3.1.143trimThe static angle of a ve

3.1.143
trim
The static angle of a vessel about its latitudinal axis.
3.1.144
two-block
The condition when the lower load block or hook assembly contacts the upper load block or boom-point sheave
assembly.
3.1.145
ultrasonic
A non-destructive form of testing that detects flaws in materials using ultrasonic pulse waves.
3.1.146
vertical boom tip dynamic acceleration
The change in velocity of the boom tip caused by vessel motions.
3.1.147
vertical dynamic coefficient
Cv
A coefficient that is multiplied by the safe working load (SWLH) to provide the vertical factored load.
3.1.148
vertical load
A load applied perpendicular to the horizontal plane.
3.1.149
vessel response amplitude operators
RAO
The response amplitude operators or a set of statistics that model a ship’s behavior at sea.
3.1.150
wind load
A load applied by air at a certain velocity passing over the crane structure.
3.1.151
wire rope
A flexible, multi-wired member usually consisting of a core member around which a number of multi-wired strands are
“laid” or helically wound.
3.1.152
working load
The external load in pounds (kilonewtons) applied to the crane including the weight of load-attaching equipment
(i.e. load block, shackles and slings).
NOTE The maximum allowable working load for a given condition is the SWL.
3.2 Abbreviations
For the purposes of this document, the following definitions apply.
ABMA American Bearing Manufacturers Association
AISC American Institute of Steel Construction
ANSI American National Standards Institute
Copyright American Petroleum Institute
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18 API SPECIFICATION 2C
API American Petroleum Institute
ASME American Society of Mechanical Engineers
ASNT American Society of Nondestructive Testing
ASTM American Society of Testing and Materials
AWS American Welding Society
BS British Standard
DOF degree of freedom
IEEE Institute of Electrical and Electronics Engineers
ISO International Organization for Standardization
MODU mobile offshore drilling unit
SAE Society of Automotive Engineers
3.3 Units
Many of the formulae in this publication depend on the input quantities having the proper units to calculate the correct
result. The formulae given in this publication are given in the U.S. Customary System (USC) of units. Primary units
used are ft (length), lb (force), s (time), and degrees (angles). These results may be converted to the International
System of Units (SI) metric equivalents, if desired. Since some of the formulae are “unit-dependent”, the U.S. units shall
be input in the formulae and U.S. unit results obtained; results may then be converted to SI units. Conversion factors
from USC to SI units are given as follows. For additional conversions, refer to ASTM SI 10 or IEEE Standard 268.
1 meter = 3.2808 ft
1 kilogram = 2.2046 lb force
1 Newton = 0.2248 lb force
1 Joule = 0.737557 ft-lb force
1 Mega Pascal (MPa) = 145.0377 lb/in.2 (psi)
° Celsius = 5/9 × (° Fahrenheit –32)
Table 1—Description of Symbols
Symbol Units Equation or Section
Used Description
An in.2 D.1 Internal thread shear area
As in.2 D.1 External thread shear area
At in.2 E.5 Tensile stress area of threaded fastener
Av g Equation (7) Boom tip vertical acceleration
BL lb Equation (31) Minimum nominal breaking load for wire rope
C1 D.2 Substitution variable for Pcr equation
C2 D.2 Substitution variable for Pcr equation
Cf D.1 Factor for flat head attachment on cylinder
Cn hr Equation (37) Hours of exposure to a specific noise level
Cs Equation (23) Member shape coefficient for wind loading
Copyright American Petroleum Institute
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OFFSHORE PEDESTAL-MOUNTED CRANES 19
Cv 5.4.5 Vertical dynamic coefficient
D ft E.5 Pitch circle diameter of swing-bearing elements
Db ft Equation (34) Pitch circle diameter of swing-bearing fasteners
Dr ft Equation (35) Pitch circle diameter of weakest swing-bearing element
dcyl in. D.1 Inside diameter of cylinder tube
DF
D.1, Equations (26),
(27), (28), (29), (32),
(33)
Design factor for rigging, load blocks, and cylinders (may be different for
each component)
Ds in. D.1 Minimum major diameter of external thread
Dsh in. 7.2.4.2 Pitch diameter of sheave wheel
d in. 7.2.4.2 Nominal diameter of wire rope
E1 lb/in.2 D.2 Elastic modulus of cylinder body material
E2 lb/in.2 D.2 Elastic modulus of cylinder rod material
En in. D.1 Maximum pitch diameter of internal thread
Ers Equation (31) Efficiency of reeving system for running rigging
Es in. D.1 Minimum pitch diameter of external thread
Eweld D.1 Tube joint weld efficiency for cylinder
FL lb Vertical factored load
g 32.2 ft/s2 Equation (2) Acceleration due to gravity
H lb Equation (34) Axial load on swing bearing
Hsig ft Significant wave height
Htip ft Equation (10) Vertical distance from boom tip to supply boat deck
I1 in.4 D.2 Second moment of area of cylinder body
I2 in.4 D.2 Second moment of area of cylinder rod
K lb/ft Equation (2) Vertical spring rate of crane
Keb B.5.1 Effective length factor for elastic buckling
Kb Equation (30) Bearing constant for reeving system efficiency
Kn in. D.1 Maximum minor diameter of internal thread
L ft E.5 Length of moment arm
L1 in. D.2 Length of cylinder body
L2 in. D.2 Length of piston extension
Le in. D.1 Length of thread engagement
M ft-lb Equation (34) Overturning moment reaction at swing bearing
N Equation (30) Number of parts of line in reeving system
n 1/in. D.1 Threads per in.
