Information
-
Patent Grant
-
6470862
-
Patent Number
6,470,862
-
Date Filed
Wednesday, January 31, 200123 years ago
-
Date Issued
Tuesday, October 29, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Wolfe; Willis R.
- Gimie; Mahmoud
Agents
- Arent Fox Kintner Plotkin & Kahn
-
CPC
-
US Classifications
Field of Search
US
- 123 520
- 123 198 D
- 123 519
- 123 518
- 123 516
- 073 1181
-
International Classifications
-
Abstract
When a leakage fault occurs in the evaporated fuel processing system of a fuel tank, a control system reliably prevents leakage of the evaporated fuel from the point where the leakage fault has occurred. The fuel tank and a canister are connected to each other via a charge passage having a bypass valve, and the canister and an intake passage of an engine are connected to each other via a purge passage having a purge control valve. When a leakage fault occurs in the fuel tank (or the charge passage upstream of the bypass valve), the bypass valve and the purge control valve are opened and an atmosphere release control valve provided on the canister, is closed. The closure of the atmosphere release control valve stops the negative intake pressure of the engine from being consumed by the intake of air through the atmosphere release control valve, and thus it is possible to efficiently prevent the evaporated fuel from leaking from the point where the leakage fault has occurred by effectively transmitting the negative intake pressure to the point where the leakage fault has occurred.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to evaporated fuel processing systems in which a canister is charged with evaporated fuel generated in the fuel tank via a charge passage and the evaporated fuel purged from the canister is supplied to the intake passage of an engine via a purge passage.
2. Description of the Prior Art
An evaporated fuel processing system is provided in order to prevent evaporated fuel generated in the fuel tank of an automobile from diffusing into the atmosphere. The evaporated fuel processing system comprises a canister containing active carbon, which can be charged with and purged of the evaporated fuel. The fuel tank and the canister are connected to each other via a charge passage, and the evaporated fuel generated in the fuel tank is supplied to the canister via the charge passage and adsorbed by the active carbon. The canister is also connected to the intake passage of the engine via a purge passage, the fuel which has been adsorbed by the active carbon is purged by air which is taken into the canister through an atmosphere connection hole by means of the negative intake pressure, and the purged evaporated fuel is supplied to the intake passage of the engine via the purge passage.
Japanese Patent Application Laid-open No. 6-185420 discloses such an evaporated fuel processing system in which, after a pathway from the fuel tank to the intake passage of the engine has been depressurized by the negative intake pressure, a charge control valve provided in the charge passage is closed to seal the fuel tank (and the charge passage upstream of the charge control valve) at a reduced pressure, and detection of a leakage fault is attempted by monitoring changes in the internal pressure of the fuel tank thereafter. When a leakage fault is detected as an increase in the internal pressure of the fuel tank, both the charge control valve and the purge control valve are opened and the evaporated fuel within the fuel tank is sucked into the intake passage of the engine by means of the negative intake pressure to thereby prevent the evaporated fuel from diffusing into the atmosphere from the point where the leakage fault has occurred.
However, in the prior art, when a leakage fault is detected and the evaporated fuel within the fuel tank is sucked into the intake passage of the engine by means of the negative intake pressure, the atmosphere release control valve for opening and closing the atmosphere communication hole of the canister which is positioned between the fuel tank and the intake passage of the engine, is maintained in an open state. Therefore, the negative intake pressure of the engine is consumed by the intake of air from the atmosphere release control valve of the canister, and the negative intake pressure of the engine cannot be transmitted effectively to the point where the leakage fault has occurred, which is upstream of the atmosphere release control valve of the canister. As a result it is difficult to completely prevent the evaporated fuel from leaking from the point where the leakage fault has occurred.
SUMMARY OF THE INVENTION
The present invention has been conducted in view of the above mentioned circumstances, and when a leakage fault occurs in the evaporated fuel processing system of a fuel tank, it is an object of the present invention to reliably prevent the evaporated fuel from leaking from the point where the leakage fault has occurred.
