JP2015161266A - Abnormality diagnosis device of fuel supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an abnormality diagnosis device of a fuel supply device which can easily suppress an operation failure of a jet pump for sending fuel to a first fuel tank from a second fuel tank.SOLUTION: When a liquid level rise rate ΔLB of a second fuel tank 202 exceeds a preset first determination value ΔLBx during an operation of an engine, an electronic control device determines that there occurs an abnormality in a fuel flow of return fuel to the second fuel tank 202. Then, when a fuel flow rate sent by a jet pump 28 to a first fuel tank 201 from the second fuel tank 202 is decreased, the liquid level rise rate ΔLB of the second fuel tank 202 becomes large. Accordingly, measures for suppressing an operation failure of the jet pump which operates by utilizing the fuel flow of the return fuel can be properly taken on the basis of determination that the abnormality has occurred. That is, as a determination result of the electronic control device, in other words, by utilizing a determination result of a step S104, the operation failure of the jet pump 28 can be easily suppressed.

Description

  The present invention relates to an abnormality diagnosis device that diagnoses an abnormality in a fuel supply device that supplies fuel to an injector of an engine.

  2. Description of the Related Art Conventionally, a fuel supply apparatus having two fuel tanks for storing fuel, that is, a fuel tank composed of a first fuel tank and a second fuel tank is known. For example, the fuel supply device of Patent Document 1 has a vertical fuel tank composed of a first fuel tank and a second fuel tank. In the fuel supply device of Patent Document 1, the fuel pumped up from the first fuel tank is supplied to the injector of the engine. The fuel accumulated in the second fuel tank is pumped up by a jet pump and sent to the first fuel tank.

JP 2012-77731 A

  In a fuel supply apparatus having a first fuel tank and a second fuel tank, such as the fuel supply apparatus of Patent Document 1, the fuel accumulated in the second fuel tank is transferred to the first fuel tank by a jet pump. Here, the jet pump is a pump that is operated using a predetermined fuel flow. However, the fuel pump returns from the injector side to the second fuel tank, for example, a supply pump for pressurizing the injector and the fuel supplied to the injector. There is a fuel supply device that uses the fuel flow returned from the fuel to the second fuel tank as a fuel flow for operating the jet pump.

  In such a fuel supply device, if the flow rate of the fuel returning to the second fuel tank is lower than the lower limit flow rate required for the operation of the jet pump, a malfunction of the jet pump or the like occurs. The fuel sent from the two fuel tanks to the first fuel tank is insufficient. In this case, although there is fuel in the second fuel tank, there is a possibility that the fuel supplied from the first fuel tank to the injector is insufficient, and drivability is deteriorated due to fuel ejection failure in the injector.

  The present invention has been made in view of the above points, and an object thereof is to provide an abnormality diagnosis device for a fuel supply device that facilitates suppressing malfunction of a jet pump that sends fuel from a second fuel tank to a first fuel tank.

In order to achieve the above object, according to the first aspect of the present invention, an accumulator (14) that stores high-pressure fuel supplied to an injector (12) that injects fuel into a combustion chamber of an engine, and a fuel to the accumulator. A supply pump (16) for supplying pressurized fuel, a first fuel tank (201) for storing fuel, a second fuel tank (202) for storing fuel, and supplying fuel stored in the first fuel tank to the supply pump A feed pump (22), a supply pump, a pressure accumulator, and a low pressure return flow path (26) for returning low pressure fuel from the injector to the second fuel tank, and a low pressure return flow path through the first An abnormality for diagnosing an abnormality in the fuel supply device (10) including a jet pump (28) for sending fuel accumulated in the second fuel tank to the first fuel tank using the fuel flow of the return fuel flowing to the two fuel tanks Diagnostic equipment There is,
When the increase amount of fuel accumulated in the second fuel tank per unit time exceeds a predetermined first determination value during engine operation, it is determined that there is an abnormality in the fuel flow of the return fuel. An abnormality determining means (S102, S103, S104) is provided.

  According to the above-described invention, the abnormality determination means is configured to increase the amount of fuel accumulated in the second fuel tank per unit time when a predetermined first determination value is exceeded during engine operation. Then, it is determined that there is an abnormality in the fuel flow of the return fuel. When the flow rate of fuel sent from the second fuel tank to the first fuel tank decreases by the jet pump, the increase amount increases. Therefore, a measure for suppressing the malfunction of the jet pump that operates using the fuel flow of the return fuel can be appropriately implemented based on the determination that the fuel flow is abnormal. That is, it becomes easy to suppress the malfunction of the jet pump by using the determination result of the abnormality determination means.

  In addition, the code | symbol in the bracket | parenthesis of each means described in the claim and this column is an example which shows a corresponding relationship with the specific means as described in embodiment mentioned later.

1 is a block diagram illustrating a schematic configuration of a fuel supply device 10 according to a first embodiment. It is a flowchart which shows the control processing of the electronic controller 38 of 1st Embodiment. 5 is a time chart for explaining the first embodiment, and is a time chart showing a second fuel tank liquid level LB and a liquid level increase rate ΔLB of the second fuel tank 202. FIG. 6 is a time chart for explaining a modification of the first embodiment, and is a time chart showing a first fuel tank liquid level LA and a liquid level reduction rate ΔLA of the first fuel tank 201. FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, the same or equivalent parts are denoted by the same reference numerals in the drawings.

(First embodiment)
FIG. 1 is a block diagram showing a schematic configuration of a fuel supply apparatus 10 in the present embodiment. The fuel supply device 10 is used in a diesel engine that is an internal combustion engine, and supplies high-pressure fuel to an injector 12 included in the diesel engine.

