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Publications in Math-Net.Ru |
Citations |
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2024 |
| 1. |
Термодинамический цикл твердо-оксидного топливного элемента с внутренней конверсией метана в приближении полного преобразования в однонаправленных реакциях
TVT, Forthcoming paper |
| 2. |
V. A. Bityurin, A. N. Bocharov, A. S. Dobrovol'skaya, P. P. Ivanov, T. N. Kuznetsova, E. A. Filimonova, “Анализ механизмов воспламенения стехиометрической топливно-воздушной смеси”, TVT, 62:3 (2024), 414–424  |
| 3. |
A. Z. Zhuk, P. P. Ivanov, “Термодинамическая оптимизация гибридной схемы энергетической установки с твердооксидным топливным элементом с внутренней конверсией метана и c газовой турбиной”, TVT, 62:2 (2024), 307–312 |
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2023 |
| 4. |
A. Z. Zhuk, P. P. Ivanov, “Характеристики твердооксидного топливного элемента для термодинамического моделирования энергетических установок”, TVT, 61:5 (2023), 777–782 |
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| 5. |
A. Z. Zhuk, P. P. Ivanov, “Simulation of the metal hydride utilization cycle in a fuel cell with a high-temperature proton exchange membrane”, TVT, 61:1 (2023), 140–144 ; High Temperature, 61:1 (2023), 129–133 |
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2022 |
| 6. |
P. P. Ivanov, “Thermodynamic and physical simulation of a high-temperature proton-exchange membrane fuel cell”, TVT, 60:6 (2022), 933–937  ; High Temperature, 60:6 (2022), 865–869 |
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| 7. |
A. Z. Zhuk, V. I. Borsenko, P. P. Ivanov, “Hydrothermal oxidation of aluminum and metal hydride compression of hydrogen”, TVT, 60:5 (2022), 781–788 ; High Temperature, 60:5 (2022), 716–722 |
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2021 |
| 8. |
E. I. Shkol'nikov, P. P. Ivanov, “Substantiation of technology for the growth of monocrystalline leucosapphire from technically pure corundum”, TVT, 59:2 (2021), 242–247 ; High Temperature, 59:2 (2021), 216–220   |
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2020 |
| 9. |
A. Z. Zhuk, P. P. Ivanov, E. A. Kiseleva, “Modeling of the electrochemical transformation of chemical energy of biofuel to electricity”, TVT, 58:2 (2020), 300–305 ; High Temperature, 58:2 (2020), 292–296 |
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| 10. |
E. I. Shkol'nikov, P. P. Ivanov, “Intensification of the removal of iron impurities from microporous aluminum oxide via argon blowing”, TVT, 58:1 (2020), 123–127 ; High Temperature, 58:1 (2020), 121–125 |
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2019 |
| 11. |
A. Z. Zhuk, P. P. Ivanov, “Modeling of the evaporation of iron impurities from microporous aluminum oxide into vacuum”, TVT, 57:5 (2019), 786–789 ; High Temperature, 57:5 (2019), 761–764 |
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| 12. |
V. B. Alekseev, V. I. Zalkind, P. P. Ivanov, V. L. Nizovskiy, S. S. Schigel, “Peculiarities of thermophysical processes of “wet compression” in power units with highly atomized water injection and their influence on power units operation”, High Temperature, 57:4 (2019), 547–554 |
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2017 |
| 13. |
V. M. Batenin, P. P. Ivanov, V. I. Kovbasyuk, “Improvement of thermodynamic efficiency of the humid biofuel application in the distributed generation power suppliers”, TVT, 55:1 (2017), 76–80 ; High Temperature, 55:1 (2017), 70–74 |
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2016 |
| 14. |
P. P. Ivanov, “An ultrafast electric vehicle charging station as an object of decentralized power engineering”, TVT, 54:1 (2016), 114–119 ; High Temperature, 54:1 (2016), 117–122 |
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2014 |
| 15. |
P. P. Ivanov, “Certain Features of the Calculation of a Two-Phase Flow in the Droplet Regime”, TVT, 52:2 (2014), 326–329 ; High Temperature, 52:2 (2014), 312–314 |
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2013 |
| 16. |
P. P. Ivanov, “Thermodynamic efficiency of water use in a gas turbine cycle”, TVT, 51:4 (2013), 592–597 ; High Temperature, 51:4 (2013), 532–536 |
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2012 |
| 17. |
P. P. Ivanov, V. I. Kovbasyuk, Yu. V. Medvedev, “On the calculated optimization of a gasifier”, TVT, 50:6 (2012), 835–840 ; High Temperature, 50:6 (2012), 779–784 |
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2011 |
| 18. |
P. P. Ivanov, “Thermodynamic Modeling of Power Plants Based on Solid Oxide Fuel Cells”, TVT, 49:4 (2011), 627–633 ; High Temperature, 49:4 (2011), 608–614 |
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1983 |
| 19. |
V. M. Batenin, V. A. Bityurin, V. A. Zhelnin, P. P. Ivanov, S. A. Medin, G. A. Lyubimov, V. R. Satanovskii, V. L. Turovets, “Gas-dynamic and electrical characteristics of MHD generator according to data from physical and numerical experiments – RM channel of the U-25 device”, TVT, 21:3 (1983), 567–576 ; High Temperature, 21:3 (1983), 438–447 |
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1982 |
| 20. |
V. A. Bityurin, P. P. Ivanov, G. M. Koryagina, G. A. Lyubimov, S. A. Medin, G. N. Morozov, A. S. Prokop, “Numerical-simulation of the operation of a MHD generator in transient regimes in MHD power-stations”, TVT, 20:2 (1982), 347–358 ; High Temperature, 20:2 (1982), 306–316 |
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1975 |
| 21. |
B. Ya. Shumyatskii, V. I. Kovbasyuk, G. M. Koryagina, P. P. Ivanov, “Исследование оптимальных характеристик МГД-генератора для комбинированных МГДЭС открытого цикла”, TVT, 13:2 (1975), 407–412 |
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1972 |
| 22. |
P. P. Ivanov, V. I. Kovbasyuk, G. M. Koryagina, A. P. Rogachev, “К выбору параметров пиковой МГД-установки”, TVT, 10:5 (1972), 1097–1101 |
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1967 |
| 23. |
V. A. Bityurin, P. P. Ivanov, “К определению времени установления неравновесного состояния на входе в канал МГД-генератора”, TVT, 5:3 (1967), 418–422 |
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1965 |
| 24. |
P. P. Ivanov, V. I. Kovbasyuk, V. A. Stepanov, “Некоторые особенности работы МГД-генератора при больших числах Холла”, TVT, 3:6 (1965), 845–850 |
| 25. |
P. P. Ivanov, V. I. Kovbasyuk, “К вопросу оптимизации течения неравновесной плазмы в канале МГД-генератора”, TVT, 3:4 (1965), 562–568 |
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