JP2017078340A - Electronic control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic control device that can open a valve of a direct injection injector and can stabilize operations of other devices by using a common booster circuit section.SOLUTION: An electronic control device 10 includes: a booster circuit section 20; a control section 21 for controlling a direct injection injector 101 and a port injection injector 102 in accordance with a vehicle operation state and controlling the booster circuit section by setting target voltage; a power supply line 23 for supplying output voltage of the booster circuit section to another ECU 103; and a supply switch Q6 provided in the power supply line. For a drive period after engine start until acquisition of an engine stop request, the control section turns off the power supply switch while setting first target voltage for injecting fuel from the direct injection injector as target voltage. For at least part of an engine stop period, second target voltage enabling stable operations of other devices is set as target voltage, and when the output voltage reaches the second target voltage, the power supply switch is turned on.SELECTED DRAWING: Figure 1

Description

  The disclosure in this specification relates to an electronic control device including a booster circuit unit, and a control unit that controls the operation of the booster circuit unit and fuel injection by a direct injection injector.

  2. Description of the Related Art Conventionally, an electronic control device is known that includes a booster circuit unit and a control unit that controls the operation of the booster circuit unit and fuel injection by a direct injection injector. In this electronic control device, the control unit sets a predetermined target voltage (for example, 65V) to open the direct injection injector, and the booster circuit unit receives a voltage supplied from a DC power supply as an input, and the target voltage Outputs the output voltage according to

  By the way, at the time of cranking for starting the engine, the voltage of the DC power supply is lowered by driving the starter. In Patent Document 1, the voltage of the DC power supply is lower than the minimum guaranteed operating voltage of the navigation ECU, the brake ECU, the meter ECU, and the like at the time of cranking, so that the microcomputer of each ECU is suppressed from being reset. A configuration including a circuit unit is disclosed. The booster circuit unit receives a voltage supplied from a DC power supply, and outputs an output voltage according to a predetermined target voltage (for example, 12 V) at which the navigation ECU or the like can operate stably.

JP 2009-292451 A

  Therefore, in an electronic control device including a booster circuit unit and a control unit that controls the operation of the booster circuit unit and the fuel injection by the direct injection injector, the operation of another device that operates by being supplied with a voltage from a DC power source In order to achieve stabilization, a booster circuit unit for stabilizing the operation of other devices is separately provided.

  This indication is made in view of such a subject, and provides the electronic control device which can open a direct injection injector and can stabilize operation of other devices by a common boost circuit part. Objective.

  The present disclosure employs the following technical means to achieve the above object. In addition, the code | symbol in parenthesis shows the corresponding relationship with the specific means as described in embodiment mentioned later as one aspect | mode, Comprising: The technical scope is not limited.

One of the present disclosure includes a booster circuit unit (20) that receives a voltage supplied from a DC power supply and outputs an output voltage according to a target voltage;
The fuel injection by the direct injection injector (101) for injecting fuel into the combustion chamber of the internal combustion engine and the port injection injector (102) for injecting fuel into the intake port of the internal combustion engine are controlled according to the vehicle operating state acquired from the outside. A control unit (21) that sets a target voltage and controls the operation of the booster circuit unit according to the set target voltage;
A power supply line (23) for supplying an output voltage to another device (103) that operates by being supplied with a voltage from a DC power supply;
A power supply switch (Q6) provided in the power supply line,
The control unit
In the driving period from the start of the internal combustion engine to the acquisition of the stop request for the internal combustion engine, the first target voltage for injecting fuel from the direct injection injector is set as the target voltage, and the power supply switch is turned off,
In at least a part of the stop period of the internal combustion engine, a second target voltage that is lower than the first target voltage and that allows other devices to operate stably is set as the target voltage, and the output voltage is set to the second target voltage. When it reaches, the power supply switch is turned on.

According to this, the booster circuit unit outputs an output voltage according to the first target voltage during the driving period. Therefore, the direct injection injector can be opened, that is, the fuel can be injected. Further, the power supply switch is turned off during the driving period in which the first target voltage is set. Therefore, it can suppress that the output voltage according to a 1st target voltage is supplied to another apparatus.

  On the other hand, in at least a part of the stop period, the booster circuit unit outputs an output voltage according to the second target voltage. When the output voltage reaches the second target voltage, the power supply switch is turned on, and the output voltage according to the second target voltage is supplied to another device. Therefore, even if the voltage supplied from the DC power supply decreases during the stop period, the operation of other devices can be stabilized.

  As described above, the common booster circuit unit can open the direct injection injector and can stabilize the operation of other devices.

It is a figure which shows schematic structure of the electronic controller which concerns on 1st Embodiment. It is a flowchart which shows the process which a control part performs at the time of cranking in a stop period. It is a figure which shows schematic structure of the electronic control apparatus which concerns on 2nd Embodiment. It is a flowchart which shows the process performed when a control part acquires an engine stop request | requirement.

  A plurality of embodiments will be described with reference to the drawings. In several embodiments, functionally and / or structurally corresponding parts are given the same reference numerals.

(First embodiment)
First, a schematic configuration of the electronic control device according to the present embodiment will be described with reference to FIG. The electronic control device of the present embodiment is configured as an engine ECU (Electronic Control Unit). In the following, among the functions as the engine ECU, a function for controlling fuel injection of the injector and a function for supplying power to other electronic control units will be described.

  An electronic control device 10 shown in FIG. 1 is disposed in, for example, an engine compartment of a vehicle, and controls opening and closing of injectors 100 provided in each cylinder of the engine (internal combustion engine), that is, fuel injection by the injectors 100. In this embodiment, as the injector 100, fuel injection is controlled by a direct injection injector 101 that injects fuel directly into a combustion chamber (cylinder) of a gasoline engine and a port injection injector 102 that injects fuel into an intake port of the gasoline engine. To do. In FIG. 1, for convenience, the direct injection injector 101 and the port injection injector 102 are shown one by one.

