KR100325234B1 - Misfire generator and method for multi misfire cylinder system - Google Patents

Abstract

The present invention relates to a misfire generator and method for a multiple misfired cylinder system that enables detection of misfire in a cylinder of a complete engine with an artificial misfire generator.

The present invention provides a signal input unit for inputting an ignition signal, an injection signal, a crank pulse, a phase pulse, and a user's misfire cylinder designation signal from an engine controller; A control unit which determines injection and ignition misfire on a cylinder designated by a predetermined program with respect to the signal input from the signal input unit and outputs the determined signal; A signal output unit configured to output an ignition signal and an injection signal to a designated cylinder output from the controller; An encoder for inputting the number of misfire occurrences of a designated cylinder from the controller; And a display unit for displaying the misfire cylinder and the number of misfires specified by the user.

Description

Misfire generator and method for multiple misfired cylinder system {MISFIRE GENERATOR AND METHOD FOR MULTI MISFIRE CYLINDER SYSTEM}

The present invention relates to a misfire generator and method for a multiple misfired cylinder system, and more particularly, to a misfired generator and method for a multiple misfired cylinder system that enables detection of misfires in a cylinder of a complete engine by an artificial misfire generator. It is about.

In general, in the case of automobiles, when the engine is completed, the engine must meet the exhaust regulation item for the completed engine, so that the misfire state of the engine must be detected to satisfy the exhaust regulation item.

As described above, in detecting misfires of the finished engines, conventionally, devices corresponding to each type of engine are individually manufactured to check the misfires, and thus, it is difficult to commercialize the devices. I had.

As described above, although there is a conventional apparatus for detecting a misfire state of an engine and controlling misfire according to the detection, few apparatuses generate misfire in order to detect the misfire state of the engine. Therefore, it is only a partial device corresponding thereto.

Accordingly, an object of the present invention is to provide a misfire occurrence apparatus and method capable of checking misfire state of an engine by generating misfires for each completed engine regardless of its kind.

1 is a control block diagram of a misfire generator for a multi-misfired cylinder system of the present invention.

2 is a flowchart of a misfire generation method for a multiple misfired cylinder system of the present invention.

Figure 3 is an input and output waveform diagram of a misfire generator for a multiple misfired cylinder system of the present invention.

In order to achieve the above object, the present invention provides a signal input unit for inputting an ignition signal, an injection signal, a crank pulse and a phase pulse, and a misfired cylinder designation signal from the engine controller; A control unit which determines injection and ignition misfire on a cylinder designated by a predetermined program with respect to the signal input from the signal input unit and outputs the determined signal; A signal output unit configured to output an ignition signal and an injection signal to a designated cylinder output from the controller; An encoder for inputting the number of misfire occurrences of a designated cylinder from the controller; And a display unit for displaying the misfire cylinder and the number of misfires specified by the user.

Hereinafter, described in detail with reference to the accompanying drawings a preferred embodiment of the present invention.

1 is a control block diagram of a misfire generator for a multiple misfired cylinder system according to the present invention, wherein a switch input unit for designating a misfired cylinder to check misfire in a completed engine is shown in FIG.

10; An ignition input unit 11 which receives an ignition signal from an engine controller (not shown); An injection input unit 12 receiving a fuel injection signal from the engine controller; A crank and phase signal input unit (13) for receiving a crank pulse signal and a phase signal from the engine controller; A controller (14) which receives misfire cylinder designation signal input, ignition, injection, crank pulse signal, and phase signal from the input units and outputs a signal for misfire control to a cylinder designated by a predetermined program; An ignition output unit 15 which receives an input from the control unit 14 and outputs an ignition signal that is a misfire occurrence signal to a designated cylinder to an engine output unit; An injection output unit 16 which receives an input from the control unit 14 and outputs an injection signal that is a misfire occurrence signal to a designated cylinder to an engine output unit; An encoder (17) for inputting the number of misfire occurrences of the cylinder according to the output signal of the controller (14); The display section 18 which displays the misfired cylinder and the number of misfires specified by the user is comprised.

2 is a flowchart of a misfired generator for a multiple-fired cylinder system of the present invention, comprising: inputting a crank pulse and a phase pulse inputted from an engine controller in an initialization state (20); Determining (21) whether the crank pulse signal input in the step (20) applies the falling edge; Determining (22) if the crank pulse signal is a falling edge in the step (21) if the phase is high before top dead center; Counting cycles (23) if the phase in step (22) is a top dead center high signal; Calculating a cylinder number if the phase is not a top dead center high signal in step 22; Determining (25) whether the cycle counted in step (23) matches the misfire rate; Determining (26) if the misfire rate coincides with the number of cycles in the step (25); Outputting an ignition misfire occurrence signal to the engine if the ignition misfire in step 26 is performed; If it is not the ignition misfire at step 26, the injection misfire generation signal is output to the engine (28).

