Ship Propulsion system
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117 slides
Oct 19, 2020
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About This Presentation
Ship propulsion system
Slide Content
Yasser B. A. Farag
MSc. of Maritime Energy Management - -Sweden
Lecturer at Institute of Maritime Upgrading Studies
Maritime Chief Engineer
Maritime Upgrading Studies Institute -2020 -
Marine Engineering Knowledge
UE231
MSc. of Maritime Energy Management - -Sweden
Lecturer at Institute of Maritime Upgrading Studies
Maritime Chief Engineer
Maritime Upgrading Studies Institute -2020 -
Marine Engineering Knowledge
UE231
Marine Engineering UE231
Ship’s thrust
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
How the ship thrust is created?
37
How the ship thrust is created?
37
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Shafting system
38
Shafting system
38
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
ENGINE
PROCESS
8.5 kg/kWh
168 g/kWh
1 g/kWh
HEAT
WORK
EXHAUST
GAS
AIR
FUEL
L.O
21% ????????????
????????????
79% ????????????
97% ????????????????????????
0.5% ????????????
97% ????????????????????????
2.5% ????????????????????????
0.5% ????????????
13% ????????????
????????????
75.8% ????????????
5.6% ????????????????????????
????????????
5.35% ????????????
????????????????????????
1500 ppm ????????????????????????
????????????
600 ppm ????????????????????????
????????????
60 ppm ????????????????????????
180 ppm ????????????????????????
120 mg/N????????????
????????????
????????????????????????
??
** All numbers are general and differs according to the engine type, manufacturer and technology updates.
Engine’s Emissions
39
ENGINE
PROCESS
8.5 kg/kWh
168 g/kWh
1 g/kWh
HEAT
WORK
EXHAUST
GAS
AIR
FUEL
L.O
21% ????????????
????????????
79% ????????????
97% ????????????????????????
0.5% ????????????
97% ????????????????????????
2.5% ????????????????????????
0.5% ????????????
13% ????????????
????????????
75.8% ????????????
5.6% ????????????????????????
????????????
5.35% ????????????
????????????????????????
1500 ppm ????????????????????????
????????????
600 ppm ????????????????????????
????????????
60 ppm ????????????????????????
180 ppm ????????????????????????
120 mg/N????????????
????????????
????????????????????????
??
** All numbers are general and differs according to the engine type, manufacturer and technology updates.
Engine’s Emissions
39
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Shafting system layout
40
Shafting system layout
40
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Ship Drive Train and Power
Engine
Reduction
Gear
Bearing Seals
Screw
Strut
DHP
THP
EHP
BHP
SHP
Shaft Horse Power (SHP)
Power output after the
reduction gears
SHP=BHP -losses in
reduction gear
Brake Horse Power (BHP)
Power output at the shaft
coming out of the engine
before the reduction gears
Ship’s movement
41
Delivered Horse Power (DHP)
Power delivered to the
propeller
DHP=SHP –losses in shafting,
shaft bearings and seals
Thrust Horse Power (THP)
Power created by the
screw/propeller
THP=DHP –Propeller losses
Effective Horse Power (EHP)
The power required to move the
ship hull at a given speed in the
absence of propeller action
Ship Drive Train and Power
Engine
Reduction
Gear
Bearing Seals
Screw
Strut
DHP
THP
EHP
BHP
SHP
Shaft Horse Power (SHP)
Power output after the
reduction gears
SHP=BHP -losses in
reduction gear
Brake Horse Power (BHP)
Power output at the shaft
coming out of the engine
before the reduction gears
Ship’s movement
41
Delivered Horse Power (DHP)
Power delivered to the
propeller
DHP=SHP –losses in shafting,
shaft bearings and seals
Thrust Horse Power (THP)
Power created by the
screw/propeller
THP=DHP –Propeller losses
Effective Horse Power (EHP)
The power required to move the
ship hull at a given speed in the
absence of propeller action
Marine Engineering Knowledge UE231 |YASSER B. A. FARAG20 October 2020
Effective Horse Power (EHP)
EHPis not related with Power Train System.
EHPcan be determined from the towing tank experiments at the various speeds of the model ship.
EHPof the model ship is converted into EHP of the full scale ship by Froude’s Law.
Towing Tank Towing carriage
Measured EHP
Effective Horse Power (EHP)
EHPis not related with Power Train System.
EHPcan be determined from the towing tank experiments at the various speeds of the model ship.
EHPof the model ship is converted into EHP of the full scale ship by Froude’s Law.
Towing Tank Towing carriage
Measured EHP
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Efficiencies
Screw
Propeller Efficiency
DHP
THP
propeller=η
Propulsive Coefficients
SHP
EHP
p
=η
propeller designed for well 6.0≈
pη
SHP
DHP
THP
EHP
Hull Efficiency
THP
EHP
H
=η
Hull efficiency changes due to hull-propeller interactions.
Well-designed ship :
Poorly-designed ship :
????????????
????????????>????????????
????????????
????????????<????????????
Efficiencies
Screw
Propeller Efficiency
DHP
THP
propeller=η
Propulsive Coefficients
SHP
EHP
p
=η
propeller designed for well 6.0≈
pη
SHP
DHP
THP
EHP
Hull Efficiency
THP
EHP
H
=η
Hull efficiency changes due to hull-propeller interactions.
Well-designed ship :
Poorly-designed ship :
????????????
????????????>????????????
????????????
????????????<????????????
