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Incorporation of sustainability in process control of hydraulic fracturing in unconventional reservoirs

•Dynamic modeling of the flow rate and TDS concentration of flowback water.•Designing of the hydraulic fracturing superstructure that minimizes TAC.•Case studies to examine the effect of water availability on the well productivity.•Evaluation of the environmental impact of flowback water using TRACI...

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Bibliographic Details
Published in:Chemical engineering research & design 2018-11, Vol.139, p.62-76
Main Authors: Etoughe, Priscille, Siddhamshetty, Prashanth, Cao, Kaiyu, Mukherjee, Rajib, Kwon, Joseph Sang-II
Format: Article
Language:English
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Summary:•Dynamic modeling of the flow rate and TDS concentration of flowback water.•Designing of the hydraulic fracturing superstructure that minimizes TAC.•Case studies to examine the effect of water availability on the well productivity.•Evaluation of the environmental impact of flowback water using TRACI. Typically, the term shale oil refers to natural oil trapped in rock of low porosity and ultra-low permeability. What has made the recovery of shale oil and gas economically viable is the extensive use of hydraulic fracturing and horizontal drilling. Research on the relationship between the distribution of propping agent, called proppant, and shale well performance indicates that uniformity of proppant bank height and suspended proppant concentration across the fracture at the end of pumping determines the productivity of produced wells. However, it is important to note that traditional fracturing fluid pumping schedules have not considered the environmental and economic impacts of the post-fracturing process such as treatment and reuse of flowback water from fractured wells. Motivated by this consideration, a control framework is proposed to integrate sustainability considerations of the post-fracturing process into the hydraulic fracturing process. In this regard, a dynamic model is developed to describe the flow rate and the concentration of total dissolved solids (TDS) in flowback water from fractured wells. Thermal membrane distillation is considered for the removal of TDS. An optimization problem is formulated to find the optimal process that consists of hydraulic fracturing, storage, transportation, and water treatment, through minimizing annualized cost and water footprint of the process. The capabilities of the proposed approach are illustrated through the simulation results of different scenarios that are performed to examine effects of water availability on the productivity of stimulated wells. Finally, the environmental impact of flowback water treatment is evaluated using TRACI, a tool for the reduction and assessment of chemical and other environmental impacts.
ISSN:0263-8762
1744-3563
DOI:10.1016/j.cherd.2018.09.016