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T.Moan.26.03.2007 1
Development of
Accidental Collapse Limit State Criteria for Offshore Structures
byTorgeir Moan
Norwegian University of Science and Technology
Risk Acceptance and RiskCommunicationStanford, March 26-27, 2007
T.Moan.26.03.2007 2
Outline
Critical event
• Introduction
• Accident experiences
• Safety management at large in theoffshore industry
• Accidental Collapse Limit State
• Concluding remarks
ULS:RC/γR > γDDC + γLLC + γEEC
FLS:D=Σni/Ni ≤ allowable D
T.Moan.26.03.2007 3
Oil and gas are dominant sources of energy; 20 % of the oil and gas is produced in the ocean environment
- affects ”world” economy
Introduction
Regulatory requirements: - National Regulatory bodies;
(MMS, HSE, PSA (NPD)- Industry : API, NORSOK,…- Class societies/IACS- IMO/ISO/(CEN)
Safety- oil and gas represents energy withlarge potential accidentconsequences
- operating in a demanding environment- loss of reputation could also be anexpensive consequence of accidents
T.Moan.26.03.2007 4
Safety with respect to - Fatalities- Environmental damage- Property damage
associated with failuere modes such as:Capsizing/sinking
Structural failure
Mooring system failure
Unavailability of Escapeways and Evacuation means (life boats….)
Introduction (continued)
T.Moan.26.03.2007 5
Technical-physicalpoint of view- Capsizing or total loss of
structural integritycommonly develops in a sequence of events
Human andorganizationalpoint of view- Codes- Design, fabrication and
use of individual structures
Accident Experiences
CriticaleventFault tree Event tree
- Fatalities- Environmental
damage- Property
damage
Safety: absence of accidents or failures
T.Moan.26.03.2007 6
Failure or accident due to ”natural hazards”
Severe damage caused by hurricane Lilli in the Gulf ofMexico
Technical-physical causes:Wave forces exceeded the structuralresistance
Human – organizational factors:State of engineering practice (codes)
Errors and omissions during the design(fabrication) phases
- relating to assessment of- wave conditions or load calculation- strength formulation- safety factors
Should the platforms have been stengthenedif improved state of the art knowledge becameavailable later ?
T.Moan.26.03.2007 7
Accident experiences for offshore platforms
Num
ber o
f acc
iden
ts p
er
1000
pla
tform
yea
rs
T.Moan.26.03.2007 8
Safety management• Design criteria
- ULS, FLS (and ALS)• QA/QC of the engineering (design)
process• QA/QC of the as-fabricated structure• QA/QC during operation
(inspection of structuralresistance , monitoring ofloads)
• Event control ofaccidental events
• Evacuation and Escape
• Direct design for damage tolerance (ALS)
ULS:RC/γR > γDDC + γLLC + γEECFLS:D=Σni/Ni ≤ allowable D
P,F P,FA
E
- Leak- Dispersion- Ignition
- Leak- Dispersion- Ignition
T.Moan.26.03.2007 9
Causes of structural failures and risk reduction measures
None- Research & DevelopmentUnknown phenomena
Quantitative riskanalysis
- Improve skills, competence, self-checking (for life cycle phase: d, f, o)
- QA/QC of engineering process (for d)- Direct ALS design – with adequate
damage condition (for f, o)- Inspection/repair of the structure
(for f, o)
Gross error or omissionduring life cycle phase:- design (d)- fabrication (f)- operation (o)
Structural reliabilityanalysis
- Increase safety factors or marginsin ULS, FLS;
- Improve inspection of the structure (FLS)
Less than adequate safety margin to cover “normal”inherent uncertainties.
