Post on 18-Nov-2014
1
Introduction to Reservoir Stimulation
Kellyville Training Center
2
Well Stimulation
Stimulation is a chemical or mechanical method of increasing flow capacity to a well.
Dowell Schlumberger is mainly concerned with three methods of stimulation:
1. Wellbore Clean-up : “ Fluids not injected into formation”• a. Chemical Treatment• b. Perf Wash
2. Matrix Treatment : “ Injection below frac pressure”• a. Matrix Acidizing• b. Chemical Treatment
3. Fracturing “ Injection above frac pressure”• a. Acid Frac• b. Propped Frac
3
Stimulation Techniques
Restores Flow Capacity:• Wellbore Clean-up• Matrix Treatment
These procedures are performed below fracture pressure.
Create New Flow Capacity:• Hydraulic Fracturing (Acid and Sand)
These procedures are performed above fracture pressure.
4
Areas Where Reduction in Flow Capacity May Occur
1. Wellbore:• Scale Damage• Sand Fill• Plugged Perforations• Paraffin Plugging• Asphalt Deposits• Etc.
2. Critical Matrix:• Drilling Mud Damage• Cement Damage• Completion Fluids• Production• Native Clays/Fines
5
WELLBORE
Primary Purpose :
Restore flow capacity by removing restrictive damage to fluid flow in the wellbore.
Methods :• Mechanical• Chemical Treatment• Acidizing Treatment
6
Critical Matrix What is It?
• The area of formation that is 3' to 5' from the wellbore. Why is it critical?
r % Pressure Drop (Drainage Radius) P (psi) P/ft (Pe - P) (Pe - Pwf) * 100
(Pe) 2,000 ft 5,000 0.07 psi/ft 01,000 ft 4,934 2.5100 ft 4,719 10.850 ft 4,654 1.3 psi/ft 13.320 ft 4,568 16.610 ft 4,503 6.5 psi/ft 19.05 ft 4,439 21.53 ft 4,391 23.32 ft 4,000 850 psi/ft 24.81 ft 3,150 27.3
(Pwf) 0 ft 2,000 1,150 psi/f 100
7
Major Goals of Matrix Treatment
1. Restore Natural Permeability• By Treating the Critical Matrix
2. Minor Stimulation
3. Leave Zone Barrier Intact
8
Matrix Acidizing 1. Sandstone:
• Major Effects: Dissolves/Disperses Damage Restores Permeability
• Minor Effects: Minor Stimulation
2. Limestone:• Major Effects:
Enlarge Flow Channels/Fractures Disperse Damage by Dissolving Surrounding Rock Creation of Highly Conductive Wormholes
9
Applications For Matrix Treatment
High Permeability Formation with Damage.
Unproppable Formations.
Treating Limitations.
Thick Zones.
To Supplement Fracturing.
10
Low Permeability Reservoir Increase well productivity by creating a highly conductive path
compared to the reservoir permeability.
The fracture will extend through the damaged near wellbore area. The fracture size is limited to two criteria :
• Drainage Radius• Cost
Fracturing is : Pumping fluid into the formation above fracture pressure.
Damage
XL
XL = Fracture half length
11
Darcy’s Equation
Oil Well : Oil Well : Gas Well : Gas Well :
q = kh (Pe - Pwf)
141.2 µ (In rerw + S)
q = kh (Pe2 - Pwf2)
1424 µzT (In rerw + S)
12
Skin (s) The total Skin (ST) is the combination of mechanical and pseudo-skins. It
is the total skin value that is obtained directly from a well-test analysis.
Mechanical Skin:• Mathematically defined as an infinitely thin zone that creates a steady-
state pressure drop at the sand face.• S > 0 Damaged Formation• S = 0 Neither damaged nor stimulated• S < 0 Stimulated formation
Pseudo Skin:• Includes situations such as fractures, partial penetration, turbulence,
and fissures. The Mechanical Skin is the only type that can be removed by stimulation.
13
Skin Example Pseudo Skin:
• Producing at high rates --> turbulence• Collapsed tubing, perforations• Partial penetration / Partial perforation• Low Perforation Density (Shots/ft)• Etc.
Formation Damage:• Scales• Organic/Mixed Deposits• Silts & Clays• Emulsions• Water Block• Wettability Change
14
Example An oil well produces 57 B/D under the following reservoir and producing
conditions:
k = 10 md
h = 50 ft
ßo = 1.23 res bbl/stb
µo = 0.6 cp
Pr = 2,000 psi
Pwf = 500 psi
rw = .33 ft
re = 1,320 ft
What is the Skin Factor?
Is there potential for Stimulation?
15
INTRODUCTION TO MATRIX TREATMENT
16
Formation Damage
Damage Definition :
• Partial or complete plugging of the near wellbore area which reduces the original permeability of the formation.
