KR19980055802A - Air fuel ratio correction method in all cities - Google Patents

Abstract

The present invention checks the amount of air sucked in the air-fuel ratio control during acceleration driving for a predetermined time and detects the deviation between the correction mapping value and the initial mapping value according to the average value of the integrated amount of these changes, and then if the deviation is greater than the preset value, The mapping value can be corrected as much as the rate of change of the mapping value to the initial mapping value, and the appropriate air-fuel ratio correction according to the load increase rate can further reduce emissions of hydrocarbons, which are unburned gas, so that the emission can be improved. An air-fuel ratio correction method, in order to achieve the above object, the present invention comprises the steps of determining whether the engine speed (NE) rises when the engine load (TL) while driving (S1); Detecting an initial load value TL1 when the engine speed NE rises (S2); Checking and integrating the load change value for a predetermined time (S3); Detecting an average value TL2 of the load integrated in the step (S4); Determining whether the deviation between the average value TL2 and the initial load value TL1 detected in the step is greater than the predetermined load value δ (S5); In the above step, when the load value is greater than the preset load value δ, the initial load value TL1 is adjusted by the load variation rate to control mapping (S6), and when the load value is smaller than the preset load value δ, it is mapped by the initial load value TL1. It is characterized in that the control to be performed as a step (S7).

Description

Air fuel ratio correction method in all cities

The present invention relates to an air-fuel ratio correction method under all loads such that emissions of hydrocarbons, which are harmful exhaust gases, are reduced during acceleration driving.

Engine control is carried out by various signals when the vehicle is running. Currently, the electronic control unit (hereinafter abbreviated as ECU) is optimal according to the engine operating condition by checking signals such as intake air volume and engine coolant temperature. The engine is driven by the combustion power of.

It is the most important in the engine control that the air-fuel ratio, which is a mixture ratio of air and fuel, to be directly controlled according to the driving state of the vehicle, which directly affects the output when driving the engine.

On the other hand, when the engine speed increases as the load increases during the above control, the ECU determines that this is a full load state, and the air-fuel ratio is increased by about 10% of the fuel than the existing mapping value, and is set and controlled richly. In order to increase the acceleration.

However, the engine generates a large amount of harmful exhaust gas according to the increase in fuel during the acceleration driving as described above. As the increase in fuel causes a shortage of air compared to fuel, harmful exhaust gases such as carbon monoxide (CO) and hydrocarbons (HC) are generated. It will be discharged in large quantities.

The double hydrocarbon (HC) is a cause of generating photochemical smog, especially with nitrogen oxides (NOX), which has a problem that worsens the air pollution.

Accordingly, the present invention has been made in view of the above-described problems, and the present invention is to check the amount of air sucked in the air-fuel ratio control during acceleration driving for a predetermined time, and between the corrected mapping value and the initial mapping value according to the average value integrating these changes. If the deviation is checked after the deviation is larger than the preset value, the initial mapping value can be corrected by the rate of change of the correction mapping value to the initial mapping value. The emission of phosphorus hydrocarbons can be further reduced so that the emission can be improved.

In order to achieve the above object, the present invention includes the steps of determining whether the engine speed increases when the engine load rises while driving; Detecting an initial load value when the engine speed is increased; Checking and integrating the load change value for a predetermined time; Detecting an average value of the load integrated in the step; Determining whether a deviation between the average value detected in the step and the initial load value is greater than a preset load value; In this step, when the load value is greater than the preset load value, the initial load value is adjusted by the load variation rate, and the mapping control is performed. When the load value is smaller than the preset load value, the mapping control is performed by the initial load value.

1 is a relationship diagram between load and engine speed during driving;

2 is a control flowchart according to the present invention.

This will be described below in more detail with reference to the accompanying drawings.

1 illustrates a relationship between a load and an engine speed according to the present invention. The present invention relates to a fuel correction method in a section in which an engine speed is increased while a load is increased.

That is, as shown in FIG. 2, when the engine speed increases as the load increases while the vehicle is driving (S1), the ECU determines that the vehicle is at full load.

At this time, the ECU detects the initial load value TL1 (S2) and checks the load variation value for a predetermined time ΔT again and integrates it (S3).

Thus, the average value TL2 of the integrated load is detected (S4), and the deviation from the initial load value TL1 is calculated, and the comparison is judged whether the deviation is larger than the preset value δ input to the ECU (S5). .

If it is determined in step S5 that the deviation is larger than the preset value δ input to the ECU, the load value is calculated as the initial load value TL1 * initial load value TL1 / average value TL2 and the mapping value is calculated. The fuel injection amount is controlled according to (S6), and if it is determined that the deviation is smaller than the preset value (δ) input to the ECU, the fuel injection amount is controlled immediately by the initial load value TL1 (S7).

Under the control as described above, when the driving state during the driving is determined to be full load, the fuel is supplied unconditionally by increasing the initial load value by about 10%. When the load value is small, the load value is large. By increasing the amount of fuel in more time, the air-fuel ratio control can be performed more precisely and efficiently.

Therefore, according to the present invention, the fuel supply can be increased more efficiently when operating at full load, thereby preventing unnecessary consumption of fuel and at the same time reducing the amount of unburned exhaust gas generated by increasing the amount of fuel relative to the amount of air. This will provide a very useful effect that will contribute greatly to the economical fuel economy, the satisfaction of international emission regulations and the prevention of air pollution.

Claims (1)

Determining whether the engine speed NE rises when the engine load TL rises while driving (S1); Detecting an initial load value TL1 when the engine speed NE rises (S2); Checking and integrating the load change value for a predetermined time (S3); Detecting an average value TL2 of the load integrated in the step (S4); Determining whether the deviation between the average value TL2 and the initial load value TL1 detected in the step is greater than the predetermined load value δ (S5); In the above step, when the load value is greater than the preset load value δ, the initial load value TL1 is adjusted by the load variation rate to control mapping (S6). To control (S7); Air-fuel ratio correction method characterized in that to be performed as.