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Chapter 7 : Trials

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Title: Chapter 7 : Trials


1
Chapter 7 Trials
2
Ch7. Sea trials / Manoeuvring characteristics of
ships
  • IMO Recommendations MSC 137(76)
  • The manoeuvrability of ships can be evaluated
    from the characteristics of conventional trial
    manoeuvres.
  • Two methods can be used
  • Scale model tests or computer predictions using
    mathematical models at the design stage / full
    scale trials must be conducted to validate these
    results
  • Full scale trials
  • Test speed at least 90 of full speed 85 of
    full engine power

3
Ch7. Sea trials / Manoeuvring characteristics of
ships
  • Imo Manoeuvring Standards
  • By resolution A.751(18) in 1993 IMO adopted
    Manoeuvring Standards
  • The standards apply to
  • All ships of 100m in lenght and over
  • All chemical tankers and gas carriers
  • They consist of
  • Turning circles to Port and starboard
  • Stopping Test
  • Zig-Zag Test

4
Ch7. Sea trials / Manoeuvring characteristics of
ships
  • Conditions at which the standards apply
  • In order to evaluate the performance of a ship,
    manoeuvring trials should be conducted to both
    port and starboard and at conditions specified
    below
  • .1 deep, unrestricted water (gt 4xmean draft)
  • .2 calm environment (Windlt 5Bft / Sealt 4)
  • .3 full load (summer load line draught), even
    keel condition
  • .4 steady approach at the test speed(min90
    full).

5
Ch7. Sea trials / Manoeuvring characteristics of
ships
  • Manoeuvring performance has traditionally
    received little attention during the design
    stages of a commercial ship.
  • Consequently some ships have been built with very
    poor manoeuvring qualities, resulting in marine
    casualties / pollution.
  • Designers have relied on shiphandling abilities
    of human operators to compensate for deficiencies
    in inherent manoeuvring qualities of the hull.
  • The implementation of manoeuvring standards will
    ensure that ships are designed to a uniform
    standard, so that an undue burden is not imposed
    on shiphandlers in trying to compensate for
    deficiencies in inherent ship manoeuvrability.
  • (Extract of IMO MSC/Circ1053)

6
Ch7. Sea trials / Preliminary
  • Forces and motions in manoeuvrability
  • Definition of the Pivot Point
  • the point around which the ship rotates
  • The centre of the hydrodynamic forces acting on
    the ships hull
  • Position of the Pivot Point
  • Depends on the shape of the hull
  • With no forward speed pivot point at midship
  • At speed pivot point shifts forward

7
Ch7. Sea trials /Preliminary
The Pivot Point at forward speed
8
Ch7. Sea trials / Manoeuvring characteristics of
ships
  • 1. Course keeping ability and dynamic stability
  • Dynamically stable ship moves along a new
    straight course without using rudder after a
    small disturbance
  • Dynamically unstable ship performs turning circle
    with rudder amidship
  • More difficult to handle dynamically unstable
    ships
  • Infos on course keeping and dynamic stability
    obtained from  Initial turning test 

9
Ch7. Sea trials / Manoeuvring characteristics of
ships
Dynamic stability dynamically stable ships
maintain A straight course with zero rudder
Dynamically unstable ships can only maintain a
straight course by repeated use of rudder control
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Ch7. Sea trials / Manoeuvring characteristics of
ships
  • Factors determining the Directional stability of
    vessels
  • Increase with the depth of the water
  • Increase with the lenght of the ship
  • Increase with Trim by the stern
  • Decrease with big blockage factor
  • Decrease for large vessel (ratio L/B)
  • Decrease when cross sectional area fwd larger
    than cross sectional area after (pivot point
    moves forward)

12
Ro-Ro ships are directionally unstable
They need more rudder to stop a swing than to
start a swing
13
Ch7. Sea trials / Manoeuvring characteristics of
ships
  • Change of trim
  • Ship by the stern has a better course keeping
    ability
  • Ship by the head
  • Slow to start a swing
  • Difficult to stop a swing
  • In shallow water, a ship gets trim by the head
    and looses directional stability

14
3 STANDARD MANOEUVRES
15
TURNING CIRCLE
Turning circle measure of turning ability of
vessel
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TURNING CIRCLE
  • To determine the turning ability
  • - The measure of the ability of a ship using
    hard-over rudder
  • - The result is a minimum  advance at 90 change
    of heading  and  tactical diameter  defined by
    the  transfer at 180 change of heading 
  • - Tactical diameter is usually given as
    multiplacity of ship lenght
  • The advance should not exceed 4.5 ship lengths
    (L)
  • the tactical diameter should not exceed 5 lengths
  • Turning circle to be performed with 35Rudder
    angle

