JP3783837B2 - Evaporative fuel processing system leak determination device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an evaporative fuel processing system leak determination device that temporarily stores evaporative fuel generated in a fuel tank in a canister and determines whether or not there is a leak in the evaporative fuel processing system of an internal combustion engine that is appropriately supplied to an intake system About.
[0002]
[Prior art]
Conventionally, as this type of leak determination device, for example, one disclosed in Japanese Patent Application Laid-Open No. 9-291854 has been known. This evaporative fuel processing system includes a canister, a fuel tank, a charge passage, a purge passage, and the like. The canister is connected to the fuel tank via the charge passage, and is connected to the intake pipe of the internal combustion engine via the purge passage. A pressure sensor is provided in the charge passage, and this pressure sensor detects the pressure in the charge passage (because this pressure is substantially equal to the pressure in the fuel tank in a steady state, hereinafter referred to as “tank internal pressure”). To do. Further, a bypass valve for opening and closing the charge passage is provided in the bypass passage. Further, an atmospheric passage that opens to the atmosphere side is connected to the canister, and a vent shut valve that opens and closes the atmospheric passage is provided in the atmospheric passage. The purge passage is provided with a purge control valve that opens and closes the purge passage.
[0003]
As will be described below, the leak determination device determines whether or not there is a leak in the evaporated fuel processing system by sequentially executing a decompression mode process and a leak check mode process. First, in the depressurization mode process, the bypass valve and the purge control valve are opened, and the vent shut valve is closed to depressurize the evaporated fuel processing system until the tank internal pressure becomes a predetermined negative pressure.
[0004]
Next, in the leak check mode process, by closing the bypass valve, purge control valve, and vent shut valve, the evaporated fuel processing system is kept in a sealed state for a predetermined time, and a change in tank internal pressure is monitored during this sealed holding. To do. When the change in the tank internal pressure becomes a predetermined value or more during the monitoring, it is determined that there is a leak. On the other hand, when the change in the tank internal pressure is less than a predetermined value during monitoring, it is determined that there is no leak.
[0005]
[Problems to be solved by the invention]
In the above-described conventional leak determination device, for example, when the vehicle shakes with a small amount of fuel in the fuel tank or when the outside air temperature is high, the amount of evaporated fuel in the fuel tank increases and the tank internal pressure becomes short. As the time rises, the leak determination may not be performed accurately. In other words, the leak check mode process only checks the change in the tank internal pressure within a predetermined time, so there is no leak when the tank internal pressure temporarily rises due to the various causes described above during this process. Nevertheless, there is a risk of erroneous determination that there is a leak.
[0006]
The present invention has been made to solve the above-described problems. Even when the pressure in the evaporative fuel processing system temporarily increases due to an increase in the amount of evaporative fuel in the fuel tank or the like, the effect of the pressure increase is achieved. It is an object of the present invention to provide a fuel vapor processing system leak determination apparatus capable of accurately performing a leak determination while eliminating the above.
[0007]
[Means for Solving the Problems]
In order to achieve this object, according to the first aspect of the present invention, the evaporated fuel generated in the fuel tank 21 is temporarily adsorbed by the canister 24 and is introduced into the intake system 4 of the internal combustion engine 3 through the purge passage 25. A leak determination device 1 for the fuel vapor processing system 20 to be supplied, which introduces pressure detection means (pressure sensor 26) for detecting the pressure (tank pressure PTANK) in the fuel vapor processing system 20 and the negative pressure of the intake system 4. By doing so, the inside of the evaporated fuel processing system 20 is maintained until the detected pressure in the evaporated fuel processing system 20 (tank pressure PTANK) reaches a predetermined negative pressure POBJ. once Depressurize once Decompression means (ECU 2, charge bypass valve 31, purge control valve 33, step 3); once By decompression means once After the decompression is finished, Following the primary decompression, The negative pressure of the intake system 4 is introduced into the evaporated fuel processing system 20 at a predetermined constant negative pressure introduction flow rate Q. Secondary pressure reduction for secondary pressure reduction in the evaporated fuel processing system 20 Means (ECU 2, charge bypass valve 31, purge bypass valve 34, jet 35, step 6); Secondary decompression By means Secondary decompression Leak determination means (ECU 2, step 11) for determining whether or not there is a leak in the evaporated fuel processing system 20 based on the pressure in the evaporated fuel processing system 20 (initial tank internal pressure PTANK1, final tank internal pressure PTANK2) detected during It is characterized by providing.
