JP2019073167A - Power supply control device - Google Patents

Abstract

To provide a power supply control device capable of preventing overdischarge of a battery when an abnormality occurs in a control device with a simple configuration and at a low cost.SOLUTION: A power supply control device includes: a power supply section S1 which supplies power to a control device MCU in a state in which an ignition switch IGN is turned on or a hold signal is input from the control device MCU; and a delay circuit DC which outputs a signal for a prescribed time even if the ignition switch IGN is turned off. When the ignition switch IGN is turned off and the signal from the delay circuit DC is cut off, the power supply section S1 is configured to cut off power supply to the control device MCU.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power control device.

  The vehicle is equipped with a microcontroller to control the engine and damping force variable shock absorber, and such microcontroller is activated when the ignition switch is turned on to control the controlled object. .

  The power supply to the microcontroller is controlled by the power supply controller, and the power supply controller supplies power to the microcontroller when the ignition switch is turned on, and supplies power to the microcontroller when the ignition switch is turned off. cut off.

  The microcontroller can not end the process normally if the power supply is suddenly cut off by turning off the ignition switch during the control process. Therefore, the power control unit is configured to maintain the power supply to the microcontroller until the control termination signal is input from the microcontroller to notify that the processing is normally terminated.

  However, if the microcontroller can not output the control end signal to the power control unit for some reason, the power control unit continues to supply power to the microcontroller even if the ignition switch is turned off, resulting in excessive discharge of the on-vehicle battery. May be degraded.

  Therefore, in the conventional power supply control device, the relay control circuit for controlling the relay provided on the supply line for supplying power to the microcontroller, the drive circuit for driving the relay control circuit, and the time when the ignition switch is turned off are counted. And a signal control circuit that receives a signal from the microcontroller and the counting unit and outputs a control signal to the drive circuit (see, for example, Patent Document 1).

  In the conventional power supply control device configured as described above, when the ignition switch is turned off, the time counted by the counting unit is predetermined even if the microcontroller has an abnormality and the control end signal is not output to the signal control device. When the time is reached, the output of the signal controller is switched to a low signal to turn off the relay or to stop the operation of the voltage generation circuit.

JP, 2014-172597, A

  As described above, in the conventional power supply control device, even if an abnormality occurs in the microcontroller, the power supply to the microcontroller can be stopped to prevent over-discharge and deterioration of the on-vehicle battery.

  However, the conventional power supply control device is complicated and expensive because it requires a configuration such as a counting unit, a signal control circuit that processes signals from the microcontroller and the counting unit, and a driving circuit.

  Therefore, an object of the present invention is to provide a power supply control device capable of preventing overdischarge of a battery when there is an abnormality in the control device at a simple and low cost.

  In order to achieve the above object, according to the power supply control device of the present invention, the power supply unit for supplying power to the control device with the ignition switch on or the input of the hold signal from the control device is turned off. The power supply unit is configured to cut off the power supply to the control device when the ignition switch is turned off and the signal from the delay circuit is cut off.

  The power supply control device configured in this way supplies power to the control device after a predetermined time has elapsed even if the control device continues to output the hold signal even though the ignition switch is turned off. Can be forced to end.

  In the power supply control device, a voltage change circuit in which the power supply unit transforms the voltage of the battery with the input of a signal from the battery, the ignition switch or the delay circuit, and outputs the voltage to the control device; And a main switch which is closed when the ignition switch is on or the hold signal from the control device is present, and a delay circuit may be provided between the ignition switch and the voltage change circuit. Thus, when the power supply control device is configured, power supply to the control device can be forcibly terminated using the voltage change circuit only by installing the delay circuit. Therefore, the configuration of the power supply control device is very simple, and the cost can be reduced more effectively.

  Furthermore, the power supply control device is provided between the battery and the voltage change circuit that converts the battery voltage and outputs the voltage to the control device, and the battery and the voltage change circuit. And a sub switch provided between the battery and the control device and closed by the input of the signal from the ignition switch or the delay circuit, and the delay circuit is an ignition switch And the sub switch may be provided. When the power supply control device is configured as described above, the power supply to the control device can be forcibly terminated only by the installation of the delay circuit and the sub switch. Therefore, the configuration of the power supply control device is very simple, and the cost can be reduced more effectively.

