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Dynamics and structural damage of tanker ships running aground
Journal of Hazardous Mate&h,
25 (1990)
61
61-73
Elsevier Science Publishers B.V., Amsterdam
DYNAMICS AGROUND
AND STRUCTURAL
DAMAGE
G.V. ASADI and H. VAUGHAN Department of Mechanical Engineering,
OF TANKER
University
SHIPS RUNNING
of British Columbia
( Canada)
SUMMARY
A finite element method is described which models a ship impacting against another object. The ship is modeled as a beam which has the same flexibility, mass distribution and floatation properties as the ship. The ship structure may collapse locally during the ongoing collision process as also may the struck object. A number of collision scenarios involving the collision of a large tanker-ship with a submerged rigid rock are investigated. The significance of ship speed on the extent and nature of the damage to the hull is established. INTRODUCTION Grounding
incidents,
by their very nature,
docking facility and sometimes crude-oil
spill with its disastrous
demonstrated
recently
being damaged
effects
on local ecology
on the Alaska coast.
and releasing
The parallel
The consequences
of a large
and environment
have been
situation of a LNG tanker ship
upwards of one hundred thousand tonnes of liquid natural
gas in the form of an unconfined not occurred.
occur in shallow waters, often close to a
near populated land masses.
heavy and toxic flammable
gas-cloud
Such ships are usually protected at the sides by collision
has fortunately
barriers
and from
below by a “double bottom” which raises the LNG tanks a meter or so above the bottom plate of the hull. Engineers ticularly
have responded
in the automotive
industry. The literature recent conference
to the demands for improved safety against collision
industry and to a lesser
on “crashworthiness”
proceedings
degree in the general
par-
transportation
is fairly recent and limited although several
and textbooks
have been devoted to it, see for example
111, PI, and ]3]. Some revealing
statistics
on marine damage incidents
gives data on one thousand serious tanker casualties IMCO (International
Maritime
Consultative
are given by Kinkead
by category of casualty,
Organization)
portation
or grounding
(165 collision,
were caused by
It is the major hazard in the trans-
of oils and gases at sea.
The effectiveness
of double bottoms
tankers has been demonstrated although
239 grounding).
by
during the period 1968 to 1980.
The data shows that slightly more than four hundred of those incidents collision
[4]. He
collected
effective
against
above the struck object,
0304-3894/90/$03.50
in the prevention
shallow penetration
of the hull, merely by keeping the cargo
it gives a very limited protection
0 -
of oil outflow from grounded
by Card [S]. A double bottom is a passive system and against
1990 Elsevier Science Publishers B.V.
deep penetration,
as
62
could occur when a ship strikes a sharp reef or ice-flow. stronger hull based on knowledge of estimated beyond the elastic
processes
considerable
and grounding
APPROACHES
In this section we categorize
TO SHIP COLLISION
which have been found to be appropriate
im-
reviewed.
ship damage and ship collisions
for the study of ship collision
the interactive
with a view towards
safety. This work is now briefly
REVIEW OF TECHNICAL DAMAGE
ence frames
work has been done to understand
involved in ship collisions
proved design and increased
cal models
to design a
limit.
In the last decade structural
Then it is necessary
impact forces and using design codes well
AND GROUNDING
into some analytic refer-
for purposes of developing theoreti-
damage.
Firstly
we clarify
minor and major
collisions. A minor collision
is one in which the ship structure
plastic strains to the shell plating or stiffeners. neither
is there any fracture
or plate tearing caused by external
This means that all strength members slightly reduced
level. Significant
which minor collision by Jones
continue to be effective
contributions
of the hull.
the criteria
useful in the preliminary
or restricted
See for example
to the barrier.
A major collision of plate leading Such collisions of structural
cannot
material
destroyed
design of protec-
using classical
[8] is commonly
theories
to the energy absorbed
[ll],
or tearing parts.
and plasticity. the latter being to be used in
method occurs when a ship
but consists
plied to general grounding problems.
of tom plating, per-
in length.
A method
for
[9] and applied by him to some
and [12]. Some dimensional
of small scale tests by Vaughan
erably extended
[7].
for many types of ships.
was first proposed by Vaughan [lo],
distortion
of the damaged
in the collision,
in width but up to one hundred meters
LNG tanker groundings
protection
of elasticity
which cannot be analyzed by Minorsky’s
such incidents
cargo.
used which merely relates the volume
The damage is then often not volumetric
haps only one meter
from a series
paper on collision
energy of the ship. A range of coefficients
method are available
A major collision
Jones’
loss in strength and effectiveness
be analyzed
to the loss in kinetic
runs aground.
under
occurs then the damage is minor
is one in which there is some gross structural
to significant
Instead a method due to Minorsky
examining
penetration
which are built into the sides of specialty ships which carry hazardous is to ensure that if collision
Minorsky’s
or small
although possibly at some
towards understanding
Clearly the design criterion
related
only elastic
damage occurs and the nature of the damage has been developed
[6]. This work has been particularly
tion barriers
sustains
No gross distortion of the structure occurs
effects
were determined
[13] which allowed his method to be ap-
His experiments
were recently repeated
and consid-
by Jones and Jouri [14].
In the late 1970’s
and early 1980’s a considerable
ships in the form of ice breakers,
ice-strengthened
effort went into the design of arctic freighters,
and particularly
ice-break-
63
ing supertankers. financially
At that time the high price of oil made the exploitation
attractive.
A design for a supertanker
posed by Johansson
successful, onstrate
particularly
created
has progressed,
towards safer
tonne displacement. through improved
ships in harsher
designs for ships in which collision
The strongest breaker,
capable
been proposed, greatest
damage
of operating
ELEMENT
and bending moments
We now describe
details
state the equations
Coast Guard is a Class Eight icedesigns
by Glen and Daley [16]. Estimates derived by Vaughan
OF SHIP COLLISION
have of the
of ships of
[17].
