SPECIFIC STABILITY REQUIREMENTS FOR RO-RO PASSENGER SHIPS
as referred to in Article 6
1. In addition to the requirements of Regulation II-1/B/8 of the SOLAS Convention relating to watertight subdivision and stability in damaged condition, all ro-ro passenger ships referred to in Article 3(1) shall comply with the requirements of this Annex.
1.1. The provisions of Regulation II-1/B/8.2.3 shall be complied with when taking into account the effect of a hypothetical amount of sea water which is assumed to have accumulated on the first deck above the design waterline of the ro-ro cargo space or the special cargo space as defined in Regulation II-2/3 assumed to be damaged (hereinafter referred to as "the damaged ro-ro deck"). The other requirements of Regulation II-1/B/8 need not be complied with in the application of the stability standard contained in this Annex. The amount of assumed accumulated sea water shall be calculated on the basis of a water surface having a fixed height above:
(a) the lowest point of the deck edge of the damaged compartment of the ro-ro deck; or
(b) when the deck edge of the damaged compartment is submerged then the calculation is based on a fixed height above the still water surface at all heel and trim angles;
as follows:
0,5 m if the residual freeboard (fr) is 0,3 m or less,
0,0 m if the residual freeboard (fr) is 2,0 m or more, and
intermediate values to be determined by linear interpolation, if the residual freeboard (fr) is 0,3 m or more but less than 2,0 m,
where the residual freeboard (fr) is the minimum distance between the damaged ro-ro deck and the final waterline at the location of the damage in the damage case being considered without taking into account the effect of the volume of assumed accumulated water on the damaged ro-ro deck,
1.2. When a high-efficiency drainage system is installed, the administration of the flag State may allow a reduction in the height of the water surface.
1.3. For ships in geographically defined restricted areas of operation, the administration of the flag State may reduce the height of the water surface prescribed in accordance with point 1.1 by substituting such height of the water surface by the following:
1.3.1. 0,0 m if the significant wave height (hs) defining the area concerned is 1,5 m or less;
1.3.2. the value determined in accordance with paragraph 1.1 if the significant wave height (hs) defining the area concerned is 4,0 m or above;
1.3.3. intermediate values to be determined by linear interpolation if the significant wave height (hs) defining the area concerned is 1,5 m or more but less than 4,0 m,
provided that the following conditions are fulfilled:
1.3.4. the flag State administration is satisfied that the defined area is represented by the significant wave height (hs) which is not exceeded with a probability of more than 10 %; and
1.3.5. the area of operation and, if applicable, the part of the year for which a certain value of the significant wave height (hs) has been established are entered on the certificates.
1.4. As an alternative to the requirements of paragraph 1.1 or 1.3, the flag State administration may exempt application of the requirements of paragraph 1.1 or 1.3 and accept proof, established by model tests carried out for an individual ship in accordance with the model test method, which appears in the Appendix, justifying that the ship will not capsize with the assumed extent of damage as provided in Regulation II-1/B/8.4 in the worst location being considered under paragraph 1.1, in an irregular seaway, and
1.5. reference to acceptance of the results of the model test as an equivalence to compliance with paragraph 1.1 or 1.3 and the value of the significant wave height (hs) used in the model tests shall be entered on the ship's certificates.
1.6. the information supplied to the master in accordance with Regulations II-1/B/8.7.1 and II-1/B/8.7.2, as developed for compliance with Regulations II-1/B/8.2.3 to II-1/B/8.2.3.4, shall apply unchanged for ro-ro passenger ships approved according to these requirements.
