JP3444196B2 - Abnormality detection device for fuel gas emission suppression device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fuel gas discharge suppressing device for preventing fuel gas (evaporated fuel) generated in a fuel tank from being discharged into the atmosphere, and an abnormality detecting device for the device. It relates to the device.

[0002]

2. Description of the Related Art Conventionally, in automobiles and the like, in order to prevent the fuel gas generated in a fuel tank from being discharged into the atmosphere, there is a regulation that a fuel gas discharge suppressing device is required to be mounted. The fuel gas emission control device is to adsorb fuel gas to a canister provided in the middle of a purge passage that connects a fuel tank and an intake pipe of the engine, and to open and close a purge control valve according to the operating state of the internal combustion engine. Thus, the adsorbed fuel gas is appropriately released into the intake pipe.
The fuel gas discharged to the intake pipe is mixed into the fuel mixture to suppress the discharge of fuel to the outside.

In such a fuel gas emission control device, normally,
A purge hose is formed by connecting a rubber hose between the canister and the intake pipe. If this rubber hose is damaged or drops off, the fuel gas will be discharged outside (in the atmosphere).
Will leak out. Therefore, as an apparatus for monitoring such a leak of fuel gas, for example, Japanese Patent Laid-Open No. Hei 5
In the "abnormality detection device for fuel evaporation prevention device" of Japanese Patent No. 125997, a pressure sensor is attached to a fuel tank, and a fuel gas leak abnormality is determined according to the sensor detection value. More specifically, the fuel tank to the intake pipe of the engine are hermetically sealed, and the hermetically sealed section is pressure-controlled near atmospheric pressure or at a predetermined negative pressure level. Then, an abnormality such as fuel leakage or passage blockage is detected from the pressure change state due to the generation of fuel gas in the closed section at that time.

[0004]

However, in the above-mentioned conventional apparatus, when the closed section is adjusted to a predetermined negative pressure level, the fuel gas is rapidly generated immediately after the pressure adjustment. Therefore, even if the rubber hose or the like forming the purge passage is not damaged and there is no fuel leak, the change amount of the pressure state becomes relatively large. On the other hand, when a small diameter hole (for example, a hole having a diameter of about 0.5 mm) is opened in the rubber bose, the amount of fuel gas leakage is relatively small, and therefore the amount of pressure change due to the leakage is relatively small. Becomes

For this reason, in the conventional device that detects the presence or absence of abnormality from the pressure change amount from the predetermined negative pressure level to the positive pressure side in the closed section, the pressure state changes due to the large amount of fuel gas generated immediately after the pressure adjustment. When it occurs, or when the amount of pressure change is relatively small when the fine holes are open,
There is a problem that accurate abnormality detection cannot be performed.

The present invention has been made in view of the above problems, and an object of the present invention is to suppress the fuel gas emission capable of accurately detecting the abnormality even when the fuel gas leaks through the fine holes. An abnormality detection device for a device is provided.

[0007]

In order to achieve the above object, the present invention is based on the premise that fuel gas generated in a fuel tank is stored in a canister, and the fuel gas stored in the canister is purged together with air through a purge pipe. It is applied to a fuel gas emission restraint device that discharges to the intake passage of an engine through a valve, seals from the fuel tank to the intake passage of the engine, and adjusts the pressure in the closed section to a predetermined negative pressure level. Pressure adjusting means and an abnormality detecting means for detecting an abnormality of the fuel gas emission suppressing device from the pressure change at that time after the pressure adjustment by the pressure adjusting means.

According to the first aspect of the invention, immediately after the negative pressure level is adjusted by the pressure adjusting means, the negative pressure level adjusted at that time is maintained for a predetermined time in the vicinity thereof. And an abnormality detection start permitting means for starting the detection of the pressure state for the abnormality detection after the negative pressure holding means holds the negative pressure for a predetermined time.

In short, when the closed section from the fuel tank to the intake passage of the engine is adjusted to a negative pressure level, fuel gas (evaporated fuel) is rapidly generated immediately after the negative pressure adjustment, and the degree of generation of this fuel gas Gradually becomes gentler over time. In this case, in the conventional device that determines the presence or absence of abnormality from the pressure change state immediately after the negative pressure adjustment, the pressure state changes when a large amount of fuel gas is generated immediately after the pressure adjustment or when the fine holes are open. Accurate abnormality detection could not be performed when the amount of change was relatively small.
On the other hand, in the configuration of the present invention, since the abnormality determination is performed after the sudden generation of the fuel gas is stopped, the unexpected pressure change does not occur due to the unexpected generation of the fuel gas, and Leak determination can be performed accurately from the change in state. As a result, even when the fuel gas leaks through the fine holes, the abnormality can be accurately detected.

Further, the negative pressure holding means, the pressure a predetermined negative pressure of the purge control valve opening duty control to the closed section of which is provided in the purge pipe between an intake passage of the canister and the engine Hold on to the level. According to this configuration, negative pressure can be properly maintained in the closed section.

The negative pressure holding means may variably set the holding time at a predetermined negative pressure level, as described in claims 2 to 4 below. Appropriate negative pressure holding control can be realized while corresponding to the degree of occurrence.

According to the second aspect of the present invention, the time period for holding at a predetermined negative pressure level is variably set according to the fuel temperature in the fuel tank. Specifically, the holding time may be increased as the fuel temperature increases.

According to the third aspect of the present invention, the time for holding at the predetermined negative pressure level is variably set according to the parameter related to the space volume of the fuel tank. The space volume of the fuel tank corresponds to the remaining amount of fuel in the same tank, and the smaller the remaining amount of fuel, the larger the space volume. In this case, the holding time may be increased as the space volume of the fuel tank increases.

