[0001] The present invention relates to a method for controlling an idling speed of an internal
combustion engine in which an injection amount is controlled by a feedback method
so as to keep a target engine speed when a vehicle runs under an idling condition
after a driver takes his or her foot off an accelerator while the vehicle runs.
[0002] An idling speed of an engine becomes stable at a rotating speed where a generated
torque of the engine and a load torque caused by a friction in the engine itself balance.
For example, if temperature is low, the idling speed is lowered since the friction
in the engine itself is increased resulted from an increased viscosity of the engine
lubricant oil. However, if the idling speed is lowered, the engine speed gets unstable,
therefore there is a possibility that the driver get an uncomfortable feeling. On
the other hand, if the idling speed is too high, the engine noise may be increased
and the fuel economy may be lowered.
[0003] To avoid above disadvantages, it is proposed that a method for controlling the injection
amount to a value that is necessary to keep the target idling speed even if the load
torque of the engine is changed. That is called as an idling speed control.
[0004] For example, in the idling speed control for an diesel engine, an actual engine speed
and a target engine speed obtained based on conditions such as a engine cooling water
temperature and a load of a compressor for an air conditioner, and the injection amount
is controlled by a PI type feedback method so that the target engine speed is achieved
in accordance with a difference between those of the engine speeds.
[0005] However, according to the conventional idling speed control, when a driver takes
foot off an accelerator in a running condition of a vehicle and runs the vehicle under
an idling condition, the actual engine speed may repeat overshoots until the actual
engine speed Ne convergences to the target engine speed Neisc. The repeated overshoots
are triggered by insignificant hunting oscillations caused by the PI type feedback
control, and causes a disadvantage that the driver may have unevenness about a drive
feeling.
[0006] The present invention was accomplished in consideration of the above-mentioned circumstances,
it is an abject of the present invention to provide a method for controlling an idling
speed of an internal combustion engine, which is capable of approaching the actual
engine speed to the target engine speed smoothly during the idling speed control executed
when the vehicle runs under the idling condition after the driver takes foot off the
accelerator while running the vehicle.
[0007] The method for controlling the idling speed of the present invention is characterized
by executing a injection correcting control for correcting the injection amount in
order to suppress an excessive drop of the engine speed (decreasing speed) caused
by a feedback control of the injection amount in accordance with a difference between
an actual engine speed and a target engine speed.
[0008] Accordingly, it is possible to prevent the actual engine speed from the excessive
drop with respect to the target engine speed, and to approaches the actual engine
speed smoothly to the target engine speed.
[0009] The injection correcting control may comprises a step of calculating a corrective
injection amount based on a decreasing speed of the engine speed. It is possible to
suppress a decreasing speed of the engine speed relative to a decreasing speed caused
by injecting a usual injection amount.
[0010] The injection correcting control may comprises a step of gradually increasing the
corrective injection amount as the actual engine speed approaches to the target engine
speed when the actual engine speed closely approaches to the target engine speed so
that 100 % of the corrective injection amount affects the engine speed. It is possible
to prevent the engine speed from an excessive quick deviation, and the driver is prevented
from an uncomfortable shock feeling.
[0011] The corrective injection amount may be different with respect to an engine load.
It is possible to execute the injection correcting control appropriately by varying
the corrective injection amount in accordance with the engine load, e.g. the corrective
injection amount is increased as the gear ratio is increased.
[0012] Features and advantages of embodiments will be appreciated, as well as methods of
operation and the function of the related parts, from a study of the following detailed
description, the appended claims, and the drawings, all of which form a part of this
application. In the drawings:
FIG. 1 is a control block diagram according to an embodiment of the present invention;
FIG. 2 is a flowchart showing a base routine of the embodiment;
FIG. 3 is a flowchart showing a subroutine of the embodiment;
FIG. 4 is a flowchart showing a subroutine of the embodiment;
FIG. 5 is a graph showing flags corresponding to an engine speed;
FIG. 6 is graph showing an affecting ratio coefficient Kd1;
FIG. 7 is a map showing a relationship among a load and a coefficient Kd2; and
FIG. 8 is a graph showing behaviors of the engine speed.
[0013] Hereinafter, an embodiment of the present invention is described with reference to
drawings.
[0014] FIG. 1 is a control block diagram of the embodiment, FIGS. 2 through 4 are flowcharts
showing processing order of an ECU which executes an idling speed control.