According to the present invention made as described above, when the misfire generator is mounted on the completed engine, and the misfire cylinder (No. 1 to No. 4) is designated from the switch input unit 10 of the misfire generator, the designated misfire cylinder is a control unit. It is inputted to (14).

In the state where the misfire cylinder designated by the control unit 14 is input, the crank and phase signal input unit 13 from the engine controller (not shown) and the crank pulse as shown in FIG. As shown in Fig. 2, long and short two pulses are respectively input (step 20).

Subsequently, the controller 14 determines whether the falling edge is applied to the crank signal pulse input to the crank and phase signal input unit 13 (step 21).

When the crank signal pulse is determined to be a falling edge, the control unit 14 determines whether the input phase pulse is high at the top-dead center (BTDC) point of the crank angle pulse signal, as shown in b of FIG. 3. (Step 22), if the phase pulse is high, the cycle is counted at the falling edge of each crank pulse (step 23); if the phase pulse is not high, the cylinder number at the falling edge of each crank pulse Will be counted (step 24).

Subsequently, the controller 14 determines whether the randomly set misfire rate coincides with the counted cycle (step 25). If the random misfire rate does not coincide with the counted misfire rate, the process is repeated. On the other hand, if the misfire rate coincides with the counted misfire rate, the control unit 14 determines whether the ignition misfire (step 26).

Therefore, if ignition misfire, the control unit 14 receives the ignition pulse input based on the crank signal and the phase signal when the misfire determination is performed on the ignition pulse as shown in FIG. 3C input to the ignition input unit 11. The ignition misfire signal as shown in FIG. Will be printed).

On the other hand, if the ignition misfire at step 26, the control unit 14 determines that the injection misfire and the control unit 14 is the injection pulse as shown in e of FIG. 3 input to the injection input unit 12 is 3, the injection pulse input based on the crank signal and the phase signal is combined with a control signal having three sections (TDC) before and after the cylinder (misfire in the high-speed range) as the misfire control section. The injection misfire signal as shown in f is output through the injection output unit 16 and output to the engine (not shown).

As described above, the present invention can easily detect misfire regardless of the type or model of the finished engine by installing a separate misfire generator for the misfire detection test in order to satisfy the exhaust regulation item for the finished engine when the vehicle engine is completed. Will be able to provide the effect.

Claims (4)

A signal input unit for inputting an ignition signal, an injection signal, a crank pulse and a phase pulse from the engine controller, and a user's misfire cylinder designation signal; A control unit which determines injection and ignition misfire on a cylinder designated by a predetermined program with respect to the signal input from the signal input unit and outputs the determined signal; A signal output unit configured to output an ignition signal and an injection signal to a designated cylinder output from the controller; An encoder for inputting the number of misfire occurrences of the designated cylinder; A misfire generator for a multiple misfired cylinder system, characterized by comprising a user-specified misfire cylinder and a display unit for displaying the number of misfires. Inputting a crank pulse and a phase pulse input from an engine control device in an initialization state; Determining whether the crank pulse signal input in the step is applying the falling edge; Determining whether the phase pulse is before top dead center if the crank pulse signal is a falling edge; Counting cycles if the phase is a top dead center high signal in this step; Calculating a cylinder number if the phase is not a top dead center high signal in the step; Determining whether the cycle counted in the step coincides with the misfire rate; Determining whether an ignition misfire occurs if the misfire rate coincides with the number of cycles in the step; Outputting an ignition misfire occurrence signal to the engine if the ignition misfire in the above step; If not the ignition misfire in the step, the misfire occurrence method for a multiple misfired cylinder system, characterized in that it comprises the step of outputting the injection misfire occurrence signal to the engine. The control signal of claim 2, wherein the ignition misfire occurrence signal includes a control signal including a ignition control interval based on a crank signal and a phase signal, and a two-stage (T2) front-back top dead center (TDC) of the corresponding cylinder; A misfire generation method for a multiple misfired cylinder system, characterized in that for output in combination. The injection misfire generation signal of claim 2, wherein the injection misfire generation signal is output by combining an injection pulse input based on the crank signal and the phase signal with a control signal having a front-back top dead center (TDC) 3 section of the corresponding cylinder as a misfire control section. Misfire generation method for a multiple misfired cylinder system characterized by the above-mentioned.