Modeling the perforation stress profile for analyzing hydraulic fracture initiation in a cased hole

S. H. Fallahzadeh, S. R. Shadizadeh, P. Pourafshary, M. R. Zare

Research output: Chapter in Book/Report/Conference proceedingConference contribution

15 Citations (Scopus)

Abstract

Hydraulic fracturing has been used for many years in order to stimulate the oil and gas wells for improving the reservoir production. Many investments are allocated for hydraulic fracturing all around the world to develop hydrocarbon resources. Most of them are done for cased holes which some of them do not significantly improve the hydrocarbon production. The main reason is improper fracture initiation and complex near-wellbore fracture geometry which is a challenging problem. In cased holes, the perforations are the only connection between the well and the reservoir, therefore the fracture initiates somewhere in the perforation. Understanding the stress distribution around the perforations is the key for analyzing the fracture initiation mechanism and thereby the near-wellbore fracture geometry. In this paper new analytical formulas are derived and applied along with numerical methods to simulate the stress profile around the perforations. Having analyzed the perforation stress distribution, it is possible to understand the mechanism of fracture initiation and consequently improving the near-wellbore fracture geometry. Results of this model are presented at some in-situ stress regimes, cement and rock properties, and also perforation and well parameters. It is concluded that, at any specific stress regime, there is an optimum well design and completion, and also perforation orientation, which leads to lower fracture initiation pressure as well as better fracture orientation geometry in terms of less near-wellbore fracture tortuosity. Therefore, better connection can be developed between the borehole and the reservoir formation. The importance of this model is its ability in analyzing the stress profile along the perforation tunnel, so more realistic fracture initiation pressure and fracture geometry can be estimated for better well completion and perforation design.

Original languageEnglish
Title of host publicationSociety of Petroleum Engineers - Nigeria Annual International Conference and Exhibition 2010, NAICE
Pages370-378
Number of pages9
Volume1
Publication statusPublished - Dec 28 2010
Externally publishedYes
Event2010 Nigeria Annual International Conference and Exhibition: Meeting the World's Energy Demand and Supply Mix: The Role of Africa, NAICE - Calabar, Nigeria
Duration: Jul 31 2010Aug 7 2010

Conference

Conference2010 Nigeria Annual International Conference and Exhibition: Meeting the World's Energy Demand and Supply Mix: The Role of Africa, NAICE
CountryNigeria
CityCalabar
Period7/31/108/7/10

Fingerprint

fracture initiation
perforation
Hydraulics
fracture geometry
modeling
Geometry
Hydraulic fracturing
Hydrocarbons
hydraulic fracturing
Stress concentration
hydrocarbon resource
fracture orientation
tortuosity
well completion
Well perforation
rock property
in situ stress
oil well
gas well
Well completion

ASJC Scopus subject areas

  • Geochemistry and Petrology
  • Geotechnical Engineering and Engineering Geology
  • Fuel Technology

Cite this

Fallahzadeh, S. H., Shadizadeh, S. R., Pourafshary, P., & Zare, M. R. (2010). Modeling the perforation stress profile for analyzing hydraulic fracture initiation in a cased hole. In Society of Petroleum Engineers - Nigeria Annual International Conference and Exhibition 2010, NAICE (Vol. 1, pp. 370-378)

Modeling the perforation stress profile for analyzing hydraulic fracture initiation in a cased hole. / Fallahzadeh, S. H.; Shadizadeh, S. R.; Pourafshary, P.; Zare, M. R.

Society of Petroleum Engineers - Nigeria Annual International Conference and Exhibition 2010, NAICE. Vol. 1 2010. p. 370-378.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Fallahzadeh, SH, Shadizadeh, SR, Pourafshary, P & Zare, MR 2010, Modeling the perforation stress profile for analyzing hydraulic fracture initiation in a cased hole. in Society of Petroleum Engineers - Nigeria Annual International Conference and Exhibition 2010, NAICE. vol. 1, pp. 370-378, 2010 Nigeria Annual International Conference and Exhibition: Meeting the World's Energy Demand and Supply Mix: The Role of Africa, NAICE, Calabar, Nigeria, 7/31/10.
Fallahzadeh SH, Shadizadeh SR, Pourafshary P, Zare MR. Modeling the perforation stress profile for analyzing hydraulic fracture initiation in a cased hole. In Society of Petroleum Engineers - Nigeria Annual International Conference and Exhibition 2010, NAICE. Vol. 1. 2010. p. 370-378
Fallahzadeh, S. H. ; Shadizadeh, S. R. ; Pourafshary, P. ; Zare, M. R. / Modeling the perforation stress profile for analyzing hydraulic fracture initiation in a cased hole. Society of Petroleum Engineers - Nigeria Annual International Conference and Exhibition 2010, NAICE. Vol. 1 2010. pp. 370-378
@inproceedings{1089669d54a149ba814fbe3b5288ec17,
title = "Modeling the perforation stress profile for analyzing hydraulic fracture initiation in a cased hole",
abstract = "Hydraulic fracturing has been used for many years in order to stimulate the oil and gas wells for improving the reservoir production. Many investments are allocated for hydraulic fracturing all around the world to develop hydrocarbon resources. Most of them are done for cased holes which some of them do not significantly improve the hydrocarbon production. The main reason is improper fracture initiation and complex near-wellbore fracture geometry which is a challenging problem. In cased holes, the perforations are the only connection between the well and the reservoir, therefore the fracture initiates somewhere in the perforation. Understanding the stress distribution around the perforations is the key for analyzing the fracture initiation mechanism and thereby the near-wellbore fracture geometry. In this paper new analytical formulas are derived and applied along with numerical methods to simulate the stress profile around the perforations. Having analyzed the perforation stress distribution, it is possible to understand the mechanism of fracture initiation and consequently improving the near-wellbore fracture geometry. Results of this model are presented at some in-situ stress regimes, cement and rock properties, and also perforation and well parameters. It is concluded that, at any specific stress regime, there is an optimum well design and completion, and also perforation orientation, which leads to lower fracture initiation pressure as well as better fracture orientation geometry in terms of less near-wellbore fracture tortuosity. Therefore, better connection can be developed between the borehole and the reservoir formation. The importance of this model is its ability in analyzing the stress profile along the perforation tunnel, so more realistic fracture initiation pressure and fracture geometry can be estimated for better well completion and perforation design.",
author = "Fallahzadeh, {S. H.} and Shadizadeh, {S. R.} and P. Pourafshary and Zare, {M. R.}",
year = "2010",
month = "12",
day = "28",
language = "English",
isbn = "9781617388835",
volume = "1",
pages = "370--378",
booktitle = "Society of Petroleum Engineers - Nigeria Annual International Conference and Exhibition 2010, NAICE",

