阅读说明：本技术 燃料系统 (Fuel system ) 是由 H·B·维玛尔 于 2019-01-23 设计创作，主要内容包括：公开了一种用于海运船舶(1)的发动机(4)的燃料系统(20)。所述燃料系统(20)包括用于清洁用于所述发动机(4)的燃料的沉降罐(110)以及用于存储用于所述发动机(4)的燃料的供给罐(130)。所述燃料系统(20)还包括过滤系统(220),所述过滤系统(220)包括第一过滤器(222),从所述沉降罐(110)流动到所述供给罐(130)的燃料穿过所述第一过滤器(222)。所述过滤系统(220)被配置成能在第一模式和第二模式下操作,在所述第一模式中,所述第一过滤器(222)从自所述沉降罐(110)流动到所述供给罐(130)的燃料去除污染物,在所述第二模式中,燃料从所述供给罐(130)流动穿过所述第一过滤器(222)以从所述第一过滤器(222)清除所述污染物。(A fuel system (20) for an engine (4) of a marine vessel (1) is disclosed. The fuel system (20) comprises a settling tank (110) for cleaning fuel for the engine (4) and a feed tank (130) for storing fuel for the engine (4). The fuel system (20) further comprises a filtration system (220), the filtration system (220) comprising a first filter (222), the first filter (222) being traversed by fuel flowing from the settling tank (110) to the feed tank (130). The filtration system (220) is configured to be operable in a first mode in which the first filter (222) removes contaminants from fuel flowing from the settling tank (110) to the supply tank (130), and a second mode in which fuel flows from the supply tank (130) through the first filter (222) to purge the contaminants from the first filter (222).)

1. A fuel system for an engine of a marine vessel, the fuel system comprising:

a settling tank for cleaning fuel for the engine;

a supply tank for storing fuel for the engine; and

a filtration system comprising a first filter through which fuel flowing from the settling tank to the feed tank passes;

wherein the filtration system is configured to be operable in a first mode in which the first filter removes contaminants from fuel flowing from the settling tank to the supply tank, and a second mode in which fuel flows from the supply tank through the first filter to purge the contaminants from the first filter.

2. The fuel system of claim 1, wherein the filtration system comprises a second filter for removing purged contaminants from fuel that has passed through the first filter when the filtration system is operating in the second mode.

3. The fuel system of claim 2, wherein the first filter is connected to the settling tank via the second filter, whereby fuel from which the second filter has removed the purged contaminants can be returned to the settling tank.

4. A fuel system according to claim 2 or claim 3, wherein the filtration system comprises a trap for collecting the contaminants removed by the second filter.

5. The fuel system of claim 4, wherein the trap is removable from the filtration system.

6. The fuel system of any one of claims 2 to 5, comprising a pump for pumping fuel through the second filter.

7. The fuel system of claim 6, wherein the filtration system is configurable to create a circuit such that the pump for pumping fuel through the second filter is capable of causing fuel to pass through the second filter multiple times and back to the pump for pumping fuel through the second filter.

8. The fuel system of any one of claims 1 to 7, comprising a pump for pumping fuel from the feed tank through the first filter when the filtration system is operating in the second mode.

9. The fuel system of claim 8, wherein the feed tank is connected to the first filter via the pump for pumping fuel from the feed tank through the first filter.

10. The fuel system of any one of claims 1 to 9, comprising a valve through which fuel flowing from the settling tank to the first filter passes, wherein the valve is for controlling the flow of fuel from the first filter towards the settling tank.

11. The fuel system of claim 10, wherein when the filtration system is operating in the second mode, the filtration system is configured such that the valve is closed to prevent or impede fuel flow from the first filter toward the settling tank.

12. The fuel system of any one of claims 1 to 11, comprising a filtration system controller for controlling the filtration system.

13. The fuel system of claim 12, wherein the filtration system comprises a sensor configured to detect a condition of the first filter or a parameter of the fuel at a location between the first filter and the supply tank, and send a signal to the filtration system controller based on the detected condition or parameter, and

wherein the filtration system controller is configured to cause the filtration system to operate in the second mode based on the signal.

14. A marine vessel comprising a fuel system according to any one of claims 1 to 13.

15. A method of operating a filtration system for a fuel system of an engine of a marine vessel, the method comprising:

causing the filtration system to operate in a first mode whereby fuel flows from a settling tank of the fuel system to a supply tank of the fuel system via a first filter of the filtration system for removing contaminants from the fuel; and

causing the filtration system to operate in a second mode whereby fuel flows from the supply tank through the first filter to purge the contaminants from the first filter.

16. A non-transitory computer readable storage medium storing instructions that, when executed by a processor of a filtration system controller, cause the processor to implement the method of claim 15.

Technical Field

The present invention relates to a fuel system for an engine of a marine vessel, a marine vessel comprising a fuel system and a method of operating a filtration system for a fuel system of an engine of a marine vessel.

Background

Marine vessels such as container ships have engines powered by Heavy Fuel Oil (HFO) or the like. Such fuels are typically relatively pure and uncontaminated as they leave the refinery. However, between oil refineries and ships, fuel may pick up solid contaminants such as catalyst fines, rust, dust, sand, dirt, and other solid particulates from, for example, dirty hoses and tanks. Such solid contaminants wear and/or clog engine components and should therefore be removed from the fuel before it enters the engines of the vessel. The fuel may also be contaminated with liquid contaminants such as fresh water or salt water.

It is generally known in the marine industry that only the use of one or more centrifugal separators (also known as purifiers) that separate particles and water from fuel is sufficient and effective to remove contaminants from fuel on a marine vessel. Thus, conventional marine vessels typically have one or more such centrifugal separators fluidly connected between one or more settling tanks and one or more supply tanks.

The settling tank is a deep tank in the engine room of the ship, which is used for pre-cleaning the fuel by gravity. The liquid mixture in the settling tank is slowly cleaned as the heavier liquids and solids sink to the bottom under the influence of gravity. Typically, a marine vessel will have at least two settling tanks, each tank having a capacity sufficient for full 24 hour operation of all the consumers on the vessel. The settling tank should be designed to facilitate separation of sludge from water and may be provided with baffles to reduce mixing of sludge with fuel. The bottom of the settling tank is preferably inclined towards the sludge discharge and the pump head should not be located near the sludge space. The temperature in the settling tank should be as high as possible to aid in settling of the solids. However, the temperature should be below 75 degrees celsius to avoid asphaltene formation, and the degree to which the temperature is higher than the "pour point" of the fuel should not be below 7 degrees celsius to ensure pumpability. Pour point is the lowest temperature at which the fuel just flows due to its own weight.