AND GROUNDING
a finite element analysis recently developed by the authors in which
some new damage mechanisms the mathematical
instead of “major”.
likely to occur during operation
using simple formulas
ANALYSIS
is “minor”
of collision
They have effectively
in eight feet of level ice at 3 knots. Several
one of which has been assessed
impact forces
were also extremely
All of these ships dem-
understanding
environments.
ship yet proposed for the Canadian
this type can be obtained FINITE
Other designs for ice-breakers
in the range of 7,000
how the designer effects,
general purpose
was built a decade ago to carry ore from the Hudson Bay to North-
which is still in operation.
and impact
to withstand ice impact forces was pro-
[15]. The ship was not built, but an ice-strengthened
ship, the M.V. Arctic, ern Europe,
of the Arctic
for ships have been investigated
since they are derived in complete
[18]. We do not include
detail in [18].
of motion that have been solved, then concentrate
We merely
on the results that
have been obtained. The ship is modelled ment matrix
as a floating beam divided into n stations.
is denoted by [U] and the displacement
The nodal displace-
[u] at any point in the body is then
given by (1)
1~1= N WI where [N] is the interpolation motion
therefore
reduced from twelve to ten, as shown in Fig. 1. The (10 x 10) mass matrix of
the element
is considered
function matrix. The ship is assumed to be axially rigid and
its axial
separately.
The degrees
of freedom
of each element
is
is [m] = [ml] + [ma], where [ml] is due to lateral inertia and [m2] is due to
rotary inertia.
Fig. 1. The beam element
with ten degrees of freedom.
64
In the analysis
it is mathematically
convenient
to represent
rigid-body
motions as
special cases of the dynamic flexural motions. Thus the natural frequency matrix includes as its leading elements
the rigid-body
periodic motions in heave, pitch and roll, respec-
tively. This was made possible by treating each beam element as a free-free consequently
admits rigid-body
The simuhaneous
displacements
treatment
beam which
as well as elastic vibrational motions.
of rigid-body
motions
and flexural
motions
enables
added mass to be included in [m] in the form of a frequency dependent matrix. The three leading elements
of the added mass matrix
correspond
again to heave, pitch and roll
whereas the later elements have to be identified with the appropriate either a vertical,
lateral,
or torsional
mode,
starting with the fundamental
working up to the desired number of higher harmonics. later in this paper.
Added mass coefficients
mode of vibration,
A particular
for transient
water are difficult to assess so in the numerical
modes
example
impulse motions
calculations
discussed
and
is given
in shallow
later, deep water
values for sinusoidal motions have been used The stiffness matrix of the element is denoted by [k]. It is composed (i) the elastic structural
stiffness of the hull, (ii) the hydrodynamic
ancy, (iii) the hydrodynamic
of flexural
vibration and torsion have been included
as well as the rigid body motions in heave, pitch and roll.
The ship, and hence each element, buoyancy,
stiffness due to buoy-
stiffness due to roll. When evaluating the stiffness associated
with (ii) and with (iii) the effects respectively,
of three parts:
restoring
briefly discussed.
buoyancy
torque,
is influenced
by the following forces:
impact or contact
forces.
These
forces
weight, are now
The weight distribution of the ship is obtained from the standard curve
in the form of tonne per meter.
The weight of each element
is thus estimated
and the
nodal values obtained. The buoyance
force on each element is obtained from the hydrostatic
ship. It is assumed that the immersed cross-sectional (different
constants
for each element).
curves of the
area is constant along each element
The buoyancy force is then adjusted to include
vertical motions of the element relative to the water surface - this merely involves adding the relative displacement heeling is calculated
of the ship onto the static draft. The restoring torque caused by
for each element using the small angle formula with the metacentric
height. The angle of heel for each element is easily deduced from the nodal rotations U3 and Ug shown in Fig. 1. The impact concentrated.
forces are treated as surface tractions and may be either distributed or
They are transferred
to the nodal points using the interpolation
The equation of motion of each element may be expressed
[ml
[cl + Eel lG1 + [kl
WI
in the form
= [sl
where [c] is the damping matrix and [q] is the generalized
force matrix.
matrix.
65
Physical characteristics are: cross-sectional element.
of each station of the ship are taken as input data. These data
area; breadth,
Mass and stiffness
(excluding obtained
contact forces) with respect
frames
matrices
inertias,
mass and length of each
for each element are generated
and external
forces
are included. The global equation of motion for the ship is then
to a fixed external
is accomplished
requirement
depth, two principal
by a series
that the displacement
frame.
Transference
of transfer
matrices.
between
local and gIoba1
Assemblage
at a node shared by two elements
is based on the
must be the same for
both of those elements. The global matrices
of the ship are of the form
[Ml = .p, [Tl’s 14
[‘Us (3)
WI = %;, PI’s [Us Pls [cl = where
.T,iTI’s [cl, [Tls [Tls
stiffness
is the transfer
matrix
and damping matrices
for element
for element
s, [ml,,
and
Ms
[cl,
are the mass,
‘s’. The global equation of motion for the ship
is then [Ml
(4)
[=I + [Cl 161 + WI PI = IQ3
where
[Ql= ,p,ITI's [q]s
When assembling
the global equation of motion (4) there is a matrix overlap of size 5
x 5 between adjacent at the common number
elements
of elements.
Equations
Clearly
the matrices
usual way by determining trix is a linear
the eigenvalues,
coordinates.
combination
damping.
requirement
constructing
This necessitates
They are uncoupled in the
the modal matrix,
the assumption matrices,
usually
supply.
records
to as
(9 dissipation
a and p can then be found from the logarithmic response
referred
we write
The main cause of damping is due to hydrodynamic tional
and then trans-
that the damping ma-
[Cl = 4Ml+ /%I ficients
where n is the
[U] and [Q] are columnar.
coupled equations.
of the mass and stiffness
Accordingly
on the displacements
in (4) are of size S(n+l),
[M], [C] and [K] are square,
(4) are a set of simultaneous
forming to principal proportional
due to the assemblage
node. Consequently
in heave and pitch.
