DE102015121126B4 - Electronic control device - Google Patents

Abstract

An electronic control apparatus (2) comprising: start determining means (S320, S380, S740) for determining whether a preset diagnosis start condition is satisfied, which indicates that a supercharging pressure, which is an intake air compressed by a supercharger (160), is low, wherein the supercharger has a turbine (161) disposed in an exhaust passage (140) of an internal combustion engine (100) and a compressor (162) disposed in an intake passage (120) of the internal combustion engine, a valve opening device (S420, S750) allowing an air bypass valve (171) for opening and closing the intake bypass passage (170) bypassing the compressor to open the intake bypass passage when the start determination device determines that the diagnosis start condition is satisfied, a diagnostic operation device (S470, S750) a waste gate valve (181) for opening and closing an exhaust bypass passage (180) bypassing the turbine allows to operate in a preset abnormality diagnosing operation to increase the boost pressure when the air bypass valve closes the intake bypass passage in a case where the start determination device determines that the diagnosis start condition is satisfied, and an abnormality determination device (S540 to S570, S760 to S790) that determines that an abnormality occurs in the air bypass valve in a case where a preset normal determination condition indicative of the boost pressure when the air bypass valve opens the intake bypass passage is not satisfied after the wastegate operates in the abnormality diagnosis operation.

Description

Technical area

The present invention relates to an electronic control apparatus that controls an internal combustion engine with a supercharger.

background

Heretofore, a technique has been known in which, in an engine with a supercharger, when a difference between a supercharging pressure and an atmospheric pressure is greater than or equal to a predetermined value, a valve opening instruction is issued to an air bypass valve and it is determined whether on the basis an abnormality in the air bypass valve occurs or not from a change in the subsequent boost pressure (for example JP 2007 - 77 897 A : US 2006/0 248 889 A1 ).

Further, a technique has been known which diagnoses an abnormality in the operation of the turbocharger in the region of the wastegate valve with a pressure sensor that determines the pressure in or upstream of the turbine. If a controller detects a predetermined limit is exceeded, the turbine geometry is changed to preclude damage to the turbine (eg DE 102 02 322 A1 ).

In addition, a technique has been known in which, in pure turbocharger operation, pressure is measured in front of and behind the compressor of a turbocharger and determines a compression ratio of the turbocharger, which is compared with a map-derived turbocharger compression ratio during normal operation to determine the abnormality , In a combined turbocharger and compressor operation, an intake manifold pressure of the internal combustion engine, a pressure between the compressor and compressor of the turbocharger, a pressure between the compressor and the internal combustion engine is measured, and the measured pressures or an air mass flow determined therefrom are compared with corresponding model pressures or model air masses Determine abnormality (for example DE 10 2004 036 064 A1 ).

However, in the above techniques, it is likely that an abnormality determination of the air bypass valve is performed according to a situation where the boost pressure becomes higher when an abnormality in an engine occurs more. For this reason, even if the abnormality of the air bypass valve is detected at a time when the boost pressure becomes higher, when the abnormality in the engine occurs more, occurrence of the abnormality of the engine caused by the irregularity of the air bypass valve is hardly prevented.

Summary

It is an object of the present disclosure to provide an electronic control apparatus capable of suppressing occurrence of a situation where failure occurs in an internal combustion engine due to an abnormality of an air bypass valve. The object is solved by the features of the independent claim. Advantageous developments of the invention are described in the subclaims.

An electronic control device according to the present disclosure includes a start determination device, a valve opening device, a diagnosis operation device, and an abnormality determination device.

The start determination device determines whether a preset diagnosis start condition indicating that a boost pressure is low, which is a pressure of intake air, which is provided by a supercharger having a turbine disposed in an exhaust passage of an internal combustion engine and a compressor that is in an intake passage the internal combustion engine is arranged, is compressed, is satisfied or not.

The valve opening device allows an air bypass valve for opening and closing the intake bypass passage bypassing the compressor to open the intake bypass passage when the start determination device determines that the diagnosis start condition is satisfied.

The diagnostic operation device allows a wastegate valve for opening and closing an exhaust bypass passage that bypasses the turbine to operate in a preset abnormality diagnosing operation to increase a boost pressure if the air bypass valve closes the intake bypass passage when the exhaust bypass passage Start determination device determines that the diagnosis start condition is satisfied.

The abnormality determination device determines that the abnormality occurs in the air bypass valve in a case where a preset normal determination condition indicative of the boost pressure when the air bypass valve opens the intake bypass passage is not satisfied after Wastegate valve in the irregularity diagnostic operation operates or works.

The above-described electronic control device according to the invention may determine that the abnormality occurs in the air bypass valve when both the air bypass valve and the wastegate valve are operative to increase the boost pressure when the boost pressure is low.

As described above, the electronic control device according to the invention can diagnose whether the abnormality occurs in the air bypass valve or not even when the boost pressure is low. For this reason, the electronic control device according to the invention can detect the irregularity of the air bypass valve before the boost pressure becomes higher as the failure in the internal combustion engine becomes more prevalent. With the above configuration, the electronic control device according to the invention can suppress the occurrence of a situation in which the failure in the internal combustion engine occurs due to the irregularity of the air bypass valve.

list of figures

• ist 1 ein Diagramm, das eine Konfiguration eines Motorsteuerungssystems 1 darstellt,
• ist 2 ein Flussdiagramm, das einen Unregelmäßigkeitsdiagnoseprozess darstellt,
• ist 3 ein Flussdiagramm, das einen WGV-Unregelmäßigkeitsdiagnoseprozess darstellt,
• ist 4 ein Flussdiagramm, das einen ersten halben Abschnitt eines ABV-Ausgangsdiagnoseprozesses darstellt,
• ist 5 ein Flussdiagramm, das einen zweiten halben Abschnitt des ABV-Ausgangsdiagnoseprozesses darstellt,
• ist 6 ein Flussdiagramm, das einen periodischen ABV-Diagnoseprozess darstellt,
• ist 7 ein Zeitplan, der den Betrieb von einem ABV und einem WGV in dem ABV-Ausgangsdiagnoseprozess darstellt,
• ist 8 ein Zeitplan, der den Betrieb von dem ABV und dem WGV in dem periodischen ABV-Diagnoseprozess darstellt,
• ist 9 ein Graph, der ein Verhältnis zwischen einer Motordrehzahl, eines angeforderten Drehmoments und einer Laderegion darstellt, und
• ist 10 ein Graph, der ein Verhältnis zwischen der Motordrehzahl, einer WGV-Öffnung und der Laderegion darstellt.