2. For assessing the effect of the volume of the assumed accumulated sea water on the damaged ro-ro deck in paragraph 1, the following provisions shall prevail:
2.1. a transverse or longitudinal bulkhead shall be considered intact if all parts of it lie inboard of vertical surfaces on both sides of the ship, which are situated at a distance from the shell plating equal to one-fifth of the breadth of the ship, as defined in Regulation II-1/2, and measured at right angles to the centreline at the level of the deepest subdivision load line;
2.2. in cases where the ship's hull is structurally partly widened for compliance with the provisions of this Annex, the resulting increase of the value of one fifth of the breadth of it is to be used throughout, but shall not govern the location of existing bulkhead penetrations, piping systems, etc., which were acceptable prior to the widening;
2.3. the tightness of transverse or longitudinal bulkheads which are taken into account as effective to confine the assumed accumulated sea water in the compartment concerned in the damaged ro-ro deck shall be commensurate with the drainage system, and shall withstand hydrostatic pressure in accordance with the results of the damage calculation. Such bulkheads shall be at least 2,2 m in height. However, in case of a ship with hanging car decks, the minimum height of the bulkhead shall be not less than the height to the underside of the hanging deck when in its lowered position;
2.4. for special arrangements such as, e.g., full-width hanging decks and wide side casings, other bulkhead heights may be accepted on the basis of detailed model tests;
2.5. the effect of the volume of the assumed accumulated sea water need not be taken into account for any compartment of the damaged ro-ro deck, provided that such a compartment has on each side of the deck freeing ports evenly distributed along the sides of the compartment complying with the following:
2.5.1. A >= 0,3 l
where A is the total area of freeing ports on each side of the deck in m2; and l is the length of the compartment in m;
2.5.2. the ship shall maintain a residual freeboard of at least 1,0 m in the worst damage condition without taking into account the effect of the assumed volume of water on the damaged ro-ro deck; and
2.5.3. such freeing ports shall be located within the height of 0,6 m above the damaged ro-ro deck, and the lower edge of the ports shall be within 2 cm above the damaged ro-ro deck; and
2.5.4. such freeing ports shall be fitted with closing devices or flaps to prevent water entering the ro-ro deck whilst allowing water which may accumulate on the ro-ro deck to drain.
2.6. When a bulkhead above the ro-ro deck is assumed damaged, both compartments bordering the bulkhead shall be assumed flooded to the same height of water surface as calculated in paragraph 1.1 or 1.3.
3. When determining significant wave height, the wave heights given on the maps or list of sea areas established by Member States in line with Article 5 of this Directive shall be used.
3.1. For ships which are to be operated only for a shorter season, the host State administration shall determine in agreement with the other country whose port is included in the ships route, the significant wave height to be used.
4. Model tests shall be conducted in accordance with the Appendix.
Appendix
Model test method
1. Objectives
In the tests provided for in paragraph 1.4 of the stability requirements included in Annex I, the ship should be capable of withstanding a seaway as defined in paragraph 3 hereunder in the worst-damage-case scenario.
2. Ship model
2.1. The model should copy the actual ship for both outer configuration and internal arrangement, in particular all damaged spaces having an effect on the process of flooding and shipping of water. The damage should represent the worst damage case defined for compliance with Regulation II-1/B/8.2.3.2 of the SOLAS Convention. An additional test is required at a level keel midship damage, if the worst damage location according to the SOLAS 90 standard is outside the range ± 10 % Lpp from the midship. This additional test is only required when the ro-ro spaces are assumed to be damaged.
2.2. The model should comply with the following:
2.2.1. length between perpendiculars (Lpp) is to be at least 3 m;
2.2.2. the hull is to be thin enough in areas where this feature has influence on the results;
2.2.3. the characteristics of motion should be modelled properly to the actual ship, paying particular attention to scaling of radii of gyration in roll and pitch motions. Draught, trim, heel and centre of gravity should represent the worst damage case;
2.2.4. main design features such as watertight bulkheads, air escapes, etc., above and below the bulkhead deck that can result in asymmetric flooding should be modelled properly as far as practicable to represent the real situation;
2.2.5. the shape of the damage opening shall be as follows:
2.2.5.1. rectangular side profile with a width according to Regulation II-1/B/8.4.1 of the SOLAS Convention and unlimited vertical extent;
2.2.5.2. isosceles triangular profile in the horizontal plane with a height equal to B/5 according to Regulation II-1/B/8.4.2 of the SOLAS Convention.
