Research on Initiation of Carbon Dioxide Fracturing Pipe Using the Liquid Carbon Dioxide Phase-Transition Blasting Technology

Research on Initiation of Carbon Dioxide Fracturing Pipe Using the Liquid Carbon Dioxide Phase-Transition Blasting Technology

Liquid carbon dioxide (L-CO<sub>2</sub>) phase-transition blasting technology (LCPTB) has caused wide concern in many fields, but there is a lack of research on the initiation of the carbon dioxide fracturing pipe. Studies regarding the carbon dioxide fracturing pipe initiation are criti...

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Main Authors: Jieqin Xia, Bin Dou, Hong Tian, Jun Zheng, Guodong Cui, Muhammad Kashif
Format: Article
Language:English
Published: MDPI AG 2021-01-01
Series:Energies
Subjects:
liquid carbon dioxide
fracturing pipe
initiation
empirical model
failure mode
Online Access:https://www.mdpi.com/1996-1073/14/3/521
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spelling doaj-995f0ee27bc94bf2acf73d8c90bfeb932021-01-21T00:00:48ZengMDPI AGEnergies1996-10732021-01-011452152110.3390/en14030521Research on Initiation of Carbon Dioxide Fracturing Pipe Using the Liquid Carbon Dioxide Phase-Transition Blasting TechnologyJieqin Xia0Bin Dou1Hong Tian2Jun Zheng3Guodong Cui4Muhammad Kashif5Faculty of Engineering, China University of Geosciences, Wuhan 430074, ChinaFaculty of Engineering, China University of Geosciences, Wuhan 430074, ChinaFaculty of Engineering, China University of Geosciences, Wuhan 430074, ChinaFaculty of Engineering, China University of Geosciences, Wuhan 430074, ChinaFaculty of Engineering, China University of Geosciences, Wuhan 430074, ChinaDepartment of Earth Sciences, University of Sargodha, Sargodha 40100, PakistanLiquid carbon dioxide (L-CO<sub>2</sub>) phase-transition blasting technology (LCPTB) has caused wide concern in many fields, but there is a lack of research on the initiation of the carbon dioxide fracturing pipe. Studies regarding the carbon dioxide fracturing pipe initiation are critical for controlling and optimizing the LCPTB. Therefore, in this article, a series of exploratory experiments of carbon dioxide blasting were carried out to investigate the qualitative and quantitative relationships between the carbon dioxide fracturing pipe initiation and the three key variables (the filling mass of liquid carbon dioxide (L-CO<sub>2</sub>) (<i>X</i><sub>1</sub>), the amount of chemical heating material (<i>X</i><sub>2</sub>) and the thickness of the constant-stress shear plate (<i>X</i><sub>3</sub>)). The failure mechanisms of three variables on the phase-transition blasting process of a carbon dioxide fracturing pipe was analyzed qualitatively based on experiment temperature, strain curve and failure form of constant-stress shear plate. An empirical model between the carbon dioxide fracturing pipe initiation (<i>Y</i>) and the three key variables (<i>X</i><sub>1</sub>, <i>X</i><sub>2</sub>, <i>X</i><sub>3</sub>) was obtained after processing experiment result data quantitatively. Based on the phase-transition and blasting process of carbon dioxide, two methods, the Viral–Han–Long (VHL) equation of gas state (EOS) and the strength-failure method were used to calculate the blasting pressure and determine the failure mode of the fracturing pipe. The proposed blasting empirical model can be used to optimize the structural design of carbon dioxide fracturing pipes, guide on-site carbon dioxide blasting operations and further achieve the best blasting effect of LCPTB, so this work can enable LCPTB to be better applied to practical projects.https://www.mdpi.com/1996-1073/14/3/521liquid carbon dioxidefracturing pipeinitiationempirical modelfailure mode
collection DOAJ
language English
format Article
sources DOAJ
author Jieqin Xia
Bin Dou
Hong Tian
Jun Zheng
Guodong Cui
Muhammad Kashif
spellingShingle Jieqin Xia
Bin Dou
Hong Tian
Jun Zheng
Guodong Cui
Muhammad Kashif
Research on Initiation of Carbon Dioxide Fracturing Pipe Using the Liquid Carbon Dioxide Phase-Transition Blasting Technology
Energies
liquid carbon dioxide
fracturing pipe
initiation
empirical model
failure mode
author_facet Jieqin Xia
Bin Dou
Hong Tian
Jun Zheng
Guodong Cui
Muhammad Kashif
author_sort Jieqin Xia
title Research on Initiation of Carbon Dioxide Fracturing Pipe Using the Liquid Carbon Dioxide Phase-Transition Blasting Technology
title_short Research on Initiation of Carbon Dioxide Fracturing Pipe Using the Liquid Carbon Dioxide Phase-Transition Blasting Technology
title_full Research on Initiation of Carbon Dioxide Fracturing Pipe Using the Liquid Carbon Dioxide Phase-Transition Blasting Technology
title_fullStr Research on Initiation of Carbon Dioxide Fracturing Pipe Using the Liquid Carbon Dioxide Phase-Transition Blasting Technology
title_full_unstemmed Research on Initiation of Carbon Dioxide Fracturing Pipe Using the Liquid Carbon Dioxide Phase-Transition Blasting Technology
title_sort research on initiation of carbon dioxide fracturing pipe using the liquid carbon dioxide phase-transition blasting technology
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2021-01-01
description Liquid carbon dioxide (L-CO<sub>2</sub>) phase-transition blasting technology (LCPTB) has caused wide concern in many fields, but there is a lack of research on the initiation of the carbon dioxide fracturing pipe. Studies regarding the carbon dioxide fracturing pipe initiation are critical for controlling and optimizing the LCPTB. Therefore, in this article, a series of exploratory experiments of carbon dioxide blasting were carried out to investigate the qualitative and quantitative relationships between the carbon dioxide fracturing pipe initiation and the three key variables (the filling mass of liquid carbon dioxide (L-CO<sub>2</sub>) (<i>X</i><sub>1</sub>), the amount of chemical heating material (<i>X</i><sub>2</sub>) and the thickness of the constant-stress shear plate (<i>X</i><sub>3</sub>)). The failure mechanisms of three variables on the phase-transition blasting process of a carbon dioxide fracturing pipe was analyzed qualitatively based on experiment temperature, strain curve and failure form of constant-stress shear plate. An empirical model between the carbon dioxide fracturing pipe initiation (<i>Y</i>) and the three key variables (<i>X</i><sub>1</sub>, <i>X</i><sub>2</sub>, <i>X</i><sub>3</sub>) was obtained after processing experiment result data quantitatively. Based on the phase-transition and blasting process of carbon dioxide, two methods, the Viral–Han–Long (VHL) equation of gas state (EOS) and the strength-failure method were used to calculate the blasting pressure and determine the failure mode of the fracturing pipe. The proposed blasting empirical model can be used to optimize the structural design of carbon dioxide fracturing pipes, guide on-site carbon dioxide blasting operations and further achieve the best blasting effect of LCPTB, so this work can enable LCPTB to be better applied to practical projects.
topic liquid carbon dioxide
fracturing pipe
initiation
empirical model
failure mode
url https://www.mdpi.com/1996-1073/14/3/521
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