risk analysis of marine activities in the belgian part of the north sea (rama) annemie volckaert...
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Risk analysis of Marine Activities in the Belgian Part of
the North Sea (RAMA)
Annemie VolckaertDirk Le Roy
Jan-Bart CalewaertPieter De MeyerFrank Maes
Tim Fowler
Supported by the Federal Science Policy
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Goals and approach
Risk-analysis of shipping incidents with environmental damage on the Belgian part of the North Sea
Approach1. Comparison of different methods for risk
analysis 2. Identification of hazardous activities at sea3. Release assessment of marine incidents4. Description of the effects of the incidents5. Risk estimation6. Examination & recommendations to existing
contingency plans
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1. Comparison of methods
≠ quantitative and qualitative approaches
7 steps of an Environmental Risk Assessment (ERA): Problem formulation Hazard identification Release assessment Exposure assessment Consequence or Effect assessment Risk characterisation Estimation & risk evaluation
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1. Comparison of methods (2)
3 important topics: Uncertainty rating Quality assessment of input Potential gaps
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2. Identification of hazardous activities at sea Activities with environmental risk:
≠ human activities in BPNS Shipping as major
contributor: Merchant shipping Shipping related to:
Fishery Sand- and gravel extraction Dredging Military exercises Off-shore constructions Pleasure crafts/recreational
Study area: Shipping lanes BPNS (11 SA’s) Excl. Scheldt traffic Excl. Noordhinder TSS (no data)
Data period: April 2003 - March 2004
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2. Identification of hazardous activities at sea
Total 57.791 voyages (or ± 320.000 ship mov.)
40% dangerous goods (DG)
60% of DG in packaged form; 40% in bulk
74% with oil tankers, RoRo/ car carriers, containers
45% CT 7 (HNS with low environmental danger)
CT1 & CT2 mainly transported with oil/chemical tanker & container ships
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3. Release assessment
Quantitative estimation of the probability of release: Historical approach (1960-2003)
Lack of relevant spill quantity data Difference in reporting trends (underestimation)
Modelling approach MARCS model Performed by Det Norske Veritas (DNV)
Accident frequency (acc. per year) Accident spill frequency (acc. with environm. spill per
year) Cargo spill risk (tonnes spilled per year)
8 different ship types; 7 types of accidents; 10 cargo types
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3. Release assessment: Ship types
8 types ST1 Oil (crude) tankers ST2 Chemical tankers + refined ST3 Gas tankers ST4 RoRo + car carriers + Ropax ST5 Bulk carriers ST6 General cargo + reefers ST7 Containers ST8 Others + Passenger Ships
Excluded from analysis : approx. 1.5 % of data
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3. Release assessment: Cargo types
10 Classes CT1 Marine Pollutants + Bulk Cat A CT2 Crude oils CT3 Bunkers and heavy fuels CT4 other oil products CT5 Potential Marine Pollutants + Bulk Cat B & C CT6 Toxic Products (IMO-code 6.1 & 2.2) CT7 other identifiable dangerous goods or HNS CT8 dangerous goods, with insufficient product
information CT9 empty but with leftover fractions from
dangerous goods CT10 No dangerous goods
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3. Release assessment: accident types Ship-ship collision; Powered grounding (groundings which occur when
the ship has the ability to navigate safely yet goes aground);
Drift grounding (groundings which occur when the ship is unable to navigate safely due to mechanical failure);
Structural failure/ foundering whilst underway; Fire/ explosion whilst underway; Powered ship collision with fixed marine structures
such as platforms or wind turbines (similar definition to powered grounding);
Drifting ship collision with fixed marine structures such as platforms or wind turbines (similar definition to drift grounding).
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3. Release assessment (2)– Accident frequency
1.0 E-08 - 1.0 E-06
1.0 E-06 - 1.0 E-05
1.0 E-05 - 1.0 E-04
1.0 E-04 - 1.0 E-03
1.0 E-03 - 1.0 E-02
> 1.0 E-02
Total acc. freq of 14.5 acc/year
Majority powered groundings: 12 acc/yr Lane ends close to
grounding lines at ports
Ground type: soft sand/mud banks; will reverse off without reporting, in many cases
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3. Release assessment (3): Accident spill freq.