  As shown in FIG. 1, the fuel supply device 10 includes a common rail 14 as a pressure accumulator, a supply pump 16, a relief valve 18, a fuel tank 20, a feed pump 22, a fuel supply pipe 24, a fuel return pipe 26, a jet pump 28, A pressure control valve 30, a fuel pressure sensor 32, a first level gauge 34, a second level gauge 36, an electronic control device 38, and the like are provided. An arrow DR1 in FIG. 1 indicates the vertical direction DR1 of the fuel tank 20.

  The injector 12 is a fuel injection device that injects high-pressure fuel into the combustion chamber of a diesel engine. The injector 12 is supplied with high-pressure fuel from the common rail 14. The injector 12 is connected to an electronic control unit 38, and the fuel injection timing and injection amount are controlled by a control signal from a fuel injection control unit included in the electronic control unit 38.

  The common rail 14 is a pressure accumulator that stores the fuel pressure of the high-pressure fuel supplied from the supply pump 16, that is, the rail pressure while maintaining the target rail pressure. The target rail pressure is determined by the electronic control unit 38 based on, for example, the operation state of the diesel engine such as the accelerator opening and the engine speed detected by a sensor (not shown).

  The supply pump 16 is a high pressure pump that pressurizes and supplies fuel to the common rail 14. Fuel is supplied to the supply pump 16 from the feed pump 22 through the fuel supply pipe 24. In FIG. 1, the supply pump 16 is indicated as S / P (supply pump).

  The relief valve 18 is a pressure reducing device that reduces the rail pressure, which is the fuel pressure in the common rail 14, and is provided on the common rail 14. The relief valve 18 is controlled to be opened and closed by an electronic control unit 38, and a relief passage 181 that is a fuel discharge passage of the relief valve 18 is connected to the fuel tank 20 via a fuel return pipe 26. In FIG. 1, the relief valve 18 is indicated as PRV (pressure relief valve).

  When the relief valve 18 is opened, the fuel in the common rail 14 is returned to the fuel tank 20, whereby the rail pressure in the common rail 14 is reduced. On the other hand, the electronic control unit 38 can increase the rail pressure by driving the supply pump 16. Accordingly, the supply pump 16 and the relief valve 18 function as a rail pressure adjusting device that adjusts the rail pressure in the common rail 14, and the electronic control unit 38 supplies the supply voltage so that the rail pressure matches a predetermined target rail pressure. The pump 16 and the relief valve 18 are controlled.

  The fuel tank 20 is a vertical fuel tank including a first fuel tank 201 and a second fuel tank 202 that store fuel. Specifically, the first fuel tank 201 and the second fuel tank 202 are separated from each other on the bottom side of the fuel tank 20, and the first fuel tank 201 and the second fuel tank 202 are separated on the upper side of the fuel tank 20. They are connected horizontally. Accordingly, when the fuel is in the fuel tank 20 above the tank bottom surface 204a in the connecting portion 204 between the first fuel tank 201 and the second fuel tank 202, the fuel level LA in the first fuel tank 201 is obtained. And the fuel liquid level LB in the second fuel tank 202 are the same.

  The feed pump 22 is provided in the first fuel tank 201, and the feed pump 22 is connected to the supply pump 16 through a fuel supply pipe 24. The feed pump 22 pumps up fuel accumulated in the first fuel tank 201 during operation of the diesel engine, and supplies the fuel to the supply pump 16 via the fuel supply pipe 24. At this time, in order to prevent fuel shortage in the injector 12, the feed pump 22 is operated so that the flow rate of the fuel supplied to the supply pump 16 exceeds the flow rate of the fuel supplied from the supply pump 16 to the common rail 14. .

  The fuel return pipe 26 constitutes a low pressure return flow path for returning the low pressure fuel discharged from the injector 12, the supply pump 16, the relief valve 18, and the pressure control valve 30 to the second fuel tank 202. For example, of the fuel that the supply pump 16 draws from the fuel supply pipe 24, the surplus fuel surplus with respect to the fuel supplied from the supply pump 16 to the common rail 14 is the pump return flow path provided in the supply pump 16. The fuel flows out from 161 to the fuel return pipe 26.

  The jet pump 28 transfers the fuel accumulated in the second fuel tank 202 to the first fuel tank 201 using the fuel flow of the return fuel flowing to the second fuel tank 202 through the fuel return pipe 26. At this time, the jet pump 28 transfers fuel from the second fuel tank 202 to the first fuel tank 201 through a transfer pipe 203 provided in the fuel tank 20 and connected to the jet pump 28.

  Specifically, the jet pump 28 has a nozzle portion, generates a negative pressure by a high-speed flow of fluid ejected from the nozzle portion, and sucks a fluid in another path by the negative pressure. It is a pump. In this embodiment, the return fuel from the fuel return pipe 26 flows into the jet pump 28 and is accumulated in the second fuel tank 202 due to the negative pressure generated when the fuel flow of the return fuel passes through the nozzle portion. The fuel is sucked. The sucked fuel flows into the first fuel tank 201 through the transfer pipe 203.

  Since the jet pump 28 has such a configuration, in order to suck the fuel accumulated in the second fuel tank 202, the flow rate of the return fuel is required to be higher than a certain level. That is, the flow rate of the return fuel that is equal to or higher than the pump operation lower limit value determined in advance from the structure of the jet pump 28 is necessary. In other words, for the normal operation of the jet pump 28, the flow rate of the return fuel is It must be maintained so that it does not fall below the lower limit. And since the source of the return fuel is the fuel pumped up from the first fuel tank 201 by the feed pump 22, the electronic control unit 38 ensures that the flow rate of the return fuel above the pump operation lower limit value is ensured. The target discharge flow rate of 22 is determined, and the feed pump 22 is operated so that the discharge flow rate of the determined target discharge flow rate is obtained.

