Experimental Investigation of Permeability Evolution on Sandstone in Triaxial and Long-Term Dissolution Experiment

Experimental Investigation of Permeability Evolution on Sandstone in Triaxial and Long-Term Dissolution Experiment

The temporal permeability and damage evolutions of low-permeability sandstone cores during triaxial and long-term dissolution experiments were measured using a triaxial-flow system. Three triaxial experiments were performed on sandstone cores having initial permeability ranging from 78×10−18 m2 to 1...

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Main Authors: Ji Shi, Jianhua Zhang, Chunyang Zhang, Tingting Jiang, Gang Huang
Format: Article
Language:English
Published: Hindawi-Wiley 2021-01-01
Series:Geofluids
Online Access:http://dx.doi.org/10.1155/2021/5580185
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spelling doaj-51f7b7e798fc414e86606fccfcb078192021-03-08T02:00:40ZengHindawi-WileyGeofluids1468-81232021-01-01202110.1155/2021/5580185Experimental Investigation of Permeability Evolution on Sandstone in Triaxial and Long-Term Dissolution ExperimentJi Shi0Jianhua Zhang1Chunyang Zhang2Tingting Jiang3Gang Huang4Mining engineeringMining engineeringMining engineeringMining engineeringMining engineeringThe temporal permeability and damage evolutions of low-permeability sandstone cores during triaxial and long-term dissolution experiments were measured using a triaxial-flow system. Three triaxial experiments were performed on sandstone cores having initial permeability ranging from 78×10−18 m2 to 120×10−18 m2. Two sets of long-term dissolution experiments were conducted on cracked sandstone cores. All dissolution experiments were performed at room temperature and using a 10 g/L H2SO4 and 0.2 g/L H2O2 input solution. Permeability evolution was determined using Darcy’s law. The cores experienced an average increase of 25% in permeability in the dissolution experiment and 900%~1500% increase at the end of the experiment. The dissolution was fairly homogeneous during the long-term experiments whether on the 1 mm scale or the 10 μm scale. The relationship between damage and permeability was speculated and its correlation coefficient has been proved to be close to 1. These results suggest that hydraulic fracturing works well in permeability increase in low-permeability sandstone reservoir.http://dx.doi.org/10.1155/2021/5580185
collection DOAJ
language English
format Article
sources DOAJ
author Ji Shi
Jianhua Zhang
Chunyang Zhang
Tingting Jiang
Gang Huang
spellingShingle Ji Shi
Jianhua Zhang
Chunyang Zhang
Tingting Jiang
Gang Huang
Experimental Investigation of Permeability Evolution on Sandstone in Triaxial and Long-Term Dissolution Experiment
Geofluids
author_facet Ji Shi
Jianhua Zhang
Chunyang Zhang
Tingting Jiang
Gang Huang
author_sort Ji Shi
title Experimental Investigation of Permeability Evolution on Sandstone in Triaxial and Long-Term Dissolution Experiment
title_short Experimental Investigation of Permeability Evolution on Sandstone in Triaxial and Long-Term Dissolution Experiment
title_full Experimental Investigation of Permeability Evolution on Sandstone in Triaxial and Long-Term Dissolution Experiment
title_fullStr Experimental Investigation of Permeability Evolution on Sandstone in Triaxial and Long-Term Dissolution Experiment
title_full_unstemmed Experimental Investigation of Permeability Evolution on Sandstone in Triaxial and Long-Term Dissolution Experiment
title_sort experimental investigation of permeability evolution on sandstone in triaxial and long-term dissolution experiment
publisher Hindawi-Wiley
series Geofluids
issn 1468-8123
publishDate 2021-01-01
description The temporal permeability and damage evolutions of low-permeability sandstone cores during triaxial and long-term dissolution experiments were measured using a triaxial-flow system. Three triaxial experiments were performed on sandstone cores having initial permeability ranging from 78×10−18 m2 to 120×10−18 m2. Two sets of long-term dissolution experiments were conducted on cracked sandstone cores. All dissolution experiments were performed at room temperature and using a 10 g/L H2SO4 and 0.2 g/L H2O2 input solution. Permeability evolution was determined using Darcy’s law. The cores experienced an average increase of 25% in permeability in the dissolution experiment and 900%~1500% increase at the end of the experiment. The dissolution was fairly homogeneous during the long-term experiments whether on the 1 mm scale or the 10 μm scale. The relationship between damage and permeability was speculated and its correlation coefficient has been proved to be close to 1. These results suggest that hydraulic fracturing works well in permeability increase in low-permeability sandstone reservoir.
url http://dx.doi.org/10.1155/2021/5580185
work_keys_str_mv AT jishi experimentalinvestigationofpermeabilityevolutiononsandstoneintriaxialandlongtermdissolutionexperiment
AT jianhuazhang experimentalinvestigationofpermeabilityevolutiononsandstoneintriaxialandlongtermdissolutionexperiment
AT chunyangzhang experimentalinvestigationofpermeabilityevolutiononsandstoneintriaxialandlongtermdissolutionexperiment
AT tingtingjiang experimentalinvestigationofpermeabilityevolutiononsandstoneintriaxialandlongtermdissolutionexperiment
AT ganghuang experimentalinvestigationofpermeabilityevolutiononsandstoneintriaxialandlongtermdissolutionexperiment
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