Abstract
Hydrogen can be generated in situ within reservoirs containing hydrocarbons through chemical reactions. This technology could be a possible solution for low-emission hydrogen production due to of simultaneous CO2 storage. In gas fields, it is possible to carry out the catalytic methane conversion (CMC) if sufficient amounts of steam, catalyst, and heat are ensured in the reservoir. There is no confirmation of the CMC’s feasibility at relatively low temperatures in the presence of core (reservoir rock) material. This study introduces the experimental results of the first part of the research on in situ hydrogen generation in the Promyslovskoye gas field. A set of static experiments in the autoclave reactor were performed to study the possibility of hydrogen generation under reservoir conditions. It was shown that CMC can be realized in the presence of core and ex situ prepared Ni-based catalyst, under high pressure up to 207 atm, but at temperatures not lower than 450 °C. It can be concluded that the crushed core model improves the catalytic effect but releases carbon dioxide and light hydrocarbons, which interfere with the hydrogen generation. The maximum methane conversion rate to hydrogen achieved at 450 °C is 5.8%.
Highlights
The growing demand for clean energy resources stimulates the development of unconventional and alternative energy
Hydrogen can be obtained from natural gas through catalytic steam methane reforming (SMR), partial oxidation, autothermal reforming, and methane cracking
This thermodynamic model is a simplification of the catalytic methane conversion (CMC) process, which does not describe the system correctly at high temperatures
Summary
The growing demand for clean energy resources stimulates the development of unconventional and alternative energy. Renewable energy is a promising and developing field, but hydrogen has a number of benefits as an energy source. According to the world’s long-term programs for developing hydrogen technologies, hydrogen can ensure 12% of the world’s total primary energy demand in 2050 [1]. There is no cheap way for sustainable hydrogen production without greenhouse gas emissions. Hydrogen can be obtained from natural gas through catalytic steam methane reforming (SMR), partial oxidation, autothermal reforming, and methane cracking. It can be produced from water through electrolysis of water or from coal through coal gasification [2]
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