The feed tank is a fuel tank containing a quantity of fuel ready for immediate use. Typically, at least one supply tank is provided for each fuel to be used onboard the vessel necessary for the propulsion system and the generator system. The supply tank should preferably have sufficient fuel capacity to enable operation at sea for at least eight hours at the maximum continuous rating of the propulsion and/or power generation equipment associated with the supply tank.

Because of the similar densities of water and oil, centrifugal separators must operate for extended periods of time (or constantly) to separate the water from the oil. The energy required to power the centrifugal separator of a typical large marine vessel for one year is considerable and may for example be equivalent to the energy present in about 300 tons HFO. In addition, approximately 1% of HFO processed by the centrifugal separator is contained in the sludge waste product produced therefrom. This sludge is not combustible and must be disposed of in an environmentally friendly manner.

Embodiments of the present invention aim to enable adequate decontamination of fuel for the engines of marine vessels, whilst addressing the aforementioned problems.

Disclosure of Invention

A first aspect of the invention provides a fuel system for an engine of a marine vessel, the fuel system comprising: a settling tank for cleaning fuel for the engine; a supply tank for storing fuel for the engine; and a filtration system comprising a first filter through which fuel flowing from the settling tank to the feed tank passes; wherein the filtration system is configured to be operable in a first mode in which the first filter removes contaminants from fuel flowing from the settling tank to the supply tank, and a second mode in which fuel flows from the supply tank through the first filter to purge the contaminants from the first filter.

Optionally, the filtration system comprises a second filter for removing the purged contaminants from fuel that has passed through the first filter when the filtration system is operating in the second mode.

Optionally, the second filter comprises a pleated fabric filter.

Optionally, the first filter is connected to the settling tank via the second filter, whereby fuel from which the second filter has removed the purged contaminants can be returned to the settling tank.

Optionally, the filtration system comprises a collector for collecting the contaminants removed by the second filter.

Optionally, the collector is removable from the filtration system.

Optionally, the collector comprises a sleeve insertable in the second filter.

Optionally, the fuel system comprises a pump for pumping fuel through the second filter. Optionally, the pump for pumping fuel through the second filter is for pumping fuel through the second filter when the filtration system is operating in the second mode.

Optionally, the filtration system can be configured to create a circuit such that the pump for pumping fuel through the second filter can cause fuel to pass through the second filter a plurality of times and back to the pump for pumping fuel through the second filter. Optionally, the circuit is isolated from the first filter such that the filtration system is operable in the first mode while the pump for pumping fuel through the second filter causes fuel to pass through the second filter a plurality of times and back to the pump for pumping fuel through the second filter.

Optionally, the fuel system comprises a pump for pumping fuel from the feed tank through the first filter when the filtration system is operating in the second mode.

Optionally, the feed tank is connected to the first filter via the pump for pumping fuel from the feed tank through the first filter.

Optionally, the fuel system comprises a valve through which fuel flows from the settling tank to the first filter and the valve is for controlling the flow of fuel from the first filter towards the settling tank.

Optionally, when the filtration system is operating in the second mode, the filtration system is configured such that the valve is closed to prevent or impede fuel flow from the first filter towards the settling tank.

Optionally, the fuel system comprises a filtration system controller for controlling the filtration system.

Optionally, the filtration system comprises a sensor configured to detect a condition of the first filter or a parameter of the fuel at a location between the first filter and the supply tank, and to send a signal to the filtration system controller based on the detected condition or parameter.

Optionally, the filtration system controller is configured to cause the filtration system to operate in the second mode based on the signal.

A second aspect of the invention provides a marine vessel comprising the fuel system of the first aspect of the invention.

A third aspect of the invention provides a method of operating a filtration system for a fuel system of an engine of a marine vessel, the method comprising: causing the filtration system to operate in a first mode whereby fuel flows from a settling tank of the fuel system to a supply tank of the fuel system via a first filter of the filtration system for removing contaminants from the fuel; and causing the filtration system to operate in a second mode whereby fuel flows from the supply tank through the first filter to purge the contaminants from the first filter.

Optionally, the causing the filtration system to operate in the first mode comprises: causing a pump to operate to pump fuel from the settling tank to the feed tank via the first filter.

Optionally, the method comprises: receiving a signal indicative of a fuel pressure at a location between the first filter and the supply tank.

Optionally, the method comprises: receiving the signal while the filtration system is operating in the first mode.

Optionally, the method comprises: causing a valve to close to prevent or impede fuel flow from the first filter toward the settling tank when it is determined that the fuel pressure is less than a predetermined threshold fuel pressure.

Optionally, the causing the filtration system to operate in the second mode comprises: causing a pump to operate to pump fuel from the feed tank through the first filter to purge the contaminants from the first filter.

Optionally, the causing the filtration system to operate in the second mode comprises: causing the contaminants that have been purged from the first filter when the filtration system is operating in the second mode and the fuel that has passed through the first filter to pass through a second filter of the filtration system for removing purged contaminants from the fuel.

Optionally, the causing the filtration system to operate in the second mode comprises: causing fuel from which the second filter has removed the purged contaminants to be returned to the settling tank.

A fourth aspect of the invention provides a non-transitory computer readable storage medium storing instructions that, when executed by a processor of a filtration system controller, cause the processor to implement the method of the third aspect of the invention.

Drawings

Embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

figure 1 shows a schematic side view of an example of a marine vessel according to an embodiment of the invention;

FIG. 2 shows a schematic diagram of an example of a fuel system according to an embodiment of the invention;

FIG. 3 shows a schematic diagram of an example of a fuel system according to another embodiment of the invention;

FIG. 4 shows a flow diagram illustrating an example of a method of operating a filtration system according to an embodiment of the present invention; and is

Fig. 5 shows a flow diagram illustrating an example of another method of operating a filtration system according to an embodiment of the present invention.

Detailed Description

Fig. 1 shows a schematic side view of an example of a marine vessel according to an embodiment of the invention. In this embodiment, the ship is a container ship 1. In other embodiments, the marine vessel may be another form of cargo vessel (such as a tanker, a dry cargo vessel or a refrigerated vessel), or a passenger vessel or any other marine vessel using liquid fuels such as fuel oil or heavy fuel oil.

