Fuel injection system for marine engine

Information

  • Patent Grant
  • 6722324
  • Patent Number
    6,722,324
  • Date Filed
    Tuesday, December 10, 2002
    22 years ago
  • Date Issued
    Tuesday, April 20, 2004
    20 years ago
Abstract
A fuel injection system for a marine engine includes an improved construction that, by the introduction of lubricant into the fuel, inhibits components of the system from rusting in the event that water, particularly salt water, is mixed with the fuel. The engine includes a lubricant delivery system to deliver lubricant to at least one portion of the engine that needs lubrication. A premix lubricant pump is provided for supplying lubricant with the fuel injection device from the lubricant delivery system so as to mix the part of the lubricant to the fuel. An ECU controls an amount of the part of the lubricant so as to be in a proper and extremely small range.
Description




PRIORITY INFORMATION




This application is based on and claims priority to Japanese Patent Applications No. 11-162559, filed Jun. 9, 1999, No. 11-165708, filed Jun. 11, 1999 and No. 11-173957, filed Jun. 21, 1999, the entire contents of which are hereby expressly incorporated by reference.




BACKGROUND OF THE INVENTION




1. Field of the Invention




This invention relates to a fuel injection system for a marine engine, and more particularly to an improved fuel injection system with corrosion protection.




2. Description of Related Art




In all fields of engine design, there is an increasing emphasis on obtaining more effective emission control, better fuel economy and, at the same time, continuing to increase power output. This trend has resulted in the substitution of fuel injection systems for carburetors as the engine charge former.




Fuel injection systems typically inject fuel into the air intake manifold. In addition, direct injection systems are being considered to obtain still better engine performance. The direct fuel injection systems inject fuel directly into the combustion chamber and potentially have significant advantages over the indirect fuel injection systems including improved emission control.




Marine engines such as for outboard motors can employ direct or indirect fuel injection systems. Fuel for such systems typically is stored fuel tanks that are usually placed in the hulls of associated watercrafts. The watercraft of course is operated in water and hull often contains some amount of water at the location of the fuel tank. The user or operator thus fills the tank with fuel under the conditions that present the possibility of water entering the tank and mixing with the fuel.




Water within the fuel injection system tends to damage the system, especially if salt water is introduced into the system. Fuel injection systems are typically provided with fuel injectors, fuel pumps and regulators, all including elements made of iron that can easily rust in the presence of salt water. The damaging effects of salt water in the fuel supply is particularly detrimental to the fuel injectors. Fuel injectors are extremely precise and delicate, and do not function properly once rusted.




SUMMARY OF THE INVENTION




An aspect of the present invention involves the recognition that the introduction of a lubricant into the fuel reduces corrosion of the internal components within the fuel system, especially the internal components of the fuel injectors. If the fuel injected into the combustion chambers contains too much lubricant, however, lubricant is not only wasted, but it also produces white smoke in the exhaust gases and fouls the spark plugs of the engine, i.e., the spark plugs fail to spark due to deposits, which the lubricant likely produces, on their electrodes.




The present fuel injection system thus inhibits corrosion of its components, in the event that water, particularly salt water, is inadvertently mixed with fuel, by introducing an amount of lubricant into the fuel delivered to the engine through the fuel injection system. The amount of lubricant introduced into the fuel, however, is metered so as not to waste lubricant and to inhibit the presence of white smoke in the engine's exhaust and the fouling of the engine's spark plugs.




In one preferred application, a fuel injected, internal combustion engine is provided for a marine propulsion device. The engine comprises a combustion chamber. A fuel delivery system is arranged to deliver fuel for combustion in the combustion chamber. The fuel delivery system includes a fuel injector spraying the fuel. A lubricant delivery system is arranged to deliver lubricant to at least one portion of the engine that needs lubrication. An intermediate lubricant supply system operates between the lubricant delivery system and the fuel delivery system to supply lubricant from the lubricant delivery system to the fuel delivery system where the lubricant is mixed with the fuel. A control device is arranged to control an amount of lubricant supplied to the fuel delivery system through the intermediate lubricant supply system. In a preferred mode, the amount of lubricant delivered to the engine through the lubricant delivery system is greater than the amount of lubricant supplied to the fuel delivery system through the intermediate lubricant supply system.




In accordance with another aspect of the present invention, a method is provided for operating an engine. The engine has a combustion chamber, a fuel delivery system, a lubricant delivery system and a control device. The fuel delivery system includes a fuel injector. The method comprises delivering fuel to the fuel injector through the fuel delivery system and spraying the fuel by the fuel injector into the combustion chamber. Lubricant is delivered to at least one portion of the engine that needs lubrication through the lubricant delivery system. Lubricant also is supplied to the fuel delivery system to mix the lubricant with the fuel. The amount of lubricant supplied is controlled depending upon at least one operating parameter indicative of engine running condition.




Further aspects, features and advantages of this invention will become apparent from the detailed description of the preferred embodiments which follow.











BRIEF DESCRIPTION OF THE DRAWINGS




These and other features of this invention will now be described with reference to the drawings of preferred embodiments which are intended to illustrate and not to limit the invention. The drawings contain the following figures.





FIG. 1

is a multi-part view showing: in the lower right-hand portion, an outboard motor that employs a direct fuel injection system which relates to the present invention; in the upper view, a partially schematic cross-sectional view of the engine of the outboard motor with its air induction and fuel injection systems shown in part schematically; and in the lower left-hand portion, a rear elevational view of the outboard motor with portions removed and other portions broken away and shown in cross section as taken along the line


1





1


in the upper view so as to more clearly illustrate the construction of the engine, with the fuel injection system shown schematically in part. An ECU for the motor links the three views together.





FIG. 2

is a top plan view showing a power head of the outboard motor that incorporates the engine. The engine is illustrated in solid, and a protective cowling of the power head, which encloses the engine, is illustrated in phantom.





FIG. 3

is a partial elevational side view of the engine looking in the direction of the Arrow


3


of FIG.


2


.





FIG. 4

is a cross-sectional view of a fuel injector employed for the direct fuel injection system.





FIG. 5

is an enlarged view of a portion of the fuel injector attached to the engine. Part of the view is shown in section.





FIG. 6

is a cross-sectional view of a fuel filter including a water sensing system of the fuel injection system.





FIG. 7

is a cross-sectional view of a vapor separator of the fuel injection system.





FIG. 8

is a side view of a plunger-type, premix lubricant pump.





FIG. 9

is another view of the lubricant pump looking in the direction of the Arrow


9


of FIG.


8


.





FIG. 10

is a cross-sectional view of the lubricant pump taken along the line


10





10


of FIG.


9


.





FIG. 11

is a graph showing a control map used to determine an injection amount of fuel based upon an engine speed versus an engine load.





FIG. 12

is a graph showing a control map used to determine an amount of lubricant based upon the engine speed versus the engine load in accordance with a first control method.





FIG. 13

is a graph showing a control map used to determine a pump speed of the lubricant pump versus a lubricant temperature in accordance with a second control method.





FIG. 14

is a graphical representation showing a control strategy in accordance with a third control method. The upper graph (A) illustrates an injection amount decrease rate versus time. The middle graph (B) illustrates an air/fuel ratio adjustment (increase) coefficient “K” versus time. The lower graph (C) illustrates a lubricant adjustment coefficient “Q” versus time.





FIG. 15

is a flowchart showing a control routine based upon the control strategy represented by the graphs of FIG.


14


.