1.0 E-08 - 1.0 E-06
1.0 E-06 - 1.0 E-05
1.0 E-05 - 1.0 E-04
1.0 E-04 - 1.0 E-03
1.0 E-03 - 1.0 E-02
> 1.0 E-02
Total acc. Spill freq of 0.3 acc/year (every 3 years)
Accident type 1° powered groundings:
0.25 acc/yr (1 per 4 yr) 2° collisions: 0.03 acc/yr
Cargo type 1° CT8 (no info): 1 per 13
yr 2° CT4 (other oil): 1 per
14 yr CT2 & CT3 (crudes &
heavy fuels): 1 per 150 yr
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3. Release assessment (4): Cargo spill risk Tonnes/yr spilled
Highest risk class 8 (dangerous, no info) Total: 539 t/yr Containers: 390 t/yr
Class 1 (MP, cat A) Total: 12.3 t/yr Containers: 9.9 t/yr
Class 2 (crudes) Total: 101 t/yr Oil tankers: 101 t/yr
1.0 E-08 - 1.0 E-06
1.0 E-06 - 1.0 E-05
1.0 E-05 - 1.0 E-04
1.0 E-04 - 1.0 E-03
1.0 E-03 - 1.0 E-02
> 1.0 E-02
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4 Description of the effects of the incident Selection of two scenarios
Worst case oil: 17.000 ton/accident; crudes Worst case HNS: 8.000 ton/accident (1.000
ton/accident); acetone cyanohydrine Ecosystem approach: interactions and
processes within species, among species and between species and their abiotic environment (in stead of protect species) Benthos Fish Birds (Mammals)
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4. Description of the effects of the incident (2) Sensitivity analysis
Ecological parameters Socio-economic parameters 3 Scenarios (general, winter, summer ~
interests)
Effect analysis Exposure assessment (PEC) Consequence assessment (PNEC) Risk characterisation (PEC/PNEC)
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4a. Sensitivity analysis
Identifying sensitive area’s in the marine and coastal zone of Belgium Economical parameters Social parameters Ecological parameters
Decision support tool Aid in prevention and preparation of spills
GIS analysis
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4a. Sensitivity analysis: methodology score
Ecological Conservation 0-5 Bird, habitat, fish
cultural Landscape, heritage 0-1 physical Shoretype, currents 0-2 economic Aquaculture, fisheries,
ports, saltworks 0-3
social population 0-1 SUM of SCORES
0
5
10
15
20
25
0 2 4 6 8 10 12 14 16
class
%
Classification: High;
medium; low
Priority spill protection zones
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4a. Sensitivity analysis methodology
GIS map per parameter (data layers)
BPNS + coast as a grid of 1km x 1km cells
Per data layer score per cell f.ex. concession zone score 1
Combining data layers and adding up scores
Sensitivity map = map representing total score
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4a. Sensitivity analysis: ecological criteriaImportance Entity Number Score
(internationally standardized)
International RAMSAR sites 2 5
EC - Special Protected Areas (SPA) (in framework of habitat or bird directive)
2 (habitat)3 (bird)
5
EC - Habitat Directive Area (Natura 2000) 13 5
EC- Bird directive Area (Natura 2000) 3 5
National Marine Protected Areas (MPA) 3* 3
Strict nature reserve 0 3
National park 0 3
Regional Beach (nature) reserves 2 1
Nature reserve 1 1
Natural monument 0 1
Landscape reserve (classified landscape) 1 1
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4a. Sensitivity analysis: socio-econ. criteriaParameter Entity Score Remark
Recreation Global tourist factor (beach recreation)
3 Relative sensitivity calculation (source GAUFRE, 2005)
Garded swimming zones 1 Relative sensitivity calculation: (number/ municipality)(source GAUFRE, 2005)
Marinas 1 Relative sensitivity calculation(source MareDasm, 2002)
Fisheries Spawning sites ? No spawning area’s were identified / reported
Concentration of fish ? No specific area’s were identified / reported
Shipping Port 2
Local port 1
Anchorage areaShipping lane
0
Economical aspects Touristical value coast 2 Relative sensitivity calculation (overnight stays; rental homes/secondary residences; day tourists; employees)
(Source: Maredasm, 2002)
Aggregate extraction and windenergy at sea
1
Social aspects High population 1 (Source FOD Economie, KMO, middenstand en energie, 2005)
