DE4001334A1 - RETROFIT KIT FOR OTTO ENGINES - Google Patents

Description

The invention relates to a retrofit kit for retrofitting Gasoline injection systems for petrol engines with one Controlled catalyst comprising lambda probe, the Gasoline injection system with one injection control Has computer with measuring probes for the operating state the engine, e.g. B. a temperature sensor, an intake manifold pressure sensor, an intake air sensor and the like in Tax connection is established.

Vehicles with an injection engine can be used for exhaust gas cleaning equipped with a regulated catalytic converter will. It is known that the existing injection control by a new one with a connection for one to the regulated one To replace the catalyst belonging to the lambda probe. This is necessary a lot of effort, especially as a rule complete wiring harness connecting the individual units must be replaced.

One could also ent the existing injection control converting speaking. However, this has the disadvantage that at Failure of the control a repair of only a few works could be carried out and that an "exchange repair "with replacement of the injection control only then is possible if a suitable, also converted tax is available. Added to this would be the fact that the Replacement of the wiring harness would be necessary.

The object of the present invention is to retrofit to create a set for injection petrol engines, the connec with the standard built-in, unchanged on spray control and a retrofitted standard Catalyst with lambda probe using an exhaust gas cleaning system Regulated three-way catalyst gives a significant Reduction of the emission of sheep results. This retrofit sentence should be designed so that the subsequent installation easily in a short time and therefore also inexpensively can be taken.

To solve this problem, the invention proposes, in particular, that the retrofit kit has an additional computer which is connected to the lambda probe and also to at least one connecting line between a measuring probe and an injection control for changing at least one of one of the measuring probes Measurement signals in the sense of a change in the mixture preparation and after regulation to an optimal air-fuel ratio within the lambda window.
With the help of the additional computer, the "incomprehensible" measurement signal of the lambda probe for the injection control is converted into a quantity that can be evaluated by the existing control. Since the mixture preparation by the control, among other things, e.g. B. in dependency on the operating temperature of the engine, a correction value can be superimposed on the value coming from the temperature sensor, the intake manifold pressure sensor, etc., so that the then changed measured value can trigger a corresponding reaction of the injection control. The measured value change is carried out so that the lambda value 1 required for optimal operation of the catalyst arises accordingly, an air-fuel ratio of 14.6: 1 with possibly small tolerance deviations. Accordingly, for example in excess air, which results in a lambda value greater than 1, when using the engine temperature as a "manipulated" measurement signal, the actual measured operating temperature value of the engine is changed to lower values by the superimposed correction value, whereupon the Injection control reacts with a fuel enrichment of the mixture. This in turn leads to a reduction in the lambda value. The readjustment of the injection control is thus carried out by simulation of "incorrect" measurement data per se. If the computer belonging to the injection control system interprets comparatively fast, that is to say measurement data changes taking place at short time intervals, in particular at its input relating to the engine temperature, as an error, other measurement signals which change during operation anyway in a comparatively large range can be superimposed of the measured value can be used with a correction value. Instead of the temperature measurement value, the intake pipe vacuum measurement value is preferably used in this case.
The retrofit kit according to the invention does not require any intervention in the existing system. The connection is made by simply re-plugging the existing connecting line between the sensor used in each case and the injection control and by connecting to the vehicle electrical system for power supply.

The additional computer preferably has one in series with one Sensor resistance switched, changeable resistance as Actuator for the simulation of the measured variable change. With this arrangement, the resistance value of the enlarge the respective measuring circuit and thus the air force Grease the mixture. It takes advantage of the fact that Basic setting of the existing injection control one Lambda value greater than 1 results in a regulation to larger measuring circuit resistance values, e.g. B. accordingly the simulation of lower operating temperature values is sufficient.  

If necessary, the existing basic setting can be corrected accordingly.
It is also advantageous with this arrangement that if there is a defect in the additional computer, there is no risk of the mixture becoming completely leaner, and thus there is a risk of engine damage, since at low resistance until the variable resistance of the additional computer becomes short in extreme cases would set the original conditions as in operation alone with the standard injection control. In the opposite case, a mixture enrichment that is harmless for the engine would result.

According to a development of the invention, it is provided that the additional computer is connected via a control line to a valve which is located in a connecting line between the tank and the gasoline injection system and that the additional computer for controlling this valve has measurement inputs at least for the engine speed and the engine temperature points.
With the help of this valve controlled by the additional computer, depending on the particular operating state of the engine, gasoline vapors can be discharged from the tank into the fuel-air mixture, expediently when the hydrocarbon emission is low.

Additional embodiments of the invention are in the white other subclaims. Below is the Er finding explained in more detail with reference to the drawing.

The only figure shows:
is a schematic representation of a gasoline engine equipped with a gasoline injection system and controlled three-way catalyst.