FIG. 16

is a flowchart showing another control routine to practice a control strategy in accordance with a fourth control method.





FIG. 17

is a graph showing a control map used to determine a coefficient of viscosity of the lubricant versus a lubricant temperature.





FIG. 18

is a graph showing temperature of a tip portion of the fuel injector as functions of engine speed and engine load.





FIG. 19

is a graph showing control map used to determine a target amount of the lubricant based upon engine speed and engine load.





FIG. 20

are exemplifying timing diagrams for controlling an electromagnetic-type lubricant pump. FIG.


20


(A) illustrates pulses of a control signal under a certain duty ratio. FIG.


20


(B) illustrates that some of the pulses are omitted from the control signal. FIG.


20


(C) illustrates that the duty ratio between pulses are reduced.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION




An exemplifying environment in which the present invention can be practiced will now be described with reference to

FIGS. 1

to


7


. The present fuel injection system has particular utility in the context of a marine engine, and thus, is described in the context of an outboard motor. The fuel injection system, however, can be used with other types of internal combustion engines employed in an environment in which the possibility of water entering the fuel supply system exists, e.g., with an engine driving a dredging pump.




With initial reference to

FIG. 1

, and in particular to the lower-right hand view of

FIG. 1

, an outboard motor


30


is depicted from the side. The entire outboard motor


30


is not depicted in that a swivel bracket and a clamping bracket, which are typically associated with a driveshaft housing


32


, are not illustrated. These components are well known in the art and the specific method by which the outboard motor


30


is mounted to the transom of an associated watercraft is not believed necessary to permit those skilled in the art to understand or practice the invention.




The outboard motor


30


includes a power head


34


that is positioned above the driveshaft housing


32


. The power head


34


comprises a protective cowling assembly and an internal combustion engine


36


. This engine


36


is shown in more detail in the remaining two views of this figure and in

FIGS. 2 and 3

, and will be described shortly by reference thereto.




A protective cowling assembly includes a main cowling member


38


and a lower tray portion


40


. Both the main cowling member


38


and the lower cowling portion


40


define a closed cavity in which the engine


36


is housed. The main cowling member


38


is detachably affixed to the lower cowling portion


40


so that the user or service person can access the engine


36


for maintenance service or for other purposes. The main cowling member


38


has air intake openings at its rear and upper end surface. Air thus can be introduced into the cavity. The lower cowling portion


40


encloses an exhaust guide member or upper portion


42


of the driveshaft housing


32


. The engine


36


is affixed to the exhaust guide member


42


so as to be supported by the driveshaft housing


32


.




A lower unit


44


is positioned beneath the driveshaft housing


32


. A propeller


46


, which forms the propulsion device for the associated watercraft, is journaled in the lower unit


44


.




As is typical with the outboard motor practice, the engine


36


is enclosed in the power head


34


and its crankshaft


48


(see the upper view) rotates about a vertically extending axis. This facilitates the connection of the crankshaft


48


to a driveshaft (not shown) which depends into the driveshaft housing


32


. The driveshaft drives the propeller


46


through a conventional forward, neutral, reverse transmission contained in the lower unit


44


.




The details of the construction of the outboard motor and the components, which are not illustrated, may be considered to be conventional or of any type known to those wishing to utilize the invention disclosed herein. Those skilled in the art can readily refer to any known constructions with which to practice the invention.




The engine


36


of the illustrated embodiment is of the V6 type and operates on a two-stroke, crankcase compression principle. Although the invention is described in conjunction with an engine having this cylinder number and cylinder configuration, it will be readily apparent that the invention can be utilized with engines having other cylinder numbers and other cylinder configurations. Also, although the engine


36


will be described as operating on a two-stroke principle, it will be apparent to those skilled in the art that certain facets of the invention can be employed in conjunction with four-stroke engines.




The engine


36


comprises a cylinder body


50


that forms a pair of cylinder banks


52


. Each of these cylinder banks


52


is formed with three vertically spaced, horizontally extending cylinder bores


54


. Pistons


56


reciprocate in these cylinder bores


54


. The pistons


56


are, in turn, connected to the small ends of connecting rods


58


. The big ends of these connecting rods


58


are journaled on the throws of the crankshaft


48


in a manner that is well known in this art.




The crankshaft


48


is journaled in a suitable manner for rotation within a crankcase chamber


60


that is formed in part by a crankcase member


62


that is affixed to the cylinder body


50


in a suitable manner. As is typical with the two-stroke engines, the portion of the crankcase chamber


60


associated with each of the cylinder bores


54


are sealed from each other. This type of construction is well known in the art.




Cylinder head assemblies


66


are affixed to the ends of the respective cylinder banks


52


that are spaced from the crankcase chamber


60


. Each cylinder head assembly


66


comprises a cylinder head member


68


that defines a plurality of recesses in its inner face. Each of these recesses cooperates with the respective cylinder bore


54


and the head of the piston


56


to define the combustion chambers of the engine


36


. Cylinder head cover members


72


complete the cylinder head assemblies


66


. The cylinder head members


68


and cylinder head cover members


72


are affixed to each other and to the respective cylinder banks


52


in a suitable known manner.




The engine


36


includes an air induction system


80


. The air induction system


80


delivers an air charge to the sections of the crankcase chamber


60


associated with each of the cylinder bores


54


. This communication is via an intake port


82


that is formed in the crankcase member


62


and registers with the respective crankcase chamber section.




The induction system


80


includes an air silencing and inlet device


84


. This inlet device


84


is contained within the forward end of the main protective cowling


38


and has a rearwardly facing air inlet opening


86


. The air introduced into the closed cavity of the protective cowling assembly is pulled into the air inlet device


84


through the air inlet opening


86


. The air inlet device


80


delivers the air to a plurality of throttle bodies


88


, each of which has a throttle valve


90


provided therein. These throttle valves


90


are journaled on throttle valve shafts which are linked together for simultaneous opening and closing of the throttle valves


90


in a manner that is well known in this art.




As is typical in the two-stroke engine practice, the intake ports


82


have provided in them reed-type check valves


94


. These check valves


94


permit the air to flow into the sections of the crankcase chamber


60


when the pistons


56


are moving upwardly in their respective cylinder bores


54


. However, as the pistons


56


move downwardly, the charge will be compressed in the sections of the crankcase chamber


60


. At that time, the reed type-check valves


94


will close so as to permit the charge to be compressed.




In the illustrated embodiment, an engine lubrication system


96


is provided. The engine lubrication system


96


includes a lubrication pump


98


that deliver lubricant to the respective throttle bodies


88


so that the lubricant can reach to certain portions of the engine


36


which need lubrication along with the introduced air. The lubrication pump


98


, as configured as seen in

FIG. 3

, is mounted on the cylinder body


50


. The lubrication pump


98


has an adjustment lever


99


that is linked with the shafts of the throttle valves


90


so that an amount of the lubricant is adjusted in response to various states of the engine operations. The engine portions that need lubrication are, for example, connecting portions of the connecting rods


58


with the pistons


56


and also with the crankshaft


48


. In the illustrated embodiment, the lubrication pump


98


is driven by an electric motor. Otherwise, it can be driven by the crankshaft


48


or the like.




