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D&P May 2014 Drilling Part
Casing Design
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Casing Design
Why Run Casing?
Types of Casing Strings
Classification of Casing
Wellheads
Burst, Collapse and Tension
Example
Effect of Axial Tension on Collapse Strength
Example
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Casing Design
Why run casing?
1. To prevent the hole from caving in
2. Onshore - to prevent contamination of
fresh water sands
3. To prevent water migration to
producing formation
What is casing? Casing
Cement
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Casing Design
4. To confine production to the wellbore
5. To control pressures during drilling
6. To provide an acceptable environment for
subsurface equipment in producing wells
7. To enhance the probability of drilling to total
depth (TD)
e.g., you need 14 ppg mud to control a lower zone,
but an upper zone will fracture at 12 lb/gal.
What do you do?
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Types of Strings of Casing
1. Drive pipe or structural pile
{Gulf Coast and offshore only}
150-300 below mudline.
2. Conductor string. 100 - 1,600 (BML)
3. Surface pipe. 2,000 - 4,000 (BML)
Diameter Example
16-60 30
16-48 20
8 5/8-20 13 3/8
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Types of Strings of Casing
4. Intermediate String
5. Production String (Csg.)
6. Liner(s)
7. Tubing String(s)
7 5/8-13 3/8 9 5/8
Diameter Example
4 1/2-9 5/8 7
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Example Hole and String Sizes (in)
Structural casing
Conductor string
Surface pipe
IntermediateString
Production Liner
Hole Size
30
20
13 3/8
9 5/8
7
Pipe Size
36
26
17 1/2
12 1/4
8 3/4
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Example Hole and String Sizes (in)
Structural casing
Conductor string
Surface pipe
IntermediateString
Production Liner
250
1,000
4,000
Mudline
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Classification of CSG.
1. Outside diameter of pipe (e.g. 9 5/8)
2. Wall thickness (e.g. 1/2)
3. Grade of material (e.g. N-80)
4. Type to threads and couplings (e.g. API LCSG)
5. Length of each joint (RANGE) (e.g. Range 3)
6. Nominal weight (Avg. wt/ft incl. Wt. Coupling)
(e.g. 47 lb/ft)
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s
e
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Length of Casing Joints
RANGE 1 16-25 ft
RANGE 2 25-34 ft
RANGE 3 > 34 ft.
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Casing Threads and Couplings
API round threads - short { CSG }
API round thread - long { LCSG }
Buttress { BCSG }
Extreme line { XCSG }
Other
See Halliburton Book...
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API Design Factors (typical)
Collapse 1.125
Tension 1.8
Burst 1.1
Required
10,000 psi
100,000 lbf
10,000 psi
Design
11,250 psi
180,000 lbf
11,000 psi
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Normal Pore Pressure Abnormal Pore Pressure
0.433 - 0.465 psi/ft gp > normal
Abnormal
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X-mas Tree Wing Valve
Choke Box
Master
Valves
Wellhead
Hang Csg. Strings
Provide Seals
Control Production
from Well
Press. Gauge
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Wellhead
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Wellhead
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Casing Design
Burst: Assume full reservoir pressure all along the
wellbore.
Collapse: Hydrostatic pressure increases with depth
Tension: Tensile stress due to weight of string is highest at
top
STRESS
Tension
Burst
Collapse
Collapse
Tension
Depth
Burst
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Casing Design - Collapse
Collapse pressure is affected by axial stress
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Casing Design - Tension
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Casing Design - Burst
(from internal pressure)
Internal Yield Pressure for pipe Internal Yield Pressure for
couplings Internal pressure leak resistance
p p Internal Pressure
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Casing Design - Burst
Example 1
Design a 7 Csg. String to 10,000 ft.
Pore pressure gradient = 0.5 psi/ft
Design factor, Ni=1.1
Design for burst only.
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Burst Example
1. Calculate probable reservoir pressure.
psi 000,5 ft000,10*ft
psi5.0pres
2. Calculate required pipe internal yield
pressure rating
psi 500,51.1 *000,5N *pp iresi
Ni = API Design Factor for BURST = 1.1
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Example
3. Select the appropriate csg. grade and wt.
from the Halliburton Cementing tables:
Burst Pressure required = 5,500 psi
7, J-55, 26 lb/ft has BURST Rating of 4,980 psi
7, N-80, 23 lb/ft has BURST Rating of 6,340 psi
7, N-80, 26 lb/ft has BURST Rating of 7,249 psi
Use N-80 Csg., 23 lb/ft
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23 lb/ft
26 lb/ft
N-80
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Collapse Pressure
The following factors are important:
The collapse pressure resistance of a pipe depends on the axial
stress
The API Design Factor
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Casing Design
Collapse pressure - with axial stress
1.