In order to achieve the above-mentioned objective, in accordance with the present invention, an evaporated fuel processing system is proposed which comprises a fuel tank for holding fuel, a canister which can be charged with and purged of evaporated fuel, a charge control valve for opening and closing a charge passage which connects the fuel tank to the canister, a purge control valve for opening and closing a purge passage which connects the canister to an intake passage of an engine, and an atmosphere release control valve for opening and closing an atmosphere communication hole of the canister. A control means is provided which detects a leakage fault in the fuel tank or the charge passage upstream of the charge control valve, and when a leakage fault is detected the control means opens the charge control valve and the purge control valve and closes the atmosphere release control valve.
In accordance with the above-mentioned system, when a leakage fault is detected the charge control valve and the purge control valve are opened to transmit the negative intake pressure of the intake passage of the engine to the point where the leakage fault has occurred, the evaporated fuel is sucked into the intake passage of the engine by means of the negative intake pressure, and thus leakage from the point where the leakage fault has occurred can be prevented. Since the atmosphere release control valve of the canister is maintained in a closed state during this period, the negative intake pressure of the engine cannot be consumed by the intake of air from the atmosphere release control valve, and the negative intake pressure of the engine can be transmitted efficiently to the point where the leakage fault has occurred to effectively prevent the evaporated fuel from leaking from the point where the leakage fault has occurred.
Furthermore, an evaporated fuel processing system according to the present invention comprises a pressure detecting means for detecting the internal pressure of the fuel tank or the charge passage upstream of the charge control valve, and when the amount of leakage detected by the control means is less than or equal to a predetermined value, the control means controls the degree of opening of the purge control valve on the basis of the pressure detected by the pressure detecting means such that the internal pressure of the fuel tank becomes slightly negative.
In accordance with the above-mentioned system, since in the case where the amount of leakage is not more than a predetermined value the degree of opening of the purge control valve is controlled on the basis of the pressure detected by the pressure detecting means so that the internal pressure of the fuel tank is slightly negative. Thus the amount of evaporated fuel sucked into the intake passage of the engine can be minimized while at the same time preventing the leakage of evaporated fuel from the point where the leakage has occurred, and the time required for the canister to become fully charged can thus be extended.
Furthermore, an evaporated fuel processing system according to the present invention comprises a pressure detecting means for detecting the internal pressure of the fuel tank or the charge passage upstream of the charge control valve, and when the control means detects an open failure of the charge control valve, the control means controls the degree of opening of the purge control valve on the basis of the pressure detected by the pressure detecting means such that the internal pressure of the fuel tank becomes slightly negative.
In accordance with the above-mentioned system, where there is an open failure in the charge control valve, the degree of opening of the purge control valve is controlled on the basis of the pressure detected by the pressure detecting means. Thus the internal pressure of the fuel tank becomes slightly negative, and the time required for the canister to become fully charged due to the additional supply of evaporated fuel from within the fuel tank to the canister can be extended.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
to
FIG. 5
illustrate an embodiment of the present invention.
FIG. 1
is a diagram showing the entire structure of an evaporated fuel processing system in the case of a large leakage.
FIG. 2
is a diagram showing the entire structure of an evaporated fuel processing system in the case of a small leakage.
FIG. 3
is a diagram for explaining a method of detecting a leakage fault and a method of detecting a failure in the opening of the charge control valve.
FIG. 4
is a flow chart of the main routine of the present invention.
FIG. 5
is a flow chart of a purge control routine which makes the internal pressure of the tank negative.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
As shown in FIG.
1
and
FIG. 2
, a fuel tank
11
for an automobile comprises a filler tube
12
for supplying fuel from a fuel supply gun of a gasoline pump (not illustrated). A strainer
13
, a fuel pump
14
and a filter
15
are provided inside the fuel tank
11
, and fuel which has passed the filter
15
is supplied to an injector
19
provided on an intake passage
18
of an engine
17
via a feed pipe
16
.