In order to supply the lubricant to the lubrication pump


98


, a main lubricant tank


102


and a sub-tank


104


are provided in the lubrication system


96


. The main tank


102


is mounted on one bank


52


of the engine


36


where the lubrication pump


98


is disposed, while the sub-tank


104


is placed in the hull of the associated watercraft. The main tank


102


is affixed to the cylinder body


50


, part to the top surface thereof and other part to the side surface thereof. The sub-tank


104


is coupled to the main tank


102


through a conduit


108


and the main tank


102


is coupled to the lubrication pump


98


through a supply conduit


110


. The lubrication pump


98


, in turn, is coupled to the respective throttle bodies


88


through six delivery conduits


112


.




Some forms of direct lubrication can be additionally employed for delivering lubricant directly to certain components or systems of the engine


36


. In the illustrated embodiment, a fuel injection system or fuel supply system


120


(see the upper and lower left-hand views of

FIG. 1

) that will be described later has special lubrication units. The lubrication for the fuel injection system


120


will be described below in great detail.




With reference again to the air induction system


80


, the air charge that is compressed in the sections of the crankcase chamber


60


is then transferred to the combustion chambers through a scavenging system. This scavenging system preferably is of the Schnurle type and includes a pair of main scavenge passages for each cylinder bore


54


that are positioned on diametrically opposite sides. These main scavenge passages terminate in main scavenge ports so as to direct scavenge air flows into the combustion chamber.




In addition, an auxiliary scavenging passage is formed between the main scavenge passages and terminates in an auxiliary scavenging port which also provides scavenging air flow. Thus, during the scavenging stroke, the intake charge will be transferred to the combustion chambers for further compression as the pistons


56


move upwardly from their bottom dead center position so as to close the scavenge ports and further compress the charge.




The engine


36


also includes a firing or ignition system. Spark plugs


124


are affixed to plug bosses formed at the cylinder head members


68


. Their respective spark gaps are exposed to the combustion chambers. The spark plugs


124


are fired under control of an ECU (Engine Control Unit)


116


, shown schematically in

FIG. 1

, through a control signal line


125


. The ECU


116


also controls other systems of the engine


36


as will be described later. Incidentally, the foregoing lubrication pump


98


can be controlled by the ECU


116


instead linked with the throttle valves


90


.




The ECU


98


receives certain signals for controlling the time of firing of the spark plugs


124


in accordance with any desired control strategy. The spark plugs


124


thus fire air/fuel charges that are formed in the illustrated embodiment from fuel sprayed directly into the combustion chambers by fuel injectors


126


and the air delivered to the combustion chambers through the scavenge system.




In the illustrated embodiment, the fuel injectors


126


are the inner-valve types and are electrically operated also under control of the ECU


116


.

FIG. 4

illustrates an exemplary fuel injector


126


of this type.




The fuel injector


126


includes an injector body


130


defined by several members. The injector body


130


has a through-hollow


132


. An injection nozzle


134


is fitted into the hollow


132


at one end of the body


130


. A fuel filter


136


is affixed to the other end of the body


130


. The injection nozzle


134


has also a through-hole


138


that is connected to the hollow


132


of the injector body


130


. The through-hollow


132


of the injector body


130


and the through-hole


138


of the injection nozzle


134


are filled with pressurized fuel when the engine is running.




A swirl member


139


is fitted into the through-hole


138


that has a swirl passage to give a swirling movement to the fuel that will be injected. A slide rod or plunger


140


is slideably supported in both the through-hollow


132


of the body


130


and the through-hole


138


of the nozzle


134


. The slide rod


140


has a needle valve member


142


at its end portion within the injection nozzle


134


. The needle valve member


142


is seated on a valve seat member


144


that is affixed to the end portion of the nozzle


134


. The valve seat member


144


has an injection opening


146


that is normally closed by the needle valve member


142


.




The other end portion of the slide rod


140


is urged by a coil spring


148


toward the injection opening


146


so that the needle valve member


142


closes the opening


146


. A solenoid


150


is embedded in the injector body


140


around this end portion of the slide rod


140


. Electric wires


152


couples the solenoid coil


148


with an electric power source such as a battery through a switching element. A control signal


154


(see

FIG. 1

) that comes from the ECU


116


can switch this connection. When the signal


154


switches to close the connection, the solenoid coil


148


pulls the slide rod


140


to open the injection opening


142


. In the illustrated embodiment, the slide rod


140


has a stroke length of sixty (60) microns.




The fuel injectors


126


are mounted on the cylinder head members


68


. As seen in

FIG. 5

, the injection nozzle


134


of each injector


126


is fitted into a through-hole


158


formed through the cylinder head member


68


so as to expose the injection opening


146


toward the combustion chamber, which is designated by the reference numeral


160


in this figure. The injector bodies


130


are pressed toward outer surfaces of the cylinder head members


68


by fuel rails


164


, which will be described shortly. A couple of ring-shaped gaskets


166


partially covered with stainless coat members


168


are interposed between each injector body


130


and the cylinder head members


68


.




As noted above, each needle valve


142


is normally seated on the valve seat member


144


to close the injection opening


146


by the biasing force of the spring


148


. When a control signal is given from the ECU


116


through the control signal line


154


, the solenoid


150


pulls the slide rod


140


so as to move the needle valve


142


from the valve seat


144


. The pressurized fuel is thus injected or spayed into the combustion chamber


160


.




Generally, the pressurized fuel is supplied by the fuel supply system


120


and its pressure is strictly regulated to be a constant value all the time. The ECU


116


controls duration of each injection so as to give a proper amount of the fuel in response to various states of the engine operations. That is, air/fuel ratios of the respective cylinders are controlled separately from each other.




The fuel supply system


120


comprises a fuel supply tank


172


that is provided in the hull of the watercraft. The fuel is drawn from this tank


172


through a conduit


174


by a first low pressure pump


176


and a plurality of second low pressure pumps


178


. The first low pressure pump


176


is a manually operated pump, while the second low pressure pumps


178


are diaphragm type pumps operated by pulsating variations in pressure that occur in the sections of the crankcase chamber


60


. As seen in

FIG. 3

, actually two low pressure pumps


178


are provided in parallel location with each other in this embodiment and they are mounted on the crankcase member


62


. A quick disconnect coupling is provided in the conduit


174


so as to detachably connect the watercraft side of the conduit


174


with the outboard side thereof.




As seen in

FIGS. 1

to


3


, a fuel filter


180


is positioned in the conduit


174


. The fuel filter


180


is mounted on the cylinder body


50


. The fuel filter


180


is disposed on the same side where the lubrication pump


98


is mounted, and generally between the lubrication pump


98


and the main lubricant tank


102


. Preferably, the fuel filter


180


is attached to a stay


182


in an appropriate manner. The stay


182


is then affixed to the cylinder body


50


by bolts


184


via ring-shaped elastic members


186


made of rubber material. The fuel filter


180


is thus well isolated from vibrations of the engine


36


.





FIG. 6

illustrates a detailed construction of the fuel filter


180


. The fuel filter


180


comprises a container


190


, a cap


192


having an inlet port


194


and an outlet port


196


, and a coupling member


198


that couples together the container


190


and the cap


192


. The coupling member


198


supports a flange portion of the container


190


disposed atop thereof and then affixes itself to the outer surface of the cap


192


by a screw connection.




The container


190


has an inner projection


200


at its bottom that projects inwardly and upwardly. The projection


200


is formed with a through-hole. A strut


202


is fitted into the through-hole so as to stand up within the container


190


. The strut


202


has a rack


204


atop thereof. The rack


204


supports a filter element


205


. The rack


204


, in turn, is supported by a coil spring


206


that is mounted on an inner flange


207


via a washer


208


. The inner flange


207


is formed at an inner surface of the container


190


. Meanwhile, the top of the filter element


205


is confined in a frame member


209


that extends from the cap


192


. The filter element


205


is thus caught between the rack


204


and the frame member


209


. The inlet


194


and the outlet


196


are coupled together only through the filter element


205


.




