Information
-
Patent Grant
-
6782695
-
Patent Number
6,782,695
-
Date Filed
Friday, October 4, 200222 years ago
-
Date Issued
Tuesday, August 31, 200420 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Brinks Hofer Gilson & Lione
-
CPC
-
US Classifications
Field of Search
US
- 060 274
- 060 276
- 060 285
- 060 277
- 701 109
- 701 115
- 701 103
- 123 103
- 123 109
- 123 115
-
International Classifications
-
Abstract
This invention relates to a method and apparatus for controlling the air-fuel ratio demanded by a fuel controller in order to maintain optimum performance of a catalytic converter. The invention provides a controller for requesting an air fuel ratio according to a switching value derived from an estimated oxygen storage value of a catalyst, in which the controller is arranged to perform the following stepsa) request a maximum ratio of air to fuel when the switching value is less than a first threshold;b) gradually decrease the requested air to fuel ratio from said maximum ratio;c) request a minimum ratio of air to fuel when the switching value is greater than a second threshold; andd) gradually increase the requested air to fuel ratio from said minimum ratio.
Description
This invention relates to a method and apparatus for controlling the air-fuel ratio demanded by a fuel controller in order to maintain optimum performance of a catalytic converter.
Three way catalytic converters are used to reduce exhaust emission of nitrous oxides (NO
x
) hydrocarbon (HC) and carbon monoxide (CO). In a steady sate of operation the performance of the catalyst in removing these pollutants is at an optimum level when the air fuel ratio of the exhaust gas is within a narrow range, close to the stoichiometric air-fuel ratio.
Conventionally, a fuel controller is used to control the air fuel ratio demand from an engine based on feedback from an air fuel ratio sensor upstream of a catalytic converter in the exhaust passage. In other known control systems two air-fuel ratio sensors are used, one upstream of the catalytic converter, and one downstream of the catalytic converter.
In one example of such fuel control schemes, the air fuel ratio demand is increased until the air fuel ratio sensor detects that the ratio demand is too lean, whereupon the requested air fuel ratio is switched to request the stoichiometric air fuel ratio, and gradually decreased until the air fuel ratio sensor detects that the ratio demand is too rich. In other examples, when the air fuel ratio becomes too rich or too lean the requested air fuel ratio is switched to request an air fuel ratio which is half way between the maximum and minimum air fuel ratios which have caused previous switching.
This invention provides a method and apparatus for operating an improved fuel control scheme in which exhaust emission of pollutants are reduced.
According to the present invention there is provided a fuel control system comprising a first sensor arranged to measure an air fuel ratio upstream of a catalyst; a second sensor arranged to measure an air fuel ratio downstream of the catalyst; a catalyst model arranged to determine oxygen storage characteristics of the catalyst; a catalyst model arranged to estimate an oxygen storage value of the catalyst in dependence upon the measured air fuel ratio upstream of the catalyst, upon the measured air fuel ratio downstream of the catalyst and upon the determined oxygen storage characteristics of the catalyst; a controller for requesting an air fuel ratio according to a switching value derived from the estimated oxygen storage value of the catalyst, in which the controller is arranged to perform the following steps
a) request a maximum ratio of air to fuel when the switching value is less than a first threshold;
b) gradually decrease the requested air to fuel ratio from said maximum ratio;
c) request a minimum ratio of air to fuel when the switching value is greater than a second threshold; and
d) gradually increase the requested air to fuel ratio from said minimum ratio.
There is a time delay between changing the air fuel ratio demand, and the resulting change in the estimated oxygen storage value which means that if the air fuel ratio demand is changed due to the estimated oxygen storage value reaching a predetermined threshold then that predetermined threshold will be exceeded, or ‘overshot’, due to the time delay. To alleviate the problem of the time delay, in a preferred embodiment a future oxygen storage value is predicted. Accordingly the fuel control system further comprises an oxygen storage predictor arranged to perform the following steps:
estimate a future oxygen storage value of the catalyst (
2
) in dependence upon the estimated oxygen storage value, the determined oxygen storage characteristics and a requested air fuel ratio; and
derive said switching value from the estimated future oxygen storage value.