The marine vessel 1 has a hull 2 and one or more engine rooms 3 inside the hull 2. The marine vessel 1 is powered by one or more large internal combustion engines 4, such as four-stroke or two-stroke auto-ignition combustion engines 4, located in an engine room 3. One or more engines 4 drive propulsion mechanisms (such as one or more propellers). The vessel 1 may also include one or more auxiliary engines (referred to as gensets) that provide power and/or heat to various power consuming devices on the vessel 1. The vessel 1 further comprises a fuel system 10, 20 for supplying fuel to one or more engines 4. The fuel systems 10, 20 may be any of the fuel systems described herein as embodiments of the invention, such as the fuel system shown in FIG. 2 or the fuel system shown in FIG. 3.

The skilled person will be familiar with the components and systems of the marine vessel and therefore further detailed discussion of these components and systems is omitted for the sake of brevity.

As noted above, solid contaminants in the fuel can wear and/or clog engine components, and it is therefore highly preferred that such solid contaminants be removed from the fuel before the fuel enters the engine. As also indicated above, it is common knowledge in the marine industry that adequate and effective removal of contaminants from fuel on a marine vessel can only be achieved using one or more centrifugal separators. This is at least in part because removal of both solid and liquid contaminants (e.g., fresh water or brine) from fuel is considered essential in the industry. However, water pollutes the fuel very little (or usually only to a small extent), and the engines of marine vessels (e.g. diesel engines) are in most cases capable of burning fuel, such as HFO, even if polluted to some extent by water. The invention is therefore based on the following insight: it is sufficient to remove solid contaminants from the fuel before it enters the engine and no liquid contaminants (particularly water) need be removed.

One known method of removing solid contaminants from oil on a marine vessel is through the use of filters. However, while it is known to use filters to filter lubricating oil, it is not generally preferred in the marine industry to use filters to filter fuel. This is because the filter will become clogged with solid contaminants, resulting in a reduction in the efficiency of the system. Once clogged, the filter may be partially unblocked by blowing air back through the filter to remove particulate matter from the filter. However, air has a relatively low inertia, and therefore once a small portion of the filter is cleaned, the air will thereafter flow entirely through the cleaned portion of the filter without clearing particular matter from the remainder of the filter. Thus, air is not particularly effective in removing particulate matter from the surface of the filter.

Embodiments of the present invention provide a fuel system for implementing the removal of solid contaminants from fuel while addressing the aforementioned problems.

FIG. 2 shows a schematic diagram of an example of a fuel system according to an embodiment of the invention. The fuel system 10 is for an engine of a marine vessel. By "for the engine" is meant one or more engines of which the fuel system 10 is intended for a marine vessel. That is, the fuel system 10 may be used to supply fuel to an engine or engines of a marine vessel (such as the engine 4 shown in fig. 1 and the marine vessel 1 or any variation thereof described herein).

Broadly, fuel system 10 includes a settling tank 110 for cleaning fuel for engine 4; a supply tank 130 for storing fuel for the engine 4; and a filtration system 120, the filtration system 120 including a first filter 122, the fuel flowing from the settling tank 110 to the supply tank 130 passing through the first filter 122. As will be described in greater detail below, the filtration system 120 is configured to be operable in a first mode in which the first filter 122 removes contaminants from fuel flowing from the settling tank 110 to the supply tank 130, and a second mode in which fuel flows from the supply tank 130 through the first filter 122 to clear contaminants from the first filter 122.

More specifically, in this embodiment, the fuel system 10 includes a storage tank 100 for storing a volume of fuel for the engine 4. In some embodiments, fuel system 10 may include a plurality of such storage tanks 100. The storage tank 100 is also referred to as a silo tank 100. The storage tank 100 stores fuel for an auxiliary engine, a boiler, or any other device that consumes fuel other than the main engine 4. The storage tank 100 may be capable of being filled during refueling of the vessel 1 from a container on another vessel (such as a barge) or vehicle or on shore (sometimes referred to as a stowing operation). If the fuel is a heavy and viscous fuel, such as HFO, the settling tank 110 may be heated (such as to about 80 degrees Celsius) in order to reduce the viscosity and consistency of the fuel. This makes it easier to pump fuel through fuel system 10. In some embodiments, the fuel may be heated above 100 degrees celsius to evaporate water from the settling tank 110.

The fuel system 100 further comprises a fuel transfer pump 105, said fuel transfer pump 105 being used for pumping fuel from the storage tank 100 to the settling tank 110. In this embodiment, storage tank 100 is fluidly connected to settling tank 110 via fuel transfer pump 105 such that fuel may flow from storage tank 100 to settling tank 110 via fuel transfer pump 105. In other embodiments, fuel transfer pump 105 may be located elsewhere. For example, in some embodiments, fuel transfer pump 105 may be located in storage tank 100 or settling tank 110. In some embodiments, storage tank 100 and/or fuel transfer pump 105 may be omitted. For example, in some embodiments, fuel may be able to flow from storage tank 100 to settling tank 110 under the influence of gravity.

In some embodiments, fuel system 10 includes one or more valves (not shown) through which fuel flowing from storage tank 100 to settling tank 110 passes. The one or more valves may be used to control the flow of fuel between storage tank 100 and settling tank 110. More specifically, the one or more valves may be used to control the flow of fuel from storage tank 100 to settling tank 110 and/or may be used to control the flow of fuel from settling tank 110 to storage tank 100. For example, the one or more valves may be closable to prevent or impede fuel flow from storage tank 100 to settling tank 110 and/or to prevent or impede fuel flow from settling tank 110 to storage tank 100.

In this embodiment, the settling tank 110 may be fluidly connected to the supply tank 130 via the first filter 122 such that fuel may flow from the settling tank 110 to the supply tank 130 via the first filter 122. In various embodiments, different types of filters may be used with respect to the first filter 122. The first filter 122 may, for example, comprise a surface filter in which particulate matter accumulates on the surface of the first filter 122, or a depth filter in which particular matter is trapped within the filter media. The first filter 122 may include one or more filter cloths or meshes to allow liquid to pass through but prevent solid matter exceeding a certain particle size from flowing. The first filter 122 may include one or more different filter screen configurations, wherein the filter includes different fabric or mesh configurations. In some embodiments, the filter media of first filter 122 may be made of one or more of the following: paper; a pleated paper filter; cellulose; weaving, knitting or winding fibers (such as cloth); ceramic fibers; a fabric; foaming; a ceramic foam; a metal fiber filter; sintering the metal; and/or a wall flow monolith structure.