Such records
of energy. Damping coef-
decrement
of the ship vibra-
are available
but in limited
66
uncoupled
The
difference
method.
in the following
equations
incrementally
The grounding and collision
using a second
forces are interactive
The nature of the contact
either explicitly or implicitly.
Examples
coefficients
involving one or
force relative to ship position must be considered
are : the ship and object are
rigid; the ship is rigid but the object crushes with a specified object is rigid but the ship becomes
order finite
and are dealt with
way. The position of initial contact must be specified,
more nodal positions. specified,
are integrated
constitutive
behaviour;
the
crushed or torn. In the latter case, certain strength
of the Minorsky type involving crushing strength both laterally and longitudi-
nally must be used together with tearing strengths obtained from [13]. During the integration process,
the position of the ship must be checked and the contact force updated to its
new value. In the case of separation
or rebound the force must be cancelled.
The extent
of the contact force is allowed to move as the motion proceeds so that new nodal positions may become
involved as time increases.
Some typical grounding scenarios
which have been examined
using this method are
now presented. SIMULATION
RESULTS
We consider thousand
tonne.
OF TANKER
SHIP GROUNDINGS
a very large tanker ship of length 330 meters The mass and buoyancy
and displacement
260
curves are shown in Fig. 2. Other required
geometry is given in Table 1. This ship is referred to as the ‘Standard Tanker Ship’ about which various parameters Added mass coefficients
are changed. The yield strength of the hull is taken as 280 MFa. in heave, sway and surge are taken as 0.75,
tively. The natural frequencies
(first six) were calculated
0.6 and 0.1 respec-
and are identified
in Table 2.
The ship is assumed to be running ahead when it strikes a smooth rock, 1.5 meters below water level, 17 meters to the port side. It is assumed that the smooth rock does not tear the hull plating, but volumetric
damage of the Minorsky type does occur.
I
1000
t
AP
Fig. 2. (a) Massdistribution
FP
and (b) 3uoyancy
AP
distribution
FP
for standard ship
67
TABLE
1 - Specification
STATION No.
STATION LENGTH meter
Tanker
32 38 42 :;
33 33 33 33 33
42 42 42 41 40
22 22 22 22 22 22 22 22 22 22
2 - Natural Frequencies
of the Ship Frequency
Mode Number
Ship’ at the Stations
STATION DRAFT meter
STATION 3READTI-I meter
33 33 33 z;
1
2 3 4 5 6 7 8 9 10
TABLE
of the ‘Standard
STATION MOMENT SHAPE FCT. Iv m4 5 7 8 :
Fig. 3 shows the extent of damage
8 8 8 7 5
360 400 600 600 600 600 600 600 400 400
Mode Shape
( Hz)
sustained
ii-l4
500 600 800 800 800 800 800 800 600 600
0.154 0.186 0.426 1.638 1.751 4.307
1
2 3 4 5 6
OF INERTIA I
Heave Pitch Roll 1st Vertical 1st Lateral 1st torsional by the hull for forward velocities
m/set, 3 m/set, 5 m/set and 7 m/set. For the low speeds the hull receives impulse near the bow which changes the angular momentum rock but the combined near midships catastrophic importance
forward motion and angular motions cause a secondary
and separation
from the rock does not occur.
inflicting
considerable
show the force and
structuraf
damage to the ship, a process
only by
which can last for up to
half the length of the ship. structural
for an identical
bled. The reduced damage Next we consider
and are shown in Fig. 4 for the higher speeds. It
kinetic energy of such a large ship can be absorbed
The effect of increased age estimates
The figures
collision are rather
clearly
that the initial
one minute and damage
estimates
speed on the nature and extent of the damage. Collision
contact times have also been determined is evident
of the ship. It then clears the
which bring it to rest. For high speeds the damage
of collision
of 1
a damaging
scenario
strength has been examined.
Fig. 5 shows the dam-
except that the ship structural
steel has been dou-
is .evident in each case.
what happens when the ship plating is ruptured,
ship runs over a sharp rock. The damage inflicted
as is likely if the
to the standard tanker for the range of
68
0
(a)
SO
100
f-p.
150 SHXP
200
LENGTH
250
300 &.P.
(M)
A, -----
Z
(b)
VERTIC. HOR:ZO.
DAMAGE DAMAGE
f.P.’
0
(cl
~~-L
f.P.
I_~~~;:
.CI
3c
[
” I
(d)
c”, .
I
1
,
100
150 swrr
LENGTH
I
1
1
200
25D
300
(Ml
L.C.
Fig. 3. Extent of damage to standard hull without rupture (a) V = lm/sec, (b} v=3 mkec, (c) v = 5 rnkec, (d) v = 7 mlsec.
69
80
v=Sm/s
z
z
40
E
d
i,\, 0
0
50
25
30 set
'IS
set
Fig. 4. Collision velocities
force on the standard hull versus time.
considered
previously, is shown in Fig. 6. It exceeds that shown in Fig. 4 for the
simple reason that a torn plate absorbs less energy than a dented one, primarily because the torn plate has little membrane Finally we illustrate maneuvering.
strength.
what happens to a ship when it grounds on a smooth rock during
We take a forward speed of 2 m/set and fore and aft rotational speeds of 2
m/set and 0.5 m/see. The rock is 15 meters below the surface, the hull, with centre of collision
extends over 20 meters of
50 meters from the bow. The force and damage calcula-
tions are shown in Fig. 7. As a results of the initial impact force, from the rock and the damage depth subsequently been included
to show that the interaction
fundamentally
different
from a normal head-on
The number of variables
decreases
and response
and scenarios
comprehensive
investigation
with time. This example
due to a rotational
has
collision
is
collision.
which may be examined
great. In this paper we have merely demonstrated oped and that it can be used to investigate
the ship moves away
are obviously very
that a working model has been devel-
many real ship-grounding
is included in the thesis
situations.
A more
[18] but ongoing case studies are
also being made. CONCLUDING
REMARKS
The consequences releases
of what happens when a tanker ship runs aground and spills oil or
liquid natural gas is a subject of much current interest. By making mathematical
models of a grounding ship and determining design
criteria
can be established
safety standards can be increased be shown to be structurally
the interactive
and subsequently
forces that the ship receives,
incorporated.
