Regulation 7 – Attained subdivision index A

Paragraph 1

The probability of surviving after collision damage to the ship hull is expressed by the index A. Producing an index A requires calculation of various damage scenarios defined by the extent of damage and the initial loading conditions of the ship before damage. Three loading conditions should be considered and the result weighted as follows:

A = 0.4A_s + 0.4A_p + 0.2A_l

where the indices s, p and l represent the three loading conditions and the factor to be multiplied to the index indicates how the index A from each loading condition is weighted.
The method of calculating the A for a loading condition is expressed by the formula:

i=t
Ac = p_i [v_i s_i]
i=1

The index c represents one of the three loading conditions, index i represents each investigated damage or group of damages and t is the number of damages to be investigated to calculate A_c for the particular loading condition.

To obtain a maximum index A for a given subdivision, t has to be equal to T, the total number of damages. In practice, the damage combinations to be considered are limited either by significantly reduced survivability possibility (i.e., flooding of substantially larger volumes) or by exceeding the maximum possible damage length.

The index A is divided into part factors as follows:

Three initial loading conditions should be used for calculating the index A. The loading conditions are defined by their mean draught d, trim and GM.

The mean draught and trim are illustrated in the figure above.

The GM values for the three loading cond itions could, as a first attempt, be taken from the intact stability GM limit curve. If the required index R is not obtained, the GM values may be increased, implying that the intact loading conditions from the intact stability book must now meet the GM limit curve from the damage stability calculations derived by linear interpolation between the three GM’s.

Paragraph 2

The calculations for differing trim should be carried out with the same initial trim for the partial and deepest subdivision draughts. For the light service draught, the actual service trim should be used (refer to the notes to regulation 2, paragraph 11).

Each combination of the index within the formula given in regulation 7.1 should not be less than the requirement given in regulation 6.2. Each partial index A should comply with the
requirements of regulation 6.1.

Example:

Based on the GM limiting curves obtained from damage stability calculations of each
trim, an envelope curve covering all calculated trim values should be developed.

Calculations covering different trim values should be carried out in steps not exceeding 1% of Ls. The whole range including intermediate trims should be covered by the damage stability calculations. Refer to the example showing an envelope curve obtained from calculations of 0 trim and 1% of Ls.

Paragraph 5

In the forward and aft ends of the ship where the sectional breadth is less than the ship’s breadth B, transverse damage penetration can extend beyond the centreline bulkhead. This application of the transverse extent of damage is consistent with the methodology to account for the localized statistics which are normalized on the greatest moulded breadth B rather than the partial breadth.

Where corrugated bulkheads are fitted, they may be treated as ordinary stiffened bulkheads as long as the corrugation is of the same order as the stiffening structure.

Pipes and valves directly adjacent to the bulkhead can be considered to be a part of the bulkhead. The same applies for small recesses, drain wells, etc.

Regulation 7-1 – Calculation of the factor pi

General

The definitions below are intended to be used for the application of part B-1 only.

In regulation 7-1, the words “compartment” and “group of compartments” should be understood to mean “zone” and “adjacent zones”.

Zone – a longitudinal interval of the ship within the subdivision length.

Room – a part of the ship, limited by bulkheads and decks, having a specific permeability.

Space – a combination of rooms.

Compartment – an onboard space within watertight boundaries.

Damage – the three dimensional extent of the breach in the ship.

For the calculation of p, v, r and b only the damage should be considered, for the calculation of the s-value the flooded space should be considered. The figures below illustrate the difference.

Damage shown as the bold square:

Flooded space shown below:

Paragraph 1.1

The coefficients b₁₁, b₁₂, b₂₁ and b₂₂ are coefficients in the bi- linear probability density function on normalized damage length (J). The coefficient b₁₂ is dependent on whether or not L_s = L^*, the other coefficients are valid irrespective of L_s.

Longitudinal subdivision

In order to prepare for the calculation of index A, the ship’s subdivision length Ls is divided into a fixed discrete number of damage zones. These damage zones will determine the damage stability investigation in the way of specific damages to be calculated.