As the catalyst ages the engine has to be run leaner to achieve a predetermined level of oxygen storage in the catalyst, and has to be run richer to achieve a predetermined level of oxygen depletion. To alleviate the problem of changing characteristics as the catalyst ages, in another embodiment of the invention, instead of controlling air fuel ratio demand using a predetermined estimated oxygen storage threshold the air fuel ratio may be controlled taking into account characteristics of the catalyst which are modelled by the catalyst model.
Therefore the oxygen storage predictor is arranged to derive said switching value from the estimated future oxygen storage value in dependence upon said oxygen storage characteristics.
Advantageously, the rate of decrease is dependant upon the difference between the switching value and the first threshold and the rate of increase is dependent upon the difference between the switching value and the second threshold.
According to another aspect of the present invention there is also provided a method of requesting an air fuel ratio according to a switching value derived from an estimated oxygen storage value of a catalyst comprising the steps of
a) requesting a maximum ratio of air to fuel when the switching value is less than a first threshold;
b) gradually decreasing the requested air to fuel ratio from said maximum ratio;
c) requesting a minimum ratio of air to fuel when the switching value is greater than a second threshold; and
d) gradually increasing the requested air to fuel ratio from said minimum ratio.
In a preferred embodiment said switching value is derived from an estimated future oxygen storage value, in which the estimated future oxygen storage value of the catalyst is estimated in dependence upon the estimated oxygen storage value, determined oxygen storage characteristics and a requested air fuel ratio
Preferably said switching value is derived from the estimated future oxygen storage value in dependence upon said oxygen storage characteristics.
Advantageously, the rate of decrease is dependant upon the difference between the switching value and the first threshold and the rate of increase is dependent upon the difference between the switching value and the second threshold.
An embodiment of the invention will now be described, by way of example only, with reference to the accompanying drawings in which
FIG. 1
is a block diagram illustrating use of a catalyst observer model;
FIG. 2
is a graph showing the difference in operation between a new catalyst, and one which has deteriorated;
FIG. 3
is a graph showing how catalyst characteristics change with age of the catalyst;
FIG. 4
is a block diagram illustrating an apparatus for implementing the fuel control scheme according to one embodiment of the invention;
FIG. 5
is a flow chart illustrating the steps which are performed in the method in one embodiment of the invention; and
FIGS. 6
a
to
6
d
are graphs illustrating how various parameters vary when the method of the flowchart of
FIG. 5
is implemented.
Referring now to
FIG. 1
, a model
1
of a catalyst
2
will be described. An air flow sensor
4
mounted in an intake pipe of an engine
3
is used to measure air mass flow induced by the engine
3
. In other embodiments of the invention the air mass flow may be estimated from other parameters, for example manifold pressure, engine speed and air temperature.
Exhaust gases from the engine
3
are fed to the catalyst
2
mounted in an exhaust pipe. A sensor
6
measures the air fuel ratio upstream of the catalyst
2
. A second sensor
7
measures the air fuel ratio down stream of the catalyst
2
. The sensor
7
may be a Universal Exhaust Gas Oxygen (UEGO) sensor or may be a Heated Exhaust Gas Oxygen (HEGO) sensor. A HEGO sensor senses whether the air-fuel ratio is rich or lean of stoichiometric, whereas a UEGO sensor provides a measurement of the air fuel ratio. The sensor
6
is a UEGO as a precise measurement of the upstream air fuel ratio is required. A sensor
8
measures the temperature of the catalyst
2
. The catalyst
2
does not perform well at low temperatures so the model
1
has the measured catalyst temperature as an input, and does not operate until the temperature of the catalyst reaches a minimum temperature. In other embodiments the catalyst temperature may be estimated using a catalyst model.
The observer model
1
operates as follows. Oxygen storage of the catalyst is represented by an oxygen storage variable φ which is equal to zero when the catalyst is in a neutral state, is negative if the catalyst is depleted of oxygen and is positive if the catalyst is oxygen rich.
