POLYACRYLAMIDE DEGRADATION DURING HYDRAULIC FRACTURING AND ITS IMPACT ON MEMBRANE FOULING DURING WASTEWATER TREATMENT. PDF Download
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Author: Boya Xiong
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
The high intensity of unconventional oil and gas development nationwide and at global scale has an enormous impact on local and regional water resource and water quality. High volume hydraulic fracturing (HVHF) utilizes a wide range of proprietary chemicals and more than a million liters of water per well, generating around 100 billion liters of flowback and produced water annually in the U.S. HVHF wastewater contains high levels of salinity, turbidity, organic matter and radioactivity; posing technical and economic challenges to wastewater treatment. Current practices are unlikely to manage the growing volume of wastewaters in a sustainable and economically feasible manner. More importantly, many environmental impacts of HVHF wastewater contamination remain unclear due to the unresolved organic components in wastewater, many of which originate from injected chemicals. The goal of work was to better quantify the environmental risks of HVHF activities by identifying and analyzing the fate and characteristics of these injected chemicals that cause challenges in subsequent membrane treatment and also have the potential to release toxic byproducts.High molecular weight (106 3107 Da) polyacrylamide (PAM) and its copolymers are heavily used as friction reducers in HVHF. Extractions in the Marcellus shale alone are estimated to have consumed 5000-140,000 tons of PAM. However, PAM molecules are not characterized by the current organic analyses that utilize advanced chromatography and mass spectrometry techniques due to their hydrophilic nature and large size. In this work, it was identified that under simulated HVHF deep subsurface conditions, PAM (1.5107 Da) is susceptible to significant free radical induced chemical degradation, with the final MWs ranging over three orders of magnitude from 8103 - 1.5107 Da as quantified by size exclusion chromatography. The degradation kinetics are governed by the formation temperature, shale mineralogy and dissolved oxygen concentration in the initial fluids. The above information on operating conditions is readily available from drilling logs and geological surveys of gas reservoirs - thus these results make it possible to predict the extent of polymer degradation at a specific fracturing site. In addition, my PhD work extends the main work on chemical degradation to quantify the mechanical degradation of polyacrylamide using a high-pressure capillary flow set up. The experimental setup simulates the high strain rates similar to that at the entrance flow through small pores and fractures in the formation face during the fracture propagation phase where the hydraulic pressure can reach as high as 700 bar. Here I report a non-chemical pathway- purely physical transformation of fracturing chemicals under HVHF conditions that is unique to high molecular weight polymers.The objectives of this work also included evaluation of membrane treatability of actual flowback and produced waters from the Marcellus shale play. The data show severe fouling during microfiltration membrane treatment. Surprisingly, the high variation in fouling behavior for different water samples cannot be correlated with their levels of total organic carbon or suspended solids, both commonly measured water quality parameters, suggesting a high level of complexity in the fouling components of the feed water matrix in these waste streams. The fouling rates of some wastewaters were dominated by the presence of colloidal and organic matter; however, their origin and detailed characterization remains unclear. Experiments performed with a synthetic fracturing fluid demonstrated that out of 10 different fracturing chemicals, the PAM-based friction reducer is the primary contributor to fouling rates during microfiltration treatment of the wastewater. More importantly, fouling rates were well correlated with the hydrodynamic size of PAM present in the wastewater. These results indicate that a higher fouling rate of membrane treatment will occur during the treatment of wastewaters containing large size polymers, when specific fracturing and formation conditions are favorable for limited polymer degradation.These degraded polymer molecules, which have unknown toxicities, are present in the wastewater and could reach downstream water supplies. Furthermore, complete degradation of PAM would result in release of the neurotoxic monomer acrylamide. This work, for the first time, provides detailed information on the downhole transformation and membrane treatability of PAM, a heavily used chemical in the HVHF process. This work enables the development of treatment strategies to minimize waste volume, toxicity, and broader environmental impacts of HVHF wastewaters that will be continuously generated in upcoming years as a part of the energy production trajectory of many nations worldwide.