Quantitative method
Risk Reduction MeasureCause
T.Moan.26.03.2007 10
Safety management – the ALS check
• Alternative principles for design against accidental actions:- design the structure locally to resist the action- accept local damage and design the structure against progressive collapse (in the manner which is relevant in connection with abnormal strength)
• Structures should be designed to ensure that small damages do not develop into disproportionately large consequences–loss of overall structural integrity–loss of buoyancy/stability
Specifieddamage
T.Moan.26.03.2007 11
Accidental Collapse Limit State relating to structural strength (NPD,1984, later NORSOK)
• Estimate the damage due to accidental event (damage, D or action, A) at an annual probability of 10-4
- apply risk analysis to establish design accidental loads
• Survival check of the damaged structure as a whole, considering P, F and environmental actions ( E ) at a probability of 10-2
Target annual probability of total loss: 10-5 for each type of hazard
P, F
A
P, F
A
P, FP, F
E
A
T.Moan.26.03.2007 12
Failure modes - Hazards (accidental actions)Instability:
Hazards
Structuraldamage onsubmergedparts, includingexplosion in column
Unintended pressure or ballast/cargo distribution
Structural failure:HazardsFire/Explosion
Fire on sea
Ship impact
Dropped objects
Mooring failure:Hazards
- Hull, mooring, risers- Safety equipment(escape ways and evacuation means)
T.Moan.26.03.2007 13
Estimating the Accidental Event
Theory based on: - accidental events originate from a small fault and develop in a sequence of
increasingly more serious events, culminating in the final event, - it is often reasonably well known how a system will respond to a certain event.
Damage or accidental load with annual probability of occurrence: P = 10-4
Need homogeneous empirical data of the order 2/p = 20 000 yearsto estimate events by empirical approach Accumulated platform years world wide:- fixed platforms: ~ 180 000- mobile units: ~ 20 000- FPSO: ~ 2 000
Account of all measures to reduce the probability and consequences of the hazards
T.Moan.26.03.2007 14
Risk indicators for large scale accidents- monitoring of incidents (near-misses)
• Blow-out related incidents- uncotrolled hydrocarbon leaks- lack of well control
• Structure related incidents- structural damage, leak, collisions, loss of mooring line..)
- ships on collision path, etc.
• Nonfunctioning barriers againstlarge scale accidents- e.g lack of detection, deluge
T.Moan.26.03.2007 15
Relevant Accidental Actions (Hazards)1 Explosion actions
(pressure, duration - impulse)scenariosexplosion mechanics probabilistic issues⇒ characteristic loads for design
2 Fire loads(thermal action, duration, size)
3 Ship impact actions (impact energy, -geometry)
4 Dropped objects 5 Accidental ballast6 Unintended pressure7 Abnormal Environmental actions8 Environmental actions on platform
in abnormal position
T.Moan.26.03.2007 16
Release of Gas and/or Liquid
Release of Gas and/or Liquid
No IgnitionNo Ignition
Immediate Ignition
Immediate Ignition FireFire
Formation of Combustible
Fuel-Air Cloud(Pre-mixed)
Formation of Combustible
Fuel-Air Cloud(Pre-mixed)
Ignition(delayed)Ignition
(delayed)Gas
ExplosionGas
Explosion
No damageNo damage
Damage toPersonnel
and Material
Damage toPersonnel
and Material
FireFire
Fireand
BLEVE
Fireand
BLEVE
Explosions & FiresExplosion is a process where combustion of premixed gas cloud is causing rapid increase of pressure
Fires is a slower combustion process
Implication of simultanous occurence of explosion and fire: Explosion can occur first and damage the fire protection beforethe fire occurs
T.Moan.26.03.2007 17
Probabilistic SimulationsFor example: explosion overpressure
(given type, I of acidental action)
FLACS PROBLAST
Dispersion AnalysisGas leak location and directionGas leak rateEnvironmental conditions
Explosion AnalysisIgnition locationGas cloud location and size
Monte Carlo SimulationProbabilistic scenario definitionOverpressure definition
OVERPRESSURE EXCEEDANCE DATA
1 .0 0 E-0 6
1 .0 0 E-0 5
1 .0 0 E-0 4
1 .0 0 E-0 3
1 .0 0 E-0 2
0 .0 0 .5 1 .0 1 .5 2 .0
P r e s s u r e [ b a r ]
St o ichio met r ic maxInho mo g eneo us maxR isk analys isSt o ichio met r ic averag e
Histogram of overpressure at each location (j)based upon different scenarios (k)
(i)jkA
T.Moan.26.03.2007 18
Abnormal strength (damage)
- generic values for specific types of structures based on consideration of the vulnerability of the structural components.