3. Procedure for experiments
3.1. The model should be subjected to a long-crested irregular seaway defined by the Jonswap spectrum with a significant wave height hs defined in paragraph 1.3 of the stability requirements and having peak enhancement factor γ and peak period Tp as follows:
3.1.1. Tp = 4[radic ]hs with γ = 3,3; and
3.1.2. Tp equal to the roll resonant period for the damaged ship without water on deck at the specified loading condition but not higher than 6[radic ]hs and with γ = 1.
3.2. The model should be free to drift and placed in beam seas (90 ° heading) with the damage hole facing the oncoming waves. The model should not be restrained in a manner to resist capsize. If the ship is upright in flooded condition, 1° of heel towards the damage should be given.
3.3. At least five experiments for each peak period should be carried out. The test period for each run shall be of such duration that a stationary state has been reached but should be run for not less than 30 minutes in full-scale time. A different wave realisation train should be used for each test.
3.4. If none of the experiments result in final inclination towards the damage, the experiments should be repeated with five runs at each of the two specified wave conditions or, alternatively, the model should be given an additional one angle of heel towards the damage and the experiment repeated with two runs at each of the two specified wave conditions. The purpose of these additional experiments is to demonstrate, in the best possible way, survival capability against capsize in both directions.
3.5. The tests are to be carried out for the following damage cases:
3.5.1. the worst damage case with regard to the area under the GZ curve according to the SOLAS Convention; and
3.5.2. the worst midship damage case with regard to the residual freeboard in the midship area if required by paragraph 2.1.
4. Survival criteria
The ship should be considered as surviving if a stationary state is reached for the successive test runs as required in paragraph 3.3, provided that angles of roll of more than 30 ° against the vertical axis, occurring more frequently than in 20 % of the rolling cycles or steady heel greater than 20 ° should be taken as capsizing events even if a stationary state is reached.
5. Test approval
5.1. Proposals for model test programmes should be submitted to the host State administration to be approved in advance. It should also be borne in mind that lesser cases of damage may create a worst-case scenario.
5.2. The test should be documented by means of a report and a video or other visual record containing all relevant information on the ship and test results.
ANNEX II
INDICATIVE GUIDELINES TO NATIONAL ADMINISTRATIONS
as referred to in Article 6(3)
PART I
APPLICATION
In line with the provisions of Article 6(3) of this Directive, these guidelines shall be used by the national administrations of Member States in the application of the specific stability requirements set out in Annex I, in so far as this is practicable and compatible with the design of the ship in question. The paragraph numbers appearing below correspond to those in Annex I.
Paragraph 1
As a first step all ro-ro passenger ships referred to in Article 3(1) of this Directive must comply with the SOLAS 90 standard of residual stability as it applies to all passenger ships constructed on or after 29 April 1990. It is the application of this requirement that defines the residual freeboard fr, necessary for the calculations required in paragraph 1.1.
Paragraph 1.1
1. This paragraph addresses the application of a hypothetical amount of water accumulated on the bulkhead (ro-ro) deck. The water is assumed to have entered the deck via a damage opening. This paragraph requires that the ship in addition to complying with the full requirements of the SOLAS 90 standard further complies with that part of the SOLAS 90 criteria contained in points 2.3 to 2.3.4 of Regulation II-1/B/8 with the defined amount of water on deck. For this calculation no other requirements of Regulation II-1/B/8 need be taken into account. For example the ship does not, for this calculation, need to comply with the requirements for the angles of equilibrium or non-submergence of the margin line.