Author: Boya Xiong
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
The high intensity of unconventional oil and gas development nationwide and at global scale has an enormous impact on local and regional water resource and water quality. High volume hydraulic fracturing (HVHF) utilizes a wide range of proprietary chemicals and more than a million liters of water per well, generating around 100 billion liters of flowback and produced water annually in the U.S. HVHF wastewater contains high levels of salinity, turbidity, organic matter and radioactivity; posing technical and economic challenges to wastewater treatment. Current practices are unlikely to manage the growing volume of wastewaters in a sustainable and economically feasible manner. More importantly, many environmental impacts of HVHF wastewater contamination remain unclear due to the unresolved organic components in wastewater, many of which originate from injected chemicals. The goal of work was to better quantify the environmental risks of HVHF activities by identifying and analyzing the fate and characteristics of these injected chemicals that cause challenges in subsequent membrane treatment and also have the potential to release toxic byproducts.High molecular weight (106 3107 Da) polyacrylamide (PAM) and its copolymers are heavily used as friction reducers in HVHF. Extractions in the Marcellus shale alone are estimated to have consumed 5000-140,000 tons of PAM. However, PAM molecules are not characterized by the current organic analyses that utilize advanced chromatography and mass spectrometry techniques due to their hydrophilic nature and large size. In this work, it was identified that under simulated HVHF deep subsurface conditions, PAM (1.5107 Da) is susceptible to significant free radical induced chemical degradation, with the final MWs ranging over three orders of magnitude from 8103 - 1.5107 Da as quantified by size exclusion chromatography. The degradation kinetics are governed by the formation temperature, shale mineralogy and dissolved oxygen concentration in the initial fluids. The above information on operating conditions is readily available from drilling logs and geological surveys of gas reservoirs - thus these results make it possible to predict the extent of polymer degradation at a specific fracturing site. In addition, my PhD work extends the main work on chemical degradation to quantify the mechanical degradation of polyacrylamide using a high-pressure capillary flow set up. The experimental setup simulates the high strain rates similar to that at the entrance flow through small pores and fractures in the formation face during the fracture propagation phase where the hydraulic pressure can reach as high as 700 bar. Here I report a non-chemical pathway- purely physical transformation of fracturing chemicals under HVHF conditions that is unique to high molecular weight polymers.The objectives of this work also included evaluation of membrane treatability of actual flowback and produced waters from the Marcellus shale play. The data show severe fouling during microfiltration membrane treatment. Surprisingly, the high variation in fouling behavior for different water samples cannot be correlated with their levels of total organic carbon or suspended solids, both commonly measured water quality parameters, suggesting a high level of complexity in the fouling components of the feed water matrix in these waste streams. The fouling rates of some wastewaters were dominated by the presence of colloidal and organic matter; however, their origin and detailed characterization remains unclear. Experiments performed with a synthetic fracturing fluid demonstrated that out of 10 different fracturing chemicals, the PAM-based friction reducer is the primary contributor to fouling rates during microfiltration treatment of the wastewater. More importantly, fouling rates were well correlated with the hydrodynamic size of PAM present in the wastewater. These results indicate that a higher fouling rate of membrane treatment will occur during the treatment of wastewaters containing large size polymers, when specific fracturing and formation conditions are favorable for limited polymer degradation.These degraded polymer molecules, which have unknown toxicities, are present in the wastewater and could reach downstream water supplies. Furthermore, complete degradation of PAM would result in release of the neurotoxic monomer acrylamide. This work, for the first time, provides detailed information on the downhole transformation and membrane treatability of PAM, a heavily used chemical in the HVHF process. This work enables the development of treatment strategies to minimize waste volume, toxicity, and broader environmental impacts of HVHF wastewaters that will be continuously generated in upcoming years as a part of the energy production trajectory of many nations worldwide.
Author: Md. Shahidul Islam
Publisher:
ISBN:
Category :
Languages : en
Pages : 171
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Book Description
The management of highly saline wastewater released from hydraulic fracturing-also known as fracking-a hydrocarbon releasing process used in the rapidly growing shale gas industry, is a serious challenge for industry and regulators due to its adverse effects on public health and to the environment in general. As well, fracking wastewater also contains particularly concerning levels of suspended solids, mainly comprised of sand and oil. Pre-treatment of fracking wastewater through microfiltration (MF) can effectively remove these suspended solids and oily materials. Forward osmosis (FO), an emerging membrane-based technology, is a feasible method for the treatment of fracking wastewater. For the FO process to be successful, an effectively engineered draw solution, a robust FO membrane, and an efficient pre-treatment, such as MF are required. FO is particularly effective when combined with membrane distillation (MD) for the recycling of the FO draw solutions. Therefore, the goals of this research project were to a) identify an effective draw solution for FO and b) fabricate two types of advanced membrane materials: MF membranes with high water flux, high rejection, and antifouling properties, and a FO membrane for recycling fracking wastewater with high water flux, high rejection, and antifouling properties. In this research, a comprehensive study was conducted to identify novel, yet effective, organic draw solutions for the treatment of fracking wastewater by FO. A novel high water-flux polyvinyl acetate-coated electrospun nylon 6/silica (SiO2) composite MF membrane was fabricated and its performance was tested in regard to water flux, oil rejection, and antifouling properties. In the next stage of this research, a new FO membrane material with high water-flux with high rejection and antifouling properties was fabricated and characterized. Finally, real fracking wastewater was treated using MF and then FO-combined with MD as a downstream separator-using the fabricated membranes. In the pre-treatment stage, 9̃8.5% turbidity and 5̃2% of total organic carbon (TOC) were removed from the fracking wastewater via the MF process. Finally, treated water with TDS 23-44 mg/L was obtained from the pre-treated wastewater via the combined FO/MD process. This produced water can effectively be reused for hydraulic fracking.