  According to the power supply control device of the present invention, it is possible to prevent overdischarge of the battery when there is an abnormality in the control device at a simple and low cost.

It is a circuit block diagram of the power supply control apparatus in 1st embodiment. It is a circuit block diagram of the power supply control apparatus in 2nd embodiment.

  Hereinafter, the present invention will be described based on the embodiments shown in the drawings. In order to avoid duplication of explanation, the same reference numerals are assigned to configurations common to the power supply control device C1 in the first embodiment described below and the power supply control device C2 in the second embodiment. About the structure demonstrated by the power supply control apparatus C1 of 1st embodiment, detailed description is abbreviate | omitted by description in the power supply control apparatus C2 of 2nd embodiment.

First Embodiment
As shown in FIG. 1, the power supply control device C1 turns on the ignition switch IGN or the power supply unit S1 that supplies power to the microcontroller MCU when there is an input of a hold signal from the microcontroller MCU as a control device, and an ignition Even when the switch IGN is turned off, a delay circuit DC which outputs a signal for a predetermined time is provided.

  Hereinafter, each part of the power supply control device C1 of this example will be described in detail. The power supply unit S1 includes a battery Bat, a voltage change circuit 2, and a main switch MS. The battery Bat and the microcontroller MCU are connected by the power supply line PL, and in the middle of the power supply line PL, the main switch MS and the voltage change circuit 2 are provided in order from the battery Bat side to the microcontroller MCU side It is done.

  The ignition switch IGN outputs an on signal of a predetermined voltage when it is turned on, and does not output a signal when it is turned off. The microcontroller MCU is a control device that controls a damping force adjustable shock absorber mounted on a vehicle (not shown), and is activated when power is supplied from the battery Bat via the voltage change circuit 2. The microcontroller MCU outputs a hold signal of a predetermined voltage during startup. The microcontroller MCU monitors the on signal output by the ignition switch IGN through the signal line 6, and outputs the hold signal until the control in progress is normally ended when the ignition switch IGN is turned off. Then, when the control ends normally, the output of the hold signal is stopped.

  The main switch MS is a P-channel MOSFET in this example, and the gate is placed on the ground GND by the control line CL halfway. Also, switching elements 3 and 4 are provided in parallel in the middle of the control line CL.

  The switching element 3 is an N-channel MOSFET in this embodiment, and is turned on when the ignition switch IGN is turned on and a voltage consisting of an on signal is applied to the gate, and the gate of the main switch MS is set to ground GND. Close the main switch MS by grounding it to a low level. Conversely, the switching element 3 is turned off when the ignition switch IGN is turned off, and the main switch MS is opened. Therefore, when the switching element 3 is turned on, power can be supplied from the battery Bat to the microcontroller MCU through the voltage change circuit 2.

  Further, the switching element 4 is an N-channel MOSFET in this embodiment, and is turned on when a voltage consisting of a hold signal is applied to the gate from the microcontroller MCU, and the gate of the main switch MS is set to the ground GND. Close the main switch MS by grounding it to a low level. Conversely, the switching element 4 is turned off when there is no hold signal input from the microcontroller MCU, and opens the main switch MS. Therefore, when the switching element 4 is turned on, power can be supplied from the battery Bat to the microcontroller MCU through the voltage change circuit 2.

  As described above, when the ignition switch IGN is turned on or the microcontroller MCU receives a hold signal, the power supply unit S1 performs power supply from the battery Bat to the microcontroller MCU by closing the main switch MS. . Although the main switch MS is a P-channel MOSFET in this example, it is not limited to this and may be a relay.

