JP2009041476A - Fuel control system of internal combustion engine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress an oxidation deterioration only if the oxidation deterioration of fuel is likely to occur based on the properties of biofuel. <P>SOLUTION: A fuel control system of a diesel engine 1 configured to use fuel including biofuel further includes: a bioconcentration sensor 19 for detecting a biofuel concentration; and a display device 78 for informing drivers of vehicles of a predetermined warning items. If a detected biofuel concentration is equal to or more than a predetermined value, the display device 78 advises the effect that fuel in use is needed to be promptly consumed or removed, or the effect that biofuel with a low concentration or a light oil is needed to be promptly supplied. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a fuel control device for an internal combustion engine configured to be able to use a fuel containing biofuel, and more specifically, suppresses the oxidative degradation only when the oxidative degradation of the fuel is likely to occur based on the properties of the biofuel. The present invention relates to a fuel control device for an internal combustion engine.

  In recent years, from the viewpoint of energy and environmental measures, oxygen-containing fuels such as alcohol and biofuels made from rapeseed and palm have attracted attention as alternative fuels to standard fuels such as gasoline and light oil. There is also a demand for the development of possible internal combustion engines.

  In particular, bio diesel oil (for example, RME: rapeseed oil methyl ester, waste cooking oil, etc.), which is a biofuel, has attracted attention as a fuel for diesel engines. However, this bio diesel oil is a fuel that is more susceptible to oxidative degradation than standard diesel oil, and is characterized by being easily oxidatively degraded over time, and also susceptible to oxidative degradation under high temperature conditions and high concentration conditions.

  Therefore, when such a bio diesel oil is used alone or mixed with a standard diesel oil for a diesel engine, it is necessary to suppress the oxidative degradation of the fuel based on its fuel properties. In fact, no means to suppress it has been provided.

  As a related technique, metal ion removal for separating and removing metals and metal ions contained in the fuel between the fuel tank and the injector in the path from the fuel tank to the internal combustion engine. There has been proposed a technique that includes means, prevents metal deposition and deposition in the injector, and drives the injector stably for a long period of time (see, for example, Patent Document 1).

  In addition, as another related technique, the following technique has also been proposed (see, for example, Patent Document 2). That is, in order to suppress the occurrence of coking in the fuel fractionation passage and the oxidative deterioration of the fuel, the fuel supplied from the fuel tank of the internal combustion engine is heated while being circulated and fractionated into vapor phase fuel and liquid phase fuel. A fuel fractionation passage having a heating fractionation section, a flow rate adjusting means for regulating the flow rate of fuel supplied to the fuel fractionation passage, fuel fractionation is required, and the temperature of the heating fractionation section is the temperature of the fuel. An operation control means for controlling the operation of the flow rate adjusting means to supply the fuel to the heated fractionation section in order to fractionate the fuel when the temperature is lower than the acceleration temperature at which the deterioration is promoted. The distillation apparatus includes a temperature acquisition unit that acquires the temperature of the heated fractionation section, and the operation control unit determines that the temperature acquired by the temperature acquisition unit is equal to or higher than the deterioration promoting temperature. Temperature is the temperature to accelerate deterioration Is obtained by configured to provide fuel to the control to heating the fractionation section the operation of the flow rate control means so as to drop below.

JP 2006-105092 A JP 2006-70796 A

  In the prior art according to Patent Document 1, attention is paid to a means for removing foreign substances based on metal deposition and deposition in fuel, and oxidation of biofuel under predetermined high concentration and high temperature conditions. No means for suppressing deterioration is disclosed. Therefore, when the bio diesel oil is used in a diesel engine without taking measures for suppressing the oxidative deterioration of the fuel, the following problems may occur.

  That is, since the biofuel in the bio light oil is likely to be oxidized and deteriorated with time, if the elapsed time after supplying the biofuel is long, the fuel is oxidized and deteriorated. When this oxidized and deteriorated fuel is used in a diesel engine, it has a corrosive action on the metal parts of the fuel system (for example, metal parts of common rails, supply pumps, and injectors) and corrodes the plating. There is a risk that the injector or the like may malfunction or cause fuel leakage.

  In particular, since the above-mentioned parts arranged in the vicinity of the engine body are exposed to high temperatures, when the biofuel concentration is higher than a predetermined value, the oxidative degradation of the fuel is promoted and may be affected by the corrosive action. Sex was great.

  Moreover, in order to suppress the oxidative degradation of the fuel under high temperature conditions, it is conceivable to control the temperature of the fuel below the oxidative degradation temperature as seen in the prior art according to Patent Document 2.

  However, if this concept is simply applied to biofuels, the fuel temperature is always controlled below the oxidation degradation temperature, even though it has the property of being less susceptible to oxidation degradation when the biofuel concentration in the fuel is low. That was a waste.

  The present invention has been made in view of the above, and provides a fuel control device for an internal combustion engine that can suppress the oxidative deterioration of the fuel only when the oxidative deterioration of the fuel is likely to occur based on the properties of the biofuel. With the goal.

  In order to solve the above-described problems and achieve the object, a fuel control device for an internal combustion engine according to claim 1 of the present invention is a fuel control device for an internal combustion engine configured to be able to use fuel containing biofuel. Biofuel concentration detection means for detecting or estimating the biofuel concentration is further provided, and when the biofuel concentration detected or estimated by the biofuel concentration detection means is equal to or higher than a predetermined value, oxidative deterioration of the fuel is suppressed. The present invention is characterized in that oxidative deterioration suppression control is performed for the purpose.

  Therefore, according to the present invention, the oxidative deterioration suppression control is performed under biofuel concentration conditions where the fuel is likely to be oxidatively deteriorated, thereby suppressing the oxidative deterioration of the fuel without waste. Thereby, since the corrosive action with respect to the metal parts, plating, etc. of a fuel system apparatus is suppressed, the malfunction of an injector etc. by a corrosion, fuel leakage, etc. are suppressed, and the reliability of an internal combustion engine improves.

  According to a second aspect of the present invention, there is provided a fuel control apparatus for an internal combustion engine according to the first aspect of the present invention, wherein the oxidation deterioration preventing agent for introducing an oxidation deterioration inhibiting agent for suppressing the oxidation deterioration of the fuel into the fuel is provided. An oxidization deterioration inhibiting control is characterized in that the oxidative deterioration preventing agent is charged into the fuel by the oxidative deterioration preventing agent charging means.