Author: Frank R. Spellman
Publisher: CRC Press
ISBN: 1351986384
Category : Technology & Engineering
Languages : en
Pages : 313
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Book Description
This book provides a balanced discussion about the wastewater generated by hydraulic fracturing operations, and how to manage it. It includes an in-depth discussion of the hydraulic fracturing process, the resulting water cycle, and the potential risks to groundwater, soil, and air. The “fracking” process involves numerous chemicals that could potentially harm human health and the environment, especially if they enter and contaminate drinking water supplies. Treatment, reuse, and disposal options are the focus, and several case studies will be presented. The book also discusses the issues of the large amounts of water required for drilling operations, the impacts on water-sensitive regions.
Author: U. S. Environmental Agency
Publisher: CreateSpace
ISBN: 9781507587270
Category :
Languages : en
Pages : 276
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Book Description
Natural gas plays a key role in our nation's clean energy future. The United States has vast reserves of natural gas that are commercially viable as a result of advances in horizontal drilling and hydraulic fracturing technologies, which enable greater access to gas in rock formations deep underground. These advances have spurred a significant increase in the production of both natural gas and oil across the country. Responsible development of America's oil and gas resources offers important economic, energy security, and environmental benefits. However, as the use of hydraulic fracturing has increased, so have concerns about its potential human health and environmental impacts, especially for drinking water. In response to public concern, the US House of Representatives requested that the US Environmental Protection Agency (EPA) conduct scientific research to examine the relationship between hydraulic fracturing and drinking water resources. In 2011, the EPA began research under its Plan to Study the Potential Impacts of Hydraulic Fracturing on Drinking Water Resources. The purpose of the study is to assess the potential impacts of hydraulic fracturing on drinking water resources, if any, and to identify the driving factors that may affect the severity and frequency of such impacts. Scientists are focusing primarily on hydraulic fracturing of shale formations to extract natural gas, with some study of other oil-and gas-producing formations, including tight sands, and coalbeds. The EPA has designed the scope of the research around five stages of the hydraulic fracturing water cycle. Each stage of the cycle is associated with a primary research question: Water acquisition: What are the possible impacts of large volume water withdrawals from ground and surface waters on drinking water resources? Chemical mixing: What are the possible impacts of hydraulic fracturing fluid surface spills on or near well pads on drinking water resources? Well injection: What are the possible impacts of the injection and fracturing process on drinking water resources? Flowback and produced water: What are the possible impacts of flowback and produced water (collectively referred to as "hydraulic fracturing wastewater") surface spills on or near well pads on drinking water resources? Wastewater treatment and waste disposal: What are the possible impacts of inadequate treatment of hydraulic fracturing wastewater on drinking water resources? This report describes 18 research projects underway to answer these research questions and presents the progress made as of September 2012 for each of the projects. Information presented as part of this report cannot be used to draw conclusions about potential impacts to drinking water resources from hydraulic fracturing. The research projects are organized according to five different types of research activities: analysis of existing data, scenario evaluations, laboratory studies, toxicity assessments, and case studies.