[0008]
According to this fuel vapor processing system leak determination device, when the leak is determined, first, the negative pressure in the intake system is introduced to reduce the pressure in the fuel vapor processing system to a predetermined negative pressure. once Reduce pressure. Then this After the completion of the primary decompression, following the primary decompression, The intake system negative pressure is introduced into the fuel vapor processing system at a predetermined constant negative pressure introduction flow rate. To reduce the pressure in the evaporative fuel treatment system With this Secondary decompression Based on the pressure of the evaporated fuel processing system detected inside, the presence or absence of leakage of the evaporated fuel processing system is determined. Thus, according to the present invention, During the secondary decompression that follows the primary decompression, As the negative pressure is introduced into the evaporative fuel treatment system, the pressure is detected. During secondary decompression The detected pressure in the evaporated fuel processing system represents a value obtained by offsetting the pressure increase due to the leak and the pressure decrease due to the negative pressure introduction. Therefore, it is possible to determine the leakage of the evaporated fuel processing system based on the pressure in the evaporated fuel processing system.
[0009]
Also, During secondary decompression, Since the pressure is detected while continuing to introduce negative pressure into the evaporative fuel treatment system, even if the pressure in the evaporative fuel treatment system temporarily increases due to an increase in the amount of evaporative fuel in the fuel tank, Leak determination can be performed while eliminating such a state. As a result, it is possible to accurately determine whether or not there is a leak in the evaporated fuel processing system while eliminating the influence of a temporary pressure increase caused by other than the leak.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a leak determination apparatus for an evaporated fuel processing system according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows a schematic configuration of an evaporative fuel processing system to which the leak determination apparatus of the present embodiment is applied, and an internal combustion engine equipped with the same. The leak determination device 1 determines whether or not there is a leak in the evaporated fuel processing system 20 of the internal combustion engine 3 (hereinafter referred to as “engine 3”). Primary decompression means, Secondary decompression Means and leak determination means). Details of the fuel vapor processing system 20 and the ECU 2 will be described later.
[0011]
The engine 3 is a gasoline engine and is mounted on a vehicle (not shown). An engine speed sensor 12 is attached to the main body of the engine 3, and the engine speed sensor 12 detects the engine speed NE and sends a detection signal to the ECU 2.
[0012]
The intake system 4 of the engine 3 includes an intake pipe 5 and a throttle valve 6. An intake pipe absolute pressure sensor 13 is attached to a portion of the intake pipe 5 downstream of the throttle valve 6. The intake pipe absolute pressure sensor 13 detects the intake pipe absolute pressure PBA in the intake pipe 5 and sends the detection signal to the ECU 2.
[0013]
Further, an injector (fuel injection valve) 7 is attached to a portion of the intake pipe 5 on the downstream side of the intake pipe absolute pressure sensor 13 so as to face an intake port (not shown). The fuel injection time TOUT, which is the valve opening time of the injector 7, is controlled by the ECU 2. The injector 7 is connected to the fuel tank 21 via the fuel supply pipe 8. A fuel pump 9 that pumps fuel to the injector 7 is provided in the middle of the fuel supply pipe 8.
[0014]
On the other hand, an O 2 sensor 14 is attached to a portion of the exhaust pipe 10 of the engine 3 upstream of the catalyst device 11. The O2 sensor 14 detects the oxygen concentration in the exhaust gas upstream of the catalyst device 11 and outputs a detection signal based on the oxygen concentration to the ECU 2. Based on the detection signal of the O2 sensor 14, the ECU 2 obtains the air-fuel ratio correction coefficient KO2 used for calculating the fuel injection time TOUT described above.