Water may accumulate in the container


190


because the fuel for this kind of marine engine is replenished in the hull or open deck under the condition that water can enter the fuel supply tank


172


. In the illustrated embodiment, the fuel filter


180


thus includes a water sensing system


212


. The water sensing system


212


comprises a float


214


, a reed switch


216


and magnets embedded in the float


214


around the strut


202


. The float


214


is made of plastic material that has a specific gravity greater than that of the fuel, i.e., gasoline, in the embodiment, but less than that of water. The float


214


can move up and down along the strut


202


through a hole of the washer


208


. The reed switch


216


is positioned at a certain height in the strut


202


and is connected to the ECU


116


through a signal line


218


.




The fuel from the first low pressure pump


176


is introduced into the container


190


through the inlet


194


and filtered by the filter element


205


so as to remove foreign substances. The fuel then goes to the second low pressure pumps


178


through the outlet


196


. Since the specific gravity of water is greater than that of gasoline, the water accumulates below the fuel, if it is contained in the supplied fuel. The float


214


, which has the specific gravity less than water, and will generally float on the surface of the water. Under the circumstances, if the water accumulates to a predetermined level, i.e., to the height where the reed switch


216


is positioned, the magnets approach the reed switch


216


so as to close the switch


216


and send a signal to the ECU


116


through the signal line


218


.




The ECU


116


will control lubrication of the fuel injection system


120


by using the water-sensing signal, as will be described later. The water-sensing signal


218


also can be used to indicate that a relatively great volume of water has accumulated in the container


190


via an indicator (e.g., warning lap) or alarm. When recognizing the indication or hearing the alarm, the user stops engine operation and empties the water from the container


190


by detaching the container


190


from the cap member


198


.




The coil spring


206


primarily supports the filter element


205


as noted above. It is, however, also useful to keep the water surface calm because the spring


206


slows down the fuel that flows into the container


190


. Of the spring


206


were not provided, the fuel flow would chum the water.




With the continued reference to

FIG. 1

, the fuel is supplied to a vapor separator


224


from the second low pressure pump


178


through a fuel line


225


. The vapor separator


224


is, as is well known in the art, a fuel reservoir that can separate vapor from liquid so as to prevent vapor lock from occurring in the fuel injection system


120


. As seen in

FIGS. 2 and 3

, the vapor separator


224


is mounted on the crankcase member


62


and on the same side of the engine


36


where the lubricant tank


102


is disposed. The vapor separator


224


has three stays


226


uniformly formed with the body of the vapor separator


224


. The stays


226


are affixed to the crankcase member


62


by bolts


228


via elastic members


230


preferably made of rubber material.





FIG. 7

illustrates a detailed construction of the vapor separator


224


. The body of the vapor separator


224


is generally defined by two pieces


232


,


234


. The bottom piece


232


forms a cavity or fuel reservoir portion


236


, while the top piece


234


forms a lid to the bottom piece


232


and also has a fuel inlet port


238


and a fuel outlet port


240


.




A float


244


is provided in the cavity


236


. The float


244


has a lever portion


246


on which a needle valve


248


is pivotally affixed. The needle valve


248


opens and closes the inlet port


238


with the floating movement of the float


244


. That is, when an amount of the fuel in the cavity


236


decreases, the float


244


falls and the needle valve


248


opens the inlet port


238


to allow the fuel to flow into the cavity


236


. Conversely, when the amount of the fuel increases, the float


244


rises and the needle valve


248


closes the inlet port


238


to prevent the fuel from entering the cavity


236


.




A high pressure electric pump


251


is also provided in the cavity


236


and is disposed next to the float


244


. The electric pump


251


comprises a housing


252


, an electric motor section, a pump section and a common shaft section


253


. Both the motor section and pump section is generally formed around the shaft section


253


within the housing


252


. Actually, the motor section forms a conventional DC motor.




The motor section includes coils


254


wound around core members, a brush


256


and terminals


258


. Couplers


260


, which are coupled with the terminals


258


, connect the terminals


258


to the battery so as to supply electric power to the motor section, and to the ECU


116


through a control line


262


(see

FIG. 1

) so as to drive the motor section under control of the ECU


116


. Since the internal cavity of the housing


252


is filled with the fuel, all the elements of the motor section including the coils


252


and brush


256


are soaked in the fuel. This construction is advantageous because the fuel can efficiently remove heat from the elements.




The pump section includes a pump impeller


264


. An internal cavity of the housing


252


communicates with the cavity


236


via an internal filter


266


and also with the outlet port


240


through passages that are not shown in the figure. The motor section rotates the shaft section


253


so that the impeller


264


introduces the fuel in the cavity


236


into the housing


251


and pressurizes it to a certain level.




Through a fuel supply line


268


, the pressurized fuel is delivered to a high pressure fuel pump unit


272


that can pressurize the fuel to higher level. The high pressure fuel pump unit


272


is illustrated schematically in FIG.


1


. In a preferred embodiment, the electric fuel pump


251


develops a pressure, for example, 3 to 10 kg/cm


2


. The high pressure fuel pump unit


272


preferably develops a pressure, for example, 50 to 100 kg/cm


2


or more. A low pressure regulator


274


is positioned in the line


268


and at the vapor separator


224


and limits the pressure that is delivered to the high pressure fuel pump unit


272


by dumping the fuel back to the vapor separator


224


. As seen in

FIG. 7

, actually the pressure regulator


274


communicates with the cavity


236


through an inner conduit


276


. These pressure valves merely exemplify one suitable mode of operation, and the engine can be operated at other fuel pressures.




As best seen in

FIG. 2

, the high pressure fuel pump


272


is mounted on a pump drive unit


278


that drives the fuel pump


272


. The pump drive unit


278


, in turn, is mounted on the cylinder body


50


in a proper manner. The pump drive unit


278


is further affixed to the cylinder block


50


so as to overhang between the two banks


52


of the V arrangement. A pulley


280


is affixed to a pump driveshaft


282


of the pump drive unit


278


. The pulley


282


is driven by a drive pulley


284


affixed to the crankshaft


46


through a drive belt


286


. A belt tensioner


288


is provided for tensioning the belt


286


.




The pump drive unit


278


includes a cam disc disposed on the pump driveshaft


282


and engaged with plungers of the high pressure fuel pump unit


272


. The high pressure fuel pump unit


272


thus pressurizes the fuel with the plungers when the cam disc pushes them with the rotation of the pump driveshaft


282


of the pump drive unit


278


.




The high pressure fuel pump unit


272


has fuel outlet ports


292


that are coupled to the fuel rails


164


through flexible conduits


294


. The fuel rails


164


are made of rigid metal material and are affixed to the respective cylinder head assemblies


66


so as to extend generally vertically. The fuel injectors


126


are attached to the fuel rails


164


so as to extend toward the respective cylinders. The fuel rails


164


define not only such mounting members of the fuel injectors


126


but also fuel passages that communicate with the flexible conduits


294


and also the through-hollows


132


of the fuel injectors


126


. Accordingly, the pressurized fuel is supplied to the respective fuel injectors


126


.