Author: Taylor Kristen Pawlik
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
During high volume hydraulic fracturing (HVHF), high rates of pumping through narrow fractures might create a high shear environment that could lead to mechanical degradation of high molecular weight polyacrylamide (PAM) used as a drag reducer. This degradation could increase the likelihood of releasing the monomer acrylamide, a neurotoxin and potential carcinogen, into the returning wastewater. The objective of this study was to determine the power law index (n) and consistency factor (K) of PAM under extremely high shear rates using high pressure (i.e. ~10,000 psi) flow through an abrupt contraction (i.e. narrow capillary), which was then used to examine the degree of mechanical degradation. The responding pressure drop values of fluid through two different diameter capillaries were recorded under constant flow rate controlled by high-pressure precision pumps. Linearized pressure and velocity parameters were used to determine n and K. Size exclusion chromatography was used to determine molecular weight change due to mechanical degradation. The power law index was determined to be 0.955 and the consistency factor was determined to be 5.06x10-3. The molecular weight of the polymer was relatively unchanged below a shear rate of 1.0x10-6 s-1, and decreased exponentially as shear rate increased. The distribution of molecular weight narrowed as shear rate increased, indicating that the majority of mechanical degradation occurred at the midpoint of the polymer chain.
Author: U. S. Environmental Agency
Publisher: CreateSpace
ISBN: 9781507587553
Category :
Languages : en
Pages : 190
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Book Description
Natural gas plays a key role in our nation's clean energy future. Recent advances in drilling technologies-including horizontal drilling and hydraulic fracturing-have made vast reserves of natural gas economically recoverable in the US. Responsible development of America's oil and gas resources offers important economic, energy security, and environmental benefits. Hydraulic fracturing is a well stimulation technique used to maximize production of oil and natural gas in unconventional reservoirs, such as shale, coalbeds, and tight sands. During hydraulic fracturing, specially engineered fluids containing chemical additives and proppant are pumped under high pressure into the well to create and hold open fractures in the formation. These fractures increase the exposed surface area of the rock in the formation and, in turn, stimulate the flow of natural gas or oil to the wellbore. As the use of hydraulic fracturing has increased, so have concerns about its potential environmental and human health impacts. Many concerns about hydraulic fracturing center on potential risks to drinking water resources, although other issues have been raised. In response to public concern, the US Congress directed the US Environmental Protection Agency (EPA) to conduct scientific research to examine the relationship between hydraulic fracturing and drinking water resources. This study plan represents an important milestone in responding to the direction from Congress. EPA is committed to conducting a study that uses the best available science, independent sources of information, and a transparent, peer-reviewed process that will ensure the validity and accuracy of the results. The Agency will work in consultation with other federal agencies, state and interstate regulatory agencies, industry, non-governmental organizations, and others in the private and public sector in carrying out this study. Stakeholder outreach as the study is being conducted will continue to be a hallmark of our efforts, just as it was during the development of this study plan. The overall purpose of this study is to elucidate the relationship, if any, between hydraulic fracturing and drinking water resources. More specifically, the study has been designed to assess the potential impacts of hydraulic fracturing on drinking water resources and to identify the driving factors that affect the severity and frequency of any impacts. Based on the increasing development of shale gas resources in the US, and the comments EPA received from stakeholders, this study emphasizes hydraulic fracturing in shale formations. Portions of the research, however, are also intended to provide information on hydraulic fracturing in coalbed methane and tight sand reservoirs. The scope of the research includes the hydraulic fracturing water use lifecycle, which is a subset of the greater hydrologic cycle. For the purposes of this study, the hydraulic fracturing water lifecycle begins with water acquisition from surface or ground water and ends with discharge into surface waters or injection into deep wells. Specifically, the water lifecycle for hydraulic fracturing consists of water acquisition, chemical mixing, well injection, flowback and produced water (collectively referred to as "hydraulic fracturing wastewater"), and wastewater treatment and waste disposal.