18
Statendam
Lenght196m / beam25m / 24300DWT / Steamship/ 2
propellers/ 19Knots
19
Advance 426m Transfer 99m Diameter
263m Tact.Dia 290m
Advance 426m Transfer 94m Diameter
258m Tact.Dia 292m
20
Advance the distance traveled in the direction
of the original course by the midship point of a
ship from the position at which the rudder order
is given to the position at which the heading has
changed 900 from the original course.
21
Tactical diameter the distance traveled by the
midship point of a ship from the position at
which the rudder order is given to the position
at which the heading has changed 1800 from the
original course. It is measured in a
direction perpendicular to the original heading
of the ship.
22
TURNING CIRCLE
  • Comments
  • Advance of the ship smaller than the distance
    ahead with an emergency stop manœuvre
  • Request sufficient searoom on the beam (tactical
    diameter)
  • Test are carried out at sea and not in shallow
    waters parameters are bigger in shallow water
    because rudder effect decreases in shallow water
    due to the reduced waterflow
  • Parameters of the turning circle do not change
    for different speeds of the ship

23
TURNING CIRCLE
  • Drift angle and Pivot point
  • The pivot point (D) is at the intersection of the
    longitudinal
  • axis of the vessel with the radius of the turning
    circle
  • The drift angle at the pivot point is zero
  • The drift angle at the centre of gravity (G)

24
TURNING CIRCLE
In shallow waters, the drift angle is smaller
the water resistance decreases and the turning
circle is larger
25
Crablike motion of the ship Water resistance
reduces the speed and the diameter of turning
circle
26
TURNING CIRCLE
Forces acting on a ship when turning
27
TURNING CIRCLE
28
TURNING CIRCLE
  • The turning circle is affected by the effects of
    wind and current

29
Turning characteristics of full and slender ships
30
TURNING CIRCLE
  • Comparison of turning characteristics of full and
    slender ships
  • Two ships of the same lenght have nearly the same
    transfer
  • Tactical diameters almost the same
  • Radius of turning circle smaller for tanker
  • Drift angle much larger for tanker
  • Pivot point closer to the bow in tanker

31
TURNING CIRCLE
Water resistance on starboard Beam during turning
circle
32
ZIG-ZAG TEST
33
ZIG-ZAG TEST (Kempf)
  • Yaw checking ability a measure of
  • the response to counter-rudder (Overshoot angle
    and overshoot time)
  • Measure of the ability to initiate and check
    course changes

Two tests are included the 10/10 and 20/20
tests
10/10 zig-zag test rudder is turned
alternately by 10 to either side following a
heading deviation of 10 from original heading
34
ZIG-ZAG TEST (Kempf)
10/10 Zig-Zag Test
35
ZIG-ZAG TEST/ Procedure
  • after a steady approach, rudder is put over to
    10 to starboard (port) (first execute)
  • when heading has changed to 10 off original
    heading, rudder reversed to 10 to port
    (starboard) (second execute)
  • after the rudder has been turned to
    port/starboard, the ship continues turning in
    original direction with decreasing turning rate.
  • In response to rudder, ship should then turn to
    port/starboard.
  • When ship has reached a heading of 10 to
    port/starboard of the original course the rudder
    is again reversed to 10 to starboard/port (third
    execute).
  • The first overshoot angle is the additional
    heading deviation experienced in the zig-zag test
    following second execute

36
Recommendations of IMO
The value of the first overshoot angle in the
10/10 zig-zag test should not exceed . 10 if
L/V is less than 10 s . 20 if L/V is 30 s or
more and . (5 1/2(L/V)) degrees if L/V is 10 s
or more, but less than 30s where L and V are
expressed in m and m/s, respectively.
The value of the second overshoot angle in the
10/10 zig-zag test should not exceed . 25, if
L/V is less than 10 s . 40, if L/V is 30 s or
more and . (17.5 0.75(L/V)), if L/V is 10 s
or more, but less than 30 s.
37
ZIG-ZAG TEST
38
ZIG-ZAG TEST
  • The 20/20 zig-zag test is performed using the
    same procedure using 20 rudder angles and 20
    change of heading, instead of 10 rudder angles
    and 10 change of heading, respectively.
  • The value of the first overshoot angle in the
    20/20
  • Zig-Zag test should not exceed 25
    Recommendation of IMO MSC 137(76)

39
20/20 Zig-Zag Test
40
STOP
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42
STOPPING TEST
43
STOPPING TEST
  • The "crash-stop" or "crash-astern" manoeuvre is
    mainly a test of engine functioning and propeller
    reversal. The stopping distance is a function of
    the ratio of astern power to ship displacement.

Procedure 1. ship brought to a steady course and
speed 2. The recording of data starts. 3. The
manoeuvre is started by giving a stop order. The
full astern engine order is applied with rudder
amidship. 4. Data recording stops and the
manoeuvre is terminated when the ship is stopped
dead
44
STOPPING TEST
  • Parameters
  • track reach
  • head reach
  • lateral deviation
  • time to dead in water

45
STOPPING TEST
  • Measure of the ability to stop while maintaining
    control
  • Full astern stopping test determines the track
    reach of a ship from the time an order for full
    astern is given until the ship stops in the
    water.
  • Track reach is the distance along the path
    described by the midship point of a ship measured
    from the position at which an order for full
    astern is given to the position at which the ship
    stops in the water
  • Track reach must not exceed 15 ships lenghts
    excepted for very large vessels maximum 20
    Ships L.