By such processes
and ships that might otherwise have been breached
sound under specified
A finite element model developed at the University of British Columbia ship grounding been illustrated.
incidents
has been described
Such illustrations
and a number
clarify the complex
ship motion and grounding force. This clarification
can
operating conditions.
of realistic
interaction
which models situations
have
which exists between
can assist in the improved structural
design of LNG and tanker ships so that spill incidents will be less likely to occur, even if grounding does occur.
70 1
VERTIC.
---I-
2
HORIZO.
OAMJGE DAMAGE
_
0
..-
(=I
I
I
I
50
100
150
F.P.
I
200
2;o
LE?rGTW (M)
SHIP
A ----.
(b)
VERTIC.
OAwh;E
HORIZO.
OAMAGE
F.P.
fc) A
F.P. 4
SHIP
LE’GfH
A.P.
(M) -----
VEFITICdL OhMatE HORIZONTAL DAMAGE
2
0 0 td)
F.P.
SO
100
150 SHIP
LEYGTH
too
250
(M)
Fig. 5. Extent of damage due to forward collision without rupture of the reinforced hull (a) v = 1 mkec. (b) v = 3 mkec. (c) v = 5 m/set, (d) v = 7 rdsec.
A.P.
71
(a)
SHIP
F.P. 4
LENGTH
(M:
7
VERTIC. HoRIzo.
-*---
3
SO
0
(bl
A.P.
101
F.P.
2c:
150 SHIP
LENGTH
250
DAMAGE OAWAGE
300 A.P.
(“:
A
----’
I
/ 0 (=I
I
i
50
150
r.p.
SHIP
2c7
i
1
250
300 A.P.
----.
VERTIC. HORIZO.
DAMAGE DAMAGE
pzzq
*
T.P.
SO
I
6
I 0 (6)
OAmAGE OAMAGE
(“1 ,
LENGTH
A
1:
VERTIC. HORIZO.
100
2””_I
150 SHIP
LENGTH
(“1
250
300 A.P.
Fig. 6. Extent of damage due to forward collision with rupture of the standard hull. (a) v = 1 m/set, (b) v = 3 mkec, (c) v = 5 mkec, (d) v = 7 mkec.
72
0
a.23
0.s
0.75
1
COLLISION
(a)
1.2s TIME
1.5
(b)
-
0.25
0.5
u.75
1
1.2s
COLLISION TIME
2
2.25
(SEC.)
3,
0
1.7s
1.5
VERTICAL
1.75
[SEC.)
Fig. 7. (a) Generated force and (b) extent of damage due to the side coffision of the standard hull during maneuver.
CAMAGE
2.5
73
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12.
13. 14. 15. 16. 17. 18.
Structural Crashworthiness, N. Jones, “Structural Aspects of the Ship Collisions”, Jones and Wierzbicki, Butterworths, 1983, pp. 309-332 P.A. Frieze, R.C. McGregor and I.E. Winkle, “Marine and Offshore Safety”, Elsevier, 1984. W. Johnson and A.G. Mama& “Crashworthiness of Vehicles”, Mechanical Engineering Publications Ltd., London, 1978. A.N. Kinkead, “Some Collision and Grounding Considerations for Refrigerated Marine and Offshore Safety, Frieze, McGregor and Winkle, ElGas Carriers”, sevier, 1984, pp. 159-182. of Double Bottoms in Preventing Oil Outflow from J.C. Card, “Effectiveness Tanker Bottom Damage Incidents”, Marine Technology, 197.5, pp. 60-64. N. Jones, “Plastic Behaviour of Ship Structures”, Transactions of the Society of Naval Architects and Marine Engineers, Vol. 84, 1976, pp. 115-145. N. Jones, “A Literature Survey on the Collision and Grounding Protection of 1979, U.S. Coast Guard, Washington, D.C. Ships”, Report SSC-283, V.U. Minorsky, “An Analysis of Ship Collisions with Reference to Protection of Nuclear Power Plants”, Journal of Ship Research, Vol. 3, 1959, pp. 1-4. H. Vaughan, “Bending and Tearing of Plate with Application to Ship-Bottom Damage”. ‘The Naval Architect’, Journal of the Royal Institution of Naval Architects, May.1978, pp. 97-99. H. Vaughan, “Damage to Ships Due to Collision and Grounding”, Det norske Veritas. Oslo. Technical Renort 77-345. August 1977. of Structural Damage on Kockums K.R. Johnsen and H. Vaug’han, “Estimatio; 133000 m3 Liquid Natural Gas Carrier Due to Collision and Grounding”, Det norske Veritas, Oslo, Technical Report 77-275, July 1977. J. Poudret, M. Huther, P. Jean and H. Vaughan, “Grounding of a Membrane Tanker, Correlation Between Damage Predictions and Observations”, Symposium on Extreme Loads, Arlington, pp. 125-132, Society of Naval Architects and Marine Engineers, 1981. H. Vaughan, “The Tearing Strength of Mild Steel Plate”, Journal of Ship Research, Vol. 24, June 1980, pp. 96-100. N. Jones and W.S. Jouri, “A Study of Plate Tearing for Ship Collision and Grounding Damage” Journal of Ship Research, Vol. 31, 1987, pp. 253-268. of an B.M. Johansson, A.J. Keinonen and B. Mercer, “Technical Development Environmentally Safe Tanker”, SNAME, Proceedings of the STAR Symposium, June 1981. I.F. Glen, C.G. Daley and G. Tam, “Analysis of the Structure of the Proposed CCG Polar Class 8 Ice Breaker Under Extreme Ice Loads”, Transactions SNAME, 1985. H. Vaughan, “Flexural Response of Ships to Impact Loads”, Transactions of the Royal Institution of Naval Architects, Vol. 128, 1986, pp. 259-267. G.V. Asadi, “Dynamic Response of Ship Structures to Impact Loads”, Ph.D. Thesis, University of British Columbia, May 1989.