According to the fourth aspect of the invention, the time for holding at a predetermined negative pressure level is variably set according to the fuel property. Specifically, the Reid vapor pressure of gasoline fuel (RV
As the P: Reid Vapor Pressure) increases, the holding time may be increased.

Further, in order to easily detect the presence / absence of the leak and the cause of the leak, it is preferable to configure as in claim 5 . That is, in the invention described in claim 5 , when sealing from the fuel tank to the intake passage of the engine, in addition to the pressure adjustment at the negative pressure level, at another pressure level different from the negative pressure level. The pressure is adjusted, the former pressure change state at the time of pressure adjustment and the latter pressure change state at the time of pressure adjustment are compared, and the abnormality of the fuel gas emission suppressing device is detected from the comparison result.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment in which the present invention is embodied in a fuel injection control system will be described below with reference to the drawings. In the present embodiment, a vehicle-mounted gasoline engine (internal combustion engine) is equipped with a fuel gas emission suppression device, and the canister of this fuel gas emission suppression device temporarily adsorbs the fuel gas generated in the fuel tank, The adsorbed fuel is released to the engine intake system via the purge passage or the like. In addition, the control system is equipped with an electronic control unit (hereinafter referred to as an ECU) that controls fuel injection control, fuel gas purge control, and the like.

FIG. 1 is a configuration diagram showing an outline of a fuel injection control system in the present embodiment. As shown in the figure, an intake pipe 2 and an exhaust pipe 3 are connected to the engine 1. An air cleaner 4 for filtering air is arranged upstream of the intake pipe 2, and the air is sucked into the intake pipe 2 via the air cleaner 4. In addition, a throttle valve 5 that opens and closes in conjunction with an accelerator pedal 6 is provided in the intake pipe 2. The sucked air is supplied to the combustion chamber 8 above the piston 10 via the throttle valve 5 and the intake valve 7. Then, the exhaust gas discharged after being burned in the combustion chamber 8 is discharged to the exhaust pipe 3 via the exhaust valve 9.

On the other hand, a fuel pump 13 is connected to a fuel tank 12 containing a liquid fuel (gasoline).
The fuel stored in the fuel tank 12 is fed to the fuel injection valve 14 while being pressurized by the fuel pump 13, and is injected into the intake pipe 2 as the fuel injection valve 14 opens. Supplied. That is, the injected fuel is mixed with the intake air in the combustion chamber 8 and used for combustion.

The fuel tank 12 is also connected to a canister 16 via a communication pipe 15. Each part described below, including the fuel tank 12 and the communication pipe 15, constitutes a fuel gas emission suppressing device of the engine. That is, in the same fuel gas emission suppressing device, the canister body 17 accommodates the adsorbent 18 made of, for example, activated carbon for adsorbing the fuel gas generated in the fuel tank 12. With such a configuration as the device, the fuel gas generated in the fuel tank 12 is taken into the canister body 17 through the communication pipe 15 and is adsorbed by the adsorbent 18 in the canister body 17. .

The canister body 17 is formed with an atmosphere hole 19 which is open to the atmosphere, and air passes between the inside and outside of the canister body 17 through the atmosphere hole 19. An electromagnetically driven canister shutoff valve 20 is provided in the atmosphere hole 19 and can be shut off if necessary. That is, the canister shutoff valve 20 opens the atmosphere hole 19 when the coil (not shown) is not energized (OFF) and closes the atmosphere hole 19 when the coil is energized (ON). Canister block valve 20
Whether or not the voltage is applied to the control unit is controlled through the ECU 40 described later.

A hose connection portion 21 is formed on the canister body 17. One end of a purge pipe 22 is attached to the hose connection portion 21, and an electromagnetically driven purge control valve 23 is connected to the other end of the purge pipe 22.
The purge control valve 23 is further connected to the intake pipe 2 on the downstream side of the throttle valve 5 via a purge pipe 24.

According to such a structure of the fuel gas discharge suppressing device, the intake pipe 2 and the canister 16 are brought into communication by opening the purge control valve 23, and conversely the control valve 23 is closed. These intake pipes 2
And the canister 16 are closed. Canister 16
Therefore, the fuel gas adsorbed by the adsorbent 18 is
In the communicating state based on the opening of the purge control valve 23, the negative pressure generated in the intake pipe 2 is introduced into the intake pipe 2.

In the purge control valve 23, when the coil (not shown) is energized, the opening degree, that is, the purge flow rate is determined according to the energization amount. Energization of the purge control valve 23 is performed by a duty-controlled pulse signal, and the purge flow rate also continuously changes in the manner shown in FIG. 2, for example, based on the duty ratio of the pulse signal. Such duty control of the purge flow rate is also executed through the ECU 40 described later.

In the fuel gas emission restraining device, the purge pipes 22 and 24 connected to the purge control valve 23 are made of a flexible material such as a rubber hose or a nylon hose. Further, the communication pipe 15 connecting the fuel tank 12 and the canister 16 is also partially formed by a rubber hose or the like.

On the other hand, in the fuel tank 12, a relief valve 12a for releasing the pressure in the fuel tank 12 when the pressure in the tank 12 falls outside the range of -40 to 150 hPa, for example.
Is provided. Therefore, even when pressure fluctuations occur in the section from the fuel tank 12 to the canister 16, the fluctuations can always be suppressed within this relief pressure range.

The fuel tank 12 is further provided with a pressure sensor 25 for detecting the pressure in the tank 12. The output of the pressure sensor 25 is used as a monitor signal when adjusting the pressure in the fuel gas emission suppression device. The pressure sensor 25 may have a structure that can withstand the above relief pressure range. Further, in the device of the embodiment, as the pressure sensor 25, a differential pressure sensor that detects a differential pressure (relative pressure) between the tank internal pressure and the atmospheric pressure is used.