The above and other objects, features and advantages of the present disclosure will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings:

• is 1 a diagram showing a configuration of an engine control system 1 represents,
• is 2 a flowchart illustrating an abnormality diagnosis process,
• is 3 a flowchart illustrating a WGV irregularity diagnosis process,
• is 4 FIG. 3 is a flowchart illustrating a first half section of an ABV home diagnostic process; FIG.
• is 5 a flowchart illustrating a second half section of the ABV initial diagnostic process,
• is 6 a flowchart illustrating a periodic ABV diagnostic process,
• is 7 a schedule of one's operation ABV and one WGV in the ABV Outbound Diagnostic process,
• is 8th a schedule of the operation of the ABV and the WGV in the periodic ABV Diagnostic process represents
• is 9 a graph representing a relationship between an engine speed, a requested torque and a loading region, and
• is 10 a graph showing a relationship between the engine speed, a WGV Opening and loading region represents.

Detailed description

Hereinafter, embodiments of the invention will be described with reference to the attached drawings.

As it is in 1 is shown, includes an engine control system 1 an engine 100 and an electronic control device 2 (hereinafter referred to as "engine ECU 2" (electronic control unit)), which is the engine 100 controls.

The motor 100 is an internal combustion engine, which is installed in a vehicle, and forms by a cylinder 101 , a piston 102 and a cylinder head 103 a combustion chamber 104 for each of multiple cylinders. A spark plug 105 for igniting a fuel is inside the combustion chamber 104 fitted.

The combustion chamber 104 of the motor 100 is through a suction valve 106 with a suction pipe 120 connected and through an exhaust valve 107 with an outlet pipe 140 connected.

A throttle valve 130 for adjusting the amount of air flowing to the engine 100 to be delivered is in the intake pipe 120 arranged. The intake pipe 120 is through a Ansaugverteiler or a Ansaugverteilerrohr 121 with the respective cylinders of the engine 100 connected and the air of the crowd passing through the intake pipe 120 with the throttle valve 130 is set through the intake manifold or the intake manifold 121 distributed and to the respective cylinder of the engine 100 delivered.

An injector or injector 122 is for every cylinder of the engine 100 in the intake manifold or intake manifold 121 arranged. A fuel coming from the injector or injector 122 is injected with the air from the intake manifold 120 mixed and attached to each cylinder of the engine 100 delivered.

Furthermore, in every cylinder of the engine 100 an air-fuel mixture with the opening / closing of the intake valve 106 into the combustion chamber 104 initiated and the introduced air-fuel mixture by the ignition of the spark plug 105 burned, the piston becomes 102 pressed down and becomes a torque on a crankshaft 108 of the motor 100 transmitted. An exhaust after a combustion is through the outlet pipe 140 with the opening / closing of the exhaust valve 107 emanated from an exterior.

The motor 100 is with a crank angle transmitter 110 and a throttle opening transmitter 124 as a transmitter for detecting an operating condition of the engine 100 fitted.

The crank angle transmitter 110 detects a rotation angle of the crankshaft 108 of the motor 100 , In particular, the crank angle transmitter gives 110 a crank angle signal indicative of an edge at any given angle (eg, for every 10 ° CA (crank angle)) according to the rotation of the crankshaft 108 of the motor 100 generated. The throttle opening transmitter 124 detects the opening of the throttle valve 130 (hereinafter referred to as "throttle opening").

The motor 100 is with a turbocharger 160 equipped. The turbocharger 160 contains a turbine 161 , a compressor 162 and a rotation shaft 163 that the turbine 161 with the compressor 162 coupled.

The turbine 161 is in the outlet pipe 140 arranged. The turbine 161 is configured to rotate over the shaft 163 with a circulation of exhaust gas coming from the engine 100 into the outlet pipe 140 is emitted, to rotate.

The compressor 162 is in the intake pipe 120 upstream of the throttle valve 130 arranged. The compressor 162 is configured to rotate over the shaft 163 due to a driving force coming from the turbine 161 through the rotary shaft 163 is transmitted to rotate. The compressor 162 compresses air in the intake manifold 120 due to the rotation of the compressor 162 and leads the compressed air to the engine 100 to.

The intake pipe 120 is with a suction bypass passage 170 who is the compressor 162 bypasses, equips and leaves the air in the intake manifold 120 circulate. The intake bypass passage 170 is with an intake bypass valve 171 (hereinafter referred to as "ABV 171 (Intake bypass valve, air bypass valve) for opening and closing the Ansaugumgehungsdurchgangs 170 equipped.

The outlet pipe 140 is with an exhaust bypass passage 180 , the turbine 161 bypasses, equips and leaves the exhaust gas in the outlet pipe 140 circulate. The outlet bypass passage 180 is with a wastegate or wastegate valve 181 (hereinafter referred to as "WGV 181 (Wastegate valve) for opening and closing the exhaust bypass passage 180 equipped.

The WGV 181 is with one WGV -Öffnungsmesswertgeber 182 equipped with an opening of the WGV 181 (hereinafter referred to as "WGV opening").

The engine control system 1 contains a boost pressure transmitter 135 that is a pressure in the intake manifold 120 (that is, a boost pressure through the turbocharger 160 ), and an atmospheric pressure transmitter 137 that captures an atmospheric pressure. The boost pressure transmitter 135 is in the intake pipe 120 at a position upstream of the throttle valve 130 and downstream of the compressor 162 Installed.

