Influence of Grain Size Heterogeneity and In-Situ Stress on the Hydraulic Fracturing Process by PFC2D Modeling

Abstract We are conducting a U.S. DOE-funded research program aimed at understanding the hydraulic fracturing process, especially those phenomena and parameters that strongly affect or control fracture geometry. Our theoretical and experimental studies consistently confirm the well-known fact that in-situ stress has a primary effect on fracture geometry, and that fractures propagate perpendicular to the least principal stress. In addition, we find that frictional interfaces in reservoirs can affect fracturing. We also have quantified some effects on fracture geometry caused by frictional slippage along interfaces. We found that variation of friction along an interface can result in abrupt steps in the fracture path. These effects have been seen in the mineback of emplaced fractures and are demonstrated both theoretically and in the laboratory. Further experiments and calculations indicate possible control of fracture height by vertical change in horizontal stresses. Preliminary results from an analysis of fluid flow in small apertures are discussed also. Introduction Hydraulic fracturing and massive hydraulic fracturing (MHF) are the primary candidates for stimulating production from tight gas reservoirs. MHF can provide large drainage surfaces to produce gas from the low- permeability formation if the fracture surfaces remain in the productive parts of the reservoir. To determine whether it is possibleto contain these fractures in the productive formations andto design the treatment to accomplish this requires a much broader knowledge of the hydraulic fracturing process. Identification of the parameters controlling fracture geometry and the application of this information in designing and performing the hydraulic stimulation treatment is a principal technical problem. Additionally, current measurement technology may not be adequate to provide the required data. and new techniques may have to be devised. Lawrence Livermore Natl. Laboratory has been conducting a DOE-funded research program whose ultimate goal is to develop models that predict created hydraulic fracture geometry within the reservoir. Our approach has been to analyze the phenomenology of the fracturing process to son out and identify those parameters influencing hydraulic fracture geometry. Subsequent model development will incorporate this information. Current theoretical and stimulation design models are based primarily on conservation of mass and provide little insight into the fracturing process. Fracture geometry is implied in the application of these models. Additionally, pressure and flow initiation in the fractures and their interjection with the fracturing process is not predicted adequately with these models. We have reported previously on some rock-mechanics aspects of the fracturing process. For example, we have studied, theoretically and experimentally, pressurized fracture propagation in the neighborhood of material interfaces. Results of interface studies showed that natural fractures in the interfacial region negate any barrier effect when the fracture is propagating from a lower modulus material toward a higher modulus material. On the other hand, some fracture containment could occur when the fracture is propagating from a higher modulus into a lower modulus material. Effect of moduli changes on the in-situ stress field have to be taken into consideration to evaluate fracture containment by material interfaces. Some preliminary analyses have been performed to evaluate how stress changes when material properties change, but we have not evaluated this problem fully. SPEJ P. 321^

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Hydraulic Fracturing Process: Roles of In Situ Stress and Rock Strength

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.616-618.435 ◽

2012 ◽

Vol 616-618 ◽

pp. 435-440

Author(s):

Yan Jun Feng ◽

Xiu Wei Shi

Keyword(s):

Hydraulic Fracturing ◽

Analytical Model ◽

Field Experiments ◽

Rock Strength ◽

Fracture Initiation ◽

In Situ Stress ◽

Experimental Investigations ◽

Propagation Process ◽

Fracturing Process

This paper presents results of a comprehensive study involving analytical and field experimental investigations into the factors controlling the hydraulic fracturing process. Analytical theories for fracture initiation of vertical and horizontal borehole are reviewed. The initiation and propagation process of hydraulic fracturing is performed in the field by means of hydraulic fracturing and stepwise hydraulic fracturing, the effect of factors such as in-situ stress and rock strength on fracture propagation process is studied and discussed. The fracture initiation pressures estimated from the analytical model and field experiments are compared as well as the fracturing process during case 1and case 2. Results from the analytical model and field experiments conducted in this study are interpreted with a particular effort to enlighten the factors controlling the hydraulic fracturing process.

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Fracture Propagation and Morphology Due to Non-Aqueous Fracturing: Competing Roles between Fluid Characteristics and In Situ Stress State

Minerals ◽

10.3390/min10050428 ◽

2020 ◽

Vol 10 (5) ◽

pp. 428

Author(s):

Yunzhong Jia ◽

Zhaohui Lu ◽

Hong Liu ◽

Jiehao Wang ◽

Yugang Cheng ◽

...

Keyword(s):

Carbon Dioxide ◽

Hydraulic Fracturing ◽

Fracture Propagation ◽

Horizontal Stress ◽

In Situ Stress ◽

Fluid Viscosity ◽

Low Viscosity ◽

Fracturing Process ◽

Fluid Characteristics

Non-aqueous or gaseous stimulants are alternative working fluids to water for hydraulic fracturing in shale reservoirs, which offer advantages including conserving water, avoiding clay swelling and decreasing formation damage. Hence, it is crucial to understand fluid-driven fracture propagation and morphology in shale formations. In this research, we conduct fracturing experiments on shale samples with water, liquid carbon dioxide, and supercritical carbon dioxide to explore the effect of fluid characteristics and in situ stress on fracture propagation and morphology. Moreover, a numerical model that couples rock property heterogeneity, micro-scale damage and fluid flow was built to compare with experimental observations. Our results indicate that the competing roles between fluid viscosity and in situ stress determine fluid-driven fracture propagation and morphology during the fracturing process. From the macroscopic aspect, fluid-driven fractures propagate to the direction of maximum horizontal stress direction. From the microscopic aspect, low viscosity fluid easily penetrates into pore throats and creates branches and secondary fractures, which may deflect the main fracture and eventually form the fracture networks. Our results provide a new understanding of fluid-driven fracture propagation, which is beneficial to fracturing fluid selection and fracturing strategy optimization for shale gas hydraulic fracturing operations.