In addition, in the system, as also shown in FIG. 1, a throttle sensor 26 for detecting the opening of the throttle valve 5, a rotation speed sensor 27 for detecting the rotation speed of the engine 1, and the intake air. An intake pipe pressure sensor 28 for detecting the pressure inside the pipe 2 is provided. The output of each of these sensors is captured by the ECU 40.

The ECU 40 includes a well-known CPU 41, a ROM 42 in which arithmetic programs for control and the like and data are stored in advance, and a RAM in which control data and the like are temporarily stored.
43, and an input / output circuit 44 connected to the various sensors and actuators are connected to each other via a common bus 45. In the ECU 40, the fuel injection valve 14 is driven based on the detection signals from the various sensors, and the purge control valve 23 and the canister closing valve 20 are driven to comprehensively control the fuel injection control, the canister purge control, and the like. Run.

Here, the outline of the present control system by the ECU 40 will be briefly described. That is, the ECU 40 calculates the basic fuel injection amount to the engine 1 based on the output of the rotation speed sensor 27 (revolution speed NE) and the output of the intake pipe pressure sensor 28 (intake pressure PM), and the basic fuel injection amount is also calculated. Then, various corrections such as air-fuel ratio correction are performed to calculate the final fuel injection amount. Then, in synchronization with the intake stroke of the engine 1, the fuel injection valve 14 is driven for the time indicated by the final fuel injection amount.

Further, the ECU 40 detects the fuel gas concentration (evaporation concentration) in the fuel gas emission suppressing device based on, for example, a feedback (F / B) correction coefficient FAF based on the air-fuel ratio deviation amount, and the detected fuel is detected. The opening information of the purge control valve 23 corresponding to the gas concentration, that is, the purge flow rate is set. When executing the purge control, the opening degree of the purge control valve 23 is determined each time with reference to the opening degree information, and the opening degree of the purge control valve 23 is duty-controlled so as to match the determined opening degree. Further, the opening / closing of the canister shutoff valve 20 is adjusted so as to control the pressure in the fuel gas discharge suppression device (the pressure in the canister 16 and the fuel tank 12) to a predetermined value.

Further, the ECU 40 carries out an abnormality detection process for the fuel gas emission suppressing device, which will be described in detail below, and in the process, an error occurrence such as leakage of the fuel gas in the fuel gas emission suppressing device occurs. Is detected,
The abnormality warning light 29 is turned on to warn the passengers of the vehicle of the occurrence of the abnormality to inform them.

Next, of the various calculation processes executed by the CPU 41 in the ECU 40, the abnormality detection process of the fuel gas emission suppressing device will be described with reference to the flowcharts of FIGS. 3 to 6 and the time chart of FIG. 7. . Figure 3
When the IG key switch (not shown) is turned on, the process of FIG. 5 is repeatedly executed at predetermined time intervals (for example, every 64 milliseconds) together with the fuel injection control process. Also, FIG.
In the time chart of the above, the period shown from time t1 to t6 corresponds to a period for detecting an abnormality such as leakage of the fuel gas of the fuel gas emission suppressing device (hereinafter referred to as a leak check period for convenience). However, the tank internal pressure PT shown in FIG. 7 indicates a pressure difference from the atmospheric pressure.

When the processing is started, the CPU 41 first determines in step 101 of FIG. 3 whether or not the abnormality detection execution condition is satisfied. Specifically, the vehicle speed SP = 0,
If the condition for executing the abnormality detection is satisfied during the idle operation, the process proceeds to step 102 when the condition is satisfied. When the condition is not satisfied, this routine is finished as it is. That is, the abnormality detection of the present embodiment is executed only when the vehicle is stopped and in the idle operation state. It should be noted that, as other execution conditions of the abnormality detection, the engine water temperature is equal to or higher than a predetermined temperature (for example, 70 ° C.), the outside air temperature is equal to or higher than a predetermined temperature (for example, −10 ° C.), and the vehicle is traveling at a constant speed. Conditions such as things may be added.

If the above step 101 is positively determined,
The CPU 41 proceeds to step 102. Then, in steps 102 to 105, it is determined which process has been progressed during the leak check period (the period from time t1 to t6 in FIG. 7), and the process branches to each step according to the determination result. In this leak check period, the first flag F1, the second flag F2, the third flag F3, the negative pressure F / B flag Fx.
The processing stage is discriminated from each of the operation states. If all the flags F1 to F3 and Fx are cleared to “0”,
That is, if all the determinations in steps 102 to 105 are negative, the CPU 41 proceeds to step 106.

Upon proceeding to step 106, the CPU 41
After completely closing the purge control valve 23, the following step 107
Then, the canister closing valve 20 is fully closed to seal the section from the fuel tank 12 to the intake pipe 2. In FIG. 7, time t
By controlling the purge control valve 23 to be fully closed at 1, the section from the fuel tank 12 to the purge control valve 23 is adjusted to the same state as the atmospheric pressure via the atmosphere hole 19. Further, at a slightly delayed time t2, the canister shutoff valve 20 is controlled to be fully closed, so that a closed section adjusted to atmospheric pressure is formed.

Subsequently, the CPU 41 fetches the input signal from the pressure sensor 25 in step 108 and stores the tank internal pressure “P1 ′” immediately after the sealing, and at the same time, the ECU 40
The built-in timer T is reset and started. Also, CPU
In the next step 109, 41 determines whether or not a predetermined time (10 seconds in the present embodiment) has elapsed after the timer T was started in step 108.

If 10 seconds have not passed, the CPU 41 sets "1" to the first flag F1 in step 110, and once ends this routine. In FIG. 7, the first flag F1 is set at the time t2, and thereafter, the above step 102 is performed.
Is affirmatively determined and steps 101 → 102 → 109 → 1.
The processing is performed in the order of 10. During this time, the pressure sensor 25
The detected value of "0 hP" is determined according to the amount of fuel gas generated in the fuel tank 12, as shown at times t2 to t3 in FIG.
It will gradually rise from "a".

