Modelling ductile failure propagation during blowdown under localized jet fire attack

Abstract

A rigorous mathematical model for determining the failure mode of pressurized vessels exposed to localized jet-fire impingement during rapid depressurization or blowdown is presented. Accounting for the thermodynamic trajectory of the two-phase hydrocarbon inventory, the method of separation of variables for non-homogenous heat conduction is used to determine the transient radial temperature gradient across the heated section of the vessel wall. The resulting temperature profile in conjunction with the appropriate vessel geometry stress equations are then used to simulate the transient triaxial thermal and pressure stress yield propagation. Failure is assumed to occur when any of the total stresses exceed the ultimate tensile strength of the vessel wall material. The application of the model to a real cylindrical vessel under localized jet fire attack in the vapour space reveals catastrophic failure involving rapid propagation of a tear along the major axis of the vessel wall due to severe thermal stress loading.

Keywords

risk analysis thermal response stress analysis blowdown

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References

Mahgerefteh

Falope

G. B.O.

Oke

A. O.

Modeling blowdown of cylindrical vessels under fire attack. AIChE J., 2002, 48, 401–410.

API Recommended Practice 521. Guide for Pressure-Relieving and Depressuring Systems, 3rd edition, 19, 1990 (American Petroleum Institute (API)).

Sumathipala

U. K.

Hadjisophocleous

G. V.

Aydemir

N. U.

C. M.

Sousa

A. C. M.

Steward

F. R.

Venart

J. E. S.

Fire engulfment of pressure-liquefied gas tanks: Experiments and modeling. Fire Hazard and Fire Risk Assessment, 1992, 1150, 100–111.

Kielec

D. J.

Birk

A. M.

Analysis of fire-induced ruptures of 400-L propane tanks. J. Press. Vessel Technol, 1994, 119, 365–372.

Birk

A. M.

Modelling the response of tankers to external fire impingement. J. Hazard. Mater., 1988, 20, 197–206.

Beynon

G. V.

Cowley

L. T.

Small

L. M.

Williams

Fire Engulfment of LPG tanks: HEATUP, a predictive model. J. Hazard. Mater., 1988, 20, 227–236.

Hunt

D. L.M.

Ramskill

P. K.

The behavior of tanks engulfed in fire—the development of a computer program. IChemE Symposium Series, 1985, 93, 71–79.

Ramskill

P. K.

A description of the ‘ENGULF’ computer codes—codes to model the thermal response of an LPG tank either fully or partially engulfed by fire. J. Hazard. Mater., 1988, 20, 177–182.

Overa

S. J.

Stange

Salater

Depressurisation of temperatures and flare rates during depressurisation and fire. Proceedings of the 72nd GPA Annual Convention, 1994, 235–242.

10.

Venart

J. E. S.

Sumathipala

U. K.

Steward

F. R.

Sousa

A. C. M.

Experiments on the thermohydraulic response of pressure liquefied gases in externally heated tanks with pressure relief. Plant/Operations Progress, 1988, 7, 139–147.

11.

Sumathipala

U. K.

Steward

F. R.

Venart

J. E. S.

The experimental thermodynamics of small break loss of coolant accidents. Proceedings, International ENS/ANS Conference on Thermal Reactor Safety, Avignon, France, 1988, 1103–1112.

12.

Moodie

Cowley

L. T.

Denny

R. B.

Small

L. M.

Williams

Fire engulfment tests on a 5 tonne LPG tank. J. Hazard. Mater., 1988, 20, 55–62.

13.

Birk

A. M.

Cunningham

M. H.

The boiling liquid expanding vapour explosion. J. Loss Prev. Process Ind., 1994, 7 (6), 474–80.

14.

Birk

A. M.

Scale effects of fire exposure of pressure-liquefied gas tanks. J. Loss Prev. Process Ind., 1995, 8, 275–284.

15.

Mahgerefteh

Wong

S. M. A.

A numerical blowdown simulation incorporating cubic equations of state. Comp. & Chem. Eng., 1999, 23 (9), 1309–1317.

16.

Mahgerefteh

Saha

Economou

I. G.

Fast numerical simulation for full bore rupture of pressurised pipelines. AIChE J., 1999, 45 (6), 1191–1201.

17.

Mahgerefteh

Saha

Economou

I. G.

Modeling fluid phase transition effects on the dynamic behaviour of ESDV. AIChE J., 2000, 46 (5), 997–1006.

18.

Peng

D. Y.

Robinson

D. B.

A new two-constant equation of state. Ind. Eng, Chem. Fundam., 1976, 15, 59–64.

19.

de Rueck

K. M.

Craven

R. J.B.

Elhassan

A. E.

Transport properties of fluids, IUPAC, 1996 (Cambridge University Press, Cambridge).

20.

Assael

M. J.

Trusler

J. P.M.

Tsolakis

T. F.

Thermophysical properties of fluids: An introduction to their prediction, 1996 (Imperial College Press, London).

21.

Michelsen

M. L.

Multi-phase isenthalpic and isentropic flash algorithms. Fluid Phase Equil, 1987, 33, 13–21.

22.

Michelsen

M. L.

The isothermal flash problem. Part I. Stability. Fluid Phase Equil, 1982, 9, 1–19.

23.

Michelsen

M. L.

The Ishothermal flash problem. Part II. Phase-split calculation. Fluid Phase Equil., 1982, 9, 21–32.

24.

Ozisik

M. N.

Heat Conduction, 1980 (John Wiley & Sons, New York).

25.

Timoshenko

S. P.

Goodier

J. N.

Theory of Elasticity, 1987 (McGraw-Hill, New York).

26.

Popov

E. P.

Engineering mechanics of solids, 1999 (Prentice Hall, New Jersey).

27.

Kent

C. H.

Thermal stresses in spheres and cylinders produced by temperatures varying with times. Trans ASME, 1994, 18, 185–192.

28.

Brandes

E. A.

(Editor) Smithells Metals Reference Book, 1983 (Butterworths, London).

29.

Nichols

(Editor) Pressure Vessels Design, 1971 (Butterworths, London).

30.

Haque

M. A.

Richardson

S. M.

Saville

Chamberlain

Shirvill

Blowdown of pressure vessels. II. Experimental validation of computer model and case studies. Trans IChemE Part B: Process Safety Environmental Protection, 1992, 70, 10–17.

31.

Falope

G. B.O.

Mahgerefteh

Modeling transient stresses in spherical vessels during blowdown under fire attack. AIChE J. (in press).

32.

Incropera

F. P.

De Witt

D. P.

Fundamentals of Heat and Mass Transfer, 4th edition, 1996 (John Wiley and Sons, New York).