Triaxial Stress Analysis

Casing Design Triaxial stress analysis

 Aguieb Larbi Ben Yagoub Mohammed Prepared by: Tan Nguyen

Casing Design

Combined Stress Effects (Triaxial

stress analysis)

The fundamental basis of casing design is that if stresses in the pipe wall exceed the yield strength of the material, a failure condition exists. Hence the yield strength is a measure of the maximum allowable stress. To evaluate the pipe strength under combined loading conditions, the uniaxial yield strength is compared to the yielding condition.

The most widely accepted yielding criterion is based on the maximum

distortion

energy

theory,

which

is

known

as

the

Huber-Von-Mises Theory. This theory states that if the triaxial stress exceeds the yield strength, a yield failure is indicated. Note that the triaxial stress is not a true stress. It is a theoretical value that allows a generalized three-dimensional stress state to be compared with a uniaxial failure criterion (the yield strength).

Casing Design



s  

VME

1 2



s  

z

 s  t



2





s  

t

Where s

Y

 – minimum yield stress, psi

s

VME

 – triaxial stress, psi

VME: Von Mises Equivalent s

z,

t,

s

s

 – axial tress, tangential

r 

stress, and radial stress, psi

 s  r



2





s  

r

 s  z



2

 s  Y

 

1

Casing Design

Setting the triaxial stress equal to the yield strength and solving equation (1) give the results: s  

t 

 pi

s  

Y 

3  s   z

2

 pi   1  s   z  pi         1   4   s  Y    2   s  Y   

(2)

pi  –internal pressure s

t

 – tangential stresses

(3)

This equation is for  the ellipse of plasticity. Combining this eq. and the equation of tangential stresses together and let r = r i, will give the combinations of internal pressure, external pressure and axial stress that will result in a yield strength mode of failure.

Casing Design

 As

axial

increases In

tension and

contrast,

critical

increases, the

the as

critical

burst-pressure

critical collapse-pressure decreases. the

burst-pressure

axial compression increases, the decreases

collapse-pressure increases.

and

the

critical

Casing Design

Example Compute the nominal collapse pressure rating for 5.5 ’’,  N-80 casing with a nominal wall thickness of 0.476 ’’  and a nominal weight per foot of 26 lbf/ft. In addition, determine the collapse pressure for in-service conditions in which the pipe is subjected to a 40,000 psi axial tension stress and a 10,000 psi internal pressure. Assume a yield strength mode of failure. Solution

For collapse pressure rating, r = r i then eq. (3) becomes



s  

t 



 pi ro  ri 2

2

  2 p r 

2 e o

ro  r i 2



2

 pi ro  ri

  pi

s  

t

s

s  

t

2

r  r i



t   p i

s  

s  

Y 

s  

Y 

2

  pi

Y 

Y 

t  

2 e o

s  

  pi

s  

  2 p r 

2 o

Y 

s

2

pi

  2r o2    pi  pe       2 2   ro  r i    s  Y      25.52    pi  pe      2  2   5.5  4.548      80,000   

pi



pe

12,649





pe

12,649

Casing Design

 z  

s  

From eq. (2) with

pi



0

we have

s  

Y 

pi

t  

s  

1

 

s  

Y 

pe



12,649

 p e



 

1

12,649 psi

For in-service conditions of

pi

t  

s  



s  

Y 

 z  

s  

pi



s  

Y 

10,000

z =

s

40,000 psi and p i = 10,000 psi

pe



12,649

40,000



10,000

80,000



0.625

Solving eq. (14) gives s   

t 

s  

Y 

 p e



pi



10,000



12,649

16,684 psi

pe



0.5284