  The pressure control valve 30 is a pressure control device that adjusts the fuel pressure flowing into the supply pump 16 from the fuel supply pipe 24. The pressure control valve 30 is connected to a fuel supply pipe 24 that forms a fuel flow path between the feed pump 22 and the supply pump 16. Specifically, the pressure control valve 30 is connected to the fuel inlet of the supply pump 16 into which the fuel sent from the feed pump 22 flows. In FIG. 1, the pressure control valve 30 is indicated as RGV (regulating valve).

  Further, the pressure control valve 30 includes a discharge passage 301 connected to the fuel return pipe 26, and discharges fuel from the fuel supply pipe 24 to the fuel return pipe 26, thereby fuel pressure at the fuel inlet of the supply pump 16. The pressure is reduced. For example, the pressure control valve 30 operates to maintain the fuel pressure at the fuel inlet of the supply pump 16 at a predetermined target feed pressure. Specifically, the pressure control valve 30 opens the discharge passage 301 when the fuel pressure at the fuel inlet exceeds the target feed pressure, and flows the fuel from the fuel inlet of the supply pump 16 to the discharge passage 301. The fuel pressure at the fuel inlet is controlled to the target feed pressure. Therefore, the pressure control valve 30 greatly reduces the pressure of the fuel flowing through the fuel supply pipe 24 as the flow rate of the fuel flowing through the discharge passage 301 to the fuel return pipe 26 is increased. That is, the fuel flowing from the feed pump 22 to the fuel inlet of the supply pump 16 is greatly decompressed.

  The fuel pressure sensor 32 is provided in the fuel supply pipe 24. The fuel pressure sensor 32 is a pressure detection device that detects the pressure of fuel flowing from the feed pump 22 to the supply pump 16, and sequentially outputs detection signals indicating the fuel pressure to the electronic control device 38.

  The first level gauge 34 is a liquid level sensor that is provided in the first fuel tank 201 and detects the liquid level of the fuel accumulated in the first fuel tank 201. That is, it is a remaining amount detection device that detects the remaining amount of fuel accumulated in the first fuel tank 201. The first level gauge 34 sequentially outputs detection signals indicating the liquid level in the first fuel tank 201 to the electronic control unit 38.

  The second level gauge 36 is a sensor similar to the first level gauge 34 and is a liquid level sensor that detects the liquid level of the fuel accumulated in the second fuel tank 202. That is, the remaining amount detection device detects the remaining amount of fuel accumulated in the second fuel tank 202. The second level gauge 36 is provided in the second fuel tank 202. The second level gauge 36 sequentially outputs detection signals indicating the liquid level in the second fuel tank 202 to the electronic control unit 38.

  The electronic control unit 38 is composed of a well-known microcomputer comprising a CPU, ROM, RAM, etc. and its peripheral circuits, and executes various control processes in accordance with a computer program stored in advance in the ROM. Further, the electronic control unit 38 outputs control signals to the injector 12, the supply pump 16, the relief valve 18, and the feed pump 22 to control their operations. For example, the electronic control unit 38 has a function as an abnormality diagnosing device for diagnosing an abnormality in the fuel supply device 10 and periodically executes the control process shown in the flowchart of FIG. 2 while the diesel engine is operating. To do.

  FIG. 2 is a flowchart showing a control process of the electronic control device 38 of the present embodiment. First, in step S101 of FIG. 2 (hereinafter, “step” is omitted), the electronic control unit 38 receives the detection signal of the first level gauge 34 and the fuel liquid accumulated in the first fuel tank 201. The first fuel tank liquid level LA which is the position is acquired. Then, the first fuel tank liquid level LA which is the output value of the first level gauge 34 is stored together with the detection time of the liquid level. At the same time, the detection signal of the second level gauge 36 is received, and the second fuel tank liquid level LB that is the liquid level of the fuel accumulated in the second fuel tank 202 is acquired. Then, the second fuel tank liquid level LB which is the output value of the second level gauge 36 is stored together with the detection time of the liquid level LB. After S101, the process proceeds to S102.

  In S102, an abnormality existence determination is performed to determine whether or not there is an abnormality in the fuel flow of the return fuel that returns to the second fuel tank 202. Specifically, whether the return fuel is insufficient in operating the jet pump 28 is determined as the fuel flow abnormality, and the presence or absence of the abnormality is determined.

  More specifically, in S102, first, the liquid in the second fuel tank 202, which is the amount of increase in the second fuel tank liquid level LB per unit time, based on the second fuel tank liquid level LB stored in S101. The position increase rate ΔLB is calculated. Since the remaining amount of fuel in the second fuel tank 202 is calculated by multiplying the second fuel tank liquid level LB by a constant bottom area in the second fuel tank 202, the liquid level increase rate ΔLB of the second fuel tank 202 is calculated. Corresponds to a fuel increase rate which is an increase amount per unit time of fuel accumulated in the second fuel tank 202.

  For example, the second fuel tank liquid level LB is detected every predetermined sampling time. As shown in FIG. 3 described later, if the second fuel tank liquid level LB after the sampling time TIMEs elapses is LB2, and the second fuel tank liquid level LB before the sampling time TIMEs elapses is LB1, the second fuel tank The liquid level increase rate ΔLB of 202 can be calculated by the following equation (1). Accordingly, the liquid level increase rate ΔLB is a value in which the direction in which the remaining amount of fuel increases in the second fuel tank 202, that is, the direction in which the second fuel tank liquid level LB increases is positive.