Input = ṁ x CV
B.P 49.3%
Jacket water cooling
5.2 %
Exhaust losses
22.3%
Mechanical Energy
Waste Heat
Waste Heat
Thrust
28%
Radiation 0.6%
Waste Heat
Lubrication 2.9%
Chemical
Energy
100% Fuel
171 g/kw.hr
Thrust
T/C
Air Cooler 14.2%
Propeller Losses
10%
Hull
Friction
10%
29%
** All numbers are general and differs according to the ship type, design and technology updates. @ Yasser B. A. Farag 2020
To other waste heat recovery techniques, such as Economizer, Exhaust Gas Boiler, Turbo Generators…
Part of heat can be recovered in the fresh water generator
Waste Heat
44
B.P 49.3%
Jacket water cooling
5.2 %
Exhaust losses
22.3%
Mechanical Energy
Waste Heat
Waste Heat
Thrust
28%
Radiation 0.6%
Waste Heat
Lubrication 2.9%
Chemical
Energy
100% Fuel
171 g/kw.hr
Thrust
T/C
Air Cooler 14.2%
Propeller Losses
10%
Hull
Friction
10%
29%
** All numbers are general and differs according to the ship type, design and technology updates. @ Yasser B. A. Farag 2020
To other waste heat recovery techniques, such as Economizer, Exhaust Gas Boiler, Turbo Generators…
Part of heat can be recovered in the fresh water generator
Waste Heat
44
Shaft Alignment
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Shaft alignment definition
•Propulsion shafting: is a system of revolving rods that transmit power and motion from the
main drive to the propeller. The shafting is supported by an appropriate number of bearings.
•Propulsion shaft alignment:is a static condition observed at the bearings supporting the
propulsion shafts.
(ABS Definitions)
46
Shaft alignment definition
•Propulsion shafting: is a system of revolving rods that transmit power and motion from the
main drive to the propeller. The shafting is supported by an appropriate number of bearings.
•Propulsion shaft alignment:is a static condition observed at the bearings supporting the
propulsion shafts.
(ABS Definitions)
46
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Dynamic loads
•Hog and Sag due to state of loading and draught, effect of waves, etc., can be quite easily as
much as 1mm per 1m of ship length
•The effect of the waves and sea action over the main engine’s rigid bedplate length of about 16
m can be ignored.
•It’s difficult to perfectly align heavy engine and shafting length into the flexible beam form of a
ship that is subjected to the influence of the forces of the sea.
•The initial alignment is carried out in the dry dock with the final alignment in the water
verified by alignment survey.
47
Dynamic loads
•Hog and Sag due to state of loading and draught, effect of waves, etc., can be quite easily as
much as 1mm per 1m of ship length
•The effect of the waves and sea action over the main engine’s rigid bedplate length of about 16
m can be ignored.
•It’s difficult to perfectly align heavy engine and shafting length into the flexible beam form of a
ship that is subjected to the influence of the forces of the sea.
•The initial alignment is carried out in the dry dock with the final alignment in the water
verified by alignment survey.
47
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
1. Alignment by Piano Wire
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1. Alignment by Piano Wire
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
2. Alignment by light
The survey will verify at different
loading conditionsthe calculations,
and stiffening in the way of tank tops
and engine seating supports, together
with the use of rigid bedplates, can
reduce the central deflection to a
maximum of about 13 mm over the
engine room length and to about 2 mm
maximum over the bedplate length.
49
2. Alignment by light
The survey will verify at different
loading conditionsthe calculations,
and stiffening in the way of tank tops
and engine seating supports, together
with the use of rigid bedplates, can
reduce the central deflection to a
maximum of about 13 mm over the
engine room length and to about 2 mm
maximum over the bedplate length.
49
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
2. Alignment by light
50
2. Alignment by light
50
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
3. Alignment by Laser
Laser alignment tools are the
modern method of completing
the process. The tools are light,
easy to set up and relatively
low cost. The precision laser is
accurate to less than half a
millimeter over 15 meters .
51
3. Alignment by Laser
Laser alignment tools are the
modern method of completing
the process. The tools are light,
easy to set up and relatively
low cost. The precision laser is
accurate to less than half a
millimeter over 15 meters .
51
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
External factors affecting shaft alignment readings
52
External factors affecting shaft alignment readings
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Shaft alignment
53
Reference datum are the height of
the shaft above the keel at the Aft
end and the height of the crank shaft
centre above the keel extended to
the forward machinery space
bulkhead
Shaft alignment
53
Reference datum are the height of
the shaft above the keel at the Aft
end and the height of the crank shaft
centre above the keel extended to
the forward machinery space
bulkhead
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Dynamic Loads
54
Dynamic Loads
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Shaft alignment Variation at different loading conditions
55
The bedplate has a sagform when light ship of say 1 mm
and a hogform when fully loadedof say 1 mm.
Main Engine
Datum
1.25 mm
15 mm
3.5 mm
Datum
Scale 4mm = 1 m
Scale 25 mm = 1mm
Bulkhead
BRG-2
BRG-1
BRG-3
BRG-4
BRG-5
Source: adopted from many sources
Wp B
B
B B B
B
Shaft alignment Variation at different loading conditions
55
The bedplate has a sagform when light ship of say 1 mm
and a hogform when fully loadedof say 1 mm.
Main Engine
Datum
1.25 mm
15 mm
3.5 mm
Datum
Scale 4mm = 1 m
Scale 25 mm = 1mm
Bulkhead
BRG-2
BRG-1
BRG-3
BRG-4
BRG-5
Source: adopted from many sources
Wp B
B
B B B
B
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Checking bearing load by Jacking
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Checking bearing load by Jacking
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Crank shaft alignment
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Crank shaft alignment
57
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Crank shaft alignment
Excessive crankshaft deflections
readings in reciprocating machinery
will mean that there is a continuing
variation in the distance between
crank webs as the shaft moves through
a full engine revolution. This will
cause dangerous bending stresses in
the web and fillets between crank pin
and web.