  Therefore, according to the present invention, the oxidative degradation of the fuel is suppressed by the action of the oxidative degradation inhibitor introduced into the fuel.

  According to a third aspect of the present invention, there is provided a fuel control device for an internal combustion engine according to the first aspect, wherein the fuel in the fuel system device in the vicinity of the internal combustion engine is extracted from the fuel system device, A fuel extraction / transfer means for transferring the fuel to another fuel system device installed away from the engine, wherein the oxidative degradation control is controlled by the fuel extraction / transfer means during the soak of the internal combustion engine. And is transferred to the other fuel system device.

  After the internal combustion engine is stopped, fuel circulation in the fuel system in the vicinity of the internal combustion engine stops, the fuel system receives radiant heat from the internal combustion engine, and cooling by the outside air is also slow. There is a possibility that the fuel staying in the system apparatus becomes high temperature and oxidation deterioration proceeds. However, when the fuel is extracted from the fuel system by the fuel extraction and transfer means and transferred to another lower temperature fuel system (for example, a fuel tank), the fuel is mixed with the lower temperature fuel in the other fuel system. As a result of being diluted and cooled, the progress of oxidative degradation is suppressed.

  According to a fourth aspect of the present invention, there is provided a fuel control device for an internal combustion engine according to the third aspect, wherein the fuel extraction and transfer means includes a fuel system device in the vicinity of the internal combustion engine and the other fuel system devices. And a valve means provided in the path of the fuel return path for blocking or opening the path.

  Therefore, according to the present invention, by opening the valve means, the fuel remaining in the fuel system device in the vicinity of the internal combustion engine is transferred to another fuel system device (for example, a fuel tank) through the fuel return passage. Is done. Since the transferred fuel is diluted and cooled by mixing with the low-temperature fuel in the other fuel system device, the progress of oxidation deterioration is suppressed.

  According to a fifth aspect of the present invention, there is provided a fuel control device for an internal combustion engine according to the first aspect, wherein the fuel in the fuel system near the internal combustion engine body is extracted from the fuel system, A fuel extraction / transfer means for transferring the fuel to another fuel system device installed apart from the internal combustion engine, and the fuel in the path of the fuel extraction / transfer means or the fuel transferred to the other fuel system device is cooled. Cooling control means, wherein the oxidative degradation suppression control is configured to control the fuel transferred to the fuel in the path of the fuel extraction transfer means or the other fuel system device by the cooling means during operation of the internal combustion engine. It is characterized by cooling.

  Therefore, according to the present invention, when the detected biofuel concentration is equal to or higher than the predetermined value, the high temperature fuel staying inside the fuel system device (for example, common rail, supply pump, etc.) is cooled by the cooling means. To another fuel system device (for example, a fuel tank), the high temperature of the fuel in the other fuel system device is suppressed, and the oxidative deterioration is suppressed.

  A fuel control apparatus for an internal combustion engine according to claim 6 of the present invention comprises the notifying means for notifying a driver of a vehicle equipped with the internal combustion engine of a predetermined warning in the invention according to claim 1, The oxidative degradation suppression control informs that it is necessary to quickly consume or remove the fuel in use by the informing means, or informs that it is necessary to promptly supply the low-concentration biofuel or standard fuel. Is notified.

  Therefore, according to the present invention, the vehicle driver can quickly consume or remove the fuel in use based on the content of the notification by the notification means, so that the fuel that may undergo oxidation deterioration may not be used in the future. It will be over. Moreover, since the biofuel having a high concentration equal to or higher than the predetermined value is rapidly diluted by supplying the low-concentration biofuel or the standard fuel to a lower concentration than the current level, the progress of oxidative deterioration is suppressed.

  According to a seventh aspect of the present invention, there is provided a fuel control apparatus for an internal combustion engine according to any one of the first to sixth aspects, wherein the fuel is not refueled in the oxidation deterioration suppression control. It is judged that there is a possibility that oxidation deterioration of the fuel may occur when the value is equal to or higher than a predetermined value, and the predetermined value is set smaller as the biofuel concentration is higher.

  Therefore, according to the present invention, the higher the concentration of biofuel and the longer the elapsed time from fuel supply, the earlier the execution timing of the oxidative degradation suppression control, or the higher the frequency or effect of execution. An execution decision is made.

  According to the fuel control device for an internal combustion engine according to the present invention (Claim 1), even when the concentration of the biofuel is considered to be oxidatively deteriorated, the oxidative deterioration suppression control is performed to suppress the oxidative deterioration of the fuel. be able to. As a result, the corrosive action on the metal parts and plating of the fuel system device is suppressed, so that malfunction of the injector and the like due to corrosion and fuel leakage can be suppressed, and the reliability of the internal combustion engine can be improved. it can.

  Further, according to the fuel control device for an internal combustion engine according to the present invention (Claim 2), when the biofuel concentration is equal to or higher than a predetermined value, the oxidative degradation inhibitor is introduced into the fuel according to the fuel amount. The oxidation deterioration of the fuel can be suppressed by the action of the antioxidant.

  Further, according to the fuel control device for an internal combustion engine according to the present invention (Claim 3), the fuel is extracted from the fuel system by the fuel extraction and transfer means when the internal combustion engine is soaked, and is transferred to another fuel system at a lower temperature. Then, the fuel is cooled by being mixed with the low-temperature fuel in the other fuel system device, so that the progress of oxidative deterioration of the fuel can be suppressed.

  Further, according to the fuel control apparatus for an internal combustion engine according to the present invention (Claim 4), the fuel can be easily extracted and transferred using the fuel return passage and the valve means which are the existing components of the internal combustion engine. Therefore, the entire apparatus can be configured easily, and an increase in the number of new parts and an increase in cost due to this can be avoided.

  Further, according to the fuel control device for an internal combustion engine according to the present invention (Claim 5), the fuel is cooled by the cooling means, so that the progress of the oxidative deterioration of the fuel can be suppressed.

  According to the fuel control device for an internal combustion engine according to the present invention (Claim 6), the fuel that the driver is likely to undergo oxidative degradation is consumed thereafter by quickly consuming or removing the fuel in use by the driver. Therefore, the progress of oxidative degradation can be suppressed. Or, since the fuel is diluted to a low concentration by rapidly supplying a low-concentration biofuel or a standard fuel, the progress of oxidative degradation can be suppressed.

