DE102012200533A1 - Fuel control device of internal combustion engine of vehicle, computes fuel amount when intake air amount detected by intake air amount detector is not equal to air amount obtained by converting inlet air pressure of air inlet passage - Google Patents

Abstract

The fuel control device has an intake air amount detector (11) for detecting inlet air amount in an air inlet passage (2) of the engine (1), and an intake pipe pressure detector (13) for detecting inlet air pressure of the air inlet passage. A transducer converts the detection value of intake pipe pressure detector into air amount and compares with intake air amount. The fuel amount for internal combustion engine is computed when the intake air amount detected by the intake air amount detector is not equal to the converted air amount.

Description

BACKGROUND OF THE INVENTION

FIELD OF THE INVENTION

The present invention relates to a fuel control apparatus for an internal combustion engine for supplying fuel to an internal combustion engine in an amount calculated using an amount of intake air, and more particularly, to a fuel control apparatus of an automotive engine.

RELATED ART

An automobile is generally provided with a brake booster to obtain a large braking force during a braking operation. The brake booster receives a braking force during a braking operation using a negative pressure generated in the intake pipe of an engine.

A fuel control device of an internal combustion engine is electronically controlled and provided with an air mass sensor that detects an intake air amount, and a crank angle sensor that detects a rotation speed of the internal combustion engine to calculate an amount of fuel to be supplied to the internal combustion engine. Further, to stabilize the idling rotation and prevent the deterioration of the exhaust emission, the fuel control apparatus corrects a fuel supply based on information input therefrom from various sensors and switches.

For example, the automobile is provided with a detection switch that detects a braking operation by detecting whether the brake is ON or OFF, and the fuel control device uses a state of this fuel control detection switch to stabilize the idling and prevent deterioration of the exhaust emission.

With reference to a fuel control device described in Patent Document 1, whether there is intake air from a brake booster to the intake pipe is determined from a shift signal indicating whether the brake is ON or OFF, and the shift is made to either a detection result of the air mass sensor or a pressure of the intake pipe when calculating an amount of fuel used for fuel control.

More specifically, when the brake is OFF and a predetermined time has elapsed since the state of the brake has been changed from ON to OFF, an amount of fuel used for fuel control is calculated using an intake air amount detected by the air mass sensor. On the other hand, when the brake is ON, and when no predetermined time has elapsed since the state of the brake has changed from ON to OFF, an amount of fuel used for fuel control is calculated using an intake air amount calculated based on the pressure detected by an intake air pressure sensor.
Patent Document 1: JP-A-2005-325700

However, the fuel control device described in Patent Document 1 can not determine whether the brake is ON or OFF when a fault occurs in the detection switch, which determines whether the brake is ON or OFF, or if the automobile is not equipped with a brake detection switch , Therefore, there arises the problem that the fuel control device can not correct the fuel control.

Generally, during a brake operation of an automobile, a brake detection switch turns ON when the brake pedal is depressed, and a brake force is generated by an operation of the brake booster when the brake pedal is further depressed.

According to Patent Document 1, because braking operation is detected by the brake switch as indicated by a broken line in FIG 5 is displayed, when the brake pedal is depressed and the brake switch is turned ON, the air amount used in the calculation for the fuel control of the internal combustion engine, regardless of an amount of braking operation of an amount of air that is detected by the air mass sensor, switched to an intake air amount is calculated based on a detected pressure from the intake pipe pressure sensor.

Therefore, even when an operation by which a brake pedal amount is too small than the brake booster operates, an intake air amount for fuel control is switched from a detected air amount from the air mass sensor to an intake air amount calculated based on the detected pressure from the intake pipe pressure sensor. Accordingly, there is the problem that the performance of the fuel control is deteriorated.

SUMMARY OF THE INVENTION

The invention has been developed in order to solve the problems discussed above and has as its object a low-cost fuel control device an internal combustion engine capable of performing fuel control by detecting an accurate intake air amount regardless of inconveniences caused when a vehicle is not equipped with a brake switch or failure occurs in the brake switch, or when an intake air amount is one Brake booster varies to an intake pipe due to a difference in the size of the braking operation.