[0015] For instance, in this embodiment, the idling speed control is applied to a diesel
engine 1. The idling speed control executes a feedback control of an injection amount
by driving an injection device 3 via an Electronic Control Unit 2 so as to coincide
an actual engine speed Ne with a target engine speed Neisc when a vehicle runs under
an idling condition after a driver takes foot off an accelerator pedal while running
a vehicle. That is, during the driver taking foot off the accelerator, an operating
degree of the accelerator is 0. The ECU 2 inputs the operating degree of the accelerator
and other sensor signals such as the engine speed Ne. The ECU 2 has a block 2a for
obtaining a proportional component of an injection amount in accordance with a difference
(Neisc - Ne) between the engine speed Ne and the target engine speed Neisc. The ECU
2 has a block 2b for obtaining an integral component of the injection amount in accordance
with the difference. The ECU 2 also has a block 2c for obtaining a differential component
of the injection amount in accordance with the decreasing speed of the engine speed.
The ECU 2 has a switch block 2d for controlling the differential component in accordance
with conditions of the vehicle and the engine. The ECU 2 has adding blocks 2e and
2f for adding the components to obtain a conclusive corrective injection amount Qisc.
The ECU 2 has a block 2g for calculating a base injection amount Qbase for maintaining
the engine rotation in accordance with the operating degree of the accelerator and
the engine speed, for calculating a conclusive injection amount Q by summing the base
injection amount Qbase and the conclusive corrective injection amount Qisc, and for
controlling the injection device 3 so as to inject and supply the conclusive injection
amount Q to the engine 1.
[0016] A processing order of the idling speed control with the ECU 2 is explained with reference
to a base routine shown in FIG. 2 and subroutines shown in FIGS. 3 and 4. Hereinafter,
functions of each step are explained step by step.
[0017] In a step 100, a corrective amount Pi for P term, proportional component, is calculated
by the following expression (1). In this embodiment, the corrective amount Pi is calculated
as a base injection amount for an idling speed control.

[0018] In a step 200, corrective amounts Ii and Di for I and D terms, integral and differential
components, are calculated and read into the main routine.
[0019] In a step 300, a conclusive corrective injection amount Qisc is calculated by summing
the corrective amounts Pi, Ii and Di.
[0020] Next, a process in the step 200 is explained.
[0021] In a step 201, it is determined that whether an initial process is completed or not.
In the initial process, for instance, it is determined that whether an engine-starting
switch (an ignition key) is turned on or not. If the engine-starting switch is turned
on (YES) the process proceeds to a step 202, if the engine-starting switch is already
turned on (NO) the process proceeds to a step 203.
[0022] In a step 202, initial values are set to flags for showing conditions of the vehicle
used in the process as follows: an ISC executing flag F0 = 1, a running condition
flag F1 = 0, and a D term correction flag F2 = 0.
[0023] In steps 203 through 210, conditions of the vehicle are determined into three categories
as shown in FIG. 5.
[0024] In a step 203, a value of the flag F2 is identified. If F2 = 1 (YES), the process
proceeds to the step 204, if F2 = 0 (NO), the process proceeds to the step 206.
[0025] In a step 204, it is determined that whether the following EVENT A is satisfied or
not. EVENT A: Ne < Neisc + ΔN2, or the driver takes foot off the accelerator and Ne
is not changed (is stable). Here, ΔN2 is a threshold value to determine whether the
correction of D term should be stopped or not a shown in FIG. 5. If the EVENT A is
satisfied (YES) the process proceeds to the step 205, if it is not satisfied (NO)
the process proceeds to the step 208.
[0026] In a step 205, in this case, since the engine speed Ne is decreased from a D term
correction region II to an ISC region I, the process proceeds to a step 211 after
setting the flags as follows: the ISC executing flag F0 = 1, F1 = 1, F2 = 0.
[0027] In a step 206, a value of the flag F1 is identified. If F1 = 1 (YES) the process
proceeds to the step 207, if the F1 = 0 (NO) the process proceeds to the step 209.
[0028] In a step 207, it is determined that whether the following EVENT B is satisfied or
not. EVENT B: Ne < Neisc + ΔN1. Here ΔN1 is a threshold value to determine whether
the Di term correction should be executed or not as shown in FIG. 5. If the EVENT
B is satisfied (YES) the process proceeds to the step 208, if it is not satisfied
(NO) the process proceeds to the step 210.
[0029] In a step 208, in this case, since the engine speed Ne is decreased from a running
region III to the D term correction region II as shown in FIG. 5, the process proceeds
to a step 211 after setting the flags as follows: the Di term correction executing
flag F2 = 1, F0 = 0, F1 = 0.