2. The accumulated water is added as a liquid load with one common surface inside all compartments which are assumed flooded on the car deck. The height (hw) of water on deck is dependent on the residual freeboard (fr) after damage, and is measured in way of the damage (see figure 1). The residual freeboard, is the minimum distance between the damaged ro-ro deck and the final waterline (after equalisation measures if any have been taken) in way of the assumed damage after examining all possible damage scenarios in determining the compliance with the SOLAS 90 standard as required in paragraph 1 of Annex I. No account should be taken of the effect of the hypothetical volume of water assumed to have accumulated on the damaged ro-ro deck when calculating fr.
3. If fr is 2,0 m or more, no water is assumed to accumulate on the ro-ro deck. If fr is 0,3 m or less, then height hw is assumed to be 0,5 m. Intermediate heights of water are obtained by linear interpolation (see figure 2).
Paragraph 1.2
Means for drainage of water can only be considered as effective if these means are of a capacity to prevent large amounts of water from accumulating on the deck i.e. many thousands of tonnes per hour which is far beyond the capacities fitted at the time of the adoption of these regulations. Such high efficiency drainage systems may be developed and approved in the future (based on guidelines to be developed by the International Maritime Organisation)
Paragraph 1.3
1. The amount of assumed accumulated water on deck may, in addition to any reduction in accordance with paragraph 1.1, be reduced for operations in geographically defined restricted areas. These areas are designated in accordance with the significant wave height (hs) defining the area in line with the provisions of Article 5 of this Directive.
2. If the significant wave height (hs), in the area concerned, is 1,5 m or less then no additional water is assumed to accumulate on the damaged ro-ro deck. If the significant wave height in the area concerned is 4,0 m or more then the height of the assumed accumulated water shall be the value calculated in accordance with paragraph 1.1. Intermediate values to be determined by linear interpolation (see figure 3).
3. The height hw is kept constant, therefore the amount of added water is variable as it is dependent upon the heeling angle and whether at any particular heeling angle the deck edge is immersed or not (see figure 4). It should be noted that the assumed permeability of the car deck spaces is to be taken as 90 % (MSC/Circ.649 refers), whereas other assumed flooded spaces permeabilities are to be those prescribed in the SOLAS Convention.
4. If the calculations to demonstrate compliance with this Directive relate to a significant wave height less than 4,0 m that restricting significant wave height must be recorded on the vessel's passenger ship safety certificate.
Paragraphs 1.4 and 1.5
As an alternative to complying with the new stability requirements in paragraph 1.1 or 1.3 an administration may accept proof of compliance via model tests. The model test requirements are detailed in the Appendix to Annex I. Guidance notes on the model tests are contained in part II of this Annex.
Paragraph 1.6
Conventionally derived SOLAS 90 standard limiting operational curve(s) (KG or GM) may not remain applicable in cases where "water on deck" is assumed under the terms of this Directive and it may be necessary to determine revised limiting curve(s) which take into account the effects of this added water. To this effect sufficient calculations corresponding to an adequate number of operational draughts and trims must be carried out.
Note:
Revised limiting operational KG/GM Curves may be derived by iteration, whereby the minimum excess GM resulting from damage stability calculations with water on deck is added to the input KG (or deducted from the GM) used to determine the damaged freeboards (fr), upon which the quantities of water on deck are based, this process being repeated until the excess GM becomes negligible.
It is anticipated that operators would begin such an iteration with the maximum KG/minimum GM which could reasonably be sustained in service and would seek to manipulate the resulting deck bulkhead arrangement to minimisethe excess GM derived from damage stability calculations with water on deck.
Paragraph 2.1
As for conventional SOLAS damage requirements bulkheads inboard of the B/5 line are considered intact in the event of side collision damage.
Paragraph 2.2
If side structural sponsons are fitted to enable compliance with Regulation II-1/B/8, and as a consequence there is an increase in the breadth (B) of the ship and hence the vessel's B/5 distance from the ship's side, such modification shall not cause the relocation of any existing structural parts or any existing penetrations of the main transverse watertight bulkheads below the bulkhead deck (see figure 5).