When 10 seconds have passed from time t2, the CPU
41 makes an affirmative decision in step 109 to proceed to step 111 in FIG. 4, fetch the input signal from the pressure sensor 25 and store the tank internal pressure “P1” ”at this time, and
In subsequent step 112, the pressure change amount (hereinafter referred to as the atmospheric pressure change amount) ΔP1 for 10 seconds after the sealing is calculated as ΔP1 = P1 ″ −P1 ′.
Then, the first flag F1 is cleared to "0" (time t in FIG. 7).
3).

Thereafter, the CPU 41 switches the purge control valve 23 from the fully closed state to the fully opened state in step 114, and resets and starts the timer T. Purge control valve 2
At this time t3 when 3 is switched to full open, the intake pipe negative pressure is introduced into the closed section under the positive pressure condition up to that point. Therefore, if there is no abnormality due to blockage in the purge passage portion, the detection value of the pressure sensor 25 (tank internal pressure PT) starts to drop.

Further, in step 115, the CPU 41 determines the tank internal pressure P based on the input signal from the pressure sensor 25.
T is a predetermined negative pressure level (in the present embodiment, −20 hP
a) Determine whether or not PT> -20hP
When it is determined to be a (the period from time t3 to t4 in FIG. 7),
The CPU 41 makes a negative decision in step 115 and proceeds to step 116. The CPU 41 then proceeds to step 116.
After the timer T is started in step 114,
That is, it is determined whether or not a predetermined time (two seconds in the present embodiment) has elapsed after time t3 in FIG.

If two seconds have not passed, the CPU 41 sets "1" in the second flag F2 in step 117. In this way, step 102 of FIG. 3 is negatively determined and step 103 is positively determined.
The processing is repeatedly executed in the order of steps 101 to 103 → 115 → 116.

If 2 seconds or more elapses from the time t3 while the state where the determination in step 115 is negative (state of PT> -20 hPa) is continued, the determination in step 116 is affirmative and the CPU 41 proceeds to step 118. . CP
In step 118, the U41 sets "1" to the purge system blockage flag Fclose, which means that there is a blockage part in the purge system from the fuel tank 12 to the intake pipe 2, and turns on the abnormality warning light 29. .

That is, unless an abnormality such as a purge system blockage has occurred, the tank internal pressure PT has reached a predetermined negative pressure level (-20 hPa) before the elapse of 2 seconds within the period from time t3 to t4.
However, if an abnormality such as a purge system blockage occurs, the tank internal pressure PT does not drop to a predetermined negative pressure level even after 2 seconds, and an abnormality occurrence indicating the purge system blockage is detected. Will be.

On the other hand, when the affirmative determination is made in step 115, the CPU 41 determines in step 119 that the second flag F2.
Is reset to "0". Further, in the subsequent step 120, the CPU 41 determines whether or not the value of the counter C for measuring the duration of negative pressure F / B processing, which will be described later, has reached a predetermined value K. Since the counter C is initially cleared to "0", a negative determination is made in step 120, and the CPU 41
Proceeds to step 121.

Here, the predetermined value K is a variable value set each time according to the map of FIG. 8, for example, and according to FIG. 8, the higher the temperature (fuel temperature) in the fuel tank 12, the predetermined value. K is set to a large value. Incidentally, the fuel temperature is measured by a known temperature sensor (not shown), and the measurement result is taken into the ECU 40.

The CPU 41 determines negative pressure F /
B flag Fx is set to "1", and the following step 200
The negative pressure F / B process is carried out. In other words, this negative pressure F / B
The process starts at time t4 in FIG. 7, and according to the process,
The tank internal pressure PT is F / B controlled in the vicinity of “−20 hPa” for a predetermined period. Therefore, after time t4, as shown in FIG.
Steps 102 and 103 are negatively determined, and step 104 is positively determined.
The processing is repeatedly executed in the order of 1 to 104 → 120 → 121 → 200.

Now, the negative pressure F / B processing executed in step 200 will be described with reference to FIG. In FIG. 6, C
The PU 41 first sets the counter C to “1” in step 201.
Increment, and in the next step 202, the tank internal pressure P
It is determined whether T has reached the A value on the negative pressure side slightly below -20 hPa. Then, under the condition that PT ≦ A (YES in step 202), the CPU 41 controls the opening degree of the purge control valve 23 to the open side in step 203. Specifically, the control duty ratio of the purge control valve 23 is set to several percent.
Increase the degree.

Further, the CPU 41 determines in step 204 whether or not the tank internal pressure PT has reached the B value slightly on the positive pressure side of -20 hPa. Then, under the condition that PT ≧ B (YES in step 204), the CPU 41
Controls the opening of the purge control valve 23 to the closed side in step 205. Specifically, the control duty ratio of the purge control valve 23 is reduced by about several percent. After the processing of FIG.
U41 returns to the original abnormality detection processing.

Then, the counter C by the processing of FIG.
C> K due to the counting operation of No., and when the determination at Step 120 is affirmative, the CPU 41 proceeds to Step 122 and clears the negative pressure F / B flag Fx to “0”. In the subsequent step 123, the counter C is cleared to "0".

After that, the CPU 41 proceeds to step 1 of FIG.
At 24, the purge control valve 23 is fully closed again. Further, the CPU 41 takes in the input signal from the pressure sensor 25 in step 125, stores the tank internal pressure “P2 ′” immediately after the negative pressure F / B in the sealed section, and at the same time, the ECU 40.
The built-in timer T is reset and started. This timing corresponds to time t5 in FIG.

In short, at time t5 in FIG. 7, the closed section is adjusted to a negative pressure state of −20 hPa, and then at time t5.
During the period of 5 to t6, the tank internal pressure PT is equal to the fuel tank 12
It gradually rises from around -20 hPa depending on the amount of fuel gas generated therein.

