A normal heavy or intermediate fuel oil treatment process begins with the oil loaded into the bunker tank. Under normal circumstances the fuel will not be used immediately and should be analysed to confirm its specifications match the order and that it is appropriate to burn in the engine.
Assuming the fuel has passed any analysis tests, it will be pumped from the bunker tanks to the settling tank. In the case of HFO it will almost certainly contain some level of cat fines and all fuels will have some amount of water and sludge. In the settling tank, water and the heavier contaminants will migrate to the bottom, but some will remain suspended in the fuel.
Settling tanks have a sloping bottom with a drain valve at the lowest point by which sludge and water can be drained at regular intervals. The feed to the next stage in the process is above the drain cock. The other components include a heating coil so as to be able to control viscosity, high- and low-level alarms and a sight glass or gauges.
Because a ship operates in a dynamic environment the settling tank is not entirely successful in keeping the fuel separate from heavy contaminants and water. In anything but a dead calm, the movements of the vessel will stir up the contents of the settling tank to a greater or lesser degree.
The longer the fuel can remain in the settling tank, the more gravitational settlement there will be and the better the fuel will be prepared for the next stage. From the settling tank the fuel is sent to the service tank. On its way it passes first through a filter to remove the larger contaminants and then to a preheater.
Different oil fuel types need differing treatment mostly to control their viscosity. Distillates are much lighter fuels and will usually flow quite well except under conditions of very low temperatures when they may wax. Heavy fuel oils on the other hand have a very high viscosity and normally require heating.
Fuel oil tanks on the most modern ships may need to be in protected locations but on some older vessels there may be just a few millimetres of steel between the fuel and the sea. Even when protected, the location of storage tanks means temperatures will only ever match the ambient outside temperature.
It would be impossible to pump heavy fuel oil at such temperatures because it becomes highly viscous, so heating is essential to bring the temperature above the pour point. For most heavy fuel oils this will be around 40ºC. As the fuel progresses through the treatment system, the temperature will be raised to aid purifying and injection. The usual means of heating are steam coils in large vessels and electric heating in smaller ships.
The steam coils will draw their heat either from boilers or via heat exchangers in the engine exhaust stream. Heat exchangers are also used further along the treatment system. In the settling tank, a temperature of 60ºC is required, thinning the oil sufficiently for heavy contaminants to gravitate to the bottom. The fuel will be heated more before entering the separator, but care needs to be taken to keep the temperature below the boiling point of water otherwise separation will not be carried out efficiently.
After passing through the separator, the fuel will be maintained at around 80ºC – 85ºC in the service tank. The temperatures required for treating heavy residual fuels exceed the flashpoint of the distillates and therefore a different treatment system is required.
There is still a need to remove impurities particularly scale and water so filtration and separation is needed. However, to achieve the viscosity requirements of some engines it may be necessary to cool rather than heat the fuel in the final stages of its journey to the combustion chamber.
There are moves to ban heavy fuel oil for ships operating in high latitudes and instead require them only to use lighter fuels. Because of the waxing problem, distillate fuels in those ships will also need heating in tanks if problems are to be avoided. After heating, the fuel is sent to the first separator. In some ships there may be only a single separator but as the importance of proper fuel treatment for modern engines has become recognised, so more sophisticated treatment systems have been installed. A second route from the settling tank to the service tank not only allows for improved treatment but also provides redundancy and a chance to carry out necessary maintenance when necessary.
A vessel operating on HFO normally has two service tanks: one for high-sulphur HFO for use outside ECAs and one for low-sulphur HFO for use inside ECAs. When a service tank is full, there is generally a return line allowing overflow back to the settling tank.
Even before the 2020 date for reducing sulphur in fuels, there had been problems with miscibility of different fuels taken on board that ostensibly should be perfectly compatible. In future, when many more varieties of low sulphur fuel will be available, it may be necessary to segregate different fuels to avoid such problems. If compatibility proves to be a big problem after 2020, it is not inconceivable that owners will be obliged to partition tanks to allow each bunkering to be kept apart from other fuels.
The separator is a centrifuge device for removing solids and water from the fuel. When operated, the spinning action causes denser substances and particles to move outward in the radial direction. At the same time, the lighter oil is separated and moves to the centre where it is drawn off and pumped to the service tank. To be effective at separating fuel from water and contaminants, separators need to be able to cope with the flow rates needed to meet engine demands. A separator with a greater capacity will be most effective while those at the upper limits of their operating range will struggle to cope. Manufacturers have agreed on a voluntary standard laid down in the Separation Performance Standard of CE standard CWA15375:2005. The standard includes a certified flow rate (CFR) which if equal to or higher than that needed by the engine should ensure satisfactory separation under most circumstances.
In the past, only sludge and water needed to be removed from the fuel but over the last ten years or so the bigger problem has been the removal of cat fines. This has come about because of the newer methods of refining needed to extract more lighter products from crude oil. The process uses an aluminium silicate catalyst and, while most of it is recovered for reuse, small particles do become detached and find their way into the heavier types of fuel.
The problem of cat fines was first raised in the early years of the 21st century but, despite it receiving a great deal of publicity and having been recognised by insurers, engine makers and the International Organization for Standardization (ISO) it seems to be a growing, rather than a receding, problem.