58
Crank shaft alignment
Excessive crankshaft deflections
readings in reciprocating machinery
will mean that there is a continuing
variation in the distance between
crank webs as the shaft moves through
a full engine revolution. This will
cause dangerous bending stresses in
the web and fillets between crank pin
and web.
58
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
shaft alignment measurement after grounding
59
shaft alignment measurement after grounding
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Thrust Block
Thrust Block
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Shafting system
61
Shafting system
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Thrust Bearing
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Thrust Bearing
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Thrust Bearing construction
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Thrust Bearing construction
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Clearance = 1mm
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Thrust Bearing construction
Clearance = 1mm
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Thrust Bearing construction
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Thrust pads
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Thrust pads
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020 66
Thrust pads
Thrust pads
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Oil wedge
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Oil wedge
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Collar
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Collar
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Pads design
•Conventional Type (Kidney shape) •Round Type (Circular)
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Pads design
•Conventional Type (Kidney shape) •Round Type (Circular)
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Plain and Tilting Pad bearings
1/3 bearing area Full bearing area
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Plain and Tilting Pad bearings
1/3 bearing area Full bearing area
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Hydrodynamic lubrication
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Hydrodynamic lubrication
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
hydrodynamic lubrication
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hydrodynamic lubrication
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Hydrodynamic and hydrostatic lubrication
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Hydrodynamic and hydrostatic lubrication
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Roller bearing
Roller Bearings are not dependent on speed
for effective lubrication. Friction is low at all
speeds. This make them suitable for steam
turbine installations and in ships where slow
steaming may be necessary
74
Roller bearing
Roller Bearings are not dependent on speed
for effective lubrication. Friction is low at all
speeds. This make them suitable for steam
turbine installations and in ships where slow
steaming may be necessary
74
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
StbdSide Thrust Block in Normal
Use
Port Side Thrust Block Prior to
Lifting
Thrust Collar and Pads Through
Inspection Cover
Thrust Bearing overheating-case study
Close up of Ahead Pad and
Thrust Collar through Inspection
Cover
Lifting Cover
Astern Pads and Collar Showing How
Pads Are Linked. Note White Metal
Debris
Wiped Ahead Pads
75
StbdSide Thrust Block in Normal
Use
Port Side Thrust Block Prior to
Lifting
Thrust Collar and Pads Through
Inspection Cover
Thrust Bearing overheating-case study
Close up of Ahead Pad and
Thrust Collar through Inspection
Cover
Lifting Cover
Astern Pads and Collar Showing How
Pads Are Linked. Note White Metal
Debris
Wiped Ahead Pads
75
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Removing Astern Thrust Pads
Thrust Bearing Repair
Turning Out Bottom Half of Shell
Bearing After Jacking Shaft
Grinder Set Up
Temporary Thrust Arrangement
To Prevent FwdMovement of
Shaft
76
Removing Astern Thrust Pads
Thrust Bearing Repair
Turning Out Bottom Half of Shell
Bearing After Jacking Shaft
Grinder Set Up
Temporary Thrust Arrangement
To Prevent FwdMovement of
Shaft
76
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Thrust Bearing Repair
77
Thrust Bearing Repair
77
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Stern tube
Stern tube
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
OIL-lubricated stern tube
•Wear rate = ¼ mm every 4 years for
white metal
•Low coefficient of friction = 0.003
•To be inspected every 6 years
•Stern tube length = 2D
•Clearance= 0.002 –0.001 D
D
79
OIL-lubricated stern tube
•Wear rate = ¼ mm every 4 years for
white metal
•Low coefficient of friction = 0.003
•To be inspected every 6 years
•Stern tube length = 2D
•Clearance= 0.002 –0.001 D
D
79
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
OIL-lubricated stern tube
80
OIL-lubricated stern tube
80
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
OIL-lubricated stern tube
81
OIL-lubricated stern tube
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Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Water-lubricated S/T
•The staves are shaped with V or U grooves
between them at the surface.
•Bearing length = 4D (3D for TUFNOL)
•Bronze liner to be examined every 3 years.
•Wear rate of 1mm/year.
•No pollution.
•Has less Load carrying capacity
•Rubber bearing surfaces may be used in small
ships.
•TUFNOL(Plastic resin compound) has a lower
coefficient of friction and twice compressive
strength of Lignum Vitae.
D
82
Water-lubricated S/T
•The staves are shaped with V or U grooves
between them at the surface.
•Bearing length = 4D (3D for TUFNOL)
•Bronze liner to be examined every 3 years.
•Wear rate of 1mm/year.
•No pollution.
•Has less Load carrying capacity
•Rubber bearing surfaces may be used in small
ships.
•TUFNOL(Plastic resin compound) has a lower
coefficient of friction and twice compressive
strength of Lignum Vitae.
D
82
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Water-lubricated S/T
83
Water-lubricated S/T
83
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Water lubricated S/T
84
Water lubricated S/T
84
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Propeller shaft inspection
Examining a tail shaft and stern tube
1.Before the periodic inspection the
bearing wear down should be
measured.
2.After shaft removed given thorough
examination.
3.On water lubricated shafts the integrity
of the fit of the bronze liner should be
checked by tapping with a hammer
along its length listening for hollow
noise indicating a separation.
4.Measure wear of shaft.
5.Examine key way for cracksespecially
the nut thread area.
6.replace rubber rings
85
Propeller shaft inspection
Examining a tail shaft and stern tube
1.Before the periodic inspection the
bearing wear down should be
measured.