Next, in step 126, the CPU 41 starts the timer T in step 125, that is, after the time t5 in FIG.
It is determined whether (10 seconds) has elapsed. If 10 seconds have not elapsed, the CPU 41 proceeds to step 127 to set the third flag F.
Set “1” to 3. Thus, this time, Steps 102 to 104 of FIG.
5 is affirmatively determined, and steps 101 to 10
The process is repeatedly executed in the order of 5 → 126 → 127.

When 10 seconds have passed from time t5, the CPU
41 makes an affirmative decision in step 126 to proceed to step 128.
Proceed to. The CPU 41 determines in step 128 the pressure sensor 2
5, the tank internal pressure "P2""at time t6 is stored, and at step 129, the pressure change amount for 10 seconds after sealing under negative pressure (hereinafter,
ΔP2, which is referred to as the amount of change in negative pressure reduction, is calculated as ΔP2 = P2 ″ −P2 ′.

After that, the CPU 41 determines in step 130 based on a predetermined leak determination condition whether or not there is a leak. Specifically, when ΔP2> α · ΔP1 + β holds, it is determined that “there is a leak”. However, α is a coefficient for correcting the difference in the fuel evaporation amount due to the difference between the atmospheric pressure and the negative pressure, and β is a coefficient for correcting the pressure sensor accuracy, the leakage of the canister blocking valve 20, and the like.

In other words, if there is a cause of leakage in the closed section from the fuel tank 12 to the purge control valve 23, outflow from the closed section to the atmosphere occurs under positive pressure, while from the atmosphere under negative pressure. Outflow to a closed section occurs. Therefore, the “negative pressure change amount ΔP2” becomes larger than the “atmospheric pressure change amount ΔP1”. Here, the atmospheric pressure change amount ΔP1 corresponds to “the amount of fuel gas generated in the fuel tank 12−the amount of outflow from the sealed section into the atmosphere”, and the negative pressure change amount ΔP2 is the “fuel tank 12 Fuel gas generation amount + inflow amount into the closed section ". From this, the leak determination condition of the above inequality is derived.

If the leak determination condition of the above inequality is not satisfied, that is, if step 130 is negatively determined, C
The PU 41 proceeds to step 131, forcibly clears the first to third flags F1 to F3 and the negative pressure F / B flag Fx, and ends this routine.

When the leak determination condition of the above inequality is satisfied, that is, when step 130 is positively determined, the CPU 41 proceeds to step 132. Then, "1" is set to the purge system leak flag Fleak, which means that there is a part causing the leak somewhere in the purge system from the fuel tank 12 to the intake pipe 2, and the abnormality warning lamp 29 is turned on. Then, this routine ends.

According to the processing described above, in the fuel gas emission restraining apparatus, the purge control valve 2 is removed from the fuel tank 12.
If there is a leak or blockage in the section up to 3, this is always detected accurately. Further, this abnormality detection can be performed regardless of the mounting position of the pressure sensor 25.

In this embodiment, the opening / closing control of the purge control valve 23 and the canister closing valve 20 in FIGS. 3 to 5 corresponds to the pressure adjusting means described in the claims, and step 130 in FIG. 5 is the abnormality detecting means. Equivalent to. Further, step 200 of FIG. 4 (processing of FIG. 6) corresponds to negative pressure holding means,
The operation of the negative pressure F / B flag Fx in FIGS. 3 to 5 corresponds to abnormality detection start permission means.

According to this embodiment described in detail above, the following unique effects can be obtained. (A) In the present embodiment, immediately after the pressure adjustment at the negative pressure level, the negative pressure level adjusted at that time is held in the vicinity thereof for a predetermined time (time t4 to t5 in FIG. 7), and the predetermined time is maintained. After the negative pressure is maintained, the detection of the pressure state for the abnormality detection is started (time t5 to t6 in FIG. 7). According to this configuration, since the abnormality determination is performed after the sudden generation of the fuel gas is stopped, there is no unintentional pressure change due to the unexpected generation of a large amount of fuel gas, and the accuracy can be obtained from the change in the pressure state. Good leak judgment can be performed. As a result, even when the fuel gas leaks through the fine holes, the abnormality can be accurately detected.

9 (a) and 9 (b) are views for confirming the effect of the present embodiment, in which the vertical axis shows the negative pressure change amount ΔP2 and the horizontal axis shows the inside of the fuel tank 12. Shows the fuel amount of. Further, (a) of the figure shows the experimental result in the device of the present embodiment, and (b) shows the experimental result in the conventional device (device which does not maintain negative pressure). The mark shows the data when there is a leak of φ1.0 mm, ・ “▲” shows the data when there is a leak of φ0.5 mm, and “○” shows the data when there is no leak. Show.

Looking at the data of each mark, the data of "x" is clearly distinguishable from other data, but the data of "▲" and "○" are respectively A1 to A3 in FIG. 9A. ，
B1 to B3 and C1 to C3 and D1 to D3 in FIG. 9B are scattered, and particularly C1 to C3 and D1 to D in FIG. 9B.
Since 3 and 3 overlap each other, it is very difficult to distinguish both data. On the other hand, in FIG.
1 to A3 and B1 to B3 can be distinguished, and fine holes (φ0.5
(mm) leak and no leak can be clearly distinguished.

(B) Further, in the present embodiment, the opening degree of the purge control valve 23 between the canister 16 and the intake pipe 2 is duty-controlled to maintain the pressure in the closed section at a predetermined negative pressure level. According to this configuration, negative pressure can be properly maintained in the closed section.

(C) The time for holding at a predetermined negative pressure level is variably set according to the fuel temperature in the fuel tank 12 (see the map in FIG. 8). In this case, it is possible to realize appropriate control of holding the negative pressure while corresponding to the generation degree of the fuel gas.