Examples: 1) slender braces in mobile drilling platforms
(semi-submersibles) due to their vulnerability to ship impacts and fatigue.
2) Catenary mooring line3) Tether in tension-leg platforms
Abnormal degradation due to fatigue or corrosion
T.Moan.26.03.2007 19
FE Analysis of damage and survival of the damaged platformValidation• To be based on full
scale experiments, laboratory tests
• For the use in a design project, the accuracy of predictions is to be identified.
Application of Methodology• Topside structure
on a jacket platform
0 20 40 60 80 1000
0.1
0.2
0.3
0.4
0.5
0.6
0.7
DISPLACEMENT [mm]
PRE
SSU
RE
[N
/mm
2]
Experiment Analysis
Laboratory experiments with corrugated panels
Courtesy:J. Czujko, 2001
T.Moan.26.03.2007 20
Framework for Risk-based Design against Accidental actions
][]|[]|[)( )(
,
)( ijk
kj
ijkFSYS APADPDFSYSPiP ∑ ⋅⋅=
probability of damaged system failure under relevant F&E actions
probability of damage, D given Ajk
(i) (decreased by designing against large Aj
(i))
probability of accidental action at location (j) and intensity (k)
(i)jkP A⎡ ⎤⎣ ⎦ is determined by risk analysis while the other probabilities
are determined by structural reliability analysis.
[ ]P FSYS | D Is determined by due consideration of relevant action and their correlation with the haazard causing the damage
For each type ofaccidental action
T.Moan.26.03.2007 21
[ ] (i) (i)FSYS jk jk
jk
P (i) P FSYS| D P D| A P A⎡ ⎤ ⎡ ⎤= ⋅ ⋅⎣ ⎦ ⎣ ⎦∑
Procedure for determining the characteristic accidental action (overpressure) on different components (j) of a given platform, can be determined as:
- Establish exceedance diagram for the load on each component- Allocate a portion (pi) of 10-4 probability to each area, and determine
the Qc for each component corresponding to the probability, pi - Determine the characteristic load for each component from the
relevant load exceedance diagram and reference probability.
-The characteristic value for each type of accidental action refers to a probability of exceedance of 10-4 .for the platform as a whole.
- In view of additive character of the PFSYS(i)
- the exceedance probability level relevant for each location (k) is taken to be a portion of 10-4 for each location.
Characteristic value of the accidental action at each relevant location
T.Moan.26.03.2007 22
- A goal-based approach is needed/practiced for new design concepts - (new function, layout,…)
• deepwater production platforms (spar, TLP, semi, FPSO)
- Future challenges relating e.g. to arctic oil and gas operations require a Goal-based Approach
- Design accidental actions tend to be more prescriptive when:
• experiences are accumulated• after accidents
From Prescriptive to Goal-basedto Prescriptive Approach
T.Moan.26.03.2007 23
Typical Explosion Loads for Design
Explosion scenario
Structural component
Overpressure (barg)
Duration Impulse (kPa s)
Deck girder (30%) 0.3-0.5 0.1 <1.4-2.0 Process area Process roof 0.2 0.3 1;3
Export riser area
0.5
Central blast wall 0.3-0.7 0.2-0.4 1.5-2.5 Wellbay area Upper deck 0.2 0.3 1.7
Note: goal-setting approach tends to become prescriptive
Significant experiences about Explosion Actions for design for commonly occuring cases
T.Moan.26.03.2007 24
CONCLUSIONS
The main cause of accidents of offshore structures is human and organizational errors and omissions – resulting in- abnormal strength- accidental actions
Besides introducing measures to limit occurrence of errors by QA/QC etc, a direct quantitative design for robustness has been introduced in NPD/NORSOK offshore codes
The Accidental Collapse Limit state Design check introducedin NORSOK is a two–step procedure
estimate damage due to accidental actions with annual prob. of 10-4
check survival of damaged structure subjected to relevant functional and environmental actions
- the necessary methods for structural analysis to determine loacal damage and system survival, have been developed
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