  In this case, the voltage change circuit 2 is a switching regulator in this example. When there is an external signal input, the voltage change circuit 2 steps down the voltage of the battery Bat to a voltage suitable for use in the microcontroller MCU and outputs the voltage, and stops operation when there is no input of the signal, Does not supply power to microcontroller MCU. And in this example, the terminal which receives the input of the signal from the outside in the voltage change circuit 2 is connected to the ignition switch IGN through the signal line 6, and operate | moves when the ON signal is input from the ignition switch IGN. The voltage of the battery Bat is stepped down and output to the microcontroller MCU. Therefore, the voltage change circuit 2 is configured to stop its operation when the on signal from the ignition switch IGN is interrupted. The voltage change circuit 2 is not limited to a switching regulator, and may be a DC / DC converter such as an LDO regulator.

  The delay circuit DC is disposed in the middle of the signal line 6 connecting the ignition switch IGN and the voltage change circuit 2, and is provided between the ignition switch IGN and the voltage change circuit 2. Specifically, the delay circuit DC is interposed in parallel between the resistor 7 provided in the middle of the signal line 6 and the voltage changing circuit 2 side and the ground GND than the first resistor 7 of the signal line 6 And a second resistor 8 and a capacitor 9. A diode D is provided in the middle of the signal line 6 and on the delay circuit DC side of a branch point of a line (not shown) for inputting the on signal to the microcontroller MCU.

  In the delay circuit DC, the capacitor 9 is charged when the ignition switch IGN is turned on, and the charge of the capacitor 9 is discharged by the resistor 8 when the ignition switch IGN is turned off, but even if the ignition switch IGN is turned off During time, it keeps outputting a signal to operate the voltage change circuit 2.

  The predetermined time from when the ignition switch IGN is turned off to when the delay circuit DC stops outputting a signal is set by the capacitance of the second resistor 8 and the capacitor 9. The predetermined time is set to be longer than the time normally required for the microcontroller MCU to complete control normally when the ignition switch IGN is turned off. The delay circuit DC is not limited to the above-described configuration, and in the present example, as long as it can output a signal for operating the voltage change circuit 2 for a predetermined time by turning off the ignition switch IGN. Good.

  Subsequently, the operation of the power control device C1 configured as described above will be described. First, an operation in a situation where the microcontroller MCU operates normally will be described. The case where the ignition switch IGN is switched from off to on will be described. When the ignition switch IGN is turned on, the switching element 3 to which the gate is applied is turned on, the main switch MS is turned on, and the battery Bat and the voltage change circuit 2 are connected. In addition, when the ignition switch IGN is turned on, the voltage change circuit 2 starts operation to step down the voltage of the battery Bat and output it to the microcontroller MCU. The microcontroller MCU receives power supply from the battery Bat, starts up, executes control, and outputs a hold signal to the switching element 4. Further, charge is stored in the capacitor 9 of the delay circuit DC when the ignition switch IGN is turned on.

  The case where the ignition switch IGN is switched from on to off will be described. When the ignition switch IGN is switched from on to off, the switching element 3 is turned off since the application to the gate is discontinued. When the input of the on signal from the ignition switch IGN is interrupted, the microcontroller MCU performs termination processing for terminating the control being executed normally, but continues to output the hold signal until normal termination. Therefore, the switching element 4 maintains the on state. The main switch MS is turned on when the switching element 3 or the switching element 4 is turned on. Therefore, even if the ignition switch IGN is turned off, the on state is maintained when the hold signal is outputted from the microcontroller MCU. Therefore, even if the ignition switch IGN is turned off, the main switch MS is maintained in the on state if the microcontroller MCU is outputting the hold signal.

  Even if the ignition switch IGN is turned off and the on signal is interrupted, the delay circuit DC maintains the voltage change circuit 2 in an operable state for a predetermined time until the charge stored in the capacitor 9 is discharged. . The diode D provided on the signal line 6 prevents the capacitor 9 from discharging the ON signal to the microcontroller MCU, and the capacitor 9 causes the microcontroller MCU to determine that the ignition switch ING is turned on. To prevent. As described above, this predetermined time is set to be longer than the time normally required for the microcontroller MCU to normally complete control. Therefore, if the microcontroller MCU is normal, the operation of the voltage change circuit 2 is secured until the microcontroller MCU normally terminates control. As described above, even if the ignition switch IGN is turned off, the power supply from the battery Bat does not stop until the microcontroller MCU stops the hold signal and the main switch MS is turned off. Then, when the microcontroller MCU stops control and ends processing normally, the hold signal is stopped and the main switch MS is turned off.

