JP3455678B2 - Fail safe control device for electronically controlled throttle type internal combustion engine - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an internal combustion engine equipped with an electronically controlled throttle system that opens and closes a throttle valve interposed in an intake system by an actuator based on at least an accelerator opening degree, and more particularly, The present invention relates to a fail-safe control technique when one of the throttle opening sensors fails in a system including at least two throttle opening sensors and selecting and using one of the detected values.

[0002]

2. Description of the Related Art Conventionally, based on the accelerator opening (accelerator pedal depression amount) or it and the engine speed, etc.,
There is an electronically controlled throttle system that electronically controls the opening of a throttle valve so as to obtain a target air amount (Japanese Patent Laid-Open No. 7-1
80570, etc.). Among such electronically controlled throttle systems, those that do not have a fail-safe mechanism that mechanically interlocks the throttle valve with a wire etc. by accelerator operation when the drive system fails (full electronically controlled throttle system), for example, The following method is adopted. Two accelerator opening sensors and two throttle opening sensors are provided, and for the accelerator opening, the smaller one of the two detected values is selected (to prevent excessive output),
Regarding the throttle valve opening, the detected value of the main throttle opening is used, and in some cases, the larger one of the two detected values is selected (the larger one is selected for feedback control and the smaller one is selected). (To prevent excessive output by making a correction).

[0003]

By the way, in the electric throttle system having at least two throttle opening sensors as described above, if one of the throttle opening sensors fails (hereinafter referred to as a single failure), it remains. The throttle valve opening is feedback-controlled using the detection value of only one sensor, but the opening of the remaining throttle valve does not correspond to the accelerator opening for some reason, and may increase excessively. In this case, in the method of setting the fuel injection amount based on the intake air amount detected by a general air flow meter and the engine rotation speed, the fuel injection amount is also increased by the increase of the intake air amount corresponding to the increase of the throttle opening. There was a case where the engine output was increased too much because it was set excessively. Even in the method of setting the fuel injection amount based on the throttle valve opening and the engine rotation speed, the fuel injection amount is excessively increased and set due to the increase of the throttle valve opening, and the engine output similarly increases. It will pass.

In view of the above situation, in the above fully electronic throttle system, even if only one throttle opening sensor fails, for example, the energization of the actuator for driving the throttle valve is stopped and the return spring is returned. There is also one in which a predetermined default opening is maintained by the balance between the default spring and the default spring. However, in the limp home control for maintaining the default opening, the maximum vehicle speed is limited to about 40 km. Moreover, since the failure rate is high among the components of the electronically controlled throttle system, it has been required to guarantee a certain level of running performance in the event of a single failure of the throttle valve opening sensor.

The present invention has been made in view of such a conventional problem, and is a fail-safe electronically controlled throttle internal combustion engine capable of obtaining an appropriate engine output in the event of a single failure of the throttle opening sensor. An object is to provide a control device.

[0006]

Therefore, as shown in FIG. 1, the invention according to claim 1 interposes in an intake system according to an engine operating condition including a detected value of an accelerator opening by an accelerator opening sensor. has been provided with a electronic throttle system to open and close by an actuator so that the target opening degree of the throttle valve, 2 throttle opening sensor for detecting an opening degree of the throttle valve Kosonae, one of the throttle opening sensor <br ) Is selected to adjust the throttle valve to the target opening.
In an electronically controlled throttle internal combustion engine used for feedback control, one of the two throttle opening sensors
When a card fails, the remaining one non-failed slot
Select the detection value of the opening sensor to open the throttle valve target.
Feedback control every time, the throttle opening sensor
When both are normal, the mass by the intake air amount detection means
Based on the detected value of intake air amount and the detected value of engine speed
And the fuel injection amount is set by one of the two throttle opening sensors, and when one of the two throttle opening sensors fails, based on the detected value of the accelerator opening and the detected value of the engine rotational speed by the engine rotational speed detecting means. Set fuel injection amount (first) Fuel injection amount
It is characterized in that it is configured to include a switching setting means .

