The fuel-air mixture formed in the intake tract requires a certain period of time until is reaches the oxygen sensor in the form of exhaust gas. This time decreases as load and engine speed increase. For this reason, the response time of the emission (lambda) control system is also dependent on load and engine speed. Fuel-air mixture deviations detected by the oxygen sensor result in adaptation values (learned correction values) being stored. By way of the adaptations, the injection can be brought close to the nominal value in advance. A reduction in the response time is achieved in this way.
For instance, if the basic injection values of the DME characteristic map are too low during idling or in order to maintain the ideal fuel-air mixture, the emission (lambda) control system would have to constantly increase the injection timing. In this case, an adaptation value is learnt which corrects the basic injection value. The emission (lambda) control then only needs to undertake the fine adjustment.
Following adaptations are performed during engine operation:
When the tank ventilation valve is open, an additional combustible mixture is supplied from the carbon canister to the engine. The shift in mixture detected by the oxygen sensor is completely corrected out by means of the tank ventilation adaptation value.
The idle speed air adaptation is adopted from the idle speed actuator or from the electric throttle valve actuator. On the basis of the air volume it ensures a constant idle speed.
If idling is detected on the basis of the throttle position during the rest phase of the tank ventilation system, idle mixture adaptation takes place at certain intervals for each cylinder bank respectively. This variable is referred to as additive mixture adaptation.
Also in the partial load range, mixture adaptation takes place at certain intervals. The determined adaptation value is taken into consideration in all partial load ranges and separately for each cylinder bank. This variable is also referred to as multiplicative mixture adaptation.
Misfiring causes irregularities in the rotational speed of the crankshaft. These irregularities can be detected by way if changes in the segment time.
Segment times (time, in which a certain number of teeth on the increment wheel move past the sensor) are constantly determined via the crankshaft sensor. These segment times are constantly checked during engine operation. In the event of fault, a fault code is stored and fuel injection of the corresponding cylinder deactivated. Refer to misfiring detection.
In order to avoid incorrect detection, sensor wheel adaptation must be carried out after replacing a DME control module or increment wheel. Sensor wheel adaptation must first be deleted if only the increment wheel is to be replaced (disconnect control module from voltage supply for 5 minutes).
The sensor wheel adaptation determines the individual irregularity of the increment wheel and takes it into consideration when evaluating the segment times. Sensor wheel adaptation is implemented automatically as soon as the engine is operated in overrun condition for at least 10 seconds.