The rate of change of the oxygen storage variable φ is estimated according to the following equation.
dφ/dt
=(Δλ
precat
−N
(φ)
S
wv
)*oxygen_mass/λ
precat
A precatalyst air fuel ratio λ
precat
is equal to air fuel ratio which is measured at the sensor
6
divided by the stoichiometric air fuel ratio. Δλ
precat
is equal to λ
precat
−1, therefore Δλ
precat
is negative if the air fuel ratio is rich of stoichiometric, and Δλ
precat
is positive if the air fuel ratio is lean of stoichiometric. The air mass flow measured at the sensor
4
is multiplied by a constant value 0.21 which is equal to the fraction of air by mass which is oxygen, this fraction is denoted oxygen_mass in the above equation.
N(φ)=Σa
1
φ
1
and represents the resistance to oxygen storage of the catalyst for a particular value of φ as illustrated in FIG.
2
.
S
wv
is equal to 0 when Δλ
precat
is negative i.e. the air fuel ratio is rich of stoichiometric and φ is greater than 0 i.e. there is excess oxygen stored in the catalyst.
It will be understood that when a rich air fuel ratio is supplied to the engine
3
, and when there is excess oxygen stored in the catalyst
2
, then the engine
3
emits gaseous components which can be oxidised by the catalyst
2
, and in this case S
wv
is equal to 0 so that
dφ/dt=Δλ
precat
*oxygen_mass/λ
precat
However, when a lean air fuel ratio is supplied to the engine
3
or when there is no oxygen stored in the catalyst
2
then S
wv
is equal to 1 so that
dφ/dt
=(Δλ
precat
−N
(φ))*oxygen_mass/λ
precat
so in this case dφ/dt is reduced by an amount equal to N(φ)*oxygen_mass/λ
precat
when compared to the previous case.
Est
(λ
postcat
)=
N
(φ)
S
wv
+1
λ
postcat
is the downstream air fuel ratio measured by the sensor
7
, divided by the stoichiometric air fuel ratio. φ is calculated by integrating the above differential equation, and then N(φ) is calculated. When S
wv
=0 then Est(λ
postcat
)=1, otherwise Est(λ
postcat
)=N(φ)+1.
Est (λ
postcat
) and the measured λ
postcat
are compared, and the difference between them is used to update the coefficients a
i
of the oxygen storage characteristic curve N(φ) and the φ value itself so that the model
1
more accurately represents the performance of the catalyst
2
. The coefficients a
i
are updated using a Kalman, filter, a description of which may be found in “Applied Optimal Estimation”, Gelb, the MIT press 1974.
FIG. 2
illustrates the differing N(φ) curves for a good catalyst compared with a deteriorated catalyst.
After the engine has been operating at a particular air fuel ratio for some time, then the oxygen stored in the catalyst will stabilise at a value which depends upon the operating air-fuel ratio, thus dφ/dt=0 and Δλ
precat
=Δλ
postcat
FIG. 3
illustrates an example oxygen storage characteristic curve showing the oxygen storage value when Δλ
precat
=Δλ
postcat
=0.1 and when Δλ
precat
=Δλ
postcat
=−0.1.
FIG. 3
illustrates how an oxygen storage characteristic curve may change for a deteriorated catalyst. The difference in the steady state oxygen storage value is illustrated for Δλ
precat
=Δλ
postcat
=−0.1 for two examples of oxygen storage characteristic curves. Hence it will be appreciated that if fuel control is implemented using air fuel ratio thresholds measured at the sensors
6
,
7
, then as the catalyst deteriorates, the fuel control scheme will allow breakthrough of NO
x
when the catalyst resists absorption of any more oxygen, and breakthrough of HC and CO when the catalyst is depleted of oxygen.
