Mechanism and numerical simulation of pressure stagnation during water jetting perforation

When perforating with an abrasive water jet, it is possible that the pressure in the hole (perforation) will be higher than that in the annulus because of water jet blasting against the hole wall, which also is the theoretical basis for the technology of hydro-jet fracturing. This paper analyzes the...

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Bibliographic Details
Published in:Petroleum science 2008-02, Vol.5 (1), p.52-55
Main Authors: Huang, Zhongwei, Li, Gensheng, Tian, Shouceng, Shen, Zhonghou, Luo, Hongbin
Format: Article
Language:English
Subjects:
Annuli
Blasting
Computer simulation
Earth and Environmental Science
Earth Sciences
Economics and Management
Energy Policy
Finite element method
Hydraulic jets
Industrial and Production Engineering
Industrial Chemistry/Chemical Engineering
Mineral Resources
Perforation
Pressure
Simulation
Stagnation
射流穿孔
数值模拟
水压临界点
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Summary:When perforating with an abrasive water jet, it is possible that the pressure in the hole (perforation) will be higher than that in the annulus because of water jet blasting against the hole wall, which also is the theoretical basis for the technology of hydro-jet fracturing. This paper analyzes the mechanism of generating pressure stagnation in water jet hole, and puts forward a new concept of hydroseal. Then, the distribution of pressure in the hole was simulated with the finite element method. The simulation results showed that the pressure in the hole was higher than that in the annulus. Also, the lower the annular pressure (confining pressure) and the higher the blasting pressure, the greater the pressure difference. An experiment indicated that the cement sample was lifted up under the pressure stagnation in the hole, which proved the finite element simulation results obviously.
ISSN:1672-5107
1995-8226
DOI:10.1007/s12182-008-0008-2