A fuel control device of an internal combustion engine according to an aspect of the invention is a fuel control device of an internal combustion engine that calculates an amount of fuel to inject the fuel required for an internal combustion engine of an automobile using an air amount. The fuel control apparatus includes: an intake air amount detector provided on each air intake passage leading to the internal combustion engine and detecting an intake air amount passing through the air intake passage; an intake pipe pressure detector that detects an intake air pressure of the air intake passage; and a converter that converts a detection value of the intake pipe pressure detector into a physical quantity into units of measurement equal to a unit of measurement of a detection value of the intake air amount detector. The intake air amount detected by the intake air amount detector is compared with an intake air amount calculated by the converter based on the detection value from the intake pipe pressure detector. When the intake air amount detected by the intake air amount detector is larger than the intake air amount calculated based on the detection value from the intake pipe pressure detector, the intake air amount detected by the intake air amount detector is used to calculate an amount of fuel for the internal combustion engine. When the intake air amount calculated based on the detection value from the intake pipe pressure detector is larger than the intake air amount detected by the intake air amount detector, the intake air amount calculated based on the detection value from the intake pipe pressure detector is used to calculate an amount of fuel for the internal combustion engine.

When configured as above, the intake air amount detected by the intake air amount detector provided to the internal combustion engine is compared with the intake air amount calculated based on the detected value from the intake pipe pressure detector, and when the intake air amount detected by the intake air amount detector is that of the air intake passage is supplied to the internal combustion engine that is larger of the two quantities, the intake air amount detected by the intake air amount detector is used to calculate an amount of fuel for the internal combustion engine, whereas when the intake air amount calculated based on the detection value from the intake pipe pressure detector is the larger of the two Is amounts that the intake air amount calculated by the intake pipe pressure detector is used to calculate an amount of fuel for the internal combustion engine. Accordingly, even in a case where the intake air amount increases after being detected by the air amount detector, it becomes possible to use the intake air amount used for the internal combustion engine fuel control from the intake air amount detected by the intake air amount detector to the intake air amount calculated based on the pressure detected by the intake pipe pressure detector switch. Consequently, an intake air amount from the brake booster can be detected without using a brake switch, and the performance of the fuel control is not impaired.

The above and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in its entirety with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

1 FIG. 14 is a view showing the configuration of a fuel control device of an internal combustion engine according to the first embodiment of the invention; FIG.

2 FIG. 12 is a block diagram used to illustrate the intake air amount switching for fuel control by the fuel control device according to the first embodiment of the invention; FIG.

4 FIG. 10 is a flowchart illustrating an operation of intake air quantity switching by a fuel control device according to a second embodiment; FIG. and

5 is a timing diagram showing the invention compared to the prior art.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

First embodiment

Hereinafter, a fuel control device of an internal combustion engine according to a first embodiment of the invention with reference to 1 to 3 described.

1 FIG. 14 is a view showing the configuration of the fuel control device of an internal combustion engine according to the first embodiment of the invention. An automobile engine 1 as an internal combustion engine is with an intake port 2 through which air is admitted in, one at the inlet port 2 provided inlet valve 3 , an exhaust passage 4 , is discharged from the exhaust to the outside, an exhaust valve 5 , which is provided at the exhaust passage, a spark plug 6 , the fuel in the engine 1 ignited, and a crank angle sensor 7 as a motor rotation detector, which is a speed of the motor 1 detected, provided.

When air in the engine 1 Air is taken in from the atmosphere and it is extracted from it by an air purifier 8th Contaminants are removed, after which the air from the inlet valve 3 by sequentially passing an inlet pipe 9 , an overpressure tank 10 and the inlet passage 2 in the engine 1 is introduced. Here are the corresponding components that allow air from the air purifier 8th until the inlet passage 2 to pass together an air intake passage of the engine 1 ,

The inlet pipe 9 is with an air sensor (AFS) 11 provided, which is an intake air amount of the engine 1 detected and forms an intake air quantity detector. Although not shown in the drawing, the air mass sensor includes 11 an intake air temperature sensor that detects a temperature of the intake air.

A throttle 12 is downstream of the air mass sensor 11 of the inlet pipe 9 intended. The throttle 12 is also provided with a function of an idle air amount control part to maintain a motor speed during operation.

A first negative pressure inlet pipe 51 is with the overpressure tank 10 connected. The overpressure tank 10 and an intake air pressure sensor 13 are above the first negative pressure inlet pipe 51 connected. The intake air pressure sensor 13 forms an inlet pipe pressure detector, which has an inlet air pressure in the overpressure tank 10 , which forms the air intake passage detected. Also is a second negative pressure inlet tube 62 with the overpressure tank 10 connected. The overpressure tank 10 and a brake booster 15 are over the second negative pressure inlet pipe 52 connected. In addition, there is a brake pedal 15 with the brake booster 14 connected.