• Damage is quantified by the skin factor ( S ).
17
Types of Formation Damage Emulsions
Wettability Change
Water Block
Scale Formation
Organic Deposits
Mixed Deposits
Silt & Clay
Bacterial Slime
18
Areas of Damage
Scales
Organic deposits
Silicates, Aluminosilicates
Emulsion
Water block
Wettability change
Tubing Gravel Pack Perforations Formation
19
Emulsions Definition:
• Formed by invasion of filtrates into oil zones or mixing of oil-based filtrates with formation brines.
• Any two immiscible fluids
Keys to Diagnosis:• Sharp decline in production• Water breakthrough• Production of solids• Fluid samples• Injection of inhibitors
Treatment:• Surfactants • Mutual solvents
20
Wettability Change Definition:
• Oil wetting of rock from hydrocarbon deposits or adsorption of an oleophilic (attracts oil) surfactant from treating fluid.
Keys to Diagnosis: (Normally difficult to diagnose)• Rapid production decline• Casing leak• Water breakthrough• Water coning• Decrease or disappearance of gas
Treatment:• Mutual solvent followed by water-wetting surfactant.
21
Water Block Definition:
• Caused by an increase in water saturation near the wellbore which decreases the relative permeability to hydrocarbons.
Keys to Diagnosis: • Rapid oil or gas production decline• Casing leak• Water breakthrough• Water out• Abnormally high water cut through lower perforations
Treatment:• Mutual solvents or surfactants
22
Scale Formation Definition:
• Scales are precipitated mineral deposits. Scale deposition occurs during production because of lower temperatures and pressures encountered in or near the wellbore.
Keys to Diagnosis: • Sharp drop in production• Visible scale on rods/tubing• Water breakthrough
Treatment:• Carbonate (Most Common)
HCl, Aqueous Acetic• Sulfate
EDTA NARS
• Chloride 1 - 3% HCl
IronIron» HCl with various iron control agentsHCl with various iron control agents
SilicaSilica» Mud AcidMud Acid
23
Keys to Diagnosis of a SampleFloats in H2O 2
Soluble in H O2
Soluble in HCl
No
Soluble in hot HCl
No
No
Iron Oxide
Magnetic
Magnetite FeCo
Soluble in U42
Soluble in hot HCl/HF
3
No
No
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
No
Organic
NaCl (probably)
Odor of rotten eggs
Silica Base (sand/clay)
SrSO (slow) BaSO (very slow)
CO Evolves
FeCO
Fe (CO ) CaCO
MgCO Ca(SO ) slowly soluble (also soluble in U42)
FeS (possible)
3
2 3 3
3
3
4 2
2
4
4
24
Scales : Inorganic Mineral Deposits
Types of Scale
Usual Occurrence
Treating Fluids Comments
Carbonates CaCO3 HCl Very Common
Sulfates
CaSO •2H O (gypsum)
BaSO /SrSO
EDTA
EDTA
Common
Rare
Chlorides NaCl H O/HCl Gas Wells
IronFe S
Fe O
HCl + EDTA
HCl + Sequestering Agent
CO /H S Possible Produced
Silica SiO HF Very Fine
Hydroxides Mg/Ca(OH) HCl
4
4 4
3
2
2
2
2
22
2
25
Organic Deposits Definition:
• Organic deposits are precipitated heavy hydrocarbons (parrafins or asphaltenes). They are typically located in the tubing, perforations and/or the formation.
• The formation of these deposits are usually associated with a change in temperature or pressure in or near the wellbore during production.
Keys to Diagnosis: • Sharp decline in production• Visual parrafin on rods and pump• Operator is "hot oiling"
Treatment:• Aromatic Solvents (Xylene, Toluene)• Mutual Solvents
26
Keys to Diagnosis of Actual Organic Deposit
Floats in water Yes Organic Deposit
1. Burns evenly with clean flame Yes Paraffin/wax
No
Black sooty flame Yes Asphaltene
2. Soluble in pentane Yes Paraffin
No
Asphaltene
3. Soluble in Toluene/Xylene Yes Paraffin/ Asphaltene
27
Silts & Clays Definition:
• Damage from silts and clays includes the invasion of the reservoir permeability by drilling mud and the swelling and/or migration of reservoir fines.
• Keys to Diagnosis: • Sharp drop in production• Lost circulation during drilling• Production tests• ARC tests
Treatment:• HCl: Carbonate Reservoirs• HF Systems: Sandstone• Quaternary Amine Polymers (L55)• Cationic Surfactant (M38B)• Fusion (Clay Acid)
28
Bacterial Slime
Definition:• Anaerobic bacteria grows downhole without oxygen up
to 150°F. Bacteria may chemically reduce sulfate in a reservoir to H2S.