[0015]
Furthermore, the vehicle speed sensor 15 is provided in the vehicle mentioned above. The vehicle speed sensor 15 detects the vehicle speed VP and sends a detection signal to the ECU 2.
[0016]
Next, the above-described evaporated fuel processing system 20 will be described. The evaporative fuel processing system 20 temporarily stores evaporative fuel generated in the fuel tank 21 in the canister 24 and appropriately discharges it into the intake pipe 5. The evaporative fuel processing system 20 includes a fuel tank 21, a charge passage 22, a refueling charge passage 23, a canister 24, a purge passage 25, and the like.
[0017]
The fuel tank 21 is connected to a canister 24 via a charge passage 22 and a refueling charge passage 23. The charge passage 22 is for sending the evaporated fuel generated in the fuel tank 21 to the canister 24. A pressure sensor 26 (pressure detection means) is disposed in a portion of the charge passage 22 close to the fuel tank 21. The pressure sensor 26 is composed of, for example, a piezoelectric element, detects the pressure in the charge passage 22, and outputs a detection signal to the ECU 2. Since the pressure in the charge passage 22 is usually substantially equal to the pressure in the fuel tank 21, it is hereinafter referred to as a tank internal pressure PTANK.
[0018]
A two-way valve 27 is provided between the pressure sensor 26 in the charge passage 22 and the canister 24. The two-way valve 27 is a mechanical valve in which both a diaphragm positive pressure valve and a negative pressure valve are combined. When the tank internal pressure PTANK becomes higher than the atmospheric pressure by a predetermined value, the two-way valve 27 is a mechanical valve. To open. The evaporated fuel in the fuel tank 21 is sent to the canister 24 by opening the positive pressure valve. The negative pressure valve opens when the tank internal pressure PTANK is lower than the pressure on the canister 24 side by a predetermined value, and the evaporated fuel stored in the canister 21 by opening the negative pressure valve. Is returned to the fuel tank 21.
[0019]
Further, a charge bypass passage 28 is provided in the charge passage 22. The charge bypass passage 28 bypasses the two-way valve 27, and is connected to a portion on the canister 24 side and a portion on the pressure sensor 26 side of the charge passage 22 with respect to the two-way valve 27. In the middle of the charge bypass passage 28, a charge bypass valve 31 ( once Decompression means, Secondary decompression Means). The charge bypass valve 31 is a normally-closed electromagnetic valve, and normally closes the charge bypass passage 28 and opens when driven by the ECU 2 to open the charge bypass passage 28.
[0020]
The above-described charge passage 23 for refueling (only part of which is shown) is for sending a large amount of evaporated fuel generated particularly during refueling to the canister 24 in the fuel tank 21 and has a larger diameter than the charge passage 22. have. A diaphragm valve 23a for opening and closing the charging passage 23 for refueling is provided in the middle. The diaphragm valve 23 a is closed except during refueling, and is opened during refueling to send evaporated fuel to the canister 24 via the refueling charge passage 23.
[0021]
Furthermore, the fuel tank 21 is provided with float valves 21a and 21b. These float valves 21a and 21b open and close the fuel tank 21 side opening of the charge passage 22 and the refueling charge passage 23, respectively, and normally open the openings of both passages 22 and 23, while the fuel tank By closing the openings of the passages 22 and 23 when the valve 21 is shaken or full, the fuel is prevented from flowing into the passages 22 and 23.
[0022]
On the other hand, the canister 24 incorporates activated carbon, and adsorbs the evaporated fuel by the activated carbon. The canister 24 is connected to an atmospheric passage 29 that opens to the atmosphere side. The atmospheric passage 29 is provided with a vent shut valve 32 that opens and closes the atmospheric passage 29. The vent shut valve 32 is a normally open type electromagnetic valve, and normally holds the atmospheric passage 29 in an open state and is driven by the ECU 2 to close the atmospheric passage 29.
