Post on 08-Mar-2018
SPE Distinguished Lecturer Program
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Society of Petroleum Engineers Distinguished Lecturer Programwww.spe.org/dl 1
Hydraulic Fracturing Materials: Application Trends & Considerations
Harold D. BrannonBJ Services Company
Society of Petroleum Engineers Distinguished Lecturer Programwww.spe.org/dl
2
Outline• Hydraulic Fracturing• Fracturing Material Functions• Fracturing Fluids & Additives
– Recent trends– Emerging Technologies
• Proppants– Recent trends– Emerging Technologies
• Summary3
What is hydraulic fracturing?• A process of placing proppant into fractures created in oil
and gas zones to increase the flow of oil or natural gas to the wellbore.
• Fractures are created by pumping fluids at high pressures and rates.
• Proppant is added to the fluid, which when pumping has ceased, ‘props’ the fractures to keep them open.
• The propped fractures provide highly conductive flow paths for the hydrocarbons to reach the wellbore
Hydraulic Fracturing
• World-wide application– ~ 100,000 wells annually– 90% of gas wells– 70% of oil wells
• Predominantly used for low-permeability reservoirs– High permeability applications increasing
• Complex operation– Requires knowledge and high competence in a number
of areas of engineering and science
Fracturing Fluids• Functions:
– Transmit hydraulic pressure to fracture– Transport proppant into the fracture
• Desired Characteristics– Non-hazardous, environmentally benign– Compatible with reservoir– Low wellbore friction pressure– Control leak-off to the formation– Transport & suspend proppant until closure– Non-damaging to fracture conductivity
6
Fracturing Systems & Trends• Aqueous
– Slickwater– Linear polymer-viscosified fluids– Crosslinked polymer gels– Viscoelastic surfactant gels
• Non-aqueous – Gelled oil– Nitrogen gas– Emulsions– Gelled methanol
Slick Water
Linear Gels
Crosslinked Gels
VES
Non-Aqueous Fluids
% of worldwide fracturing treatments BJ Services Company, 2009 7
Aqueous Systems
• Strong transition to slickwater and low viscosity, non-crosslinked fluids driven by the increased development of ultra-low permeability reservoirs (from 21% to >50% of N. American treatments)
Crosslinked Gels
Linear GelsSlick Water
Slick Water
Linear GelsCrosslinked Gels
1998
2009
8
% of US Fracturing treatments
Slickwater
• Water with acrylamide polymers
– PAA polymers reduce pipe friction
– Minimal polymer loading with low system costs
– Low viscosity
– Poor fluid efficiency, proppant transport
– Minimal fracture damage potential9
Complex Network Fracturing • Slickwater is the preferred fluid for naturally fractured shale reservoirs (ultra low perm.)
• Massive volume of low viscosity fluids facilitates development of a large and complex fracture network
• Poor proppant transport and suspension capabilities typically necessitate high injection rates
Guar Polymer Systems
– Cost effective, used widely in food stuffs and cosmetics
– May be processed to enhance fluid properties in harsh environments
– Improved guar products yield much lower insoluble residues and higher viscosity per unit
11
• Guar is the most commonly used gelling agent for viscosifying fracturing fluids
-- Naturally occurring polymer extracted from guar seeds
Guar pods, seeds, splits, and powderModern Fracturing (2007)
Crosslinked Polymer Systems• Crosslinking a polymer exponentially increases
the fluid viscosity– 10 to 60 cP increased to 100 to > 1000 cP
• Crosslinking : – Increases treating friction – Improves fluid efficiency (leak-off control)– Improves proppant transport– Increases gel damage potential
Crosslinked Gel Vortex Closure, progression over 3 minutes, Modern Fracturing (2007) 12
Guar Polymer Systems
High viscosityShear stableGood proppant transport Good retained conductivity
Zirconium-X-linked20 – 60 pptg CMHPGBHSTs to 375oFpH 4 -10
Borate-X-linked 20 – 50 pptg GuarBHSTs to 300oFpH 9 – 12
Moderate viscosityShear sensitiveGood proppant transport Fair retained conductivity
Linear Guar10 – 20 pptgBHSTs to 200oFpH 6-8
Low viscosityShear stablePoor proppant transport Best retained conductivity
Modern Fracturing (2007) 13
Gelled Aqueous Systems
• Linear gel usage increased, mostly due to unconventional reservoirs applications in lieu of slickwater
• Crosslinked, high viscosity guar systems using low polymer loadings replaced up to 65% of previous crosslinked guar system usage
• Viscoelastic surfactant gels (VES), usage increased to 4% of non-slickwater, gelled aqueous fluids
Crosslinked Gels
Linear Gels
Linear Gels
Conv. X-linked
Gels
VES
Low Loading X-linked Gels
1998
2008
14
Low Guar Crosslinked Fluids
• High viscosity yield per unit of polymer• Provides for up to 50%
polymer loading reduction• Lower friction pressure
• Reduced loading results in less gel damage
• Higher regained conductivity
• Improved fluid recovery and cleanup• Lower Flow Initiation Stress (FIS)
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• Viscoelastic surfactants used to gel fluids– No polymers
• Operationally simple
• Components multi-functional– No need for biocide, buffer,
clay control, etc.