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Comparison between different manœuvres for
stopping a ship
48
ADDITIONAL TESTS FOR UNSTABLE SHIPS
  • Where standard manoeuvres indicate dynamic
    instability, alternative tests may be conducted
    to define the degree of instability  Initial
    turning test 
  • Guidelines for alternative tests such as a
     spiral test  or  pull-out manœuvre  are
    included in the Explanatory notes to the
    Standards for ship manoeuvrability, referred to
    in paragraph 6.1 above.
  • Refer to MSC/Circ.1053 on Explanatory notes to
    the Standards for ship manoeuvrability

49
INITIAL TURNING TEST
50
INITIAL TURNING TEST
  • Initial Turning ability
  • Measure of change of the heading in response to a
    moderate helm
  • Expressed in
  • distance covered before course change of 10
    when 10 of rudder is applied (also with 20
    rudder angle)
  • Assessed by the  Initial Turning Test  Test to
    be performed for unstable ships (IMO
    Recommandations)

51
  • Initial Turning Test
  • Measure of nonlinear
  • directional stability
  • Ability to control yaw
  • motion with small rudder
  • angles

With 10 rudder angle to port/starboard, the ship
should not have travelled more than 2.5 lengths
by the time the heading has changed 10 from
original heading
52
PULL-OUT TEST
Additional test for ships with
unsatisfactory manoeuvring standards Measure
of course keeping ability and dynamic stability
of a ship
53
PULL-OUT TEST
  • The ship is first made to turn with a certain
    rate of turn
  • The rudder is returned to midship position
  • With a stable ship rate of turn decays to zero
  • Unstable ship rate of turn reduces but residual
    rate of turn will remain

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55
SPIRAL TEST
56
SPIRAL TEST
  • The Standard Manoeuvres are used to evaluate
  • course-keeping ability based on the overshoot
  • angles resulting from the 10/10 zig-zag
    manoeuvre.
  • The zig-zag manoeuvre was chosen for reasons of
  • simplicity and expediency in conducting
    trials.
  • However, where more detailed analysis of dynamic
  • stability is required some form of spiral
    manœuvre
  • (direct or reverse) should be conducted as an
  • additional measure.

57
SPIRAL TEST
58
DIRECT SPIRAL TEST
  • The direct spiral is a turning circle manoeuvre
    in which various steady state yaw rate/rudder
    angle values are measured by making incremental
    rudder changes throughout a circling manoeuvre.
  • In the case where dynamic instability is detected
    with other trials or is expected, a direct spiral
    test can provide more detailed information about
    the degree of instability.
  • In cases where the ship is dynamically unstable
    it will appear that it is still turning steadily
    in the original direction although the rudder is
    now slightly deflected to the opposite side.

59
DIRECT SPIRAL TEST
  • steady course and speed
  • recording of data starts
  • rudder turned 15 degrees and held until yaw rate
    remains constant for one minute
  • rudder angle is then decreased in 5 degree
    increments. At each increment the rudder is held
    fixed until a steady yaw rate is obtained,
    measured and then decreased again
  • this is repeated for different rudder angles
    starting from large angles to both port and
    starboard
  • when a sufficient number of points is defined,
    data recording stops.

60
REVERSE SPIRAL MANOEUVRE
  • In the reverse spiral test the ship is steered to
    obtain a constant yaw rate, the mean rudder angle
    required to produce this yaw rate is measured.
  • the yaw rate versus rudder angle plot is created.

61
RESULT OF SPIRAL TEST FOR STABLE SHIP
62
RESULT OF SPIRAL TEST FOR UNSTABLE SHIP
63
DIEUDONNE SPIRAL MANOEUVRE
  • the vessel path follows a growing spiral, and
    then a contracting spiral in the opposite
    direction.
  • Suppose that
  • the first 15 rudder deflection (Sb) causes the
    vessel to turn right
  • At zero rudder, the yaw rate is still to the
    right the vessel has gotten stuck here, and
    will require a negative rudder action to pull out
    of the turn.
  • the rudder in this case has to be used
    excessively driving the vessel back and forth.
  • We say that the vessel is unstable, and clearly a
    poor design.

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65
Comments to IMO Standards
  • For deep water and service/design speed only
  • Give no indication of the handling
    characteristics in wind, waves and current
  • Do not look at manoeuvres normally carried out by
    most merchant ships
  • Full astern stopping test results in extreme
    termal loads on the engine
  • Criteria derived from databases heavily biased
    towards (old) tankers and bulk carriers

66
Comments to IMO Standards
  • From operational aspects additional requirements
    should be developed
  • Manoeuvrability in shallow water
  • Low speed manoeuvring capabilities
  • Maximum tolerable wind forces in harbour
    manoeuvres
  • Limited heel angles
  • Steering in waves
  • Steering with special devices

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