ΔLB = (LB2−LB1) / TIMEs (1)
In S102, when the liquid level increase rate ΔLB of the second fuel tank 202 is calculated, the liquid level increase rate ΔLB is compared with a preset first determination value ΔLBx, as shown in the following formula (2). It is determined whether or not the liquid level increase rate ΔLB exceeds the first determination value ΔLBx. The first determination value ΔLBx is a threshold for the liquid level increase rate ΔLB of the second fuel tank 202, and is set to a positive value, for example. Further, when the return fuel returning to the second fuel tank 202 becomes insufficient in operating the jet pump 28, the fuel returns to the second fuel tank 202, but the fuel is transferred from the second fuel tank 202 to the first fuel tank 201. Since the second fuel tank liquid level LB rises, the first determination value ΔLBx is experimentally determined in advance so that the flow rate shortage can be determined.

ΔLB> ΔLBx (2)
In S102, when the liquid level increase rate ΔLB exceeds the first determination value ΔLBx, it is determined that there is an abnormality in the fuel flow of the return fuel, and the process proceeds to S104. On the other hand, if the liquid level increase rate ΔLB is equal to or less than the first determination value ΔLBx, it is determined that there is no abnormality in the fuel flow of the return fuel, and the process proceeds to S103.

  Here, with reference to FIG. 3 which is a time chart showing the second fuel tank liquid level LB and the liquid level increase rate ΔLB of the second fuel tank 202, the second when the abnormality occurs in the fuel flow of the return fuel. Changes in the fuel tank liquid level LB and the liquid level increase rate ΔLB will be described. FIG. 3 is a time chart when the first fuel tank liquid level LA and the second fuel tank liquid level LB are both lower than the tank bottom surface 204 a (see FIG. 1) of the connecting portion 204 in the fuel tank 20.

  In FIG. 3, an abnormality has occurred in the fuel flow of the return fuel at time tb1. That is, from the time point tb1, the pumping of fuel from the second fuel tank 202 by the jet pump 28 is delayed due to the insufficient flow rate in the fuel flow. Therefore, the fuel return from the fuel return pipe 26 is superior to the fuel pumped out from the second fuel tank 202, and the liquid level increase rate ΔLB of the second fuel tank 202 is increased from the time point tb1. At time tb1, the liquid level increase rate ΔLB exceeds the first determination value ΔLBx.

  Returning to FIG. 2, in S103, a determination is made that there is no abnormality in the fuel flow of the return fuel to the second fuel tank 202, that is, a determination that the fuel flow is normal. Therefore, in S103, the electronic control unit 38 does not take any special action, and the control process from S101 is executed again.

  In S104, it is determined that there is an abnormality in the fuel flow of the return fuel. After S104, the process proceeds to S105.

  In S105, an abnormality type determination is performed to determine the details of the abnormality in the fuel flow of the return fuel that returns to the second fuel tank 202. Here, as the types of the abnormality, specifically, the fuel leakage in the return side fuel flow path where the fuel returns from the fuel supply destination of the feed pump 22, that is, the fuel leakage of the fuel return pipe 26, the failure of the pressure control valve 30, Is assumed. For this reason, in S105, it is determined whether or not a fuel leak in the fuel return pipe 26 has occurred. The failure of the pressure control valve 30 means that the discharge flow path 301 of the pressure control valve 30 is difficult to open and the fuel does not easily flow from the fuel supply pipe 24 to the discharge flow path 301.

  Specifically, during operation of the diesel engine, fuel is consumed by the engine, so the fuel in the fuel tank 20 is reduced. Therefore, in S105, first, the tank total remaining amount Qt, which is the sum of the remaining amount of fuel stored in the first fuel tank 201 and the remaining amount of fuel stored in the second fuel tank 202, is set to a value before the elapse of a predetermined time. It calculates about each after progress. The predetermined time is specifically the above sampling time TIMEs.

  For example, if the tank total remaining amount Qt before the sampling time TIMEs elapses is Q1t, the Q1t is calculated by the following equation (3). If the tank total remaining amount Qt after the sampling time TIMEs elapses is Q2t, the Q2t is Calculated by equation (4).

Q1t = LA1 × ARA + LB1 × ARB (3)
Q2t = LA2 × ARA + LB2 × ARB (4)
In the above formulas (3) and (4), LA1 is the first fuel tank liquid level LA before the sampling time TIMEs elapses, ARA is the bottom area in the tank of the first fuel tank 201, and LB1 is the sampling time TIMEs before the elapse of the sampling time TIMEs. The second fuel tank liquid levels LB and ARB are the bottom area in the tank of the second fuel tank 202, LA2 is the first fuel tank liquid level LA after the sampling time TIMEs has elapsed, and LB2 is the second fuel tank after the sampling time TIMEs has elapsed. Each of the liquid levels LB is shown.

  Next, the decrease amount ΔQt of the tank total remaining amount Qt within the period when the sampling time TIMEs elapses is calculated by the following equation (5).

ΔQt = Q1t−Q2t (5)
Then, when the reduction amount ΔQt is calculated, the fuel consumption amount Qcn consumed by the injection of the injector 12 is acquired within the period in which the fuel reduction of the reduction amount ΔQt occurs, that is, within the period when the sampling time TIMEs elapses. Then, the fuel consumption amount Qcn is compared with the decrease amount ΔQt, and thereby, it is determined whether or not the fuel leakage of the fuel return pipe 26 has occurred. That is, as a result of the comparison, when the decrease amount ΔQt of the tank total remaining amount Qt exceeds the fuel consumption amount Qcn, in short, when the following equation (6) is satisfied, the fuel leakage of the fuel return pipe 26 It is determined that it has occurred. On the contrary, when the following formula (6) is not established, it is determined that a failure of the pressure control valve 30 which is another type of fuel flow abnormality has occurred. The fuel consumption amount Qcn is acquired from, for example, a fuel injection control unit that controls fuel injection of the injector 12.