There are no rules for the subdividing, except that the length Ls defines the extremes for the actual hull. However, it is important to consider a strategy carefully to obtain a good result (that is a large attained index A). All zones and combination of adjacent zones may contribute to the index A.

The figure above shows different longitudinal divisions of the length L_s.

The first example is a very rough division into three zones of approximately the same size with limits where transverse subdivision is established. The probability that the ship will survive a damage in one of the three zones is expected to be low (s-factor = 0) and, therefore, the total attained index A will be lost.

In the second example the zones have been placed in accordance with the watertight arrangement, including minor subdivision (as in double bottom, etc.). The chances of getting good s- factors in this case should be good.

Where transverse corrugated bulkheads are fitted, they may be treated as equivalent plane
bulkheads, provided the corrugation is of the same order as the stiffening structure.

The triangle in the figure below illustrates the possible single and multiple zone damages in a ship with a watertight arrangement suitable for a seven-zone division. The triangles at the bottom line indicate single zone damages and the parallelograms indicate adjacent zones damages.

Figure illustrates the possible single and multiple zone damages in a ship.

As an example, the triangle illustrates a damage opening the rooms in zone 2 to the sea and the parallelogram illustrates a damage where rooms in the zones 4, 5 and 6 are flooded
simultaneously.

The shaded area illustrates the effect of the maximum absolute damage length. The p-factor for a combination of three or more adjacent zones equals zero if the length of the combined adjacent damage zones minus the length of the foremost and the aft most damage zones in the combined damage zone is greater than the maximum damage length. Having this in mind when subdividing Ls could limit the number of zones defined to optimize the attained index A.

As the p- factor is related to the watertight arrangement by the longitudinal limits of damage
zones and the transverse distance from the ship side to any longitudinal barrier in the zone, the following indices are introduced:

Paragraph 1.2

Transverse subdivision in a damage zone

Damage to the hull in a specific damage zone may just penetrate the ship ’s watertight hull or penetrate further towards the centreline. To describe the probability of penetrating only a wing compartment, a probability factor r is used, based mainly on the penetration depth b. The value of r is equal to 1, if the penetration depth is B/2 where B is the maximum breadth of the ship at the deepest subdivision draught ds, and r = 0 if b = 0.

The penetration depth b is measured at level deepest subdivision draught ds as a transverse
distance from the ship side right-angled to the centreline to a longitudinal barrier.

Where the actual watertight bulkhead is not a plane parallel to the shell, b should be determined by means of an assumed line, dividing the zone to the shell in a relationship b₁/b2 with ½ = b₁/b₂ = 2.

Examples of such assumed division lines are illustrated in the figure below. Each sketch
represents a single damage zone at a water line plane level ds and the longitudinal bulkhead represents the outermost bulkhead position below d_s + 12.5 m.

In calculating r-values for a group of two or more adjacent compartments, the b-value is common for all compartments in that group, and equal to the smallest b- value in that group:

b = min {b₁, b₂, …, b_n}

where:	n =	number of wing compartments in that group;
	b1, b2, …, bn =	mean values of b for individual wing compartments contained in the group.

Accumulating p

The accumulated value of p for one zone or a group of adjacent zones is determined by:

k=K_j,_n
p_j,n = p_j,n,k
k=1

j+n-1
where K_j,n =  K_j the total number of b_k’s for the adjacent zones in question.
j

The figure above illustrates b’s for adjacent zones. The zone j has two penetration limits and one to the centre, the zone j+1 has one b and the zone j+n-1 has one value for b. The multiple zones will have (2+1+1) four values of b, and sorted in increasing order they are:

(b_j,1 ; b_j+1,1 ; b_j+n-1,1 ; b_j,2 ; b_K)

The total accumulated p

j=T
p = p_j,n
j=1

where T is the total number of damages.

Examples of multiple zones having a different b

Examples of combined damage zones and damage definitions are given in the figures below. Rooms are identified by R10, R12, etc.