With reference again to

FIG. 1

, the pressure of the fuel supplied by the high pressure fuel pump unit


272


is regulated to a fixed or constant value by a high pressure regulator


296


that dumps fuel back to the vapor separator


224


through a pressure relief line


298


in which a fuel heat exchanger or cooler


300


is provided. As described above, it is important to keep the fuel under the constant pressure because fuel injection amounts are determined by changes of duration of injection under this constant fuel pressure.




Each of the fuel injectors


126


sprays fuel directly into the combustion chamber from its injection nozzle


134


. The sprayed fuel or fuel charge expands into the combustion chamber


72


. The fuel charge is fired by the spark plugs


124


. The injection timing and duration, and the firing timing are all controlled by the ECU


116


.




Once the charge burns and expands, the pistons


56


will be driven away from the cylinder head in the cylinder bores


54


until the pistons


56


reach the bottom dead center position. At this time, exhaust ports will be uncovered so as to open the communication with an exhaust passage


304


formed in the cylinder body


50


. The burnt charge or exhaust gases flow through the exhaust passages


304


to exhaust manifold sections


306


that are also formed within the cylinder body


50


.




A pair of exhaust pipes


308


depend from the lower tray portion


40


and extend into an expansion chamber


310


formed in the driveshaft housing


32


. From this expansion chamber


310


, the exhaust gases are discharged to the atmosphere through a suitable exhaust system. As is well known in outboard motor practice, this may include an underwater, high speed exhaust gas discharge and an above the water, low speed exhaust gas discharge. Since these types of systems are well known in the art, a further description of them is not believed to be necessary to permit those skilled in the art to practice the invention.




A feedback control system including the ECU


116


is provided for control of engine operation. The injection timing and duration control and the firing timing control are included in this feedback control. The feedback control system includes, as well as the ECU


116


, a number of sensors that sense either engine running conditions, ambient conditions or conditions of the outboard motor


30


that will affect engine performance.




Certain sensors are shown schematically in FIG.


1


and will be described by reference to that figure.




For example, there is provided a crankshaft angle position sensor


314


that, when measuring crankshaft angle versus time, outputs a crankshaft rotational speed signal or engine speed signal to the ECU


116


through a signal line


316


.




Operator demand or engine load, as determined by a throttle angle of the throttle valve


90


, is sensed by a throttle position sensor


318


which outputs a throttle position or load signal


320


to the ECU


116


. When the operator desires to increase speed, i.e., accelerate, the operator operates a throttle lever (not shown). The throttle valve


90


is consequently opened toward a certain open position that corresponds to the desired speed. Correspondingly, more air is introduced into the crankcase chamber


60


through the throttle bodies


88


. The engine load also increases when the associated watercraft advances against wind. In this situation, the operator also operates the throttle so as to maintain the desired speed.




A combustion condition or oxygen (O


2


) sensor


322


senses the in-cylinder combustion conditions by sensing the residual amount of oxygen in the combustion products or exhaust gases at a time near the time when the exhaust port is opened. The sensor


322


in this embodiment senses the conditions in a cylinder bore


54


that positioned atop of one bank of the cylinder body


50


. This output and air/fuel ratio signal is indicted at


324


that goes to the ECU


116


.




There is also provided a pressure sensor


326


that is connected to the pressure regulator


296


. This pressure sensor


326


outputs the high pressure fuel signal to the ECU


116


. The signal line is not shown in FIG.


1


.




A water temperature sensor


328


may also be provided for outputting a cooling water or engine temperature signal


330


to the ECU


116


. This signal


330


can be substituted for a lubricant temperature signal.




Further, an intake air temperature sensor


332


is provided and this sensor


332


outputs an intake air temperature signal


334


to the ECU


116


.




Although these sensors are shown in

FIG. 1

, it is of course practicable to provide other sensors such as an engine height sensor, a trim angle sensor, a knock sensor, a neutral sensor, a watercraft pitch sensor and an atmospheric temperature sensor in accordance with various control strategies.




Additionally, other engine components such as, for example, a starter motor arranged to start the engine


36


and a flywheel assembly including a generator are provided, although not shown.




As has been noted, water may occasionally enter the fuel supply tank


104


with high frequency in connection with a marine engine like the engine


36


in the illustrated embodiment. If this occurs, corrosion can seriously damage the fuel injection system


120


. Particularly, the fuel injectors


126


are highly sophisticated, precise device and hence must be inhibited from rusting. Other components of the fuel injection system


120


may have similar problems with rust, but to a lesser degree.




In addition, in the illustrated embodiment, the motor section of the electric fuel pump


251


is soaked in the fuel. Under the circumstances, the water mingled with the fuel can cause following problems. First, motor elements such as bearings corrode to make noise, vibrations and frictions. This causes further power loss. Second, if the water includes impurities such as salt content, a local short circuit occurs at the brush


256


to expedite wear thereof. Third, the water electrolyzes at the brush


256


, and metallic cations and hydroxyl radicals together make the neutralization reaction to produce salts (hydroxide substances). That is, foreign substances come into existence in the fuel. Such foreign substances in the fuel cause problems such that the pressure loss of the fuel increases.




In the illustrated embodiment, therefore, the engine


36


has an intermediate lubricant supply system that supplies lubricant to the fuel injection system


120


for protecting components thereof from rusting. In addition, the ECU


116


controls an amount of the lubricant supplied to the injection system


120


.




With reference to

FIGS. 1

to


3


and


7


to


10


, the intermediate lubricant supply system includes a lubricant branch conduit


350


is provided for supplying the lubricant to the fuel injection system


120


from the lubrication system


96


. The lubricant branch conduit


350


is branched off between the main lubricant tank


102


and the lubrication pump


98


in the supply conduit


110


. As best seen in

FIG. 7

, the other end of the branch conduit


350


is connected to a lubricant inlet port


352


of the vapor separator


224


. The lubricant inlet port


352


communicates with the inner conduit


276


and thus the lubricant is introduced into the cavity


236


with the fuel. Alternatively, the other end of the branch conduit


350


can be connected to the pressure relief line


298


or to the fuel line


225


as indicated in dotted lines in FIG.


1


.




In the branch conduit


350


, there are provided a lubricant filter


352


, a premix lubrication pump


354


and a check valve


356


. The lubricant filter


352


is provided for removing foreign substances from the lubricant because such foreign substances can damage the fuel injection system


120


, particularly the fuel injectors


126


. The check valve


356


is provided for preventing fuel from flowing into the lubricant supply conduit


110


.




In the illustrated embodiment, a part


358


of the branch conduit


350


, which couples the check valve


356


with the inlet port


350


of the vapor separator


224


, is preferably formed with a transparent material. Because of this, the user or service person can easily ascertain that lubricant is being supplied to the vapor separator


224


under the engine running condition.




The premix lubrication pump


354


pressurizes the lubricant to the vapor separator


224


. The vapor separator


224


defines a recess


360


(see

FIGS. 2 and 3

) at its bottom and rear portion. As seen in

FIGS. 3 and 7

, a rig


362


is uniformly formed with the bottom piece


232


of the vapor separator


224


. The premix pump


354


is affixed to the rig


362


by a stay


364


.




As noted above, the vapor separator


224


is affixed to the crankcase member


62


via the elastic members


230


. The premix pump


354


, which is affixed to this vapor separator


224


, also is isolated from engine vibrations. Otherwise, the premix pump


354


can be affixed to the stay


182


of the fuel filter


180


to obtain the same effect, because the stay


182


also is affixed to the engine body


50


via the elastic members


186


.