ΔQt> Qcn (6)
If it is determined in S105 that fuel leakage from the fuel return pipe 26 has occurred, the process proceeds to S106. On the other hand, if it is determined that a failure of the pressure control valve 30 has occurred, the process proceeds to S108.

  In S106, in the determination by the self-diagnosis, that is, the diagnosis determination, it is determined that the fuel leakage from the fuel return pipe 26 has occurred. For example, in this diagnosis determination, the electronic control unit 38 turns on a warning lamp indicating that fuel leakage has occurred in the fuel return pipe 26. The warning light is provided on an instrument panel or the like so that an occupant can visually recognize, for example. After S106, the process proceeds to S107.

  In S107, the fuel discharge pressure of the feed pump 22 corresponds to the fuel leakage of the fuel return pipe 26 so that the return fuel to the second fuel tank 202 is prevented from being insufficient when the jet pump 28 is operated. And adjust.

  Specifically, in S107, compared to the case where the fuel flow of the return fuel to the second fuel tank 202 is normal, that is, the case where it is determined in S102 that there is no abnormality in the fuel flow of the return fuel, the feed pump The rotational speed of 22 is increased, and thereby the pressure of the fuel discharged from the feed pump 22 is increased. At this time, the increase range of the fuel pressure with respect to the normal time of the fuel flow is experimentally determined in advance under the condition that the abnormality of the fuel flow of the return fuel is due to the fuel leakage of the fuel return pipe 26.

  In S108, in the determination by the self-diagnosis, that is, the diagnosis determination, it is determined that a failure of the pressure control valve 30 has occurred. For example, in this diagnosis determination, the electronic control unit 38 turns on a warning lamp indicating the occurrence of a failure of the pressure control valve 30. The warning light is provided on an instrument panel or the like so that an occupant can visually recognize, for example. After S108, the process proceeds to S109.

  In S109, the fuel discharge pressure of the feed pump 22 is adjusted to correspond to the failure of the pressure control valve 30 so that the return fuel to the second fuel tank 202 is suppressed from becoming insufficient when the jet pump 28 is operated. Adjust.

  Specifically, in S109, compared to the case where the fuel flow of the return fuel to the second fuel tank 202 is normal, that is, the case where it is determined in S102 that there is no abnormality in the fuel flow of the return fuel, the feed pump The rotational speed of 22 is increased, and thereby the pressure of the fuel discharged from the feed pump 22 is increased. At this time, the increase in the fuel pressure with respect to the normal fuel flow is experimentally determined in advance under the condition that the abnormality in the fuel flow of the return fuel is due to the failure of the pressure control valve 30. In S107 or S109, this flowchart is ended, and the control process from S101 is executed again.

  Note that the processing in each step of FIG. 2 described above constitutes a means for realizing each function. For example, S102, S103, and S104 in FIG. 2 correspond to abnormality determination means, S105 corresponds to abnormality type determination means, and S107 and S109 correspond to pressure increase means.

  As described above, according to the present embodiment, as shown in S102 to S104 of FIG. 2, the electronic control unit 38 determines that the liquid level increase rate ΔLB of the second fuel tank 202 is predetermined during the operation of the engine. When the determined first determination value ΔLBx is exceeded, it is determined that there is an abnormality in the fuel flow of the return fuel to the second fuel tank 202. When the fuel flow rate that the jet pump 28 sends from the second fuel tank 202 to the first fuel tank 201 decreases, the liquid level increase rate ΔLB of the second fuel tank 202 increases. Therefore, a measure for suppressing the malfunction of the jet pump that operates using the fuel flow of the return fuel can be appropriately implemented based on the determination that the abnormality is present. That is, the malfunction of the jet pump 28 can be easily suppressed by using the determination result of the electronic control unit 38, that is, the determination result of S104 in FIG.

  Further, according to the present embodiment, the electronic control unit 38 determines that the return fuel to the second fuel tank 202 is insufficient in flow rate for operating the jet pump 28 as an abnormality in the fuel flow of the return fuel. Determine if there is an abnormality in the fuel flow. Therefore, it is possible to detect a malfunction of the jet pump 28 based on the determination.

  Further, according to the present embodiment, the electronic control unit 38 determines that the reduction amount ΔQt of the tank total remaining amount Qt is the fuel consumption amount Qcn consumed by the injection of the injector 12 within the period in which the fuel reduction of the reduction amount ΔQt occurs. Is exceeded, it is determined that a fuel leak has occurred in the fuel return pipe 26. Accordingly, a measure corresponding to the abnormal content of the fuel leak in the fuel return pipe 26 can be appropriately implemented based on the determination that the fuel leak has occurred.

  Further, according to the present embodiment, the electronic control unit 38 determines that the reduction amount ΔQt of the tank total remaining amount Qt is the fuel consumption amount Qcn consumed by the injection of the injector 12 within the period in which the fuel reduction of the reduction amount ΔQt occurs. If it does not exceed, it is determined that the pressure control valve 30 has failed. Therefore, a measure corresponding to the abnormal content such as failure of the pressure control valve 30 can be appropriately implemented based on the determination that the pressure control valve 30 is defective.