According to this structure, when one of the throttle opening sensors fails, the opening value of the throttle valve is feedback-controlled by using the detection value of the remaining sensor. Even if an abnormal increase occurs, the fuel injection amount switching setting means causes the accelerator opening degree detected by the accelerator opening degree sensor operated by the driver's intention and the engine rotation speed to be changed. Since the fuel injection amount is set based on, the increase in the fuel injection amount can be suppressed without depending on the increase in the intake air amount even if the intake air amount increases with the increase in the throttle valve opening. Further, the desired engine output can be obtained by setting the proper fuel injection amount without the engine output being excessively restricted by limiting the throttle valve opening to the default opening.

Further , the fuel injection amount switching setting means is
When both of the tortle opening sensors are normal, the fuel injection amount is set based on the detected value of the intake air amount by the intake air amount detection means and the detected value of the engine rotation speed. Based on the detected value and the detected value of the engine rotation speed, the fuel injection amount control can be performed with high accuracy corresponding to the intake air amount.

Further, according to the second aspect of the present invention, as shown in FIG. 2, the target is a throttle valve interposed in the intake system according to the engine operating condition including the detected value of the accelerator opening by the accelerator opening sensor. An electronically controlled throttle system that opens and closes with an actuator so that the opening is opened, and two throttle opening sensors that detect the opening of the throttle valve are provided, and the detection value of one throttle opening sensor is selected.
For feedback control to the target opening of the throttle valve
In electronic throttle internal combustion engine to be used, the Ro
When one of the two throttle opening sensors fails,
Detection of one remaining throttle opening sensor that has not failed
Select a value and feed back the throttle valve to the target opening
The fuel injection is controlled based on the detected value of the accelerator opening and the engine speed detected by the engine speed detection means when one of the two throttle opening sensors fails. Amount, and the fuel injection amount set based on the detected value of the mass intake air amount by the intake air amount detection means and the detected value of the engine rotation speed, the smaller value is selected and set, and the throttle opening is set. When both sensors are normal,
It is characterized in that it is configured to include (second) fuel injection amount switching setting means for setting the fuel injection amount based on the detected value of the mass intake air amount and the detected value of the engine rotation speed.

According to this structure, in the case of the invention according to claim 1, when the air density is lowered due to a single malfunction of the throttle sensor during traveling at high altitudes, the accelerator opening is increased, and therefore the accelerator opening and the engine speed are increased. When the fuel injection amount is set based on the speed and the fuel injection amount may become excessive, when the fuel injection amount is set based on the detected value of the mass intake air amount and the detected value of the engine rotation speed. In this case, the fuel injection amount is not set excessively because it is not affected by the decrease in air density. Since the latter one of the smaller fuel injection amounts is selected, an appropriate engine output can be secured.

Further, in the invention according to claim 3 , the fuel injection amount switching setting means is set in response to the failure when one of the two throttle opening sensors fails. It is characterized by including a function of setting a lower limit value of the fuel injection amount corresponding to a lower limit value of the throttle valve opening.
According to this configuration, when the single failure occurs in a state where the accelerator opening is too small (for example, open state),
Although the throttle valve has the lower limit value (default opening) corresponding to the failure, the accelerator opening is smaller, so the fuel injection amount set based on the accelerator opening and the engine speed. Is too small, causing a delay in the rise of the fuel injection amount and possibly causing a stall.However, by setting the lower limit value of the fuel injection amount corresponding to the lower limit value of the throttle valve, the stall is prevented. And a stable limp home function can be secured.

Further, the invention according to claim 4 is characterized in that two accelerator opening sensors are provided, and a detection value of one sensor is selected and used. According to this structure, two accelerator opening sensors are provided, and a failure or abnormality can be dealt with by selecting and using the detection value of one sensor, for example, the smaller value.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. FIG. 3 shows the system configuration of an embodiment of the present invention. Two accelerator position sensors (APS) 1
A and 1B detect the depression amount (accelerator opening) of the accelerator pedal depressed by the driver.

