Ключевые слова

2411-3336

2541-9404

Записки Горного института

Journal of Mining Institute

Санкт-Петербургский горный университет императрицы Екатерины ΙΙ

Empress Catherine II Saint Petersburg Mining University

SCSESI

pmi-15962

https://pmi.spmi.ru/pmi/article/view/15962

Геотехнология и инженерная геология

Geotechnical Engineering and Engineering Geology

Analysis of the assessment of the prospects for the burial of CO2 in unexplored aquifer complexes on the example of a facility in the Perm Region

Анализ оценки перспективности захоронения СО2 в неизученных водоносных комплексах на примере объекта Пермского края

Masoud

Riazi

Масуд

Риази

Masoud

Riazi

mriazi180@gmail.com

0000-0002-6843-621X

Назарбаев Университет (Астана, Казахстан) Nazarbayev University (Astana, Kazakhstan)

Ilyushin

Pavel Yu.

Илюшин

П. Ю.

Ilyushin

Pavel Yu.

ilushin-pavel@yandex.ru

0000-0003-4463-0883

Пермский национальный исследовательский политехнический университет (Пермь, Россия) Perm National Research Polytechnic University (Perm, Russia)

Baldina

Tatyana R.

Балдина

Т. Р.

Baldina

Tatyana R.

t.baldina@girngm.ru

0000-0001-8217-4167

ООО МИП «ПрогнозРНМ» (Пермь, Россия) LLC SIE “PrognozRNM” (Perm, Russia)

Sannikova

Nadezhda S.

Санникова

Н. С.

Sannikova

Nadezhda S.

n.sannikova@girngm.ru

0000-0003-0002-4187

Пермский национальный исследовательский политехнический университет (Пермь, Россия) National Research Polytechnic University (Perm, Russia)

Kozlov

Anton V.

Козлов

А. В.

Kozlov

Anton V.

anton.kozlov@girngm.ru

0000-0003-2350-2153

Пермский научно-образовательный центр мирового уровня «Рациональное недропользование» (Пермь, Россия) Perm World-class Scientific and Educational Center “Rational Subsoil Use” (Perm, Russia)

Ravelev

Kirill A.

Равелев

К. А.

Ravelev

Kirill A.

Kirill.Ravelev@pstu.ru

0000-0002-7402-2830

ГК «Газпром нефть» (Санкт-Петербург, Россия) Gazprom Neft Company Group (Saint Petersburg, Russia)

23 10 2024

2024

270 931 940 21 09 2022 03 06 2024 25 12 2024

2024

Риази Масуд, П. Ю. Илюшин, Т. Р. Балдина, Н. С. Санникова, А. В. Козлов, К. А. Равелев

Riazi Masoud, Pavel Yu. Ilyushin, Tatyana R. Baldina, Nadezhda S. Sannikova, Anton V. Kozlov, Kirill A. Ravelev

Эта статья доступна по лицензии Creative Commons Attribution 4.0 International (CC BY 4.0)

This article is licensed under a Creative Commons Attribution 4.0 International License (CC BY 4.0)

https://pmi.spmi.ru/pmi/article/view/15962

Одной из важнейших проблем современности является ежегодный рост объемов эмиссии парниковых газов в атмосферу. Бороться с этим явлением можно при помощи сокращения выбросов или разработки и применения технологий улавливания, хранения, использования и утилизации СО2. В данной работе рассматривается оценка целесообразности и возможности захоронения углекислого газа в глубоких водоносных горизонтах, изучение которых осуществляется в малой степени из-за отсутствия в них полезного ископаемого. Исследованы параметры и результаты закачки СО2 в водоносный горизонт одного из нефтяных месторождений Пермского края, геологические свойства и характеристики которого определены в данной работе. Рассматриваются критерии применимости, способы оценки объема коллектора и лабораторные исследования по определению свойств СО2 и особенностей его взаимодействия с моделью пластового флюида. Определен объект закачки, объем коллектора, выполнены PVT-исследования целевого газа, определена его растворимость в пластовой воде. Рассчитана продолжительность заполнения полного объема ловушки при улавливании с целевого промышленного объекта 400 тыс. т СО2 в год – 202 года. Такое заключение сигнализирует о перспективности захоронения углекислого газа в подземных отложениях неразрабатываемого водоносного комплекса на территории Пермского края, что отражает важность изучения таких геологических объектов захоронения СО2 для достижения мировых целей по углеродной нейтральности.

One of the most important problems of our time is the annual increase in greenhouse gas emissions into the atmosphere. It is possible to combat this phenomenon by reducing emissions or developing and applying technologies for capturing, storing, using and disposing of CO2. In this work, an assessment of the expediency and possibility of carbon dioxide burial in deep aquifers is considered, the study of which is carried out to a small extent and due to the lack of useful material in them. The parameters and results of CO2 injection into the aquifer of one of the oil fields of the Perm Region, the geological properties and characteristics of which are determined in this work, are studied. The criteria of applicability, methods of estimating the volume of the reservoir and laboratory studies to determine the properties of CO2 and the features of its interaction with the model of the reservoir fluid are considered. The injection object and reservoir volume were determined, PVT studies of the target gas were performed, and its solubility in reservoir water was determined. The duration of filling the full volume of the trap when capturing 400 thousand tons of CO2 per year from the target industrial facility is calculated to be 202 years. This conclusion signals the prospects for the burial of carbon dioxide in the underground deposits of an undeveloped aquifer complex in the Perm Region, which reflects the importance of studying such geological CO2 burial sites in order to achieve global carbon neutrality goals.

Ключевые слова углекислый газ водоносный горизонт захоронение лабораторные исследования углеродный след

Keywords carbon dioxide aquifer burial laboratory studies carbon footprint

Исследование выполнено при финансовой поддержке Программы стратегического академического лидерства «Приоритет-2030».

The research was carried out with the financial support of the Strategic Academic Leadership Program “Priority 2030”.

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