[0023]
Further, in the middle of the purge passage 25 described above, a purge control valve 33 (open / closed) is opened / closed. once Decompression means) is provided. The purge control valve 33 is composed of an electromagnetic valve whose opening degree changes continuously according to the duty ratio of the drive signal of the ECU 2. When the vent shut valve 32 is in the open state, the purge control valve 33 is opened so that the evaporated fuel adsorbed by the canister 24 is fed into the intake pipe 5 by the negative pressure in the intake pipe 5. The ECU 2 controls the flow rate of the evaporated fuel sent from the canister 24 to the intake pipe 5, that is, the purge flow rate, by performing duty control on the opening degree of the purge control valve 33 during the purge control.
[0024]
Further, a purge bypass passage 30 similar to the charge bypass passage 28 described above is connected to the purge passage 25. The purge bypass passage 30 bypasses the purge control valve 33 and is connected to a portion of the purge passage 25 closer to the canister 24 than the purge control valve 33 and a portion closer to the intake pipe 5. In the middle of the purge bypass passage 30, a purge bypass valve 34 and a jet 35 are attached in order from the canister 24 side.
[0025]
This purge bypass valve 34 ( Secondary decompression The means) is constituted by a normally closed electromagnetic valve, and normally holds the purge bypass passage 30 in a closed state and is driven by the ECU 2 to open the purge bypass passage 30. By opening the purge bypass valve 34, the negative pressure of the intake pipe 5 is introduced into the evaporated fuel processing system 20, whereby secondary decompression described later is executed. Jet 35 ( Secondary decompression The means) is an orifice having a predetermined diameter, and restricts the flow rate of introduction of the negative pressure during the secondary pressure reduction to a predetermined constant flow rate Q. The flow rate Q is set to a value (for example, 3 liters / minute) at which the tank internal pressure PTANK gradually decreases when there is no leak in the evaporated fuel processing system 20 during the secondary decompression.
[0026]
On the other hand, the ECU 2 is constituted by a microcomputer including an I / O interface, a CPU, a RAM, and a ROM. The detection signals of the sensors 12 to 15 and 26 described above are input to the CPU after A / D conversion and shaping by the I / O interface. The CPU determines the operating state of the engine 3 according to these input signals, drives the above-described valves 31 to 34 according to a control program stored in advance in the ROM, data stored in the RAM, and the like. The leak determination process described in (1) is executed.
[0027]
Hereinafter, the leak determination process of the evaporated fuel processing system 20 executed by the ECU 2 will be described with reference to FIG. This figure is a flowchart showing a program of this processing. This process is interrupted and executed every predetermined time (for example, 80 msec) according to the timer setting, and this process is not executed after execution of leak determination (determination in step 14 described later). That is, the leak determination by this process is executed only once between the start and end of operation of the engine 3.
[0028]
First, in step 1 (abbreviated as S1 in the figure, the same applies hereinafter), it is determined whether or not a monitoring condition is satisfied. This monitoring condition is for determining whether or not the execution condition of the leak determination process is satisfied. For example, when all of the following conditions (1) to (4) are satisfied, the monitoring condition Is determined to be true.
[0029]
(1) The purge control valve 33 is open and purge control is being executed.
(2) The engine 3 is in a predetermined steady operation state (determined based on, for example, the absolute pressure PBA in the intake pipe and the engine speed NE).
(3) A cruising operation in which the change in the vehicle speed VP is small.
(4) The air-fuel ratio correction coefficient KO2 is not less than a predetermined value and the influence of purge fuel on the air-fuel ratio A / F is small.
[0030]
When the determination result of step 1 is NO, that is, when at least one of the above conditions (1) to (4) is not satisfied, this process is terminated.
[0031]
On the other hand, when the determination result in step 1 is YES, that is, when all of the above conditions (1) to (4) are satisfied, the process proceeds to step 2 to check whether the primary pressure reduction execution flag FPOK is “1”. Determine whether or not. This primary pressure reduction executed flag FPOK is set to “1” when the primary pressure reduction in steps 3 to 6 described below is completed (step 7).