  On the other hand, a case where the microcontroller MCU continues to output the hold signal even if the microcontroller MCU has an abnormality and the ignition switch IGN is switched from on to off will be described. In this case, since the ignition switch IGN is turned off, the switching element 3 is turned off, but the switching element 4 continuing to receive the hold signal is turned on and the main switch MS is turned on. Even if the ignition switch IGN is turned off, the voltage change circuit 2 continues input of the signal for a predetermined time by the charge stored in the capacitor 9 of the delay circuit DC, and for a predetermined time after the ignition switch IGN is turned off. Continue to work. However, when a predetermined time passes after the ignition switch IGN is turned off, the input of the signal from the delay circuit DC stops, so the voltage change circuit 2 stops its operation and the voltage output to the microcontroller MCU is stopped and the microcontroller MCU Power supply to the power is shut off. Then, the microcontroller MCU can not output the hold signal, and not only the switching element 3 but also the switching element 4 is turned off and the main switch MS is turned off.

  As described above, the power supply control device C1 turns on the ignition switch IGN or receives the hold signal from the microcontroller (control device) MCU, and supplies the power supply unit S1 for supplying power to the microcontroller (control device) MCU; Even if the switch IGN is turned off, it has a delay circuit DC that outputs a signal for a predetermined time, and when the ignition switch IGN is turned off and the signal from the delay circuit DC is cut off, the power supply unit S1 is a microcontroller (control device ) Turn off the power supply to the MCU.

  The power supply control device C1 configured as described above operates the microcontroller after the delay circuit DC has passed the predetermined time even if the microcontroller MCU continues to output the hold signal despite the ignition switch IGN being turned off. Power supply to the MCU can be forcibly terminated.

  Therefore, the configuration of the power supply control device C1 is simpler and less expensive than that of the conventional device, and even if there is an abnormality in the microcontroller (control device) MCU, it is possible to prevent overdischarge of the battery Bat.

  Further, in the power supply control device C1 of this example, the power supply unit S1 transforms the voltage of the battery Bat with the input of the signal from the battery Bat and the ignition switch IGN or the delay circuit DC, and outputs it to the microcontroller (control device) MCU And a main switch MS which is provided between the battery Bat and the voltage change circuit 2 and is closed in a state in which the ignition switch IGN is on or the hold signal from the microcontroller (control device) MCU is present. And a delay circuit DC is provided between the ignition switch IGN and the voltage change circuit 2. When the power supply control device C1 is configured as described above, the power supply to the microcontroller (control device) MCU can be forcibly terminated by using the voltage change circuit 2 only by installing the delay circuit DC. Therefore, the configuration of the power supply control device C1 is very simple, and the cost can be reduced more effectively.

Second Embodiment
As shown in FIG. 2, the power supply control device C2 turns on the ignition switch IGN or receives a hold signal from the microcontroller MCU as a control device, and supplies an electric power supply unit S2 for supplying power to the microcontroller MCU, and an ignition Even when the switch IGN is turned off, a delay circuit DC which outputs a signal for a predetermined time is provided.

  The power supply unit S2 has a configuration in which a sub switch 10 is provided to the power supply unit S1 of the first embodiment. Further, the voltage change circuit 2 in the power supply unit S2 is configured to step down and continuously output to the microcontroller MCU while the main switch MS is on and connected to the battery Bat. Thus, unlike the power supply unit S1, the power supply unit S2 in the power supply control device C2 of this example operates continuously without receiving the input of the ON signal from the ignition switch IGN. There is.

  In this example, the sub switch 10 is a switching element formed of an N-channel MOSFET, and is provided between the voltage change circuit 2 on the power supply line PL and the microcontroller MCU. When a voltage is applied to the gate, the sub switch 10 is turned on to connect the voltage change circuit 2 and the microcontroller MCU, and when there is no voltage applied to the gate, the sub switch 10 is turned off to disconnect the both.

