes and heat and mass transfer, we have determined the required parameters of a hydrogen-oxygen steam generator taking into account the temperature regime of its operation, and a power range of hydrogen-oxygen steam generators with the proposed combustion chamber design.
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36

Karapekmez, Aras, and Ibrahim Dincer. "Modelling of hydrogen production from hydrogen sulfide in geothermal power plants." International Journal of Hydrogen Energy 43, no. 23 (June 2018): 10569–79. http://dx.doi.org/10.1016/j.ijhydene.2018.02.020.

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37

Li, Zheng, Peng Guo, Ruihua Han, and Hexu Sun. "Current status and development trend of wind power generation-based hydrogen production technology." Energy Exploration & Exploitation 37, no. 1 (July 24, 2018): 5–25. http://dx.doi.org/10.1177/0144598718787294.

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The hydrogen production technology by wind power is an effective mean to improve the utilization of wind energy and alleviate the problem of wind power curtailment. First, the basic principles and technical characteristics of the hydrogen production technology by wind power are briefly introduced. Then the history of the hydrogen production technology is reviewed, and on this basis, the hydrogen production system by wind power is elaborated in detail. In addition, the prospect of the application of the hydrogen production technology by wind power is analyzed and discussed. In the end, the key technology of the hydrogen production by wind power and the problems to be solved are comprehensively reviewed. The development of hydrogen production technology by wind power is analyzed from many aspects, which provides reference for future development of hydrogen production technology by wind power.
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38

Borm, Oliver, and Stephen B. Harrison. "Reliable off-grid power supply utilizing green hydrogen." Clean Energy 5, no. 3 (August 1, 2021): 441–46. http://dx.doi.org/10.1093/ce/zkab025.

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Abstract Green hydrogen produced from wind, solar or hydro power is a suitable electricity storage medium. Hydrogen is typically employed as mid- to long-term energy storage, whereas batteries cover short-term energy storage. Green hydrogen can be produced by any available electrolyser technology [alkaline electrolysis cell (AEC), polymer electrolyte membrane (PEM), anion exchange membrane (AEM), solid oxide electrolysis cell (SOEC)] if the electrolysis is fed by renewable electricity. If the electrolysis operates under elevated pressure, the simplest way to store the gaseous hydrogen is to feed it directly into an ordinary pressure vessel without any external compression. The most efficient way to generate electricity from hydrogen is by utilizing a fuel cell. PEM fuel cells seem to be the most favourable way to do so. To increase the capacity factor of fuel cells and electrolysers, both functionalities can be integrated into one device by using the same stack. Within this article, different reversible technologies as well as their advantages and readiness levels are presented, and their potential limitations are also discussed.
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39

Gençer, Emre, Dharik S. Mallapragada, François Maréchal, Mohit Tawarmalani, and Rakesh Agrawal. "Round-the-clock power supply and a sustainable economy via synergistic integration of solar thermal power and hydrogen processes." Proceedings of the National Academy of Sciences 112, no. 52 (December 14, 2015): 15821–26. http://dx.doi.org/10.1073/pnas.1513488112.

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We introduce a paradigm—“hydricity”—that involves the coproduction of hydrogen and electricity from solar thermal energy and their judicious use to enable a sustainable economy. We identify and implement synergistic integrations while improving each of the two individual processes. When the proposed integrated process is operated in a standalone, solely power production mode, the resulting solar water power cycle can generate electricity with unprecedented efficiencies of 40–46%. Similarly, in standalone hydrogen mode, pressurized hydrogen is produced at efficiencies approaching ∼50%. In the coproduction mode, the coproduced hydrogen is stored for uninterrupted solar power production. When sunlight is unavailable, we envision that the stored hydrogen is used in a “turbine”-based hydrogen water power (H2WP) cycle with the calculated hydrogen-to-electricity efficiency of 65–70%, which is comparable to the fuel cell efficiencies. The H2WP cycle uses much of the same equipment as the solar water power cycle, reducing capital outlays. The overall sun-to-electricity efficiency of the hydricity process, averaged over a 24-h cycle, is shown to approach ∼35%, which is nearly the efficiency attained by using the best multijunction photovoltaic cells along with batteries. In comparison, our proposed process has the following advantages: (i) It stores energy thermochemically with a two- to threefold higher density, (ii) coproduced hydrogen has alternate uses in transportation/chemical/petrochemical industries, and (iii) unlike batteries, the stored energy does not discharge over time and the storage medium does not degrade with repeated uses.
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40

Alirahmi, Seyed Mojtaba, Ehsanolah Assareh, Ata Chitsaz, Shahriyar Ghazanfari Holagh, and Saeid Jalilinasrabady. "Electrolyzer-fuel cell combination for grid peak load management in a geothermal power plant: Power to hydrogen and hydrogen to power conversion." International Journal of Hydrogen Energy 46, no. 50 (July 2021): 25650–65. http://dx.doi.org/10.1016/j.ijhydene.2021.05.082.

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41

Hank, Hogan. "Clean Fuel from Nuclear Power." Mechanical Engineering 142, no. 07 (July 1, 2020): 40–45. http://dx.doi.org/10.1115/1.2020-jul3.

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Abstract The current commercial hydrogen production has a significant carbon footprint. Now, projects co-funded by the U.S. Department of Energy and commercial nuclear utilities with operating nuclear power facilities aim to change that by exploiting the capabilities of nuclear power plants. This article delves into four projects aimed at demonstrating technology to make hydrogen from water on an industrial scale using energy from an operating commercial nuclear power plant.
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42

SHIMIZU, SABURO. "Peak power supply and electrolytic hydrogen producing by nuclear power generation." Journal of the Atomic Energy Society of Japan / Atomic Energy Society of Japan 36, no. 4 (1994): 335–36. http://dx.doi.org/10.3327/jaesj.36.335.