[0032]
Immediately after the start of this process, since FPOK = 0, the determination result in step 2 is NO, the process proceeds to step 3, and the primary pressure reduction in the evaporated fuel processing system 20 is executed. Specifically, with the purge bypass valve 34 held in a closed state, the vent shut valve 32 is closed, the charge bypass valve 31 is opened, and based on the tank internal pressure PTANK detected by the pressure sensor 26, The duty ratio of the purge control valve 33 is controlled so that the tank internal pressure PTANK becomes a predetermined negative pressure POBJ (for example, −20 hPa). Thereby, the negative pressure of the intake pipe 5 is introduced into the evaporated fuel processing system 20, and the tank internal pressure PTANK is reduced to a predetermined negative pressure POBJ. In this case, since the charge bypass valve 31 is in the open state, the tank internal pressure PTANK represents the pressure in the evaporated fuel processing system 20.
[0033]
Next, it progresses to step 4, and it is discriminate | determined whether decompression time passed. During this decompression time, if the valves 31 to 34, the pressure sensor 26, etc. are operating normally and there is not a large amount of leak in the evaporated fuel processing system 20, the tank pressure PTANK is set to a predetermined value by the primary decompression within that time. It is set to a value (for example, 15 sec) that is assumed to surely decrease to the negative pressure POBJ. When the determination result is NO, that is, when the decompression time has not elapsed, the present process is terminated.
[0034]
On the other hand, when the determination result in step 4 is YES, that is, when the pressure reducing time has elapsed, the process proceeds to step 5 to determine whether or not the tank internal pressure PTANK is equal to or lower than the predetermined negative pressure POBJ.
[0035]
When the determination result in step 5 is NO, that is, when PTANK> POBJ, the valves 31 to 34, the pressure sensor 26, etc. are not operating normally, or there is a large amount of leak in the evaporated fuel processing system 20 Thus, assuming that the leak determination of the evaporated fuel processing system 20 is not in a normal state, the leak determination end flag FDONE is set to “1” (step 8), and this process is ended. Since the leak determination end FDONE is set to “1”, the process is not executed thereafter, that is, the leak determination is not performed.
[0036]
On the other hand, when the determination result in step 5 is YES, that is, when PTANK ≦ POBJ, the process proceeds to step 6 to end the primary pressure reduction and subsequently to start the secondary pressure reduction. Specifically, the purge control valve 33 is closed and the purge bypass valve 34 is opened while the vent shut valve 32 is kept closed and the charge bypass valve 31 is kept open. As a result, the evaporated fuel processing system 20 communicates with the intake pipe 5 only through the purge bypass passage 30, and the negative pressure in the intake pipe 5 flows into the evaporated fuel processing system 20 at the constant flow rate Q via the jet 35. To be introduced.
[0037]
Next, the process proceeds to step 7, the primary decompression execution flag FPOK is set to “1”, and the process proceeds to step 9. As a result, in the next and subsequent loops of this process, the determination result in Step 2 is YES. In this case, Steps 3 to 7 are skipped and the process proceeds to Step 9 in the same manner.
[0038]
In step 9, it is determined whether or not the leak check time has elapsed. The leak check time is set to a sufficient length (for example, 30 sec) so that the fluctuation tendency of the tank internal pressure PTANK due to the presence or absence of leak appears clearly after the start of secondary pressure reduction, for example. When the determination result is NO, that is, when the leak check time has not elapsed, this processing is ended as it is.
[0039]
On the other hand, when the determination result of step 9 is YES, that is, when the leak check time has elapsed, the process proceeds to step 10 where the secondary pressure reduction is terminated and the change amount ΔP of the tank internal pressure PTANK is calculated. The end operation of the secondary pressure reduction is performed by closing the charge bypass valve 31 and the purge bypass valve 34 and opening the vent shut valve 32 while keeping the purge control valve 33 in the closed state.
