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PURIFICATION(??) OF FUEL OILS

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LESSON 6 PURIFICATION( ) OF FUEL OILS Fuels vary considerably in viscosity, quality and chemical composition. They also contain impurities from producing ... – PowerPoint PPT presentation

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Title: PURIFICATION(??) OF FUEL OILS


1
LESSON 6
  • PURIFICATION(??) OF FUEL OILS

2
  • Fuels vary considerably in viscosity, quality and
    chemical composition. They also contain
    impurities from producing, transferring and
    storage.

3
  • All heavy fuels contain insoluble(?????)
    impurities such as mineral salts, asphalt(??),
    foreign matter and some liquids not
    miscible(????).

4
  • These impurities can to a great degree(extend) be
    removed by centrifugal(???) and filtration(??)
    treatments.

5
  • Failure of any cleaning equipment could cause
    very serious troubles to the mechanical parts of
    the fuel injection equipment,

6
  • therefore standby duplicate cleaning equipment
    must be provided and so arranged that continuous
    operation can be maintained should the working
    unit fail.

7
  • The most common method of cleaning fuel is by
    centrifuging and there are various makes of
    purifiers(???) and clarifiers(???) in use

8
  • such as Alfalaval, Titan, Sharpies, etc., the
    basic principles of operation and design are
    similar.

9
Dirty oil
Clean oil
water
gravity disc
Separation disc
Cylindrical interface
bowl
10
  • The separation discs(???) in purifiers and
    clarifiers are conical in shape and are made of
    stainless steel,

11
  • the outer periphery(??) is perforated(??) by a
    series of holes through which the fuel passes,
    the distance between each disc is approximately
    0.5 mm and the thickness is about 1 mm.

12
  • When the fuel is pumped into an operating
    centrifuge the centrifugal force generated causes
    the heavier fractions(??) such as sludge and
    water to be forced along the underside of the
    discs to the outer periphery.

13
  • A cylindrical interface(?????) is formed between
    the heavier fractions (water) and the lighter
    fractions (oil). The lighter fraction is forced
    inward and up to the clean oil outlet.

14
  • The impurities and sludge can be collected in the
    bowl(???), sludge space, or in some designs
    discharged at regular intervals to a sludge tank.

15
  • The best results are obtained when the interface
    zone is close to the periphery of the bowl and it
    must be outside the disc stack(??) areas.

16
  • The specific gravity of the fuel determines the
    size of the gravity rings(???) to be fitted and
    it is important to refer to the makers
    instruction manual for verification.

17
  • A higher throughput(????) and more efficient
    process can be achieved if the fuel is heated to
    reduce its viscosity.

18
  • Heaters are, therefore, installed in the system.
    Recommended temperatures for high viscosity fuels
    are between 80 to 95? depending on the viscosity
    of the fuel.

19
  • If the purifying of relatively clean fuel is
    needed, a centrifuge fitted with a clarifier bowl
    should be used.

20
  • There is only one outlet for clean oil, no
    gravity discs(rings) are fitted for the
    separation of water.

21
  • Consequently, the maximum cleaning efficiency is
    achieved, as the oil feed will at all time be
    outside the disc stack zone.

22
  • Experience has shown excellent results from a
    two-stage centrifuge treatmentpurifying followed
    by clarifying.

23
  • The fuel is pumped into the purifier fitted with
    gravity rings and with separate discharges for
    oil, water and sludge.

24
  • The relatively clean oil is then pumped into a
    clarifier which extracts(???) any small amount of
    water or impurities still left in the oil.

25
  • Unacceptably large quantities of impurities are
    left in the oil after the purifying process if
    the oil is insufficiently heated, or the
    throughput is too high or the wrong type of
    gravity disc is fitted.

26
  • Improvements in oil, oil purifying techniques and
    centrifuges have led to the development of single
    phase purifiers which have in themselves been
    aided by improved temperature control, heaters,
    flood alarms and other ancillary equipment.

27
  • A further development has been the self-cleaning
    purifier which operates unattended(???????, )
    for long periods and discharges its own sludge.

28
  • The self cleaning unit can be stopped and started
    at any time without dismantling(??) for manual
    cleaning which is a dirty and time consuming
    job.

29
  • If the unit is not self-cleaning, then a strict
    maintenance routine must be followed.

30
  • Poorly maintained units are a continuous source
    of trouble and allowing a machine to run beyond
    its recommended time can result in a choked bowl,
    especially if very dirty fuel is being purified.

31
  • The efficiency of centrifugal unit decreases
    rapidly when the accumulation of impurities
    reaches a certain point.

32
  • For self-cleaning purifiers used in unmanned
    machinery spaces controls are arranged that if a
    centrifuge fails the standby unit will
    automatically comes into operation.

33
  • The purifiers are fitted with electric timers for
    controlling the period between bowl emptying
    operations and sequential regulating devices
    control the various' emptying operations

34
  • The units must incorporate an audio-visual alarm
    system which come into operation when any running
    condition is out of order.

35
  • When an alarm condition prevails with the unit,
    it should be arranged to shut down or the fuel
    oil recycling valve should open and the oil flow
    should be passed to the outer circle thus
    preventing the loss of oil.