The air mass sensor 11 is downstream of the air purifier 8th disposed and is upstream of the second negative pressure inlet pipe 52 localized. The intake air pressure sensor 13 is downstream of the second negative pressure inlet pipe 52 localized. Therefore, one contains by the air mass sensor 11 detected intake air quantity none from the brake booster 14 in the overpressure tank 10 flowing air. On the other hand, because the intake air pressure sensor 13 downstream of the second negative pressure inlet pipe 52 is located, contains a through the intake air pressure sensor 13 detected intake air pressure from the brake booster 14 in the overpressure tank 10 flows.

The intake air passage 2 is with a fuel injector 16 provided upstream of the inlet valve 3 is localized.

By combustion in the engine 1 generated exhaust gas is produced by sequentially passing through the exhaust passage 4 and a three-way catalyst 17 released to the atmosphere. The exhaust passage 4 is with an air-fuel ratio sensor 18 Mistake.

An electronic control unit 20 Incorporates a microcomputer and therefore calculates a control amount of various types based thereon from the air mass sensor 11 , the throttle 12 , the intake air pressure sensor 13 , the air-fuel ratio sensor 18 and the crank angle sensor 7 entered information and drives the fuel injector 16 and the spark plug 6 using a control signal corresponding to a control amount.

The through the electronic control unit 20 performed air quantity switching is now based on 2 which is a block diagram used to describe intake air quantity switching for the fuel control. In 2 are all components designated by reference numerals that start with a B major except the air mass sensor 11 , the intake air pressure sensor 13 and the crank angle sensor (engine speed detector) 7 , in the electronic control unit 20 intended.

Initially, the air flow converter B01 converts through the intake air pressure sensor 13 detected intake pipe pressure RPB in a physical quantity EQa the same measuring unit as an intake air amount to, so that a comparison with one by the air mass sensor 11 detected intake air quantity RQa can be made. Then, an air quantity switching part B02 determined by the air mass sensor 11 detected intake air amount RQa and the based on the detected pressure from the intake air pressure sensor 13 calculated intake air amount EQa is selected as an amount of intake air used to calculate an amount of fuel (fuel control).

Meanwhile, an intake air pressure converter B04 converts a predicted intake pipe pressure EPb found by an intake pipe pressure prediction part B03, which predicts intake air pressure of the intake passage, to a physical quantity in the same measuring unit as the intake pipe pressure RPb. Then, an intake air pressure comparator B05 compares that through the intake air pressure sensor 13 detected intake pipe pressure RPb with the value converted by the intake air pressure transducer B04. This comparison result is one of the factors that determine whether the switching by the air quantity switching part B02 is enabled or disabled.

Regarding the intake air quantity RQa passing through the air mass sensor 11 is detected, an intake air amount at the last scan, RQa (i-1) is stored in a memory B06, and an intake air amount in the current scan, RQa (i), is stored in a memory B07. The intake air amount RQa (i-1) and the intake air amount RQa (i) are input to the air mass comparator B08 and compared therein. This comparison result is one of the factors that determine whether the switching by the air quantity switching part B02 is enabled or disabled.

Further, an engine revolution comparator B10 compares one through the crank angle sensor 7 rotational speed Ne detected as a motor rotation detector with a base rotational speed Nebase stored in the base motor speed storage B09. This comparison result is one of the factors that determine whether the switching by the air quantity switching part B02 is enabled or disabled.

When configured as above, from the intake air pressure comparator B05, the air amount comparator B08, and the engine rotation comparator B10, the air quantity changeover part B02 makes a determination as to whether or not the air mass sensor is detected based on the results of determining whether the air quantity switching is enabled or disabled 11 detected intake air amount RQa based on the detected pressure from the intake air pressure sensor 13 calculated intake air amount EQa is selected as an intake air amount used for fuel control, and performs the switching to the selected amount.

Hereinafter, an intake air amount switching operation by the fuel control device of the first embodiment will be specific according to the flowchart of FIG 3 described.