(D) At the time of sealing the fuel tank 12 to the intake pipe 2, the atmospheric pressure (first predetermined pressure) and -20 hP.
By switching a (second predetermined pressure), an abnormality such as a leak was detected from the comparison result of the pressure change states at each pressure. In this case, if the cause of the leak exists, the leak rate changes according to the difference in relative pressure difference from the atmospheric pressure when adjusting each pressure. Therefore, according to the difference between the two pressure change states, the presence or absence of leak and the cause of leak can be easily detected.

In addition to the above, the embodiment of the present invention can be realized in the following forms. In the above embodiment, the predetermined value K corresponding to the negative pressure holding time is variably set according to the fuel temperature (fuel temperature) according to the relationship of FIG. 8. However, this configuration has the following (a) to (c). ) Is changed.

(A) The predetermined value K is variably set according to the parameter related to the space volume in the fuel tank 12. In this case, as shown in FIG. 10, the predetermined value K may be increased as the space volume in the fuel tank 12 increases.
Incidentally, the space volume is calculated based on the measurement result of the fuel level gauge attached to the fuel tank 12, and the larger the fuel remaining amount measured by the level gauge, the smaller the space volume, and the smaller the fuel remaining amount, the space volume. growing.

If the space volume is large, that is, if the remaining amount of fuel is small, the predetermined value K is set to a large value from the map of FIG. As a result, as shown in FIG. 12, the time during which the negative pressure F / B is continued is set to a relatively long time (time t4 to t15). And after that, at time t
In 16, the negative pressure change amount ΔP2 is calculated, and the abnormality is detected from the ΔP2 value. The duration of the negative pressure F / B is extended from "t4 to t5" indicated by the chain double-dashed line to "t4 to t".
In the case of 15 ”, the negative pressure change amount ΔP2 is measured in a state where the generation of the fuel evaporative gas is more stable. Therefore, the influence of the fuel evaporative emission can be reduced, and highly reliable leak detection can be performed.

(B) The predetermined value K is variably set according to the fuel property. In this case, as shown in FIG. 11, the predetermined value K may be increased as the Reid vapor pressure (RVP) of the gasoline fuel increases. Incidentally, the Reid vapor pressure is calculated based on the measurement result of the gasoline property sensor attached to the fuel tank 12 or the like.

(C) The predetermined value K is variably set according to the pressure gradient or the required time when the negative pressure is introduced. Specifically, the time required to change the tank internal pressure PT to a predetermined negative pressure value (−20 hPa) in the leak check period of FIG. 7 (time t3 to t4 of FIG. 7) is calculated, The predetermined value K is set according to the required time. At this time, the longer the time required to reach the predetermined negative pressure is, the larger the amount of fuel gas generated per time is, and the predetermined value K is increased. Or
Similarly, when the negative pressure changes within the leak check period (time t3 to t4 in FIG. 7), the pressure gradient at that time is obtained, and the predetermined value K is set according to the pressure gradient. At this time, the smaller the pressure gradient is, the larger the amount of fuel gas generated per time is, and the predetermined value K is increased.

According to each of the above configurations (a) to (c), it is possible to realize appropriate control of maintaining the negative pressure while corresponding to the generation degree of the fuel gas. Note that it is also possible to use a plurality of elements such as the fuel temperature, the tank internal volume (remaining fuel amount), the fuel property, and the pressure gradient at the time of introducing the negative pressure to obtain the predetermined value K. The reliability of abnormality detection is improved by using the element. On the other hand, it is possible to embody the predetermined value K as a fixed value.

In the above-described embodiment, in the abnormality detection process executed in the flowcharts of FIGS. 3 to 5, after measuring the pressure change state near atmospheric pressure, the pressure change state at negative pressure is measured. This order may be reversed.

Time for pressure adjustment in the abnormality detection process (time t2 to t3, t3 to t4, t5 to t6 in FIG. 7).
The time) is not limited to the above-mentioned time, and may be embodied by appropriately changing it according to the engine specifications and the like.
However, when abnormality detection is performed by comparing the pressure change amount near the atmospheric pressure and the pressure change amount in the negative pressure region as described above, the detection period of each pressure change amount (time t2 to t3, t5 to t5 in FIG. 7).
It is desirable to match 6) or set each time as a time associated with each other.

In the above embodiment, the pressure change amount (ΔP1) near the atmospheric pressure and the pressure change amount (ΔP1) in the negative pressure region are set.
Although the abnormality detection is performed by comparison with 2), the pressure change amount is detected at least in the negative pressure range, and the abnormality detection is performed only by the pressure change amount. In this case, a normal / abnormal determination is made from the pressure change amount in the negative pressure region, using a determination value set in advance by experiments or the like. Even in this configuration, the negative pressure level is maintained for a predetermined time when the pressure is adjusted in the negative pressure region, and thereafter, the detection of the pressure state for the abnormality detection is started, so that the same as in the above-described embodiment. Even when the fuel gas leaks due to the fine holes, it is possible to obtain an excellent effect that the abnormality can be accurately detected.

In the above embodiment, the pressure sensor 25 as the pressure detecting means is provided in the fuel tank 12, but the pressure sensor 25 may be provided in the section between the canister 16 and the intake pipe 2, for example. . Also in this case, it is possible to determine the leak of the entire closed section based on the pressure change state after the closed section is configured.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an outline of a fuel injection control system according to an embodiment of the invention.

FIG. 2 is a graph showing a duty driving mode of a purge control valve.

FIG. 3 is a flowchart showing an abnormality detection process.

FIG. 4 is a flowchart showing anomaly detection processing continued from FIG. 3;

FIG. 5 is a flowchart showing anomaly detection processing subsequent to FIGS. 3 and 4;

FIG. 6 is a flowchart showing negative pressure F / B processing.