The filtration system 120 of this embodiment includes a valve 121 through which fuel flowing from the settling tank 110 to the first filter 122 passes. Valve 121 is used to control the flow of fuel between the first filter 122 and the settling tank 110. More specifically, valve 121 is used to control the flow of fuel from first filter 122 to settling tank 110. As will be described further below, when the filtration system 120 is operating in the second mode, the filtration system 120 is configured such that the valve 121 is closed to prevent or impede fuel flow from the first filter 122 toward the settling tank 110. In some embodiments, the valve 121 may be a non-return valve (also referred to as a check valve or one-way valve) configured such that fuel cannot flow from the first filter 122 to the settling tank 110 via the valve 121, and thus the valve 121 may not need to be actively closed. In some embodiments, the valve 121 may be selectively operated from a remote controller (not shown). In other embodiments, valve 121 may be omitted. In some such other embodiments, the settling tank 110 may be permanently fluidly connected to the supply tank 130 via the first filter 122. However, fuel flowing through the first filter 122 when the filtration system 120 is operating in the second mode may carry the purged contaminants from the first filter 122 back to the settling tank 110. This may be undesirable as it may increase the contaminant to fuel ratio in the settling tank 110. However, in some embodiments, it may nevertheless be intentional or desirable to collect the purged contaminants in the settling tank 110.

In some embodiments, fuel system 10 may include one or more pre-filters or strainers for removing particularly large particulate matter before fuel passes through first filter 122 when filtration system 120 is operating in the first mode.

In this embodiment, the filtration system 120 includes a second pump 124, the second pump 124 for pumping fuel from the supply tank 130 through the first filter 122 when the filtration system 120 is operating in the second mode. In this embodiment, the supply tank 130 is fluidly connected to the first filter 122 via the second pump 124 such that fuel may flow from the supply tank 130 to the first filter 122 via the second pump 124. In other embodiments, the second pump 124 may be located elsewhere. For example, in some embodiments, the second pump 124 may be located in the supply tank 130, or a second filter 125 (discussed below) may be connected to the first filter 122 via the second pump 124. In some embodiments, the second pump 124 may be integral with the first filter 122. In some embodiments, the second pump 124 may be omitted. For example, in some embodiments, when the filtration system 120 is operating in the second mode, fuel may be able to flow from the supply tank 130 through the first filter 122 under the influence of gravity. However, it is highly preferred that the second pump 124 is provided so that the fuel passing through the first filter 122 has sufficient momentum to clear contaminants from the first filter 122 when the filtration system 120 is operating in the second mode.

In some embodiments, the second pump 124 is a bi-directional pump. Thus, in such embodiments, the second pump 124 is used to pump fuel from the settling tank 110 to the supply tank 130 via the first filter 122 when the filtration system 120 is operating in the first mode. In other embodiments, the second pump 124 is a one-way pump for pumping fuel from the supply tank 130 through the first filter 122 when the filtration system 120 is operating in the second mode, and the filtration system 120 includes a pump (not shown, but referred to herein for ease of reference as a third pump) separate from the second pump 124 for pumping fuel from the settling tank 110 to the supply tank 130 via the first filter 122 when the filtration system 120 is operating in the first mode. In some embodiments, the settling tank 110 is fluidly connected to the feed tank 130 via a third pump such that fuel may flow from the settling tank 110 to the feed tank 130 via the third pump. More specifically, in some embodiments, first filter 122 is fluidly connected to supply tank 130 via a third pump. In other embodiments, the third pump may be located elsewhere. For example, in some embodiments, a third pump may be located in the supply tank 130, or the settling tank 110 may be connected to the first filter 122 via the third pump. In some embodiments, the third pump may be omitted. For example, in some embodiments, fuel may be able to flow from the settling tank 110, through the first filter 122, and to the supply tank 130 under the influence of gravity.

In this embodiment, the filtration system includes a second filter 125, the second filter 125 for removing the purged contaminants from the fuel that has passed through the first filter 122 when the filtration system 120 is operating in the second mode. The second filter 125 may, for example, comprise a pleated fabric filter, such as paper. In various embodiments, different types of filters may be used with respect to the second filter 125. The second filter 125 may, for example, include a surface filter in which particulate matter accumulates on a surface of the second filter 125, or a depth filter in which particular matter is trapped within a filter medium. The second filter 125 may include one or more filter cloths or meshes to allow liquid to pass through but prevent solid matter exceeding a certain particle size from flowing. The second filter 125 may include one or more different filter screen configurations, wherein the filter includes different fabric or mesh configurations. In some embodiments, the filter media of the second filter 125 can be made of one or more of the following: paper; a pleated paper filter; cellulose; weaving, knitting or winding fibers (such as cloth); ceramic fibers; a fabric; foaming; a ceramic foam; a metal fiber filter; sintering the metal; and/or a wall flow monolith structure. In this embodiment, the filtration system 120 includes a collector 126, the collector 126 for collecting contaminants removed by the second filter 125. In some embodiments, the collector 126 may be removable from the filtration system 120, such as for cleaning the collector 126 or for replacing the collector 126 when the collector 126 is full or nearly full. For example, in some embodiments, the collector 126 comprises a sleeve that is insertable into the second filter 125 and thereafter detachable from the second filter 125. In other embodiments, the collector 126 may be omitted.

In this embodiment, the first filter 122 is connected to the settling tank 110 via a second filter 125. Thus, fuel from which the second filter 125 has removed the purged contaminants may be returned to the settling tank 110. In some embodiments, a non-return valve (not shown) may be disposed between the second filter 125 and the settling tank 110 and configured such that fuel cannot flow from the settling tank 110 to the second filter 125 via the non-return valve.

In some embodiments, the second filter 125 may be omitted. For example, in some embodiments, the purged contaminants and fuel that has passed through the first filter 122 when the filtration system 120 is operating in the second mode may be collected in a canister without being filtered. The tank may be, for example, the settling tank 110 or a different tank, although using the settling tank 110 for this purpose as discussed above may be undesirable because it may increase the contaminant to fuel ratio in the settling tank 110.

The fuel system 10 of this embodiment includes a filtration system controller 140 for controlling the filtration system 120. The controller 140 may include one or more microprocessors. In this implementation, the controller 140 is communicatively connected to and for controlling each of the following: a fuel transfer pump 105, a valve 121, and a second pump 124, as depicted by the dashed lines in fig. 2. In other embodiments, the controller 140 may be used to control the third pump (not shown) discussed above. In some embodiments, some of these elements may be controlled by an entity other than controller 140. Of course, in embodiments where one or more of the fuel transfer pump 105, valve 121, and second pump 124 are omitted, the controller 140 will not be communicatively connected to and used to control such omitted elements.

