Advanced Modeling of Interwell Fracturing Interference: An Eagle Ford Shale Oil Study - Refracturing

Morales, Adrián; Zhuang, Ke; Gakhar, Kush; Porcu, Matteo Marongiu; Lee, Don; Shan, Dan; Malpani, Raj; Pope, Tim; Sobernheim, David; Acock, A.M.

doi:10.2118/179177-ms

Cited by 66 publications

(14 citation statements)

References 21 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…By creating the pressure barrier around the parent well, the child well's created fracture network is more likely to extend into undepleted reservoir areas with higher remaining oil in place. This occurrence has been modelled and shown by Marongio-Porcu et al (2015) and Morales et al (2016).…”

Section: Single Well Refracturing Versus Parent Well Protection Reframentioning

confidence: 56%

“…Instead, the current production rates of the well tripled. Morales et al (2016) modeled the interwell fracture interference using a complex fracture modeling workflow for an Eagle Ford study. In this study, Morales et al found that refracturing the parent well before completing the new offset wells can not only increase the production of the existing parent well, but it can also increase the production potential of the new infill wells, as shown in Fig.…”

Section: Production Results For Parent Well Protection Refracturingmentioning

confidence: 99%

“…Many papers have been written discussing this occurrence and principles as to how fracture hits may happen (Diakhate et al 2015;Lindsay et al 2016;Malpani et al 2015;Marongio-Porcu et al 2015;Martinez et al 2012;Morales et al 2016;Roussel and Sharma 2010;Roussel and Sharma 2012). The depletion effects during the life of the original parent well create localized pressure sinks.…”

Section: Effects Of Infill Well Drilling On Parent Wellsmentioning

confidence: 99%

See 2 more Smart Citations

Parent Well Refracturing: Economic Safety Nets in an Uneconomic Market

et al. 2016

View full text Add to dashboard Cite

As unconventional basins mature, infill drilling and completion campaigns take a more central role in field development planning, not only for maximizing infill well potential, but also for protecting the economic potential of pre-existing wells. Reservoir depletion from parent wells can create localized Љpressure sinks.Љ When a nearby infill well is fractured, the hydraulic fracture grows towards areas of lowest stress (the depleted area), which can damage the parent well. Subsequently, the production potential of the new well is decreased because it is now draining from the same reservoir area as the parent well. In a damaging fracturing hit from an infill well, the parent well can lose some to all of its production compared to rates before the fracturing hit. Sometimes, simply shutting in the parent well is not sufficient to prevent this damage.In this paper, more than 3,100 fracture interferences in 5 major basins (Eagle Ford, Bakken, Haynesville, Niobrara, and Woodford) are examined to determine which basins are more prone to positive or negative fracture interferences from new infill wells. The Haynesville and Bakken have more positive fracture hits than the other basins, while a majority of the fracture hits in the Woodford and Niobrara are negative.With the advent of modern diversion-based refracturing techniques, it is possible to create a Љpressure barrierЉ around the parent well that helps redirect the new fracturing treatment into other, virgin areas of reservoir. By refracturing the parent well first, this may not only preserve the original production of the parent well, but it may also increase the production of the parent well as well as the new infill wells. Although refracturing adds to the capital expenditure of the project, project economics may be more favorable with the investment in parent well refracturing. Examples of parent well refracturing are also presented in this paper.

show abstract

Section: Single Well Refracturing Versus Parent Well Protection Reframentioning

confidence: 56%

Section: Production Results For Parent Well Protection Refracturingmentioning

confidence: 99%

Section: Effects Of Infill Well Drilling On Parent Wellsmentioning

confidence: 99%

See 1 more Smart Citation

Parent Well Refracturing: Economic Safety Nets in an Uneconomic Market

et al. 2016

View full text Add to dashboard Cite

show abstract

“…This interwell communication can be portrayed as "pressure sinks" that interfere with induced fracture effectiveness, and might affect unconventional EOR methods efficacy if they are overridden or not accounted for. For instance, numerous documented studies have demonstrated fracture interference occurrence and assessed this phenomenon in unconventional reservoirs (Ambrose et al, 2011;Manchanda et al, 2013;Portis et al, 2013;Sardinha et al, 2014;Sani et al, 2015;Awada et al, 2016;Morales et al, 2016;Klenner et al, 2018;Seth et al, 2018;Yu and Sepehrnoori, 2018). The current interest is focused on warding off negative impacts caused by fracture hits interwell propagation and affecting further productive wells.…”