  The gate of the sub switch 10 is connected to the ignition switch IGN via the signal line 11, and the sub switch 10 is also turned on when the ignition switch IGN is turned on.

  The delay circuit DC is provided on a signal line 11 connecting the ignition switch IGN and the sub switch 10, and is disposed between the ignition switch IGN and the sub switch 10. Further, the signal line 11 is provided with a diode D for the same purpose as the power control device C1 in the first embodiment.

  The above is the difference from the power control device C1 of the first embodiment in the power control device C2 of this example, and the other configurations of the power control device C2 are the same as the power control device C1 of the first embodiment. It is.

  The operation of the power supply control device C2 configured as described above will be described. First, an operation in a situation where the microcontroller MCU operates normally will be described. The case where the ignition switch IGN is switched from off to on will be described. When the ignition switch IGN is turned on, the switching element 3 to which the gate is applied is turned on, the main switch MS is turned on, and the battery Bat and the voltage change circuit 2 are connected. Further, when the ignition switch IGN is turned on, charges are stored in the capacitor 9 of the delay circuit DC, and the sub switch 10 is turned on to connect the voltage change circuit 2 and the microcontroller MCU. Thus, since the main switch MS and the sub switch 10 are turned on, the voltage lowered by the voltage change circuit 2 can be output to the microcontroller MCU, and power is supplied from the battery Bat to the microcontroller MCU. . Then, the microcontroller MCU receives power supply from the battery Bat, starts up, executes control, and outputs a hold signal to the switching element 4.

  The case where the ignition switch IGN is switched from on to off will be described. When the ignition switch IGN is switched from on to off, the switching element 3 is turned off since the application to the gate is discontinued. When the input of the on signal from the ignition switch IGN is interrupted, the microcontroller MCU performs termination processing for terminating the control being executed normally, but continues to output the hold signal until normal termination. Therefore, the switching element 4 maintains the on state. The main switch MS is turned on when the switching element 3 or the switching element 4 is turned on. Therefore, even if the ignition switch IGN is turned off, the on state is maintained when the hold signal is outputted from the microcontroller MCU. Therefore, even if the ignition switch IGN is turned off, the main switch MS is maintained in the on state if the microcontroller MCU is outputting the hold signal.

  Even if the ignition switch IGN is turned off and the on signal is interrupted, the delay circuit DC maintains the sub switch 10 in the on state for a predetermined time until the charge stored in the capacitor 9 is discharged. Maintain power supply from Bat to microcontroller MCU. As described above, this predetermined time is set to be longer than the time normally required for the microcontroller MCU to normally complete control. Therefore, if the microcontroller MCU is normal, power supply from the battery Bat to the microcontroller MCU is secured until the microcontroller MCU normally terminates control. As described above, even if the ignition switch IGN is turned off, the power supply from the battery Bat does not stop until the microcontroller MCU stops the hold signal and the main switch MS is turned off. Then, when the microcontroller MCU stops control and ends processing normally, the hold signal is stopped and the main switch MS is turned off.

  On the other hand, a case where the microcontroller MCU continues to output the hold signal even if the microcontroller MCU has an abnormality and the ignition switch IGN is switched from on to off will be described. In this case, since the ignition switch IGN is turned off, the switching element 3 is turned off, but the switching element 4 continuing to receive the hold signal is turned on and the main switch MS is turned on. Even if the ignition switch IGN is turned off, the sub switch 10 is turned on for a predetermined time after the input of the signal is continued for a predetermined time by the charge stored in the capacitor 9 of the delay circuit DC and the ignition switch IGN is turned off. It is maintained in the state. However, when a predetermined time passes after the ignition switch IGN is turned off, the input of the signal from the delay circuit DC is interrupted, and the sub switch 10 is turned off, so that the battery Bat and the microcontroller MCU are disconnected and the microcontroller Power supply to the MCU stops. Then, the microcontroller MCU can not output the hold signal, and not only the switching element 3 but also the switching element 4 is turned off and the main switch MS is turned off.