  Further, according to the present embodiment, when the electronic control unit 38 determines in S102 of FIG. 2 that there is an abnormality in the fuel flow of the return fuel that returns to the second fuel tank 202, in S107 or S109. The pressure of the fuel discharged from the feed pump 22 is increased. As a result, the flow rate of the fuel flowing from the fuel supply pipe 24 through the discharge passage 301 to the fuel return pipe 26 is increased, and the malfunction of the jet pump 28 due to the lack of the flow power of the return fuel can be suppressed. The shortage of the remaining fuel in the first fuel tank 201 can be suppressed. And the deterioration of the drivability by the fuel discharge defect in the injector 12 can be suppressed.

  Further, according to the present embodiment, the warning light indicating the occurrence of fuel leakage in the fuel return pipe 26 is turned on in the diagnosis determination of S106, and the warning light indicating the occurrence of the failure of the pressure control valve 30 is turned on in the diagnosis determination of S108. Therefore, it is possible to prompt the user to take measures against abnormal fuel flow of the return fuel to the second fuel tank 202.

(Second Embodiment)
Next, a second embodiment of the present invention will be described. In the present embodiment, differences from the first embodiment will be mainly described, and the same or equivalent parts as those in the first embodiment will be omitted or simplified.

  In the present embodiment, the contents of S105 in FIG. 2 are different from those in the first embodiment. Specifically, in S105 of the present embodiment, instead of comparing the decrease amount ΔQt of the tank total remaining amount Qt with the fuel consumption amount Qcn, the fuel pressure detected by the fuel pressure sensor 32, that is, the suction of the supply pump 16 The above abnormality type determination is performed based on the mouth pressure.

  More specifically, when a failure occurs in the pressure control valve 30 such that the discharge flow path 301 of the pressure control valve 30 is difficult to open, the fuel in the fuel supply pipe 24 is less likely to be depressurized. As a result, the fuel pressure in the fuel supply pipe 24 increases. Therefore, in S105 of FIG. 2, the fuel pressure detected by the fuel pressure sensor 32 is acquired. Then, it is determined whether or not the fuel pressure exceeds a predetermined pressure threshold. The pressure threshold is experimentally set in advance so that a failure of the pressure control valve 30 can be determined.

  As a result of the determination, when the fuel pressure detected by the fuel pressure sensor 32 exceeds the pressure threshold, it is determined that a failure of the pressure control valve 30 has occurred. On the contrary, when the fuel pressure is equal to or lower than the pressure threshold, it is determined that the fuel return pipe 26 has a fuel leak.

  If it is determined in S105 that fuel leakage from the fuel return pipe 26 has occurred, the process proceeds to S106. On the other hand, if it is determined that a failure of the pressure control valve 30 has occurred, the process proceeds to S108.

  As described above, according to the present embodiment, when the fuel pressure detected by the fuel pressure sensor 32 exceeds the pressure threshold, the electronic control device 38 has failed in the pressure control valve 30. Therefore, the measure corresponding to the abnormal content of the failure of the pressure control valve 30 can be appropriately implemented based on the determination of the failure of the pressure control valve 30.

  Further, according to the present embodiment, the electronic control unit 38 determines that a fuel leak has occurred in the fuel return pipe 26 when the fuel pressure detected by the fuel pressure sensor 32 is equal to or lower than the pressure threshold. Therefore, a measure corresponding to the abnormal content of the fuel leak in the fuel return pipe 26 can be appropriately implemented based on the determination that the fuel leak has occurred.

(Other embodiments)
[1] In each of the above-described embodiments, when the liquid level increase rate ΔLB calculated by the above equation (1) exceeds the first determination value ΔLBx in S102 of FIG. 2, the process returns to the second fuel tank 202. Although it is determined that there is an abnormality in the fuel flow of the return fuel, the presence or absence of the abnormality may be determined by adding conditions other than the liquid level increase rate ΔLB. If other conditions are added and the presence / absence of the abnormality is determined, the determination can be made with higher accuracy than when no other conditions are added.

  For example, the presence / absence of the abnormality may be determined by adding a condition based on the liquid level reduction rate ΔLA of the first fuel tank 201, which is a reduction amount per unit time of the first fuel tank liquid level LA. If so, in S102, the liquid level increase rate ΔLB exceeds the first determination value ΔLBx, and the liquid level decrease rate ΔLA of the first fuel tank 201 is predetermined as shown in the following equation (7). When the second determination value ΔLAx is exceeded, it is determined that the fuel flow is abnormal. The liquid level reduction rate ΔLA of the first fuel tank 201 is calculated by multiplying the bottom area in the first fuel tank 201 in which the remaining amount of fuel in the first fuel tank 201 is constant to the first fuel tank liquid level LA. Therefore, this corresponds to a fuel reduction rate that is a reduction amount of fuel accumulated in the first fuel tank 201 per unit time.

ΔLA> ΔLAx (7)
Similarly to the second fuel tank liquid level LB, the first fuel tank liquid level LA is also detected every predetermined sampling time, so that the liquid level decrease rate ΔLA of the first fuel tank 201 is as shown in FIG. If the first fuel tank liquid level LA after the sampling time TIMEs elapses is LA2, and the first fuel tank liquid level LA before the sampling time TIMEs elapses is LA1, it can be calculated by the following equation (8). Therefore, the liquid level decrease rate ΔLA is a value in which the direction in which the remaining amount of fuel decreases in the first fuel tank 201, that is, the direction in which the first fuel tank liquid level LA decreases is positive.