The crank angle sensor 2 generates a position signal for each unit crank angle and a reference signal for each cylinder stroke phase difference, and measures the number of generated position signals per unit time, or the reference signal generation. The engine speed can be detected by measuring the cycle. The air flow meter 3 detects a mass intake air amount to the engine 4 (hereinafter, simply referred to as intake air amount).

The water temperature sensor 5 detects the cooling water temperature of the engine. The engine 4 is provided with a fuel injection valve 6 that is driven by a fuel injection signal and directly injects fuel into the combustion chamber, and a spark plug 7 that is mounted in the combustion chamber and ignites. The direct injection method into the combustion chamber enables lean formation by stratified combustion, and the air-fuel ratio can be variably controlled over a wide range.

A throttle valve 9 is provided in the intake passage 8 of the engine 4, and an actuator 10 capable of electronically controlling the opening of the throttle valve 9 is provided. Further, the throttle valve 9 has two throttle opening degree sensors (TPS) 11A, 1 for detecting the opening degree of the throttle valve 9.
1B is provided. The exhaust passage 12 is provided with an air-fuel ratio sensor 13 as an air-fuel ratio detecting means for detecting the air-fuel ratio of the combustion mixture by detecting the concentration of a specific component such as oxygen in the exhaust.

Detection signals from the various sensors are input to the control unit 14, and the control unit 14 drives the actuator 11 according to the operating state detected based on the signals from the sensors. The opening of the throttle valve 9 is controlled, the fuel injection valve 6 is driven to control the fuel injection amount (fuel supply amount), the ignition timing is set, and the ignition plug 7 is ignited at the ignition timing. To do.

Next, the accelerator opening sensors 1A and 1B
Also, regarding the failure diagnosis of the throttle opening sensors 11A and 11B and the fail-safe control (limp home control) at the time of the failure, particularly focusing on the limp home control at the time of the single failure of the throttle opening sensor according to the present invention, FIG. This will be described with reference to FIG. In the figure, the accelerator opening sensor system diagnosis will be described.
In the output diagnosis of B, open and short faults are detected, and the flags APS1CA and APS2CA are set to 1 when a fault occurs. However, in order to eliminate a transient fault, when the fault condition continues for a predetermined delay time, a flag is set. APS
1NG and APS2NG are set to 1 to confirm the failure of the accelerator opening sensors 1A and 1B. In addition, when each flag (including flags to be described later) is set to 1,
The output to each circuit described below is at a high level, and when reset to 0, the output to each circuit is set to a low level.

Further, it is diagnosed whether the difference between the accelerator opening sensors 1A and 1B is large and there is a mismatch (APS mismatch diagnosis).
Also, the flag APSXCA is set to 1 when there is a mismatch, but in this case as well, the flag APSXNG is set to 1 when the mismatch condition continues for a predetermined delay time in order to remove the excessive mismatch. And determine that it is inconsistent.

On the other hand, the throttle opening sensor system diagnosis is the same as the accelerator opening sensor system diagnosis. That is, the open / short failure of the throttle opening sensors 11A, 11B is detected and the flags TPS1CA, TPS2CA are set to 1 when the failure occurs, but when the failure state continues for a predetermined delay time, the flag TP is set.
S1NG and TPS2NG are set to 1 to confirm the failure of the throttle opening sensors 11A and 11B, and when the difference between the throttle opening sensors 11A and 11B is largely inconsistent, the flag TPSXCA is set to 1. When the inconsistent state continues for a predetermined delay time, a flag TPS
Set XNG to 1 to confirm.

Regarding the accelerator opening sensor system, three flags APS1NG, APS2NG, APS are used.
When both XNG are 0 (first from the top of the table of the same system), that is, when the diagnosis results of the accelerator opening sensor system are all normal, the smaller value among the two detected values of the accelerator opening sensors 1A and 1B Select (LOWER). Also, regarding the throttle opening sensor system, three flags TP
When S1NG, TPS2NG and TPSXNG are all 0 (first from the top of the table of the same system), the detection value TPO1 of one throttle opening sensor 14A is selected.