The engine-ECU 2 contains a microcomputer 3 , which is a process for controlling the engine 100 performs, a driver or drive circuit 4 , the various actuators according to control signals from the microcomputer 3 operated, and an input circuit 5 that the microcomputer 3 feeds different signals.

The microcomputer contains a CPU 11 (central processing unit, central processing unit), a ROM 12 (Read-only memory), and a RAM 13 (Random Access Memory).

The CPU 11 performs various processes for controlling the engine 100 based on programs that are in the ROM 12 are stored. The ROM 12 is a permanent or non-volatile memory and stores programs by the CPU 11 and data relating to a time or time of executing the program. The RAM 13 is a volatile or non-permanent memory and stores CPU results 11 temporarily.

The microcomputer 3 receives through the input circuit 5 a signal from the crank angle transmitter 110 , a signal from the throttle opening transducer 124 and a signal from the boost pressure transducer 135 , The input circuit 5 is a general circuit that suspends signals such as the transducer signals, predetermined signal processing such as analog-to-digital conversion, noise removal, or waveforms, and then converts the input signals into signals generated by the microcomputer 3 are processable.

The microcomputer 3 detects a condition of the engine 100 based on the corresponding signals through the input circuit 5 are input, and outputs the control signal to the drive circuit based on the detection result 4 out. With the above configuration, the microcomputer controls 3 the spark plug 105 , the intake valve 106 , the exhaust valve 107 , the injector or injector 122 , the throttle valve 130 , the ABV 171 and the WGV 181 to the engine 100 to operate or operate.

For example, the microcomputer calculates 3 a target boost pressure based on the throttle opening and the engine speed. The microcomputer 3 calculates one WGV Target opening based on a difference between the calculated target boost pressure and the boost pressure provided by the boost pressure transmitter 135 is detected, and performs a control to the WGV Opening by the WGV -Öffnungsmesswertgeber 182 is to enable the WGV Target opening to correspond.

When the boost pressure caused by the boost pressure transmitter 135 is captured, larger than a preset ABV Opening determination value ( ABV -OT) or equal to this, gives the microcomputer 3 a control signal for opening of the ABV 171 out.

In the engine control system 1 , which is configured as described above, runs the CPU 11 in the microcomputer 3 an abnormality diagnosing process for diagnosing the abnormality of the ABV 171 out.

First, a procedure of the abnormality diagnosing process will be described. The abnormality diagnosis process becomes for each preset execution cycle (for example, 5 ms in this embodiment) during operation of the microcomputer 3 repeatedly executed.

During the execution of the irregularity diagnosis process, as described in 2 is shown, the CPU determines 11 of the microcomputer 3 in S10 first, whether that WGV Diagnostic result is "not captured" or not. In particular, the CPU determines 11 whether a value that indicates "unrecognized" in one WGV Diagnostic result information stored in the RAM 13 for saving the WGV Diagnostic result is provided, stored or not. If the value that indicates "not detected" in the WGV Diagnostic result information is stored, the CPU determines 11 , that this WGV Diagnostic result is "not detected". An initial value of WGV Diagnostic result information is a value that indicates "not detected".

In this example, if that leads WGV Diagnostic result is "not detected" (YES in S10 ), the CPU 11 the WGV Irregularity diagnosis process to be described later in S20 out and move them to S30 in front. If, however, the WGV Diagnosis result is not "not detected" (NO in S10 ), moves the CPU 11 to S30 in front.

If the CPU 11 to S30 advances, determines the CPU 11 , if this WGV Diagnostic result is "normal" or not. In particular, the CPU determines 11 whether the value that suggests "normal" in the WGV Diagnostic result information is stored or not. If the value that indicates close to "normal" in the WGV Diagnostic result information is stored, the CPU determines 11 , that this WGV Diagnostic result is "normal."

If that WGV Diagnosis result is not "normal" (NO in S30 ), moves the CPU 11 to S80 in front. If, however, the WGV Diagnosis result is "normal" (YES in S30 ), determines the CPU 11 in S40 , if this ABV Diagnostic result is "not captured" or not. In particular, the CPU determines 11 whether the value that indicates "unrecognized" in the ABV Diagnostic result information stored in the RAM 13 for saving the ABV Diagnostic result is provided, stored or not. If the value that indicates "not detected" in the ABV Diagnostic result information is stored, the CPU determines 11 , that this ABV Diagnostic result is "not detected". An initial value of ABV Diagnostic result information indicates "not detected".

If that ABV Diagnostic result is "not detected" (YES in S40 ), the CPU performs 11 one ABV Initial Diagnostic Process to be Described Later in FIG S50 out and move them to S70 in front. If, however, the ABV Diagnosis result is not "not detected" (NO in S40 ), the CPU performs 11 a periodic ABV Diagnostic process, which will be described later, in S60 out and move them to S70 in front.

The CPU 11 closes S70 before and determines if that ABV Diagnostic result is "unusual" or not. In particular, the CPU determines 11 whether the value that suggests "unusual" in the ABV Diagnostic result information is stored or not. If the value that indicates "unusual" in the ABV Diagnostic result information is stored, the CPU determines 11 , that this ABV Diagnostic result is "unusual".

If that ABV Diagnostic result is "unusual" (YES in S70 ), moves the CPU 11 to S80 in front. After the procedure of the CPU 11 to S80 advances or advances, leads the CPU 11 a boost pressure limit and this completes the irregularity diagnosis process once.

If, however, the ABV Diagnostic result is not "unusual" (NO in S70 ), raises the CPU 11 in S90 the boost pressure limit and this terminates the irregularity diagnostic process once.

Subsequently, a procedure of a WGV Irregularity diagnosis process described in S20 is to execute.