In this embodiment, the filtration system 120 includes a pressure sensor 123, the pressure sensor 123 configured to detect a fuel pressure at a location between the first filter 122 and the supply tank 130, the fuel pressure being a parameter of the fuel that has flowed through the first filter 122. The location in this embodiment is between the first filter 122 and the second pump 124, but in other embodiments the location may be elsewhere, such as between the second pump 124 and the supply tank 130. In this embodiment, the pressure sensor 123 is communicatively connected to the controller 140 and is configured to send a signal to the controller 140 indicative of the fuel pressure at the location. When it is determined that the fuel pressure at the location is less than the predetermined threshold fuel pressure, the controller 140 is configured to cause the filtration system 120 to operate in the second mode.

This determination may be made by the controller 140. For example, the pressure sensor 123 may be configured to detect fuel pressure and send a signal to the controller 140 continuously, periodically, or upon command by the controller 140, and the controller 140 may be configured to determine whether the fuel pressure is less than a predetermined threshold fuel pressure based on the received signal, such as by extracting information from the received signal and/or comparing the received signal or the extracted information to data accessible to the controller 140. Alternatively, the determination may be made at a location other than the controller 140, such as at the pressure sensor 123. For example, pressure sensor 123 may be configured to detect fuel pressure continuously, periodically, or upon command by controller 140, and send a signal to controller 140 only when the fuel pressure is less than a predetermined threshold fuel pressure (such as by comparing the detected pressure to a predetermined threshold fuel pressure). The controller 140 may then be configured to cause the filtration system 120 to operate in the second mode based on having received the signal. In any case, it should be appreciated that the filtration system 120 includes a sensor 123, the sensor 123 is configured to detect a parameter (in this case, pressure) of the fuel at a location between the first filter 122 and the supply tank 130 and send a signal to the controller 140 based on the detected parameter, and the controller 140 is configured to cause the filtration system 120 to operate in the second mode based on the signal (the nature or content of the signal, or the receipt of the signal).

FIG. 3 shows a schematic diagram of an example of another fuel system according to an embodiment of the invention. The fuel system 20 is also used for engines of marine vessels, such as the engine 4 and marine vessel 1 shown in fig. 1 or any variation of the engines and marine vessels described herein.

Broadly, fuel system 20 includes a settling tank 110 for cleaning fuel for engine 4; a supply tank 130 for storing fuel for the engine 4; and a filtration system 220, the filtration system 220 comprising a first filter 222, the fuel flowing from the settling tank 110 to the supply tank 130 passing through the first filter 222. Filtration system 220 is configured to be operable in a first mode in which first filter 222 removes contaminants from fuel flowing from settling tank 110 to supply tank 130, and a second mode in which fuel flows from supply tank 130 through first filter 222 to clear contaminants from first filter 222.

Similar to the embodiment of fig. 2, in this embodiment, the fuel system 20 includes a storage tank 100 for storing a volume of fuel for the engine 4, a fuel transfer pump 105 for pumping fuel from the storage tank 100 to a settling tank 110, and the storage tank 100 is fluidly connected to the settling tank 110 via the fuel transfer pump 105 such that fuel may flow from the storage tank 100 to the settling tank 110 via the fuel transfer pump 105. However, in other embodiments, any of the modifications to storage tank 100 and/or fuel transfer pump 105 and/or settling tank 110 (such as heating thereof) and/or elements therebetween (such as one or more valves) discussed herein with reference to the embodiment of fig. 2 may be made to the embodiment of fig. 3 to form further embodiments.

In this embodiment, the settling tank 110 may be fluidly connected to the supply tank 130 via a first filter 222 such that fuel may flow from the settling tank 110 to the supply tank 130 via the first filter 222. In various embodiments, different types of filters may be used with respect to first filter 222. The first filter 222 may, for example, comprise any one or more of the filter types discussed herein with respect to the first filter 122 of the embodiment of fig. 2.

In this embodiment, the filtration system 220 includes a fuel pump 221 for pumping fuel from the settling tank 110 to the feed tank 130 through a first filter 222 when the filtration system 220 is operating in the first mode. In this embodiment, the settling tank 110 is fluidly connected to the first filter 222 via the fuel pump 221 such that fuel may flow from the settling tank 110 to the first filter 222 via the fuel pump 221. In other embodiments, the fuel pump 221 may be located elsewhere. For example, in some embodiments, the fuel pump 221 may be located in the settling tank 110, or between the first filter 222 and the feed tank 130. In some embodiments, the fuel pump 221 may be integral with the first filter 222. In some embodiments, fuel pump 221 may be omitted. For example, in some embodiments, when the filtration system 220 is operating in the first mode, fuel may be able to flow from the settling tank 110 through the first filter 222 under the influence of gravity. However, it is highly preferred to provide the fuel pump 221 to assist the fuel system 20 in reliably meeting the fuel demand of the engine 4. Further, it is easier to push the fuel through the first filter 222 than to pull the fuel, and therefore it is preferable to provide the fuel pump 221 upstream of the first filter 222, as shown. In some embodiments, fuel pump 221 has a variable speed drive for regulating the flow of fuel through filter system 220. The variable speed drive may be used to match the consumption of the engine 4 to the flow rate of fuel in the fuel system 20.

In some embodiments, when the filtration system 220 is operating in the second mode, the fuel pump 221 may be configured to prevent or impede fuel flow from the first filter 222 toward the settling tank 110. In some embodiments, the filtration system 220 may include a valve (not shown) through which fuel flowing from the settling tank 110 to the first filter 222 passes and which is used to prevent or impede fuel flow from the first filter 222 toward the settling tank 110 when the filtration system 220 is operating in the second mode. The valve may, for example, take any of the forms described herein for the valve 121 of the embodiment of fig. 2.

In some embodiments, fuel system 20 may include one or more pre-filters or strainers for removing particularly large particulate matter before fuel passes through first filter 222 when filtration system 220 is operating in the first mode.