If all systems are diagnosed to be normal, there is no need for limp home, so the limp home permission flag is set to 0 when the sensor has a single failure. Therefore, if both systems are all normal, the actuator 1
1 is driven to reach the target throttle opening degree set based on the smaller accelerator opening degree APO,
The opening degree of the throttle valve 9 is controlled. Also in this case,
Since the output of the first OR circuit 31 is maintained at the low level, the warning lamp 32 does not light up.

When only the mismatch flag APSXCA (TPSXCA) is set to 1 for at least one system (second in the table of each system), which of the accelerator opening sensors 1A and 1B (throttle) is used. It is determined that the detected values of the opening sensors 14A, 14B) are also unreliable, and the first OR circuit 31 goes to a high level and the warning light is turned on as shown in FIG. 32. Similarly, the actuator 11 is driven, and the opening of the throttle valve 9 is controlled so that the target throttle opening is set based on the smaller accelerator opening APO. In addition, as described below, the six flags APS1N
G, APS2NG, APSXNG, TPS1NG, TP
When at least one of S2NG and TPSXNG is 1, the first OR circuit 31 becomes high level and the warning light is turned on, and therefore the description thereof is omitted below.

Next, for the throttle opening sensor system, one of the flags TPS1NG and TPS2NG is set to 1
That is, when only one of the throttle opening sensors 11A and 11B is diagnosed as a failure (single failure) (third to sixth in the table of each system), the sensor single failure limp home permission flag is set to 1. As for the accelerator opening APO (throttle opening TPO), the detected value on the side not diagnosed as a failure, APS1 or APS2 (TPO1 or TPO1
PO2) is selected, but regarding the setting of the fuel injection amount,
It is set by the following method.

That is, in the first embodiment shown in this figure,
When both the throttle opening sensors 11A and 11B are normal, that is, when the limp home permission flag at the time of sensor single failure is reset to 0, the output of the inverter 33 becomes high level and the first fuel injection amount calculation is performed. Circuit 34
Thus, the fuel injection amount Tp is calculated based on the intake air amount Q and the engine rotation speed N detected by the air flow meter 3.

Further, the throttle opening sensors 11A, 11
When B has a single failure, the sensor single failure limp home permission flag becomes 1, and the second fuel injection amount calculation circuit 34 selects the detected value (APO1 or APO2) of the accelerator opening sensor 1A, 1B. The fuel injection amount Tp is calculated based on the engine rotation speed N. That is, when the throttle opening sensor 1A, 1B has a single failure, if the opening value of the throttle valve 9 is feedback-controlled using the detection value of the remaining sensor, the opening degree of the throttle valve 9 may increase abnormally. Can occur.

However, even in such a case, the fuel injection amount is calculated and set based on the accelerator opening detected by the accelerator opening sensor operated by the driver's intention and the engine rotation speed. Even if the intake air amount increases as the throttle valve opening increases, the increase in the fuel injection amount can be suppressed without depending on the increase in the intake air amount. In addition, as described above, by setting the fuel injection amount according to the driver's intention, the throttle valve opening is limited to the default opening as in the conventional method, and the fuel injection amount is adjusted according to the intake air amount at that time. It is also possible to prevent the engine output from being excessively limited due to the setting of. When calculating the fuel injection amount based on the accelerator opening and the engine rotation speed, the second fuel injection amount calculation circuit 35 first obtains the target intake air amount from these and then the intake air amount and the engine rotation speed. The fuel injection amount may be calculated based on the speed, and further, the target torque is first calculated based on the accelerator opening and the engine rotation speed, and based on the target torque and the engine rotation speed. The target intake air amount may be calculated, and the fuel injection amount may be calculated based on the target intake air amount and the engine rotation speed (the same applies to the following embodiments).