25 (1990)
61
61-73
Elsevier Science Publishers B.V., Amsterdam
DYNAMICS AGROUND
AND STRUCTURAL
DAMAGE
G.V. ASADI and H. VAUGHAN Department of Mechanical Engineering,
OF TANKER
University
SHIPS RUNNING
of British Columbia
( Canada)
SUMMARY
A finite element method is described which models a ship impacting against another object. The ship is modeled as a beam which has the same flexibility, mass distribution and floatation properties as the ship. The ship structure may collapse locally during the ongoing collision process as also may the struck object. A number of collision scenarios involving the collision of a large tanker-ship with a submerged rigid rock are investigated. The significance of ship speed on the extent and nature of the damage to the hull is established. INTRODUCTION Grounding
incidents,
by their very nature,
docking facility and sometimes crude-oil
spill with its disastrous
demonstrated
recently
being damaged
effects
on local ecology
on the Alaska coast.
and releasing
The parallel
The consequences
of a large
and environment
have been
situation of a LNG tanker ship
upwards of one hundred thousand tonnes of liquid natural
gas in the form of an unconfined not occurred.
occur in shallow waters, often close to a
near populated land masses.
heavy and toxic flammable
gas-cloud
Such ships are usually protected at the sides by collision
has fortunately
barriers
and from
below by a “double bottom” which raises the LNG tanks a meter or so above the bottom plate of the hull. Engineers ticularly
have responded
in the automotive
industry. The literature recent conference
to the demands for improved safety against collision
industry and to a lesser
on “crashworthiness”
proceedings
degree in the general
par-
transportation
is fairly recent and limited although several
and textbooks
have been devoted to it, see for example
111, PI, and ]3]. Some revealing
statistics
on marine damage incidents
gives data on one thousand serious tanker casualties IMCO (International
Maritime
Consultative
are given by Kinkead
by category of casualty,
Organization)
portation
or grounding
(165 collision,
were caused by
It is the major hazard in the trans-
of oils and gases at sea.
The effectiveness
of double bottoms
tankers has been demonstrated although
239 grounding).
by
during the period 1968 to 1980.
The data shows that slightly more than four hundred of those incidents collision
[4]. He
collected
effective
against
above the struck object,
0304-3894/90/$03.50
in the prevention
shallow penetration
of the hull, merely by keeping the cargo
it gives a very limited protection
0 -
of oil outflow from grounded
by Card [S]. A double bottom is a passive system and against
1990 Elsevier Science Publishers B.V.
deep penetration,
as
62
could occur when a ship strikes a sharp reef or ice-flow. stronger hull based on knowledge of estimated beyond the elastic
processes
considerable
and grounding
APPROACHES
In this section we categorize
TO SHIP COLLISION
which have been found to be appropriate
im-
reviewed.
ship damage and ship collisions
for the study of ship collision
the interactive
with a view towards
safety. This work is now briefly
REVIEW OF TECHNICAL DAMAGE
ence frames
work has been done to understand
involved in ship collisions
proved design and increased
cal models
to design a
limit.
In the last decade structural
Then it is necessary
impact forces and using design codes well
AND GROUNDING
into some analytic refer-
for purposes of developing theoreti-
damage.
Firstly
we clarify
minor and major
collisions. A minor collision
is one in which the ship structure
plastic strains to the shell plating or stiffeners. neither
is there any fracture
or plate tearing caused by external
This means that all strength members slightly reduced
level. Significant
which minor collision by Jones
continue to be effective
contributions
of the hull.
the criteria
useful in the preliminary
or restricted
See for example
to the barrier.
A major collision of plate leading Such collisions of structural
cannot
material
destroyed
design of protec-
using classical
[8] is commonly
theories
to the energy absorbed
[ll],
or tearing parts.
and plasticity. the latter being to be used in
method occurs when a ship
but consists
plied to general grounding problems.
of tom plating, per-
in length.
A method
for
[9] and applied by him to some
and [12]. Some dimensional
of small scale tests by Vaughan
erably extended
[7].
for many types of ships.
was first proposed by Vaughan [lo],
distortion
of the damaged
in the collision,
in width but up to one hundred meters
LNG tanker groundings
protection
of elasticity
which cannot be analyzed by Minorsky’s
such incidents
cargo.
used which merely relates the volume
The damage is then often not volumetric
haps only one meter
from a series
paper on collision
energy of the ship. A range of coefficients
method are available
A major collision
Jones’
loss in strength and effectiveness
be analyzed
to the loss in kinetic
runs aground.
under
occurs then the damage is minor
is one in which there is some gross structural
to significant
Instead a method due to Minorsky
examining
penetration
which are built into the sides of specialty ships which carry hazardous is to ensure that if collision
Minorsky’s
or small
although possibly at some
towards understanding
Clearly the design criterion
related
only elastic
damage occurs and the nature of the damage has been developed
[6]. This work has been particularly
tion barriers
sustains
No gross distortion of the structure occurs
effects
were determined
[13] which allowed his method to be ap-
His experiments
were recently repeated
and consid-
by Jones and Jouri [14].
In the late 1970’s
and early 1980’s a considerable
ships in the form of ice breakers,
ice-strengthened
effort went into the design of arctic freighters,
and particularly
ice-break-
63
ing supertankers. financially
At that time the high price of oil made the exploitation
attractive.
A design for a supertanker
posed by Johansson
successful, onstrate
particularly
created
has progressed,
towards safer
tonne displacement. through improved
ships in harsher
designs for ships in which collision
The strongest breaker,
capable
been proposed, greatest
damage
of operating
ELEMENT
and bending moments
We now describe
details
state the equations
Coast Guard is a Class Eight icedesigns
by Glen and Daley [16]. Estimates derived by Vaughan
OF SHIP COLLISION
have of the
of ships of
[17].