Therefore, in an improved fuel control scheme fuel control is achieved using the oxygen storage value φ which is estimated using the model
1
as described above. However, there are two reasons why φ may not be used directly to control the air fuel ratio demand of the engine. Firstly, there is a time delay between changing the air fuel ratio demand, and the resulting change in φ which means that if the air fuel ratio demand is changed due to φ reaching a predetermined threshold then that predetermined threshold will be exceeded, or ‘overshot’, due to the time delay. Secondly, as the catalyst ages, as shown in
FIG. 3
, the engine has to be run leaner to achieve a predetermined level of oxygen storage in the catalyst, and has to be run richer to achieve a predetermined level of oxygen depletion. Therefore, a predetermined threshold may only be reached by φ after breakthrough of NO
x
, or HC and CO has already occurred, in fact for an extremely aged catalyst the predetermined threshold may never be reached, and the fuel control scheme would cease to switch air fuel ratio demand at all.
To alleviate the problem of the time delay, in this embodiment of the invention, a future φ is predicted, as will be described shortly with reference to
FIG. 4
, and this predicted φ is used to trigger switching of the air fuel ratio requested. In other embodiments of the invention the threshold φ may simply be set to have a smaller magnitude so that switching is triggered before the maximum desired φ is reached, in order to overcome the problem of overshooting the maximum desired φ.
FIG. 4
illustrates a fuel controller
14
which sends an air fuel ratio request to the engine
3
in dependence upon an estimated future oxygen storage value received from an oxygen storage predictor
13
. Features of
FIG. 14
which are equivalent to features of
FIG. 1
are labelled with like numerals.
The oxygen storage predictor
13
uses values of φ and coefficients of N(φ), received from the catalyst model
1
, along with data from an engine model
9
to predict a value for φ a short time in the future. The engine model
9
receives the air fuel ratio request from the fuel controller
14
, an engine speed signal, which is measured by an engine speed sensor
5
, and the air fuel ratio measured by the sensor
6
, upstream of the catalyst
2
. The engine model
9
predicts a likely future upstream air fuel ratio based on the current upstream air fuel ratio, the air fuel ratio request and the engine speed. The likely future upstream air fuel ratio is used by the oxygen storage predictor
13
, together with values of φ and coefficients of N(φ) received from the catalyst model
1
to generate a prediction of φ (φ
pred
) a short time in the future.
A controller
10
receives φ
pred
from the oxygen storage predictor
13
and generates an air fuel ratio request according to the steps illustrated in the flow chart of FIG.
5
. φ
pred
is used as a switching value to determine when to switch from a lean air fuel request to a rich air fuel request and vice versa.
At step
50
the maximum and minimum λ (λ
max
and λ
min
) are set to predetermined maximum and minimum values respectively. λ
max
is set to a predetermined value greater than N(φ
max
)+1 and λ
min
is set to a predetermined value less than N(φ
min
)+1.
At step
52
the received prediction of φ (φ
pred
) is compared with the first threshold φ
max
. If φ
pred
is greater than φ
max
then this means that the air fuel mixture is becoming too lean, in which case step
56
is performed. Otherwise φ
pred
is compared with the second threshold φ
min
at step
54
. If φ
pred
is less than φ
min
then this means the air fuel mixture is becoming too rich, in which case step
58
is performed. If the air fuel mixture is becoming neither too rich nor too lean then step
60
is performed.
FIG. 6
a
illustrates variation of φ
pred
,
FIG. 6
b
illustrates corresponding variation of Est (λ
postcat
),
FIG. 6
c
illustrates the resulting effect on φ
peak
, and
FIG. 6
d
illustrates the resulting λ
req
.
Dealing firstly with the case where the air fuel mixture is becoming too lean i.e. at point
61
where φ
pred
is greater than φ
max
. At step
56
the air fuel ratio request λ
req
is set to λ
min
, illustrated at point
63
, which is the richest air fuel mixture which may be requested. λ
peak
is also set to λ
min
, λ
peak
is used to record the peak λ request from which the next λ
req
will be calculated at step
60
. φ
peak
is set to be equal to φ
pred
, illustrated at point
62
, φ
peak
is used to record a peak φ value from which the next λ
req
will be calculated at step
60
.