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Development of hydraulic fracturing in-situ stress measurement technology and its application

In-Situ Rock Stress ◽

10.1201/9781439833650.ch16 ◽

2006 ◽

pp. 121-126

Author(s):

Q Guo ◽

Q Chen ◽

C Wang

Keyword(s):

Hydraulic Fracturing ◽

Stress Measurement ◽

In Situ Stress ◽

Measurement Technology ◽

In Situ Stress Measurement

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The Application of Hydraulic Fracturing in Storage Projects of Liquefied Petroleum Gas

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.306-308.1509 ◽

2006 ◽

Vol 306-308 ◽

pp. 1509-1514 ◽

Cited By ~ 1

Author(s):

Jing Feng ◽

Qian Sheng ◽

Chao Wen Luo ◽

Jing Zeng

Keyword(s):

Rock Mass ◽

Hydraulic Fracturing ◽

Stress Measurement ◽

Test Procedure ◽

In Situ Stress ◽

Test System ◽

Petroleum Engineering ◽

Liquefied Petroleum Gas

It is very important to study the pristine stress field in Civil, Mining, Petroleum engineering as well as in Geology, Geophysics, and Seismology. There are various methods of determination of in-situ stress in rock mass. However, hydraulic fracturing techniques is the most convenient method to determine and interpret the test results. Based on an hydraulic fracturing stress measurement campaign at an underground liquefied petroleum gas storage project which locates in ZhuHai, China, this paper briefly describes the various uses of stress measurement, details of hydraulic fracturing test system, test procedure adopted and the concept of hydraulic fracturing in arriving at the in-situ stresses of the rock mass.

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Determination of in situ stress profiles through hydraulic fracturing measurements in two distinct geologic areas

International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts ◽

10.1016/0148-9062(89)91444-7 ◽

1989 ◽

Vol 26 (6) ◽

pp. 637-645

Author(s):

W.S. Whitehead ◽

J.M. Gatens ◽

S.A. Holditch

Keyword(s):

Hydraulic Fracturing ◽

In Situ Stress ◽

Stress Profiles

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In situ stress determination by hydraulic fracturing—a method employing an artificial notch

International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts ◽

10.1016/0148-9062(89)91969-4 ◽

1989 ◽

Vol 26 (3-4) ◽

pp. 197-202 ◽

Cited By ~ 10

Author(s):

K. Hayashi ◽

T. Ito ◽

H. Abe

Keyword(s):

Hydraulic Fracturing ◽

In Situ Stress ◽

Stress Determination

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Fracturing curve and its corresponding gas productivity of coalbed methane wells in the Zhengzhuang block, southern Qinshui Basin, North China

Energy Exploration & Exploitation ◽

10.1177/0144598720923820 ◽

2020 ◽

Vol 38 (5) ◽

pp. 1387-1408

Author(s):

Yang Chen ◽

Dameng Liu ◽

Yidong Cai ◽

Jingjie Yao

Keyword(s):

Hydraulic Fracturing ◽

Coalbed Methane ◽

Continuous Production ◽

Fracture Morphology ◽

Geological Structure ◽

In Situ Stress ◽

Gas Production ◽

Type Curves ◽

Stable Type

Hydraulic fracturing has been widely used in low permeability coalbed methane reservoirs to enhance gas production. To better evaluate the hydraulic fracturing curve and its effect on gas productivity, geological and engineering data of 265 development coalbed methane wells and 14 appraisal coalbed methane wells in the Zhengzhuang block were investigated. Based on the regional geologic research and statistical analysis, the microseismic monitoring results, in-situ stress parameters, and gas productivity were synthetically evaluated. The results show that hydraulic fracturing curves can be divided into four types (descending type, stable type, wavy type, and ascending type) according to the fracturing pressure and fracture morphology, and the distributions of different type curves have direct relationship with geological structure. The vertical in-situ stress is greater than the closure stress in the Zhengzhuang block, but there is anomaly in the aggregation areas of the wavy and ascending fracturing curves, which is the main reason for the development of multi-directional propagated fractures. The fracture azimuth is consistent with the regional maximum principle in-situ stress direction (NE–NEE direction). Furthermore, the 265 fracturing curves indicate that the coalbed methane wells owned descending, and stable-type fracturing curves possibly have better fracturing effect considering the propagation pressure gradient (FP) and instantaneous shut-in pressure (PISI). Two fracturing-productivity patterns are summarized according to 61 continuous production wells with different fracturing type and their plane distribution, which indicates that the fracturing effect of different fracturing curve follows the pattern: descending type > stable type > wavy type > ascending type.

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