A petrol engine 1 shown in the figure is equipped with a gasoline injection system 2 , which is connected to an injection control 3 . This injection control 3 has a series of measurement inputs 4 , the measurement data supplied here being processed by a computer belonging to the injection control 3 . At these measuring inputs 4 , for example, data relating to the speed, the intake pipe negative pressure, the outside temperature, the engine temperature, the throttle valve position, the position of the idle CO potentiometer, the intake air temperature and the like are supplied.

All these supplied data are processed and the gasoline injection system 2 is accordingly set by the injection control 3 to the optimum mixture preparation for the particular operating conditions.

In a gasoline engine of this type with a gasoline injection system, a three-way catalytic converter is now to be retrofitted to reduce pollutant emissions. For this purpose, a catalytic converter 6 and a lambda probe 7 are installed in the exhaust pipe 5 . The air-fuel ratio can be checked with the help of the lambda probe. It is essential here that the exhaust gas composition is kept in a range required for the optimal action of the catalytic converter, the so-called lambda window. The measurement data coming from the lambda probe 7 cannot be processed by the existing injection control. In order to make this possible, the retrofit kit according to the invention has an additional computer 8 in addition to the catalytic converter 6 and the lambda probe 7 . This is connected on the one hand via a connecting line 9 to the lambda probe 7 and also to one or more connecting lines between a measuring probe relating to the aforementioned measured variables and the injection control 3 . In the illustrated embodiment, the additional computer is connected to the connecting line 10 between a temperature sensor 11 on the engine 1 and the injection control 3 .

The fuel injection quantity is heavily dependent on the engine temperature. At a lower engine temperature, the fuel-air mixture is enriched, while with an increasing operating temperature, the air content increases and the mixture becomes leaner. An air-fuel ratio of 14.6: 1 is particularly sought when using a catalyst. This corresponds to a lambda value equal to 1. With the help of the lambda probe, it can now be checked whether this optimal mixture composition is present.
The standard injection control 3 is now z. B. supplied via the temperature measurement line 10 from the additional computer ner 8 a superimposed correction signal. Since it can also vary the fuel injection system as a function of this signal, there is now the possibility of converting the measurement signal coming from the lambda probe 7 through the additional computer 8 and simulating a temperature measurement value which causes the injection control 3 , a correction of the injection quantity in the sense of a regulation to a lambda value 1.
The temperature sensor 11 on the motor 1 usually consists of a temperature-dependent resistor with a negative temperature coefficient. This means that the resistance of the temperature sensor decreases with increasing temperature. Be preferred is now provided that within the additional computer 8, a series-connected to the temperature sensor, changing cash resistance - for example a transistor - is provided. The resistance of the temperature measuring circuit can thus be increased. However, an increase in the measuring circuit resistance interprets the injection control 3 as a temperature reduction and would then enrich the air / fuel mixture, ie increase the fuel injection quantity. In practice, the regulation in the enrichment area is sufficient since the gasoline injection systems or their injection control are generally set to be lean, which would correspond to a lambda value greater than 1. However, since a lambda value of 1 is aimed for an optimal working of the catalytic converter, a (small) shift to a richer mixture is necessary in any case.
However, there is also the possibility that the temperature sensor resistance within the additional computer 8 a changeable resistor is connected in parallel and that a series-connected, further variable resistor is provided in parallel with this parallel connection. As a result, the resistance value of the temperature sensor can be changed to both smaller and larger values. As already mentioned, however, it has been shown in practical tests that a series connection of the temperature sensor resistor and a variable resistor is sufficient as an actuator for the simulation of the measured value change.

In addition to its control program, the additional computer also preferably includes an emergency program for generating approximately Lamb da 1 corresponding control signals in the event of failure and / or malfunction of the input measurement signals. Also due to the system, a series connection of the measuring probe resistance and the variable actuator resistance results in a further safety factor, since an uncontrolled lean-off from the engine cannot occur here. If a short circuit occurred in the changeable resistor connected in series, the result would be the same conditions as in the original, standard setting. If the resistance changed to higher values or there was an interruption, the mixture would simply be over-greased, but this would not cause any damage to the engine. Also can be restored in this case in the simplest way by simply plugging the connec tion line 10 to the original state. If necessary, a switch that can also be operated by a layperson could also be provided for this purpose.
As can be seen in the figure, the existing at the end of the connecting line 10 connector 12 is no longer connected directly to the temperature sensor 11 , but to the additional computer 8 , which in turn has a connector 12 a, which is connected to the temperature sensor 11 instead of the connector 12 is. This also makes it clear that no intervention in the existing system is required.