Once only two-stroke main engines used HFO but today many four-strokes and gensets are also able to run on it as well. In some ships there is a single fuel strategy with only HFO being used. Cat fines are extremely hard and damaging to machinery which is why their removal is imperative. Maximum levels in fuels are set in the various versions of ISO 8217 but these are higher than engine makers’ recommendations. ISO Standard 8217:2012 introduced a maximum permissible 60ppm level of cat fines, expressed as Aluminium + Silicon, for marine residual fuels, a reduction from the 80ppm levels in ISO 8217:2005. The level of 60ppm Al+Si is maintained in the ISO 8217:2017 Fuel Standard.
However, engine manufacturers generally recommend a maximum of 15ppm level of cat fines in the fuel entering their engines. As this level is significantly lower than the levels specified in the ISO standards, it is essential to ensure adequate fuel handling and purification equipment and procedures are in place onboard to effectively bring the levels of cat fines in the fuel below 15ppm.
Wear from cat fines in two-stroke engines is found in the combustion chamber on cylinder liner, piston rings and piston ring grooves, resulting in high wear rates and possible scuffing. In the small four-stroke gensets, wear from cat fines is found primarily in the fuel system, where the fuel atomiser holes are worn out and have become too large for making suitable atomisation of the fuel. This causes poor combustion and increased soot and deposits in turbochargers, creating a vicious circle which eventually can lead to major engine damage.
Applying the separation standard to the fuel treatment plant is not mandatory, but the advice of independent experts is that it will definitely reduce the risk of damage posed by the significant quantity of cat fines found in some of the heaviest fuels. While it is possible to construct a fuel treatment system from individually sourced components, the leading specialists in the field produce modular units that can be customised to specific requirements.
Apart from the core components such as pumps, heat exchangers and separators, many fuel treatment systems will incorporate additional components. Counted among the most useful of these is a homogeniser that breaks down long chain molecules into smaller particles that combust more easily and reducing deposits. In very heavy fuels, molecules of carbon often form long chains that will never combust entirely in the engine. The homogeniser overcomes this by grinding the long chains and cutting them into smaller particles. Such a device will greatly reduce the amount of sludge and improve the combustion characteristics of the fuel.
Some of these devices also have a modification that allows the introduction of controlled amounts of water to form an emulsion. Emulsified fuels are known to produce less NOx and are predicted to become highly beneficial in helping ship operators meet the most stringent NOx emission regulations.
Mechanical treatment of fuel can also be complemented by using additives to achieve improved fuel consumption and reduced emissions. The history of chemical additives is a chequered one, as not all products have been found to produce the claimed results. Nevertheless, some products do achieve improvements and it is almost certain that, as emission reduction demands increase, more products will be put forward as solutions. An area that may well see more additive product activity is in ensuring that stability of blended fuels is improved and sludge reduced.
The design of the fuel system and choice of components is mostly in the control of the shipowner but there are safety elements to be considered and some aspects are regulated under SOLAS where requirements for fuel systems include:
Fuel systems on gas-only or dual-fuel vessels that are not LNG carriers are something of a novelty and outside the experience of most operators. This is likely to be the case for many years to come as most industry observers now believe that it will be 2025 or even later before the number of LNG powered vessels other than LNG carriers reaches 1,000. That may sound a large number, but it is less than 2% of all ships.
In adopting the IGF Code, the IMO has requested the ISO to develop a standard for quick-disconnect bunkering connections and work on this is progressing. A standard LNG bunkering checklist was not included as part of the request but the MSC has since been requested for this to be included as part of the task. The biggest problem of LNG is that the fuel must be stored at extremely low temperatures and under pressure.
In addition, it has a lower flash point than oil fuels and in the event of a leak in the storage or fuel delivery system, any escape of fuel would be far more difficult to contain and to recover than is the case with oil. However, the system between tank and engine is less complex and there are virtually no waste products to be stored and disposed of ashore.
Until the adoption of the IMO’s IGF Code, approval of LNG fuel storage and delivery systems was done by flag states on a more-or-less case-by-case basis. There are a small number of systems so far developed for LNG although the number must be expected to increase. Several shipbuilders either have or are developing systems and while they will have much in common there will be variations. Few seagoing engineers apart from those who have been employed on gas carriers or the small number of other ship types with dual-fuel or pure gas engines will have much knowledge of the fuel systems for gas fuelled ships.
According to the IGF rules, the LNG fuel tanks have to be selected from among the “Independent Types A, B, or C”. ‘Independent’ means that the tanks are not formed as part of the ship’s structure. In the first two types the gas is stored at atmospheric pressure but in a type C tank, the gas is contained under high pressure. Type C tanks require less space inside the ship than A or B types and for this reason have generally been favoured for use as fuel tanks on LNG-fuelled vessels. However, for larger cargo ships running on gas, a type B tank may be considered because there may be more space available – especially if the intended cargo is a high density one such as ores – and because of the cheaper construction costs involved. Whatever tank type is chosen the need to retain any leakage of gas within a second barrier before it can contact the ship’s hull is an imperative. This is because the cryogenic temperatures needed to keep LNG in its liquid form will mean spills that come into contact with the hull structures will inevitably cause cracking of the steel structure of the vessel.
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