  Further, according to the fuel control device for an internal combustion engine according to the present invention (Claim 7), the execution judgment of the oxidative deterioration suppression control is performed in accordance with the property of the biofuel that the higher the biofuel concentration is, the easier the fuel is oxidatively deteriorated. be able to.

  Embodiments of a fuel control device for an internal combustion engine according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

  1 is a schematic configuration diagram showing a diesel engine system to which a fuel control device for an internal combustion engine according to Embodiment 1 of the present invention is applied. As shown in FIG. 1, a diesel engine (hereinafter referred to as an engine) 1 that is an internal combustion engine includes a fuel system 10, a combustion chamber 20, and an intake system 30 that forms a passage for intake air supplied into the combustion chamber 20. This is an in-line four-cylinder diesel engine system that mainly includes an exhaust system 40 that forms a passage for exhaust gas discharged from each combustion chamber 20.

  The fuel system 10 includes a fuel tank 18 that stores biofuel, a main fuel passage P0, a fuel filter 18a, a supply pump 11, a common rail 12, a fuel injection valve 13, a shutoff valve 14, an exhaust fuel addition valve 17, an engine fuel passage P1, and An additional fuel passage P2 and the like are provided.

  Further, the fuel tank 18 is provided with a bio concentration sensor (bio fuel concentration detecting means) 19 for detecting the bio concentration of fuel and a level sensor 18b for detecting the remaining amount of fuel.

  The bio-concentration sensor 19 may be configured so as to be able to detect or estimate the biofuel concentration from, for example, measured values such as fuel viscosity and temperature, and the detection / estimation principle is not limited. Detection signals from the bio-concentration sensor 19 and the level sensor 18b are output to the ECU 77, which is an electronic control device described later.

  The supply pump 11 increases the pressure of the fuel pumped from the fuel tank 18 via the main fuel passage P0 and supplies it to the common rail 12 via the engine fuel passage P1. The common rail 12 accumulates the high-pressure fuel supplied from the supply pump 11 at a predetermined pressure and distributes it to each fuel injection valve 13. A fuel injection valve 13 that is an electromagnetic valve injects fuel into the combustion chamber 20 at a predetermined time.

  Further, the supply pump 11 supplies a part of the fuel pumped from the fuel tank 18 to the exhaust fuel addition valve 17 via the addition fuel passage P2. The shut-off valve 14 shuts off the fuel supply P2 when necessary and stops the fuel supply.

  A metering valve (not shown) is also provided in the added fuel passage P2. This metering valve controls the pressure (fuel pressure) of the fuel supplied to the exhaust fuel addition valve 17. Further, the exhaust fuel addition valve 17 which is an electromagnetic valve adds and supplies the fuel functioning as a reducing agent to the upstream of the NOx storage reduction catalyst 41 in the exhaust system 40 at an appropriate amount and at an appropriate timing.

  Further, the engine 1 includes a turbocharger 50 that supercharges intake air by the exhaust gas. The intercooler 31 provided in the turbocharger 50 forcibly cools the intake air whose temperature has been increased by supercharging. The throttle valve 32 provided downstream of the intercooler 31 is a so-called electronic throttle, and adjusts the amount of intake air supplied.

  Further, the engine 1 is provided with an EGR passage 60 that bypasses the intake system 30 and the exhaust system 40 and returns a part of the exhaust to the intake system 30. The EGR passage 60 is provided with an EGR valve 61 that adjusts the exhaust gas flow rate and an EGR cooler 62 that cools the exhaust gas. A catalyst (not shown) is provided on the upstream side of the EGR cooler 62.

  The exhaust system 40 includes an NSR (NOx Storage Reduction) catalytic converter 41a in which a NOx storage reduction catalyst is supported on a carrier, and a DPNR (Diesel Particulate NOx Reduction) in which a NOx storage reduction catalyst is supported on a porous ceramic structure. ) A catalytic converter 41b and an oxidation catalytic converter 42 provided downstream thereof are provided.

  These catalytic converters 41a and 41b are for storing NOx when the air-fuel ratio of the exhaust gas is lean, and for releasing and reducing the NOx stored in the reducing atmosphere while reducing the oxygen concentration in the exhaust gas. .

  Further, each part of the engine 1 includes an air flow meter 72 that detects an intake air amount, an air-fuel ratio sensor 73 that detects an oxygen concentration in exhaust gas, and an exhaust gas temperature that detects exhaust gas temperatures upstream and downstream of the DPNR catalytic converter 41b. A pressure sensor 75 for detecting a pressure difference between the upstream side and the downstream side of the sensors 74a and 74b, the NSR catalytic converter 41a and the DPNR catalytic converter 41b is provided.

  Although not shown, each part of the engine 1 includes a temperature sensor and a pressure sensor for detecting the temperature and pressure of the fuel in the common rail 12, a crank position sensor for detecting the crankshaft rotation of the engine 1, and an intake air temperature. Intake temperature sensor for detecting, intake pressure sensor for detecting intake pressure, accelerator position sensor for detecting accelerator pedal depression amount (accelerator position), throttle position sensor for detecting position of throttle valve 32, and cooling of engine 1 A water temperature sensor or the like for detecting the water temperature is provided.

  Detection signals from various sensors such as the bio concentration sensor 19 and the level sensor 18b are input to the ECU 77 via an external input circuit. The ECU 77 performs various controls relating to the operating state of the engine 1 such as opening / closing control of the fuel injection valve 13 and the exhaust fuel addition valve 17 based on these signals, and controls the display device 78 and the like.

  That is, as will be described later, the ECU 77 controls the oxidative degradation such as the fuel injection amount, the ignition timing, and a predetermined warning described later according to the operating state of the engine 1 and the properties (biofuel concentration) and remaining amount of the fuel to be used. Is configured to do. The ECU 77 is configured to be able to count an elapsed time T1 (described later) after refueling even when the ignition switch is OFF.

  The display device (notification means) 78 is disposed, for example, on an instrumental panel in front of the driver's seat, and displays various information necessary for driving, warnings, and the like. In the first embodiment, as will be described later, it is necessary to warn that it is necessary to quickly consume or remove the fuel in use, or to quickly supply low-concentration biofuel or standard fuel (light oil). It is configured to warn that.