[0030] In a step 209, it is determined that whether the following EVENT C is satisfied or
not. EVENT C : Ne ≥ Neisc + ΔN1. If the EVENT C is satisfied (YES) the process proceeds
to the step 210, if the EVENT C is not satisfied (NO) the process proceeds to the
step 205. Here, the ΔN1 is a greater value than the ΔN2.
[0031] In a step 210, in this case, since the engine speed (Ne) is increased from the ISC
region I to the running region III as shown in FIG. 5, the process proceeds to a step
211 after setting the flags as follows: the running condition flag F1 = 1, F0 = 0,
F2 = 0.
[0032] Next, the corrective amounts Ii and Di for the I term and the D term are calculated
in accordance with the running condition of the engine.
[0033] In a step 211, a value of the flag F2 is identified. If F2 = 1 (YES) the process
proceeds to a step 212, if F2 = 0 (NO) the process proceeds to a step 214. In a step
212, a differential component is calculated. The step 212 is activated only when the
engine speed is approaching to the target engine speed and the engine speed is within
a predetermined range. In the step 212, the process proceeds to a step 213 after calculating
the corrective amount Di for the D term by the following expression (2).

Kd: coefficient (affecting ratio coefficient), dNe/dt: decreasing speed of the
Ne.
[0034] Here, it is necessary to be effective the corrective amount smoothly as the actual
engine speed Ne approaches to the target engine speed Neisc, since if all (100 %)
of the calculated corrective amount Di for D term is injected at once the engine speed
quickly deviates and the driver may feel an uncomfortable shock. Therefore, the coefficient
Kd is obtained as the product of a coefficient Kd1 and Kd2 as shown in FIGS. 6 and
7. The coefficient Kd1 is obtained based on a difference between the Ne and the Neisc.
The coefficient Kd1 is set to increase the corrective amount gradually so as to affect
100 % of the corrective amount for Di term when the engine speed Ne coincides with
the target engine speed Neisc. The coefficient Fd2 is determined by parameters such
as an engine load as shown in FIG. 7, if the vehicle runs on a flat road and is in
a constant temperature condition. The load may be obtained by a signal from a transmission
indicative of gear positions. For example, it is necessary to increase torque generated
by the engine 1 to obtain an even torque (deceleration) on a driving wheel as a gear
position (ratio) is increased. Therefore, the corrective injection amount is also
increased.
[0035] In a step 213, the process proceeds to a step 220 after replacing the corrective
amount Ii-1 calculated in the last time with the present corrective amount Ii.
[0036] In a step 214, a value of the flag F0 is identified. If F0 = 1 (YES) the process
proceeds to a step 215, if F0 = 0 (No) the process proceeds to a step 218. In a step
215, it is determined that whether the flag F0 = 1 is set in the present process or
not. If the determination is YES the process proceeds to a step 216, if the determination
is NO (the ISC control has been already executed) the process proceeds to a step 219.
[0037] In a step 216, the process proceeds to a step 217 after calculating the corrective
amount Ii for the I term by the following expression (3).

[0038] In this step, the corrective amount Di calculated in the step 212 is added only when
the flags are changed from F2 = 1 to F0 = 1, i.e. only when the corrective amount
Ii is calculated for the first time. Accordingly, it is possible to suppress drop
of the engine speed Ne when it is changed from the D term correction region II to
the ISC executing region I, and to provide a smooth transition of the corrective amount.
[0039] In a step 217, the process proceeds to a step 220 after setting Di = 0. In this step,
Di = 0 is set so that adding the corrective amount Di is substantially inhibited for
a second or later calculation of the corrective amount Ii.
[0040] In a step 218, the process proceeds to the step 220 after calculating the corrective
amount Ii by the following expression (4).

[0041] In a step 210, the process proceeds to the step 220 after calculating the corrective
amount Ii by the following expression (5).

[0042] In a step 220, the corrective amounts Ii-1 and Di-1 calculated in the last time are
replaced with the corrective amounts Ii and Di calculated in the present process.