P
A
2/12
P
APPA
Y
S5.0
Y
S75.01YY
YPA = yield strength of axial stress
equivalent grade, psi
YP = minimum yield strength of pipe, psi
SA = Axial stress, psi (tension is positive)
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Example 3
Determine the collapse strength for a 5 1/2 O.D., 14.00 #/ft,
J-55 casing under axial load of 100,000 lbf
The axial tension will reduce the collapse pressure
as follows:
P
p
A
2
p
APA Y
Y
S5.0
Y
S75.01Y
psi
Area
FS AA 820,24
012.55.54
000,100
22
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Example 3 contd
The axial tension will reduce the collapse
pressure rating to:
psi 216,38
000,55000,55
820,245.0
000,55
820,2475.01Y
2
PA
Here the axial load decreased the J-55
rating to an equivalent J-38.2 rating
P
p
A
p
APA Y
Y
S
Y
SY
5.075.01
2
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Example 3 - contd
We shall be using API Tables to correct for the
effect of axial tension on collapse strength of
casing.
The Halliburton Cementing Tables list the
collapse resistance of 5 -in, 14.00 lb/ft J-55
casing at 3,120 psi.
The axial tension in this case would derate the
collapse strength to about 2,550 psi.
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Casing Design Example
Example Problem
API Design Factors
Worst Possible Conditions
Effect of Axial Tension on Collapse Strength
Iteration and Interpolation
Design for Burst, Collapse and Tension
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Casing Design Example
Design a 9 5/8-in., 8,000-ft combination
casing string for a well where the mud wt.
will be 12.5 ppg and the formation pore
pressure is expected to be 6,000 psi.
Only the grades and weights shown are
available (N-80, all weights). Use API
design factors.
Design for worst possible conditions.
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Casing Design - Solution
Before solving this problem is it necessary to
understand what we mean by Design Factors and worst possible
conditions.
API Design Factors
Design factors are essentially safety factors that allow us to
design safe, reliable casing
strings. Each operator may have his own set
of design factors, based on his experience,
and the condition of the pipe.
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Casing Design
In PETE 661, well use the design factors recommended by the API
unless otherwise
specified.
These are the API design Factors:
Tension and Joint Strength: NT = 1.8
Collapse (from external pressure): Nc= 1.125
Burst (from internal pressure): Ni = 1.1
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Casing Design
What this means is that, for example, if we
need to design a string where the maximum
tensile force is expected to be 100,000 lbf,
we select pipe that can handle 100,000 * 1.8
= 180,000 lbf in tension.
Note that the Halliburton Cementing Tables
list actual pipe strengths, without safety
factors built in.
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Casing Design
Unless otherwise specified in a particular
problem, we shall also assume the following:
Worst Possible Conditions
1. For Collapse design, assume that the
casing is empty on the inside (p = 0 psig)
2. For Burst design, assume no backup fluid on the outside of
the casing (p = 0 psig)
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Casing Design
Worst Possible Conditions, contd
3. For Tension design,
assume no buoyancy effect
4. For Collapse design,
assume no buoyancy effect
The casing string must be designed to stand up to the
expected conditions in burst, collapse and tension.
Above conditions are quite conservative. They are also
simplified for easier understanding of the basic concepts.
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Casing Design - Solution
Burst Requirements (based on the expected pore pressure)
The whole casing string must be capable of
withstanding this internal pressure without failing in
burst.
psi600,6P
1.1*psi000,6
FactorDesign*pressureporeP
B
B
Dep
th
Pressure
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Casing Design - Solution
Collapse Requirements
For collapse design, we start at the bottom of
the string and work our way up.
Our design criteria will be based on
hydrostatic pressure resulting from the 12.5
ppg mud that will be in the hole when the
casing string is run, prior to cementing.
