The present application is based on, and claims priority from, Korean Application Serial Number 10-2005-0080175, filed on Aug. 30, 2005, the disclosure of which is hereby incorporated by reference herein in its entirety.
The present invention relates to LPI (liquefied petroleum gas injection) engines and, more particularly, to a control circuit of an injector having a cut solenoid for an LPI engine, a control method of the cut solenoid and a diagnostic method thereof.
Generally, in an LPI engine, if fuel, which has been supplied to an injector, still remains in a fuel line even after the engine stops, there is a likelihood of leakage of the liquefied fuel, having a property of being easily evaporated, outside of the engine. Particularly, there is a high possibility of leakage of the fuel through the injector.
Therefore, to prevent fuel from leaking through the injector when the engine is not running, an injector 502 seen in
As shown in the drawing, the conventional injector 502 with the cut solenoid 500 includes an injector part 504 which is provided at an upper position and has the same structure as that of an injector of prior arts, and a cut solenoid part 506 which is provided at a lower position and has a valve mechanism to be operated by the cut solenoid 500. Only when power is applied to the cut solenoid 500 can fuel be injected from the injector part 504 into the engine through the cut solenoid part 506.
Embodiments of the present invention provide a control circuit for an injector having a cut solenoid for an LPI engine, a control method of the cut solenoid and a diagnostic method thereof.
A control circuit for injectors having cut solenoids for an LPI engine according to an embodiment of the present invention includes cut solenoids which are provided in the respective injectors. A power supply is connected to each of the cut solenoids. An electronic control unit controls the cut solenoids. Control lines connect the electronic control unit to the respective cut solenoids.
A method for controlling a cut solenoid of an injector for an LPI engine according to an embodiment of the present invention includes the step of determining whether a vehicle is in an ignition ON state, in which an ignition key is at an ON position or a START position. When the vehicle is in the ignition ON state, power is supplied to the cut solenoid provided in the injector, such that a cut solenoid part of the injector is opened. A malfunction of a cut solenoid related circuit is diagnosed through repeating a step of determining whether there is a malfunction of the cut solenoid related circuit, by comparing the ignition ON state with a power supply state of the cut solenoid until the vehicle enters an ignition OFF state from the ignition ON state, and a step of storing a diagnostic trouble code when there is a malfunction of the cut solenoid related circuit. The power of the cut solenoid is interrupted when the vehicle is in the ignition OFF state, such that the cut solenoid part of the injector is closed.
A method for diagnosing a cut solenoid of an injector of an LPI engine according to an embodiment of the present invention includes the step of determining whether a current, applied to the cut solenoid provided in the injector, flows in a phase equal to a phase of both an ignition ON state, in which an ignition key is at an ON position or a START position, and an ignition OFF state, in which the ignition key is at other positions. It is determined that a cut solenoid related circuit is in a normal state when the phases are equal to each other. It is determined that the cut solenoid related circuit is in a malfunctioning state when the phases are different from each other.
For a better understanding of the nature and objects of the present invention, reference should be made to the following detailed description with the accompanying drawings, in which:
Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.
Referring to
As shown in
In other words, the electronic control unit 1 controls both the injector parts 504 and the cut solenoid parts 506 of the injectors 502.
The power supply, which is connected in common to the cut solenoids 500, feeds power to the cut solenoids 500 through a fuel pump relay 508 provided to feed power to a fuel pump. Furthermore, this embodiment is constructed such that solenoids 510 of the injector parts 504 as well as the cut solenoids 500 are supplied with power through the fuel pump relay 508.
For reference, in
Meanwhile, as shown in
The operation of the electronic control unit 1 for driving the cut solenoid 500 is as follows, with reference to
In this state, a valve constituting the cut solenoid part 506 is opened by magnetization of the cut solenoid 500, so that fuel transferred from the injector part 504 can be supplied at any time into the engine.
