KR20110072874A - Apparatus for detecting fail of a solenoid valve driver - Google Patents

Abstract

PURPOSE: A breakdown detecting circuit of a driving part of a solenoid valve is provided to prevent a malfunction of a fail safe by determining abnormality of a valve power supply FET(Field Effect Transistor) and a solenoid valve drive FET. CONSTITUTION: The first resistor(R3) detects a voltage of a drain of a solenoid valve power supply FET. The second resistor(R2) detects a voltage of a source of the solenoid valve electric power supply FET. The first comparator(21) compares the voltage of the source with that of the drain of the solenoid valve electric power supply FET. The second comparator(22) compares the voltage of the source of the solenoid valve electric power supply FET with the reference voltage. A micro control unit decides fails of the solenoid valve drive FET and the solenoid valve electric power supply FET.

Description

Failure detection circuit of solenoid valve driving unit {apparatus for detecting fail of a solenoid valve driver}

The present invention relates to a failure detection circuit of a solenoid valve driving unit, and more particularly, to a solenoid valve used in an anti-lock brake system (ABS) or an electronic stability program (ESP). A circuit for detecting a failure of the drive unit.

Recently, various vehicles are installed to improve driving stability and braking stability. As such various devices, an anti-lock brake system (ABS) for preventing wheel slip during brake operation of a vehicle and a collision control system (TCS: Traction for preventing wheel slip during start or acceleration of the vehicle) Control System (ESP) and Electronic Stability Program (ESP) to stabilize the vehicle by integrating ABS and TCS systems.

The system such as ABS, TCS, ESP is provided with a solenoid valve, the general solenoid valve driving unit is shown in FIG.

1 is a configuration diagram of a general solenoid valve driving unit.

The solenoid valve driving unit includes a charge pump IC 11, a solenoid valve power supply FET 12, a solenoid coil 13, a solenoid valve driving FET 14, and a reverse voltage prevention diode 15. .

When the solenoid valve drive FET 14 is turned off, the source voltage of the solenoid valve power supply FET 12 is at a low level because the storage voltage of the solenoid coil 13 is discharged.

On the other hand, when the solenoid valve driving FET 14 is turned on, the drain and source stages, the solenoid coil 13 and the solenoid valve driving FET of the reverse voltage prevention diode 15 and the solenoid valve power supply FET 12 are turned on. Current flows through the drain and source stages of (14), and current is accumulated in the solenoid coil 13. As a result, the source end of the solenoid valve power supply FET 12 is at a high level.

Conventionally, in order to determine whether the solenoid valve power supply FET 12 is normal, the micro control unit (MCU) monitors the source terminal of the solenoid valve power supply FET 12. The source stage of the solenoid valve power supply FET 12 goes low when the solenoid valve drive FET 14 is turned off, and the source of the solenoid valve power supply FET 12 when the solenoid valve drive FET 12 is turned on. When the stage is at the high level, it is determined that the solenoid valve power supply FET 12 is in a normal state.

However, when the solenoid valve driving FET 14 is turned on or turned off, it is determined that the solenoid valve power supply FET 12 is in an abnormal state when the solenoid valve driving FET 14 does not operate as described above to drive a failsafe.

However, since the solenoid coil has a resistance value depending on the temperature, the current value flowing in the circuit under the same voltage varies according to the temperature, which causes the solenoid valve driving FET 14 to be out of the normal voltage range when turned on or turned off. There is a case. Although the solenoid valve power supply FET is in a normal state, there is a problem in that the microcontrol unit is misleading to drive a failsafe.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a circuit for determining whether the solenoid valve power supply FET and the solenoid valve driving FET is normal.

Another object of the present invention is to provide a circuit for accurately determining whether the solenoid valve power supply FET and the solenoid valve driving FET are normal even if the resistance value of the solenoid coil is changed.