AND GROUNDING
a finite element analysis recently developed by the authors in which
some new damage mechanisms the mathematical
instead of “major”.
likely to occur during operation
using simple formulas
ANALYSIS
is “minor”
of collision
They have effectively
in eight feet of level ice at 3 knots. Several
one of which has been assessed
impact forces
were also extremely
All of these ships dem-
understanding
environments.
ship yet proposed for the Canadian
this type can be obtained FINITE
Other designs for ice-breakers
in the range of 7,000
how the designer effects,
general purpose
was built a decade ago to carry ore from the Hudson Bay to North-
which is still in operation.
and impact
to withstand ice impact forces was pro-
[15]. The ship was not built, but an ice-strengthened
ship, the M.V. Arctic, ern Europe,
of the Arctic
for ships have been investigated
since they are derived in complete
[18]. We do not include
detail in [18].
of motion that have been solved, then concentrate
We merely
on the results that
have been obtained. The ship is modelled ment matrix
as a floating beam divided into n stations.
is denoted by [U] and the displacement
The nodal displace-
[u] at any point in the body is then
given by (1)
1~1= N WI where [N] is the interpolation motion
therefore
reduced from twelve to ten, as shown in Fig. 1. The (10 x 10) mass matrix of
the element
is considered
function matrix. The ship is assumed to be axially rigid and
its axial
separately.
The degrees
of freedom
of each element
is
is [m] = [ml] + [ma], where [ml] is due to lateral inertia and [m2] is due to
rotary inertia.
Fig. 1. The beam element
with ten degrees of freedom.
64
In the analysis
it is mathematically
convenient
to represent
rigid-body
motions as
special cases of the dynamic flexural motions. Thus the natural frequency matrix includes as its leading elements
the rigid-body
periodic motions in heave, pitch and roll, respec-
tively. This was made possible by treating each beam element as a free-free consequently
admits rigid-body
The simuhaneous
displacements
treatment
beam which
as well as elastic vibrational motions.
of rigid-body
motions
and flexural
motions
enables
added mass to be included in [m] in the form of a frequency dependent matrix. The three leading elements
of the added mass matrix
correspond
again to heave, pitch and roll
whereas the later elements have to be identified with the appropriate either a vertical,
lateral,
or torsional
mode,
starting with the fundamental
working up to the desired number of higher harmonics. later in this paper.
Added mass coefficients
mode of vibration,
A particular
for transient
water are difficult to assess so in the numerical
modes
example
impulse motions
calculations
discussed
and
is given
in shallow
later, deep water
values for sinusoidal motions have been used The stiffness matrix of the element is denoted by [k]. It is composed (i) the elastic structural
stiffness of the hull, (ii) the hydrodynamic
ancy, (iii) the hydrodynamic
of flexural
vibration and torsion have been included
as well as the rigid body motions in heave, pitch and roll.
The ship, and hence each element, buoyancy,
stiffness due to buoy-
stiffness due to roll. When evaluating the stiffness associated
with (ii) and with (iii) the effects respectively,
of three parts:
restoring
briefly discussed.
buoyancy
torque,
is influenced
by the following forces:
impact or contact
forces.
These
forces
weight, are now
The weight distribution of the ship is obtained from the standard curve
in the form of tonne per meter.
The weight of each element
is thus estimated
and the
nodal values obtained. The buoyance
force on each element is obtained from the hydrostatic
ship. It is assumed that the immersed cross-sectional (different
constants
for each element).
curves of the
area is constant along each element
The buoyancy force is then adjusted to include
vertical motions of the element relative to the water surface - this merely involves adding the relative displacement heeling is calculated
of the ship onto the static draft. The restoring torque caused by
for each element using the small angle formula with the metacentric
height. The angle of heel for each element is easily deduced from the nodal rotations U3 and Ug shown in Fig. 1. The impact concentrated.
forces are treated as surface tractions and may be either distributed or
They are transferred
to the nodal points using the interpolation
The equation of motion of each element may be expressed
[ml
[cl + Eel lG1 + [kl
WI
in the form
= [sl
where [c] is the damping matrix and [q] is the generalized
force matrix.
matrix.
65
Physical characteristics are: cross-sectional element.
of each station of the ship are taken as input data. These data
area; breadth,
Mass and stiffness
(excluding obtained
contact forces) with respect
frames
matrices
inertias,
mass and length of each
for each element are generated
and external
forces
are included. The global equation of motion for the ship is then
to a fixed external
is accomplished
requirement
depth, two principal
by a series
that the displacement
frame.
Transference
of transfer
matrices.
between
local and gIoba1
Assemblage
at a node shared by two elements
is based on the
must be the same for
both of those elements. The global matrices
of the ship are of the form
[Ml = .p, [Tl’s 14
[‘Us (3)
WI = %;, PI’s [Us Pls [cl = where
.T,iTI’s [cl, [Tls [Tls
stiffness
is the transfer
matrix
and damping matrices
for element
for element
s, [ml,,
and
Ms
[cl,
are the mass,
‘s’. The global equation of motion for the ship
is then [Ml
(4)
[=I + [Cl 161 + WI PI = IQ3
where
[Ql= ,p,ITI's [q]s
When assembling
the global equation of motion (4) there is a matrix overlap of size 5
x 5 between adjacent at the common number
elements
of elements.
Equations
Clearly
the matrices
usual way by determining trix is a linear
the eigenvalues,
coordinates.
combination
damping.
requirement
constructing
This necessitates
They are uncoupled in the
the modal matrix,
the assumption matrices,
usually
supply.
records
to as
(9 dissipation
a and p can then be found from the logarithmic response
referred
we write
The main cause of damping is due to hydrodynamic tional
and then trans-
that the damping ma-
[Cl = 4Ml+ /%I ficients
where n is the
[U] and [Q] are columnar.
coupled equations.
of the mass and stiffness
Accordingly
on the displacements
in (4) are of size S(n+l),
[M], [C] and [K] are square,
(4) are a set of simultaneous
forming to principal proportional
due to the assemblage
node. Consequently
in heave and pitch.
Such records
of energy. Damping coef-
decrement
of the ship vibra-
are available
but in limited
66
uncoupled
The
difference
method.
in the following
equations
incrementally
The grounding and collision
using a second
forces are interactive
The nature of the contact
either explicitly or implicitly.