Paragraph 2.3
1. Transverse or longitudinal bulkheads/barriers which are fitted and taken into account to confine the movement of assumed accumulated water on the damaged ro-ro deck need not be strictly "watertight". Small amounts of leakage may be permitted subject to the drainage provisions being capable of preventing an accumulation of water on the "other side" of the bulkhead/barrier. In such cases where scuppers become inoperative as a result of a loss of positive difference of water levels other means of passive drainage must be provided.
2. The height (Bh) of transverse and longitudinal bulkheads/barriers shall be not less than (8 x hw) metres, where hw is the height of the accumulated water as calculated by application of the residual freeboard and significant wave height ( as referred to in paragraphs 1.1 and 1.3). However in no case is the height of the bulkhead/barrier to be less than the greater of:
(a) 2,2 metres; or
(b) the height between the bulkhead deck and the lower point of the underside structure of the intermediate or hanging car decks, when these are in their lowered position. It should be noted that any gaps between the top edge of the bulkhead and the underside of the plating must be "plated-in" in the transverse or longitudinal direction as appropriate (see figure 6).
Bulkheads/barriers with a height less than that specified above, may be accepted if model tests are carried out in accordance with part II of this Annex to confirm that the alternative design ensures appropriate standard of survivability. Care needs to be taken when fixing the height of the bulkhead/barrier such that the height shall also be sufficient to prevent progressive flooding within the required stability range. This range is not to be prejudiced by model tests.
Note:
The range may be reduced to 10 degrees provided the corresponding area under the curve is increased (as referred to in MSC 64/22).
Paragraph 2.5.1
The area "A" relates to permanent openings. It should be noted that the "freeing ports" option is not suitable for ships which require the buoyancy of the whole or part of the superstructure in order to meet the criteria. The requirement is that the freeing ports shall be fitted with closing flaps to prevent water entering, but allowing water to drain.
These flaps must not rely on active means. They must be self-operating and it must be shown that they do not restrict outflow to a significant degree. Any significant efficiency reduction must be compensated by the fitting of additional openings so that the required area is maintained.
Paragraph 2.5.2
For the freeing ports to be considered effective the minimum distance from the lower edge of the freeing port to the damaged waterline shall be at least 1,0 m. The calculation of the minimum distance shall not take into account the effect of any additional water on deck (see figure 7).
Paragraph 2.5.3
Freeing ports must be sited as low as possible in the side bulwark or shell plating. The lower edge of the freeing port opening must be no higher than 2 cm above the bulkhead deck and the upper edge of the opening no higher than 0,6 m (see figure 8).
Note:
Spaces to which paragraph 2.5 applies, i.e. those spaces fitted with freeing ports or similar openings, shall not be included as intact spaces in the derivation of the intact and damage stability curves.
Paragraph 2.6
1. The statutory extent of damage is to be applied along the length of the ship. Depending on the subdivision standard the damage may not affect any bulkhead or may only affect a bulkhead below the bulkhead deck or only bulkhead above the bulkhead deck or various combinations.
2. All transverse and longitudinal bulkheads/barriers which constrain the assumed accumulated amount of water must be in place and secured at all times when the ship is at sea.
3. In those cases where the transverse bulkhead/barrier is damaged the accumulated water on deck shall have a common surface level on both sides of the damaged bulkhead/barrier at the height hw (see figure 9).
PART II
MODEL TESTING
The purpose of these guidelines is to ensure uniformity in the methods employed in the construction and verification of the model as well as in the undertaking and analyses of the model tests, while appreciating that available facilities and costs will affect in some way this uniformity.
The content of paragraph 1 of the Appendix to Annex I is self-explanatory.
Paragraph 2 - Ship model
2.1. The material of which the model is made is not important in itself, provided that the model both in the intact and damaged condition is sufficiently rigid to ensure that its hydrostatic properties are the same as those of the actual ship and also that the flexural response of the hull in waves is negligible.