The failure detection circuit of the solenoid valve driving unit according to the present invention for achieving the above object includes a first resistor for detecting the drain terminal voltage of the solenoid valve power supply FET;

A second resistor for detecting a source terminal voltage of the solenoid valve power supply FET;

A first comparator for comparing the drain terminal voltage of the solenoid valve power supply FET with the source terminal voltage of the solenoid valve power supply FET;

A second comparator for comparing a source terminal voltage and a reference voltage of the solenoid valve power supply FET;

When the solenoid valve power supply FET and the solenoid valve driving FET are turned on or off, respectively, an output value of the first comparator and an output value of the second comparator are input to receive the solenoid valve power supply FET and the solenoid valve driving FET. Characterized in that it comprises a micro control unit for determining whether or not a failure.

As described above, according to the present invention, the solenoid valve power supply FET and the solenoid valve driving FET of the solenoid valve driving unit used in a system such as ABS, TCS, ESP, etc. of the vehicle can be accurately detected.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment according to the present invention.

2 is a block diagram illustrating a failure detection circuit of a solenoid valve driving unit according to an exemplary embodiment of the present invention.

The fault detection circuit of the solenoid valve driving unit according to the present invention includes a resistor R3 for detecting the drain stage voltage of the solenoid valve power supply FET 12 and a source terminal voltage of the solenoid valve power supply FET 12. The first comparator 21 for comparing the resistance (R2), the drain terminal voltage of the solenoid valve power supply FET and the source terminal voltage of the solenoid valve power supply FET, and the source terminal voltage and the reference voltage of the solenoid valve power supply FET. The output value of the first comparator 21 and the second comparator 22 when the second comparator 22 to be compared, the solenoid valve power supply FET 12 and the solenoid valve drive FET 14 are turned on or turned off, respectively. And a micro control unit 23 for determining whether the solenoid valve power supply FET 12 and the solenoid valve driving FET 14 are broken by using the output value of.

In addition, the failure detection circuit of the solenoid valve driving unit according to the present invention further includes a resistor R1 having one end connected to the driving voltage VCC and the other end connected to the source terminal of the solenoid valve power supply FET 12. The driving voltage VCC is divided by the resistance value of the resistor R1 and the solenoid coil, and the divided voltage is provided to the micro control unit 23.

The micro control unit 23 obtains the resistance value of the solenoid coil according to the divided voltage, and applies the control value according to the resistance value of the solenoid coil to enable precise control. Here, the micro control unit 23 changes the duty ratio of the switching signals of the solenoid valve power supply FET 12 and the solenoid valve driving FET 14 according to the resistance value of the solenoid coil to uniformly match the current flowing in the solenoid valve driving unit. Can be.

The micro control unit 23 turns the solenoid valve power supply FET 12 and the solenoid valve driving FET 14 on or off, respectively, and receives the output values of the first comparator 21 and the second comparator 22 therefrom. It is determined whether the solenoid valve power supply FET 12 and the solenoid valve driving FET 14 have failed.

Table 1 shows the failure determination table according to the output values of the two comparators for each turn-on / turn-off state of each FET.

Power Supply FET Drive FET First comparator Second comparator Judgment Turn-on Turn off Hi low Power Supply FET Normal Turn-on Turn off low low Power supply FET open Turn-on Turn-on Hi low Power Supply FETs & Drive FETs Turn-on Turn-on low low Power supply FET open Turn-on Turn-on Hi Hi Power Supply FET Short Turn off Turn-on low Hi Drive FET Normal Turn off Turn-on Hi low Power Supply FET Short Turn off Turn off low Hi Power Supply FET Normal Turn off Turn off Hi Hi Power Supply FET Short

For example, when the solenoid valve power supply FET 12 is turned on and the solenoid valve drive FET 14 is turned off, the solenoid valve is driven by the internal resistance of the solenoid valve power supply FET 12 when the solenoid valve drive unit is normal. The drain terminal voltage of the power supply FET 12 is higher than the source terminal voltage. In this case, the first comparator 21 outputs a high level and the second comparator 22 outputs a low level.