2.After shaft removed given thorough
examination.
3.On water lubricated shafts the integrity
of the fit of the bronze liner should be
checked by tapping with a hammer
along its length listening for hollow
noise indicating a separation.
4.Measure wear of shaft.
5.Examine key way for cracksespecially
the nut thread area.
6.replace rubber rings
85
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Comparison
86
Comparison
86
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Water lubricated seals
87
Water lubricated seals
87
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Sealing ring shape
88
Sealing ring shape
88
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Sealing rings
89
Sealing rings
89
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Sealing rings
90
Sealing rings
90
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Air sealing
91
Air sealing
91
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Air sealing
92
Air sealing
92
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Propeller removal
Propeller removal
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Removal of a keyed propeller
1.Slack Propeller nut. DON’T REMOVE IT
2.Propeller must be safely secured with a group of chains.
3.Flange between the Tailshaft and Intermediate shaft
slacked, a piece of wood to be inserted between them to
absorb any inward thrust.
4.NO HEATING UP TO THE PROPELLER HUB.
5.Dismantling special tool to be mounted firmly against the
propeller hub.
6.While tightening the special tool nuts against the
propeller nut, the propeller withdrawn from the shaft.
7.Special care given to the shaft screw teeth and a source
of protection must be applied.
8.Key ways to be inspected, Cracks and rust if present to
be found.
94
Removal of a keyed propeller
1.Slack Propeller nut. DON’T REMOVE IT
2.Propeller must be safely secured with a group of chains.
3.Flange between the Tailshaft and Intermediate shaft
slacked, a piece of wood to be inserted between them to
absorb any inward thrust.
4.NO HEATING UP TO THE PROPELLER HUB.
5.Dismantling special tool to be mounted firmly against the
propeller hub.
6.While tightening the special tool nuts against the
propeller nut, the propeller withdrawn from the shaft.
7.Special care given to the shaft screw teeth and a source
of protection must be applied.
8.Key ways to be inspected, Cracks and rust if present to
be found.
94
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Pilgrim nut
Pilgrim nut
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Poisson’s ratio
A metal with the same elastic properties in all
directions will have a constant relationship
between axial strain and lateral strain. This is
termed by POISSON’s RATIO.
????????????????????????????????????????????????????????????????????????????????????
′
????????????????????????????????????????????????????????????????????????=
????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????
????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????
96
Poisson’s ratio
A metal with the same elastic properties in all
directions will have a constant relationship
between axial strain and lateral strain. This is
termed by POISSON’s RATIO.
????????????????????????????????????????????????????????????????????????????????????
′
????????????????????????????????????????????????????????????????????????=
????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????
????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????
96
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Pilgrim type hydraulic coupling bolt
•The Bolt is Hollowand before being fitted is
stretched with hydraulic pressure (within its
elasticlimits) .
•These bolts used in FLANGE COUPLINGS and FLANGE
MOUNTED PROPELLER
•Easy to remove for inspection and maintenance.
97
Pilgrim type hydraulic coupling bolt
•The Bolt is Hollowand before being fitted is
stretched with hydraulic pressure (within its
elasticlimits) .
•These bolts used in FLANGE COUPLINGS and FLANGE
MOUNTED PROPELLER
•Easy to remove for inspection and maintenance.
97
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
•Pilgrim nut is used to ensure a solid frictional grip
between the propeller and shaft. The use of
pilgrim nut facilitates the transmission of the
engine torque without using the key.
•Pilgrim nut is basically a hydraulic jack with
threads, which is screwed into the slot provided
on the tail shaft . The propeller is forced onto the
tapered tail shaftregion by using a steel ring,
which receives the thrust from a hydraulically
pressurized nitrile rubber tyre.
•In simple, when the tyre is pressurizedthe
propeller will come off the tapered region.
Pilgrim nut
98
•Pilgrim nut is used to ensure a solid frictional grip
between the propeller and shaft. The use of
pilgrim nut facilitates the transmission of the
engine torque without using the key.
•Pilgrim nut is basically a hydraulic jack with
threads, which is screwed into the slot provided
on the tail shaft . The propeller is forced onto the
tapered tail shaftregion by using a steel ring,
which receives the thrust from a hydraulically
pressurized nitrile rubber tyre.
•In simple, when the tyre is pressurizedthe
propeller will come off the tapered region.
Pilgrim nut
98
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Propeller fitting by using pilgrim nut
Assembly: Propeller bedded to tailshaft and
jacked up to usual shop mark. The Pilgrim nut
is then screwed on the shaft with the loading
ring against the prop boss. With the lever
operated, high pressure grease gun, grease is
pumped into the inner tube inside the nut at
around 600 bar, ( w.p. stamped on nut, not to
be exceeded), the prop will be pushed
sufficiently up the taper to give the required
frictional grip. The pressure is then released
and the nut is rotated until it is hard up against
the aft face of the prop hub and locked, fair
water cone then fitted.
99
Propeller fitting by using pilgrim nut
Assembly: Propeller bedded to tailshaft and
jacked up to usual shop mark. The Pilgrim nut
is then screwed on the shaft with the loading
ring against the prop boss. With the lever
operated, high pressure grease gun, grease is
pumped into the inner tube inside the nut at
around 600 bar, ( w.p. stamped on nut, not to
be exceeded), the prop will be pushed
sufficiently up the taper to give the required
frictional grip. The pressure is then released
and the nut is rotated until it is hard up against
the aft face of the prop hub and locked, fair
water cone then fitted.
99
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Propeller withdrawal by using pilgrim nut method
Wood
Block
Withdrawal :After removal of fair
water cone and the locking plate, the
pilgrim nut is removed, reversed and
together with a loose shock ring is
screwed back onto the shaft.