1) to b3 with R10, R20 and R31 damaged
2) to B/2 with R10, R20, R31 and R32 damaged

1) to b3 with R11, R21 and R31 damaged
2) to b2 with R11, R21, R31 and R32 damaged
3) to b1 with R11, R21, R31, R32, and R22 damaged
4) to B/2 with R11, R21, R31, R32, R22 and R12 damaged

1) to b₁ with R11, R21 and R31 damaged
2) to b₂ with R11, R21, R31 and R12, damaged
3) to B/₂ with R11, R21, R31, R12, and R22, R32 damage

A damage having a horizontal extension b and a vertical extension H₂ leads to a flooding of both wing compartment and hold; for b and H₁ only the wing compartment. The figure illustrates a partial subdivision draught dp damage.

The same is valid if b- values are calculated for arrangements with sloped walls.

The same is valid if b- values are calculated for arrangements with sloped walls.

Regulation 7-2 – Calculation of the factor si

General

Initial condition – an intact loading condition to be considered in the damage analysis described by the mean draught, vertical centre of gravity and the trim. Or alternative parameters from where the same may be determined (ex. displacement, GM and trim). There are three initial conditions corresponding to the three draughts d_s, d_p and d_l.

Immersion limits – immersion limits are an array of points that are not to be immersed at various stages of flooding as indicated in paragraphs 5.2 and 5.3 of the regulation.

Openings – all openings need to be defined: both weathertight and unprotected. Openings are the most critical factor to preventing an inaccurate index A. If the final waterline immerses the lower edge of any opening through which progressive flooding takes place, the factor “s” may be recalculated taking such flooding into account. However, in this case the s value should also be calculated without taking into account progressive flooding and corresponding opening. The smallest s value should be retained for the contribution to the attained index.

Paragraph 2

Intermediate stages of flooding

The case of instantaneous flooding in unrestricted spaces in way of the damage zone does not require intermediate stage flooding calculations. Where intermediate stages of flooding calculations are necessary in connection with progressive flooding, they should reflect the sequence of filling as well as filling level phases. Calculations for intermediate stages of flooding should be performed whenever equalization is not instantaneous, i.e. equalization is of a duration greater than 60 s. Such calculations consider the progress through one or more floodable (non-watertight) spaces. Bulkheads surrounding refrigerated spaces, incinerator rooms and longitudinal bulkheads fitted with non-watertight doors are typical examples of structures that may significantly slow down the equalization of main compartments.

Flooding boundaries

If a compartment contains decks, inner bulkheads, structural elements and doors of sufficient tightness and strength to seriously restrict the flow of water, for intermediate stage flooding calculation purposes it should be divided into corresponding non-watertight spaces. It is assumed that the non-watertight divisions considered in the calculations are limited to “A” class fire-rated bulkheads and do not apply to “B” class fire-rated bulkheads normally used in accommodation areas (e.g. cabins and corridors). This guidance also relates to regulation 4, paragraph 4.

Sequential flooding computation

For each damage scenario, the damage extent and location determine the initial stage of flooding. Calculations should be performed in stages, each stage comprising of at least two intermediate filling phases in addition to the full phase per flooded space. Unrestricted spaces in way of damage should be considered as flooded immediately. Every subsequent stage involves all connected spaces being flooded simultaneously until an impermeable boundary or final equilibrium is reached. If due to the configuration of the subdivision in the ship it is exp ected that other intermediate stages of flooding are more onerous, then those should be investigated.

Cross flooding/equalization

In general, cross flooding is meant as a flooding of an undamaged space on the other side of the ship to reduce the heel in the final equilibrium condition.

The cross-flooding time should be calculated in accordance with resolution A.266(VIII). If complete fluid equalization occurs in 60 s or less, it should be treated as instantaneous and no further calculations need to be carried out. Only passive open cross-flooding arrangements without valves should be considered effective for instantaneous flooding cases.

If complete fluid equalization can be finalized in 10 min or less, the assessment of survivability can be carried out for passenger ships as the smallest values of s_intermediate,i or s_final.

In case the equalization time is longer than 10 min, s_final is calculated for the floating position achieved after 10 min of equalization. This floating position is computed by calculating the amount of flood water according to resolution A.266(VIII) using interpolation, where the equalization time is set to 10 min, i.e. the interpolation of the flood water volume is made between the case before equalization (T = 0) and the total calculated equalization time.