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Summer scenario
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Winter scenario
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Ecological impact assessment model
Physico-chemical databaseModelling
Biological databaseEcotoxicological database
Exposure assessmentPEC
Consequence assessment
PNEC or LC50
Risk characterisation
4b. Effect analysis
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4b. Effect analysis: worst case oil
Exposure assessment: 12,6 km² oil spill (MU slick
lets model) 1 mm thickness / 4 km
diameter In 13 hours Zwin
Consequence assessment: LC50 values of aromatic
components Direct loss biota: 12% - 68% Bird loss open sea: 471 Bird loss Zwin: 741
Seabirds; 2595 Water birds
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4b. Effect analysis: worst case HNS
Exposure assessment: 0,01 mg/l (critical
effect concentration = 1% loss biota)
No birds Consequence
assessment: 75 simulation days Max. concentration Ecological impact area 8.000 ton: 70% BPNS 1.000 ton: 40% BPNS
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5. Risk estimation
Frequency x consequence of event
Frequency: hazard identification & release assessment (quantitative)
Consequence: direct loss (qualitative ~ hazardous characteristics
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5. Risk estimation (2)
OilTan ChemTank GasTank RoRo Bulk GenCar Contain Other
SA1 2 12 16 8 54 36 2 54
SA2 2 12 16 8 36 36 2 54
SA3 1 6 12 4 18 18 1 27
SA4 3 18 24 12 81 54 3 81
SA5 2 6 12 2 27 27 2 27
SA6 2 6 12 2 27 27 6 27
SA7 1 6 18 4 18 27 1 27
SA8 8 18 36 4 54 24 4 36
SA9 27 27 54 6 81 81 27 36
SA10 3 27 54 24 54 54 9 54
SA11 3 18 24 12 81 36 3 81
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5. Risk estimation (3) the highest risk in the high risk subareas SA3, SA5, SA6,
SA7 characterised by sandbank formations and/or presence of harbour (intense shipping traffic is not the determining factor);
in the first place oil tankers and container ships form a high risk for almost the total BPNS due to the fact that they transport the most hazardous cargo types and that in case of a spill accident high quantities of dangerous goods are spilled at sea (related to high transported quantities);
secondly also chemical tankers and RoRo traffic is risk full, in particular in the high risk subareas, respectively due to the hazardous characteristics of chemical tankers (notice the low spill quantity) and a medium frequency and quantity of accidents with RoRo ships;
the risk from bulk, general cargo and other (passenger ships & other ships) transport is rather low.
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6. Contingency planning: an evaluation
1. Framework Legal / competences / International context / … Situating new developments
2. Required elements of a good plan ? Other contingency plans; IMO and other
guidelines …
3. Examination of elements identified in 2. Gaps, weaknesses, improvements, …
4. Recommendations
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6. Recent developments contingency planning New Royal Decree (BOJ 15 March 2006)
Focus on land-based planning Some new concepts and definitions
Coastguard Structure better coordination between competent
authorities at sea Working group “rampenplan Noordzee”
Active review of the BNSDP Operational plans
Oiled birds Clean beaches Pollution combating interventions at sea
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6. Conclusions and recommendations BNSDP has served purpose in the past
New situation thorough revision recommended definitions / coverage: applies to? / target audience overviews: nat. & intern. legal frame / competences relationship with other plans (operational, land-based,
…) equipment: spill-size / platform or vessel / study
capacity Area assessment – RAMA, GAUFRE, BWZEE, … Information and communication …
Operational pollution intervention plan Good first step – clear and straightforward further elaborated Main focus on oil ! Separate plans?
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Thank you for your attention.
Any questions?