  Note that this warning may be used in combination with sound or a buzzer in addition to the display on the display device 78. Thereby, the user (driver) can recognize the current state in which the fuel is likely to be oxidized and deteriorated, and can perform refueling and the like quickly, so that the oxidation deterioration of the fuel can be avoided in advance.

  Next, a control method according to the first embodiment will be described with reference to FIGS. 1 and 3 based on FIG. Here, FIG. 2 is a flowchart showing the control method, and FIG. 3 is a map showing an example of a limit time set according to the biofuel concentration.

  As described above, biofuel is a fuel that easily undergoes oxidative degradation, and oxidative degradation is promoted over time. Therefore, when biofuel is mixed with light oil and used in the engine 1, the fuel is not refueled for a certain period of time. Be careful.

  Therefore, in the first embodiment, the oxidation deterioration limit time in the fuel tank 18 according to the biofuel concentration (the time from the previous refueling to the next refueling, which must be taken into account for the oxidative deterioration) A map (see Fig. 3) with a time limit) is provided, and if the oxidation deterioration limit time is exceeded, the driver is warned to take measures to avoid it, and the fuel oxidation deterioration due to changes over time It is intended to suppress the above.

  In the following control (including other examples), it is assumed that the type of biofuel is defined in advance. That is, for example, fuel mixed with rapeseed oil and soybean oil is not used. Further, this control is executed by the ECU 77.

  As shown in FIG. 2, first, after the ignition switch (IG) is turned on (step S10), it is determined whether or not fuel has been supplied (step S20). Note that after the ignition switch (IG) is turned on, normal start control and combustion control are performed in another routine (not shown), but the description thereof is omitted.

  The presence or absence of the refueling can be determined as follows. For example, the remaining amount of fuel in the fuel tank 18 detected by the level sensor 18b is compared with the current amount when the vehicle was stopped last time, and if the difference exceeds a predetermined amount, it is determined that fuel has been supplied. can do.

  Further, when the fuel lid (not shown) is opened while the ignition switch is OFF, and the fuel remaining value before and after the opening is increased, it can be determined that the fuel has been supplied.

  If the fuel has been refueled (Yes at Step S20), the warning display to the driver by the display device 78 is set to OFF to return the control condition to the initial setting (Step S30), and the elapsed time T1 since refueling. Is set to zero (step S40), the value of the elapsed time T1 since the fuel supply is started to be counted by the counter of the ECU 77 (step S50), and the process returns to the fuel supply determination step S20.

  On the other hand, if not refueled (No at Step S20), the ECU 77 detects the value of the elapsed time T1 since the last refueling (Step S60). Next, the biofuel concentration in the fuel tank 18 is detected by the bioconcentration sensor 19 (step S70).

  Then, the oxidation deterioration limit time T2 corresponding to the detected biofuel concentration is calculated from the map (see FIG. 3) (step S80). The limit time T2 of this map is a threshold at which the fuel may be oxidized and deteriorated when the limit time is exceeded, and is obtained in advance by experiments or the like according to the type of fuel.

  Next, it is determined whether or not the elapsed time T1 detected in step S60 is equal to or longer than the limit time T2 (step S90). If the elapsed time T1 is less than the limit time T2 (No at Step S90), there is no possibility that the fuel will be oxidized and deteriorated due to a change with time, and the routine returns to the determination step S20 for determining whether or not fuel is supplied.

  If the elapsed time T1 is equal to or longer than the limit time T2 (Yes at Step S90), the fuel may be oxidized and deteriorated due to the change over time, so that a warning display on the display device 78 is provided to the driver to take a workaround. Is turned on (step S100), and the control is terminated.

  That is, it warns that it is necessary to quickly consume or remove the fuel in use, or warns that it is necessary to promptly supply low-concentration biofuel or standard fuel (light oil).

  The driver who received the warning consumes or removes the fuel in use promptly, so that it is not necessary to use the fuel that is likely to undergo the oxidative degradation after that, thereby suppressing the progress of the oxidative degradation. be able to. Moreover, since the fuel is diluted to a low concentration by rapidly supplying a low-concentration biofuel or a standard fuel, the progress of oxidative degradation can be suppressed.

  Therefore, if the oxidative deterioration of the fuel can be suppressed in this way, the corrosive action on the metal parts of the fuel system 10 (for example, metal components such as the fuel injection valve 13, the common rail 12, the supply pump 11, etc.), the plating thereof, etc. Since it can suppress, the reliability of the engine 1 can be raised.

  FIG. 4 is a schematic configuration diagram showing a diesel engine system to which a fuel control device for an internal combustion engine according to Embodiment 2 of the present invention is applied, and FIG. 5 is a flowchart showing a control method. In the following description, the same or corresponding parts as those already described or the step numbers are denoted by the same reference numerals, and redundant description is omitted or simplified.

  The configuration of the second embodiment is different from the configuration of the first embodiment shown in FIG. That is, as shown in FIG. 4, the configuration of the second embodiment has a common rail (fuel system device near the internal combustion engine) 12 and an additional fuel passage (fuel system device near the internal combustion engine) P2 and a fuel tank (another fuel system). Device) 18 is connected to a fuel return passage (fuel withdrawal / transfer means) P3, and an electromagnetic relief valve (fuel withdrawal / transfer means, valve means) 80a provided in the path of the fuel return passage P3 for blocking or opening the passage. , 80b.

  The fuel return passage P3 and the electromagnetic relief valves 80a and 80b are not shown in FIG. 1 of the first embodiment. Therefore, for convenience of explanation, it has been described that they are members added in the second embodiment. The member is generally provided as a member for fuel return in a normal diesel engine system.

  When the engine 1 is in a completely warmed-up state and the outside air temperature is above a certain value and is not easily cooled naturally, the fuel system device in the vicinity of the engine 1, that is, the common rail 12 Since the fuel staying inside the additive fuel passage P2, the supply pump 11 and the like receives radiant heat from the engine 1 and is gradually cooled by the outside air, the temperature is expected to rise. Since this high temperature promotes oxidative deterioration of the fuel, it is necessary to suppress the high temperature of the fuel.