A canister
20
inside which is stored active carbon and which can be charged with and purged of the evaporated fuel, is connected to the fuel tank
11
via a charge passage
21
, and a known two-way valve
22
which is formed by connecting two relief valves to each other in parallel and in opposite directions is positioned in the midsection of the charge passage
21
. In a bypass passage
23
which is connected to the both ends of the two-way valve
22
, there is provided a bypass valve
24
which corresponds to a charge control valve, comprising an ON/OFF solenoid valve for opening and closing the bypass passage
23
. A purge passage
25
which connects the canister
20
to the intake passage
18
of the engine
17
, is provided with a purge control valve
26
comprising a linear solenoid valve which can control the degree of opening in a stepless manner. Furthermore, an atmosphere communication hole
27
of the canister
20
is provided with an atmosphere release control valve
28
comprising an ON/OFF solenoid valve for opening and closing the atmosphere communication hole
27
.
A pressure detecting means
30
for detecting a pressure difference from atmospheric pressure, which is provided on the charge passage
21
between the fuel tank
11
and the upstream side of the bypass valve
24
, detects the internal pressure of the tank which is input into a control means
29
comprising a microcomputer. The control means
29
controls the opening and closing of the bypass valve
24
and the atmosphere release control valve
28
on the basis of the internal pressure of the tank detected by the pressure detecting means
30
and also controls the degree of opening of the purge control valve
26
.
Next, the action of the evaporated fuel processing system during usual operation (normal operation) is explained.
The bypass valve
24
and the purge control valve
26
are normally closed and the atmosphere release control valve
28
is normally open. When the temperature of the fuel tank
11
increases while the engine
17
is not running so as to increase the internal pressure, the positive pressure valve of the two-way valve
22
opens due to the internal pressure, the evaporated fuel generated within the fuel tank
11
and the expanded air are supplied to the canister
20
. The evaporated fuel is adsorbed by the active carbon inside the canister
20
, and the air alone is discharged through the atmosphere release control valve
28
. Thus it is possible to prevent the evaporated fuel from diffusing into the atmosphere as well as prevent the internal pressure of the fuel tank
11
from increasing excessively.
When the temperature of the fuel tank
11
decreases while the engine
17
is not running to thereby decrease the internal pressure, the negative pressure valve of the two-way valve
22
opens due to the difference in pressure from atmospheric pressure and air introduced through the atmosphere release control valve
28
is supplied to the fuel tank
11
. It is thus possible to prevent the fuel tank
11
from being distorted by the negative pressure.
Furthermore, the bypass valve
24
is opened to connect the fuel tank
11
to the atmosphere communication hole
27
prior to feeding fuel to the fuel tank
11
. Thus, even if the internal pressure of the fuel tank
11
is positive at this stage it can be reduced to atmospheric pressure, and it is possible to prevent evaporated fuel from diffusing into the atmosphere through the fuel inlet of the filler tube
12
.
Moreover, by opening the purge control valve
26
regularly during operation of the engine
17
to connect the canister
20
to the intake passage
18
of the engine
17
, the fuel with which the canister
20
has been charged can be purged by air taken in through the atmosphere communication hole
27
and the purged evaporated fuel can be supplied to the intake passage
18
of the engine
17
.
Next, the method of detecting a leakage fault of the fuel tank
11
(including a leakage fault in the charge passage
21
upstream of the bypass valve
24
) by means of the control means
29
and the method of detecting an open failure of the bypass valve
24
are explained by reference to FIG.
3
.
Checking for detection of a leakage fault is carried out periodically while the vehicle is travelling. Both the purge control valve
26
in the purge passage
25
and the bypass valve
24
in the charge passage
21
are opened while closing the atmosphere release control valve
28
of the canister
20
. As a result, the interior of the fuel tank
11
, the interior of the purge passage
25
and the interior of the charge passage
21
are depressurized by means of the negative intake pressure generated in the intake passage
18
of the engine
17
. When the bypass valve
24
is closed in this state, the interior of the charge passage
21
between the bypass valve
24
and the fuel tank
11
and the interior of the fuel tank
11
are sealed in a state in which they are depressurized at a pressure level P
1
. Since the pressure required for opening the negative pressure valve of the two-way valve
22
is lower than this level, the negative pressure valve is maintained in a closed state and the depressurization is not disturbed by the two-way valve
22
.
