Preformed particle gel extrusion through open conduits during conformance control treatments

Abdulmohsin Imqam; Baojun Bai; Mustafa A.I. Ramadan; Mingzhen Wei; Mojdeh Delshad; Kamy Sepehrnoori

Preformed particle gel extrusion through open conduits during conformance control treatments

Abdulmohsin Imqam, Baojun Bai^*, Mustafa A.I. Ramadan, Mingzhen Wei, Mojdeh Delshad, Kamy Sepehrnoori

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

15 Scopus citations

Abstract

Millimeter-sized (10 um∼mm) preformed particle gels (PPGs) have been used successfully as conformance control agents in more than 5,000 wells. They help to control both water and CO₂ production through high-permeability streaks or conduits (large pore openings), which naturally exist or are aggravated either by mineral solutions or by a high injection pressure during the flooding process. This paper explores several factors that can have an important impact on the injectivity and plugging efficiency of PPGs in these conduits. Extensive experiments were conducted to examine the effect of the conduit's opening size and the PPG strength on the ratio of the particle size to the opening diameter, injectivity index, resistance factor, and plugging efficiency. Five-foot tubes with four internal diameters were designed to emulate the opening conduits. Three pressure taps were mounted along the tubes to monitor PPG transport and plugging performance. The results show that weak gel has less injection pressure at a large particle opening ratio compared to strong gel. PPG strength impacted injectivity more significantly than did particle opening ratio. Resistance factor increased as the brine concentration and conduit opening size increased. PPGs can significantly reduce the permeability of an open conduit and their plugging efficiency depends highly on the particle strength and the conduit's opening size. The particle size of PPG was reduced during their transport through conduits. Experimental results confirm that the size reduction was caused by both dehydration and breakdown. Based on the lab data, two mathematical models were developed to quantitatively calculate the resistance factor and the stable injection pressure as a function of the particle strength, particle opening ratio, and shear rate. This research provides significant insight into designing better millimeter-sized particle gel treatments intended for use in large openings, including open fractures, caves, worm holes, and conduits.

Original language	English
Title of host publication	Society of Petroleum Engineers - 19th SPE Improved Oil Recovery Symposium, IOR 2014
Publisher	Society of Petroleum Engineers (SPE)
Pages	1098-1112
Number of pages	15
ISBN (Print)	9781632663863
State	Published - 2014
Externally published	Yes

Publication series

Name	Proceedings - SPE Symposium on Improved Oil Recovery
Volume	2

ASJC Scopus subject areas

Energy Engineering and Power Technology
Geotechnical Engineering and Engineering Geology

Cite this

Imqam, A., Bai, B., Ramadan, M. A. I., Wei, M., Delshad, M., & Sepehrnoori, K. (2014). Preformed particle gel extrusion through open conduits during conformance control treatments. In Society of Petroleum Engineers - 19th SPE Improved Oil Recovery Symposium, IOR 2014 (pp. 1098-1112). (Proceedings - SPE Symposium on Improved Oil Recovery; Vol. 2). Society of Petroleum Engineers (SPE).

@inproceedings{510108c5d73140fbb5be94e368802383,

title = "Preformed particle gel extrusion through open conduits during conformance control treatments",

abstract = "Millimeter-sized (10 um∼mm) preformed particle gels (PPGs) have been used successfully as conformance control agents in more than 5,000 wells. They help to control both water and CO2 production through high-permeability streaks or conduits (large pore openings), which naturally exist or are aggravated either by mineral solutions or by a high injection pressure during the flooding process. This paper explores several factors that can have an important impact on the injectivity and plugging efficiency of PPGs in these conduits. Extensive experiments were conducted to examine the effect of the conduit's opening size and the PPG strength on the ratio of the particle size to the opening diameter, injectivity index, resistance factor, and plugging efficiency. Five-foot tubes with four internal diameters were designed to emulate the opening conduits. Three pressure taps were mounted along the tubes to monitor PPG transport and plugging performance. The results show that weak gel has less injection pressure at a large particle opening ratio compared to strong gel. PPG strength impacted injectivity more significantly than did particle opening ratio. Resistance factor increased as the brine concentration and conduit opening size increased. PPGs can significantly reduce the permeability of an open conduit and their plugging efficiency depends highly on the particle strength and the conduit's opening size. The particle size of PPG was reduced during their transport through conduits. Experimental results confirm that the size reduction was caused by both dehydration and breakdown. Based on the lab data, two mathematical models were developed to quantitatively calculate the resistance factor and the stable injection pressure as a function of the particle strength, particle opening ratio, and shear rate. This research provides significant insight into designing better millimeter-sized particle gel treatments intended for use in large openings, including open fractures, caves, worm holes, and conduits.",

author = "Abdulmohsin Imqam and Baojun Bai and Ramadan, \{Mustafa A.I.\} and Mingzhen Wei and Mojdeh Delshad and Kamy Sepehrnoori",

year = "2014",

language = "English",

isbn = "9781632663863",

series = "Proceedings - SPE Symposium on Improved Oil Recovery",

publisher = "Society of Petroleum Engineers (SPE)",

pages = "1098--1112",

booktitle = "Society of Petroleum Engineers - 19th SPE Improved Oil Recovery Symposium, IOR 2014",

address = "United States",

}

Imqam, A, Bai, B, Ramadan, MAI, Wei, M, Delshad, M & Sepehrnoori, K 2014, Preformed particle gel extrusion through open conduits during conformance control treatments. in Society of Petroleum Engineers - 19th SPE Improved Oil Recovery Symposium, IOR 2014. Proceedings - SPE Symposium on Improved Oil Recovery, vol. 2, Society of Petroleum Engineers (SPE), pp. 1098-1112.

