Stern tubes
Water lubricated bearings
- The stern tube is normally constructed of cast iron slightly larger at the forward end to ease
removal. The forward end is flanged and bolted to a doubler plate stiffened aft peak bulkhead.
The forward end is supplied with a stuffing box and gland, the after end with a bearing
comprising lignum vitae or similar, the wood is dove tailed into a brass bush, the wood is
machined and cut on end grain. Can be lined with Lignum Vitae , rubber composition (cutlass
rubber) or an approved plastic material (Certain plastics possess good bearing properties being
inert and very tolerant of slow speed boundary lubrication conditions. Cresylic resin bonded
asbestos such as Railco WA80H give good results in condition of heavy water contamination in
the lubricating oil of almost 100%)
For water lubricated bearing not less than 4 x the diameter of the steel shaft. If the bearing is over
380mm diameter forced water lubrication must be used, a circulating pump or other source with
a water flow indicator.
The shaft is withdrawn for examination every 3 years.
Modern Water tolerant oil lubricated stern Tube
With the increase in size of VLCC's shipping companies required a stern tube bearing capable of
operating with high degrees of water comtamination. The alloys in white metal tend to oxidise
and the clearance is removed leading to seizure. In addition as shaft revs reduced in search of
improved propeller efficiency the hydrodynamic forces available become limitedfor oil film
generation.
For this reason Railco WA80H bearings where developed.These contained a phenolic resin
impregnated asbestos yarn. The next generation contained non-asbestos material. This material
tended to be tainted due a series of overheating problems. (later found due to the combination of
stiff high power transfer shafts and flexible hull design).
The modern material is called SternSafe and comprises an inner bearing surface with an
overwound outerlayer. This has greater tolerance to overheating and reduced swell in the event
of water contamination. The latter allows for reduced running clearance and thereby greater
control of the shaft position reducing oil loss, seal damage and water ingress.
A wear gauge is incorporated into the bearing as our temperature sensors.
Oil lubricated bearings
Unlike for the water lubricated stern tube a shaft liner is unnecessary. Generally a small one is
fitted in way of the aft seal bolted on to the propeller boss. In this way it excludes sea water
contact with the main shaft and provides an easily replaceable rubbing surface for the seal. Lined
with white metal are to have a bearing length so as not to exceed a bearing pressure from the
weight of the shaft and propeller of 5 kg/cm2. The limitations of a bearing are the load it can
withstand without metal cracking or squeezing out and the temperature it can withstand without
melting. Length of bearing not less than 2 D in any case. Cast iron and bronze bearings must have a bearing length not less than 4D. Lubrication system must be capable of maintaining oil
tightness despite varying temperature. Gravity tanks fitted with low level alarms, Usual for aft
peak to be filled with water to provide cooling low suction valve to be fitted to be locked shut.
Wear down for the white metal should not exceed 2mm to avoid hammering out and the period
for inspection is 6 years. A highly resilient reinforced plastic may be used in place of the white
metal. It is claimed to have greater load carrying capacity, high resistance to fatigue and shock
loading, with good lubrication properties. Ceramic liners can also be used.
This system depends upon Hydrostatic lubrication stern tube oil charge remaining in stern tube
until pressure test is carried put to ensure that oil supply line is not blocked. This is done by
manipulation of valves at header tank and operation of pump which slightly over pressurises
stern tube. Oil returning to tank indicating clear oil lines. Top half of white metal bearing is
usually machined to give a left hand and right hand helix, this gives a small pumping pressure
forward to aft to provide lubrication and to assist in maintaining oil tightness of the oil seals.
If outboard seal leaks, the following steps are to be taken
1. Fresh water in gravity tank to emulsify and coagulate it, oil pumped around system to seal and lubricated.
2. Recharge with high viscosity oil 3. disconnect oil supply line and reconnect to 45 gallon drum which is supported by
block and tackle in order to give a variable head. By raising and lowering the
drum the oil pressure in the system can be made to match the water pressure from
outside (taking into account the difference in gravities.
When large propellers are fitted the heavy overhanging weight greatly increases the load at the
after end of the stern tube breaking down the hydrostatic lubrication causing metal to metal
contact and seizure towards the aft end of bearing. To obviate this it is usual to angle the shaft
downwards for about 8mm over 100m length thus attempting to ensure than the weight of the
bearing is taken on the full length of the bearing. It is good practice to leave the oil tank open to
the stern tube when in port with machinery stopped, this prevents sea water leaking into the
system. However, water has been known to contaminate lubricating oil systems causing rusting
of tail shaft particularly when shaft is stopped for periods long enough for water to settle in
bottom of bearing. Fit only water seperator I,e, a coalescer or cyclonic or osmosis system.