Returning to 3 First, in step S01, it is determined whether there is any failure in the intake air pressure sensor 13 gives. In a case where the occurrence of a failure in the intake air pressure sensor 13 is determined (YES), the process proceeds to step S10, in which the intake air amount RQa, which by the air mass sensor 11 is detected, is replaced by an intake air amount to the controller CQa, and the operation ends. In a case where there is no failure in the intake air pressure sensor 13 is detected in step S01 (NO), the process proceeds to step S02.

In step S02, it is determined whether there is any failure in the air mass sensor 11 gives. In the case where a failure in the air mass sensor 11 is detected (YES), the switching control of an intake air amount ends. In a case where in the air mass sensor 11 If no failure is detected (NO), the flow advances to step S03.

In step S03, the air amount converter B01 calculates the intake air amount EQa for the intake air pressure sensor 13 detected intake pipe pressure RPb from equation (1) below using a conversion coefficient to an intake air amount, TK. EQa = TK × RPb (1) TK = KEv × KAP × V / {Ts × R × (Ti + 273)} (2) where KEv is a volumetric efficiency correction, V is a stroke volume, R is an air gas constant, Ts is a time required per stroke, Ti is a temperature of intake air, and KAP is an atmospheric pressure correction.

In step S04, the intake pipe pressure prediction part B03 calculates the predicted intake pipe pressure EPb by an experiment using the rotational speed Ne and the opening of the throttle valve 12 data obtained as a parameter.

In step S05, the engine speed comparator B10 determines whether a difference of the engine speed Ne and the engine speed Nebase (here, assuming that a target engine speed during idling is the basic engine speed) is smaller than a predetermined value BKNe. The predetermined value BKNe is set to a value slightly greater than an increase in the engine speed that increases with the engine 1 supplied air due to incoming air from the brake booster 14 accompanied.

In a case where it is found in step S05 that the difference between the engine speed Ne and the basic engine speed Nebase is smaller than the predetermined value BKNe (YES), the flow advances to step S06-1. In a case where the difference between the engine speed Ne and the basic engine speed Nebase is equal to or greater than the predetermined value BKNe is (NO), the flow advances to step S10.

In step S06-1, a determination is made as to whether a difference between the intake pipe pressure RPb flowing through the intake air pressure sensor 13 is detected, and the predicted intake pipe pressure EPb predicted by the intake pipe pressure prediction part B03 is larger than the predetermined value BKPb. The predetermined value BKPb is set to a value slightly larger than a fluctuation of intake air pressure supplied by the intake air pressure sensor 13 in the engine 1 is detected, which operates in a uniform state.

In a case where it is found in step S06-1 that the difference between the intake pipe pressure RPb flowing through the intake air pressure sensor 13 is detected, and the predicted intake pipe pressure EPb is greater than the predetermined value BKPb is (YES), the flow advances to step S07. In a case where the difference between that through the intake air pressure sensor 13 If the detected intake pipe pressure RPb and the predicted intake pipe pressure EPb are less than the predetermined value BKPb (NO), the flow advances to step S06-2.

In step S06-2, a determination is made as to whether a predetermined time has elapsed since the difference between that by the intake air pressure sensor 13 detected intake pipe pressure RPb and the predicted intake pipe pressure EPb is intercepted at or below the predetermined value BKPb. In a case where the predetermined time has not elapsed (NO), the flow advances to step S07. In a case where the predetermined time has elapsed (YES), the flow advances to step S10. Herein, the predetermined time is set to a time slightly longer than a time that the brake booster 14 takes to return from an operating state to a non-operating state when the state of the braking operation is changed from ON to OFF.

In step S07, a determination is made as to whether a difference between the amount of intake air EQa calculated in step S03 and the intake air amount RQa flowing through the air mass sensor 11 is detected greater than a predetermined value BKQa. The predetermined value BKQa becomes a value slightly larger than a fluctuation of the intake air amount RQA generated by the air mass sensor 11 in the engine 1 is detected, which runs in a steady state, set.

In a case where it is found in step S07 that the difference between the intake air amount EQa calculated in step S03 and that by the air mass sensor 11 If the detected intake air amount RQa is larger than the predetermined value BKQa is (YES), the flow advances to step S08, and otherwise, the flow advances to step S10 (NO).

In step S08, a determination is made as to whether a variance exists between the current sample RQa (i) and the last sample RQa (i-1) of the intake air amount RQa detected by the air mass sensor 11 is less than a predetermined value ΔRQa.