•A strong back is fitted and secured
with studs to the prop boss. Grease is
now inserted to the system
expanding the inner tube forcing the
loading ring, strongback, withdrawal
studs and prop aft.
100
Propeller withdrawal by using pilgrim nut method
Wood
Block
Withdrawal :After removal of fair
water cone and the locking plate, the
pilgrim nut is removed, reversed and
together with a loose shock ring is
screwed back onto the shaft.
•A strong back is fitted and secured
with studs to the prop boss. Grease is
now inserted to the system
expanding the inner tube forcing the
loading ring, strongback, withdrawal
studs and prop aft.
100
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SKF oil injection method
1
2
Assembly
101
SKF oil injection method
1
2
Assembly
101
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SKF oil injection method
•Oil is injectedbetween the shaft taper and the bore
of the propeller by means of high pressure pumps.
•Oil penetration is assisted by a system of small
axial and circumferential grooves or a continuous
helical groove, machined in the propeller bore.
•The oil reduces the CoFbetween the surfaces to
about 0.015.
•A development of the keyless method involves a cost
iron sleeve which is bonded into the propeller boss.
•The sleeve is easier to handle when machining and
bedding than a complete propeller. Another benefit
is that cost iron has a CoFnearer to that of the
shaft than to propeller bronze.
102
SKF oil injection method
•Oil is injectedbetween the shaft taper and the bore
of the propeller by means of high pressure pumps.
•Oil penetration is assisted by a system of small
axial and circumferential grooves or a continuous
helical groove, machined in the propeller bore.
•The oil reduces the CoFbetween the surfaces to
about 0.015.
•A development of the keyless method involves a cost
iron sleeve which is bonded into the propeller boss.
•The sleeve is easier to handle when machining and
bedding than a complete propeller. Another benefit
is that cost iron has a CoFnearer to that of the
shaft than to propeller bronze.
102
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020 103
Keyless propeller
Keyless propeller
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020 104
Keyless propeller
Keyless propeller
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Keyless propeller
Advantages
•Precise tightening working on a measured
applied load
•Adequate interference fit
•no heat used
•Simple and safe to operate
•No shock loads applied
•Considerable saving in man power and time
105
Keyless propeller
Advantages
•Precise tightening working on a measured
applied load
•Adequate interference fit
•no heat used
•Simple and safe to operate
•No shock loads applied
•Considerable saving in man power and time
105
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Muff coupling
Tailshaft
•When the coupling is in position, the outer sleeve is
hydraulically driven on the tapered inner sleeve.
•At the same time, oil is injectedbetween the contact
surfaces to separate them and thus overcome the friction between them.
•When the outer sleeve has been driven on to a predetermined position
,
1.the forced lubrication pressure is released and
drained.
2.Oil pressure is maintained in the hydraulic space
until the oil between the sleeves drains and normal friction is restored.
3.After disconnecting hoses, plugsare fitted and
rust preventive applied to protect exposed seatings
Intermediate Shaft
1
2
106
Muff coupling
Tailshaft
•When the coupling is in position, the outer sleeve is
hydraulically driven on the tapered inner sleeve.
•At the same time, oil is injectedbetween the contact
surfaces to separate them and thus overcome the friction between them.
•When the outer sleeve has been driven on to a predetermined position
,
1.the forced lubrication pressure is released and
drained.
2.Oil pressure is maintained in the hydraulic space
until the oil between the sleeves drains and normal friction is restored.
3.After disconnecting hoses, plugsare fitted and
rust preventive applied to protect exposed seatings
Intermediate Shaft
1
2
106
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Muff coupling
Tail shaft
•The grip of the coupling is checked by
measuring the diameter of the outer sleeve
before and after tightening. The diameter
increaseshould agree with the figure stamped
on the sleeve.
•To disconnect the coupling, oil pressure is
brought to a set pressure in the hydraulic space.
Thenwith the shafts supported, oil is forced
between the sleeves. The outer sleeve slides off
the inner at a rate controlled by the slow
release of the hydraulic oil pressure.
Intermediate Shaft
1
2
107
Muff coupling
Tail shaft
•The grip of the coupling is checked by
measuring the diameter of the outer sleeve
before and after tightening. The diameter
increaseshould agree with the figure stamped
on the sleeve.
•To disconnect the coupling, oil pressure is
brought to a set pressure in the hydraulic space.
Thenwith the shafts supported, oil is forced
between the sleeves. The outer sleeve slides off
the inner at a rate controlled by the slow
release of the hydraulic oil pressure.
Intermediate Shaft
1
2
107
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Muff coupling
Intermediate ShaftTailshaft
Assembly :
1.Apply 1at the same time 2
2.release1then2
Dismantling :
1.Apply2then 1
2.release2slowly so the
outer sleeve slides off the
inner then release1
1
2
Note: The thin inner sleeve has a bore
slightly larger than the shaft diameter
108
Muff coupling
Intermediate ShaftTailshaft
Assembly :
1.Apply 1at the same time 2
2.release1then2
Dismantling :
1.Apply2then 1
2.release2slowly so the
outer sleeve slides off the
inner then release1
1
2
Note: The thin inner sleeve has a bore
slightly larger than the shaft diameter
108
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Muff coupling
SKF Hydraulic Muff Coupler on 5.5" Shaft
Thehydrauliccouplerinstallationrequiresanexactfitandalighttouchbetweenthesteelcoupler
sleeveandtheshaftends.Therearenofastenersinthissystem–nobolts,nokeysorkey-ways.