With the execution of the WGV -Unnormality diagnostic process as it is in 3 is displayed, the CPU calculates 11 in the microcomputer 3 with the use of one WGV Opening (hereinafter referred to as "current WGV Opening "), which is indicated by the WGV -Öffnungsmesswertgeber 182 is recorded at the present time or the current time, in S110 first a lower one WGV Diagnostic limit ( WGV -LO) and an upper one WGV Diagnostic limit ( WGV -HI). In particular, the CPU calculates 11 a value obtained by subtracting a preset diagnostic distance from the current one WGV Opening as the WGV LO and compute this value by adding a current one WGV Opening to the diagnostic interval than the WGV -HI is obtained.

In S120 determines the CPU 11 , if she WGV Target opening larger than the WGV -LO or equal to this and smaller than that WGV -HI or equal to this or not. If the WGV Target opening smaller than that WGV -LO or greater than that WGV -HI is (NO in S120), counts the CPU 11 in S130 one WGV Irregularity determination counter stored in the RAM 13 is set up (adds 1) and sets this one WGV Normal destination counter stored in the RAM 13 is provided, back (sets 0).

After that, the CPU determines 11 in S140 whether a value (hereinafter referred to as "WGV-AC") of the WGV Irregularity determination counter greater than a preset one WGV Unevenness determination value (hereinafter referred to as "WGV-AT", a value corresponding to, for example, 1 second in this embodiment) or not. If the WGV -AC smaller than that WGV -AT is (NO in S140 ), the CPU stops 11 the WGV -Unregelmäßigkeitsdiagnoseprozess. If, however, the WGV -AC bigger than that WGV -AT or equal to this is (YES in S140 ), sets the CPU 11 in S150 the WGV Diagnostic result on "irregularity". In particular, the CPU saves 11 a value indicative of an "irregularity" in which WGV -Diagnoseergebnisinformation. Furthermore, the CPU stops 11 the WGV Irregularity diagnosis process after the WGV Diagnosis result is set to "irregularity".

If the WGV Target opening in S120 bigger than that WGV -LO or equal to this and smaller than that WGV -HI or equal to this is (YES in S120 ), counts the CPU 11 in S160 the WGV -Normalbestimmungszähler high and sets this furthermore the WGV -Unnormality determination counter back.

After that, the CPU determines 11 in S170 whether a value of WGV -Normal determination counter (hereinafter referred to as "WGV-NC") larger than a preset one WGV -Normal determination value (hereinafter referred to as "WGV-NT", a value corresponding to, for example, 1 second in this embodiment) or not. If the WGV -Normalbestimmungszählerwert WGV -NC smaller than that WGV -Normalbestimmungswert WGV -NT is (NO in S170 ), the CPU stops 11 the WGV -Ausgangsdiagnoseprozess. If, however, the WGV -Normalbestimmungszählerwert WGV -NC bigger than that WGV -Normalbestimmungswert WGV -NT or equal to this (YES in S170 ), sets the CPU 11 in S180 the WGV Diagnostic result on "normal". In particular, the CPU saves 11 a value that suggests "normal" in the WGV -Diagnoseergebnisinformation. Furthermore, the CPU stops 11 the WGV Irregularity diagnosis process after the WGV Diagnosis result is set to "normal".

Then a procedure of ABV Output diagnostic process described in S50 is to execute.

In the execution of the ABV Initial Diagnostic Process, as in 4 and 5 is shown, the CPU determines 11 of the microcomputer 3 in S310 first, whether an initial diagnostic start edge stored in the RAM 13 is set, set or not. If the initial diagnostic startup edge is not set (NO in S310 ), determines the CPU 11 in S320 whether the target boost pressure is less than an atmospheric pressure detected by the atmospheric pressure transmitter 137 is, or is equal to, or not.

When the target boost pressure exceeds the atmospheric pressure (NO in S320 ), gives the CPU 11 in S330 a control signal for an instruction to close it ABV 171 out. In response to the control signal, that concludes ABV 171 the intake bypass passage 170 ,

Furthermore, the CPU continues 11 in S340 one ABV Irregularity determination counter stored in the RAM 13 is provided. The CPU 11 puts in S350 one ABV Normal destination counter returned in the RAM 13 is provided. Furthermore, the CPU continues 11 in S360 on ABV Diagnosis result on "not detected." In particular, the CPU 11 a value that indicates "not detected" in the ABV -Diagnoseergebnisinformation. Furthermore, the CPU continues 11 the ABV Diagnostic result on "not detected" and then ends this the ABV -Ausgangsdiagnoseprozess.

When the destination transfer pressure in S320 less than or equal to the atmospheric pressure (YES in S320 ), determines the CPU 11 in S370 , whether the boost pressure transmitter 135 normal or not. When the boost pressure transmitter 135 is not normal or usual (NO in S370 ), moves the CPU 11 to S330 and performs the above processing. In contrast, when the boost pressure transmitter 135 is normal (YES in S370 ), determines the CPU 11 in S380 whether a boost pressure (hereinafter referred to as "present boost pressure") at the present time or time by the boost pressure transducer 135 greater than a preset lower one ABV Diagnostic Limit (hereinafter referred to as "ABV-LO") or equal to this and smaller than a preset upper one ABV Diagnostic Limit (hereinafter referred to as "ABV-HI") or equal to it or not. In this embodiment, the ABV A value obtained by subtracting a preset diagnostic distance from the target boost pressure. The ABV -HI is a value obtained by adding the target boost pressure to the diagnostic margin.

If the current boost pressure is lower than the ABV -LO or higher than that ABV -HI is (NO in S380 ), moves the CPU 11 to S330 and performs the above processing. If, however, the current boost pressure is greater than the ABV -LO or equal to this and smaller than that ABV -HI or equal to this is (YES in S380 ), counts the CPU 11 in S390 a non-diagnostic expiration time counter stored in the RAM 13 is provided.