Any type of pump device can be employed as the premix lubrication pump


354


.

FIGS. 8

to


10


illustrate an exemplary, plunger-type pump.




The plunger-type pump, still indicated by the reference numeral


354


, comprises a pump body


368


, a plunger


372


, a sub-plunger


374


, a coil spring


375


, an inlet port


376


and outlet ports


378


. The pump body


368


defines a cylindrical bore


380


and supports slideably and rotatably the plunger


372


that is coupled together with the sub-plunger


374


. The plunger


372


has a gear portion


382


.




A worm gear


383


is provided in another cylindrical bore formed in the pump body


368


. The worm gear


383


has a gear shaft


384


, which axis extends normal to an axis


385


of the plunger


372


, and is meshed with the gear portion


382


so as to rotate the plunger


372


.




A camshaft


386


is provided to extend normal to the plunger axis


385


. The camshaft


386


has a large cam


388


and a small cam


390


, both are configured right circles but decentered from an axis of the camshaft


386


. The coil spring


375


normally biases the plunger


372


in the right direction in FIG.


10


. Either one of the large or small cam


388


,


390


can push back the plunger


372


in the opposite direction alternately with the rotation of the camshaft


386


.




The worm gear shaft


384


and the camshaft


386


are connected to an electric motor through a drive mechanism (both are not shown) so as to be driven by the electric motor.




The inlet port


376


communicates with the bore


380


through an inlet passage


392


, while the bore


380


also communicates with the outlet ports


378


through outlet passages


394


. In addition, inner passages are internally formed within the plunger


372


and sub-plunger


374


so as to connect the inner passages


392


with the outer passages


394


.




When the motor drives the warm gear shaft


384


and the cam shaft


386


, the plunger


372


and the sub-plunger


374


rotate and reciprocate within the bore


380


. With this rotational and reciprocal movement, the lubricant is introduced into bore


380


through the inlet passage


392


. The lubricant is then transferred to the outlet passages


394


through the inner passages and pushed out from the outlet ports


378


.




In the illustrated embodiment, the plunger


372


extends generally vertically in parallel to the crankshaft


48


as seen in FIG.


3


. This arrangement is advantageous because engine vibrations, which are particularly caused by the horizontal movement of the pistons


56


, hardly affect the premix pump


354


.




Such a plunger-type pump device is conventional and is well known in the art. Other types of pump devices, such as, for example, an electromagnetic-type pump, are of course also practicable. The electromagnetic-type pump is also well known.




The fuel injection system


120


needs lubricant only to protect the components from rusting by the water inadvertently mixed with the fuel. It has been found that the lubricant easily adhere to the components to coat over them and only a small amount of the lubricant is necessary to keep this condition. In other words, a large amount of lubricant is not necessary. Moreover, such a large amount of lubricant is undesirable because white smoke will be produced and also the spark plugs


124


are likely to fail proper ignitions due to deposits, which are produced with the lubricant, on their electrodes caused by the lubricant. The ECU


116


, therefore controls the pump


354


through a signal line


398


(see

FIG. 1

) to regulate an amount of lubricant so as to introduce a proper volume.




A various control methods to supply this lubrication can be practiced.




Before describing a first control method, generally, the ECU


116


stores in memory a fuel amount control map for the fuel injectors


126


that is shown in FIG.


11


. In this map, an engine speed is indicated on the horizontal line, while an engine load is indicated on the vertical line. For example, if the engine speed is “m” and the engine load is “n”, then a fuel amount is determined as “F


mn


”. The ECU


116


calculates an amount of the lubricant “F” with this value “F


mn


” by the following formula:








F=F




mn




×C


(


C


: constant)






Actually, the fraction value {fraction (1/2000)} is preferably selected as the constant value. A value in a range {fraction (1/250)} to {fraction (1/2000)} is preferred. If the value is greater than {fraction (1/200)}, the plug fouls may increase and thus it is not preferred; a value less than {fraction (1/2000)} may not maintain the proper coating of the components. The premix lubrication pump


354


doses such an extremely small amount of lubricant. The premix pump


354


, thus, supplies this amount of the lubricant to the vapor separator


224


. This method can provides a proper lubricant amount to the fuel injection system


120


at all times in accordance with the engine's speed and load. Incidentally, in other methods described below, the premix lubrication pump


354


functions in a similar manner.





FIG. 12

illustrates a lubricant amount control map for a first method of operating the premix pump


354


that controls an amount of the lubricant so that a mixture ratio of the lubricant with the fuel, which is determined by the fuel amount control map in

FIG. 11

, will be constant.




In this embodiment, if the engine speed is less than “x” and the engine load is less than “y”, the ECU


116


will not operate the premix pump


354


and thus no lubricant is supplied to the vapor separator


224


because the fuel injection amount is not very large in this range. If, however, the engine speed exceeds “x” and the engine load exceeds “y”, the ECU


116


will operate the premix pump


354


to supply a constant of fixed amount of the lubricant such as “A”. The ECU


116


in this embodiment controls only two states, one is to supply no lubricant and the other is to supply constant amount lubricant “A”. This method is, thus, quite simple.





FIG. 13

illustrates a second control method. In this embodiment, the ECU


116


operates the premix pump


354


at a predetermined pump speed “p” so as to output a constant amount of the lubricant if the lubricant temperature exceeds “t”. Otherwise, the ECU


116


increases a pump speed so as to be greater than “p” along the curve


402


in the graph. That is, the lower the lubricant temperature is, the greater the pump speed is. This is because a coefficient of viscosity of the lubricant is large when it is cold. Although a lubricant temperature sensor can sense the lubricant temperature, in the illustrated method, the ECU


116


uses the water temperature signal


330


because the lubricant temperature is generally proportioned to the water temperature.




With reference back to

FIG. 5

, in the illustrated embodiment, the engine


36


includes the fuel injectors


126


directly spraying fuel into the combustion chambers


160


as noted above. The injection nozzles


134


are hence exposed to the combustion chambers


160


in which air/fuel charges burn. Under the circumstances, the injection nozzles


134


are likely to have deposits (hydrocarbons)


404


, particularly around the injection openings


146


. The diameters of the openings


146


, which are extremely precisely controlled, will be narrowed accordingly, and amounts of the fuel injected from the openings


146


must fluctuate. This is a serious problem with the fuel injection system


120


.




In addition, marine engines are typically operated in a range of high load and high engine speed in comparison with automobile engines that are normally operated in a range of low load and low/medium engine speed. The engine operation in that range tends to develop insufficient vaporization of the fuel because of lack of injection time. The injected fuel, therefore, makes relatively large diameter mist that expedite production of the deposits.




Also, the engine


36


in this embodiment employs such a collective exhaust system as shown in FIG.


1


. The collective exhaust system makes large differences in conditions of the respective cylinders. The engine


36


additionally practices the separate air/fuel ratio controls by the ECU. This type of engine particularly tends to have the foregoing problem with the deposits.




In order to resolve the problem, the user can add a cleaning agent that inhibits the deposits from being developed at the injection openings


146


. The cleaning agent preferably includes surface-active substances such as aminoamid. A ratio of a cleaning agent amount relative to a lubricant amount is, for example, 5 to 25%.




The diameters of the openings


146


, however, can be narrowed not only by the deposits


404


but also by rust. Whether adding the cleaning agent to the lubricant or not, therefore, the following third and fourth methods are effective as measures against narrowing of the injection openings.