  Therefore, in the second embodiment, when the temperature of the fuel is expected to rise, the electromagnetic relief valves 80a and 80b are opened, the common rail 12, the added fuel passage P2, the supply pump (fuel system device in the vicinity of the internal combustion engine) 11, etc. The purpose is to suppress the high temperature of the fuel and the oxidative deterioration by returning the high-pressure and high-temperature fuel staying in the fuel tank 18 to the fuel tank 18 via the fuel return passage P3 (withdrawing and transferring the fuel). Yes.

  The fuel extracted from the common rail 12 or the like and returned to the fuel tank 18 is the fuel in the fuel tank 18 provided away from the engine 1 (fuel having a lower temperature than the fuel remaining in the common rail 12 or the like). This is because the mixture is cooled by mixing, so that the progress of oxidation deterioration is suppressed.

  That is, in the second embodiment, the control shown in FIG. 5 is performed. As shown in FIG. 5, first, after the ignition switch (IG) is turned off (step S110), the biofuel concentration in the fuel tank 18 is detected by the bioconcentration sensor 19 (step S120).

  Next, it is determined whether or not the biofuel concentration detected in step S120 exceeds a concentration L at which oxidation degradation should be considered (step S130). The concentration L is a threshold value obtained in advance through experiments or the like, and can be set to 50%, for example.

  If the biofuel concentration exceeds the concentration L (Yes at Step S130), then, the cooling water temperature of the engine 1 detected by a water temperature sensor (not shown) exceeds the water temperature LW that can be recognized as a complete warm-up state. It is determined whether or not there is (step S140). This water temperature LW is a threshold value obtained in advance by experiments or the like, and can be set to 70 ° C., for example.

  If the cooling water temperature of the engine 1 exceeds the water temperature LW (Yes at step S140), it is further determined whether or not the outside air temperature (intake air temperature) detected by the intake air temperature sensor exceeds a predetermined temperature LA ( Step S150).

  The predetermined temperature LA is an outside air temperature at which the fuel temperature can be predicted to increase due to heat received from the engine 1 during the soak of the engine 1, and is a threshold value obtained in advance through experiments or the like. For example, the predetermined temperature LA can be set to 20 ° C.

  If the outside air temperature (intake air temperature) exceeds the predetermined temperature LA (Yes at Step S150), it is expected that the temperature of the fuel will increase. Therefore, the electromagnetic relief valves 80a and 80b are opened (step S160), and high-pressure and high-temperature fuel staying inside the common rail 12, the added fuel passage P2, the supply pump 11 and the like is supplied to the fuel tank via the fuel return passage P3. Return to 18. Note that the shut-off valve 14 is also opened as necessary.

  When the electromagnetic relief valves 80a and 80b are opened (step S160), the engine 1 is stopped (step S170) and the control is terminated.

  As a result, the fuel extracted from the common rail 12 or the like and returned to the fuel tank 18 is cooled by being mixed with the fuel in the fuel tank 18 provided away from the engine 1. Is suppressed, and oxidative deterioration is suppressed.

  Further, since the fuel can be easily extracted and transferred using the fuel return passage P3 and the electromagnetic relief valves 80a and 80b, which are often existing components of the engine 1, the entire apparatus can be simply configured. It is possible to avoid an increase in the number of new parts and an increase in cost due thereto.

  In the case where the temperature of the fuel is not expected to be high (No in Step S130, No in S140, No in S150), there is no risk of oxidative deterioration of the fuel and it is not subject to this control, so the electromagnetic relief valves 80a and 80b are opened. Without doing so, the engine 1 is stopped (step S170), and the control is terminated.

  When the engine 1 is restarted after the electromagnetic relief valves 80a and 80b are opened and the fuel is subjected to the relief control, it takes a predetermined time until the fuel is supplied to the common rail 12, and it takes longer to start than usual. Take it. Therefore, although an example of the control flowchart is omitted, it is preferable that the display device 78 informs the driver that it will take longer than usual when the engine 1 is restarted next time.

  Further, in the concentration determination step of the second embodiment (see step S130 in FIG. 5), the threshold value of biofuel concentration is determined by one threshold value L. However, the present invention is not limited to this, and more detailed concentration conditions (for example, 10) Based on the% concentration condition), the control of the water temperature determination (step S140) and the control of the outside air temperature determination (step S150) may be executed.

  6 is a schematic configuration diagram showing a diesel engine system to which a fuel control device for an internal combustion engine according to Embodiment 3 of the present invention is applied, FIG. 7 is a flowchart showing a control method, and FIG. 8 is a soak time and fuel temperature. It is explanatory drawing which shows these relationships.

  The configuration of the third embodiment is different from the configuration of the second embodiment shown in FIG. 4 in the following points. That is, as shown in FIG. 6, the configuration of the third embodiment has a fuel temperature (hereinafter referred to as fuel temperature) in a common rail (fuel system device near the internal combustion engine) 12 and a supply pump (fuel system device near the internal combustion engine) 11. The fuel temperature sensors 12a and 11a are provided. These fuel temperature sensors 11a and 12a are connected to the ECU 77 (the control line is omitted) and output detection signals.

  In the second embodiment, the fuel temperature in the soak of the engine 1 is predicted from the cooling water temperature and the outside air temperature (intake air temperature), and control is performed to extract fuel from the common rail 12 and the like. Since this control is performed based on the predicted value of the fuel temperature, control on the safe side must be performed.

  However, if the fuel extraction control is performed, it takes a longer start time than usual when the engine 1 is restarted. Therefore, it is a best practice not to perform the fuel extraction control as much as possible.

  Therefore, in the third embodiment, the fuel temperature in the soak of the engine 1 is measured by the fuel temperature sensors 11a and 12a, and the fuel extraction control is performed only when the limit value of the oxidative deterioration of the fuel is exceeded. Is.

  That is, in the third embodiment, the control shown in FIG. 7 is performed. As shown in FIG. 7, steps S110 to S130 are the same as in the case of the second embodiment, and a duplicate description is omitted. If the biofuel concentration exceeds the concentration L (Yes at Step S130), the engine 1 that is a heat generation source is immediately stopped (Step S132), and further increase in fuel temperature due to heat received from the engine 1 is suppressed.

  If the biofuel concentration does not exceed the concentration L (No at step S130), there is no risk of oxidative degradation of the fuel, and therefore the fuel temperature monitoring control by the ECU 77 is stopped without executing the control of steps S132 to S160. (Step S165) and the control is terminated.