In a case where a difference between the last sample RQa (i-1) and the current sample RQa (i) is smaller than the predetermined value ΔRQa (YES), the flow advances to step S09. In a case where the difference between the last sample RQa (i-1) and the current sample RQa (i) is greater than the predetermined value ΔRQa (NO) (if there is a variance), the flow advances to step S10 continued. Herein, the predetermined value ΔRQa becomes a value slightly larger than a sample-by-sample fluctuation of the intake air amount RQa flowing through the air mass sensor 11 in the engine operating in a uniform state 1 is detected, set.

In step S09, the pressure based on the detected pressure from the intake air pressure sensor 13 In step B03, the intake air amount EQa calculated by the intake air amount to the controller CQa that is for the fuel control of the engine 1 is used, replaced and the operation ends.

On the other hand, in step S10, the air mass sensor 11 detected intake air amount RQa by the intake air amount to the control CQa, which for the fuel control of the engine 1 is used, replaced and the operation ends.

The fuel control is thus by calculating a the engine 1 supplied amount of fuel based on the amount of intake air to the controller CQa performed.

When the control is performed as above, as indicated by a solid line in FIG 5 is displayed in a case where a variance in an intake pipe pressure due to an intake air amount from the brake booster 14 because, because a brake pressure amount is large, an intake air amount used for fuel control occurs from the intake air amount RQa flowing through the air mass sensor 11 is detected based on the through the intake air pressure sensor 13 Switched inlet manifold pressure calculated intake air quantity EQa switched. On the other hand, in a case where there is no variance in the intake pipe pressure, when an intake air amount becomes out of the brake booster 14 is small, because a brake pressure amount is small, the Switching is not performed as described above, and the control device operates to control the flow through the air mass sensor 11 detected intake air amount RQa used as an amount of intake air used for fuel control.

Therefore, even in a case where the vehicle is not provided with a brake switch in which a failure occurs in the brake switch, or in which an intake air amount from the brake booster 14 to the air intake passage varies with a difference in the amount of braking operation, the performance of the fuel control can be improved regardless of the inconvenience caused in these cases.

As has been described, according to the first embodiment of the invention, the air mass sensor 11 (Intake air quantity detector), the intake pipe 9 of the internal combustion engine, detected intake air amount RQa with the based on the detected value from the intake air pressure sensor 13 (Inlet pipe pressure detector), the pressure tank 10 When the intake air amount RQa detected by the intake air amount detector is larger than the two amounts, the intake air amount RQa is used for the internal combustion engine fuel control, while when the intake air amount EQa calculated based on the detected value from the intake pipe pressure detector the larger of the two amounts, the intake air amount EQa calculated by the intake pipe pressure detector is used for the internal combustion engine fuel control.

In short, according to the invention, in a case where the brake booster 14 incoming air is detected based on the pressure generated by the intake air pressure sensor 13 is detected, calculated intake air amount EQa used for the fuel control, while in a case where no incoming air from the brake booster 14 is detected by the air mass sensor 11 detected intake air amount RQa is used for fuel control.

Accordingly, in a case where the amount of air downstream of the air mass sensor 11 rises, possibly, the intake air amount used for fuel control of the internal combustion engine from that through the air mass sensor 11 detected intake air amount RQa based on the by the intake air pressure sensor 13 detected pressure calculated intake air quantity EQa switch. Consequently, an intake air amount from the brake booster can be detected without using a brake switch.

Also, the air mass sensor provided at the intake pipe of the internal combustion engine becomes 11 detected intake air amount RQa with that based on the through the intake air pressure sensor 13 detected pressure compared to calculated intake air quantity EQa and by the air mass sensor 11 detected intake air amount RQa is based on the by the intake air pressure sensor 13 detecting pressure-calculated intake air amount EQa switched when a difference between the detected values is equal to or greater than a predetermined value. Thus, it becomes possible to prevent the air quantity switching from occurring repeatedly when a difference between the intake air amount RQa and the intake air amount EQa calculated based on the detection value of the intake pipe pressure is small. Therefore, an intake air amount can be stably calculated.

Also, according to the invention, the intake pipe pressure prediction part B03 that predicts pressure of the intake pipe is provided, and the intake air amount is calculated from a difference between the intake pipe pressure obtained by the intake pipe pressure prediction part B03 and the intake air pressure sensor 13 (Inlet Pipe Pressure Detector) detected inlet pipe pressure switched. It thus becomes possible to detect an intake air amount sucked into the internal combustion engine independently of an intake air amount flowing through the air mass sensor 11 (Inlet air quantity detector) is detected. Therefore, the detection accuracy of an intake air amount from the brake booster 14 be improved.