Nb E.5, Equation (34) Number of swing-bearing fasteners or elements
Table 1—Description of Symbols (Continued)
Symbol Units Equation or Section
Used Description
Copyright American Petroleum Institute
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20 API SPECIFICATION 2C
NE dB(A) Equation (36) Permissible noise exposure
OL Equation (10) Substitution variable for Equation (9)
P lb/in.2 D.1 Pressure in cylinder
Pb lb E.5, Equation (34) Load on individual swing-bearing fastener or element
Pcr lb D.2 Elastic buckling force for cylinder
PF Equation (25) Factor applied to vertical and horizontal loads on the pedestal in addition to
the factored load
Pn lb E.5, Equation (35) Ultimate capacity of load element of swing circle assembly
PbNb lb E.5 Maximum swing-bearing load times number of load elements
PnNb lb E.5 Ultimate capacity of swing-bearing load elements
Pwind lb/ft2 Equation (23) Wind pressure acting on the projected area
p in. D.1 Screw thread pitch
q1 in. D.2 Substitution variable for Pcr equation
q2 in. D.2 Substitution variable for Pcr equation
S Equation (30) Number of sheave wheels in reeving system
Sa lb/in.2 D.1 Maximum allowable tensile stress in cylinder
SF E.3.2, E.4.4 Factor relating load in the boom suspension to a load on the hook
St lb/in.2 D.1 Maximum allowable thread shear stress in cylinder
s1 D.2 Substitution variable for Pcr equation
s2 D.2 Substitution variable for Pcr equation
T hr Equation (36) Duration of noise exposure
Tn hr Equation (37) Total permitted hours of exposure to a specific noise level
Ts lb/in.2 D.1, E.5 Ultimate tensile stress of material
t in. E.5 Height/thickness of swing-bearing geometry
twall in. D.1 Minimum cylinder tube wall thickness
thead in. D.1 Minimum cylinder head thickness
U knot Equation (23) Wind velocity
Vc ft/s Equation (5) Crane boom tip vertical velocity
Vd ft/s Equation (5) Supply boat deck vertical velocity
Vh ft/s Equation (5) Maximum possible steady hoisting velocity
Vhmin ft/s Equation (6) Required minimum steady hoisting velocity
Vr ft/s Equation (2) Relative velocity between hook and supply boat
W lb Equation (31) Total applied load in a wire rope system
WhorizontalCM lb Equation (16) Horizontal load acting on suspended load due to crane base motion
Woff(wind) lb Equation (21) Horizontal offlead load acting on crane due to wind
Table 1—Description of Symbols (Continued)
Symbol Units Equation or Section
Used Description
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OFFSHORE PEDESTAL-MOUNTED CRANES 21
4 Documentation
4.1 Manufacturer-supplied Documentation upon Purchase
The manufacturer shall supply to the purchaser certain documentation for each crane manufactured. The
documentation shall include:
a) load and information charts according to 8.2;
b) information for crane foundation support structure design including:
— kingpost or pedestal-mounting dimensions at the crane and supporting structure interface;
— maximum overturning moment with corresponding axial and radial load, and torque and side moments at the
crane and supporting structure interface in accordance with 6.2;
— maximum axial load with corresponding overturning moment and radial load, and torque and side moments at
the crane and supporting structure interface in accordance with 6.2; and
— fatigue design moment and corresponding other loads to be used to design supporting structure for 1,000,000
cycles in accordance with 6.4;
c) list of all critical components in accordance with 5.2 and certification that these components meet the API 2C
material, traceability, welding (as applicable), and nondestructive examination requirements;
d) operations, parts, and maintenance manual(s); and
e) failure-mode assessment results for unintended gross overloads ac