ΔLA = (LA1-LA2) / TIMEs (8)
The second determination value ΔLAx is a threshold for the liquid level reduction rate ΔLA of the first fuel tank 201, and is set to a positive value, for example. Then, when the return fuel returning to the second fuel tank 202 becomes insufficient in operating the jet pump 28, the fuel transfer from the second fuel tank 202 to the first fuel tank 201 is delayed and the level of the first fuel tank liquid level LA is decreased. Since the decrease is promoted, the second determination value ΔLAx is experimentally determined in advance so that the flow rate shortage can be determined and the fuel consumption by the injector 12 is not determined as the abnormality.

  Here, with reference to FIG. 4 which is a time chart showing the first fuel tank liquid level LA and the liquid level reduction rate ΔLA of the first fuel tank 201, the first time when an abnormality occurs in the fuel flow of the return fuel. Changes in the fuel tank liquid level LA and the liquid level decrease rate ΔLA will be described. FIG. 4 is a time chart when the first fuel tank liquid level LA and the second fuel tank liquid level LB are both lower than the tank bottom surface 204 a (see FIG. 1) of the connecting portion 204 in the fuel tank 20.

  In FIG. 4, an abnormality has occurred in the fuel flow of the return fuel at the time point ta1. That is, from the time point ta1, the pumping of fuel from the second fuel tank 202 by the jet pump 28 is delayed due to the insufficient flow rate of the fuel flow. Therefore, the fuel supply from the second fuel tank 202 to the first fuel tank 201 decreases, and the liquid level reduction rate ΔLA of the first fuel tank 201 increases from the time ta1. At the time point ta1, the liquid level reduction rate ΔLA exceeds the second determination value ΔLAx. That is, in the illustration of the time chart of FIG. 4, at the time point ta1, the liquid level reduction rate ΔLA changes downward with the second determination value ΔLAx interposed therebetween.

  In S102 of FIG. 2, the presence or absence of the abnormality may be determined by adding a condition based on the first fuel tank liquid level LA as a condition other than the liquid level increase rate ΔLB. If so, in S102, a third determination in which the liquid level increase rate ΔLB exceeds the first determination value ΔLBx and the first fuel tank liquid level LA is predetermined as shown in the following equation (9). When it becomes less than the value LAx, it is determined that the fuel flow is abnormal. By multiplying the first fuel tank liquid level LA by the bottom area in the first fuel tank 201, the remaining amount of fuel accumulated in the first fuel tank 201, that is, the remaining fuel amount in the first fuel tank 201 can be calculated. The first fuel tank liquid level LA corresponds to the remaining amount of fuel in the first fuel tank 201.

LA <LAx (9)
Note that the first fuel tank liquid level LA is used to determine the abnormality of the fuel flow of the return fuel when the fuel transfer from the second fuel tank 202 to the first fuel tank 201 by the jet pump 28 is delayed. This is because the lowering of the position LA is promoted. The third determination value LAx is experimentally determined in advance so that it can be determined that the return fuel returning to the second fuel tank 202 has an insufficient flow rate for operating the jet pump 28. In the time chart of FIG. 4, the first fuel tank liquid level LA is less than the third determination value LAx at the time point ta2.

  Moreover, in S102 of FIG. 2, the presence or absence of the abnormality may be determined by adding a condition based on the second fuel tank liquid level LB as a condition other than the liquid level increase rate ΔLB. If so, in S102, the liquid level increase rate ΔLB exceeds the first determination value ΔLBx, and the second fuel tank liquid level LB is predetermined as shown in the following equation (10). When the value LBx is exceeded, it is determined that the fuel flow is abnormal. By multiplying the second fuel tank liquid level LB by the bottom area in the second fuel tank 202, the remaining amount of fuel stored in the second fuel tank 202, that is, the remaining fuel amount in the second fuel tank 202 can be calculated. The second fuel tank liquid level LB corresponds to the remaining amount of fuel in the second fuel tank 202.

LB> LBx (10)
It should be noted that the second fuel tank liquid level LB is used for determining the return fuel fuel flow abnormality when the fuel transfer by the jet pump 28 from the second fuel tank 202 to the first fuel tank 201 is delayed. This is because the return of fuel from the fuel return pipe 26 is superior to the pumping of fuel from 202, and the second fuel tank liquid level LB rises. The fourth determination value LBx is experimentally determined in advance so that it can be determined that the return fuel returning to the second fuel tank 202 has an insufficient flow rate for operating the jet pump 28. In the time chart of FIG. 3, the second fuel tank liquid level LB exceeds the fourth determination value LBx at time tb2.

  As described above, in any of the three exemplified modifications, as in the first or second embodiment, if it is determined in S102 in the flowchart of FIG. 2 that there is an abnormality in the fuel flow of the return fuel, the process proceeds to S104. If it is determined that there is no, the process proceeds to S103. In addition to the above three modifications, in addition to the above formula (2), any two or more of the above formulas (7), (9), and (10) are met. When it is done, it may be determined that the abnormality is present.

  [2] In each of the above-described embodiments, the internal combustion engine in which the fuel supply apparatus 10 is used is a diesel engine, but may be another type of internal combustion engine such as a gasoline engine.

  [3] In each of the above-described embodiments, the first fuel tank 201 and the second fuel tank 202 are connected to each other to form a vertical fuel tank 20, but the first fuel tank 201 and the second fuel tank 202 are The fuel tanks may be separated from each other to constitute separate fuel tanks.

  [4] In each of the embodiments described above, the fuel return pipe 26 is a flow path that returns the low-pressure fuel discharged from the injector 12, the supply pump 16, the relief valve 18, and the pressure control valve 30 to the second fuel tank 202. However, it is not necessary to be connected to all of the devices 12, 16, 18, and 30, and it may be connected to any of the devices 12, 16, 18, and 30.