Furthermore, in the event of a failure, either the air mass sensor 11 (Intake air quantity detector) or the intake air pressure sensor 13 (Intake pipe pressure detector), the intake air amount is not switched. Therefore, there is no erroneous switching due to a mistake in these components.

Second embodiment

A fuel control device of an internal combustion engine according to a second embodiment will now be described with reference to FIG 4 described.

The first embodiment above is applicable only to a case where a temperature of intake air is equal when the predicted intake pipe pressure EPb is predicted by the intake pipe pressure prediction part B03 and when the pressure RPb by the intake air pressure sensor 13 is detected. In contrast, the second embodiment is applicable when there is a temperature change in the intake air.

4 FIG. 10 is a flowchart illustrating intake air amount switching operation by the fuel control device of the second embodiment. FIG.

Compared to 3 In the first embodiment above, steps S01, S02, S03, S04, S05, S07, S08, S09, and S10 of FIG 4 the same as those in the first embodiment above, and a description of these steps will be omitted here.

According to the first embodiment above, in a case where a temperature of intake air when the intake pipe pressure RPb is through the intake air pressure sensor 13 is detected differs from an intake air temperature when an experiment for determining the predicted intake pipe pressure EPb is performed, the oxygen density in the air also differs when passing through the intake air pressure sensor 13 detected intake pipe pressure RPb and the intake pipe pressure EPb predicted by the intake pipe pressure prediction part B03 are compared. Accordingly, an air quantity switching is not performed accurately.

In order to eliminate influences of a difference in the temperature of intake air as above, the second embodiment is configured such that a difference ΔDPb between that through the intake air pressure sensor 13 detected inlet pipe pressure RPb and predicted by the inlet pipe pressure prediction part B03 predicted inlet pipe pressure EPb per predetermined sampling frequency, and a determination is made on the difference thus found, whether a variance between the current deviation ΔDPb (i) and the last deviation ΔDPb (i 1) is greater than a predetermined value.

More specifically, in step SA06-1, a difference ΔDPb between that through the intake air pressure sensor 13 detected inlet pipe pressure RPb and the predicted by the inlet pipe pressure prediction part B03 predicted inlet pipe pressure EPb found to determine whether a variance between the current deviation ΔDPb (i) and the last deviation ΔDPb (i - 1) is greater than a predetermined value BKDPb. In a case where the variance between the current deviation ΔDPb (i) and the last deviation ΔDPb (i-1) is larger than the predetermined value BKDPb (YES), the flow advances to step S07. In a case where the variance between the current deviation ΔDPb (i) and the last deviation ΔDPb (i-1) is smaller than the predetermined value BKDPb (NO), the flow advances to step SA06-2.

In step SA06-2, a determination is made as to whether a predetermined time has elapsed since the variance between the current deviation ΔDPb (i), which is a difference between that by the intake air pressure sensor 13 is detected intake pipe pressure RPb and the predicted intake pipe pressure EPb predicted by the intake pipe pressure prediction part B03, and the last deviation ΔDPb (i-1) has dropped to or below the predetermined value BKDPb. In a case where the predetermined time has not elapsed (NO), the flow advances to step S07. In a case where the predetermined time has elapsed (YES), the flow advances to step S10.

According to the second embodiment of the invention as in the first embodiment above and as shown by a solid line in FIG 5 is displayed in a case where a variance in the intake pipe pressure due to one of the brake booster 14 Incoming intake air amount occurs, because a brake pressure amount is large, an intake air amount used for the fuel control from that by the air mass sensor 11 detected intake air amount RQa on the basis of by the intake air pressure sensor 13 switched inlet air quantity EQa switched. On the other hand, in a case where no variance occurs in the intake pipe pressure, when an intake air amount from the brake booster 14 is small, because a brake pressure amount is small, the switching is not performed as described above, and the control device operates to control the flow rate through the air mass sensor 11 detected intake air amount RQa used as an intake air amount used for the fuel control.