  As described above, the power supply control device C2 turns on the ignition switch IGN or receives the hold signal from the microcontroller (control device) MCU, and supplies the power supply unit S2 for supplying power to the microcontroller (control device) MCU; Even if the switch IGN is turned off, it has a delay circuit DC that outputs a signal for a predetermined time, and when the ignition switch IGN is turned off and the signal from the delay circuit DC is cut off, the power supply unit S2 is a microcontroller (control device ) Turn off the power supply to the MCU.

  In the power supply control device C2 configured as described above, even if the microcontroller MCU continues to output the hold signal despite the fact that the ignition switch IGN is turned off, the microcontroller after the predetermined time elapses in the delay circuit DC. Power supply to the MCU can be forcibly terminated.

  Therefore, the configuration of the power supply control device C2 is simpler and less expensive than the conventional device, and can prevent overdischarge of the battery Bat even if the microcontroller (control device) MCU has an abnormality.

  Further, in the power supply control device C2 of this example, the power supply unit S2 transforms the voltage of the battery Bat and the voltage of the battery Bat and outputs the voltage change circuit 2 to the microcontroller (control device) MCU, the battery Bat and the voltage change circuit Between the battery Bat and the microcontroller (control device) MCU, provided between 2 and the main switch MS, which is provided in the state where the ignition switch IGN is on or the hold signal is input from the microcontroller (control device) MCU , And the delay circuit DC is provided between the ignition switch IGN and the sub switch 10, and the sub switch 10 is closed at the input of the signal from the ignition switch IGN or the delay circuit DC. When the power supply control device C2 is configured as described above, the power supply to the microcontroller (control device) MCU can be forcibly terminated only by the installation of the delay circuit DC and the sub switch 10. Therefore, the configuration of the power supply control device C2 is very simple, and the cost can be reduced more effectively.

  The sub switch 10 may be installed anywhere on the power supply line PL, that is, between the battery Bat and the microcontroller MCU. However, in the case where the voltage change circuit 2 steps down the voltage of the battery Bat, if the voltage change circuit 2 is installed between the voltage change circuit 2 and the microcontroller MCU, the subswitch 10 with low withstand voltage can be used, which is advantageous in cost.

  Furthermore, the voltage change circuit 2 is a circuit that steps up the voltage and outputs it to the control device as described above, but boosts the voltage when the voltage requested by the control device is higher than the voltage of the battery Bat. May be

  Of course, the control devices in the power supply control devices C1 and C2 of the present invention may be used for control other than the damping force adjustable shock absorber.

  While the preferred embodiments of the present invention have been described above in detail, modifications, variations and changes are possible without departing from the scope of the claims.

2: Voltage changing circuit, 10: Sub switch, Bat: Battery, C1, C2: Power control device, DC: Delay circuit, IGN: Ignition switch, MCU: Micro Controller (control device), MS ... main switch, S1, S2 ... power supply unit

Claims (3)

A power supply unit for supplying power to the control device in a state in which an ignition switch is turned on or a hold signal is input from the control device;
And a delay circuit that outputs a signal for a predetermined time even if the ignition switch is turned off,
The power supply control device, wherein the power supply unit shuts off the power supply to the control device when the ignition switch is turned off and the signal from the delay circuit is cut off. The power supply unit includes a battery, a voltage change circuit that transforms a voltage of the battery with an input of a signal from the ignition switch or the delay circuit and outputs the voltage to the control device, and the battery and the voltage change circuit. And a main switch which is provided between the ignition switch and the on / off of the hold signal from the control device.
The power supply control device according to claim 1, wherein the delay circuit is provided between the ignition switch and the voltage change circuit. The power supply unit is provided between a battery, a voltage change circuit that transforms a voltage of the power supply and outputs the voltage to the control device, and a control device for turning on the ignition switch or provided between the battery and the voltage change circuit. And a sub switch provided between the battery and the control device and closed by the input of the signal from the ignition switch or the delay circuit.
The power supply control device according to claim 1, wherein the delay circuit is provided between the ignition switch and the sub switch.

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