Changes in the pressure of the charge passage
21
are monitored over time by means of the pressure detecting means
30
. More particularly, after the bypass valve
24
is closed at time T
1
, the pressure is detected at time T
2
after a comparatively short time, and the pressure is detected again at time T
3
after a comparatively long time.
As a result, if the pressure which is P
1
at time T
1
, rapidly increases to P
2
at time T
2
and then remains unchanged until time T
3
, that is to say, if the difference (P
2
-P
1
) between P
2
and P
1
is not less than a predetermined threshold value, it is determined that there is a large leakage. A large leakage could be caused, for example, by the cap of the filler tube
12
of the fuel tank
11
dropping off to thereby connect the fuel tank
11
to the atmosphere as shown in FIG.
1
.
If the pressure which is P
1
at time T
1
, slightly increases to P
1
′ at time T
2
and then slowly increases to P
3
at time T
3
after a comparatively long time, that is to say, if the difference (P
3
-P
1
′) between P
3
and P
1
′ is not less than a predetermined threshold value, it is determined that there is a small leakage. A small leakage could be caused, for example, by a tiny hole
11
a being formed in the fuel tank
11
as shown in FIG.
2
.
If the pressure which is P
1
at time T
1
, decreases to P
4
at time T
2
, it is determined that an open failure has occurred in the bypass valve
24
(a failure due to it sticking in the open state). This is because if the bypass valve
24
is closed correctly when its closure is attempted at time T
1
, since the negative intake pressure of the engine
17
is blocked, the pressure should not decrease further.
Next, the control process which is carried out when a leakage fault occurs is explained by reference to the flow chart shown in FIG.
4
.
Firstly, in Step S
1
a determination is made as to whether or not any abnormality (large leakage, small leakage or open failure of the bypass valve
24
) has occurred. If there is no abnormality, the routine moves on to Step S
5
and the normal purge control is carried out. If there is some abnormality in Step S
1
, in Step S
2
it is determined whether the abnormality is a small leakage, in Step S
3
it is determined whether the abnormality is an open failure of the bypass valve
24
and in Step S
4
it is determined whether the abnormality is a large leakage, and the routine then moves on to Step S
6
to Step S
8
. Even in the case where it is decided in Step Si that there is some abnormality, if all the determinations in Step S
2
to Step S
4
are ‘NO’, a normal purge control is carried out in Step S
5
.
When a determination is made that there is a large leakage in Step S
4
, the bypass valve
24
is opened in Step S
6
and the atmosphere release control valve
28
is closed in Step S
7
. As a result, in Step S
8
the air which has been sucked from the point where the large leakage has occurred (for example, the filler tube
12
from which the cap has dropped off) is taken into the intake passage
18
of the engine
17
through the charge passage
21
in which the bypass valve
24
is fully opened, the canister
20
and the purge passage
25
in which the purge control valve
26
is fully opened, and thus the evaporated fuel is prevented from diffusing into the atmosphere through the point where the large leakage has occurred. At this stage since the atmosphere release control valve
28
provided on the atmosphere communication hole
27
of the canister
20
, is closed, air is prevented from entering via the atmosphere communication hole
27
and the canister
20
, and it is possible to suppress diffusion of the evaporated fuel into the atmosphere to a minimum level by taking in the maximum level of air from the point where the large leakage has occurred.
On the other hand, when a determination is made in Step S
2
that there is a small leakage, in Step S
9
the bypass valve
24
is opened, in Step S
10
the atmosphere release control valve
28
is closed, and further in Step S
11
the degree of opening of the purge control valve
26
provided on the purge passage
25
, is controlled to make the gauge pressure in the vicinity of the point where the small leakage has occurred (for example, the small hole
11
a
of the fuel tank
11
) slightly negative thereby preventing the evaporated fuel from diffusing into the atmosphere.
Also in the case where there is an open failure of the bypass valve
24
in Step S
3
, Steps S
9
to S
11
are carried out and the degree of opening of the purge control valve
26
is appropriately controlled. Thus, the evaporated fuel within the fuel tank
11
is prevented from being supplied excessively to the canister
20
through the bypass valve
24
in which there is an open failure, and it is possible to delay the canister
20
from becoming fully charged.