Approximately7″ofshaftendsthatareinsidethecouplermustbemachinedtowithintenthsofa
millimetretothecouplersleeve.
109
Muff coupling
SKF Hydraulic Muff Coupler on 5.5" Shaft
Thehydrauliccouplerinstallationrequiresanexactfitandalighttouchbetweenthesteelcoupler
sleeveandtheshaftends.Therearenofastenersinthissystem–nobolts,nokeysorkey-ways.
Approximately7″ofshaftendsthatareinsidethecouplermustbemachinedtowithintenthsofa
millimetretothecouplersleeve.
109
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Shaft stresses
Shaft stresses
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Shaft Stresses
•Stress is expressed as the total load divided by the area that it is acting through.
•The intermediate shaft is subject to torsional shear stress which influences the factor of
safety and hence resultant working stress, bendingand possible variation of torque
•Thrust shaft will require thicker diameter at the collar root (1.15d)
•Stern tube shaft diameter is 1.14d. If any part of the shaft is in contact with sea water
these sizes are to be increased 2.5%
•For propeller shaft, there is fluctuating, combined bending and twisting, with end thrust
and the possibility of corrosion attack.
111
Shaft Stresses
•Stress is expressed as the total load divided by the area that it is acting through.
•The intermediate shaft is subject to torsional shear stress which influences the factor of
safety and hence resultant working stress, bendingand possible variation of torque
•Thrust shaft will require thicker diameter at the collar root (1.15d)
•Stern tube shaft diameter is 1.14d. If any part of the shaft is in contact with sea water
these sizes are to be increased 2.5%
•For propeller shaft, there is fluctuating, combined bending and twisting, with end thrust
and the possibility of corrosion attack.
111
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Propeller Shaft Stresses
•Due to the considerable weight of the propeller, the tail
shaft is subject to a bending stress. There are however
other stresses which are likely to be encountered. There is
a torsional stress due to the propeller resistance and the
engine turning moment, and a compressive stress due to
the prop thrust. All these stresses coupled with the fact
that the shaft may be in contact with highly corrosive sea
water makes the likelihood of corrosion attack highly
probable.
112
Propeller Shaft Stresses
•Due to the considerable weight of the propeller, the tail
shaft is subject to a bending stress. There are however
other stresses which are likely to be encountered. There is
a torsional stress due to the propeller resistance and the
engine turning moment, and a compressive stress due to
the prop thrust. All these stresses coupled with the fact
that the shaft may be in contact with highly corrosive sea
water makes the likelihood of corrosion attack highly
probable.
112
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Propeller Shaft Faults
1.Before the periodic inspection the
bearing wear down should be
measured.
2.After shaft removed given thorough
examination.
3.On water lubricated shafts the
integrity of the fit of the bronze liner
should be checked by tapping with a
hammer along its length listening for
hollow noise indicating a separation.
4.Measure wear of shaft.
5.Examine key way for cracksespecially
the nut thread area.
6.replace rubber rings
113
Propeller Shaft Faults
1.Before the periodic inspection the
bearing wear down should be
measured.
2.After shaft removed given thorough
examination.
3.On water lubricated shafts the
integrity of the fit of the bronze liner
should be checked by tapping with a
hammer along its length listening for
hollow noise indicating a separation.
4.Measure wear of shaft.
5.Examine key way for cracksespecially
the nut thread area.
6.replace rubber rings
113
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Shaft balancing
Shaft balancing
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Simple revolving mass
•An unbalanced massm at radius r, to balance introduce
an opposite mass, Bat radius b, in the plane of rotation
such that:
????????????????????????
????????????
b = m????????????
????????????
????????????
i.e. equal centrifugal force effects.
????????????b = m????????????
115
Simple revolving mass
•An unbalanced massm at radius r, to balance introduce
an opposite mass, Bat radius b, in the plane of rotation
such that:
????????????????????????
????????????
b = m????????????
????????????
????????????
i.e. equal centrifugal force effects.
????????????b = m????????????
115
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Several revolving masses in one plane
Draw a mass moment (actual mass x radius) polygon and closing side give Bbmagnitude and direction.
116
Several revolving masses in one plane
Draw a mass moment (actual mass x radius) polygon and closing side give Bbmagnitude and direction.
116
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Several Revolving Mases in Different Planes
•A couple is a tendency to rock the shaft in its bearings in the form
of an end to end turning moment. Magnitude of the couple shown
= Px
•Proceed as before and draw the mass moment polygon to find the
unbalance mass moment
•Assume it is necessary to add say twobalance masses, having
equivalent mass moment to that found, for convenience at say X
and Y, i.e. one big mass to a particular point may not be
convenient so the mass is split up
117
Several Revolving Mases in Different Planes
•A couple is a tendency to rock the shaft in its bearings in the form
of an end to end turning moment. Magnitude of the couple shown
= Px
•Proceed as before and draw the mass moment polygon to find the
unbalance mass moment
•Assume it is necessary to add say twobalance masses, having
equivalent mass moment to that found, for convenience at say X
and Y, i.e. one big mass to a particular point may not be
convenient so the mass is split up
117
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Several Revolving Mases in Different Planes
•These two masses are also in different
planes.
•By using one of the planes, X or Y, as a
fixed reference it can be fixed and then
ignored, having no moment.
•Then a couple polygon or a tabulation is
drawn for the other position. Thus the
masses, radii and location of the planes
for balance are determined.
118
Several Revolving Mases in Different Planes
•These two masses are also in different
planes.
•By using one of the planes, X or Y, as a
fixed reference it can be fixed and then
ignored, having no moment.
•Then a couple polygon or a tabulation is
drawn for the other position. Thus the
masses, radii and location of the planes
for balance are determined.