Section: Motivation Of the Studymentioning

confidence: 99%

Modeling Interwell Fracture Interference and Huff-N-Puff Pressure Containment in Eagle Ford Using EDFM

Fiallos-Torres

Ganjdanesh

et al. 2019

Day 2 Wed, April 10, 2019

View full text Add to dashboard Cite

First, I would like to express my profound gratitude to my academic supervisor Dr. Sepehrnoori for the continuous guidance and support during these two years of graduate school. I am truly grateful for his interest and willingness to guide me since the very first day of my graduate studies. I would also like to express sincere gratefulness to Dr. Wei Yu for his dedication, expertise advises, and insistent valuable guidance. I will always appreciate how he shared part of his extensive expertise in unconventional reservoirs, and reservoir modeling with me. Also, I would like to thank Erich Kerr and his company for supplying the field data that made this research possible. I gained great practice and understanding through their suggestions for my research work. Their invaluable support received weekly through my entire career will always be appreciated. There are not enough words to express how convinced I am that this would not have been possible without the support of my family. I thank my father Mario and my mother María for covering part of my tuition, and also my sister Carla Adriana for their continuous encouragement to pursue my dreams. I would like to thank Carolina for her caring love and support. I am indebted to my parents, my sister and my girlfriend who never stopped encouraging during both the good and the not so good times. I would also like to thank Reza, Sutthaporn, Fabio, Jorge, and Esmail for their collaboration and assertive comments for my work and my research. Finally, a very special acknowledgment is extended to the Fulbright Commission of Ecuador, the Department of State of the United States, and the Cockrell School of Engineering for being the sponsoring entities which provided me the scholarships to fund and make this accomplishment possible.

show abstract

“…As shown in Figure 11(b), the cumulative gas production of the well increases from 0.48 × 10 8 m 3 to 0.54 × 10 8 m 3 while the hydraulic fracture half-length increases from 70 m to 110 m. In addition, the reservoir pressure decreases slower with higher hydraulic fracture half-length, which is beneficial for long-time production, as shown in Figures 12 and 13. However, in refracturing, the fracture does not follow the same path of the initial fracture due to the change in stress anisotropy; it is not easy to obtain longer fracture length [14]. Figure 11: Effects of hydraulic fracture half-length on: (a) gas flow rate and (b) gas flow rate of refracturing through new perforation zones.…”

Section: Hydraulic Fracture Half-lengthmentioning

confidence: 99%

Well Performance Simulation and Parametric Study for Different Refracturing Scenarios in Shale Reservoir

et al. 2018

View full text Add to dashboard Cite

Refracturing is an encouraging way to uplift gas flow rate and ultimate gas recovery from shale gas wells. A numerical model, considering the stimulated reservoir volume and multiscale gas transport, is applied to simulate the gas production from a refractured shale gas well. The model is verified against field data from a shale gas reservoir in Sichuan Basin. Two refracturing scenarios: refracturing through existing perforation clusters and refracturing through new perforation zones, are included in the simulation work. Three years after production is determined to be the optimum time for refracturing based on the evolution analysis of reservoir pressure, effective stress, fracture permeability, and gas recovery. The role that the hydraulic fracture conductivity and hydraulic fracture half-length play in gas production for different refracturing cases is explored. Pumping parameters of the refracturing job in Sichuan Basin are discussed combining with sensitivity analysis, and suggestions for pumping parameters optimization are proposed.

show abstract

Advanced Modeling of Interwell Fracturing Interference: An Eagle Ford Shale Oil Study - Refracturing

Cited by 66 publications

References 21 publications

Parent Well Refracturing: Economic Safety Nets in an Uneconomic Market

Parent Well Refracturing: Economic Safety Nets in an Uneconomic Market

Modeling Interwell Fracture Interference and Huff-N-Puff Pressure Containment in Eagle Ford Using EDFM

Well Performance Simulation and Parametric Study for Different Refracturing Scenarios in Shale Reservoir

Contact Info

Product

Resources

About