• Poor leakoff control
• Good transport
• Non-damaging• Recovered fluids recyclable
Viscoelastic Surfactant Fluids
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• High Density Fracturing Fluids• Bottomhole treating pressures > 15,000 psi• Crosslinked guar in high density brine• Reduces surface treating pressure & HHP
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@ 20,000 ft, 12.5 ppg brine provides for a 4,300 psi reduction in treating pressure
Emerging Fluid Technologies
• Ultra High Temperature Systems:
• BHSTs from 350oF – > 500oF• Synthetic polymer-based• Stable > 2 hrs at 450oF
• Provides for execution of job sized sufficiently for proper stimulation without the requirement of a “cool-down” pad
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Emerging Fluid Technologies
Emerging Fluid Technologies• Ultra-high Quality Foams
– +/- 95 Quality foam (N2 , CO2 , or mixed gas)
– Favorable environmental impact characteristics • Minimized impact on water supply• Foamers chemically benign
– Most applicable for low-pressured reservoirs• Additional gas volumes enhance recovery
– Non-damaging, 100% regained conductivity
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• Associative Thickener Systems– Non-polymer gelled fluid
• Relies on ionic ‘association’ of additives• Attributes similar to VES systems
– Thickening initiated by elevated temperature,• Viscosity begins to increase at 150oF • Rheologically stable to >250oF
– Non-damaging• 100% regained conductivity
– Environmentally benign
Emerging Fluid Technologies
Emerging Fluid Technologies• Environmentally Acceptable Chemistries
– Governmentally driven• Most active in US & Europe• Growing activities globally
– In US, applies to all frac appls
– Replacement characteristics• Performance functionality• Safe to handle• Low toxicity• Biodegradable
21
TargetedMaterials
Diesel & BTEXBacteriacidesClay controlSurfactantsNon-emulsifiersCorrosion inhibitors
Proppants
Ottawa Frac Sand
Low Density Ceramic
Brown Frac Sand
• Proper placement creates a conductive pathway from the reservoir to the wellbore
• Proppant is the only material which is intended to remain in the reservoir after a hydraulic fracturing treatment completion and cleanup
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Proppant Characteristics• Transportability
– particle density, size, shape – fluid velocity, viscosity, density
• Particle strength @ in-situ stresses– particle composition, size, shape
• Fracture conductivity – particle concentration, size, packing
23
Proppant Usage Trends
010,00020,00030,00040,00050,00060,00070,00080,00090,000
100,000110,000120,000130,000140,000150,000160,000170,000180,000190,000200,000
1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010
Tons
White Sand Brown Sand Resin/Ceramics/Speciality Total
Data courtesy of BJ Services Company USA
1999 - 2009: 660% increase in proppant usage
2002 – 2008: Sand has increased from 70% to 85% of total
Proppant Size Usage Trends
010,00020,00030,00040,00050,00060,00070,00080,00090,000
100,000110,000120,000130,000140,000150,000160,000170,000
1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010
Tons
White 20/40 White 16/30White 12/20 White 30/50White 40/70 & 30/70 White 100 MeshWhite 20/50 Total
1999 - 2009: 20/40 reduced from >90% to <50% of total usage
2004 - 2008: 30/50, 40/70, & 70/140 usage increased > 1,000%
Data courtesy of BJ Services Company USA
Proppant ConductivityConductivity (Cf = kf w) is a measure of the
fracture’s ability to transmit fluids
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• kf = fracture permeability• w = fracture width• k = reservoir permeability • Xf = fracture length
f
fFD kX
wkC
Cf D contrasts the transmissibility of the propped fracture to that of adjacent reservoir
Fracture Conductivity• A key design parameter for successful
stimulation
• Subject to change over the life of the well due to:– Proppant particle failure– Effective stress increase with production – Damage: gel residuals, embedment, fines– Non-Darcy or multiphase flow
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Proppant Selection
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Most typically based upon propped fracture conductivity at reservoir closure pressure