Secondly, when the air fuel is becoming too rich i.e. φ
pred
is less than φ
min
, illustrated at point
64
. At step
58
the air fuel ratio request λ
req
is set to λ
max
, illustrated at point
65
which is the leanest air fuel mixture which may be requested. λ
peak
is also set to λ
max
, λ
peak
is used to record the peak λ request from which the next λ
req
will be calculated at step
60
. φ
peak
is set to be equal to φ
pred
, illustrated at point
66
, φ
peak
is used to record a peak φ value from which the next λ
req
will be calculated at step
60
.
Finally, if the mixture is becoming neither too rich nor too lean i.e. φ
min
≦φ≦φ
max
, then step
60
is preformed. The air fuel ratio request λ
req
is either decreased or increased from the peak request λ
peak
depending upon a gain value, on the recorded value φ
peak
and upon φ
pred
. Increasing λ
req
from a minimum peak value is illustrated by a section of
FIG. 6
d
labelled
67
. Decreasing λ
req
from a maximum peak value is illustrated by a section of
FIG. 6
d
labelled
68
.
The difference between φ
peak
and φ
pred
is calculated. If φ
peak
is equal to φ
max
then this difference will be a positive value, and λ
peak
will be equal to λ
min
. It follows that λ
req
will be equal to λ
min
plus the difference between φ
max
and φ
pred
normalised by the maximum possible difference (φ
max
−φ
min
) and multiplied by a gain value. Therefore in this case λ
req
is increasing from the minimum possible air fuel ratio request in dependence upon the difference between the predicted oxygen storage value and the predetermined maximum oxygen storage value.
If φ
peak
is equal to φ
min
then this difference will be a negative value, and λ
peak
will be equal to λ
max
. It follows that λ
req
will be equal to λ
max
minus the difference between φ
pred
and φ
min
normalised by the maximum possible difference (φ
max
−φ
min
) and multiplied by a gain value. Therefore in this case λ
req
is decreasing from the maximum possible air fuel ratio request in dependence upon the difference between the predicted oxygen storage value and the predetermined minimum oxygen storage value. λ
req
is then capped at N(φ
min
)+1 or N(φ
max
)+1 appropriately.
To alleviate the problem of changing φ as the catalyst ages, in other embodiments of the invention, instead of controlling air fuel ratio demand using a predetermined threshold of φ, the air fuel ratio may be controlled using a predetermined threshold of N(φ). The result is that a predetermined threshold of N(φ) results in a threshold of φ which decreases in magnitude as the catalyst ages. Other techniques may of course be used to decrease this threshold as the catalyst ages.
In some exhaust systems there are two catalysts in series, each being capable of storing and releasing oxygen. In such systems, the air fuel ratio request may be controlled in dependence upon the oxygen storage state of both catalysts. Otherwise it could occur that the downstream catalyst is full of oxygen and is unable to remove NO
x
emissions from the upstream catalyst.
Claims
- 1. A fuel control system for monitoring engine exhaust of a vehicle having a catalyst, said system comprisinga first sensor arranged to measure an air fuel ratio upstream of the catalyst; a second sensor arranged to measure an air fuel ratio downstream of the catalyst; a catalyst model arranged to determine oxygen storage characteristics of the catalyst, the catalyst model further being arranged to estimate an oxygen storage value of the catalyst in dependence upon the measured air fuel ratio upstream of the catalyst, upon the measured air fuel ratio downstream of the catalyst, and upon the determined oxygen storage characteristics of the catalyst; an oxygen storage predictor arranged to determine a future oxygen storage value of the catalyst in dependence on the estimated oxygen storage value and a predicted future air fuel ratio; a controller adapted to request an air fuel ratio according to a switching value derived from the future estimated oxygen storage value, in which the controller is arranged to perform the following steps a) request a maximum ratio of air to fuel when the switching value is less than a first threshold; b) gradually decrease the requested air to fuel ratio from said maximum ratio; c) request a minimum ratio of air to fuel when the switching value is greater than a second threshold; and d) gradually increase the requested air to fuel ratio from said minimum ratio.