Furthermore, the CPU determines 11 in S400 Whether or not a value of the non-diagnostic runtime counter (hereinafter referred to as "NDC") is lower than a preset diagnosis stop determination value (hereinafter referred to as "DSDT", a value corresponding to, for example, 5 seconds in this embodiment). If the NDC is greater than or equal to the DSDT (NO in S400 ), sets the CPU 11 in S410 the ABV Diagnostic result on "timeout". In particular, the CPU saves 11 a value that indicates a "timeout" in which ABV -Diagnoseergebnisinformation. The CPU 11 closes S610 before, after that ABV Diagnosis result is set to "timeout".

On the other hand, if the NDC is lower than the DSDT (YES in S400 ), gives the CPU 11 in S420 a control signal for an instruction about the opening of the ABV 171 out. In response to the control signal, this opens ABV 171 the intake bypass passage 170 , Furthermore, the CPU continues 11 in S430 the initial diagnostic start edge and ends this ABV -Ausgangsdiagnoseprozess.

When the initial diagnostic startup edge in S310 is set (YES in S310 ), determines the CPU 11 in S440 , if one WGV -Close start edge in the RAM 13 is set, set or not. If the WGV Closing start edge is not set (NO in S440 ), counts the CPU 11 in S450 one ABV Opening counter high in the RAM 13 is provided.

In S460 determines the CPU 11 whether a value (hereinafter referred to as "ABV-OC") of the ABV Opening counter greater than a pre-set WGV -Setting determination value (hereinafter referred to as "WGV-CT", a value corresponding to, for example, 5 ms in this embodiment) or not, or not. If the ABV -OC lower than that WGV -CT is (NO in S460 ), the CPU stops 11 the ABV -Ausgangsdiagnoseprozess.

If, however, the ABV -OC bigger than that WGV -CT or equal to this (YES in S460 ), sets the CPU 11 in S470 the WGV - Target opening on an opening that indicates a fully closed state (hereinafter referred to as "completely closed WGV Opening "). As a result, that concludes WGV 181 the exhaust bypass passage 180 , Furthermore, the CPU continues 11 in S480 the WGV -Schließstartflanke. The CPU 11 puts in S490 the ABV -Opening counter back and finish the ABV -Ausgangsdiagnoseprozess.

If the WGV Closing start in S440 is set (YES in S440 ), counts the CPU 11 in S500 one WGV Shutdown counter high in the RAM 13 is provided.

Furthermore, the CPU determines 11 in S510 whether a value of WGV Key count (hereinafter referred to as "WGV-CC") is greater than or equal to a preset cancel release determination value (hereinafter referred to as "CCV", a value corresponding to, for example, 1 second in this embodiment). If the WGV -CC is smaller than the CCV (NO in S510 ), moves the procedure of the CPU 11 to S540 in front.

If, however, the WGV -CC is greater than or equal to CCV (YES in S510 ), raises the CPU 11 in S520 a state in which the WGV Target opening on the completely closed WGV -Opening is set on. As a result, that is WGV 181 does or does this work, so that the opening of the WGV 181 the WGV Target opening, which is calculated continuously. Furthermore, the CPU continues 11 in S530 the WGV Reset counter and move it to S540 in front.

The CPU 11 closes S540 before and then determines whether the current boost pressure is greater than the ABV -LO or equal to this and smaller than that ABV -HI or this is or not. If the current boost pressure is less than the ABV -LO or greater than that ABV -HI is (NO in S540 ), counts the CPU 11 in S550 one ABV Irregularity determination counter stored in the RAM 13 is high and sets this one more ABV Normal destination counter stored in the RAM 13 is provided back.

After that, the CPU determines 11 in S560 whether a value (hereinafter referred to as "ABV-AC") of the ABV Irregularity determination counter greater than a preset one ABV Unevenness determination value (hereinafter referred to as "ABV-AT", a value corresponding to, for example, 0.1 second in this embodiment) or not. If the ABV -AC smaller than that ABV -AT is (NO in S560 ), the CPU stops 11 the ABV -Ausgangsdiagnoseprozess. If, however, the ABV -AC bigger than that ABV -AT or equal to this is (YES in S560 ), sets the CPU 11 in S570 the ABV Diagnosis result on "unusual". In particular, the CPU saves 11 a value that suggests "unusual" in the ABV -Diagnoseergebnisinformation. Furthermore, the CPU moves 11 on S610 before, after that ABV Diagnosis result is set to "unusual".

If the current boost pressure in S540 bigger than that ABV -LO or equal to this and smaller than that ABV -HI or equal to this is (YES in S540 ), counts the CPU 11 in S580 the ABV -Normalbestimmungszähler high and sets this furthermore the ABV -Unnormality determination counter back.

After that, the CPU determines 11 in S590 whether a value of ABV -Normal determination counter (hereinafter referred to as "ABV-NC") larger than a preset one ABV -Normal determination value (hereinafter referred to as "ABV-NT", a value corresponding to, for example, 1 second in this embodiment) or not. If the ABV -Normal determination counter value smaller than the ABV -Normal determination value is (NO in S590 ), the CPU stops 11 the ABV -Ausgangsdiagnoseprozess. If, however, the ABV -Normal determination counter value greater than the ABV -Normal determination value or equal to this (YES in S590 ), sets the CPU 11 in S600 the ABV Diagnostic result on "normal". In particular, the CPU saves 11 a value that suggests "normal" in the ABV -Diagnoseergebnisinformation. Furthermore, the CPU moves 11 to S610 before, after that ABV Diagnosis result is set to "normal".

Furthermore, the CPU moves 11 on S610 and gives this a control signal for an instruction about the closing of the ABV 171 out. In response to the control signal, that concludes ABV 171 the intake bypass passage 170 , Furthermore, the CPU clears or eliminates 11 in S620 the initial diagnostic startup edge and the WGV -Close start edge, and stop the ABV -Ausgangsdiagnoseprozess.

Then a procedure of the periodic ABV Diagnostic process described in S60 is to execute.