}

TY - GEN

T1 - Modeling the perforation stress profile for analyzing hydraulic fracture initiation in a cased hole

AU - Fallahzadeh, S. H.

AU - Shadizadeh, S. R.

AU - Pourafshary, P.

AU - Zare, M. R.

PY - 2010/12/28

Y1 - 2010/12/28

N2 - Hydraulic fracturing has been used for many years in order to stimulate the oil and gas wells for improving the reservoir production. Many investments are allocated for hydraulic fracturing all around the world to develop hydrocarbon resources. Most of them are done for cased holes which some of them do not significantly improve the hydrocarbon production. The main reason is improper fracture initiation and complex near-wellbore fracture geometry which is a challenging problem. In cased holes, the perforations are the only connection between the well and the reservoir, therefore the fracture initiates somewhere in the perforation. Understanding the stress distribution around the perforations is the key for analyzing the fracture initiation mechanism and thereby the near-wellbore fracture geometry. In this paper new analytical formulas are derived and applied along with numerical methods to simulate the stress profile around the perforations. Having analyzed the perforation stress distribution, it is possible to understand the mechanism of fracture initiation and consequently improving the near-wellbore fracture geometry. Results of this model are presented at some in-situ stress regimes, cement and rock properties, and also perforation and well parameters. It is concluded that, at any specific stress regime, there is an optimum well design and completion, and also perforation orientation, which leads to lower fracture initiation pressure as well as better fracture orientation geometry in terms of less near-wellbore fracture tortuosity. Therefore, better connection can be developed between the borehole and the reservoir formation. The importance of this model is its ability in analyzing the stress profile along the perforation tunnel, so more realistic fracture initiation pressure and fracture geometry can be estimated for better well completion and perforation design.

AB - Hydraulic fracturing has been used for many years in order to stimulate the oil and gas wells for improving the reservoir production. Many investments are allocated for hydraulic fracturing all around the world to develop hydrocarbon resources. Most of them are done for cased holes which some of them do not significantly improve the hydrocarbon production. The main reason is improper fracture initiation and complex near-wellbore fracture geometry which is a challenging problem. In cased holes, the perforations are the only connection between the well and the reservoir, therefore the fracture initiates somewhere in the perforation. Understanding the stress distribution around the perforations is the key for analyzing the fracture initiation mechanism and thereby the near-wellbore fracture geometry. In this paper new analytical formulas are derived and applied along with numerical methods to simulate the stress profile around the perforations. Having analyzed the perforation stress distribution, it is possible to understand the mechanism of fracture initiation and consequently improving the near-wellbore fracture geometry. Results of this model are presented at some in-situ stress regimes, cement and rock properties, and also perforation and well parameters. It is concluded that, at any specific stress regime, there is an optimum well design and completion, and also perforation orientation, which leads to lower fracture initiation pressure as well as better fracture orientation geometry in terms of less near-wellbore fracture tortuosity. Therefore, better connection can be developed between the borehole and the reservoir formation. The importance of this model is its ability in analyzing the stress profile along the perforation tunnel, so more realistic fracture initiation pressure and fracture geometry can be estimated for better well completion and perforation design.

UR - http://www.scopus.com/inward/record.url?scp=78650464220&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=78650464220&partnerID=8YFLogxK

M3 - Conference contribution

AN - SCOPUS:78650464220

SN - 9781617388835

VL - 1

SP - 370

EP - 378

BT - Society of Petroleum Engineers - Nigeria Annual International Conference and Exhibition 2010, NAICE

ER -