It is also important to ensure that the damaged compartments are modelled as accurately as practicably possible to ensure that the correct volume of flood water is represented.
Since ingress of water (even small amounts) into the intact parts of the model will affect its behaviour, measures must be taken to ensure that this ingress does not occur.
2.2. Model particulars
2.2.1. In recognising that scale effects play an important role in the behaviour of the model during tests, it is important to ensure that these effects are minimised as much as practically possible. The model should be as large as possible since details of damaged compartments are easier constructed in larger models and the scale effects are reduced. It is therefore recommended that the model length is not less than that corresponding to 1:40 scale. However it is required that the model is not less than 3 metres long at the subdivision load line.
2.2.2(a) The model in way of the assumed damages must be as thin as practically possible to ensure that the amount of flood water and its centre of gravity is adequately represented. It is recognised that it may not be possible for the model hull and the elements of primary and secondary subdivision in way of the damage to be constructed with sufficient detail and due to these constructional limitations it may not be possible to calculate accurately the assumed permeability of the space.
2.2.2(b) It has been found during tests that the vertical extent of the model can affect the results when tested dynamically. It is therefore required that the ship is modelled to at least three super structure standard heights above the bulkhead (freeboard) deck so that the large waves of the wave train do not break over the model.
2.2.2(c) It is important that not only the draughts in the intact condition are verified, but also that the draughts of the damaged model are accurately measured for correlation with those derived from the damaged stability calculation. After measuring the damaged draughts it may be found necessary to make adjustments to the permeability of the damaged compartment by either introducing intact volumes or by adding weights. However it is also important to ensure that the centre of gravity of the flood water is accurately represented. In this case any adjustments made must err on the side of safety.
2.2.2(d) If the model is required to be fitted with barriers on deck and the barriers are less than the height required as per paragraph 2.3 of Annex I, the model is to be fitted with CCTV so that any "splashing over" and any accumulation of water on the undamaged area of the deck can be monitored. In this case a video recording of the event is to form part of the test records.
2.2.3. In order to ensure that the model motion characteristics represent those of the actual ship it is important that the model is both inclined and rolled in the intact condition so that the intact GM and the mass distribution are verified.
The transverse radius of gyration of the actual ship is not to be taken as being greater than 0,4B and the longitudinal radius of gyration is not to be taken as being more than 0,25L.
The transverse rolling period of the model is to be obtained by:
>REFERENCE TO A GRAPHIC>
where:
GM: metacentric height of the actual (intact) ship
g: acceleration due to gravity
λ: scale of model
B: breadth of actual ship.
Note:
While inclining and rolling the model in the damage condition may be accepted as a check for the purpose of verifying the residual stability curve, such tests are not to be accepted in lieu of the intact tests.
Nevertheless the damaged model must be rolled in order to obtain the rolling period required to perform the tests as per paragraph 3.1.2.
2.2.4. The contents of this paragraph are self-explanatory. It is assumed that the ventilators of the damage compartment of the actual ship are adequate for unhindered flooding and movement of the flood water. However in trying to scale down the ventilating arrangements of the actual ship undesirable scale effects may be introduced. In order to ensure that these do not occur it is recommended to construct the ventilating arrangements to a larger scale than that of the model, ensuring that this does not affect the flow of water on the car deck.
2.2.5. The isosceles triangular profile of the prismatic damage shape is that corresponding to the load waterline.
Additionally in cases where side casings of width less than B/5 are fitted and in order to avoid any possible scale effects, the damage length in way of the side casings must not be less than 2 metres.
Paragraph 3 - Procedure for experiments
3.1. Wave spectra
The Jonswap spectrum it to be used as this describes fetch and duration limited seas which correspond to the majority of the conditions world wide. In this respect it is important that not only the peak period of the wave train is verified but also that the zero crossing period is correct.