FIG. 5 shows the configuration of the fail-safe control according to the second embodiment. The second embodiment is configured by adding a predetermined circuit to the first embodiment.
When the throttle opening sensors 11A and 11B are both normal, the first fuel injection amount calculation circuit 34 outputs the intake air amount Q and the engine speed N detected by the air flow meter 3 via the output of the inverter 33. Fuel injection amount T
It is the first to calculate p and use the calculated value as it is.
This is the same as the embodiment.

Further, the throttle opening sensors 11A, 11
When B has a single failure, the sensor single failure limp home permission flag is set to 1, and the second fuel injection amount calculation circuit 35 selects the detected value (APO1 or APO2) of the accelerator opening sensor 1A, 1B. The calculation of the fuel injection amount Tp based on the engine rotation speed N is also similar,
At the same time, the high level output of the limp home permission flag at the time of sensor single failure is also led to the first fuel injection amount calculation circuit 34, and the intake air amount Q and the engine speed N are also calculated by the first fuel injection amount calculation circuit 33. The fuel injection amount Tp is also calculated based on and. Then, the fuel injection amount Tp calculated by the first fuel injection amount calculation circuit 34 by the select low circuit 36 which is driven by receiving the output of the flag.
The smaller fuel injection amount of 1 and the fuel injection amount Tp2 calculated by the second fuel injection amount calculation circuit 35 is selected and used.

With this configuration, when the air density decreases due to traveling at a high altitude or the like when the throttle opening sensor has a single failure, the accelerator opening increases, so the accelerator opening by the second fuel injection amount calculation circuit 35 is increased. The calculated value of the fuel injection amount based on the engine rotation speed and the engine rotation speed may result in an excessive fuel injection amount. However, the detected value of the (mass) intake air amount by the first fuel injection amount calculation circuit 34 and the engine rotation speed In the case of the calculated value of the fuel injection amount based on the detected value of the speed, the fuel injection amount is not excessively calculated because it is not affected by the decrease in the air density. Then, by the select low circuit 36,
Since the latter one of the smaller fuel injection amounts is selected and set, an appropriate engine output can be secured.

FIG. 6 shows the configuration of the fail-safe control according to the third embodiment. In this embodiment, a predetermined circuit is added to the configuration of the second embodiment. That is, the output of the accelerator opening APO is input to the second fuel injection amount calculation circuit 35 via the lower limit limiter circuit 37. Here, when the throttle opening sensor fails, the lower limit value of the opening of the throttle valve 9 (default opening)
Is set, and the throttle valve 9 is held at the default opening even when the accelerator opening is smaller than the default opening. Therefore, the lower limit limiter circuit 37 sets the lower limit value of the accelerator opening to the value corresponding to the default opening, and limits the accelerator opening APO to the lower limit or more.

Therefore, the second fuel injection amount calculation circuit 35
Even if the actual accelerator opening is smaller than the default opening, since the accelerator opening uses a value equivalent to the default opening to calculate the fuel injection amount, the fuel injection amount corresponding to the default opening is calculated. It will be. As a result, it is possible to prevent the select low circuit 36 from selecting an excessively small fuel injection amount corresponding to the actual accelerator opening, and it is possible to prevent stall. In addition, this lower limit limiter 37
Of course, in the simple first embodiment shown in FIG. 3, it may be configured to be added to the preceding stage of the first fuel injection amount calculation circuit 35.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration and function of the invention according to claim 1.

FIG. 2 is a block diagram showing the configuration and function of the invention according to claim 3;

FIG. 3 is a diagram showing a system configuration of an embodiment.

FIG. 4 is a circuit block diagram showing fuel injection amount control by diagnosis of an accelerator opening sensor and a throttle opening sensor according to the first embodiment.

FIG. 5 is a circuit block diagram showing fuel injection amount control by diagnosis of an accelerator opening sensor and a throttle opening sensor according to a second embodiment.

FIG. 6 is a circuit block diagram showing fuel injection amount control by diagnosis of an accelerator opening sensor and a throttle opening sensor according to a third embodiment.