If a leakage fault or an open failure of the bypass valve
24
is detected, the driver is alerted of the need for a repair.
Next, the contents of Step S
11
are explained in detail by reference to the flow chart shown in FIG.
5
.
Firstly, the state of the tank internal pressure determination flag F_PTOBJ is determined in Step S
21
. When the tank internal pressure determination flag F_PTOBJ is, ‘1’ the internal pressure of the tank is lower than a target value, and when the tank internal pressure determination flag F_PTOBJ is ‘0’, the internal pressure of the tank is higher than the target value.
If the tank internal pressure determination flag F_PTOBJ is ‘0’ in Step S
21
and the internal pressure of the fuel tank is higher than the target value, in Step S
22
the actual tank internal pressure PTANK (the pressure detected by the pressure detecting means
30
) is compared with a predetermined tank internal pressure lower limit PTOBJL. If the actual tank internal pressure PTANK is less than the tank internal pressure lower limit PTOBJL, in Step S
23
the tank internal pressure determination flag F_PTOBJ is set to ‘1’ which indicates low pressure and in Step S
24
the predetermined tank internal pressure upper limit PTOBJH is made the target tank internal pressure PTOBJ.
Therefore, if the actual tank internal pressure PTANK is not less than the tank internal pressure lower limit PTOBJL in Step S
22
, in Step S
25
the tank internal pressure lower limit PTOBJL is used as the target tank internal pressure PTOBJ. If the actual tank internal pressure PTANK is less than the tank internal pressure lower limit PTOBJL in Step S
22
, in Step S
25
the tank internal pressure upper limit PTOBJH is used as the target tank internal pressure PTOBJ.
On the other hand, if the tank internal pressure determination flag F_PTOBJ is ‘1’ in Step S
21
and the internal pressure of the fuel tank is lower than the target value, in Step S
26
the actual tank internal pressure PTANK (the pressure detected by the pressure detecting means
30
) is compared with the predetermined tank internal pressure upper limit PTOBJH. If the actual tank internal pressure PTANK exceeds the tank internal pressure upper limit PTOBJH, in Step S
27
the tank internal pressure determination flag F_PTOBJ is set to ‘0’ which indicates high pressure and in Step S
28
the predetermined tank internal pressure lower limit PTOBJL is made the target tank internal pressure PTOBJ.
Therefore, if the actual tank internal pressure PTANK does not exceed the tank internal pressure upper limit PTOBJH in Step S
26
, in Step S
25
the tank internal pressure upper limit PTOBJH is used as the target tank internal pressure PTOBJ. If the actual tank internal pressure PTANK exceeds the tank internal pressure lower limit PTOBJL in Step S
26
, in Step S
25
the tank internal pressure lower limit PTOBJL is used as the target tank internal pressure PTOBJ.
When the target tank internal pressure PTOBJ has thus been determined on the basis of the actual tank internal pressure PTANK, the degree of opening of the purge control valve
26
, that is, the target flow QPGOBJ is calculated in Step S
25
. In detail, the value which is obtained by multiplying the deviation of the actual tank internal pressure PTANK from the target internal pressure PTOBJ by a factor KIPTOO is added to the previous value for the target flow QPGOBJ to give the current value for the target flow QPGOBJ. The tank internal pressure upper limit PTOBJH is, for example, −930 Pa, and the tank internal pressure lower limit PTOBJL is, for example, −1330 Pa.
In the subsequent Step S
29
the degree of opening of the purge control valve
26
is determined to obtain the target flow QPGOBJ, and in Step S
30
the atmosphere release control valve
28
is closed. As a result, the pressure detected by the pressure detecting means
30
is controlled to be in the vicinity of −670 Pa by the negative pressure of the intake passage
18
of the engine
17
, and this negative pressure works on the point where the small leakage has occurred to prevent the evaporated fuel from diffusing into the atmosphere. Furthermore, in the case where an open failure occurs in the bypass valve
24
, it is possible to delay the canister
20
from becoming fully charged due to excess supply of evaporated fuel to canister
20
by extracting the evaporated fuel from within the fuel tank
11
by means of a small degree of negative pressure of about −670 Pa.