3.1.1. Corresponding to a peak period of 4[radic ]hs and given that the enhancement factor γ is 3,3, the zero crossing period is not to be greater than:
{Tp/(1,20 to 1,28)} +/- 5 %
3.1.2. The zero crossing period corresponding to a peak period equal to the rolling period of the damaged model and given that the factor γ is to be 1, is not to be greater than:
{Tp/(1,3 to 1,4)} +/- 5 %,
noting that if the rolling period of the damaged model is greater than 6[radic ]hs, the peak period is to be limited to 6[radic ]hs.
Note:
It has been found that it is not practical to set limits for zero crossing periods of the model wave spectra according to the nominal values of the mathematical formulae. Therefore an error margin of 5 % is allowed.
It is required that for every test run the wave spectrum is recorded and documented. Measurements for this recording are to be taken in the immediate vicinity of the model (but not on the leeside) - see figure (a) below, and also near the wave-making machine. It is also required that the model is instrumented so that its motions (roll, heave and pitch) as well as its attitude (heel, sinkage and trim) are monitored and recorded though out the test.
>PIC FILE= "L_2003123EN.003501.TIF">
The "near the model" wave measuring probe to be positioned either on arc A or arc B (figure (a)).
Paragraphs 3.2, 3.3, 3.4
The contents of these paragraphs are considered self-explanatory.
Paragraph 3.5 Simulated damages
Extensive research carried out for the purpose of developing appropriate criteria for new vessels has clearly shown that in addition to the GM and freeboard being important parameters in the survivability of passenger ships, the area under the residual stability curve up to the angle of maximum GZ is also an other major factor. Consequently in choosing the worst SOLAS damage for compliance with the requirement of paragraph 3.5.1, the worst damage is to be taken as that which gives the least area under the residual stability curve up to the angle of the maximum GZ.
Paragraph 4 - Survival criteria
The contents of this paragraph are considered self-explanatory.
Paragraph 5 - Test approval
The following documents are to be part of the report to the administration:
(a) damage stability calculations for worst SOLAS and mid-ship damage (if different);
(b) general arrangement drawing of the model together with details of construction and instrumentation;
(c) inclining experiment and rolling test reports;
(d) calculations of actual ship and model rolling periods; and
(e) nominal and measured wave spectra (near the wave-making machine and near the model respectively);
(f) representative record of model motions, attitude and drift;
(g) relevant video recordings.
Note:
All tests must be witnessed by the administration.
Figures
(Indicative guidelines to national administrations)
Figure 1
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Figure 2
>PIC FILE= "L_2003123EN.003701.TIF">
1. If fr >= 2,0 metres, height of water on deck (hw) = 0,0 metres.
2. If fr < 0,3 metres, height of water on deck (hw) = 0,5 metres.
Figure 3
>PIC FILE= "L_2003123EN.003702.TIF">
1. If hs >= 4,0 metres, height of water on deck is calculated as per figure 3.
2. If hs < 1,5 metres, height of water on deck (hw) = 0,0 metres.
For example:
If fr = 1,15 metres and hs = 2,75 metres, height hw = 0,125 metres.
Figure 4
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Figure 5
>PIC FILE= "L_2003123EN.003901.TIF">
Figure 6
>PIC FILE= "L_2003123EN.004001.TIF">
Ship without hanging car decks
Example 1:
Height of water on deck = 0,25 metres
Minimum required height of barrier = 2,2 metres
Ship with hanging deck (in way of the barrier)
Example 2:
Height of water on deck (hw) = 0,25 metres
Minimum required height of barrier = x
Figure 7
>PIC FILE= "L_2003123EN.004002.TIF">
Minimum required freeboard to freeing port = 1,0 m
Figure 8
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Figure 9
>PIC FILE= "L_2003123EN.004102.TIF">
Deck edge not immersed
>PIC FILE= "L_2003123EN.004103.TIF">
Deck edge immersed