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43

Nasri, Sihem, Ben Slama Sami, and Adnane Cherif. "Power management strategy for hybrid autonomous power system using hydrogen storage." International Journal of Hydrogen Energy 41, no. 2 (January 2016): 857–65. http://dx.doi.org/10.1016/j.ijhydene.2015.11.085.

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44

Jovan, David Jure, and Gregor Dolanc. "Can Green Hydrogen Production Be Economically Viable under Current Market Conditions." Energies 13, no. 24 (December 14, 2020): 6599. http://dx.doi.org/10.3390/en13246599.

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This paper discusses the potential of green hydrogen production in a case study of a Slovenian hydro power plant. To assess the feasibility and eligibility of hydrogen production at the power plant, we present an overview of current hydrogen prices and the costs of the power-to-gas system for green hydrogen production. After defining the production cost for hydrogen at the case study hydro power plant, we elaborate on the profitability of hydrogen production over electricity. As hydrogen can be used as a sustainable energy vector in industry, heating, mobility, and the electro energetic sectors, we discuss the current competitiveness of hydrogen in the heating and transport sectors. Considering the current prices of different fuels, it is shown that hydrogen can be competitive in the transport sector if it is unencumbered by various environmental taxes. The second part of the paper deals with hydrogen production in the context of secondary control ancillary service provided by a case study power plant. Namely, hydrogen can be produced during the time period when there is no demand for extra electric power within a secondary control ancillary service, and thus the economics of power plant operation can be improved.
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Yarullin, R. S., I. Z. Salikhov, D. S. Cherezov, and A. R. Nurislamova. "Prospects of hydrogen technologies in power and chemical industries." Power engineering: research, equipment, technology 23, no. 2 (May 21, 2021): 70–83. http://dx.doi.org/10.30724/1998-9903-2021-23-2-70-83.

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THE PURPOSE. Consider the use of hydrogen technologies in energy. The total production of hydrogen in Russia is about 5 million tons with a global consumption of 72 million tons. However, in the case of toughening of carbon regulation by importers of Russian products, the production of hydrogen in the Russian Federation may double. The roadmap «Development of hydrogen energy in Russia» stipulates that Gazprom and Rosatom will become the first hydrogen producers in the country - in 2024 they should launch pilot hydrogen plants, including at nuclear power plants. METHODS. To realize the potential in the country and achieve the goals laid down in the Energy Strategy, the departments have prepared a special action plan (roadmap) for the development of hydrogen energy in Russia until 2024, which was approved by Russian government on October 12, 2020. The main goal of this plan is called the organization of priority work on the formation in Russia of a high-performance export-oriented hydrogen energy, developing on the basis of modern technologies and provided with highly qualified personnel. RESULTS. Transportation and safe storage remains one of the key issues in hydrogen energy. The complexity of this problem is determined by the fact that in the free state hydrogen is one of thelow-boiling gases, in liquid and solid state more than an order of magnitude lighter than water and an order of magnitude lighter than gasoline. The molecules of the substance are so small that they can seep through the atomic structure of a metal container at temperatures above minus 253 ° C. Maintaining such a temperature in a large volume for a long time is energy-intensive. Another problem is hydrogen embrittlement and destruction of metals by atomic hydrogen. Even high-strength steels, as well as titanium and nickel alloys, are susceptible to it. CONCLUSION. The demand for hydrogen is growing due to the shift to the consumption of cleaner and lighter fuel oils, while the petroleum feedstock is getting heavier. But at the same time, the potential of natural gas has not yet been exhausted, which already now contributes to the low-carbon development of the economy. Skepticism about hydrogen technologies will disappear only when one of them gains relatively widespread use. At the same time, there is no doubt that hydrogen is very relevant for the creation of chemical current generators. This is of great importance for transport, and for distributed energy, and for a number of other areas.
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Langston, Lee S. "Hydrogen Fueled Gas Turbines." Mechanical Engineering 141, no. 03 (March 1, 2019): 52–54. http://dx.doi.org/10.1115/1.2019-mar-6.

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Hydrogen, reacting with oxygen, is a very energetic, non-polluting fuel. Can it be used as a fuel for gas turbines? Two successful and significant examples of its use are reviewed. Surplus renewable electrical energy from solar and wind could be used for electrolysis of water to produce hydrogen to power gas turbine power plants. Serving as a means of energy storage, the hydrogen could be kept in caverns. It could also be added directly to natural gas pipeline systems serving gas turbine power plants, thus reducing greenhouse gas production.
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Yamamoto, Seigoro. "Hydrogen Embrittlement of Nuclear Power Plant Materials." MATERIALS TRANSACTIONS 45, no. 8 (2004): 2647–49. http://dx.doi.org/10.2320/matertrans.45.2647.

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HAMA, Jun. "Trend of power use in hydrogen energy." Journal of the Japan Society for Precision Engineering 55, no. 11 (1989): 1970–74. http://dx.doi.org/10.2493/jjspe.55.1970.

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Karp, I. M. "HYDROGEN IN ELECTRIC AND TRANSPORT POWER ENGINEERING." Tekhnichna Elektrodynamika 2020, no. 1 (January 16, 2020): 64–70. http://dx.doi.org/10.15407/techned2020.01.064.

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Acar, Canan, Ibrahim Dincer, and Greg F. Naterer. "Clean hydrogen and power from impure water." Journal of Power Sources 331 (November 2016): 189–97. http://dx.doi.org/10.1016/j.jpowsour.2016.09.026.

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