118
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Vibration
Vibration
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
General Vibration
•Vibration is a mechanicalphenomenon whereby
oscillationsoccur about an equilibrium point.
The oscillations may be periodic, such as the
motion of a pendulum or random, such as the
movement of a tire on a gravel road.
•There are three modes of vibration:
1.Transverse vibration.
2.Longitudinal vibration (Axial).
3.Torsional Vibration
120
General Vibration
•Vibration is a mechanicalphenomenon whereby
oscillationsoccur about an equilibrium point.
The oscillations may be periodic, such as the
motion of a pendulum or random, such as the
movement of a tire on a gravel road.
•There are three modes of vibration:
1.Transverse vibration.
2.Longitudinal vibration (Axial).
3.Torsional Vibration
120
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
General Vibration
•Modern shafting is built after consideration of both low
cycle and high cycle fatigue.
•Every vibration problem reduces to the solution of an
equation of forces:
Inertia + Damping + Spring + Exciting = 0
Spring-mass Undamped
Spring-mass over-damped
Spring-mass under-damped
Spring-mass critically-damped
121
General Vibration
•Modern shafting is built after consideration of both low
cycle and high cycle fatigue.
•Every vibration problem reduces to the solution of an
equation of forces:
Inertia + Damping + Spring + Exciting = 0
Spring-mass Undamped
Spring-mass over-damped
Spring-mass under-damped
Spring-mass critically-damped
121
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Transverse Vibration
•This occurs in the athwart ship direction with large
reciprocating engines. It is' usually due to cylinder
pressure forces and inertia forces giving a resulting
couple about the engine crankshaft centre line and
through the guide shoe.
•Propeller torque variations can increase or
decrease this couple.
•The usual solution is to stay the engine to the hull
with lateral stays. Such stays must be connected to
the hull by pins that would shear if the hull was
distorted in collision
Transverse Vibration
•This occurs in the athwart ship direction with large
reciprocating engines. It is' usually due to cylinder
pressure forces and inertia forces giving a resulting
couple about the engine crankshaft centre line and
through the guide shoe.
•Propeller torque variations can increase or
decrease this couple.
•The usual solution is to stay the engine to the hull
with lateral stays. Such stays must be connected to
the hull by pins that would shear if the hull was
distorted in collision
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Axial Vibration
•Some axial movements of amplitude ±2.5 mm have been noted, a
movement of ±1 mm can quite easily introduce crank bending
stresses of 28 MN/m2.
•Invariably these movements are propeller excited occurring as say
4th order vibrations (8 vibrations per second at 2 rev/s of shaft).
•In this respect a 4 bladed propeller is causing the axial vibration
with 2 blades passing the aperture every 1/4 rev giving an axial
pulse.
•the introduction of 5 bladed propellers and more rigid thrust
seating have done much to reduce such amplitudes of vibration.
•Some experiments have been tried to utilisethe principle of the
Michellthrust indicator to introduce a dashpot damping effect.
123
Axial Vibration
•Some axial movements of amplitude ±2.5 mm have been noted, a
movement of ±1 mm can quite easily introduce crank bending
stresses of 28 MN/m2.
•Invariably these movements are propeller excited occurring as say
4th order vibrations (8 vibrations per second at 2 rev/s of shaft).
•In this respect a 4 bladed propeller is causing the axial vibration
with 2 blades passing the aperture every 1/4 rev giving an axial
pulse.
•the introduction of 5 bladed propellers and more rigid thrust
seating have done much to reduce such amplitudes of vibration.
•Some experiments have been tried to utilisethe principle of the
Michellthrust indicator to introduce a dashpot damping effect.
123
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Torsional Vibration
•A node is a point at which the shaft is undisturbed by vibration, i.e.
at the node the shaft can be imagined as clamped, the sections at
each side vibrating opposite in phase but with the same frequency.
•One node gives one mode of vibration, two nodes two modes, etc.,
most shafting systems can be simplified to a one or two mode form,
i.e. first or second degree of vibration as at least a first
assumption.
•This means for calculation the shaft system is considered as a 3
mass system, engine in one, flywheel and propeller.
•Only one serious criticaloccurs in the running range usually, for aft
end installations commonly abovethe maximum revolutions and for
midshipinstallations commonly below.
124
Torsional Vibration
•A node is a point at which the shaft is undisturbed by vibration, i.e.
at the node the shaft can be imagined as clamped, the sections at
each side vibrating opposite in phase but with the same frequency.
•One node gives one mode of vibration, two nodes two modes, etc.,
most shafting systems can be simplified to a one or two mode form,
i.e. first or second degree of vibration as at least a first
assumption.
•This means for calculation the shaft system is considered as a 3
mass system, engine in one, flywheel and propeller.
•Only one serious criticaloccurs in the running range usually, for aft
end installations commonly abovethe maximum revolutions and for
midshipinstallations commonly below.