Author: Johannes Fink
Publisher: Gulf Professional Publishing
ISBN: 0128220740
Category : Technology & Engineering
Languages : en
Pages : 356
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Book Description
Petroleum engineers continue to need cost saving and environmentally sustainable products and methods for today's hydraulic fracturing operations. Hydraulic Fracturing Chemicals and Fluid Technology, Second Edition, continues to deliver an easy-to-use manual of fluid formulations to meet specific job needs. Enhanced with more environmental aspects, this reference helps engineers and fluid specialists select and use the appropriate chemicals for any hydraulic fracturing job. New information concerning nanotechnology applications such as wellbore sealant and proppants are added to enhance operations in a sustainable manner while saving on production costs. Other updates include low recovery of fracturing water in shale, surfactants for waterless hydraulic fracturing, and expanded produced water treatment. Rounding out with updated references and patents for easy reference, Hydraulic Fracturing Chemicals and Fluid Technology, Second Edition, gives engineers a critical guide on selecting better products to boost productions while strengthening environmental enhancement and consideration. - Gain insight with new information surrounding environmental contamination and produced water treatment methods - Save on production costs with new nanoparticle-enhanced fluids and applications - Eliminate guesswork with systematic approach to fluid technology organized by project need
Author: Long D. Tran
Publisher:
ISBN: 9781321101584
Category : Hydraulic fracturing
Languages : en
Pages : 130
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Book Description
Innovations in hydraulic fracturing technology have created opportunities for petroleum and natural gas production. This technology injects water, sand, and additives to create fissures in rock formations and discharge oil and gas to the surface. The average amount of water used per well is approximately 4.4 million gallons. The large water demand and the complexities involved in wastewater treatment make this process very expensive and not sustainable as far as water use is concerned. Flexible membrane technology has not been developed to process fracking water for re-use across the U.S. The objective of this project is to compare and analyze the recovery of contaminated fracking water through different types of ultrafiltration and nanofiltration membranes. Through ultrafiltration, the hydraulic fracture water is pretreated to remove the majority of total suspended solids (TSS) and turbidity. The water flux, chemical oxygen demand (COD), turbidity, TSS, and salt level concentrations are then measured. Afterwards, the treated water is filtered using flat sheet nanofiltration membranes of Osmonics and SEPA Membrane Element Cell Equipment. The process is repeated with different membranes to determine optimal operating pressure, flux, and salt rejection. This study reveals that the highest performing membranes could remove 70 percent of divalent ions with an 85 percent water recovery in the permeate. Therefore, the process reduces significant amount of wastewater, which is disposed to the deep wells injection. With these promising results, our process can recycle water for reuse in hydraulic fracturing while minimizing environmental damage due to water contamination. Through this project, we are confident that hydraulic fracking can become a more sustainable process.
Author: United States. Environmental Protection Agency
Publisher:
ISBN:
Category : Drinking water
Languages : en
Pages : 0
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Book Description
This final report provides a review and synthesis of available scientific information concerning the relationship between hydraulic fracturing activities and drinking water resources in the United States. The report is organized around activities in the hydraulic fracturing water cycle and their potential to impact drinking water resources. The stages include: (1) acquiring water to be used for hydraulic fracturing (Water Acquisition), (2) mixing the water with chemical additives to prepare hydraulic fracturing fluids (Chemical Mixing), (3) injecting the hydraulic fracturing fluids into the production well to create fractures in the targeted production zone (Well Injection), (4) collecting the wastewater that returns through the well after injection (Produced Water Handling), and (5) managing the wastewater via disposal or reuse methods (Wastewater Disposal and Reuse). EPA found scientific evidence that hydraulic fracturing activities can impact drinking water resources under some circumstances. The report identifies certain conditions under which impacts from hydraulic fracturing activities can be more frequent or severe.
Author: Kuan Huang
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
Shale gas extraction based on unconventional horizontal drilling and hydraulic fracturing for nature gas recovery from low-permeable gas formation has greatly increased oil and gas production around the country in the past ten years. However, it also triggered environmental and human health concerns due to its impact on water resources, especially on disinfection by-product (DBP) formation upon chlorination. Increased bromide levels have been reported in several surface waters in Pennsylvania that accounted for the increased formation of DBPs in downstream water utilities. However, the effects of non-bromide ions in production wastewater at extremely high levels are vaguely defined. In this study, we investigated the effects of production wastewater, with bromide and non-bromide species, on the formation of DBPs when spiked into surface waters at different percentages. Results showed that the spiking of production wastewater dramatically increased DBP formation and shifted its speciation towards brominated species. Brominated DBPs increased at the expenses of chlorinated species as more production wastewater was added, while mixed bromochloro-DBPs rose and then declined. However, the introduction of debrominated production wastewater led to increased formation of some chlorinated DBP species in selected surface water and wastewater. As the spiking percentage of debrominated production wastewater increased, the chlorinated DBP species increased. The study of individual cations suggested that their contributions to DBP formation followed a sequence of magnesium > calcium > barium at high spiking percentage due to the different catalytic effects of their chelates with organic precursors. The study of anions suggested that the discharge of treated production wastewater containing elevated sulfate may further enhance DBP formation. The significance of this study lies in the fact that while bromide concerns from production wastewater are important, non-bromide species also contributed to DBP formation. The gas production wastewater management decision should consider the negative impacts from both bromide and non-bromide species to better protect drinking water resources.