In this embodiment, the filtration system 220 includes a back flush pump 222a, such as a piston pump, for pumping fuel from the supply tank 130 through the first filter 222 when the filtration system 220 is operating in the second mode. In this embodiment, when the filtration system 220 is operating in the second mode, the backflush pump 222a is located upstream of the first filter 222 such that the supply tank 130 is fluidly connected to the first filter 222 via the backflush pump 222a and fuel may flow from the supply tank 130 to the first filter 222 via the backflush pump 222 a. In this embodiment, the backflush pump 222a is integral with the first filter 222. In other embodiments, the backflush pump 222a may be located elsewhere. For example, in some embodiments, the backflushing pump 222a may be located between the supply tank 130 and the first filter 222 and not integral with the first filter 222, or located in the supply tank 130, or a second filter 225 (discussed below) may be connected to the first filter 222 via the backflushing pump 222 a. In some embodiments, the backflush pump 222a may be omitted. For example, in some embodiments, when the filtration system 220 is operating in the second mode, fuel may be able to flow from the supply tank 130 through the first filter 222 under the influence of gravity. However, it is highly preferred that the backflush pump 222a be provided so that fuel passing through the first filter 222 has sufficient momentum to clear contaminants from the first filter 222 when the filtration system 220 is operating in the second mode.

In this embodiment, the filtration system 220 includes a fuel return valve 224, and the first filter 222 is connected to the supply tank 130 via the fuel return valve 224. The fuel return valve 224 may be controlled by the filtration system controller 140 (discussed below) to direct fuel pumped by the fuel pump 221 to the feed tank 130 or back to the settling tank 110 via a fuel return path R connecting the fuel return valve 224 to the settling tank 110. When the ship is at port or during emptying of the supply tank 130, it may be desirable to recirculate the fuel back to the settling tank 110 to regulate the fuel pressure, or if the fuel has a particularly high degree of solid contaminants, it may be desirable to pass the fuel more than once through the first filter 222. In other embodiments, the fuel return valve 224 and the fuel return path R may be omitted.

Further, in this embodiment, the filtration system 220 includes a first bypass valve BV1 and a second bypass valve BV2 connected by a bypass B. The first bypass valve BV1 is located between the fuel pump 221 and the first filter 222, and the second bypass valve BV2 is located between the recoil pump 222a and the supply tank 130. In other embodiments, the second bypass valve BV2 may be located between the first filter 222 and the supply tank 130 without bypassing the backflush pump 222 a. The first bypass valve BV1 and the second bypass valve BV2 may be controlled by the controller 140 to direct fuel pumped by the fuel pump 221 via the bypass B rather than via the first filter 222. This may be desirable to enable heating of the tubing prior to use of the first filter 222. For example, fuel that may be heated in the settling tank 110 can flow out of the settling tank 110 via the fuel pump 221, the bypass B, the fuel return valve 224, and the fuel return path R, and then return to the settling tank 110. Then, the first bypass valve BV1 and the second bypass valve BV2 may be controlled by the controller 140 to thereafter direct the fuel pumped by the fuel pump 221 through the first filter 222 and onto the supply tank 130. In other embodiments, the first bypass valve BV1, the second bypass valve BV2, and the bypass B may be omitted.

In this embodiment, the filtration system 220 includes a second filter 225 for removing the purged contaminants from the fuel that has passed through the first filter 222 when the filtration system 220 is operating in the second mode (referred to herein as "backflush fuel" for simplicity). In various embodiments, different types of filters may be used with respect to the second filter 225. The second filter 225 may, for example, comprise any one or more of the filter types discussed herein with respect to the second filter 125 of the embodiment of fig. 2. In this embodiment, the filtration system 220 includes a collector 226, the collector 226 for collecting contaminants removed by the second filter 225. In some embodiments, the collector 226 may be removable from the filtration system 220, such as for cleaning the collector 226 or for replacing the collector 226 when the collector 226 is full or nearly full. For example, in some embodiments, the collector 226 comprises a sleeve that is insertable into the second filter 225 and thereafter detachable from the second filter 225. In other embodiments, the collector 226 may be omitted. In some embodiments, the second filter 225 may include a series of filters for removing different types of contaminants, such as rust, dirt, and the like, and in some embodiments, a collector (e.g., a removable sleeve) may be provided for each of the series of filters.

In some embodiments, the filtration system 120, 220 includes a collector (not shown) for collecting contaminants removed by the first filter 122, 222. In some embodiments, such a collector may be removable from the filtration system 120, 220, such as for cleaning the collector or for replacing the collector when it is full or nearly full. For example, in some embodiments, the collector comprises a sleeve that is insertable into the first filter 122, 222 and thereafter detachable from the first filter 122, 222. In other embodiments, such a collector may be omitted. In some embodiments, first filter 122, 222 may include a series of filters for removing different types of contaminants, such as rust, dirt, and the like, and in some embodiments, a collector (e.g., a removable sleeve) may be provided for each of the series of filters of first filter 122, 222.

In some embodiments, the fuel system 20 may include one or more pre-filters or strainers for removing particularly large particulate matter before the backflushed fuel passes through the second filter 225.

In this embodiment, the first filter 222 is connected to the settling tank 110 via a second filter 225. Thus, the fuel from which the second filter 225 has removed the purged contaminants (referred to herein as "filtered backflush fuel" for simplicity) may be returned to the settling tank 110. In some embodiments, a non-return valve (not shown) may be disposed between the second filter 225 and the settling tank 110 and configured such that fuel cannot flow from the settling tank 110 to the second filter 225 via the non-return valve.

In some embodiments, the second filter 225 may be omitted. For example, in some embodiments, the purged contaminants and the back-flushing fuel carrying them may be collected in a tank without being filtered. The tank may be, for example, the settling tank 110 or a different tank, although using the settling tank 110 for this purpose as discussed above may be undesirable because it may increase the contaminant to fuel ratio in the settling tank 110.

In this embodiment, the filtration system 220 includes a collection tank 250, and the first filter 222 is connected to the second filter 225 via the collection tank 250. The backflush fuel driven through the first filter 222 by the backflush pump 222a is collected in the collection tank 250. In this embodiment, the collection tank 250 is fluidly connected to the overflow tank 260 such that the backflush fuel in excess of the volume of the collection tank 250 in which the backflush fuel may be stored can flow from the collection tank 250 into the overflow tank 260 as needed. In other embodiments, the overflow tank 260 may be omitted. Indeed, in some embodiments, the collection tank 250 may also be omitted.