FIG. 7 is a time chart for explaining an implementation process of abnormality detection processing.

FIG. 8 is a map for setting a predetermined value K corresponding to a negative pressure holding time according to the fuel temperature.

FIG. 9 is a graph for explaining the effect of the embodiment.

FIG. 10 is a map for setting a predetermined value K corresponding to a negative pressure holding time according to the space volume of the fuel tank.

FIG. 11 is a map for setting a predetermined value K corresponding to a negative pressure holding time according to gasoline RVP.

FIG. 12 is a time chart for explaining an implementation process of abnormality detection processing.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Engine (internal combustion engine), 2 ... Intake pipe, 12 ... Fuel tank, 15 ... Communication pipe, 16 ... Canister, 20 ... Canister closing valve, 22, 24 ... Purge piping, 23 ... Purge control valve, 25 ... Pressure sensor , 40 ... ECU (electronic control unit), 41 ... CPU constituting pressure adjusting means, abnormality detecting means, negative pressure holding means, and abnormality detection start permitting means.

Continuation of front page (56) Reference JP-A-9-291854 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) F02M 25/08 F02M 25/08 301 F02D 41/22 325

Claims (12)

(57) [Claims] 1. A fuel gas emission control device for storing fuel gas generated in a fuel tank in a canister, and discharging the fuel gas stored in the canister together with air into an intake passage of an engine through a purge pipe. And a pressure adjusting means for sealing the fuel tank to the intake passage of the engine and adjusting the pressure in the closed section to a predetermined negative pressure level, and after the pressure adjustment by the pressure adjusting means, In an abnormality detecting device comprising an abnormality detecting means for detecting an abnormality of the fuel gas emission suppressing device from a pressure change, a negative pressure level adjusted at that time immediately after pressure adjustment at a negative pressure level by the pressure adjusting means. A negative pressure holding means for holding for a predetermined time in the vicinity thereof, and after the negative pressure holding means holds the negative pressure for a predetermined time, the abnormality for starting the detection of the pressure state for the abnormality detection is started. A detection start permitting means , wherein the negative pressure holding means is the canister and the intake passage of the engine.
The opening of the purge control valve provided in the purge pipe between
By controlling the duty, the pressure in the closed section is adjusted to the specified negative pressure level.
An abnormality detection device for a fuel gas emission suppression device, which is characterized in that 2. The negative pressure holding means is provided in the fuel tank.
Depending on the fuel temperature, the time to hold at a predetermined negative pressure level
The abnormality detection device for a fuel gas emission suppression device according to claim 1, wherein the abnormality detection device is variably set . 3. The negative pressure holding means is an empty space of the fuel tank.
Depending on the parameters related to the volume
The abnormality detection device for a fuel gas emission suppression device according to claim 1 , wherein the holding time is set to be variable . 4. The negative pressure holding means is provided depending on a fuel property.
A variable negative pressure level holding time is set.
An abnormality detection device for the fuel gas emission suppression device according to 1 . 5. From the fuel tank to the intake passage of the engine
In addition to the pressure adjustment at the negative pressure level mentioned above,
Adjust the pressure at another pressure level different from the negative pressure level of
The pressure change condition of the former pressure adjustment and the latter pressure adjustment
Comparing the pressure change state of sage, said from the comparison result
Claim 1- Claim which detects the abnormality of a fuel gas discharge restraint device
Item 5. An abnormality detection device for a fuel gas emission suppression device according to any one of items 4 . 6. The fuel gas generated in the fuel tank is stored in a canister.
The fuel gas stored in the canister to the air.
Along with it, it will be discharged to the intake passage of the engine through the purge pipe.
It is applied to the fuel gas emission control device, and if the fuel tank and the intake passage of the engine are sealed.
Together, the pressure in the closed section is adjusted to a predetermined negative pressure level.
And the pressure change at that time after adjusting the pressure by the pressure adjusting means.
Detection of abnormality in the fuel gas emission control device
In the abnormality detecting and means, after the pressure adjustment in the negative pressure level by the pressure adjustment means
The negative pressure level adjusted at that time for a predetermined time
Negative pressure holding means for holding near the negative pressure holding means and the different pressure after holding the negative pressure for a predetermined time by the negative pressure holding means.
Start detection of pressure condition for normal detection Start of abnormality detection
Permitting means, and the negative pressure holding means responds to the fuel temperature in the fuel tank.
Then, set the time for holding at the specified negative pressure level to be variable.
Abnormality detecting device for that fuel emission control device. 7. The fuel gas generated in the fuel tank is stored in a canister.
The fuel gas stored in the canister to the air.
Along with it, it is discharged to the intake passage of the engine through the purge pipe.
It is applied to the fuel gas emission control device, and if the fuel tank and the intake passage of the engine are sealed.
Together, the pressure in the closed section is adjusted to a predetermined negative pressure level.
And the pressure change at that time after adjusting the pressure by the pressure adjusting means.
Detection of abnormality in the fuel gas emission control device
In the abnormality detecting and means, after the pressure adjustment in the negative pressure level by the pressure adjustment means
The negative pressure level adjusted at that time for a predetermined time
The negative pressure holding means for holding the negative pressure holding means in the vicinity and the negative pressure holding means for holding the negative pressure for a predetermined time after the different pressure
Start detection of pressure condition for normal detection Start of abnormality detection
Permitting means, and the negative pressure holding means relates to the space volume of the fuel tank.
Time to hold at a predetermined negative pressure level according to the parameter
An abnormality detection device for a fuel gas emission suppression device. 8. A fuel gas generated in a fuel tank is stored in a canister.
The fuel gas stored in the canister to the air.
Along with it, it is discharged to the intake passage of the engine through the purge pipe.
It is applied to the fuel gas emission control device, and if the fuel tank and the intake passage of the engine are sealed.
Together, the pressure in the closed section is adjusted to a predetermined negative pressure level.
And the pressure change at that time after adjusting the pressure by the pressure adjusting means.