In the right view of
Then, the cut solenoid 500 is demagnetized, so that the valve constituting the cut solenoid part 506 is closed. In this state, fuel cannot be supplied from the injector part 504 into the engine.
Hereinafter, a method for controlling a cut solenoid 500 of an injector 502 of the LPI engine according to the present invention will be described herein below with reference to
As shown in
In this embodiment, the cut solenoid control method further includes the step of turning on a main relay and a fuel pump relay 508 between the step of determining whether the vehicle is in the ignition ON state and the step of supplying the power to the cut solenoid 500.
Furthermore, the cut solenoid control method further includes the step of turning off the main relay and the fuel pump relay 508 between the diagnosing step of detecting a malfunction until the vehicle enters the ignition OFF state and the step of interrupting the power of the cut solenoid 500.
The electronic control unit 1 takes the case, in which a driver rotates the ignition key at the START position or maintains it at the ON position, as the ignition ON state, and takes the case, in which the ignition key is at other positions, as the ignition OFF state.
When a first ignition ON state occurs, another separate electronic control unit (not shown), which performs overall control of the engine along with the electronic control unit 1, sets the main relay, which supplies power to various electronic elements related to the engine, and the fuel pump relay 508, which supplies power the fuel pump to drive the fuel pump, to ON states.
Thereafter, the electronic control unit 1 applies a base current to the transistor 512 to supply power to the cut solenoid 500 of the injector, thus grounding the cut solenoid such that current flows through the cut solenoid 500.
In this state, the cut solenoid part 506 allows fuel to be supplied at any time into the engine from the injector part 504, and this state is maintained during the operational state of the engine.
While maintaining the above-mentioned state, the electronic control unit 1 repeatedly performs the diagnosing step until the vehicle enter the ignition OFF state, thus diagnosing a malfunction and disconnection of the circuit related to the cut solenoid part 506.
The diagnostic method will be explained in detail later herein.
When the ignition OFF state occurs, the separate electronic control unit, which governs the overall control of the engine, turns off the main relay and the fuel pump relay 508. Subsequently, the electronic control unit I interrupts the supply of the base current to the transistor 512 to interrupt the supply of the current to the cut solenoid 500, thus preventing fuel from leaking through the injector 502.
The method for diagnosing a cut solenoid 500 of an injector 502 of the LPI engine will be explained herein below with reference to
The diagnostic method includes the step of determining whether current, applied to the cut solenoid 500 provided in the injector 502, flows in a phase equal to a phase of both the ignition ON state, in which the ignition key is at the ON position or the START position, and the ignition OFF state, in which the ignition key is at other positions. When the phases are equal to each other, it is determined that a cut solenoid related circuit is in a normal state. When the phases are different from each other, it is determined that the cut solenoid related circuit is in a malfunctioning state.
The diagnostic circuit 516 of the electronic control unit 1 determines the flow state of current applied to the cut solenoid 500 by detecting whether current flows through a control line 3 which electrically connects the cut solenoid 500 to the transistor 512.
The diagnostic circuit 516 simultaneously detects the ignition ON state and the ignition OFF state and determines whether the flow state of the current applied to the cut solenoid 500 varies to correspond to variation between the ignition ON state and the ignition OFF state.
In detail, as shown in the left view of
The center view of
If this state is detected, the electronic control unit 1 stores a desired diagnostic trouble code, as described above, thus providing information about the malfunction when vehicle maintenance is performed.
Of course, in this case, the injector 502 cannot perform fuel injection normally.
The right view of
This is the case in which a section A-B in a circuit diagram of
As is apparent from the foregoing, the present invention provides a control circuit for an injector having a cut solenoid for an LPI engine, a control method of the cut solenoid and a diagnostic method thereof, so that fuel is effectively prevented from leaking through an injector to the atmosphere when the LPI engine stops, thus preventing air pollution, and meeting a variety of relevant regulations.
Number | Date | Country | Kind |
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10-2005-0080175 | Aug 2005 | KR | national |