In ships with large changes in draught it is usual to fit two gravity tanks. The upper tank is used
when fully loaded or there is water leaking in.
Water based oil replacements
Available are water based sterntube lubricants having the advantages of oil but with a more eco-
friendly face. These lubricants must have an adequate viscosity, resistance to sea water
contamination as well as biodegradability.
They typically have a water content greater than 90% and are highly soluble. Friction is reduced
in comparison to equivalent mineral oil/white metal bearing.
Other benefits include increased heat transfer rates and better protection against galvanic
corrosion of dissimilar metals found in the shaft/prop arrangement.The fluid has no measurable
flash point.
Simplex shaft seal
A very common arrangement for oil lubricated stern tube bearings. A simplex seal arrangement
is fitted to both inner and outer ends.
The replaceable chrome liner prevents damage to the prop shaft which would be expensive to
repair.
Not show is a rope guard bolt to the hull which prevents material from being 'wound' into the gap
and damaging the seal. Rope cutters may be fitted with a fixed blade attached to the hull and a
moving blade to the propeller.
Oil pressure is fed to the area between the two opposite facing seals. This pressure is governed
by the draught of the vessel and is often supplied via tanks situated at set heights. This pressure
balances the sea water pressure on the seal and prevents sea water ingress, by opening the correct
tank the pressure exerted by the oil is insufficient to cause oil to leakage out.
Stern tube seals with oil lubrication have tended to use rubber rings increasingly. Fluoric rubber
(Viton) with additives has been shown to be more effective than nitrile butadiene rubber for seal
rings
Fitting Shaft seals in service.
It is possible to replace lip seals without removal of the tailshaft by vulcanising split seals on the
shaft.
The old seal is removed and the shaft and housing carefully cleaned
A pre cut seal is assembled into the vulcanising machine
The vulcanising machine is then set up off the shaft and the position of the seal checked.
The vulcanising agent is mixed and applied to the seal ends.
The vulcanising machine is then fitted to the shaft and connected to an electrical supply. A heater
within the machine heats the seal to a predetermined temperature for a set time determined by
ambient temperature, material type etc.
Split type stern tube (Ross-turnbull)
Main advantage of this system is that tail end shaft, stern tube bearing and tapped bolts can be
inspected without dry docking. System allows stern tube to be drawn into the vessel for
inspection
The bottom half bearing is supported on chocks which in turn rest on two ford and aft machined
surfaces within stern tube boss, these chocks govern the height of shafting. A detachable arch is
attached to the lower bearing and carries the outboard oil seal, the face of which comes into
contact with a seal seat which is fastened to and rotates with tail shaft flange.
The top half of the bearing module makes a seal on the face of the arch and a seal along the
horizontal joint on the bearing. The bearing is held in place vertically by 4 x 50 tonne pilgrim
type jacks, these jacks also hold the two half bearings together. Lateral positioning is by 4 x
30tonne pilgrim type jacks, two each side.
A running track is arranged above the bearing for easy removal of top half . A rolled race skid is
provided so that the bottom half can be transported.
Removal-The hydro mechanical seal is actuated making a seal on the ford face of the propeller
and locked mechanically in position. The space is then drained of water.
Top half of bearing can then be removed by taking out the top vertical jacks and using the lifting
jack to allow the top half to be brought inboard on the running track. These jacks are now fitted
under the lower half bearing to raise bearing and shaft sufficient to allow the chocks to be
removed.
The jacks are then lowered until the propeller rest on the propeller rest built into the stern frame.
Further lowering allows the bearing to move away from the shaft until bearing is resting on roller
skids. The lower half bearing complete with oil seal can then be removed into the vessel for
examination.
Reversing the procedure enables the bearing to be replaced
Odd facts-Anti vibration locking gear fitted to jack nuts. As with a CPP it is usual to fit a flange
mounted propeller eliminating taper and keyway with there associated problems. The tap bolts
securing propeller to tail shaft flange can be removed one at a time, crack detected and returned
to their working position.
Stresses in tail shafts
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.
Examining a tail shaft and stern tube
o Before the periodic inspection the bearing weardown should be measured.
o After shaft removed given thorough examination.
o 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 seperation.
o Measure wear of shaft.
o Examine key way for cracks especially the nut thread area.
o replace rubber rings
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