In order to meet even stricter exhaust gas standards, the tank and the gasoline injection system can be connected to one another via a line, within which a valve 14 is located. In certain operating situations of the engine, gasoline vapors can be added to the air-fuel mixture via this valve. A carbon active filter can also be used within the connecting line between the tank and the gasoline injection system to bind pollutants. The valve 14 is controlled by the additional computer 8 . The additional computer 8 is connected to measurement inputs 15 for the engine speed and a measurement input 16 for the operating temperature of the engine. The measuring inputs 15 are connected to the ignition coil 17 in the exemplary embodiment, while the measuring input 16 is connected to a further temperature sensor 18 , which is also connected to a temperature display 19 . From this measurement data, the operating state is recognized in which gasoline vapors can be fed to the engine. This is the case when the hydrocarbon content in the exhaust gases is low.

If the vehicle is provided with a thrust circuit 21 , the then existing throttle valve switch can be connected to the rate calculator 8 , in order to avoid malfunctions in overrun.
With 20 is still a connection for self-diagnosis of the additional computer 8 .
The retrofit kit can have in addition to the computer 8 a cable harness, each made up for the specific vehicle type, with corresponding plug connections. As a result, this retrofit kit can be installed in no time without special knowledge. Complicated interventions in the existing system can be avoided.
A major advantage of the system according to the invention is that the motor does not stop if the additional computer 8 fails and can therefore be continued.

It should also be mentioned that in jerk-sensitive engines, the lambda control only starts at 1400 to 1700 revolutions / min, because in these speed ranges, for. B. at lambda values of 0.98 to 0.99 only little nitrogen oxide is produced and hydrocarbon is still well oxidized.
For the sake of simplicity, it is advisable to manipulate only one measurement signal to readjust the mixture preparation. In principle, however, it is also possible to change several measurement data simultaneously and, if necessary, to different degrees.

All in the description, the claims and the drawing features shown can be both individually and in be any combination with each other be essential to the invention.

Claims (10)

1. Retrofit kit for retrofitting gasoline injection systems for Otto engines with a lambda probe have the regulated catalyst, the gasoline injection system having an injection control with a computer, which with measuring probes for the operating state of the engine, for. B. a temperature sensor, an intake manifold pressure sensor, an intake air temperature sensor and the same in control connection, characterized in that the retrofit kit has an additional computer ( 8 ) which to the lambda probe ( 7 ) and also to at least one connecting line ( 10 ) between a measuring probe and the injection control ( 3 ) is connected to change at least one measuring signal coming from a measuring probe in the sense of changing the mixture preparation and readjusting to an optimal air-fuel ratio within the lambda window. 2. Retrofit kit according to claim 1, characterized in that the additional computer ( 8 ) has a variable resistor connected in series with a sensor resistor, as an actuator for the simulation of the change in measured variables. 3. Retrofit kit according to claim 1 or 2, characterized in that the additional computer ( 8 ) has a parallel connected to the sensor resistor, variable resistor and a GE connected to this parallel connection in series, further, variable resistance as actuators for the simulation of the measured variable change. 4. Retrofit kit according to one of claims 1 to 3, characterized in that for changing the mixture preparation of the additional computer with an engine temperature sensor ( 11 ), preferably with the temperature sensor connected to a display instrument is connected. 5. retrofit kit according to one of claims 1 to 4, characterized in that for changing the mixture preparation of the additional computer ( 8 ) to the intake manifold pressure sensor and / or to a throttle valve potentiometer and / or to the intake air temperature sensor and / or connected to the idle CO potentiometer is. 6. Retrofit kit according to one of claims 1 to 5, characterized in that the additional computer ( 8 ) is connected via a control line to a valve ( 14 ) which is located in a connecting line between the tank and the gasoline injection system and that the additional computer ( 8 ) to control this valve measuring inputs ( 15 , 16 ) at least for the engine speed and the engine temperature. 7. retrofit kit according to claim 6, characterized in that it has a carbon active filter for supplying gasoline vapors from the tank to the engine in the connecting line having the valve ( 14 ). 8. retrofit kit according to one of claims 1 to 7, characterized in that the additional computer ( 8 ) has a measuring input for detecting the fuel cut-off and is preferably connected to a throttle valve switch. 9. retrofit kit according to one of claims 1 to 8, characterized in that it the additional computer ( 8 ) with a cable harness assembled for certain vehicle types, preferably with plug connections at least for the engine heat sensor ( 11 ), the heat sensor connector ( 12 ) of the injection -Control ( 3 ) and the lambda probe ( 7 ) and that optionally further connections, preferably plug-in connections for the ignition coil ( 17 ) or the like and for a further particular temperature sensor (18) are provided. 10. Retrofit kit according to one of claims 1 to 9, characterized in that the additional computer ( 8 ) contains in addition to its control program an emergency program for generating approximately lambda equal to 1 corresponding control signals in the event of failure and / or malfunction of the input measurement signals.