- 2. A fuel control system for monitoring engine exhaust of a vehicle having a catalyst, said system comprisinga first sensor arranged to measure an air fuel ratio upstream of the catalyst; a second sensor arranged to measure an air fuel ratio downstream of the catalyst; a catalyst model arranged to determine oxygen storage characteristics of the catalyst, the catalyst model further being arranged to estimate an oxygen storage value of the catalyst in dependence upon the measured air fuel ratio upstream of the catalyst, upon the measured air fuel ratio downstream of the catalyst, and upon the determined oxygen storage characteristics of the catalyst; an oxygen storage predictor arranged to provide the switching value to the controller, wherein the oxygen storage predictor estimates a future oxygen storage value of the catalyst in dependence upon the estimated oxygen storage value, the determined oxygen storage characteristics, and a requested air fuel ratio, and derives the switching value from the estimated future oxygen storage value; and a controller adapted to request an air fuel ratio according to a switching value derived from the estimated oxygen storage value of the catalyst, in which the controller is arranged to perform the following steps: a) request a maximum ratio of air to fuel when the switching value is less than a first threshold; b) gradually decrease the requested air to fuel ratio from said maximum ratio; c) request a minimum ratio of air to fuel when the switching value is greater than a second threshold; and d) gradually increase the requested air to fuel ratio from said minimum ratio.
- 3. A fuel control system according to claim 2, wherein the oxygen storage predictor is arranged to derive the switching value from the estimated future oxygen storage value in dependence upon the oxygen storage characteristics.
- 4. A fuel control system according to claim 1 wherein the rate of decrease in step b) is dependant upon the difference between the switching value and the first threshold and the rate of increase in step d) is dependent upon the difference between the switching value and the second threshold.
- 5. A fuel control system according to claim 2 wherein the rate of decrease in step b) is dependant upon the difference between the switching value and the first threshold and the rate of increase in step d) is dependent upon the difference between the switching value and the second threshold.
- 6. A fuel control system according to claim 3 wherein the rate of decrease in step b) is dependant upon the difference between the switching value and the first threshold and the rate of increase in step d) is dependent upon the difference between the switching value and the second threshold.
- 7. A method of requesting an air fuel ratio according to a future estimated oxygen storage value of a catalyst comprising the steps ofa) deriving a switching value from the future estimated oxygen storage value; b) requesting a maximum ratio of air to fuel when the switching value is less than a first threshold; c) gradually decreasing the requested air to fuel ratio from said maximum ratio; d) requesting a minimum ratio of air to fuel when the switching value is greater than a second threshold; and e) gradually increasing the requested air to fuel ratio from said minimum ratio.
- 8. A method of requesting an air to fuel ratio according to a switching value derived from an estimated oxygen storage value of a catalyst comprising the steps of:a) deriving the switching value from an estimated future oxygen storage value, in which the estimated future oxygen storage value of the catalyst is estimated in dependence upon the estimated oxygen storage value, determined oxygen storage characteristics, and a requested air fuel ratio; b) requesting a maximum ratio of air to fuel when the switching value is less than a first threshold; c) gradually decreasing the requested air to fuel ratio from said maximum ratio; d) requesting a minimum ratio of air to fuel when the switching value is greater than a second threshold; and e) gradually increasing the requested air to fuel ratio from said minimum ratio.
- 9. A method according to claim 8, in which the switching value is derived from the estimated future oxygen storage value in dependence upon said oxygen storage characteristics.
- 10. A fuel control system according to claim 7 wherein the rate of decrease in step b) is dependant upon the difference between the switching value and the first threshold and the rate of increase in step d) is dependent upon the difference between the switching value and the second threshold.
- 11. A fuel control system according to claim 8 wherein the rate of decrease in step b) is dependant upon the difference between the switching value and the first threshold and the rate of increase in step d) is dependent upon the difference between the switching value and the second threshold.
- 12. A fuel control system according to claim 9 wherein the rate of decrease in step b) is dependant upon the difference between the switching value and the first threshold and the rate of increase in step d) is dependent upon the difference between the switching value and the second threshold.
Priority Claims (1)
Number |
Date |
Country |
Kind |
01308485 |
Oct 2001 |
EP |
|
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