However, when the solenoid valve power supply FET 12 is open, when the solenoid valve power supply FET 12 is turned on and the solenoid valve drive FET 14 is turned off, the drain of the solenoid valve power supply FET 12 is turned off. However, as the voltage decreases, both the first comparator 21 and the second comparator 22 output a low level.

Accordingly, the microcontrol unit 23 has the output signal of the first comparator 21 being high level and the second comparator with the solenoid valve power supply FET 12 turned on and the solenoid valve drive FET 14 turned off. If the output signal of (22) is at a low level, it is determined that the solenoid valve power supply FET 12 is in a normal state. If both the output signals of the first comparator 21 and the second comparator 22 are at a low level, the solenoid valve power supply is determined. It is determined that the supply FET 12 is in a faulty (open) state.

Similarly, when both the solenoid valve power supply FET 12 and the solenoid valve driving FET 14 are turned on, the output signal of the first comparator 21 is at a high level and the output signal of the second comparator 22 is at a low level. The solenoid valve power supply FET 12 and the solenoid valve drive FET 14 are determined to be in a normal state. However, if the output signals of the first comparator 21 and the second comparator 22 are both at a low level, it is determined that the solenoid valve power supply FET 12 is in a faulty (open) state. If the output signals of the two comparators 22 are all at a high level, it is determined that the solenoid valve power supply FET 12 is in a fault (short) state.

In addition, when the solenoid valve power supply FET 12 is turned off and the solenoid valve driving FET 14 is turned on, the output signal of the first comparator 21 is at a low level and the output signal of the second comparator 22 is If the level is high, the solenoid valve driving FET 14 is determined to be in a steady state. However, if the output signal of the first comparator 21 is at a high level and the output signal of the second comparator 22 is at a low level, it is determined that the solenoid valve power supply FET 12 is in a fault (short) state.

In addition, when both the solenoid valve power supply FET 12 and the solenoid valve driving FET 14 are turned off, the output signal of the first comparator 21 is at a low level and the output signal of the second comparator 22 is at a high level. At the level, it is determined that the solenoid valve power supply FET 12 is in a normal state. However, if the output signals of the first comparator 21 and the second comparator 22 are both at a high level, it is determined that the solenoid valve power supply FET 12 is in a fault (short) state.

When the solenoid valve power supply FET 12 and the solenoid valve drive FET 14 are determined to be in a fault state, the micro control unit 23 indicates that a failure has occurred in the system while the power supplied to the solenoid valve is cut off and failsafe. ) And inform the outside so that the driver can get proper maintenance for the vehicle.

1 is a configuration diagram of a typical solenoid valve driving unit,

2 is a block diagram illustrating a failure detection circuit of a solenoid valve driving unit according to an exemplary embodiment of the present invention.

   <Explanation of symbols for the main parts of the drawings>

21: first comparator 22: second comparator

23: micro control unit

Claims (3)

A first resistor for detecting the drain terminal voltage of the solenoid valve power supply FET; A second resistor for detecting a source terminal voltage of the solenoid valve power supply FET; A first comparator for comparing the drain terminal voltage of the solenoid valve power supply FET with the source terminal voltage of the solenoid valve power supply FET; A second comparator for comparing a source terminal voltage and a reference voltage of the solenoid valve power supply FET; When the solenoid valve power supply FET and the solenoid valve driving FET are turned on or off, respectively, an output value of the first comparator and an output value of the second comparator are input to receive the solenoid valve power supply FET and the solenoid valve driving FET. A failure detection circuit for a solenoid valve driving unit comprising a micro control unit for determining a failure. The driving circuit of claim 1, further comprising a third resistor connected at one end to a driving voltage VCC and at the other end connected to a source terminal of the solenoid valve power supply FET. And a voltage divided by the resistance value of the solenoid coil is provided to the micro control unit. The control switch signal of claim 2, wherein the micro control unit obtains a resistance value of the solenoid coil according to the divided voltage, and controls the solenoid valve power supply FET and the solenoid valve driving FET according to the resistance value of the solenoid coil. The fault detection circuit of the solenoid valve driving unit characterized in that it changes the duty ratio of.

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