Examples
coefficients
involving one or
force relative to ship position must be considered
are : the ship and object are
rigid; the ship is rigid but the object crushes with a specified object is rigid but the ship becomes
order finite
and are dealt with
way. The position of initial contact must be specified,
more nodal positions. specified,
are integrated
constitutive
behaviour;
the
crushed or torn. In the latter case, certain strength
of the Minorsky type involving crushing strength both laterally and longitudi-
nally must be used together with tearing strengths obtained from [13]. During the integration process,
the position of the ship must be checked and the contact force updated to its
new value. In the case of separation
or rebound the force must be cancelled.
The extent
of the contact force is allowed to move as the motion proceeds so that new nodal positions may become
involved as time increases.
Some typical grounding scenarios
which have been examined
using this method are
now presented. SIMULATION
RESULTS
We consider thousand
tonne.
OF TANKER
SHIP GROUNDINGS
a very large tanker ship of length 330 meters The mass and buoyancy
and displacement
260
curves are shown in Fig. 2. Other required
geometry is given in Table 1. This ship is referred to as the ‘Standard Tanker Ship’ about which various parameters Added mass coefficients
are changed. The yield strength of the hull is taken as 280 MFa. in heave, sway and surge are taken as 0.75,
tively. The natural frequencies
(first six) were calculated
0.6 and 0.1 respec-
and are identified
in Table 2.
The ship is assumed to be running ahead when it strikes a smooth rock, 1.5 meters below water level, 17 meters to the port side. It is assumed that the smooth rock does not tear the hull plating, but volumetric
damage of the Minorsky type does occur.
I
1000
t
AP
Fig. 2. (a) Massdistribution
FP
and (b) 3uoyancy
AP
distribution
FP
for standard ship
67
TABLE
1 - Specification
STATION No.
STATION LENGTH meter
Tanker
32 38 42 :;
33 33 33 33 33
42 42 42 41 40
22 22 22 22 22 22 22 22 22 22
2 - Natural Frequencies
of the Ship Frequency
Mode Number
Ship’ at the Stations
STATION DRAFT meter
STATION 3READTI-I meter
33 33 33 z;
1
2 3 4 5 6 7 8 9 10
TABLE
of the ‘Standard
STATION MOMENT SHAPE FCT. Iv m4 5 7 8 :
Fig. 3 shows the extent of damage
8 8 8 7 5
360 400 600 600 600 600 600 600 400 400
Mode Shape
( Hz)
sustained
ii-l4
500 600 800 800 800 800 800 800 600 600
0.154 0.186 0.426 1.638 1.751 4.307
1
2 3 4 5 6
OF INERTIA I
Heave Pitch Roll 1st Vertical 1st Lateral 1st torsional by the hull for forward velocities
m/set, 3 m/set, 5 m/set and 7 m/set. For the low speeds the hull receives impulse near the bow which changes the angular momentum rock but the combined near midships catastrophic importance
forward motion and angular motions cause a secondary
and separation
from the rock does not occur.
inflicting
considerable
show the force and
structuraf
damage to the ship, a process
only by
which can last for up to
half the length of the ship. structural
for an identical
bled. The reduced damage Next we consider
and are shown in Fig. 4 for the higher speeds. It
kinetic energy of such a large ship can be absorbed
The effect of increased age estimates
The figures
collision are rather
clearly
that the initial
one minute and damage
estimates
speed on the nature and extent of the damage. Collision
contact times have also been determined is evident
of the ship. It then clears the
which bring it to rest. For high speeds the damage
of collision
of 1
a damaging
scenario
strength has been examined.
Fig. 5 shows the dam-
except that the ship structural
steel has been dou-
is .evident in each case.
what happens when the ship plating is ruptured,
ship runs over a sharp rock. The damage inflicted
as is likely if the
to the standard tanker for the range of
68
0
(a)
SO
100
f-p.
150 SHXP
200
LENGTH
250
300 &.P.
(M)
A, -----
Z
(b)
VERTIC. HOR:ZO.
DAMAGE DAMAGE
f.P.’
0
(cl
~~-L
f.P.
I_~~~;:
.CI
3c
[
” I
(d)
c”, .
I
1
,
100
150 swrr
LENGTH
I
1
1
200
25D
300
(Ml
L.C.
Fig. 3. Extent of damage to standard hull without rupture (a) V = lm/sec, (b} v=3 mkec, (c) v = 5 rnkec, (d) v = 7 mlsec.
69
80
v=Sm/s
z
z
40
E
d
i,\, 0
0
50
25
30 set
'IS
set
Fig. 4. Collision velocities
force on the standard hull versus time.
considered
previously, is shown in Fig. 6. It exceeds that shown in Fig. 4 for the
simple reason that a torn plate absorbs less energy than a dented one, primarily because the torn plate has little membrane Finally we illustrate maneuvering.
strength.
what happens to a ship when it grounds on a smooth rock during
We take a forward speed of 2 m/set and fore and aft rotational speeds of 2
m/set and 0.5 m/see. The rock is 15 meters below the surface, the hull, with centre of collision
extends over 20 meters of
50 meters from the bow. The force and damage calcula-
tions are shown in Fig. 7. As a results of the initial impact force, from the rock and the damage depth subsequently been included
to show that the interaction
fundamentally
different
from a normal head-on
The number of variables
decreases
and response
and scenarios
comprehensive
investigation
with time. This example
due to a rotational
has
collision
is
collision.
which may be examined
great. In this paper we have merely demonstrated oped and that it can be used to investigate
the ship moves away
are obviously very
that a working model has been devel-
many real ship-grounding
is included in the thesis
situations.
A more
[18] but ongoing case studies are
also being made. CONCLUDING
REMARKS
The consequences releases
of what happens when a tanker ship runs aground and spills oil or
liquid natural gas is a subject of much current interest. By making mathematical
models of a grounding ship and determining design
criteria
can be established
safety standards can be increased be shown to be structurally
the interactive
and subsequently
forces that the ship receives,
incorporated.
