Three-dimensional and two-phase numerical simulation of fractured dry gas reservoirs

Three-dimensional and two-phase numerical simulation of fractured dry gas reservoirs

Abstract A significant percentage of hydrocarbon reservoirs around the world is fractured. Moreover, the major part of gas reservoirs in Iran is also fractured type, so the existence of an in-house software is necessary. In this study, an efficient, user-friendly, and indigenous simulation of a thre...

Full description

Bibliographic Details
Main Authors: Ahmadreza Ejraei Bakyani, Ameneh Taghizadeh, Amir Nematollahi Sarvestani, Feridun Esmaeilzadeh, Dariush Mowla
Format: Article
Language:English
Published: SpringerOpen 2018-01-01
Series:Journal of Petroleum Exploration and Production Technology
Subjects:
Fracture
In-house software
IMPES formulation
C++ language
Numerical simulation
Online Access:http://link.springer.com/article/10.1007/s13202-017-0423-2
id doaj-0e230fe8d1ff493ba936d134e0c84894
record_format Article
spelling doaj-0e230fe8d1ff493ba936d134e0c848942020-11-24T22:03:16ZengSpringerOpenJournal of Petroleum Exploration and Production Technology2190-05582190-05662018-01-01841425144110.1007/s13202-017-0423-2Three-dimensional and two-phase numerical simulation of fractured dry gas reservoirsAhmadreza Ejraei Bakyani0Ameneh Taghizadeh1Amir Nematollahi Sarvestani2Feridun Esmaeilzadeh3Dariush Mowla4Department of Petroleum Engineering, School of Chemical, Petroleum, and Gas Engineering, Shiraz UniversityDepartment of Petroleum Engineering, School of Chemical, Petroleum, and Gas Engineering, Shiraz UniversityDepartment of Petroleum Engineering, School of Chemical, Petroleum, and Gas Engineering, Shiraz UniversityDepartment of Petroleum Engineering, School of Chemical, Petroleum, and Gas Engineering, Shiraz UniversityDepartment of Petroleum Engineering, School of Chemical, Petroleum, and Gas Engineering, Shiraz UniversityAbstract A significant percentage of hydrocarbon reservoirs around the world is fractured. Moreover, the major part of gas reservoirs in Iran is also fractured type, so the existence of an in-house software is necessary. In this study, an efficient, user-friendly, and indigenous simulation of a three-dimensional black oil fractured dry gas reservoir has been developed through IMPES method with the two-phase flow of gas and water. The presented simulator, which was written by C++ language and was known as fracture dry gas reservoir simulator, uses the implicit pressure and explicit saturation method for solving the equations. Also, effect of gravity pressure is neglected and effect of the capillary is considered in equations. By this simulator, we can investigate the dry gas reservoirs behavior with fractures. Darcy or non-Darcy fracture and matrix flow, Cartesian, cylindrical, and combination of Cartesian–cylindrical reservoir gridding, single porosity, dual porosity–single permeability, and dual porosity–dual permeability modeling are abilities of this simulator too. Additionally, this simulator is able to make outputs (such as pressure) at any given specific radius and time interval as numerical and/or graphical output in so little run time. Also, this simulator has PVT box and gridding box for doing the calculation of PVT and gridding. PVT box contains new correlations and EOS in comparison with another reservoir simulator. Gridding box makes us be able to simulate fractured dry gas reservoirs and hydraulically fractured well reservoirs too. Finally, the validity of this simulator was verified by comparing the simulation results with the other reservoir simulator (Eclipse) and showed a good compatibility between the developed software and Eclipse results in each time with different conditions such as various gridding conditions, various fluid data conditions and also various well configuration conditions.http://link.springer.com/article/10.1007/s13202-017-0423-2FractureIn-house softwareIMPES formulationC++ languageNumerical simulation
collection DOAJ
language English
format Article
sources DOAJ
author Ahmadreza Ejraei Bakyani
Ameneh Taghizadeh
Amir Nematollahi Sarvestani
Feridun Esmaeilzadeh
Dariush Mowla
spellingShingle Ahmadreza Ejraei Bakyani
Ameneh Taghizadeh
Amir Nematollahi Sarvestani
Feridun Esmaeilzadeh
Dariush Mowla
Three-dimensional and two-phase numerical simulation of fractured dry gas reservoirs
Journal of Petroleum Exploration and Production Technology
Fracture
In-house software
IMPES formulation
C++ language
Numerical simulation
author_facet Ahmadreza Ejraei Bakyani
Ameneh Taghizadeh
Amir Nematollahi Sarvestani
Feridun Esmaeilzadeh
Dariush Mowla
author_sort Ahmadreza Ejraei Bakyani
title Three-dimensional and two-phase numerical simulation of fractured dry gas reservoirs
title_short Three-dimensional and two-phase numerical simulation of fractured dry gas reservoirs
title_full Three-dimensional and two-phase numerical simulation of fractured dry gas reservoirs
title_fullStr Three-dimensional and two-phase numerical simulation of fractured dry gas reservoirs
title_full_unstemmed Three-dimensional and two-phase numerical simulation of fractured dry gas reservoirs
title_sort three-dimensional and two-phase numerical simulation of fractured dry gas reservoirs
publisher SpringerOpen
series Journal of Petroleum Exploration and Production Technology
issn 2190-0558
2190-0566
publishDate 2018-01-01
description Abstract A significant percentage of hydrocarbon reservoirs around the world is fractured. Moreover, the major part of gas reservoirs in Iran is also fractured type, so the existence of an in-house software is necessary. In this study, an efficient, user-friendly, and indigenous simulation of a three-dimensional black oil fractured dry gas reservoir has been developed through IMPES method with the two-phase flow of gas and water. The presented simulator, which was written by C++ language and was known as fracture dry gas reservoir simulator, uses the implicit pressure and explicit saturation method for solving the equations. Also, effect of gravity pressure is neglected and effect of the capillary is considered in equations. By this simulator, we can investigate the dry gas reservoirs behavior with fractures. Darcy or non-Darcy fracture and matrix flow, Cartesian, cylindrical, and combination of Cartesian–cylindrical reservoir gridding, single porosity, dual porosity–single permeability, and dual porosity–dual permeability modeling are abilities of this simulator too. Additionally, this simulator is able to make outputs (such as pressure) at any given specific radius and time interval as numerical and/or graphical output in so little run time. Also, this simulator has PVT box and gridding box for doing the calculation of PVT and gridding. PVT box contains new correlations and EOS in comparison with another reservoir simulator. Gridding box makes us be able to simulate fractured dry gas reservoirs and hydraulically fractured well reservoirs too. Finally, the validity of this simulator was verified by comparing the simulation results with the other reservoir simulator (Eclipse) and showed a good compatibility between the developed software and Eclipse results in each time with different conditions such as various gridding conditions, various fluid data conditions and also various well configuration conditions.
topic Fracture
In-house software
IMPES formulation
C++ language
Numerical simulation
url http://link.springer.com/article/10.1007/s13202-017-0423-2
work_keys_str_mv AT ahmadrezaejraeibakyani threedimensionalandtwophasenumericalsimulationoffractureddrygasreservoirs
AT amenehtaghizadeh threedimensionalandtwophasenumericalsimulationoffractureddrygasreservoirs
AT amirnematollahisarvestani threedimensionalandtwophasenumericalsimulationoffractureddrygasreservoirs
AT feridunesmaeilzadeh threedimensionalandtwophasenumericalsimulationoffractureddrygasreservoirs
AT dariushmowla threedimensionalandtwophasenumericalsimulationoffractureddrygasreservoirs
_version_ 1725832380974891008

Similar Items