In any cases where complete fluid equalization exceeds 10 min, the value of sfinal used in the formula in paragraph 1.1 should be the minimum of sfinal, i at 10 min or at final equalization.

Paragraph 4

The displacement is the intact displacement at the subdivision draught in question (ds, dp and dl).

Paragraph 4.1.1

The beam B used in this paragraph means breadth as defined in regulation 2.8.

Paragraph 4.1.2

The parameter A (projected lateral area) used in this paragraph does not refer to the attained subdivision index.

Paragraph 5

In cargo ships where cross flooding devices are fitted, the safety of the ship should be maintained in all stages of flooding. The Administration may request for this to be demonstrated. Cross-flooding equipment, if installed, should have the capacity to ensure that the equalization takes place within 10 min.

Paragraph 5.2.1

Unprotected openings

The flooding angle will be limited by immersion of such an opening. It is not necessary to define a criterion for non- immersion of unprotected openings at equilibrium, because if it is immersed, the range of positive GZ limited to flooding angle will be zero so “s” will be equal to zero. An unprotected opening connects two rooms or one room and the outside.

An unprotected opening will not be taken into account if the two connected rooms are flooded or none of these rooms are flooded. If the opening is connected to the outside, it will not be taken into account if the connected compartment is flooded. An unprotected opening does not need to be taken into account if it connects a flooded room or the outside to an undamaged room, if this room will be considered as flooded in a subsequent stage.

Openings fitted with a weathertight mean of closing (“weathertight openings”)

The survival “s” factor will be “0” if any such point is submerged at a stage which is considered as “final”. Such points may be submerged during a stage or phase which is considered as “intermediate”, or within the range beyond equilibrium.

If an opening fitted with a weathertight means of closure is submerged at equilibrium during a stage considered as intermediate, it should be demonstrated that this weathertight means of closure can sustain the corresponding head of water and that the leakage rate is negligible.

These points are also defined as connecting two rooms or one room and the outside, and the same principle as for unprotected openings is applied to take them into account or not. If several stages have to be considered as “final”, a “weathertight opening” does not need to be taken into account if it connects a flooded room or the outside to an undamaged room if this room will be considered as flooded in a successive “final” stage.

Paragraph 5.2.2

Horizontal evacuation routes on the bulkhead deck include only escape routes (designated as category 2 stairway spaces according to SOLAS regulation II-2/9.2.2.3 or as category 4 stairway spaces according to SOLAS regulation II-2/9.2.2.4 for passenger ships carrying not more than 36 passengers) used for the evacuation of undamaged spaces. orizontal evacuation routes do not include corridors within the damaged space. No part of a horizontal evacuation route should be immersed.

The provisions for escape in SOLAS chapter II-2 may allow more than one watertight compartment below the bulkhead deck to be served by a common stairway within the same main vertical zone (MVZ). Partial immersion of the bulkhead deck may be accepted at final equilibrium. The new provision is intended to ensure that evacuation along the bulkhead deck to the vertical escapes will not be impeded by water on that deck. A “horizontal evacuation route” in the context of this regulation means a route on the bulkhead deck connecting spaces located on and under this deck with the vertical escapes from the bulkhead deck required for compliance with SOLAS chapter II-2.

Paragraph 5.3.1

The purpose of this paragraph is to provide an incentive to ensure that evacuation through a vertical escape will not be obstructed by water from above. The paragraph is intended for smaller emergency escapes, typically hatches, where fitting of a watertight or weathertight means of closure would otherwise exclude them from being considered as flooding points.

Since the probabilistic regulations do not require that the watertight bulkheads be carried
continuously up to the bulkhead deck, care should be taken to ensure that evacuation from intact spaces through flooded spaces below the bulkhead deck will remain possible, for instance by means of a watertight trunk.

Paragraph 6

The sketches in the figure illustrate the connection between position of watertight decks in the reserve buoyancy area and the use of factor v for damages below these decks.