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Casing Design
Collapse Requirements, contd
severe less are
tsrequiremen collapse the hole the up Further
.bottom the at d'reqpsi 850,5P
125.1*000,8*5.12*052.0
factor design*depth*weight mud*052.0P
c
c
Dep
th
Pressure
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Casing Design
Reqd: Burst: 6,600 psi Collapse: 5,850 psi
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Casing Design
Note that two of the weights of N-80 casing
meet the burst requirements, but only the
53.5 #/ft pipe can handle the collapse
requirement at the bottom of the hole (5,850
psi).
The 53.5 #/ft pipe could probably run all the
way to the surface (would still have to check
tension), but there may be a lower cost
alternative.
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Casing Design
To what depth might we
be able to run N-80, 47
#/ft? The maximum
annular pressure that this
pipe may be exposed to,
is:
psi 231,4125.1
760,4
factordesign
pipe of pressure CollapsePc
Dep
th
Pressure
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Casing Design
First Iteration
At what depth do we see this pressure (4,231
psig) in a column of 12.5 #/gal mud?
ft 509,65.12*052.0
231,4
5.12*052.0
Ph
h*5.12*052.0P
c1
1c
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Casing Design
This is the depth to which the pipe
could be run if there were
no axial stress in the pipe
But at 6,509 we have (8,000 - 6,509) = 1,491 of 53.5 #/ft pipe
below us.
The weight of this pipe will reduce the
collapse resistance of the 47.0 #/ft pipe!
8,000
6,509
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Casing Design
Weight, W1 = 53.5 #/ft * 1,491 ft
= 79,769 lbf
This weight results in an axial
stress in the 47 #/ft pipe
psi 877,5in 13.572
lbf 769,79
area end
weightS of
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Casing Design
The API tables show that the above
stress will reduce the collapse resistance
from 4,760 to somewhere between
4,680 psi (with 5,000 psi stress)
and 4,600 psi (with 10,000 psi stress)
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Casing Design
Interpolation between these values shows
that the collapse resistance at 5,877 psi
axial stress is:
psi 148,4125.1
666,4P
psi 666,4)600,4680,4(*)000,5000,10(
)000,5877,5(680,4P
cc1
1c
With the design factor,
2112
11c1P PP
SS
SSP
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Casing Design
This (4,148 psig) is the pressure at a
depth
Which differs considerably from the
initial depth of 6,509 ft, so a second
iteration is required.
ft 382,65.12*052.0
148,4h2
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Casing Design
Second Iteration
Now consider running the 47 #/ft
pipe to the new depth of 6,382 ft.
psi 378,6in 572.13
lbf 563,86S
lbf 563,865.53*)382,6000,8(W
22
2
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Casing Design
Interpolating again,
This is the pressure at a depth of
psipcc 140,4600,4680,4*5000
5000378,6680,4
125.1
12
ft 369,65.12*052.0
140,4h3
21
12
11c1
D.F.
1P PP
SS
SSP
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Casing Design
This is within 13 ft of the assumed value. If
more accuracy is desired (generally not
needed), proceed with the:
Third Iteration
psi 429,6572.13
259,87S
lbf 259,875.53*)369,6000,8(W
'369,6h
3
3
3
Pcc3 = ?
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Casing Design
Third Iteration, contd
2
3
140,4
)600,4680,4(*000,5
000,5429,6680,4
125.1
1
cc
cc
Ppsi
Pthus
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Casing Design
Third Iteration, contd
This is the answer we are looking for, i.e.,
we can run 47 #/ft N-80 pipe to a depth of
6,369 ft, and 53.5 #/ft pipe between 6,369
and 8,000 ft.
Perhaps this string will run all the way to the
surface (check tension), or perhaps an even
more economical string would include some
43.5 #/ft pipe?
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Casing Design
At some depth the 43.5 #/ft pipe would be
able to handle the collapse requirements,
but we have already determined that it will
not meet burst requirements.
!NO
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N-80 53.5 #/ft
N-80 47.0 #/ft
N-80 43.5 #/ft?
Depth = 5,057? 5,066? 5,210?
Depth = 6,369 6,369 6,382 6,509
8,000
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Tension Check
The weight on the top joint of casing
would be
With a design factor of 1.8 for tension, a
pipe strength of
weightactual 602,386
)/#5.53* 631,1()/#0.47* 369,6(
lbs
ftftftft
required is lbf 080,695602,386*8.1
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Tension Check
The Halliburton cementing tables give a
yield strength of 1,086,000 lbf for the pipe
body and a joint strength of 905,000 lbf for
LT & C.
surface to OK is ft/# 0.47