124
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Introduction to hydraulic systems
Introduction to hydraulic systems
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Introduction to Hydraulic system
Hydraulics are used in many applications onboard ships:
•Steering/control systems (rudder)
•CPP
•Deck machinery (anchor windlass, capstans, winches)
•(loading & launching)
•Other: elevators
126
Introduction to Hydraulic system
Hydraulics are used in many applications onboard ships:
•Steering/control systems (rudder)
•CPP
•Deck machinery (anchor windlass, capstans, winches)
•(loading & launching)
•Other: elevators
126
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Hydraulic system
Hydraulics
•Covers the physical behavior of liquids in motion
•Pressurized oil used to gain mechanical advantage and perform work
Important Properties
•Shapelessness
•Incompressibility
•Transmission of Force
127
Hydraulic system
Hydraulics
•Covers the physical behavior of liquids in motion
•Pressurized oil used to gain mechanical advantage and perform work
Important Properties
•Shapelessness
•Incompressibility
•Transmission of Force
127
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Features
“Shapelessness”
Liquids have no neutral form
Conform to shape of container
Easily transferred through piping from one location to another
Incompressibility
Liquids are essentially incompressible
Once force is removed, liquid returns to original volume (no permanent distortion)
Transmission of Force
Force is transmitted equally & undiminished
in every direction -> vessel filled with pressure
128
Features
“Shapelessness”
Liquids have no neutral form
Conform to shape of container
Easily transferred through piping from one location to another
Incompressibility
Liquids are essentially incompressible
Once force is removed, liquid returns to original volume (no permanent distortion)
Transmission of Force
Force is transmitted equally & undiminished
in every direction -> vessel filled with pressure
128
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
PASCAL’s Law
Magnitude of force transferred is in direct proportion to the surface area (F = P*A)
Pressure = Force/Area
Liquid properties enable large
objects (rudder, planes, etc.) to
be moved smoothly
129
PASCAL’s Law
Magnitude of force transferred is in direct proportion to the surface area (F = P*A)
Pressure = Force/Area
Liquid properties enable large
objects (rudder, planes, etc.) to
be moved smoothly
129
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Theory
•Piston/cylinder used if desired motion is linear
•Hydraulic pressure moves piston & ram
•Load is connected to ram (rudder, planes, masts, periscopes)
Piston
Cylinder
RAM
Hydraulic Fluid Supply/Return Ports
Seal
130
Theory
•Piston/cylinder used if desired motion is linear
•Hydraulic pressure moves piston & ram
•Load is connected to ram (rudder, planes, masts, periscopes)
Piston
Cylinder
RAM
Hydraulic Fluid Supply/Return Ports
Seal
130
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Pros & Cons
Advantages disadvantages
•Convenient power transfer
Few moving parts
Low losses over long distances
less wear
•Flexibility
Distribute force in multiple directions
Safe and reliable for many uses
Can be stored under pressure for long periods
•Variable speed control
Quick response (linear and rotary
•Requires positive confinement (to give shape)
•Fire/explosive hazard if leaks or ruptures
•Filtration critical - must be free of debris
•Manpower intensive to clean up
131
Pros & Cons
Advantages disadvantages
•Convenient power transfer
Few moving parts
Low losses over long distances
less wear
•Flexibility
Distribute force in multiple directions
Safe and reliable for many uses
Can be stored under pressure for long periods
•Variable speed control
Quick response (linear and rotary
•Requires positive confinement (to give shape)
•Fire/explosive hazard if leaks or ruptures
•Filtration critical - must be free of debris
•Manpower intensive to clean up
131
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Controllable pitch
propeller
Controllable pitch
propeller
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Theory
133
Theory
133
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
CPP
134
CPP
134
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Types
135
Types
135
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Construction
136
Construction
136
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Construction
137
Construction
137
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Construction
The advantage of this
arrangement is that
the operating piston is
easily accessed in the
event of failure.
138
Construction
The advantage of this
arrangement is that
the operating piston is
easily accessed in the
event of failure.
138
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Control
139
Control
139
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Control
Control
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Mechanism
141
Mechanism
141
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Mechanism
142
Mechanism
142
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
CPP hub actuator
143
CPP hub actuator
143
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Mechanism
Ahead
Astern
144
Mechanism
Ahead
Astern
144
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
CPP hub
145
CPP hub
145
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Hub return spring
146
Hub return spring
146
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Defect location
147
Defect location
147
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Illustration
148
Illustration
148
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Illustration
149
Illustration
149
Marine Engineering Knowledge UE231|YASSER B. A. FARAG20 October 2020
Pros & Cons
Advantages disadvantages
•Fast stop manoeuvres are possible.
•The main engine does not need to be
reversible.
•Fine control of thrust can be achieved without
the need to accelerate or decelerate the
propulsion machinery.
•These propellers allow engagement of shaft
generator to be driven from the main engine
which is efficient and cheap. Variable ship
speeds can be obtained with constant
propeller rpm as required by the generator.
•consumption is higher. The higher propeller rpm at lower
speed is hydrodynamically suboptimal.
•It require a thicker hub (0.24-0.32 D). The pitch
distribution is suboptimal. The usual almost constant pitch
in the radial direction causes negative angles of attach at
the outer radii at reduced pitch, thus slowing the ship
down. Therefore such propellers usually have higher pitch
at the outer radii and lower pitch at the inner radii. The
higher pitch at the outer radii necessitates a large
propeller clearance.
•Higher costs forpropeller.
•Complicated design
150
Pros & Cons
Advantages disadvantages
•Fast stop manoeuvres are possible.
•The main engine does not need to be
reversible.
•Fine control of thrust can be achieved without
the need to accelerate or decelerate the
propulsion machinery.
•These propellers allow engagement of shaft
generator to be driven from the main engine
which is efficient and cheap. Variable ship
speeds can be obtained with constant
propeller rpm as required by the generator.
•consumption is higher. The higher propeller rpm at lower
speed is hydrodynamically suboptimal.
•It require a thicker hub (0.24-0.32 D). The pitch
distribution is suboptimal. The usual almost constant pitch
in the radial direction causes negative angles of attach at
the outer radii at reduced pitch, thus slowing the ship
down. Therefore such propellers usually have higher pitch
at the outer radii and lower pitch at the inner radii. The
higher pitch at the outer radii necessitates a large
propeller clearance.
•Higher costs forpropeller.
•Complicated design
150
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