  Next, the fuel temperatures of the supply pump 11 and the common rail 12 are measured at regular intervals by the fuel temperature sensors 11a and 12a, and the maximum fuel temperature in the soak as shown in FIG. 8 (hereinafter referred to as MAX fuel temperature). ) Is stored (step S134).

  Then, it is determined whether or not the current fuel temperature actually measured in step S134 exceeds the oxidation deterioration limit fuel temperature (step S136). This oxidation deterioration limit fuel temperature is a threshold at which it is determined that oxidation deterioration is promoted when the temperature is higher than this, and is obtained in advance by experiments or the like according to the type of fuel.

  If the actually measured actual fuel temperature exceeds the oxidation degradation limit fuel temperature (Yes in step S136), the electromagnetic relief valves 80a and 80b are opened in order to suppress the acceleration of oxidation degradation due to further higher temperature ( Step S160), the high-pressure and high-temperature fuel staying inside the common rail 12, the added fuel passage P2, the supply pump 11, etc. is returned to the fuel tank 18 through the fuel return passage P3. Note that the shut-off valve 14 is also opened as necessary.

  When the electromagnetic relief valves 80a and 80b are opened (step S160), the fuel temperature monitoring control by the ECU 77 is stopped (step S165), and the control is terminated.

  As a result, the fuel is extracted from the common rail 12 and the like only when it is necessary to exceed the limit value based on the actually measured fuel temperature. The fuel returned to the fuel tank 18 is cooled by being mixed with the fuel in the fuel tank 18 that is provided apart from the engine 1, so that the fuel only when the limit value of the oxidative deterioration of the fuel is exceeded. Temperature rise is suppressed, and oxidative degradation is suppressed.

  On the other hand, if the actual fuel temperature actually measured does not exceed the oxidation degradation limit fuel temperature (No in step S136), the current fuel temperature is a value obtained by subtracting a predetermined value FA (see FIG. 8) from the MAX fuel temperature. It is determined whether it is below (step S138).

  As shown in FIG. 8, the predetermined value FA is a temperature difference at which it can be determined that the fuel temperature has started to drop from the peak (MAX fuel temperature) during the soak, and is obtained in advance through experiments or the like according to the type of fuel. is there.

  If the current fuel temperature is lower than the value obtained by subtracting the predetermined value FA from the stored MAX fuel temperature (Yes in step S138), in other words, when it can be determined that there is no risk of further increase in fuel temperature. Stops the fuel temperature monitoring control by the ECU 77 (step S165) and ends the control.

  If the current fuel temperature exceeds the stored maximum fuel temperature minus the predetermined value FA (No at step S138), in other words, it can be determined that there is a possibility of further increase in fuel temperature. In that case, the process returns to step S134 to continue monitoring of the fuel temperature.

  As described above, based on the actually measured fuel temperature, the fuel extraction control can be performed only when the limit value of the oxidation deterioration of the fuel is exceeded, and the oxidation deterioration of the fuel can be suppressed. It is possible to minimize the increase in the starting time at the time of starting.

  In the fourth embodiment, when the detected biofuel concentration is equal to or higher than a predetermined value, a known antioxidant that suppresses the oxidative deterioration of the fuel is introduced into the fuel tank 18 in accordance with the amount of fuel. . FIG. 9 is a schematic configuration diagram showing a diesel engine system to which a fuel control device for an internal combustion engine according to Embodiment 4 of the present invention is applied.

  The configuration of the fourth embodiment is different from the configuration of the first embodiment shown in FIG. That is, in the configuration of the fourth embodiment, as shown in FIG. 9, the oxidation degradation inhibitor is stored so that the antioxidant (oxidation degradation inhibitor) can be introduced into the fuel tank 18 when necessary. Antioxidant tank (oxidation degradation preventing agent charging means) 90, an antioxidant passage (oxidation degradation preventing agent charging means) P4 connecting the antioxidant tank 90 and the fuel tank 18, and an antioxidant. And a pump (oxidation deterioration preventing agent charging means) 92 for sending the antioxidant in the tank 90 to the fuel tank 18. Known antioxidants according to the type of biofuel are stored in the antioxidant tank 90 in advance.

  The level sensor 94 provided in the antioxidant tank 90 is for detecting the remaining amount of the antioxidant in the antioxidant tank 90. The pump 92 and the level sensor 94 are connected to the ECU 77.

  In the fourth embodiment, the display device 78 shown in the first embodiment is not shown, but it may be provided if necessary. Further, an injector that can add the antioxidant to the antioxidant passage P4 may be provided instead of the pump 92.

  Next, a control method according to the fourth embodiment will be described with reference to FIG. 9 based on FIG. Here, FIG. 10 is a flowchart showing a control method.

  As shown in FIG. 10, first, after the ignition switch (IG) is turned on (step S210), the fuel amount NF in the fuel tank 18 is detected by the level sensor 18b (step S220).

  Then, after the biofuel concentration BL in the fuel tank 18 is detected by the bioconcentration sensor 19 (step S230), the engine 1 is started (step S240). This start control includes control necessary for starting the engine 1 and is well known and will not be described.

  Next, it is determined whether or not fuel is supplied while the ignition switch (IG) is OFF (step S250). This can be easily determined, for example, by storing the remaining amount of fuel in the fuel tank 18 at the previous stop and comparing it with the current fuel amount NF detected in step S220.

  If the fuel is supplied while the ignition switch (IG) is OFF (Yes at step S250), does the biofuel concentration BL detected at step S230 exceed the concentration L at which oxidative degradation of the fuel must be taken into account? It is determined whether or not (step S260). The concentration L is a threshold value obtained in advance through experiments or the like, and can be set to 50%, for example.

  If the biofuel concentration BL exceeds the concentration L (Yes at step S260), the oxidation required according to the current fuel amount NF and the biofuel concentration BL in order to suppress the oxidative deterioration of the fuel. The inhibitor amount K is calculated (step S270).

  In this calculation, a necessary antioxidant concentration map (not shown) corresponding to the biofuel concentration is provided, and the antioxidant amount is calculated from this map, the current fuel amount NF, and the biofuel concentration BL. K is calculated.

  Then, the calculated antioxidant amount K is supplied to the fuel tank 18 from the antioxidant passage P4 by operating the pump 92 (step S280). Thereby, the oxidative deterioration of the fuel in the fuel tank 18 is suppressed.

