Details
| Original language | English |
|---|---|
| Article number | 213774 |
| Journal | Geoenergy Science and Engineering |
| Volume | 249 |
| Early online date | 17 Feb 2025 |
| Publication status | Published - Jun 2025 |
Abstract
Natural gas hydrates hold great promise as an environmentally friendly energy resource, yet the trial production capacity remains an order of magnitude below the threshold for commercial development. Scholars have verified the effectiveness and viability of applying hydraulic fracturing stimulation technology to hydrate reservoirs through laboratory experiments and numerical simulations. However, the unique low-temperature and high-pressure environment of hydrates complicates the initiation and propagation characteristics of hydraulic fractures in unconsolidated argillaceous sediments. Building on previous researches, we conducted true triaxial fracturing experiments using hydrate-bearing sediments (HBS) substitute in both vertical and radial wells. The results indicate that radial well fracturing provides enhanced stimulation effects compared to vertical well fracturing, increasing the stimulated volume and fracture complexity by 27% and 5%, respectively. Due to the weak physical properties of the hydrate reservoir, drilling multiple radial wells in the same horizontal layer causes reservoir degradation to form weak bedding planes, inducing fractures to initiate and propagate in the horizontal direction. Employing high injection rates and low-viscosity fracturing fluids can boost fracture complexity by approximately 10%, facilitating proppant placement and transport and thereby maintaining the efficient, long-term, and safe development of hydrates. Our study offers insights and theoretical frameworks to facilitate the implementation of hydraulic fracturing techniques in the exploitation of hydrate reservoirs.
Keywords
- Fracture propagation, Hydraulic fracturing, Natural gas hydrate reservoir, Radial well, Stimulation effect
ASJC Scopus subject areas
- Energy(all)
- Renewable Energy, Sustainability and the Environment
- Energy(all)
- Energy Engineering and Power Technology
- Energy(all)
- Energy (miscellaneous)
- Earth and Planetary Sciences(all)
- Geotechnical Engineering and Engineering Geology
Sustainable Development Goals
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In: Geoenergy Science and Engineering, Vol. 249, 213774, 06.2025.
Research output: Contribution to journal › Article › Research › peer review
}
TY - JOUR
T1 - Experimental research on fracture initiation and propagation behavior in argillaceous silt hydrate reservoirs
AU - Hui, Chengyu
AU - Zhang, Yiqun
AU - An, Youkeren
AU - Hu, Zhaowen
AU - Zhuang, Xiaoying
AU - Wang, Jinshan
AU - Qin, Yu
AU - Li, Gensheng
N1 - Publisher Copyright: © 2025 Elsevier B.V.
PY - 2025/6
Y1 - 2025/6
N2 - Natural gas hydrates hold great promise as an environmentally friendly energy resource, yet the trial production capacity remains an order of magnitude below the threshold for commercial development. Scholars have verified the effectiveness and viability of applying hydraulic fracturing stimulation technology to hydrate reservoirs through laboratory experiments and numerical simulations. However, the unique low-temperature and high-pressure environment of hydrates complicates the initiation and propagation characteristics of hydraulic fractures in unconsolidated argillaceous sediments. Building on previous researches, we conducted true triaxial fracturing experiments using hydrate-bearing sediments (HBS) substitute in both vertical and radial wells. The results indicate that radial well fracturing provides enhanced stimulation effects compared to vertical well fracturing, increasing the stimulated volume and fracture complexity by 27% and 5%, respectively. Due to the weak physical properties of the hydrate reservoir, drilling multiple radial wells in the same horizontal layer causes reservoir degradation to form weak bedding planes, inducing fractures to initiate and propagate in the horizontal direction. Employing high injection rates and low-viscosity fracturing fluids can boost fracture complexity by approximately 10%, facilitating proppant placement and transport and thereby maintaining the efficient, long-term, and safe development of hydrates. Our study offers insights and theoretical frameworks to facilitate the implementation of hydraulic fracturing techniques in the exploitation of hydrate reservoirs.
AB - Natural gas hydrates hold great promise as an environmentally friendly energy resource, yet the trial production capacity remains an order of magnitude below the threshold for commercial development. Scholars have verified the effectiveness and viability of applying hydraulic fracturing stimulation technology to hydrate reservoirs through laboratory experiments and numerical simulations. However, the unique low-temperature and high-pressure environment of hydrates complicates the initiation and propagation characteristics of hydraulic fractures in unconsolidated argillaceous sediments. Building on previous researches, we conducted true triaxial fracturing experiments using hydrate-bearing sediments (HBS) substitute in both vertical and radial wells. The results indicate that radial well fracturing provides enhanced stimulation effects compared to vertical well fracturing, increasing the stimulated volume and fracture complexity by 27% and 5%, respectively. Due to the weak physical properties of the hydrate reservoir, drilling multiple radial wells in the same horizontal layer causes reservoir degradation to form weak bedding planes, inducing fractures to initiate and propagate in the horizontal direction. Employing high injection rates and low-viscosity fracturing fluids can boost fracture complexity by approximately 10%, facilitating proppant placement and transport and thereby maintaining the efficient, long-term, and safe development of hydrates. Our study offers insights and theoretical frameworks to facilitate the implementation of hydraulic fracturing techniques in the exploitation of hydrate reservoirs.
KW - Fracture propagation
KW - Hydraulic fracturing
KW - Natural gas hydrate reservoir
KW - Radial well
KW - Stimulation effect
UR - http://www.scopus.com/inward/record.url?scp=85217939731&partnerID=8YFLogxK
U2 - 10.1016/j.geoen.2025.213774
DO - 10.1016/j.geoen.2025.213774
M3 - Article
AN - SCOPUS:85217939731
VL - 249
JO - Geoenergy Science and Engineering
JF - Geoenergy Science and Engineering
M1 - 213774
ER -