References

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Альтернативная энергетика и экология (ISJAEE)

Alternative Energy and Ecology (ISJAEE)

1608-8298

Международный издательский дом научной периодики "Спейс

10.15518/isjaee.2024.01.087-101

alternative-2369

Research Article

II. НЕВОЗОБНОВЛЯЕМАЯ ЭНЕРГЕТИКА 9. Атомная энергетика

Метано-водородный переход к водородной экономике

Methane-hydrogen transition to hydrogen economy

Столяревский

А. Я.

Stolyarevsky

A. Ya.

Анатолий Яковлевич Столяревский - директор Центра,

г. Москва, ул. Максимова, 4, 123182

Anatoliy Yakovlevich Stolyarevsky - Director,

Moscow, st. Maksimova, 4, 123182

anatoly.stolyarevsky@ccortes.ru

Центр комплексного развития технологий и энерготехнологических систем (Центр КОРТЭС)РоссияCenter for Integrated Development of Technologies and Energy Technology Systems (CORTES Center)Russian Federation

2024

16052024

0187101

2023

Международный издательский дом научной периодики "Спейс

https://www.isjaee.com/jour/about/submissions#copyrightNotice

https://www.isjaee.com/jour/article/view/2369

Природный газ – один из ключевых энергоносителей в мировой энергетике XXI века, роль которого с каждым годом возрастает, благодаря его эксплуатационным характеристикам. В будущем водородное топливо должно заменить природный газ. Водород – самое эффективное и экологически чистое топливо. В России разработана технология адиабатической конверсии метана (АКМ), позволяющая получать метано-водородное топливо (МВС) с содержанием водорода до 50 %. Эта технология существенно упрощает промышленный процесс получения водорода, поскольку он не требует получения кислорода и происходит при более низких температурах (до 680 °С).

Natural gas is one of the key energy carriers in the global energy sector of the XXI century, the role of which is increasing every year due to its operational characteristics. In the future, hydrogen fuel should replace natural gas. Hydrogen is the most efficient and environmentally friendly fuel. In Russia, the technology of adiabatic methane conversion (ACM) has been developed, producing methane-hydrogen fuel (MHM) with a hydrogen content of up to 50 %. This technology significantly simplifies the industrial process of producing hydrogen, since it does not require oxygen production and occurs at lower temperatures (up to 680°C).

энергетикаводородальтернативная энергетикаэкологияэнергоэффективностьприродный газконверсия метанаудаление СО2

energyhydrogenalternative energyecologyenergy efficiencynatural gasmethane conversionCO2 removal

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The authors declare that there are no conflicts of interest present.