36
  • In order to control the interface zone of the
    bowl a constant pressure control valve is fitted
    at the clean oil outlet.

37
  • By applying a high back pressure the interface
    moves outward and with a low back pressure the
    opposite results.

38
  • It is important to note that when an excessive
    amount of water is present in the fuel the
    temperature for centrifuging must be kept below
    the boiling point of water, otherwise foaming(??)
    and, agitation(??) of the fuel takes place.

39
  • Under these circumstances it will be necessary to
    purify at a very low rate to achieve a reasonable
    efficiency.

40
READING MATERIAL
  • A. OIL TREATMENT

41
  • Both fuel oils and lubricating oils require
    treatment before passing to the engine.

42
  • This will involve storage and heating to allow
    separation of water present, coarse and fine
    filtering to remove solid particles and also
    centrifuging.

43
  • The centrifugal separator is used to separate two
    liquids, for example oil and water, or a liquid
    and solids as in contaminated oil.

44
  • Separation is speeded up by the use of centrifuge
    and can be arranged as a continuous process.
    Where a centrifuge is arranged to separate two
    liquids, it is known as a 'purifier'.

45
  • Where a centrifuge is arranged to separate
    impurities and small amounts of water from oil it
    is known as a clarifier.

46
  • The separation of impurities and water from fuel
    oil is essential for good combustion. The removal
    of contaminating impurities from lubricating oil
    will reduce engine wear and possible breakdowns.

47
Centrifuging
  • A centrifuge consists of an electric motor drive
    to a vertical shaft on the top of which is
    mounted the bowl assembly.

48
  • An outer framework(??) surrounds the assembly and
    carries the various feed and discharge
    connections.

49
  • The bowl can be a solid assembly which retains
    the separated sludge and operates
    non-continuously, or the bowl can be arranged so
    that the upper and lower parts separate and the
    sludge can be discharged while the centrifuge
    operates continuously.

50
  • The dirty oil is admitted into the center of the
    bowl, passes up through a stack of discs and out
    through the top.

51
The Purifying Process
  • The centrifugal separation of two liquids such as
    oil and water, results in the formation of a
    cylindrical interface between the two.

52
  • The position of this interface within the
    centrifuge is very important for correct
    operation.

53
  • The setting or positioning of the interface is
    achieved by the use of dam ring(???) or gravity
    disc at the outlet of the centrifuge.

54
  • Various diameter rings are available for each
    machine when different densities of oil are used.

55
The Clarifying Process
  • Cleaning oil that contains little or no water is
    achieved in a clarifier bowl where the impurities
    and water collect at the bowl periphery.

56
  • A clarifier bowl has only one outlet. No gravity
    disc is necessary since no interface is formed.

57
  • The bowl therefore operates at maximum separating
    efficiency since the oil is subjected to the
    maximum centrifugal force.

58
The Bowl Discs
  • Purifier and clarifier bowls each contain a stack
    of conical discs. The discs may number up to 150
    and are separated from one another by a small
    gap.

59
  • Separation of impurities and water from the oil
    takes place between these discs. A series of
    aligned(???) holes near the outside edge permits
    entry of the dirty oil.

60
  • The action of centrifugal force causes the
    lighter components (the clean oil) to flow,
    inwards and the water and impurities flow
    outwards.

61
  • The water and impurities form a sludge which
    moves outwards along the undersides of the discs
    to the periphery of the bowl.

62
Selection of Gravity Disc
  • The interface between the liquid seal (water) and
    the oil should be positioned as close as possible
    to the bowl periphery.

63
  • However, the interface must not be located so far
    from the bowl center that the oil will pass the
    outer edge of the top disc, breaking the liquid
    seal and discharging with the water.

64
  • Factors influencing the interface position are
  • Oil viscosity and density. A high oil density
    will position the interface closer to the bowl
    periphery than will a low density.

65
  • Throughput and back pressure. As a rule the
    interface will be located closer to the bowl
    periphery at a high throughput than at a low one.

66
  • The same effect is produced by a high back
    pressure, and a low one respectively, in the
    clean oil outlet.

67
  • Gravity disc. The location of the interface is
    adjusted by altering the outlet for the water,
    i.e. exchanging the gravity disc.

68
  • Changing to a gravity disc with larger hole
    diameter will move the interface towards the bowl
    periphery,

69
  • whereas a disc with smaller hole diameter will
    position the interface closer to the bowl center.

70
  • The nomogram(???) is an aid to select a
    tentative(???) gravity disc when the density of
    the oil at a given temperature is known.

71
  • The hole diameter of the disc to be tried first
    appears directly from the nomogram.

72
  • However, in practical operation the best result
    is obtained by using the gravity disc with
    largest hole diameter that will not cause a break
    in the liquid seal in the bowl or an
    emulsification(??)in the water outlet.

73
Discharge of Sludge
  • Modern centrifuge designs enable continuous
    operating, over a considerable period of time.

74
  • This is achieved by an ejection process which is
    timed to discharge the sludge at regular
    intervals.