FIG. 14

illustrates a control strategy of the third method. Generally, if the deposit


404


or rust is produced at the injection openings


146


, a rate of the injection amount decreases as shown in the section (A). The ECU


116


, therefore, is configured to increase the duration of the injection so as to compensate for the decrease of the injection amount. Actually, the ECU


116


increases an air/fuel adjustment (increase) coefficient or feedback adjustment coefficient “K” as shown in the section (B). This coefficient “K” is completely in inverse proportion to the injection amount decrease rate. As shown in the section (C), the ECU


116


starts controlling the premix pump


354


to operate with a lubricant adjustment (increase) coefficient “Q”. The coefficient “Q” in this embodiment is selected as 1.2 when the air/fuel adjustment coefficient in the section (B) becomes greater than a first predetermined level 1.05. By this control, the air/fuel adjustment coefficient “K” will not increase and then goes down. The ECU


116


continuously watches if the air/fuel adjustment coefficient “K” becomes smaller than the first predetermined value 1.05 but grater than a second predetermined value 1.025. If this is affirmative, the ECU


116


controls the premix pump


354


to operate with another lubricant adjustment coefficient “Q”, which is the value 1.1. Then, if the air/fuel adjustment coefficient “K” becomes smaller than the second predetermined value 1.025, the ECU


116


no longer has the premix pump


354


increase the lubricant to the fuel injection system


120


.




The ECU


116


stores this data as control maps. Incidentally, The sections (A) and (B) of

FIG. 14

also show that both the actual lines continue to extend along the dotted lines if no lubricant is supplied to the fuel injection system


120


.





FIG. 15

illustrates a control routine practiced by the ECU


116


to realize the third method. The program starts and proceeds to the step S


1


to determine the air/fuel adjustment coefficient “K”.




The program then goes to the step S


2


to determine if the air/fuel adjustment coefficient “K” is greater than the value 1.05. If this is positive, the program goes to the step S


3


. If, however, it is negative, the program goes to the step S


4


.




At the step S


3


, the program determines the lubricant adjustment coefficient “Q” as the value 1.2. After the step S


3


, the program goes to the step S


8


.




At the step S


4


, the program determines whether the ECU


116


is in an increase control of the premix pump


354


. At the first time, this is negative. Thus, the program goes to the step S


5


. If, however, it is positive in a second or later circulation, the program goes to the step S


6


.




At the step S


5


, the program determines the lubricant adjustment coefficient “Q” as the value 1.0. After the step S


5


, the program goes to the step S


8


.




It should be noted that the coefficient “Q” is the value 1.0 means that the premix pump


354


operates to supply a standard amount of the lubricant, i.e., neither increased nor decreased amount. Alternatively, however, another control is available such that no lubricant will be supplied if the program goes to the step S


5


.




At the step S


6


, the program determines if the air/fuel adjustment coefficient “K” is smaller than the value 1.05 but greater than the value 1.025. If this is positive, the program goes to the step S


7


. If, however, it is negative, the program goes to the step S


5


.




At the step S


7


, the program determines the lubricant adjustment coefficient “Q” as the value 1.1. After the step S


7


, the program goes to the step S


8


.




At the step S


8


, the program operates the premix lubricant pump


354


so that the pump


354


supplies the amount of lubricant that has been determined.




After practicing this control routine, the program again returns to the step S


1


and repeats circulation of the routine until the end of the engine operation.





FIG. 16

illustrates another control routine practiced by the ECU


116


to realize the fourth control method. The program starts and proceeds to the step S


11


. The ECU


116


determines an engine speed, engine load and lubricant temperature. The engine speed is determined by the signal


316


from the crankshaft angle position sensor


314


. The engine load is determined by the signal


320


from the throttle position sensor


318


. The lubricant temperature, in turn, is indirectly determined by the signal


330


from the water temperature sensor


328


.




Next, the program goes to the step S


12


and determines an adjustment coefficient of viscosity of the lubricant. This adjustment coefficient is determined by a graph shown in FIG.


17


. The viscosity “V” at the vertical axis is generally in inverse proportion to the lubricant temperature “T” at the horizontal axis. For example, if the lubricant temperature “T” is “T


1


”, the viscosity “V” is “V


1


”.




The control routine then goes to the step S


13


and first determines a fundamental amount “F


mn


” of the lubricant based upon a temperature of the injection nozzle


134


, i.e., the tip portion of the injector


126


. Because the deposits


404


that can close the injection openings


146


are most likely to be produced in a range of the temperature 100° C. to 200° C. As shown in

FIG. 18

, in an exemplifying mode, generally, the temperature of this portion is given if both the engine speed and the engine load are determined. For example, if the engine speed is “s” and the engine load is “d”, then the temperature will be 130° C. Because of this, the fundamental amount “F


mn


” can be previously stored in a control map as shown in FIG.


19


. If, therefore, the engine speed is “s” and the engine load is “d”, then the fundamental amount “F


mn


” will be determined as the value 8. Then, the program determines an adjusted amount “F” that is given in multiplying the coefficient “V”, which has been obtained at the step S


12


, to the fundamental amount “F


mn


”. That is, the adjusted amount F is given by the following formula:








F=F




mn




×V








Then, the program goes to the step S


14


and determines whether the overall operation time “OT” of the engine


36


exceeds thirty hours or not. For this purpose, the ECU


116


has a timer that measures the operation time of the engine


36


. Otherwise, the ECU


116


can have a counter that counts the number of times of the signal


316


from the crankshaft angle position sensor


314


. If the answer is positive, the program goes to the step S


15


. If it is negative, the program goes to the step S


16


bypassing the step S


15


.




At the step S


15


, the program determines a time adjustment coefficient “H” based upon the graph shown in the right-hand side of the step S


15


in FIG.


16


. The time adjustment coefficient “H” decreases in inverse proportion to the lapse of time “t”. That is, the time adjustment coefficient “H” starts at the value “h” and then decreases to zero in thirty hours. The adjusted amount “F” is again adjusted with this value “H”. That is, the adjusted amount “F” is given by the following formula:








F=F×H








This is because a new engine requires a large quantity of lubricant. After the step S


15


, the program goes to the step S


16


.




At the step S


16


, the program determines if the engine


36


is in an acceleration period, deceleration period or no such transitional periods. If the program determines that it is in an acceleration period, then it goes to the step S


17


. If the program determines that it is in a deceleration period, then it goes to the step S


118


. If it determines that neither acceleration nor deceleration is made, then it goes to the step S


19


. The ECU


116


can recognize the acceleration or deceleration condition by the signal


320


from the throttle position sensor


318


that shows an open or close state of the throttle valve


90


and its change rate.




At the step S


17


, the program further adjusts the adjusted amount “F” with an acceleration adjusting coefficient “J” to increase the amount “F”. That is, the adjusted amount “F” is given by the following formula:








F=F×J








Meanwhile, at the step S


18


, the program adjusts the adjusted amount “F” with a deceleration adjusting coefficient “R”. Alternatively, the amount “F” can be zero to completely cut the lubricant. That is, the adjusted amount F is given by the following formula:








F=F×R


or


F


=0






After either the step


17


or step


18


, the program goes to the step S


19


.




At the step


19


, the program operates the premix lubricant pump


354


so that the pump


354


supplies the amount of lubricant that has been determined.




After practicing this control routine, the program again returns to the step S


11


and repeats circulation of the routine until the end of the engine operation.




The lubricant amount depends on the pump speed of the premix pump


354


. If the pump


354


is the plunger-type, the pump speed changes with the change of the motor speed, and this motor speed is changeable by controlling a current or voltage supplied to the motor.