• Higher proppant concentrations generally provide greater conductivities due to the increased imparted width. The exception is partial proppant
monolayers
• Strong industry trend driven by increased unconventional resource development to use of smaller diameter proppants at low concentrations
Fracture Conductivity
29
30
Effect of Proppant Concentration
Modern Fracturing (2007)
Effect of Proppant Size
31Modern Fracturing (2007)
(Penny (Stim-Lab), 1992)
Fracture conductivity damage from crosslinked gelled fracturing fluids with breakers typically ranges from 20 - 90%
Residual Fluid Damage
32
Gel Damage Regained Conductivity vs. Breaker Concentration
0
10
20
30
40
50
60
70
80
90
100
% R
egai
ned
Con
duct
ivity
VES, 2%
Slickwater
B/HE Guar, 25 ppg
Linear Guar,
40#
Zr/CMG, 2
0 pptg
B/Guar, 40 pptg
Zr/CMHPG, 3
0 pptg
No Breaker Low Breaker Moderate Breaker High Breaker
33Data courtesy of Stim-Lab Consortia
• Reduced density proppants (ultra-lightweight) to improve proppant transport and placement for enhanced conductive fracture area.
Emerging Proppant Technologies
34
0 50 100
150
200
250
300
350
Transport Distance, ft.
Bauxite, 3.50, 40/70 Sand, 2.65, 40/70 LWC, 2.55, 40/70Sand, 2.65, 70/140 ULWP-1.06, 30/80
SPE
106312Elliptical Geom.(3:1), 0.25”
width, Injection Rate
1 bbl/ft, 3 cp
Transport of ULW 1.05 ASG Proppant 14/40 mesh; 4 cP slick water
20 mesh Sand@ 1,000 psi
“Emerging” Proppant Technology
Partial monolayers exhibit open areas around and between particles increasing the conductivity of the propped fracture
36Adapted from SPE-1291-G, 1959
Conductivity vs. Closures Stress Proppant Packs vs. Partial Monolayer
100
1000
10000
1000 2000 3000 4000 5000 6000Closure Stress (psi)
Con
duct
ivity
(md-
ft)
ULW-1.05, 0.02 ppsf 20/40 Sand @ 2.0 ppsf 20/40 Sand @ 1.0 ppsf20/40 Sand @ 0.5 ppsf 40/80 LWC @ 0.5 ppsf
37SPE-119385
• Stronger, more thermally stable, ultra-lightweight proppants to improve transport and conductivity
– First generation: 200oF / 5,000 psi– Current generation: 240oF / 7,000 psi– Next generation: 275oF / 8,000 psi
Emerging Proppant Technologies
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• Proppants with improved ability to mitigate non-Darcy flow issues common to high rate and/or multi-phase production
• Materials to mitigate effects of proppant pack diagenesis (scaling)
Emerging Proppant Technologies
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Emerging Fracturing Technology• Production Assurance
– Particulates containing controlled-release additives deployed in fracturing treatments for long-term flow assurance via inhibition of scale, salt, paraffin, or asphaltene deposition
– Reside within proppant pack and slowly release production chemicals to maintain the conductivity of proppant packs and to prolong the time to needed intervention (> 3 years protection experienced)
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• Ultra-high strength proppants for deep well applications (+20 kpsi)
• High strength proppants with reduced abrasive properties to protect hardware in high rate, low viscosity fluid applications
Emerging Proppant Technologies
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• “Smart” proppant to allow mapping of conductive fractures
– Live or activatable particles dispersed within proppant pack
– Once placed, can be located within reservoir for identification of the conductive fracture geometry and azimuth.
• Fracture width can be estimated from frequency
Emerging Proppant Technology
45
Summary
• Hydraulic fracturing of unconventional reservoirs has resulted in significant shifts in the fracturing materials employed, most significantly to lower viscosity fluids and smaller proppant size.
47
Summary• Evolution of fracturing materials is ongoing
to effectively satisfy the developing needs of unconventional resources stimulation
• Innovation of fracturing materials is occurring to effectively fracture in the ever- increasing extremes of reservoir thermal and stress
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Hydraulic Fracturing Materials: Application Trends & Considerations
Harold D. BrannonBJ Services Company
Society of Petroleum Engineers Distinguished Lecturer Programwww.spe.org/dl
49
Thank You !
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