By such processes
and ships that might otherwise have been breached
sound under specified
A finite element model developed at the University of British Columbia ship grounding been illustrated.
incidents
has been described
Such illustrations
and a number
clarify the complex
ship motion and grounding force. This clarification
can
operating conditions.
of realistic
interaction
which models situations
have
which exists between
can assist in the improved structural
design of LNG and tanker ships so that spill incidents will be less likely to occur, even if grounding does occur.
70 1
VERTIC.
---I-
2
HORIZO.
OAMJGE DAMAGE
_
0
..-
(=I
I
I
I
50
100
150
F.P.
I
200
2;o
LE?rGTW (M)
SHIP
A ----.
(b)
VERTIC.
OAwh;E
HORIZO.
OAMAGE
F.P.
fc) A
F.P. 4
SHIP
LE’GfH
A.P.
(M) -----
VEFITICdL OhMatE HORIZONTAL DAMAGE
2
0 0 td)
F.P.
SO
100
150 SHIP
LEYGTH
too
250
(M)
Fig. 5. Extent of damage due to forward collision without rupture of the reinforced hull (a) v = 1 mkec. (b) v = 3 mkec. (c) v = 5 m/set, (d) v = 7 rdsec.
A.P.
71
(a)
SHIP
F.P. 4
LENGTH
(M:
7
VERTIC. HoRIzo.
-*---
3
SO
0
(bl
A.P.
101
F.P.
2c:
150 SHIP
LENGTH
250
DAMAGE OAWAGE
300 A.P.
(“:
A
----’
I
/ 0 (=I
I
i
50
150
r.p.
SHIP
2c7
i
1
250
300 A.P.
----.
VERTIC. HORIZO.
DAMAGE DAMAGE
pzzq
*
T.P.
SO
I
6
I 0 (6)
OAmAGE OAMAGE
(“1 ,
LENGTH
A
1:
VERTIC. HORIZO.
100
2””_I
150 SHIP
LENGTH
(“1
250
300 A.P.
Fig. 6. Extent of damage due to forward collision with rupture of the standard hull. (a) v = 1 m/set, (b) v = 3 mkec, (c) v = 5 mkec, (d) v = 7 mkec.
72
0
a.23
0.s
0.75
1
COLLISION
(a)
1.2s TIME
1.5
(b)
-
0.25
0.5
u.75
1
1.2s
COLLISION TIME
2
2.25
(SEC.)
3,
0
1.7s
1.5
VERTICAL
1.75
[SEC.)
Fig. 7. (a) Generated force and (b) extent of damage due to the side coffision of the standard hull during maneuver.
CAMAGE
2.5
73
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12.
13. 14. 15. 16. 17. 18.
Structural Crashworthiness, N. Jones, “Structural Aspects of the Ship Collisions”, Jones and Wierzbicki, Butterworths, 1983, pp. 309-332 P.A. Frieze, R.C. McGregor and I.E. Winkle, “Marine and Offshore Safety”, Elsevier, 1984. W. Johnson and A.G. Mama& “Crashworthiness of Vehicles”, Mechanical Engineering Publications Ltd., London, 1978. A.N. Kinkead, “Some Collision and Grounding Considerations for Refrigerated Marine and Offshore Safety, Frieze, McGregor and Winkle, ElGas Carriers”, sevier, 1984, pp. 159-182. of Double Bottoms in Preventing Oil Outflow from J.C. Card, “Effectiveness Tanker Bottom Damage Incidents”, Marine Technology, 197.5, pp. 60-64. N. Jones, “Plastic Behaviour of Ship Structures”, Transactions of the Society of Naval Architects and Marine Engineers, Vol. 84, 1976, pp. 115-145. N. Jones, “A Literature Survey on the Collision and Grounding Protection of 1979, U.S. Coast Guard, Washington, D.C. Ships”, Report SSC-283, V.U. Minorsky, “An Analysis of Ship Collisions with Reference to Protection of Nuclear Power Plants”, Journal of Ship Research, Vol. 3, 1959, pp. 1-4. H. Vaughan, “Bending and Tearing of Plate with Application to Ship-Bottom Damage”. ‘The Naval Architect’, Journal of the Royal Institution of Naval Architects, May.1978, pp. 97-99. H. Vaughan, “Damage to Ships Due to Collision and Grounding”, Det norske Veritas. Oslo. Technical Renort 77-345. August 1977. of Structural Damage on Kockums K.R. Johnsen and H. Vaug’han, “Estimatio; 133000 m3 Liquid Natural Gas Carrier Due to Collision and Grounding”, Det norske Veritas, Oslo, Technical Report 77-275, July 1977. J. Poudret, M. Huther, P. Jean and H. Vaughan, “Grounding of a Membrane Tanker, Correlation Between Damage Predictions and Observations”, Symposium on Extreme Loads, Arlington, pp. 125-132, Society of Naval Architects and Marine Engineers, 1981. H. Vaughan, “The Tearing Strength of Mild Steel Plate”, Journal of Ship Research, Vol. 24, June 1980, pp. 96-100. N. Jones and W.S. Jouri, “A Study of Plate Tearing for Ship Collision and Grounding Damage” Journal of Ship Research, Vol. 31, 1987, pp. 253-268. of an B.M. Johansson, A.J. Keinonen and B. Mercer, “Technical Development Environmentally Safe Tanker”, SNAME, Proceedings of the STAR Symposium, June 1981. I.F. Glen, C.G. Daley and G. Tam, “Analysis of the Structure of the Proposed CCG Polar Class 8 Ice Breaker Under Extreme Ice Loads”, Transactions SNAME, 1985. H. Vaughan, “Flexural Response of Ships to Impact Loads”, Transactions of the Royal Institution of Naval Architects, Vol. 128, 1986, pp. 259-267. G.V. Asadi, “Dynamic Response of Ship Structures to Impact Loads”, Ph.D. Thesis, University of British Columbia, May 1989.