Further, in this embodiment, the filtration system 220 includes a second filter pump 227, such as a piston pump, and the collection tank 250 is connected to the second filter 225 via the second filter pump 227. The second filter pump 227 is operable to pump the backflush fuel from the collection tank 250 to the second filter 225 and through the second filter 225 such that the second filter 225 may remove contaminants from the backflush fuel. In some embodiments, the second filter pump 227 may be located between the collection tank 250 and the second filter 225, and not integral with the second filter 225 (as shown). In other embodiments, the second filter pump 227 may be located elsewhere. For example, in some embodiments, the second filter pump 227 is integral with the second filter 225, or located in the collection tank 250, or the second filter 225 may be connected to the settling tank 110 via the second filter pump 227. In some embodiments, second filter pump 227 may be omitted. For example, in some embodiments, when the filtration system 220 is operating in the second mode, the backflush fuel may be able to flow through the second filter 225 under the influence of gravity. However, it is preferred that the second filter pump 227 be provided to reduce the work required by the backflush pump 222a at least when the filtration system 220 is operating in the second mode.

In this embodiment, the filtration system includes a first circulation valve 228 and a second circulation valve 229 joined by a circulation path C. First circulation valve 228 is located between first filter 222 and second filter 225. More specifically, in this embodiment, first recirculation valve 228 is located between first filter 222 and collection tank 250. A second circulation valve 229 is located between the second filter 225 and the settling tank 110. First recirculation valve 228 and second recirculation valve 229 may be controlled by filtration system controller 140 to direct filtered backflush fuel pumped by second filter pump 227 back to collection tank 250 (when collection tank 250 is provided; or to second filter 225 when collection tank 250 is not provided) via recirculation path C rather than to settling tank 110. This may be desirable if the filtered backflush fuel is still contaminated after passing through the second filter 225. First circulation valve 228 and second circulation valve 229 may be controlled to circulate such for an extended period of time such that the backflush fuel is subjected to several rounds of filtration by second filter 225. In other words, the filtration system 220 may be configured to create a circuit such that the second filter pump 227 is capable of causing fuel to pass through the second filter 225 and back to the second filter pump 227 multiple times. It should be noted that the circuit including first and second recirculation valves 228, 229, recirculation path C, collection tank 250, second filter pump 227, and second filter 225 may be isolated from first filter 222 by first and second recirculation valves 228, 229 such that fuel may circulate around this circuit while first filter 222 continues to filter the fuel as it goes to supply tank 130. Thus, the circuit may be isolated from the first filter 222 such that the filtration system 220 may operate in the first mode while the second filter pump 227 causes fuel to pass through the second filter 225 and back to the second filter pump 227 multiple times. Thereafter, the first circulation valve 228 and the second circulation valve 229 may be controlled by the controller 140 to thereafter direct the filtered backflush fuel pumped by the second filter pump 227 to the settling tank 110.

In some embodiments, a non-return valve (not shown) may be disposed in circulation path C between first circulation valve 228 and second circulation valve 229, and configured such that fuel cannot flow from first filter 222 to second circulation valve 229 via circulation path C. In some embodiments, first circulation valve 228 may be omitted, and circulation path C may simply be connected to the flow path connecting first filter 222 with second filter 225. In some embodiments, first and second circulation valves 228, 229 and recirculation path C may be omitted.

It should be understood that in fig. 3, each of the fuel return valve 224, the first bypass valve BV1 and the second bypass valve BV2, and the first circulation valve 228 and the second circulation valve 229 are schematically illustrated as a single element at the junction of the two flow paths. In some embodiments, any of these valves may comprise a single valve, such as a rotary selector valve, at the associated junction. However, the skilled reader will appreciate that in other embodiments, any of these valves may alternatively be implemented by (and thus include) a plurality of valves located in the flow path and operable to determine the flow path that fuel proximate the valve is to take.

The fuel system 20 of this embodiment includes a filtration system controller 140 for controlling the filtration system 220. The controller 140 may include one or more microprocessors. In this implementation, the controller 140 is communicatively connected to and for controlling each of the following: the fuel delivery pump 105, the fuel pump 221, the first and second bypass valves BV1, BV2, the recoil pump 222a, the fuel return valve 224, the second filter pump 227, and the recirculation valves 228, 229, as depicted by dashed lines in fig. 3. In some embodiments, some of these elements may be controlled by an entity other than controller 140. Of course, in embodiments where one or more of these elements are omitted, the controller 140 will not be communicatively connected to and used to control such omitted elements.

In this embodiment, the filtration system 220 includes a pressure sensor 223, the pressure sensor 223 being configured to detect a fuel pressure at a location between the first filter 222 and the supply tank 130, the fuel pressure being a parameter of the fuel that has flowed through the first filter 222. The location in this embodiment is between the backflush pump 222a and the second pump fuel return valve 224, but in other embodiments the location may be elsewhere, such as between the fuel return valve 224 and the supply tank 130. In this embodiment, the pressure sensor 223 is communicatively connected to the controller 140 and is configured to send a signal to the controller 140 indicative of the fuel pressure at the location. When it is determined that the fuel pressure at the location is less than the predetermined threshold fuel pressure, the controller 140 is configured to cause the filtration system 220 to operate in the second mode. As described above with respect to the embodiment of fig. 2, this determination may be made by the controller 140, or may be made at a location other than the controller 140, such as at the pressure sensor 223.

In other embodiments, additional or alternative sensors may be provided in addition to the pressure sensors 123, 223 to detect the condition of the first filter 122, 222 or a parameter of the fuel at a location between the first filter 122, 222 and the supply tank 130. For example, a mass flow sensor may be used to obtain information regarding the amount of fuel flow between the first filter 122, 222 and the supply tank 130. Other sensors may be used, such as a viscosity sensor, a density sensor, or any sensor for measuring a parameter of the fuel. A change in a parameter of the fuel at this location may indicate that the first filter 122, 222 requires backflushing. Any such employed sensor may be communicatively connected to the controller 140 and configured to send a signal to the controller 140 based on the detected condition or parameter. The controller 140 may be configured to cause the filtration system 120, 220 to operate in the second mode based on a signal (such as a characteristic or content of the signal, or receipt of the signal). In some other embodiments, no such sensor is present, and the controller 140 instead receives a signal from a timer (not shown) indicating that a certain period of time has elapsed since a previous backflush of the first filter 122, 222. The controller 140 may be configured to then cause the filtration system 120, 220 to operate in the second mode based on having received such a signal.