If the pump


354


is the electromagnetic-type pump, the pump speed reduces with a partial operation or with the change of its duty ratio. For example, FIGS.


20


(A), (B) and (C) illustrates this control. FIG.


20


(A) shows a line of pulses under a certain duty ratio. If the electromagnetic pump must reduce the pump speed, a several pulses are given and the rest of the pulses are omitted as shown in FIG.


20


(B) or the duty ratio is reduced as shown in FIG.


20


(C).




As a fifth method, the ECU


116


can control the premix pump


354


using the signal


218


from the water-sensing system


180


. That is, the ECU


116


allows the premix pump


354


to supply a predetermined amount of the lubricant when it receives the signal


218


. The ECU


116


, in this regard, can start supplying the lubricant, or increase the lubricant amount in the situation that the premix pump


354


has already supplied the lubricant.




As described above, in the illustrated embodiments, part of the lubricant is mixed to the fuel under control of the ECU. The fuel injection system thus can inhibit, by introducing lubricant into the fuel, its components from being rusted in the event that water, particularly salt water, is mixed into the fuel. In addition, the lubricant amount supplied to the fuel injection system is always kept in a proper and extremely small range. No lubricant is, therefore, wasted for the purpose, and neither white smoke nor plug foul will occur. Of course, for this affect, the amount of lubricant introduced into the fuel is much less than the amount of lubricant delivered to the engine by the lubrication pump


98


.




The present invention can be practiced not only with a direct injected engine but also with an indirect injected engine such that the fuel is injected into the air induction system.




Although the present invention has particular applicability in connection with an outboard motor, and therefore has been described in this context, certain aspects of the present invention can be used with other marine drive units as well (e.g., a stern drive unit).




Of course, the foregoing description is that of a preferred embodiment of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, as defined by the appended claims.



Claims
  • 1. A fuel injected, internal combustion engine for a marine propulsion device comprising a combustion chamber, a fuel delivery system arranged to deliver fuel for combustion in the combustion chamber, the fuel delivery system including a fuel injector spraying the fuel, a lubricant delivery system including a first lubrication pump arranged to deliver lubricant from at least one lubricant tank to at least one engine component that needs lubrication, an intermediate lubricant supply system operating between the lubricant delivery system and the fuel delivery system including a second lubrication pump to supply an amount of the lubricant to the fuel delivery system from the at least one lubricant tank so as to mix the lubricant with the fuel, and a control device arranged to control the amount of the lubricant supplied to the fuel delivery system through the intermediate lubricant supply system.
  • 2. The fuel injected, internal combustion engine as set forth in claim 1, wherein the engine component is at least one crankshaft.
  • 3. The fuel injected, internal combustion engine as set forth in claim 1, wherein the engine component is at least one connecting rod.
  • 4. The fuel injected, internal combustion engine as set forth in claim 1, wherein the engine component is at least one piston.
  • 5. The fuel injected, internal combustion engine as set forth in claim 1, wherein the first oil pump is driven by an electric motor.
  • 6. The fuel injected, internal combustion engine as set forth in claim 1, wherein the first oil pump is mechanically driven by the engine.
  • 7. The fuel injected, internal combustion engine as set forth in claim 1, wherein the second oil pump is driven by an electric motor.
  • 8. A fuel and oil injection system for an internal combustion engine comprising a lubricant tank, a fuel tank, a first lubricant pump adapted to draw lubricant from said lubricant tank through a first lubricant supply line, a fuel vapor separator receiving fuel from said fuel tank, said first lubricant pump adapted to supply lubricant drawn from said lubricant tank to a mechanical component of said engine through a second lubricant supply line, a second lubricant pump adapted to scavenge lubricant from said first lubricant supply line and to supply said lubricant to said fuel vapor separator, said second lubricant pump being controlled by a control unit such that a flow rate of lubricant into said fuel vapor separator can be altered by said second lubricant pump.
  • 9. The system of claim 8, wherein said flow rate of lubricant is calculated as a function of a sensed engine load and a sensed engine speed.
  • 10. The system of claim 9, wherein said function has a constant of {fraction (1/2000)}.
  • 11. The system of claim 8, wherein said second lubricant pump is not operated if a sensed engine speed is less than a predetermined engine speed and if a sensed engine load is less than a predetermined engine load.
  • 12. The system of claim 11, wherein said second lubricant pump is operated to supply a constant amount of lubricant if said sensed engine speed exceeds said predetermined engine speed or said sensed engine load exceeds said predetermined engine load.
  • 13. The system of claim 8, wherein said second lubricant pump is operated to increase said flow rate of lubricant to said fuel vapor separator if a sensed engine temperature is low and to decrease said flow rate of lubricant to said fuel vapor separator as said engine temperature increases until a predetermined engine temperature is exceeded.
  • 14. The system of claim 13, wherein said second lubricant pump is operated at a constant speed once said sensed engine temperature exceeds said predetermined engine temperature.
  • 15. The system of claim 8, wherein an operating speed of said second lubricant pump is altered in accordance with a change in output from a fuel injector over time, whereby increased lubricant is supplied to said fuel injector when said fuel injector output is reduced by a deposit or rust.
  • 16. The system of claim wherein said alteration of said operating speed comprises moving between three different operating speeds depending upon a degree to which fuel injector output has been affected.
  • 17. The system of claim 8, wherein said lubricant flow rate from said second lubricant pump is controlled as a function of engine load, engine speed and engine temperature.
  • 18. The system of claim 17, wherein said lubricant flow rate from said second lubricant pump is further controlled as a function of engine operating time.
  • 19. The system of claim 8, wherein said lubricant flow rate from said second lubricant pump is varied depending upon whether said engine is accelerating or decelerating.
Priority Claims (3)
Number Date Country Kind
11-162559 Jun 1999 JP
11-165708 Jun 1999 JP
11-173957 Jun 1999 JP
Parent Case Info

This application is a Continuation of application Ser. No. 09/591,458, filed Jun. 9, 2000, now U.S. Pat. No. 6,516,756.

US Referenced Citations (26)
Number Name Date Kind
4142486 Schreier Mar 1979 A
4403578 Iwai et al. Sep 1983 A
4480602 Kobayashi et al. Nov 1984 A
4539949 Walsworth Sep 1985 A
4594970 Baars et al. Jun 1986 A
4700671 Matsushita Oct 1987 A
4708674 Matsumoto Nov 1987 A
5136990 Motoyama et al. Aug 1992 A
5235944 Adachi Aug 1993 A
5287833 Yashiro Feb 1994 A
5297511 Suzuki Mar 1994 A
5355851 Kamiya Oct 1994 A
5370089 Harada Dec 1994 A
5390635 Kidera et al. Feb 1995 A
5511524 Kidera et al. Apr 1996 A
5537959 Ito Jul 1996 A
5630383 Kidera et al. May 1997 A
5701872 Kaku et al. Dec 1997 A
5709186 Taue Jan 1998 A
5732672 Nakase Mar 1998 A
5829401 Masuda Nov 1998 A
5941745 Kanno Aug 1999 A
5951342 Ozawa et al. Sep 1999 A
5954555 Ozawa et al. Sep 1999 A
5970942 Koeberlein et al. Oct 1999 A
6047671 Tubb et al. Apr 2000 A
Continuations (1)
Number Date Country
Parent 09/591458 Jun 2000 US
Child 10/316209 US