[0040]
Further, the change amount ΔP of the tank internal pressure PTANK is, for example, the final tank detected at the end of the leak check time and at the start of timing, that is, at the end and start of the secondary decompression (time t2 and time t1 in FIG. 3), respectively. It is calculated as a differential pressure (PTANK2-PTANK1) between the internal pressure PTANK2 and the initial tank internal pressure PTANK1. In this case, PTANK1 = POBJ is usually set by the duty ratio control of the purge control valve 33.
[0041]
Next, the process proceeds to step 11 where it is determined whether or not the change amount ΔP calculated in step 10 is smaller than a predetermined leak determination value ΔPREF (for example, 5 hPa). When the determination result is YES, that is, when ΔP <ΔPREF, it is determined that the tank internal pressure PTANK is gradually decreasing or the increase degree is small, and there is no leak in the evaporated fuel processing system 20. Next, in order to express this, the leak determination flag FLEAK is set to “0” (step 12), and then the primary pressure reduction executed flag FPOK is set to “0” (step 14), and this processing is terminated. To do.
[0042]
On the other hand, when the determination result in step 11 is NO, that is, when ΔP ≧ ΔPREF, it is determined that the degree of increase in the tank internal pressure PTANK is large and the evaporated fuel processing system 20 has a leak. Next, the process proceeds to step 13, and in order to represent it, the leak determination flag FLEAK is set to “1”, and then the above-described step 14 is executed and the present process is terminated.
[0043]
Next, an example of the transition of the tank internal pressure PTANK obtained when the above leak determination process is executed will be described with reference to the time chart shown in FIG. The curves shown by the solid line and the broken line in the figure show the transition of the tank internal pressure PTANK when there is no leak in the evaporated fuel processing system 20 and when there is a leak, respectively.
[0044]
First, when primary pressure reduction is started (time t0), the tank internal pressure PTANK decreases. Thereafter, when the tank internal pressure PTANK decreases to the predetermined negative pressure POBJ and the pressure reducing time has elapsed (time t1), the purge control valve 33 is closed and the charge bypass valve 34 is opened in synchronization with this. As a result, the primary decompression is completed and the secondary decompression is started. After that, at the time when the leak check time ends (time t2), the secondary pressure reduction ends, and a fluctuation amount ΔP that is a differential pressure between the final tank internal pressure PTANK2 and the initial tank internal pressure PTANK1 is calculated, and this is the leak determination value ΔPREF. Are compared to make a leak determination.
[0045]
In this case, when there is no leak in the evaporated fuel processing system 20, the tank internal pressure PTANK gradually decreases during the secondary pressure reduction, as shown by the solid line in the figure, so that the fluctuation amount ΔP becomes a negative value, which is shown in FIG. The determination result of step 11 is YES (ΔP <ΔPREF). Thereby, it is determined that there is no leak in the evaporated fuel processing system 20. On the other hand, when there is a leak in the evaporated fuel processing system 20, as indicated by a broken line in the figure, the tank internal pressure PTANK gradually increases and ΔP ≧ ΔPREF is determined, so that it is determined that there is a leak in the evaporated fuel processing system 20. Is done.
[0046]
As described above, according to the leak determination device 1 of the present embodiment, the tank internal pressure PTANK is detected while the negative pressure of the intake system 4 is introduced into the evaporated fuel processing system 20 during the secondary decompression, A fluctuation amount ΔP that is a differential pressure between the final tank internal pressure PTANK2 and the initial tank internal pressure PTANK1 during the next pressure reduction is calculated. This fluctuation amount ΔP represents a final pressure value in which the pressure increase due to the leak and the pressure decrease due to the introduction of the negative pressure are offset. Therefore, by comparing such a fluctuation amount ΔP with the predetermined value ΔPREF, it is possible to determine whether or not there is a leak in the evaporated fuel processing system 20.
[0047]
Further, since the tank internal pressure PTANK is detected while continuing the secondary pressure reduction, even if the tank internal pressure PTANK rises temporarily due to an increase in the amount of evaporated fuel in the fuel tank 21, such a state is eliminated. However, the leak determination can be performed. As a result, it is possible to accurately determine whether or not there is a leak in the evaporated fuel processing system 20 while eliminating the influence of a temporary pressure increase caused by other than the leak.
