DE4225361A1 - Functional testing of secondary air admission into IC engine exhaust - involves measuring lambda value of exhaust gases by sensor supplying electronic control unit for secondary air pump and valve - Google Patents

Abstract

In a procedure for testing the admission of secondary air into the exhaust of an IC engine as a decontamination measure, there is a sensor (22) measuring the oxygen content (or lambda) in the exhaust gas at the exit of the exhaust headers. The sensor (22) feeds into an electronic control unit (ECU) (26) for an auxiliary pump and a valve supplying extra air when necessary upstream of the sensor. The sensor signal (or a mean value derived from it) is compared with a stored theoretical value and if the difference exceeds a preset amount, an error signal is generated. ADVANTAGE- Exact monitoring of secondary air admission.

Description

The invention relates to a method for functional testing the secondary air supply into the exhaust system Internal combustion engine with exhaust gas detoxification, according to the Ober Concept of claim 1.

For immediate, improved exhaust gas detoxification to achieve in the cold start area of the internal combustion engine and when using, for example, a three-way kata lysators to ensure its quick start, it is known to introduce secondary air into the exhaust system lead and the internal combustion engine at short notice with stoichiometric fuel-air ratio (= rich) too operate. It is through the Japanese patent stract 3-15619 (A) known to close the secondary air supply check by the temperature rise of the catalyst measured and compared with a target value. A such a method is complex and required additional means such as accurate temperature sensors etc.

The object of the invention is a generic Ver drive to show which one with simple means allows a more precise check of the secondary air supply light.

According to the invention, this object is characterized by the solved the features of claim 1. Further advantageous further development of the method are the white tere patent claims.  

In the method according to the invention, during the Se the actual signal or an integrator signal from the exhaust gas probe, in particular a lambda probe, recorded and compared with a stored setpoint and an error signal at a predetermined difference generated. Because the lambda sensor due to its machinenna hen arrangement in the exhaust system and possibly a separate one Heating ready for operation after just a few seconds this signal or its derived signal used for the time of the secondary air supply an anomaly in the secondary air supply point out. In this case, a electronic control unit, e.g. B. directly in the Control unit for the lambda control, a setpoint or a map with several setpoints stored and on Actual setpoint comparison.

In further training of the method can be done over the entire Test time of the signal level recorded and the quotient from the Time interval of a defined signal value the total test time is calculated and saved Values are compared.

It is also advantageous, particularly in the case of internal combustion machines in motor vehicles, defined load conditions to hide (e.g. overrun phases) in which no relevant tes probe signal is present. Furthermore, the total test time begin with the operational readiness of the flue gas probe, which is reached after a few seconds and end with the shutdown of the secondary air supply.

In further development of the method can also be used for warm internal combustion engine sporadically and briefly the secondary air supply switched on and one Check the exhaust gas probe signal.  

For example, the tightness of the system, especially the function of the secondary air supply tion arranged control valve can be checked. By which is due to the sudden change in the exhaust gas composition or oxygen supply into the exhaust system Tending signal deviation of the exhaust gas probe signal can also the proper functioning of the secondary air supply be closed reliably. This should be preferred Check in a stationary operation of the Brenn engine take place, especially in idle mode. Signal deviations at the exhaust gas probe can be particularly important here which are precisely recorded.

An embodiment of the invention is as follows explained in more detail with further details. The schemati The drawing shows in

Fig. 1 is a block diagram of a reciprocating internal combustion engine with exhaust gas detoxification via a catalyst and with a feed device for secondary air, which is monitored by a switched-on lambda probe and a control unit;

FIG. 2 shows the test sequence of the device according to FIG. 1 on the basis of a simplified Lambda signal; and

Fig. 3 shows another test sequence in Betriebsswar mer internal combustion engine for system tightness check.

In Fig. 1, 10 denotes a four-cylinder reciprocating internal combustion engine, the fuel-air supply via an intake manifold 12 and a fuel injection, not shown, while the exhaust gas through an exhaust manifold 14 , an exhaust pipe 16 , a three-way catalyst 18 and one exhaust system, not shown, is discharged with an exhaust pipe 20 .

In the connection area between the exhaust manifold 14 and the exhaust pipe 16 , a lambda probe 22 is provided as an exhaust gas probe of a known type, via which the oxygen content in the exhaust gas of the internal combustion engine can be detected and thus the fuel metering can be influenced in the control method. The signal from the lambda probe 22 is fed via a line 24 to a control unit 26 for the lambda control.