Treatment:• M91 (Bleach+Caustic soda)
29
Sources of Formation Damage Drilling
Cementing
Perforating
Completion and Workover
Gravel Packing
Production
Stimulation
Injection Operations
30
31
Successful Matrix Treatment
REQUIREMENTS :
• Enough Treating Fluid Volume
• Correct Reactive Chemicals
• Low Injection Pressure
• Total Zone Coverage
32
INTRODUCTION TO FRACTURING
33
Applications For Hydraulic Fracturing
If wells natural permeability is low ( Ke < 10 md )
Natural production is below economic potential
Skin By-Pass “ HyperSTIM “ or higher permeability and soft formations.
The injected fluid is pumped at a rate above the fracture pressure of the reservoir to create cracks or fractures within the rock itself.
34
Hydraulic Fracturing Treatment
Primary Purpose :• To increase the effective wellbore area by creating a
fracture of length XL whose conductivity is greater than that of the formation.
Dimensionless Conductivity ( Fcd ) = Kf Wf / Ke Xf
Two Methods :• Sand Frac• Acid Frac
35
Propped Frac & Acid Frac
1/2"open fractureduring job
fracture tends to closeonce the pressure has been
released
sand used to prop thefrac open
acid etched frac walls
36
Propped Fracture Optimization
Optimize the reservoir deliverability by balancing fracture characteristics and reservoir properties
Analyze the effect of production systems :• Perform => Nodal Analysis
Determine the pumping parameters :• DataFRAC
Tailor the fracturing fluid and proppant to the reservoir Determine treatment size (Fluid & proppant amount)
• Calculate XLand FCD
Calculate the benefit of the treatment => $• FracNPV
37
Acid Fracture
Bottom hole pressure above fracturing pressure
Acid reacts with the formation
Fracture is etched
Formation must retain integrity without fracture collapse
38
Hydraulic Fracturing Accomplishes:
Creates Deep Penetrating Fractures to :
Improve productivity Interconnect formation permeability Improve ultimate recovery Aid in secondary recovery Increase ease of injectivity
• A hydraulic Fracture has to be cost effective to the customer.
39
Fracture Penetration is influenced by: FORMATION CHARACTERISTICS :
• Type • Hardness• Permeability• Zone Height “ Presence of Barriers “• Drainage Radius
FRAC FLUID CHARACTERISTICS :• Base Fluid• Viscosity• Volume• Pump Rate• Fluid Loss
41
Orientation Of The Fracture
The fracture will extend perpendicular to the axis of the least stress.
• X - Y - Z Coordinate :Overburden Pressure
Least Principal Stress
Favored Fracture Direction
(i.e. Vertical Fracture)
42
Vertical Or Horizontal Fracture
Rule-Of-thumb :• Frac Gradient < 0.8 psi / ft --------> Vertical Fracture• Frac Gradient > 1.0 psi / ft --------> Horizontal Fracture
Vertical fracture plane is perpendicular to earth’s surface due to overburden stress being too great to overcome
Horizontal fracture with a pancake likegeometry. Usually associated withshallow wells of less than 3,000 ft. depth
43
Fracture Propagation Models
KGD
• XL < h
PKN
• XL > h
Radial
• XL = h/2
44
Rock Mechanical Behavior Young’s Modulus :
• E =
Poisson’s Ratio : L1 - L2 / L1
d1 - d2 / d1D1
D2
45
Rock Mechanical Behavior
Young’s Modulus :• E =
Poisson’s Ratio : L1 - L2 / L1
d1 - d2 / d1
46
Fracture Width
W = ( Q L) 1/4 PKN E
W = ( QL2)1/4 KGD EH
= Viscosity of fluid
• Q = Injection Rate • H = Gross Height
• L = Xf
• E = Young’s Modulus
47
Net Present Value FracNPV BENEFITS :
• Design lowest cost job• Realize full production rate potential• Forecast post treatment decline• Study impact of treatment variables
APPLICATION :
• Select optimum XL, W & proppant type
• Aid in determining whether or not to fracture a new well• Determine size of production equipment• Evaluation of the fracture treatment based on well performance
48
FracNPV
52
0 100 200 300 400 500
Hydraulic Half-Length - ft
-100000
0
100000
200000
300000
400000
500000
600000
Ne
t Pre
se
nt V
alu
e -
$(U
S)
YF120LG
ClearFRAC (3
Production time 1 year
Fluid Type
FracCADE*
*Mark of Schlumberger
Net Present Value
Well XXXX1235.5//1249.508-26-1997
Design
58
Conclusion Three Types of Stimulation :
• Wellbore Clean-up• Matrix Treatment• Hydraulic Fracturing
Well Candidate Selection :• What is it ?• How does Dowell Schlumberger use it ?• What are some of the tools associated with it ?
NPV• What is it ?• How can it be used to design a treatment ?• How does the output benefit our customers and us ?