Detection of abnormality in the fuel gas emission control device
In the abnormality detecting and means, after the pressure adjustment in the negative pressure level by the pressure adjustment means
The negative pressure level adjusted at that time for a predetermined time
The negative pressure holding means for holding the negative pressure holding means in the vicinity and the negative pressure holding means for holding the negative pressure for a predetermined time after the different pressure
Start detection of pressure condition for normal detection Start of abnormality detection
The negative pressure holding means is provided with a predetermined negative pressure level according to the fuel property.
An abnormality detection device for a fuel gas emission suppression device that variably sets the holding time . 9. A fuel gas generated in a fuel tank is stored in a canister.
The fuel gas stored in the canister to the air.
Along with it, it will be discharged to the intake passage of the engine through the purge pipe.
It is applied to the fuel gas emission control device, and if the fuel tank and the intake passage of the engine are sealed.
Together, the pressure in the closed section is adjusted to a predetermined negative pressure level.
And the pressure change at that time after adjusting the pressure by the pressure adjusting means.
Detection of abnormality in the fuel gas emission control device
In the abnormality detecting and means, after the pressure adjustment in the negative pressure level by the pressure adjustment means
The negative pressure level adjusted at that time for a predetermined time
The negative pressure holding means for holding the negative pressure holding means in the vicinity and the negative pressure holding means for holding the negative pressure for a predetermined time after the different pressure
Start detection of pressure condition for normal detection Start of abnormality detection
And a permitting means for sealing the fuel tank to the intake passage of the engine.
In addition to the pressure adjustment at the negative pressure level,
Pressure adjustment at another pressure level different from
Pressure change state during pressure adjustment and the latter pressure adjustment
Compared with the change state, the fuel gas exhaust
An abnormality detection device for a fuel gas emission suppression device that detects an abnormality in the emission suppression device. 10. The fuel gas generated in the fuel tank is stored in the tank.
Store the fuel gas in the canister and empty the fuel gas stored in the canister.
Discharge to the intake passage of the engine along with air through the purge pipe
It is applied to the fuel gas emission restraint device, and when the fuel tank to the intake passage of the engine is sealed
Together, the pressure in the closed section is adjusted to a predetermined negative pressure level.
And the pressure change at that time after adjusting the pressure by the pressure adjusting means.
Detection of abnormality in the fuel gas emission control device
In the abnormality detecting and means, after the pressure adjustment in the negative pressure level by the pressure adjustment means
The negative pressure level adjusted at that time for a predetermined time
The negative pressure holding means for holding the negative pressure holding means in the vicinity and the negative pressure holding means for holding the negative pressure for a predetermined time after the different pressure
Start detection of pressure condition for normal detection Start of abnormality detection
In the purge pipe between the permitting means and the canister and the intake passage of the engine
To adjust the purge flow rate to the provided intake passage
Of the purge control valve, and the negative pressure maintaining means controls the opening degree of the purge control valve.
Tee control to bring the pressure in the closed section to near the specified target negative pressure.
Different for fuel gas emission control device characterized by holding
Always detection device. 11. The fuel gas generated in the fuel tank is stored in the tank.
Store the fuel gas in the canister and empty the fuel gas stored in the canister.
Discharge to the intake passage of the engine along with air through the purge pipe
It is applied to the fuel gas emission restraint device, and when the fuel tank to the intake passage of the engine is sealed
Together, the pressure in the closed section is adjusted to a predetermined negative pressure level.
And the pressure change at that time after adjusting the pressure by the pressure adjusting means.
Detection of abnormality in the fuel gas emission control device
In the abnormality detecting and means, after the pressure adjustment in the negative pressure level by the pressure adjustment means
The negative pressure level adjusted at that time for a predetermined time
The negative pressure holding means for holding the negative pressure holding means in the vicinity and the negative pressure holding means for holding the negative pressure for a predetermined time after the different pressure
Start detection of pressure condition for normal detection Start of abnormality detection
In the purge pipe between the permitting means and the canister and the intake passage of the engine
To adjust the purge flow rate to the provided intake passage
Of the purge control valve, and the negative pressure maintaining means controls the opening degree of the purge control valve.
Control the tee to adjust the pressure in the closed section to the first predetermined pressure and the second
Fuel gas, characterized in that it is held between a predetermined pressure and
Anomaly detection device for emission control device. 12. The fuel gas generated in the fuel tank is stored in the tank.
Store the fuel gas in the canister and empty the fuel gas stored in the canister.
Discharge to the intake passage of the engine along with air through the purge pipe
It is applied to the fuel gas emission restraint device, and when the fuel tank to the intake passage of the engine is sealed
Together, the pressure in the closed section is adjusted to a predetermined negative pressure level.
And the pressure change at that time after adjusting the pressure by the pressure adjusting means.
Detection of abnormality in the fuel gas emission control device
In the abnormality detecting and means, after the pressure adjustment in the negative pressure level by the pressure adjustment means
The negative pressure level adjusted at that time for a predetermined time
The negative pressure holding means for holding the negative pressure holding means in the vicinity and the negative pressure holding means for holding the negative pressure for a predetermined time after the different pressure
Start detection of pressure condition for normal detection Start of abnormality detection
In the purge pipe between the permitting means and the canister and the intake passage of the engine
To adjust the purge flow rate to the provided intake passage
Of the purge control valve, and the negative pressure maintaining means controls the opening degree of the purge control valve.
Tee control to adjust the pressure in the closed section to the specified target negative pressure.
The first predetermined pressure on the positive pressure side and the predetermined target negative pressure
It is maintained between the second predetermined pressure on the negative pressure side and
Anomaly detection device for fuel gas emission control device.