Preformed particle gel extrusion through open conduits during conformance control treatments. / Imqam, Abdulmohsin; Bai, Baojun; Ramadan, Mustafa A.I. et al.
Society of Petroleum Engineers - 19th SPE Improved Oil Recovery Symposium, IOR 2014. Society of Petroleum Engineers (SPE), 2014. p. 1098-1112 (Proceedings - SPE Symposium on Improved Oil Recovery; Vol. 2).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Preformed particle gel extrusion through open conduits during conformance control treatments

AU - Imqam, Abdulmohsin

AU - Bai, Baojun

AU - Ramadan, Mustafa A.I.

AU - Wei, Mingzhen

AU - Delshad, Mojdeh

AU - Sepehrnoori, Kamy

PY - 2014

Y1 - 2014

N2 - Millimeter-sized (10 um∼mm) preformed particle gels (PPGs) have been used successfully as conformance control agents in more than 5,000 wells. They help to control both water and CO2 production through high-permeability streaks or conduits (large pore openings), which naturally exist or are aggravated either by mineral solutions or by a high injection pressure during the flooding process. This paper explores several factors that can have an important impact on the injectivity and plugging efficiency of PPGs in these conduits. Extensive experiments were conducted to examine the effect of the conduit's opening size and the PPG strength on the ratio of the particle size to the opening diameter, injectivity index, resistance factor, and plugging efficiency. Five-foot tubes with four internal diameters were designed to emulate the opening conduits. Three pressure taps were mounted along the tubes to monitor PPG transport and plugging performance. The results show that weak gel has less injection pressure at a large particle opening ratio compared to strong gel. PPG strength impacted injectivity more significantly than did particle opening ratio. Resistance factor increased as the brine concentration and conduit opening size increased. PPGs can significantly reduce the permeability of an open conduit and their plugging efficiency depends highly on the particle strength and the conduit's opening size. The particle size of PPG was reduced during their transport through conduits. Experimental results confirm that the size reduction was caused by both dehydration and breakdown. Based on the lab data, two mathematical models were developed to quantitatively calculate the resistance factor and the stable injection pressure as a function of the particle strength, particle opening ratio, and shear rate. This research provides significant insight into designing better millimeter-sized particle gel treatments intended for use in large openings, including open fractures, caves, worm holes, and conduits.

AB - Millimeter-sized (10 um∼mm) preformed particle gels (PPGs) have been used successfully as conformance control agents in more than 5,000 wells. They help to control both water and CO2 production through high-permeability streaks or conduits (large pore openings), which naturally exist or are aggravated either by mineral solutions or by a high injection pressure during the flooding process. This paper explores several factors that can have an important impact on the injectivity and plugging efficiency of PPGs in these conduits. Extensive experiments were conducted to examine the effect of the conduit's opening size and the PPG strength on the ratio of the particle size to the opening diameter, injectivity index, resistance factor, and plugging efficiency. Five-foot tubes with four internal diameters were designed to emulate the opening conduits. Three pressure taps were mounted along the tubes to monitor PPG transport and plugging performance. The results show that weak gel has less injection pressure at a large particle opening ratio compared to strong gel. PPG strength impacted injectivity more significantly than did particle opening ratio. Resistance factor increased as the brine concentration and conduit opening size increased. PPGs can significantly reduce the permeability of an open conduit and their plugging efficiency depends highly on the particle strength and the conduit's opening size. The particle size of PPG was reduced during their transport through conduits. Experimental results confirm that the size reduction was caused by both dehydration and breakdown. Based on the lab data, two mathematical models were developed to quantitatively calculate the resistance factor and the stable injection pressure as a function of the particle strength, particle opening ratio, and shear rate. This research provides significant insight into designing better millimeter-sized particle gel treatments intended for use in large openings, including open fractures, caves, worm holes, and conduits.

UR - https://www.scopus.com/pages/publications/84905724874

M3 - Conference contribution

AN - SCOPUS:84905724874

SN - 9781632663863

T3 - Proceedings - SPE Symposium on Improved Oil Recovery

SP - 1098

EP - 1112

BT - Society of Petroleum Engineers - 19th SPE Improved Oil Recovery Symposium, IOR 2014

PB - Society of Petroleum Engineers (SPE)

ER -

Preformed particle gel extrusion through open conduits during conformance control treatments

Abstract

Publication series

ASJC Scopus subject areas

Fingerprint

Cite this