[Explanation of symbols]

1A, 1B accelerator opening sensor 4 institutions 9 Throttle valve 10 actuators 11A, 11B Throttle opening sensor 14 Control unit 33 inverter 34 First Fuel Injection Amount Calculation Circuit 35 Second Fuel Injection Amount Calculation Circuit 36 Select Low Circuit 37 Lower limit limiter circuit

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Mikio Nozaki 2 Takaracho, Kanagawa-ku, Yokohama, Kanagawa Nissan Motor Co., Ltd. (56) References JP-A-10-176582 (JP, A) JP-A-10- 176583 (JP, A) JP 5-209541 (JP, A) JP 3-281969 (JP, A) JP 6-264800 (JP, A) JP 63-147940 (JP, A) JP-A-7-4294 (JP, A) JP-A-6-229299 (JP, A) JP-A-63-71552 (JP, A) JP-A-60-187735 (JP, A) JP-A-2-147439 (JP, A) JP-A-6-280656 (JP, A) JP-A-9-287513 (JP, A) JP-B-3-63654 (JP, B2) (58) Fields investigated (Int.Cl. ⁷⁾ , DB name) F02D 9/00-11/10 F02D 13/00-28/00 F02D 29/00-29/06 F02D 41/00-41/40 F02D 43/00-43/04 F0 2D 45/00 F02M 25/06-25/07 F02M 39/00-71/04

Claims (4)

(57) [Claims] 1. An electronically controlled throttle system in which an actuator opens and closes a throttle valve interposed in an intake system in accordance with an engine operating condition including a detected value of an accelerator opening by an accelerator opening sensor so as to reach a target opening. It is equipped with two throttle opening sensors for detecting the opening of the throttle valve , and the detection value of one throttle opening sensor is selected.
Then, feedback control to the target opening of the throttle valve
In the electronically controlled throttle internal combustion engine used, one of the two throttle opening sensors has failed.
Sometimes, one remaining throttle opening sensor
Select the sensor detection value and set the throttle valve to the target opening.
And Dobakku control, the throttle opening sensor is both two During normal inhalation
Detected value of mass intake air amount by air amount detection means and engine speed
When the fuel injection amount is set based on the detected value of rolling speed and one of the two throttle opening sensors fails,
An electronically controlled throttle system including a fuel injection amount switching setting means for setting a fuel injection amount based on the detected value of the accelerator opening and the detected value of the engine rotational speed by the engine rotational speed detecting means. Fail-safe control device for internal combustion engine. 2. An electronically controlled throttle system in which an actuator opens and closes a throttle valve interposed in an intake system according to an engine operating condition including a detected value of an accelerator opening by an accelerator opening sensor so as to reach a target opening. It is equipped with two throttle opening sensors for detecting the opening of the throttle valve , and the detection value of one throttle opening sensor is selected.
Then, feedback control to the target opening of the throttle valve
In the electronically controlled throttle internal combustion engine used, one of the two throttle opening sensors has failed.
Sometimes, one remaining throttle opening sensor
Select the sensor detection value and set the throttle valve to the target opening.
When the feedback control is performed and one of the two throttle opening sensors fails, the fuel set based on the detected value of the accelerator opening and the detected value of the engine rotational speed by the engine rotational speed detecting means. Of the injection amount, the fuel injection amount set based on the detection value of the mass intake air amount by the intake air amount detection means and the detection value of the engine rotation speed, the smaller value is selected and set,
When both of the throttle opening sensors are normal, the fuel injection amount switching setting means for setting the fuel injection amount based on the detected value of the mass intake air amount and the detected value of the engine rotation speed is included. Fail-safe control device for electronically controlled throttle internal combustion engine. 3. The fuel injection amount switching setting means, when one of the two throttle opening sensors fails,
The electronic control according to claim 1 or 2, further comprising a function of setting a lower limit value of a fuel injection amount corresponding to a lower limit value of a throttle valve opening set corresponding to the failure. Fail-safe control device for throttle type internal combustion engine. 4. An electronically controlled throttle system according to any one of claims 1 to 3 , wherein two accelerator opening sensors are also provided, and a detection value of one sensor is selected and used. Fail-safe control device for internal combustion engine.