  When the fuel is not supplied while the ignition switch (IG) is OFF (No at Step S250), it is considered that the fuel property without the possibility of oxidation deterioration is maintained. Further, when the biofuel concentration BL does not exceed the concentration L (No at Step S260), it is not necessary to consider the oxidative deterioration of the fuel. Therefore, in these cases, it is only necessary to end the control without performing the above steps S270 and S280.

  The control in steps S250 to S280 performed after the start control (step S240) is performed in parallel with the well-known combustion control (not shown) so as not to affect the start.

  As described above, when the biofuel concentration is equal to or higher than the predetermined value, the antioxidant is introduced into the fuel tank 18 in accordance with the amount of fuel, so that the oxidation deterioration of the fuel is suppressed by the action of the antioxidant. be able to.

  In the concentration determination step of Example 4 (see step S260 in FIG. 10), the threshold value for biofuel concentration is determined by one threshold value L. However, the present invention is not limited to this, and more detailed concentration conditions (for example, 10). Subsequent control (steps S270 and S280) may be executed based on the concentration condition for each%.

  In the second embodiment, as shown in FIG. 4, the high-pressure and high-temperature fuel staying in the common rail 12, the added fuel passage P2, the supply pump 11, etc. is directly supplied to the fuel tank 18 through the fuel return passage P3. It was configured to return to.

  However, if the high-temperature fuel is returned to the fuel tank 18 as it is, the temperature of the fuel in the fuel tank 18 is raised. Especially when the remaining amount of fuel in the fuel tank 18 is small, the effect of temperature reduction due to the dilution described above. Is not preferred because of a decrease in

  Therefore, in the fifth embodiment, when the detected biofuel concentration is equal to or higher than a predetermined value, the high-pressure and high-temperature fuel staying inside the common rail 12, the added fuel passage P2, the supply pump 11, etc. is cooled, By returning to the fuel tank 18 via the fuel return passage P3, the temperature of the fuel in the fuel tank 18 is suppressed from being increased, and oxidation deterioration is suppressed.

  FIG. 11 is a schematic configuration diagram showing a diesel engine system to which a fuel control device for an internal combustion engine according to Embodiment 5 of the present invention is applied. The configuration of the fifth embodiment is different from the configuration of the second embodiment shown in FIG. That is, the configuration of the fifth embodiment includes a cooling means for cooling the fuel in the fuel return passage P3 before being returned to the fuel tank 18, as shown in FIG.

  The cooling means includes a cooling device (cooling means) 96 that cools the refrigerant in the refrigerant passage P5, and a fuel cooling heat exchanger that lowers the fuel temperature by exchanging heat between the refrigerant and the fuel in the fuel return passage P3. 97 and a refrigerant introduction electromagnetic control valve 98 that controls refrigerant introduction from the cooling device 96 to the fuel cooling heat exchanger 97, and is configured by a known technique.

  The cooling device 96 here uses a cooling unit (not shown) of an air conditioner mounted on the vehicle, and the ON / OFF operation thereof is performed by the driver. In addition, the cooling device 96 is connected to the ECU 77 so as to monitor the operation (ON / OFF) state. The refrigerant introduction electromagnetic control valve 98 is also connected to the ECU 77 so that its operation is controlled.

  In addition, when the air conditioner (cooling device 96) is not turned on by the driver, that is, when the vehicle interior is not cooled by the air conditioner, if the fuel needs to be cooled as described later, the cooling is performed. The device 96 is turned on by the ECU 77 and used only for cooling the fuel.

  The temperature sensor 95 is for detecting the fuel temperature in the fuel return passage P3, and the detected value is output to the ECU 77 (the control line is not shown).

  Next, a control method according to the fifth embodiment will be described with reference to FIG. 11 based on FIG. Here, FIG. 12 is a flowchart showing a control method.

  In this control, the electromagnetic relief valves 80a and 80b are opened, the fuel is extracted from the common rail 12 and transferred to the fuel return passage P3 as described above. In the following control for cooling the fuel, it is assumed that the control is performed on the fuel transferred through the fuel return passage P3.

  That is, as shown in FIG. 12, first, after the ignition switch (IG) is turned on (step S310), the biofuel concentration in the fuel tank 18 is detected by the bioconcentration sensor 19 (step S320). Note that after the ignition switch (IG) is turned on, normal start control and combustion control are performed in another routine (not shown), but a description thereof is omitted here.

  Next, it is determined whether or not the biofuel concentration detected in step S320 exceeds a concentration L for which oxidation degradation should be considered (step S330). This concentration L is a threshold value obtained in advance by experiments or the like, and can be set in consideration of the fuel temperature by the temperature sensor 95. For example, the value L can be set to 50%.

  If the biofuel concentration exceeds the concentration L (Yes at Step S330), it is then determined whether or not the cooling device 96 is operating (ON) (Step S340).

  If the cooling device 96 is operating (ON) (Yes at Step S340), the refrigerant introduction electromagnetic control valve 98 is opened (Step S350), the refrigerant is circulated in the refrigerant passage P5, and the heat exchanger for fuel cooling. The fuel in the fuel return passage P3 is cooled by heat exchange at 97.

  On the other hand, when the cooling device 96 is not operated (ON) (No at Step S340), the cooling device 96 is operated (ON) (Step S370), and the refrigerant introduction electromagnetic control valve 98 is opened (Step S350). As a result, the fuel is cooled. The operation of the cooling device 96 is performed by a driver's manual switch operation.

  As described above, the fuel extracted from the common rail 12 and the like is cooled and then returned to the fuel tank 18, so that the high temperature of the fuel in the fuel tank 18 can be suppressed and oxidative degradation can be suppressed.

  The fuel cooling control described above is followed as it is once executed while the ignition switch (IG) is ON.

  If the biofuel concentration does not exceed the concentration L (No at Step S330), the refrigerant introduction electromagnetic control valve 98 is closed because there is no possibility of oxidative deterioration (Step S360), and the refrigerant is not circulated into the refrigerant passage P5. That is, the control is finished without cooling.

  As described above, since the fuel cooling (oxidation deterioration suppression control) is performed only when it is necessary to suppress the oxidative deterioration of the fuel, the energy loss of the entire vehicle can be suppressed, which can contribute to the improvement of the fuel consumption.