(Advantages of the embodiment)
[0043] According to the embodiment, if the engine speed is decreased when the driver takes
foot off the accelerator while the running condition of the vehicle, a corrective
injection amount for correcting the injection amount is obtained on a vicinity of
the target engine speed (Neisc + ΔN2 ≤ Ne < Neisc + ΔN1). Therefore, it is possible
to suppress a decreasing speed of the engine speed relative to a conventional idling
speed control using a PI type feedback control. Accordingly, it is possible to prevent
the engine speed from an excessive drop (overshoot) with respect to the target engine
speed. It is possible to approach the engine speed smoothly to the target engine speed
as shown in FIG. 8 with a solid line. If the driver takes foot off the accelerator
while the running condition of the vehicle, an engine speed decreases to a target
engine speed for an idling condition. A corrective injection amount is calculated
and added on a base injection amount when the engine speed is in a vicinity of the
target engine speed (Neisc + ΔN2 ≤ Ne < Neisc + ΔN1). The corrective injection amount
is calculated based on a decreasing speed dNe/dt of the Ne. The corrective amount
is gradually increased by an affecting ratio coefficient Kd1 so that 100 % of the
corrective amount is fully effective when the engine speed Ne coincides with the target
engine speed Neisc. As a result, it is possible to suppress a decreasing speed of
the engine speed. It is possible to prevent the engine speed from an excessive drop
with respect to the target engine speed. It is possible to approach the engine speed
smoothly to the target engine speed.
1. A method for controlling an idling speed of an internal combustion engine (1), the
method comprising the steps of:
controlling an injection amount by a feedback method so as to maintain a target engine
speed when a vehicle runs under an idling condition after a driver takes foot off
an accelerator while running a vehicle, characterized in that
the injection amount is corrected (2b, 2c, 2e, 2f) in order to suppress an excessive
drop of the engine speed that may be caused by a feedback control of the injection
amount in accordance with a difference between an actual engine speed and a target
engine speed.
2. The method for controlling the idling speed of the internal combustion engine according
to claim 1, wherein the method comprising the steps of:
calculating (2a) a base injection amount (Pi) for an idling speed control in accordance
with a difference (Neisc - Ne) between the actual engine speed and the target engine
speed;
calculating (2b, 2c) a corrective injection amount (Di) based on a decreasing speed
(dNe/dt) of the engine speed;
obtaining (2e, 2f) a conclusive injection amount (Qisc) for the idling speed control
by summing the base injection amount and the corrective injection amount.
3. The method for controlling the idling speed of the internal combustion engine according
to claim 2, further comprising the step of gradually increasing (2c) the corrective
injection amount (Di) as the actual engine speed approaches to the target engine speed
so that 100 % of the corrective injection amount affects the engine speed when the
actual engine speed is substantially coincide with the target engine speed.
4. The method for controlling the idling speed of the internal combustion engine according
to claim 2 or 3, wherein the corrective injection amount is different with respect
to an engine load.
5. The method for controlling the idling speed of the internal combustion engine according
to one of claims 2 through 4, wherein the step of calculating (2c) the corrective
injection amount (Di) based on the decreasing speed (dNe/dt) of the engine speed is
activated only when the engine speed is approaching to the target engine speed and
the engine speed is within a predetermined range (Neisc + ΔN2 ≤ Ne < Neisc + Δn1).
6. The method for controlling the idling speed of the internal combustion engine according
to one of claims 2 through 5, wherein the method further comprising the steps of:
calculating a base injection amount (Qbase) for rotating the engine;
calculating a conclusive injection amount (Q) by summing the base injection amount
(Qbase) and the conclusive injection amount (Qisc) for the idling speed control; and
injecting the conclusive injection amount (Q) into the engine.
7. The method for controlling the idling speed of the internal combustion engine according
to claim 1, wherein the method comprising the steps of:
calculating a base injection amount (Qbase) for rotating the engine;
calculating a proportional component (Pi) for executing an idling speed control based
on a difference (Neisc - Ne) between the engine speed and the target engine speed;
calculating a conclusive injection amount (Q) by summing the base injection amount
(Qbase) and the proportional component (Pi);
injecting the conclusive injection amount (Q) to the engine;
calculating a differential component (Di) for executing an idling speed control based
on a decreasing speed (dNe/dt) of the engine speed;
calculating a conclusive injection amount (Q) by summing the base injection amount
(Qbase), the proportional component (Pi) and the differential component (Di) when
the engine speed is within a predetermined range (Neisc + ΔN2 ≤ Ne < Neisc + Δn1)
which is set slightly above the target engine speed; and
injecting the conclusive injection amount (Q) to the engine when the engine speed
is within the predetermined range.
8. The method for controlling the idling speed of the internal combustion engine according
to claim 7, wherein the differential component (Di) is calculated so as to increase
the differential component as the engine speed approaches to the target engine speed.
9. The method for controlling the idling speed of the internal combustion engine according
to claim 7, wherein the differential component (Di) is calculated so as to affect
100 % of the differential component affects the idling speed control when the engine
speed substantially coincide with the target engine speed.
10. The method for controlling the idling speed of the internal combustion engine according
to claim 7, wherein the differential component (Di) is calculated so as to increase
the differential component as an engine load increases.