In this example, there are 3 horizontal subdivisions to be taken into account as the vertical extent of damage. The example shows the maximum possible vertical extent of damage d + 12.5 m is positioned between H2 and H3. H1 with factor v1, H2 with factor v2 > v1 but v2 < 1 and H3 with factor v3 = 1.   The factors v1 and v2 are the same as above. The reserve buoyancy above H3 should be taken undamaged in all damage cases. The combination of damages into the rooms R1, R2 and R3 positioned below the initial water line should be chosen so that the damage with the lowest s- factor is taken into account. That often results in the definition of alternative damages to be calculated and compared. If the deck taken as lower limit of damage is not watertight, down flooding should be considered.

 
Paragraph 6.1

The parameters x₁ and x₂ are the same as parameters x1 and x2 used in regulation 7-1.

Regulation 7-3 – Permeability

Paragraph 2

The following additional cargo permeabilities may be used:

Paragraph 3

Concerning the use of other figures for permeability “if substantiated by calculations”, such
permeabilities should reflect the general conditions of the ship throughout its service life rather than specific loading conditions.

This paragraph allows for the recalculation of permeabilities. This should only be considered in cases where it is evident that there is a major discrepancy between the values shown in the regulation and the real values. It is not designed for improving the attained value of a deficient ship of regular type by the modification of chosen spaces in the ship that are known to provide significantly onerous results. All proposals should be considered on a case-by-case basis by the Administration and should be justified with adequate calculations and arguments.

Regulation 13 – Openings in watertight bulkheads below the bulkhead deck in passenger ships

General – Steps in the bulkhead deck

If the transverse watertight bulkheads in a region of the ship are carried to a higher deck which forms a vertical step in the bulkhead deck, openings located in the bulkhead at the step may be considered as being located above the bulkhead deck. Such openings should then comply with regulation 17 and should be taken into account when applying regulation 7-2.

All openings in the shell plating below the upper deck throughout that region of the ship should be treated as being below the bulkhead deck and the provisions of regulation 15 should be applied. See figure below.

Paragraph 7.6

The IEC standard referenced in the footnote (IEC publication 529, 1976) has been replaced by the newer standard IEC 60529:2003.

Regulation 13-1 – Openings in watertight bulkheads and internal decks in cargo ships

Paragraph 1

If the transverse watertight bulkheads in a region of the ship are carried to a higher deck than in the remainder of the ship, openings located in the bulkhead at the step may be considered as being located above the freeboard deck.

All openings in the shell plating below the upper deck throughout that region of the ship should be treated as being below the freeboard deck, similar to the bulkhead deck for passenger ships (see figure above), and the provis ions of regulation 15 should be applied.

Regulation 15 – Openings in the shell plating below the bulkhead deck of passenger ships and the freeboard deck of cargo ships

General – Steps in the bulkhead deck and freeboard deck

For the treatment of steps in the bulkhead deck of passenger ships see notes under regulation 13.
For the treatment of steps in the freeboard deck of cargo ships see notes under regulation 13-1.

Regulation 15-1 – External openings in cargo ships

Paragraph 1

With regard to air-pipe closing devices, they should be considered weathertight closing devices (not watertight). This is consistent with their treatment in regulation 7-2.5.2.1. However, in the context of regulation 15-1, “external openings” are not intended to include air-pipe openings.

Regulation 35-1 – Bilge pumping arrangements

Paragraph 2.6

The drainage from enclosed ro-ro spaces or special category spaces should be of such capacity that two-thirds of the scuppers, freeing ports etc. on the starboard or port side are capable of draining off a quantity of water originating from both sprinkler pumps and fire pumps, taking into account a list of 1° for ships with a breadth of 20 m or more and 2° for ships with a breadth below 20 m and a trim forward or aft of 0.5°.

Scuppers on ro-ro decks should be provided, over the outlet grate, with a removable grill with vertical bars, to prevent large obstacles from blocking the drain. The grill may be placed obliquely against the side of the ship. The grill should have a height of at least 1 m above the deck and should have a free flow area of at least 0.4 m², while the distance between the individual bars should be not more than 25 mm.