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Clasification Society Rules and Regulations - Rules and Regulations for the Classification of Offshore Units, January 2016 - Part 10 SHIP UNITS - Chapter 2 Loads and Load Combinations - Section 6 Combination of loads

Section 6 Combination of loads

Parent topic: Chapter 2 Loads and Load Combinations

6.1 Symbols

6.1.1 For the purposes of this Section, the following symbols apply:

Table 2.6.1 Design load combinations

Global hull girder loads
Load component Operation on-site Inspection/maintenance Transit Flooded
S S+D S S+D S S+D S S+D
Msw-perm-oper Msw-perm-oper+ Mwv Msw-perm-maint Msw-perm-maint + Mwv Msw-perm-sea Msw-perm-sea + Mwv Msw-perm-flood Msw-perm-flood + Mwv
Mh Mh Mh Mh
Q Qsw-perm-oper Qsw-perm-oper + Qwv Qsw-perm-maint Qsw-perm-maint + Qwv Qsw-perm-sea Qsw-perm-sea + Qwv Qsw-perm-flood Qsw-perm-flood + Qwv
Local loads
Load component Space type Operation on-site Inspection/maintenance Transit Flooded
S S+D S S+D S S+D S S+D
External sea pressure Exposed deck        
Hull envelope
Liquid pressure Ballast tanks
Cargo tanks/other tanks designed for liquid filling
Fresh water and fuel/lube oil tanks
Water tight boundaries/ void spaces        
Dry space            
Deck loads Dry space
NOTES
1. All the dynamic wave loads are to be adjusted by the factor. The value of is dependent on the operational condition, see Pt 10, Ch 2, 3.4 Return periods and probability factor, fprob .
2. The pressure in cargo tanks, and other tanks designed for liquid filling, that are stated in the unit’s Operations Manual as not to be loaded during transit may be taken as zero for the transit assessment.

6.2 General

6.2.1  Application.
  1. The design load combinations given in Pt 10, Ch 2, 6.1 Symbols 6.1.1 corresponding to the applicable static load scenarios given in Pt 10, Ch 2, 2.3 Local static loads are to be used as the basis for the scantling requirements and strength assessment (by FEM).
  2. For each dynamic load case, the envelope load values as given in Pt 10, Ch 2, 3 Dynamic load components are multiplied with dynamic load combination factors to give simultaneously acting dynamic loads.
  3. The procedures for calculating the simultaneously acting dynamic loads are given in Pt 10, Ch 2, 6.3 Application of dynamic loads. The dynamic loads for unrestricted worldwide transit are given in Pt 10, Ch 2, 7 Environmental loads for unrestricted worldwide transit condition. The dynamic loads for the site-specific load scenarios are given in Pt 10, Ch 2, 8 Environmental loads for site-specific load scenarios.

6.3 Application of dynamic loads

6.3.1  Dynamic load combination factors.
  1. For scantling assessment, the dynamic load combination factors used for the calculations of the simultaneously acting dynamic loads are to be taken as given in:

    For strength assessment by FEM, the dynamic load combination factors are to be taken as given in:

  2. The heading correction factor, , is to be taken as follows:

    = 0,8 for beam sea dynamic load cases

    = 1,0 for all other dynamic load cases

    = 1,0 for beam sea dynamic load cases.

6.3.2  Vertical and Horizontal wave bending moment for a considered dynamic load case.
  1. The simultaneously acting vertical wave bending moment, and horizontal wave bending moment, , are to be taken as:
    • Vertical wave bending moment:

      = kNm for ≥ 0

      = — kNm for ≥ 0

    • Horizontal wave bending moment:

    = kNm

6.3.3  Vertical wave shear force for a considered dynamic load case.
  1. The simultaneously acting vertical wave shear force, , is to be taken as:

    = kNm for ≥ 0

    = kNm for < 0.

6.3.4  Dynamic wave pressure distribution for a considered dynamic load case.
  1. The simultaneously acting dynamic wave pressure, , is to be taken as follows, but not to be less than – g () below still waterline or less than 0 above still waterline:
    • For the port and starboard side within the region with a defined bilge:

      =

      between centreline and start of bilge

      =

      between end of bilge and still waterline

      =

      for side shell above still waterline intermediate values of around the bilge are to be obtained by linear interpolation along the vertical distance.