75
  • The sludge deposits build up on the bowl
    periphery as separation-continues, and the
    ejection process is timed to clear these deposits
    before they begin to affect the separation
    process.

76
  • To start the ejection process the oil feed to the
    centrifuge is first shut off and the oil
    remaining in the bowl removed by admitting
    flushing water(???).

77
  • Water is then fed into the hydraulic system in
    the bottom of the bowl to open a number of
    spring-load valves.

78
  • This 'operating' water causes the sliding bowl
    bottom to move downwards and open discharge ports
    in the bowl periphery.

79
  • The sludge is discharged through these ports by
    centrifugal force. Closing operating water is
    now feed in to raise sliding bowl up again and
    close the discharge ports.

80
  • Water is fed into the bowl to remake the liquid
    seal, the oil feed reopened, and separation
    continues.

81
Maintenance
  • The bowl and the disc stack will require
    periodical cleaning whether or not an ejection
    process is in operation.

82
  • Care should be taken in stripping(??) down the
    bowl, using only the special tools provided and
    noting that some left-hand threads are used.

83
  • The centrifuge is a perfectly balanced piece of
    equipment, rotating at high speeds all parts
    should therefore be handled and treated with
    care.

84
  • B. OPERATION OF AN OIL SEPARATOR

85
Before Starting
  • The bowl should be well cleaned and assembled
    according to the instruction. Check particularly
    The brake is released.

86
  • The collecting covers (frame hood respectively)
    are clamped(??) with the hinged(???) bolts. The
    oil level in worm gear (??) housing is somewhat
    above the middle of the gauge glass.

87
  • The operating liquid tank is full and the control
    valves are closed (operating liquid feed turned
    off bowl open).

88
  • Note The oil level must never be allowed to sink
    below the lower edge of the gauge glass. If the
    glass is provided with corrugation(??) they
    should be vertical.

89
  • Keep the gauge glass clean, otherwise a line,
    which could be mistaken for the oil level, will
    in time build upon the inside of the glass.

90
  • If the machine has been idle (for instance during
    a night), screw out the drain screw some turns
    and drain off any water.

91
Starting the Motor
  • If the process liquid is to be preheated,
    circulate it through the preheating until
    suitable temperature is reached.

92
  • Shortly after starting it may occur that the bowl
    begins to vibrate more than normal.

93
  • The cause is generally lack of balance due to bad
    cleaning of the bowl. Stop the machine and clean
    the bowl if the vibrations are very heavy.

94
  • Heat is always generated in the clutch(???)
    coupling during the running-up period.

95
  • This will be noticeable, especially when the
    pads(?, ??) on the friction block are new,
    through smoke and smell of burning. Like the
    sliding sound, this is quite normal and has no
    importance.

96
  • During acceleration the power consumption is
    higher than in normal operation.

97
  • The acceleration time may vary somewhat
    depending, for instance, on the condition of the
    friction pads in the clutch coupling(???).

98
Bowl Closing
  • After attaining the right speed, the bowl should
    be closed.

99
  • Before starting the closing operation, the number
    of revolutions of the speed indicator must be
    checked against the speed table in the
    instruction book.

100
  • The acceleration time can vary somewhat
    depending, i.e. on the wear of the friction pads.
  • Close the bowl by opening the corresponding
    control valve. Wait till the bowl has closed.
    Then fill it.

101
Filling
  • The filling procedure differs for purification,
    clarification and concentration(????), i.e. for
    machines provided with purifier, clarifier and
    concentrator bowl respectively.

102
Clarification (clarifier bowl)
  • Set the flow regulator to wanted throughput and
    open the process liquid feed valve.

103
Purification (purifier bowl)
  • Supply liquid, usually water, to form the liquid
    seal. This liquid should preferably have the same
    temperature as the process liquid and must be
    supplied quickly.

104
  • Shut off the feed of sealing liquid when this
    begins flowing out and becomes visible in the
    sight glass.

105
Set the Flow Regulator to Desired Throughput
  • Slowly open the process liquid feed valve. A
    certain quantity of sealing liquid will now
    escape, until equilibrium is reached.

106
  • If the valve is opened too quickly, the liquid
    seal could be forced away to the effect that
    light liquid phase is discharged in the wrong
    way,

107
  • i.e. through the outlet for the heavy liquid
    phase. When this occurs with the filling
    procedure has to be repeated.

108
  • Adjust to suitable back pressure in the conduit
    for light phase (For machine with equipment for
    interface disposition see Selection of gravity
    disc)

109
Concentration (concentrator bowl)
  • The liquid seal builds up automatically. Adjust
    to wanted throughput-see Purification above.

110
Running
  • Check particularly that throughput and working
    temperature are constant that oil does not leak
    from the worm gear housing (oil level at
    operative height)

111
  • that, in purification, light phase is not
    escaping together with the heavy one, thereby
    indicating that the bowl is clogged or the liquid
    seal is broken.

112
  • If so, a sludge discharge must be carried out
    immediately and henceforth the interval between
    discharges be reduced.

113
  • If sludge had packed(??) between the bowl discs
    it may be necessary to stop the machine for
    manual cleaning of the bowl.
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