In the execution of the periodic ABV -Diagnosis process, as in 6 is shown, counts the CPU 11 of the microcomputer 3 in S710 First, the diagnostic interval counter, which is in the RAM 13 is provided, down (subtracted by 1) or not. The diagnostic interval counter sets a preset periodical execution determination value (a value corresponding to, for example, 1 minute in this embodiment) as an initial value so as to have an execution cycle of the periodic one ABV Diagnostic process.

Furthermore, the CPU determines 11 in S720 whether or not a value of the diagnostic interval counter (hereinafter referred to as "diagnostic interval counter value") is 0 or not. If the diagnostic interval counter value is not 0 (NO in S720 ), sets the CPU 11 in S730 the ABV Irregularity determination counter and the ABV -Normal determination counter back, and this ends the periodic ABV -Diagnoseprozess.

On the other hand, it is the diagnostic interval counter value 0 (YES in S720 ), determines the CPU 11 in S740 Whether a preset periodic diagnostic start condition is met or not. The periodic diagnosis start condition according to this embodiment must satisfy all of the start conditions, first periodic start condition, second periodic start condition, third periodic start condition, and fourth periodic start condition, which will be described below.

The first periodic start condition is that the throttle opening is smaller than a first start determination value set to be in advance to provide or equal to a small opening.

The second periodic start condition is a situation in which a controller for opening of the WGV 181 is performed to suppress an increase in the boost pressure. In particular, it is determined that there is a case where the WGV Target opening gradually increases with time, being in a situation where control for opening of the WGV 181 on the basis of multiple WGV Target openings calculated last.

The third periodic starting condition is that the current boost pressure is lower than a pressure (hereinafter referred to as "WGV off-loading pressure"), which is the only one WGV 181 can be controlled to turn off the charging or off. The WGV Off-loading is determined with reference to a three-dimensional map or drawing in which a value of the WGV -Out shift boost pressure in advance with an engine speed, a charging efficiency of the cylinder 101 and the current one WGV Opening is set as a parameter.

The fourth periodic start condition is that the boost pressure transducer 135 normal.

If the periodic diagnostic start condition is not satisfied (NO in S740 ), moves the CPU 11 to S730 and performs the above processing. On the other hand, if the periodic diagnosis start condition is satisfied (YES in FIG S740 ), gives the CPU 11 in S750 a control signal for an instruction about the opening of the ABV 171 out and put these the WGV Target opening to a constant target value of the throttle opening at the current time or the current time. The constant target value is one WGV Target opening calculated in a steady state where the throttle opening is maintained at the present time.

After that, the CPU determines 11 in S760 whether the current boost pressure is greater than that ABV -LO or equal to this and smaller than that ABV -HI or this is or not. If the current boost pressure is less than the ABV -LO or greater than that ABV -HI is (NO in S760 ), counts the CPU 11 in S770 one ABV Irregularity determination counter high and sets this one more ABV -Normal determination counter back.

After that, the CPU determines 11 in S780 , if he ABV -AC bigger than that ABV -AT or this is or not. If the ABV -AC smaller than that ABV -AT is (NO in S780 ), the CPU stops 11 the periodic ABV -Diagnoseprozess. If, however, the ABV -AC bigger than that ABV -AT or equal to this is (YES in S780 ), set the CPU 11 in S790 the ABV Diagnostic result on "unusual" and moves them to S830 in front.

If the current boost pressure in S760 bigger than that ABV -Lo or equal to this and less than that ABV -HI or equal to this is (YES in S760 ), counts the CPU 11 in S800 the ABV -Normal determination counter high and sets this ABV -Normal determination counter back.

After that, the CPU determines 11 in S810 , if he ABV -Normal determination counter value greater than the ABV -Normal determination value or is equal to this or not. If the ABV -Normal determination counter value smaller than the ABV -Normal determination value is (NO in S810 ), the CPU stops 11 the periodic ABV -Diagnoseprozess. If, however, the ABV -Normal determination counter value greater than the ABV -Normal determination value or equal to this (YES in S810 ), sets the CPU 11 in S820 the ABV -Diagnose result on "normal" and moves them to S830 in front.

If the procedure of the CPU 11 to S830 advances, gives the CPU 11 a control signal indicating the closing of the ABV 171 indicates, and removes, a state in which the WGV Target opening is set to a constant target value. In response to the control signal, that concludes ABV 171 the intake bypass passage 170 , The WGV 181 is active or works, so that the opening of the WGV 181 the WGV Target opening, which is calculated continuously.

Furthermore, the CPU initializes 11 in S840 the diagnostic interval counter. In particular, the CPU continues 11 a value of the diagnostic interval counter to the above execution cycle determination value. Upon completion of the initialization of the diagnostic interval counter, the CPU stops 11 the periodic ABV -Diagnoseprozess.

Then the operation of the ABV 171 and the WGV 181 in that ABV Output diagnostic process.

As it is in 7 is shown, the ABV -Outgoing diagnostic process performed immediately after the engine 100 starts (with respect to the throttle opening TP), and gives the microcomputer 3 first an instruction to open that ABV 171 off (with respect to a time or a time t1 ). After a time that the WGV -CT matches, elapses, the microcomputer closes 3 the WGV 181 (with reference to a time or a time t2 ). Further, after a time corresponding to the CCV elapses, the microcomputer opens 3 the WGV 181 (with respect to a time t3).

If that ABV 171 in response to the instruction to open that ABV 171 is opened, the current boost pressure does not change, even if that WGV 181 is closed (with respect to a boost pressure BP1). If, however, the ABV 171 due to the irregularity of the ABV 171 remains closed, although the microcomputer 3 the instruction to open that ABV 171 gives rise to the current boost pressure (with respect to a boost pressure BP2).

After the microcomputer 3 on the basis of the current boost pressure determines whether the ABV 171 normal or ordinary or unusual, is the microcomputer 3 an instruction to close that ABV 171 off (with respect to a time or a time t4).

As described above, the ABV Initial Diagnostic Process the Irregularity of the ABV 171 diagnose in a situation where there is no charge request. In the situation where there is no load request, the target boost pressure is set to the atmospheric pressure. For that reason, if that ABV 171 normal or common is the microcomputer 3 the irregularity of that ABV 171 without diagnosing any variation in boost pressure.