[0048]
In the embodiment described above, the change amount ΔP of the tank internal pressure PTANK is calculated as a differential pressure between the final tank internal pressure PTANK2 during the secondary pressure reduction and the initial tank internal pressure PTANK1, but the tank internal pressure PTANK during the secondary pressure reduction is calculated. As a parameter representing the change state, an appropriate parameter other than the change amount ΔP can be adopted. For example, the change amount ΔP may be calculated as a cumulative value of the differences between the plurality of tank internal pressures PTANK and the initial tank internal pressure PTANK1 detected at a plurality of times during the secondary pressure reduction, or the initial tank internal pressure PTANK1 may be calculated. It may be calculated as an integral value of the tank internal pressure PTANK during the secondary secondary pressure reduction.
[0049]
Further, instead of the purge bypass valve 34 and the jet 35, a flow rate adjusting valve that limits the flow rate of the purge bypass passage 30 to the same flow rate Q as the jet 35 may be used. Further, the purge bypass passage 30, the purge bypass valve 34, and the jet 35 are omitted, and instead of the purge control valve 33, the flow rate of the purge passage 25 ranges from the flow rate Q by the jet 35 to the flow rate controlled by the purge control valve 33. By using a control valve that can be controlled with high accuracy, purge control or secondary pressure reduction may be executed. Further, the purge bypass passage 30 may be provided separately from the purge passage 25, and thereby the intake pipe 5 and the canister 24 may be communicated with each other during the secondary pressure reduction.
[0050]
【The invention's effect】
As described above, according to the leak determination processing of the evaporated fuel processing system of the present invention, even when the pressure in the evaporated fuel processing system is temporarily increased due to an increase in the amount of evaporated fuel in the fuel tank, etc. Leakage determination can be performed accurately while eliminating the influence of pressure rise.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of an evaporative fuel processing system to which a leak determination device according to an embodiment of the present invention is applied and an internal combustion engine equipped with the same.
FIG. 2 is a flowchart of a leak determination process executed by the leak determination apparatus.
FIG. 3 is a time chart showing an example of a transition of tank internal pressure PTANK when a leak determination process is executed.
[Explanation of symbols]
1 Leak determination device
2 ECU ( once Decompression means, Secondary decompression Means, leak judgment means)
3 Internal combustion engine
4 Intake system
20 Evaporative fuel treatment system
21 Fuel tank
24 Canister
25 Purge passage
26 Pressure sensor (pressure detection means)
31 Charge bypass valve ( once Decompression means, Secondary decompression means)
33 Purge control valve ( once Decompression means)
34 Purge bypass valve ( Secondary decompression means)
35 Jet ( Secondary decompression means)
PTANK tank internal pressure (pressure inside the evaporative fuel treatment system)
PTANK1 Initial tank internal pressure (pressure detected during negative pressure introduction)
PTANK2 Final tank internal pressure (pressure detected during negative pressure introduction)
POBJ Predetermined negative pressure
Q Predetermined constant negative pressure introduction flow rate

Claims (1)

An evaporative fuel processing system leak determination device that temporarily absorbs evaporative fuel generated in a fuel tank with a canister and supplies the fuel vapor to an intake system of an internal combustion engine through a purge passage,
Pressure detecting means for detecting pressure in the evaporated fuel processing system;
By introducing the negative pressure of the intake system, a primary pressure reduction means the pressure in the detected evaporative emission control system is depressurized primary inside the evaporative emission control system until a predetermined negative pressure,
The primary vacuum after termination by the primary vacuum means, subsequent to the primary vacuum, by introducing into the intake system vacuum to a predetermined constant of said evaporative emission control system with negative pressure introduction flow rate of the evaporative fuel processing Secondary decompression means for secondary decompression in the system ;
Leak determination means for determining whether or not there is a leak in the evaporated fuel processing system based on the pressure in the evaporated fuel processing system detected during the secondary pressure reduction by the secondary pressure reducing means;
An evaporative fuel treatment system leak determination apparatus comprising:

Images