KR19980049824A - How to calculate basic ignition timing at start-up - Google Patents

Abstract

The present invention relates to a method for calculating a basic ignition timing at start-up, the method comprising the steps of: reading data on cooling water temperature and engine speed and intake temperature data from each sensor from a map; The electronic control device comprises the steps of determining and returning the ignition timing as a comprehensive value obtained using the interpolation of the data; The ignition timing is optimized by taking the correction margin of the basic ambient environment into consideration with the factors related to cooling water temperature and intake air temperature and the transient correction margin due to fluctuations in engine speed, thereby preventing knock occurrence and improving the exhaust gas and startability. Provides a method of calculating the basic ignition timing at startup.

Description

How to calculate the basic ignition timing at start-up

The present invention relates to the calculation of the basic ignition timing at start-up. More specifically, the electronic control device produced by each manufacturer controls all the variables that greatly affect the operability or the exhaust gas by controlling the ignition timing as a specific constant or a specific variable. The present invention relates to a method for calculating a basic ignition timing at start-up, which results in an improvement in operability and exhaust gas.

In recent years, many automobiles rely on electronic control so that the performance of the vehicle depends on the electronic control method.

In particular, environmental awareness is getting higher and cars are becoming a part of the living environment.

As a result, electronic controls that do not take into consideration the ride quality or driving ability of a car are losing value.

Most recently, the vehicle has been controlled as a specific constant or a specific variable factor that greatly depends on the driving performance in the electronic control apparatus in the vehicle in consideration of the riding comfort, the driving characteristics, and the environment due to the exhaust gas.

That is, the determination of the ignition timing having a great influence on the operability and the exhaust gas has been controlled to the specific value as described above.

As an example, the basic ignition timing at start-up is determined using an appropriate value, or as another example, the ignition timing is determined by calculating a function relating to the cooling water temperature at start-up.

However, when the ignition timing is determined by a specific constant as described above, the conventional technique is poor in starting and emission matching by controlling the engine to the same value even in a cooling state or an overheating state. Therefore, differentiating the ignition timing has a problem that can not exclude the possibility of knock occurs due to the intake of high temperature intake air at the start in hot areas.

Accordingly, an object of the present invention is to solve the above-mentioned problems, by providing a correction margin for the basic ambient environment, taking into account both the factors related to the cooling water temperature and the intake air temperature and the transient correction margin according to the engine speed variation. It is to provide a basic ignition timing control method at start-up to solve the above problems.

As a means for achieving the above object, the feature comprises the steps of: reading data on the cooling water temperature and data on the engine speed and intake temperature from the respective sensors into a map; The electronic control device includes a step of determining and returning an ignition timing as a comprehensive value obtained by using the interpolation method of the data.

1 is a block diagram related to general ignition timing control,

2 is an ignition timing control flowchart considering cooling water temperature, air temperature, and engine rotation speed according to an embodiment of the present invention;

3 is a characteristic diagram relating to cooling water temperature, air temperature, and ignition timing according to an embodiment of the present invention;

4 is a characteristic diagram regarding an engine speed and an ignition timing according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The most preferred embodiments in which those skilled in the art can easily implement the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the block diagram related to general ignition timing control includes: a coolant temperature sensor 10 that checks and outputs a temperature of coolant that maintains engine heat; An intake air temperature sensor 20 for detecting a temperature of intake air; A crank angle sensor 30 for detecting the rotation speed of the engine; An electronic control device (40) for receiving and processing detection signals from the sensors and outputting control signals; A plug 50 for receiving a control signal from the electronic control device 40 and discharging it; It consists of an engine 60 that generates power by burning an internal mixer by spark discharge of the plug 50.

The ignition timing control according to the embodiment of the present invention will be described with reference to FIG. 2 as the configuration shown in FIG.

The electronic control device 40 receives data on the cooling water temperature from the cooling water temperature sensor 10, receives data on the engine speed from the crank angle sensor 30, and intake temperature from the intake air temperature sensor 20. The data about is read from the map (S20).

The electronic controller 40 determines the ignition timing as a comprehensive value by using the interpolation method of the data. The value using the water temperature data or the intake air temperature data is defined as SPKCRK1M, and the value obtained by the engine speed is defined as SPKCRK2L. Therefore, when the value obtained by combining the two data by interpolation is set to SB, the calculation of the ignition timing SB is as follows.

SB = SPKCR1M + SPKCRK2L

Therefore, when the ignition timing data obtained by the above equation is output to the plug 50, the plug 50 burns fuel of the engine by spark discharge to obtain power.

As described above, in the embodiment of the present invention, by preventing the occurrence of knocks by optimizing the ignition timing in consideration of the factors related to the cooling water temperature and intake air temperature and the transient compensation margin according to the engine rotational fluctuation with the correction margin for the basic ambient environment. And a basic ignition timing calculation method at start-up which has an effect of improving exhaust gas and startability.

Claims (1)

Reading data about cooling water temperature and engine speed and intake air temperature from each sensor from the maps; And a step of determining and returning the ignition timing as a comprehensive value obtained by interpolating the data.