Then the operation of the ABV 171 and the WGV 181 in the periodic ABV -Diagnosis process described.

As it is in 8th is shown, when the throttle opening becomes smaller than or equal to the first start determination value, the microcomputer 3 first an instruction to open that ABV 171 and sets this the WGV Target opening to a consistent target value TG11 in the throttle opening at the present time (with respect to a time) t11 ). When the throttle opening decreases, when the periodic ABV Diagnostic process is not running, the microcomputer controls 3 the WGV 181 , So that the WGV Target opening usually greater than the constant target value TG11 will (with reference to a WGV Opening WP 11 ).

If that ABV 171 according to the instruction to open that ABV 171 is opened, the present boost pressure does not change, even if the opening of the WGV 181 to the same target value TG11 is fixed (with respect to a boost pressure BP11 ). If, however, the ABV 171 because of the irregularity of that ABV 171 remains closed, although the microcomputer 3 the instruction to open that ABV 171 gives rise to the current boost pressure (with respect to a boost pressure BP12 ).

After the microcomputer 3 on the basis of the current boost pressure determines whether the ABV 171 normal or ordinary or unusual, is the microcomputer 3 an instruction to close that ABV 171 (with reference to a time or a time t12 ). The microcomputer 3 picks up a state in which the WGV Target opening is set at the same target value. As a result, that is WGV 181 works or works this way, so the opening of the WGV 181 the WGV Target opening, which is continuously calculated, corresponds (with respect to a WGV -Zielöffnung TG12 ).

As described above, the periodic operates ABV -Diagnosis process that WGV 181 so that the boost pressure increases in a situation where the boost pressure due to the WGV 181 reduced in a normal state. Since the throttle opening is small, the microcomputer can 3 the irregularity of that ABV 171 diagnose in a situation where the boost pressure is low. For this reason, even if the boost pressure due to the abnormality diagnosis of the ABV 171 changes, an influence on a driving behavior of the vehicle small.

The engine-ECU 2 configured as described above determines whether the diagnostic start condition indicating that the boost pressure is low is satisfied or not ( S320 . S380 . S740 ).

The diagnostic start condition must satisfy the first start condition or the second start condition.

The first start condition includes that the target boost pressure is less than or equal to the atmospheric pressure ( S320 ) and that the current boost pressure is greater than the ABV -LO or equal to this and smaller than that ABV -HI or equal to this is ( S380 ). As a result, the first start condition can be satisfied when the engine 100 is in an idle mode.

The second start condition includes that the throttle opening is smaller than or equal to the first start determination value ( S740 ). As a result, the second start condition can be satisfied when the boost pressure is low.

When the diagnostic start condition is satisfied, the engine ECU allows 2 the ABV 171 for opening and closing the intake bypass passage 170 who is the compressor 162 bypasses the intake bypass passage 170 to open ( S420 . S750 ).

If furthermore the ABV 171 the intake bypass passage 170 closes, allows the engine-ECU 2 the WGV 181 for opening and closing the exhaust bypass passage 180 , the turbine 161 bypasses operating in a default anomaly diagnostic mode to increase boost (fig. S470 . S750 ). In particular, when the first start condition is satisfied, the engine ECU allows 2 the WGV 181 , the exhaust bypass passage 180 like the irregularity operation ( S470 ) close. When the second start condition is satisfied, the engine-ECU resets 2 the WGV Target opening to the constant target value in the throttle opening at the present time or the current time as the irregularity diagnosis operation ( S750 ).

The engine-ECU 2 determines that an irregularity in the ABV 171 occurs when a default normal determination condition indicative of the boost pressure when the ABV 171 the intake bypass passage 170 opens, not satisfied, after the engine-ECU 2 the WGV 181 allows to operate or operate in the abnormality diagnostic mode ( S540 to S50 . S760 to S790 ).

If the engine-ECU 2 configured as described above, may determine that the irregularity in the ABV 171 occurs if the engine-ECU 2 both the ABV 171 as well as that WGV 181 operates when the boost pressure is low to increase the boost pressure.

As described above, the engine-ECU 2 diagnose if the irregularity in the ABV 171 occurs or not, even if the boost pressure is low.

As it is in 9 is shown, charging is performed when the requested torque is the output limit torque T1 , which is effected regardless of the engine speed by a natural or normal intake, exceeds (with respect to loading regions RB1 and RB2 ). Regarding 9 identifies the loading region RB1 from the loading region RB1 and loading region RB2 a region where an operation of the ABV 171 is required to suppress an increase in boost pressure.

As it is in 10 even if there is no need to allow the ABV 171 operates to suppress an increase in the boost pressure (that is, in a situation corresponding to the charging region RB2), the engine-ECU 2 both valves, ABV 171 and WGV 181 , operate or operate to the irregularity of the ABV 171 to diagnose. Regarding 10 A region above a diagnosis operation boundary line Lw denotes a region where the irregularity of the ABV 171 can be diagnosed.

For this reason, the engine-ECU 2 the irregularity of that ABV 171 capture before the boost pressure gets higher when the engine fails 100 more occurs. With the above configuration, the engine-ECU 2 suppress the occurrence of a situation in which the failure in the engine 100 due to the irregularity of the ABV 171 occurs.

When the boost pressure is low, the engine-ECU is diagnosed 2 the irregularity of that ABV 171 , For this reason, even if the boost pressure due to the irregularity of the ABV 171 in the abnormality diagnosis situation of that ABV 171 increased, a change in pressure small. As a result, the engine-ECU 2 an influence of the change in the boost pressure due to the abnormality diagnosis of the ABV 171 in driving behavior (for example, a variation of the engine speed) of the vehicle minimize. If the driving behavior of the vehicle due to the change in the boost pressure in the abnormality diagnosis of the ABV 171 changes, a driver of the vehicle, who perceives the change in driving behavior, recognize that the irregularity in the ABV 171 can occur.