Via the electronic control unit 26 , the secondary air supply to the internal combustion engine 10 is also controlled, an electrically driven secondary air pump 30 being controlled via a line 28 and a control valve 34 being controllable via a line 32 . The control valve 34 is seated in a feed line 36 , via which oxygen-containing gas or air can be blown into the exhaust gas channels of the internal combustion engine 10 .

If the internal combustion engine 10 is started in the cold state, which is communicated to the control unit 26 via a temperature signal T1, the secondary air pump 30 is activated and the control valve 34 is opened, so that the internal combustion engine is supplied with air or oxygen with a stoichiometric fuel-air mixture is blown into the exhaust system. After a short term of z. B. 20 seconds, the exhaust gas probe 22 has warmed to a temperature at which it is ready for operation by the hot exhaust gas in connection with the after-reaction by the secondary air blowing.

As shown in Fig. 2, the flow chart of time t (curve I) shows, after engine start at the mark _{SLP, a} secondary air pump 30 and the controller 34 is activated, specifically, for the entire secondary air feeding. B. 90 seconds (until SLP _off ).

With the operational readiness of the lambda probe 22 (e.g. after 20 seconds), its signal is detected as rich (increased) or lean (lines II and III) and evaluated for the function check of the secondary air supply.

Defined load conditions, such as B. Thrust phase (no fuel supply) or high engine speed pay (verification too imprecise) according to line IV blinds, so not rated.

The remaining signals indicating an over-stoichiometric fuel-air admixture to the internal combustion engine (- bold; theoretically, however, the lean signals could also be detected) of the lambda probe 22 are added in a counter (line V) of the electronic control unit 26 and the quotient is added the total test time (minus the hidden load ranges) determined and compared with a setpoint stored in the control unit 26 in a fixed value memory. It goes without saying that, instead of one setpoint, a plurality of setpoints can also be stored, similar to a map and assigned different load spectra of the internal combustion engine.

If the actual value determined via the lambda signals or an integrator signal derived therefrom differs from the target value in a defined manner, then an error signal is output via a line 38 to a warning lamp 40 via the control unit 26 (cf. FIG. 1). The error signal can also be stored temporarily or permanently in an error memory and read out during a function check (on-board diagnosis).

Fig. 3 shows a further flow diagram over time t (line VI) in which the secondary air pump 30 is briefly switched on (line VII), but the control valve 34 is not, when the internal combustion engine is warm when idling (idling speed, for example 800 min-1) is activated, i.e. is closed. The line VIII shows in solid lines a course of the integrator signal 42 , with an increasing mean value due to the lambda signal "ma ger", which drops again after the secondary air pump 30 is switched off to the normal mean value 44 pending when idling.

This curve results when the control valve 34 is leaking in the secondary air supply, that is, additional oxygen is supplied to the exhaust gas of the internal combustion engine, which falsifies the signal from the lambda sensor 22 after "lean" (= excess air in the fuel-air admixture). With a functional and tight control valve 34 , the lambda signal would remain unchanged in accordance with the mean value 44 . The deviation shown can be detected by the control unit 26 by comparison with a stored setpoint and an error signal can also be triggered.

Claims (7)

1. A method for functional testing of the secondary air supply in the exhaust system of an internal combustion engine with exhaust gas detoxification with a supply device for secondary air which flows upstream of an exhaust gas influencing the fuel additive solution to the internal combustion engine, characterized in that during the secondary air supply the actual signal or a derivative thereof Signal mean value detected and compared with a stored target value, and that an error signal is given at a predetermined difference. 2. The method according to claim 1, characterized in that that the duration of a defined signal value over the Test time recorded and the quotient with the overall test time determined and compared with stored values will. 3. The method according to claims 1 and 2, characterized ge indicates that defined load conditions of the combustion engine are hidden. 4. The method according to claims 1 to 3, characterized ge indicates that the functional test when reached the operational readiness of the flue gas probe begins and the remaining duration of the secondary air supply tion extends. 5. The method according to one or more of claims 1 to 4, characterized in that when warmer  Internal combustion engine sporadically briefly the second air supply switched on and another radio tion test is carried out. 6. The method according to claim 5, characterized in that with a secondary air supply through an air pump and a control valve the further functional test tion is carried out with the control valve closed becomes. 7. The method according to claims 5 and 6, characterized ge indicates that the further functional test in stationary operation of the internal combustion engine, in particular which is carried out in idle mode.