Although only one filtration system 120, 220 is shown in the fuel systems 10, 20 of fig. 2 and 3, in other embodiments, the fuel systems 10, 20 may include a plurality of such filtration systems 120, 220 arranged in parallel, each filtration system 120, 220 including a first filter 122, 222 through which fuel flowing from the settling tank 110 to the feed tank 130 passes. In some embodiments, the multiple filtration systems 120, 220 may be operable independently of one another. Thus, in some embodiments, one of the filtration systems 120, 220 may be inactive or operating in one of the first and second modes while the other of the filtration systems 120, 220 is operating in one of the first and second modes. In some embodiments, the filtration system controller 140 of the fuel system 10, 20 is used to control each of the plurality of filtration systems 120, 220. In other embodiments, each of the plurality of filtration systems 120, 220 may be controlled by a respective one of the plurality of controllers 140.

An exemplary method of operating a filtration system for a fuel system of an engine of a marine vessel will now be described.

Fig. 4 shows a flow chart illustrating an example of a method of operating a filtration system for a fuel system of an engine of a marine vessel according to an embodiment of the invention. The method comprises the following steps: the filtration system 120, 220 (such as the filtration system 120 of fig. 2 or the filtration system 220 of fig. 3) is caused 401 to operate in a first mode whereby fuel flows from the settling tank 110 of the fuel system 10, 20 to the feed tank 130 of the fuel system 10, 20 via a first filter 122, 222 of the filtration system 120, 220, the first filter 122, 222 being used to remove contaminants from the fuel. The method further comprises the following steps: the filtration system 120, 220 is caused 402 to operate in a second mode whereby fuel flows from the supply tank 130 through the first filter 122, 222 to clean contaminants from the first filter 122, 222.

A further method of operating a filtration system for a fuel system of an engine of a marine vessel according to a respective embodiment of the invention will now be described with reference to fig. 5. The methods will be described with reference to the filtration systems 120, 220 of fig. 2 and 3, but it will be understood that in still further embodiments, the filtration systems 120, 220 used in any of the methods may be any of the variations of the filtration systems 120, 220 of fig. 2 and 3 described herein.

The method comprises the following steps: the filter system 120, 220 is caused 501 to operate in a first mode whereby fuel flows from the settling tank 110 of the fuel system 10, 20 to the supply tank 130 of the fuel system 10, 20 via a first filter 122, 222 of the filter system 120, 220, the first filter 122, 222 being used to remove contaminants from the fuel.

In some embodiments, causing 501 the filtration system to operate in the first mode comprises: causing 502 the pump to operate to pump fuel from the settling tank 110 to the feed tank 130 via the first filter 122, 222. The pump may be the second pump 124 shown in fig. 2, the third pump discussed above, the fuel pump 221 shown in fig. 3, or another type of pump. The pump may take any suitable form. In other embodiments, such operation of the pump is rendered 501 to be excluded. For example, as also discussed above, in some embodiments, fuel may be able to flow from the settling tank 110 through the first filter 122, 222 and to the feed tank 130 under the influence of gravity.

In some embodiments, the method comprises: a signal indicative of a condition of the first filter 122, 222 or a parameter of the fuel at a location between the first filter 122, 222 and the supply tank 130 is received 503. This signal may be provided according to any of the schemes discussed herein. Thus, in some embodiments, the method comprises: the signal is received while the filtration system 120, 220 is operating in the first mode (as indicated by the dashed line in fig. 5). In some embodiments, the method comprises: the signal is received 503 after the filtration system 120, 220 has ceased operating in the first mode. For example, conditions or parameters may be monitored and reported (e.g., to the controller 140) even when fuel is not being introduced into the supply tank 130.

In some embodiments, the method comprises: when it is determined that the fuel pressure is less than the predetermined threshold fuel pressure, the valve 121 is caused 504 to close to prevent or impede fuel flow from the first filter 122, 222 toward the settling tank 110. In other embodiments, this operation may be omitted. For example, as discussed above, in some embodiments, the valve 121 may be a non-return valve configured such that fuel cannot flow from the first filter 122 to the settling tank 110 via the valve 121, and thus the valve 121 may not need to be actively closed. In some embodiments, the fuel pump 221 may instead be configured to prevent or impede fuel flow from the first filter 222 toward the settling tank 110.

The method further comprises the following steps: the filtration system 120, 220 is caused 505 to operate in a second mode whereby fuel flows from the supply tank 130 through the first filter 122, 222 to purge contaminants from the first filter 122, 222.

As discussed above, in some embodiments, causing 505 the filtration system 120, 220 to operate in the second mode comprises: causing 506 the pump to operate to pump fuel from the supply tank 130 through the first filter 122, 222 to clean contaminants from the first filter 122, 222. The pump may be the second pump 124 shown in fig. 2, the backflush pump 222a shown in fig. 3, or another type of pump. The pump may take any suitable form. In other embodiments, 505 is rendered to not include such operation of a pump. For example, as also discussed above, in some embodiments, fuel may be able to flow from the supply tank 130 through the first filter 122, 222 under the influence of gravity.

In some embodiments, causing 505 the filtration system 120 to operate in the second mode comprises: the contaminants (and the contaminant-laden backflush fuel) that have been purged from the first filter 122, 222 when the filtration system 120 is operating in the second mode are caused 507 to pass through a second filter 125, 225 of the filtration system, the second filter 125, 225 being used to remove the purged contaminants from the fuel. This may be according to any of the schemes discussed herein. Thus, in some embodiments, causing 505 the filtration system 120, 220 to operate in the second mode comprises: the fuel from which the second filter 125, 225 has removed the purged contaminants is caused 508 to return to the settling tank 110. However, in some embodiments, this process (and second filter 125, 225) may also be omitted, as also discussed herein.

In some embodiments, the method returns to 501 after completing 505 execution, such that the filtration system 120, 220 begins operating in the first mode again.

In some embodiments, the method may be performed by a filtration system controller (such as controller 140 shown in fig. 2 or controller shown in fig. 3). Accordingly, there is also provided a non-transitory computer readable storage medium storing instructions that, when executed by a processor of a filtration system controller, cause the processor to implement the method. The processor may be included in the controller 140 of fig. 2, the controller 140 of fig. 3, or elsewhere.

Accordingly, the skilled reader will appreciate that embodiments of the present invention provide a fuel system for removing solid contaminants from fuel while addressing the aforementioned problems in conventional and alternative systems.

In other embodiments, two or more of the above embodiments may be combined. In other embodiments, features from one embodiment may be combined with features of one or more other embodiments.

Embodiments of the present invention have been discussed with specific reference to the illustrated examples. It should be understood, however, that variations and modifications to the described examples may be made within the scope of the present invention.