    • For the port and starboard side within the region without a defined bilge:

      =

      between bottom centreline and still waterline

      =

      above still waterline

      where

      = dynamic wave pressure at bottom centreline, to be taken as:

      = kN/m2

      = dynamic wave pressure at z = 0 and y = , to be taken as:

      = kN/m2

      = dynamic wave pressure at waterline, to be taken as:

      = kN/m2

  2. Pt 10, Ch 2, 6.3 Application of dynamic loads 6.3.5 to Pt 10, Ch 2, 6.3 Application of dynamic loads 6.3.5 illustrate simultaneously acting dynamic wave pressures.
6.3.5  Green sea load of a considered dynamic load case.
  1. The simultaneously acting green sea load on the weather deck, is shown in Pt 10, Ch 2, 6.3 Application of dynamic loads 6.3.5.

    Figure 2.6.1 Dynamic wave pressure for head sea dynamic load cases

    Figure 2.6.2 Dynamic wave pressure for beam sea dynamic load cases

    Figure 2.6.3 Pressure distribution for wave crest and wave trough for forward and aft

    Table 2.6.2 Green sea load

    Inclined green sea load, see Note
    = max. kN/m2
    Uniformly distributed
    = max. kN/m2
    NOTE
    Inclined green sea load is obtained by linear interpolation between port side and starboard side, with load decreasing from port side to starboard side, with the maximum value at vessel side given by the formula and the minimum value at the opposite side taken as 34,3 kN/m2. The assessment is then to be repeated, with loading decreasing from starboard side to port side.
6.3.6  Dynamic tank pressure for a considered dynamic load case.
  1. The simultaneously acting dynamic tank pressure, , is to be taken as:
    • For tanks in the cargo region:

      = kN/m2

    • For tanks outside the cargo region:

      = kN/m2

    where

    = envelope dynamic tank pressure due to vertical acceleration, as defined in Pt 10, Ch 2, 3.8 Dynamic local loads 3.8.4 with reference point taken as:
    1. top of tank
    2. top of air pipe/overflow for ballast tanks designed

      see Pt 10, Ch 2, 6.3 Application of dynamic loads 6.3.6, in kN/m2

    = envelope dynamic tank pressure due to transverse acceleration, as defined in Pt 10, Ch 2, 3.8 Dynamic local loads 3.8.4 with reference point taken as:
    1. tank top towards port side for > 0
    2. tank top towards starboard side for < 0

      see Pt 10, Ch 2, 6.3 Application of dynamic loads 6.3.6, in kN/m2

    = envelope dynamic tank pressure due to longitudinal acceleration, as defined in Pt 10, Ch 2, 3.8 Dynamic local loads 3.8.4 with reference point taken as:
    1. forward bulkhead for > 0
    2. aft bulkhead of the tank for < 0,

      see Pt 10, Ch 2, 6.3 Application of dynamic loads 6.3.7, in kN/m2

NOTES

1. For a non-parallel tank, should be selected from either forward or aft bulkhead corresponding to the reference point . If the longitudinal load combination factor = 0, should be selected from the bulkhead with the greater breadth.

2. The vertical, transverse and longitudinal acceleration is to be taken at the centre of gravity of the tank under consideration.

Figure 2.6.4 Dynamic tank pressure in cargo tank (Left) and ballast tank (Right) due to positive and negative vertical tank acceleration

Figure 2.6.5 Dynamic tank pressure in cargo tank (Left) and ballast tank (Right) due to negative and positive transverse tank acceleration

6.3.7  Dynamic deck loads for a considered dynamic load case.
  1. The simultaneously acting dynamic deck load for uniformly distributed load, , on the enclosed upper deck, where a forecastle or poop is fitted, and also on all lower decks, is to be taken as:

    = kN/m2

  2. The simultaneously acting dynamic vertical force for heavy units, , acting on supporting structures and securing systems for heavy units of cargo, equipment or structural components, is to be taken as:

    = kN

    Figure 2.6.6 Dynamic tank pressure in tanks due to positive and negative longitudinal acceleration
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