  In the concentration determination step of the fifth embodiment (see step S330 in FIG. 12), the determination is made with one threshold value L as the biofuel concentration threshold value. However, the present invention is not limited to this, and more detailed concentration conditions (for example, 10 Based on the% concentration condition), control for determining the operating state of the cooling device 96 (step S140) and control for closing the refrigerant introduction electromagnetic control valve 98 (step S360) may be executed. Thereby, further fine control according to the biofuel concentration can be performed.

  In the fifth embodiment, the cooling means cools the fuel in the fuel return passage P3. However, the present invention is not limited to this, and the cooling means is provided in the fuel tank 18 to cool the fuel in the fuel tank 18. The same effect as above can be expected.

  Further, although the cooling device 96 has been described as using a cooling unit (not shown) of an air conditioner mounted on the vehicle, the invention is not limited thereto, and a dedicated fuel cooling device may be provided.

  The refrigerant introduction electromagnetic control valve 98 is configured not to control the refrigerant flow rate to be constant or zero by opening / closing, but to variably control the refrigerant flow rate based on the fuel temperature detected by the temperature sensor 95. May be.

  As a result, the amount of refrigerant required for heat exchange with the fuel can be finely adjusted, which can contribute to a reduction in fuel consumption of the vehicle.

  As described above, the fuel control device for an internal combustion engine according to the present invention is useful for a diesel engine that can use biofuel, and in particular, only when the fuel is susceptible to oxidative deterioration based on the properties of the biofuel. Suitable for diesel engines aiming to suppress deterioration.

It is a schematic block diagram which shows the diesel engine system to which the fuel control apparatus of the internal combustion engine which concerns on Example 1 of this invention is applied. It is a flowchart which shows a control method. It is a map which shows an example of the limit time set according to biofuel concentration. It is a schematic block diagram which shows the diesel engine system to which the fuel control apparatus of the internal combustion engine which concerns on Example 2 of this invention is applied. It is a flowchart which shows a control method. It is a schematic block diagram which shows the diesel engine system to which the fuel control apparatus of the internal combustion engine which concerns on Example 3 of this invention is applied. It is a flowchart which shows a control method. It is explanatory drawing which shows the relationship between soak time and fuel temperature. It is a schematic block diagram which shows the diesel engine system to which the fuel control apparatus of the internal combustion engine which concerns on Example 4 of this invention is applied. It is a flowchart which shows a control method. It is a schematic block diagram which shows the diesel engine system to which the fuel control apparatus of the internal combustion engine which concerns on Example 5 of this invention is applied. It is a flowchart which shows a control method.

Explanation of symbols

1 engine (internal combustion engine)
10 Fuel system 11 Supply pump (fuel system)
11a, 12a Fuel temperature sensor 12 Common rail (fuel system)
14 Shut-off valve 18 Fuel tank (other fuel system)
18b Level sensor 19 Bio concentration sensor (Bio fuel concentration detection means)
77 ECU
78 Display device (notification means)
80a, 80b Electromagnetic relief valve (fuel removal transfer means, valve means)
90 Antioxidant tank (Oxidation degradation inhibitor charging means)
92 Pump (Oxidation degradation inhibitor charging means)
94 Level sensor 95 Temperature sensor 96 Cooling device (cooling means)
97 Heat exchanger for fuel cooling (cooling means)
98 Refrigerant introduction electromagnetic control valve (cooling means)
P0 Main fuel passage P1 Engine fuel passage P2 Addition fuel passage (fuel system)
P3 Fuel return passage (fuel removal transfer means)
P4 Antioxidant passage (Oxidation degradation inhibitor charging means)
P5 Refrigerant passage (cooling means)

Claims (7)

In a fuel control device for an internal combustion engine configured to be able to use fuel including biofuel,
Further comprising biofuel concentration detection means for detecting or estimating the concentration of the biofuel,
A fuel for an internal combustion engine, characterized in that, when the biofuel concentration detected or estimated by the biofuel concentration detection means is greater than or equal to a predetermined value, oxidative deterioration suppression control is performed to suppress oxidative deterioration of the fuel. Control device. Oxidation degradation inhibitor introduction means for introducing an oxidation degradation inhibitor that suppresses the oxidation degradation of the fuel into the fuel;
2. The fuel control device for an internal combustion engine according to claim 1, wherein in the oxidation deterioration suppression control, the oxidation deterioration preventing agent is charged into the fuel by the oxidation deterioration preventing agent charging unit. A fuel extraction and transfer means for extracting the fuel in the fuel system near the internal combustion engine from the fuel system and transferring it to another fuel system installed away from the internal combustion engine;
2. The oxidative degradation suppression control according to claim 1, wherein the fuel is extracted from the fuel system device by the fuel extraction and transfer means during the soak of the internal combustion engine and transferred to the other fuel system device. A fuel control device for an internal combustion engine.   The fuel extraction and transfer means includes a fuel return passage connecting a fuel system device in the vicinity of the internal combustion engine and the other fuel system device, and a valve provided in a route of the fuel return passage for blocking or opening the route. The fuel control device for an internal combustion engine according to claim 3, wherein the fuel control device comprises: A fuel extraction and transfer means for extracting the fuel in the fuel system near the internal combustion engine body from the fuel system and transferring it to another fuel system installed apart from the internal combustion engine;
Cooling means for cooling the fuel in the path of the fuel extraction and transfer means or the fuel transferred to the other fuel system device;
With
The oxidative degradation suppression control is characterized in that the fuel transferred to the fuel or the other fuel system device in the path of the fuel extraction transfer means is cooled by the cooling means during operation of the internal combustion engine. The fuel control device for an internal combustion engine according to claim 1. Informing means for informing a driver of a vehicle equipped with the internal combustion engine of a predetermined warning item,
The oxidative degradation suppression control informs that it is necessary to quickly consume or remove the fuel in use by the informing means, or informs that it is necessary to promptly supply the low-concentration biofuel or standard fuel. The fuel control apparatus for an internal combustion engine according to claim 1, wherein:   In the oxidative degradation suppression control, it is determined that there is a possibility that the oxidative degradation of the fuel may occur when the period during which the fuel is not supplied is equal to or greater than a predetermined value, and the predetermined value is set smaller as the biofuel concentration is higher. The fuel control device for an internal combustion engine according to any one of claims 1 to 6, wherein:

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