An occurrence frequency of the situation in which the boost pressure is low is greater than a frequency of occurrence of the situation in which the boost pressure is high. The engine-ECU 2 The number of executions of the abnormality diagnosis of the ABV 171 increase, as the irregularity of the ABV 171 is diagnosed when the boost pressure is low.

The first start condition implies that the NDC is greater than or equal to the DSDT ( S400 ) in addition to the target boost pressure being less than or equal to the atmospheric pressure ( S320 ), and that the present boost pressure is greater than the ABV -LO or equal to this and smaller than that ABV -HI or equal to this is ( S380 ). As a result, the engine-ECU 2 the ABV Run the initial diagnostic process when the engine is running 100 starts and the engine 100 in idle mode. Because the vehicle stops when the engine 100 starts, even if the drivability of the vehicle due to the change in the boost pressure in the abnormality diagnosis of the ABV 171 changes, the engine-ECU 2 prevent the change in driving behavior to inhibit the operation of the vehicle by the driver.

If the NDC is greater than or equal to the DSDT (NO in S400 ), stops the engine-ECU 2 the irregularity diagnosis mode (ie the ABV Output diagnostic process) caused by meeting the first start condition.

With the above configuration, after the diagnosis stop determination time has elapsed corresponding to the DSDT, not both the ABV Output diagnostic process as well as the more periodic ABV Diagnostic process, but only the periodic ABV Diagnostic process can be performed, an arithmetic processing load of the engine ECU 2 be reduced.

In the embodiment described above, the engine ECU 2 An electronic control device according to the invention is the processing of S320 . S380 and S740 a start determining device according to the invention is the processing of S420 and S750 a valve opening device according to the invention, is the processing of S470 and S750 a diagnostic operating device according to the invention, is the processing of S540 to S570 and S760 to S790 an irregularity determination device according to the invention and is the processing of S400 a stopper device according to the invention.

Embodiments of the invention have been described above. However, the invention is not limited to the above-described embodiments, and various aspects can be made within a range that does not depart from the technical scope of the invention.

Modification 1

For example, in the above embodiment, the embodiment of the ABV Output diagnostic process until the diagnostic stop determination time elapses according to the DSDT. However, even after the diagnosis stop determination time has elapsed, the ABV Output process are executed if the first start condition is met.

In addition, a function of a constituent element in the above-described embodiments may be divided among a plurality of constituent elements, or functions of a plurality of constituent elements may be integrated into one constituent element. In addition, at least a portion of the configuration in the above-described embodiment may be replaced with a well-known configuration having the same function. Part of the configuration of the above embodiments may be omitted. In addition, at least part of the configurations of the above-described embodiments may be added to or exchanged with the configurations of the other embodiments. In addition, all aspects included in the technical sense specified solely by the words of the appended claims are embodiments of the invention.

An engine ECU determines whether or not a preset diagnosis start condition indicating that a boost pressure is low is satisfied. When the diagnostic start condition is satisfied, the engine ECU allows one ABV to open a suction bypass passage. If that ABV closes the intake bypass passage, the engine ECU allows one WGV operate in a preset abnormality diagnostic mode to increase boost pressure. The engine-ECU determines that an irregularity in the ABV occurs when a default normal determination condition indicative of a boost pressure when the ABV opens the intake bypass passage is not satisfied after the engine-ECU the WGV allows to operate in the abnormality diagnosis mode.

Claims (5)

An electronic control apparatus (2) comprising: start determining means (S320, S380, S740) for determining whether a preset diagnosis start condition is satisfied, which indicates that a supercharging pressure, which is an intake air compressed by a supercharger (160), is low, wherein the supercharger has a turbine (161) disposed in an exhaust passage (140) of an internal combustion engine (100) and a compressor (162) disposed in an intake passage (120) of the internal combustion engine, a valve opening device (S420, S750) allowing an air bypass valve (171) for opening and closing the intake bypass passage (170) bypassing the compressor to open the intake bypass passage when the start determination device determines that the diagnosis start condition is satisfied, a diagnostic operation device (S470, S750) coupled to a wastegate (181) for opening and closing an exhaust bypass passage (180), bypassing the turbine allows to operate in a preset abnormality diagnosing operation to increase the boost pressure when the air bypass valve closes the intake bypass passage in a case where the start determination device determines that the diagnosis start condition is satisfied, and an abnormality determination device (S540 to S570, S760 to S790) that determines that an abnormality occurs in the air bypass valve in a case where a preset normal determination condition determines the boost pressure when the air bypass valve opens the intake bypass passage is not satisfied after the wastegate operates in the abnormality diagnosis operation. Electronic control device according to Claim 1 wherein it is the diagnosis start condition that the internal combustion engine is in an idling operation, and the abnormality diagnosis operation closes the exhaust bypass passage. Electronic control device according to Claim 1 wherein it is the diagnosis start condition that opening of a throttle valve disposed in the intake passage is smaller than a preset start determination value indicating that a throttle opening is small or equal to, and the abnormality diagnosis operation sets an opening of the wastegate less than the one if the diagnostic start condition is not met. Electronic control device according to Claim 2 wherein it is the diagnostic start condition that the engine starts and the engine is in the idle mode. Electronic control device according to Claim 1 wherein the diagnostic starting condition is a first starting condition indicating that the engine is in the idling operation or a second starting condition indicating that the opening of the throttle valve disposed in the intake passage is smaller than a preset starting determination value indicating that the throttle opening is small is equal to, or equal to, the abnormality diagnosing operation closes the exhaust bypass passage when the first start condition is satisfied, the abnormality diagnosis sets the opening of the wastegate to be smaller than that when the second start condition is not satisfied, if the second start condition is satisfied is satisfied, and the electronic control apparatus further comprises a prohibition device (S400) that inhibits the abnormality diagnosis operation caused by satisfying the first start condition, if any The diagnostic stop determination time elapses after the engine starts.

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