In addition, since the canister
20
would become fully charged if the control process which is carried out when a leakage fault has occurred, that is, the control process which opens the purge control valve
26
and the bypass valve
24
while closing the atmosphere release control valve
28
, is continued over a long period, the control process is periodically switched over to purge control to purge the fuel within the fully charged canister
20
into the intake passage
18
of the engine
17
. That is, the bypass valve
24
is closed, the atmosphere release control valve
28
is opened and the purge control valve
26
is fully opened to suck air into the canister
20
through the atmosphere communication hole
27
, and the fuel with which the canister
20
has been charged is purged by means of the air.
The pressure detecting means
30
is provided on the charge passage
21
upstream of the bypass valve
24
in the embodiment described above, but the pressure detecting means
30
may be provided directly on the fuel tank
11
.
In accordance with the present invention, when a leakage fault is detected the charge control valve and the purge control valve are opened to transmit the negative intake pressure of the intake passage of the engine to the point where the leakage fault has occurred. The evaporated fuel is sucked into the intake passage of the engine by means of the negative intake pressure, and thus leakage from the point where the leakage fault has occurred can be prevented. Since the atmosphere release control valve of the canister is maintained in a closed state during this period, the negative intake pressure of the engine cannot be consumed by the intake of air from the atmosphere release control valve, and the negative intake pressure of the engine can be transmitted efficiently to the point where the leakage fault has occurred to effectively prevent the evaporated fuel from leaking from the point where the leakage fault has occurred.
In the case where the amount of leakage is not more than a predetermined value, the degree of opening of the purge control valve is controlled on the basis of the pressure detected by the pressure detecting means so that the internal pressure of the fuel tank is slightly negative. The amount of evaporated fuel sucked into the intake passage of the engine can be minimized while at the same time preventing the leakage of evaporated fuel from the point where the leakage has occurred, and the time required for the canister to become fully charged can thus be extended.
In the case where there is a failure in the opening of the charge control valve, the degree of opening of the purge control valve is controlled on the basis of the pressure detected by the pressure detecting means so that the internal pressure of the fuel tank becomes slightly negative, and the time required for the canister to become fully charged due to the additional supply of evaporated fuel from within the fuel tank to the canister can be extended.
The present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The presently disclosed embodiment is therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims, rather than the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are, therefore, to be embraced therein.
Claims
- 1. An evaporated fuel processing system for an engine having an intake passage, the system comprising:a fuel tank for holding fuel; a canister adapted to be charged with and purged of evaporated fuel; a charge passage for connecting the fuel tank and the canister; a charge control valve for opening and closing the charge passage connecting the fuel tank and the canister; a purge passage for connecting the canister and the intake passage of the engine; a purge control valve for opening and closing the purge passage connecting the canister and the intake passage of the engine; and an atmosphere release control valve for opening and closing an atmosphere communication hole of the canister; and a control means for detecting a leakage fault in the fuel tank or the charge passage upstream of the charge control valve; wherein when a leakage fault is detected the control means opens the charge control valve and the purge control valve and closes the atmosphere release control valve.
- 2. An evaporated fuel processing system according to claim 1, including a pressure detecting means for detecting the internal pressure of the fuel tank or the charge passage upstream of the charge control valve, wherein when the amount of leakage detected by the control means is less than or equal to a predetermined value, the control means controls the degree of opening of the purge control valve on the basis of the pressure detected by the pressure detecting means, such that the internal pressure of the fuel tank becomes negative.
- 3. An evaporated fuel processing system according to claim 1, includinga pressure detecting means for detecting the internal pressure of the fuel tank or the charge passage upstream of the charge control valve, wherein when the control means detects an open failure of the charge control valve, the control means controls the degree of opening of the purge control valve on the basis of the pressure detected by the pressure detecting means such that the internal pressure of the fuel tank becomes negative.
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