As described, according to the second embodiment of the invention, a difference between the predicted intake air pressure EPb obtained by the intake pipe pressure prediction part B03 that predicts pressure of the intake pipe and that through the intake air pressure sensor is made 13 (Intake Pipe Pressure Detector) detects detected intake pipe pressure RPb, and the intake air amount switching is performed based on a variation of the calculated differences. Thus, it becomes possible to eliminate influences of a difference in oxygen density in a case where a temperature of intake air differs when the predicted intake air pressure is found by the intake pipe pressure prediction part B03 and when the intake pipe pressure is determined by the intake air pressure sensor provided at the air intake passage 13 is detected. Consequently, a detection accuracy of an intake air amount from the brake booster 14 be further improved.

Various modifications and changes of this invention will become apparent to those skilled in the art without departing from the scope and spirit of this invention, and it should be understood that these are not is limited to the illustrative embodiments presented herein.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2005-325700 A [0006]

Claims (6)

A fuel control apparatus of an internal combustion engine that calculates an amount of fuel to inject fuel required for an internal combustion engine of an automobile using an air amount, comprising: an intake air amount detector (FIG. 11 ) provided at an air intake passage leading to the internal combustion engine and detecting an intake air amount passing through the air intake passage; an inlet pipe pressure detector ( 13 ) detecting an intake air pressure of the air intake passage; and a converter (B01) having a detection value of the intake pipe pressure detector (B01) 13 ) into a physical quantity in units of measurement equal to a unit of measurement of a detection value of the intake air quantity detector (FIG. 11 ) converts; where: through the intake air quantity detector ( 11 ) detected intake air amount with one by the converter (B01) based on the detection value from the intake pipe pressure detector ( 13 ) is compared to calculated intake air amount; when passing through the intake air quantity detector ( 11 ) detected intake air amount greater than that based on the detection value from the intake pipe pressure detector (FIG. 13 ) is the calculated amount of intake air passing through the intake air quantity detector ( 11 ) detected intake air amount is used to calculate an amount of fuel for the internal combustion engine, and if based on the detection value from the intake pipe pressure detector ( 13 ) calculated intake air quantity greater than that through the intake air quantity detector ( 11 ) detected intake air amount, which is based on the detection value from the intake pipe pressure detector ( 13 ) is used to calculate an amount of fuel for the internal combustion engine. The fuel control apparatus of an internal combustion engine according to claim 1, further comprising: an intake pipe pressure prediction part (B03) that predicts an intake pipe pressure of the air intake passage, the intake air amount used for calculating an amount of fuel for the internal combustion engine based on a difference between an intake pipe pressure obtained by the intake pipe pressure prediction part (B03) and an intake pipe pressure the inlet pipe pressure sensor ( 13 ) detected inlet pipe pressure is switched. The fuel control apparatus of an internal combustion engine according to claim 1, further comprising: an intake pipe pressure prediction part (B03) that predicts an intake air pressure of the air intake passage, a difference between the intake pipe pressure obtained by the intake pipe pressure prediction part (B03) and an intake pipe pressure sensor (B03). 13 ) and the intake air amount used for calculating an amount of fuel for the internal combustion engine is switched based on a variation of the calculated difference. A fuel control device of an internal combustion engine according to any one of claims 1 to 3, wherein: the intake air amount is not switched when a failure in the intake air amount detector (14) 11 ) or the intake manifold pressure sensor ( 13 ) occurs. A fuel control device of an internal combustion engine according to any one of claims 1 to 4, wherein: the exhaust air mass sensor (14) 11 ) detected intake air amount with the based on the detection value from the intake pipe pressure sensor ( 13 ) is compared to calculated intake air amount; and if based on the detection value from the intake manifold pressure sensor ( 13 ) calculated intake air amount equal to or greater than that of the intake air quantity detector ( 11 is the detected intake air amount by a predetermined amount or more, the intake air amount used for calculating an amount of fuel for the internal combustion engine is calculated based on the detection value from the intake air pressure sensor (FIG. 13 ) from the intake air quantity detector ( 11 ) detected intake air amount calculated intake air amount switched. A control apparatus of an internal combustion engine according to any one of claims 1 to 5, further comprising: a motor rotation detector (16); 7 ), which detects a speed of the internal combustion engine, wherein: one by the engine rotational detector ( 7 ) detected engine speed is compared with a base engine speed; and if a difference between the one based on the detection value of the motor rotation detector ( 7 ) and the basic engine speed is equal to or greater than a predetermined range, the intake air amount used for calculating an amount of fuel for the internal combustion engine is determined by the intake air quantity detector ( 11 ) detected intake air quantity is switched.

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