  In addition, this invention is not limited to above-described embodiment, In the range described in the claim, it can change suitably. In each of the above-described embodiments, it is needless to say that elements constituting the embodiment are not necessarily essential unless explicitly stated as essential and clearly considered essential in principle. Yes. Further, in each of the above embodiments, when numerical values such as the number, numerical value, quantity, range, etc. of the constituent elements of the embodiment are mentioned, it is clearly limited to a specific number when clearly indicated as essential and in principle. The number is not limited to the specific number except for the case. In each of the above embodiments, when referring to the material, shape, positional relationship, etc. of the constituent elements, etc., unless otherwise specified, or in principle limited to a specific material, shape, positional relationship, etc. The material, shape, positional relationship, etc. are not limited.

10 Fuel supply device 12 Injector 14 Common rail (pressure accumulator)
16 Supply pump 18 Relief valve (pressure reduction device)
22 Feed pump 24 Fuel supply pipe 26 Fuel return pipe (low pressure return flow path)
28 Jet Pump 201 First Fuel Tank 202 Second Fuel Tank

Claims (10)

An accumulator (14) for storing high-pressure fuel supplied to an injector (12) for injecting fuel into the combustion chamber of the engine; a supply pump (16) for pressurizing and supplying fuel to the accumulator; A first fuel tank (201) for storing fuel; a second fuel tank (202) for storing fuel; a feed pump (22) for supplying fuel stored in the first fuel tank to the supply pump; the supply pump; A low pressure return flow path (26) for returning low pressure fuel from at least one of the pressure accumulator and the injector to the second fuel tank, and a return fuel flowing through the low pressure return flow path to the second fuel tank. An abnormality diagnosing device for diagnosing an abnormality in a fuel supply device (10) comprising a jet pump (28) for sending fuel accumulated in the second fuel tank to the first fuel tank using the fuel flow of Te,
If the increase amount of fuel accumulated in the second fuel tank per unit time exceeds a predetermined first determination value during operation of the engine, there is an abnormality in the fuel flow of the return fuel. An abnormality diagnosis device comprising abnormality determination means (S102, S103, S104) for determining that there is a device.   The abnormality determination means is configured to increase the amount of fuel accumulated in the second fuel tank per unit time exceeding the first determination value during operation of the engine, and the fuel accumulated in the first fuel tank. The abnormality diagnosis device according to claim 1, wherein the abnormality is determined when the amount of decrease per unit time exceeds a predetermined second determination value.   The abnormality determination means is configured to increase the amount of fuel accumulated in the second fuel tank per unit time exceeding the first determination value during operation of the engine, and the fuel accumulated in the first fuel tank. The abnormality diagnosis apparatus according to claim 1, wherein the abnormality is determined when the remaining amount is less than a predetermined third determination value.   The abnormality determination unit is configured to increase the amount of fuel accumulated in the second fuel tank per unit time during the operation of the engine and exceed the first determination value, and the fuel accumulated in the second fuel tank. The abnormality diagnosis device according to any one of claims 1 to 3, wherein the abnormality is determined when the remaining amount of the battery exceeds a predetermined fourth determination value.   5. The abnormality determination unit according to claim 1, wherein the abnormality determination unit determines the presence / absence of the abnormality based on the fact that the return fuel has an insufficient flow rate for operating the jet pump. The abnormality diagnosis device described in 1. An abnormality type determining means (S105) for determining the content of the abnormality when the abnormality is determined by the abnormality determining means;
The abnormality type determination means is a reduction amount (ΔQt) of a total remaining amount (Qt) obtained by adding up the remaining amount of fuel accumulated in the first fuel tank and the remaining amount of fuel accumulated in the second fuel tank. However, if it exceeds the fuel consumption (Qcn) consumed by the injection of the injector within the period in which the fuel decrease of the decrease amount occurs, it is determined that fuel leakage has occurred in the low pressure return flow path. The abnormality diagnosis apparatus according to claim 1, wherein The fuel supply device includes a pressure control device (30) for adjusting the pressure of fuel flowing from the feed pump to the supply pump,
The pressure control device is connected between the feed pump and the supply pump, and is also connected to the low pressure return flow path. The more the flow rate of fuel flowing to the low pressure return flow path is increased, the more The fuel flowing into the supply pump is greatly depressurized,
The said abnormality kind determination means determines with the said pressure control apparatus having failed, when the amount of reduction | decrease of the said total remaining amount does not exceed the said fuel consumption. Abnormality diagnosis device. An abnormality type determining means (S105) for determining the content of the abnormality when the abnormality is determined by the abnormality determining means;
The fuel supply device includes a pressure control device (30) for adjusting the pressure of fuel flowing from the feed pump to the supply pump, and a pressure detection device (32) for detecting the pressure of fuel flowing from the feed pump to the supply pump. )
The pressure control device is connected between the feed pump and the supply pump, and is also connected to the low pressure return flow path. The more the flow rate of fuel flowing to the low pressure return flow path is increased, The fuel flowing into the supply pump is greatly depressurized,
The abnormality type determination means determines that the pressure control device is out of order when the fuel pressure detected by the pressure detection device exceeds a predetermined pressure threshold value. The abnormality diagnosis device according to any one of claims 1 to 5.   The abnormality type determination means determines that fuel leakage has occurred in the low-pressure return flow path when the fuel pressure detected by the pressure detection device is equal to or lower than the pressure threshold. The abnormality diagnosis device according to claim 8.   8. A pressure increase means (S107, S109) for increasing the pressure of fuel discharged from the feed pump when the abnormality determination means determines that there is an abnormality. The abnormality diagnosis device according to any one of 9.

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