  The direct injection injector 101 and the port injection injector 102 have solenoids 101a and 102a (coils), respectively. Each injector 100 is configured to be released by electromagnetic force generated by the solenoids 101a and 102a when the solenoids 101a and 102a are energized to inject fuel. When the solenoids 101a and 102a are not energized, the solenoids 101a and 102a are closed by a biasing force of a spring (not shown) provided in the injector 100.

  The upstream side of the solenoids 101a and 102a is connected to the output terminal P1 of the electronic control device 10, and the downstream side is connected to the output terminal P2. The output terminal P1 is also referred to as an upstream terminal, and the output terminal P2 is also referred to as a downstream terminal. The output terminal P1 has an output terminal P11 connected to the upstream side of the solenoid 101a and an output terminal P12 connected to the upstream side of the solenoid 102a. The output terminal P2 has an output terminal P21 connected to the downstream side of the solenoid 101a and an output terminal P22 connected to the downstream side of the solenoid 102a.

  The electronic control device 10 includes a booster circuit unit 20, a peak current switch Q2, a constant current switch Q3, drive switches Q4 and Q5, a supply switch Q6, and a control unit 21.

  The step-up circuit unit 20 includes a capacitor C1, an inductor L1 (coil), a charge switch Q1, a resistor R1, and a diode D1. The capacitor C1 is an electrolytic capacitor. The capacitor C1 stores energy to be applied to the solenoid 101a in order to inject fuel from the direct injection injector 101. The capacitor C1 is also referred to as a boost power source.

  The battery voltage VB is supplied to the power supply terminal P3 of the electronic control device 10. The battery voltage VB is a DC voltage supplied from an in-vehicle battery (DC power supply) via a main relay (not shown). A power supply line 22 is connected to the power terminal P3. One end of the inductor L1 is connected to the power supply line 22, and the charging switch Q1 is connected to the other end of the inductor L1. When, for example, an n-channel MOSFET is employed as the charge switch Q1, the drain of the charge switch Q1 is connected to the inductor L1, and the source is connected to the ground via the resistor R1.

  An anode of a backflow prevention diode D1 is connected to a connection point between the inductor L1 and the charge switch Q1. A capacitor C1 is disposed between the connection point between the charging switch Q1 and the resistor R1 and the cathode of the diode D1. The positive electrode of the capacitor C1 is connected to the cathode of the diode D1, and the negative electrode is connected to the connection point between the charge switch Q1 and the resistor R1.

  The booster circuit unit 20 outputs an output voltage VC according to the set target voltage. The output voltage VC is a potential on the positive side of the capacitor C1. When the output voltage VC becomes equal to or lower than the set target voltage, the booster circuit unit 20 charges the capacitor C1 so that the output voltage VC becomes the target voltage by repeatedly turning on and off the charging switch Q1. When the charging switch Q1 is turned on, a charging current flows through the resistor R1 through the inductor L1 and the charging switch Q1. When the charge switch Q1 is turned off, the energy stored in the inductor L1 is transferred to the capacitor C1 through the diode D1, and the output voltage VC increases. At this time, a charging current flows through the resistor R1.

  The peak current switch Q2 is disposed between the capacitor C1 and the output terminal P11, and is turned on, so that the output voltage VC of the booster circuit unit 20, that is, the energy accumulated in the capacitor C1 is solenoided via the output terminal P11. This is a switch for discharging to 101a. For this reason, the peak current switch Q2 is also referred to as a discharge switch. When, for example, a p-channel type MOSFET is employed as the peak current switch Q2, the source of the peak current switch Q2 is connected to the positive electrode of the capacitor C1, and the drain is connected to the upstream side of the solenoid 101a via the output terminal P11. .

  The constant current switch Q3 is a switch that is arranged on the upstream side with respect to the output terminal P11 and is turned on to supply the battery voltage VB to the solenoid 101a via the output terminal P11. When, for example, a p-channel MOSFET is employed as the constant current switch Q3, the source of the constant current switch Q3 is connected to the power supply line 22, and the drain is connected to the solenoid via the backflow prevention diode D2 and the output terminal P11. 101a is connected to the upstream side.

  The anode of the diode D2 is connected to the drain of the constant current switch Q3, and the cathode is connected to the drain of the peak current switch Q2. Between the connection point of the diode D2 and the peak current switch Q2 and the ground, a free-wheeling diode D3 is arranged with the anode on the ground side.

  The drive switch Q4 is provided corresponding to the solenoid 101a and is disposed on the downstream side of the corresponding solenoid 101a. When the drive switch Q4 is turned on, the downstream side of the corresponding solenoid 101a is connected to the ground. For this reason, the drive switch Q4 is also referred to as a low-side switch. Further, since it is provided for each solenoid 101a, it is also referred to as a cylinder selection switch. When, for example, an n-channel MOSFET is used as the drive switch Q4, the source of the drive switch Q4 is connected to the ground via the current detection resistor R2, and the drain is downstream of the solenoid 101a via the output terminal P21. Connected to the side. The resistor R2 is a resistor for detecting the current flowing through the solenoid 101a when the drive switch Q4 is turned on.

  The drive switch Q5 is provided corresponding to the solenoid 102a and is disposed on the downstream side of the corresponding solenoid 102a. When the drive switch Q5 is turned on, the downstream side of the corresponding solenoid 102a is connected to the ground. For this reason, the drive switch Q5 is also referred to as a low-side switch. Further, since it is provided for each solenoid 102a, it is also referred to as a cylinder selection switch. For example, when an n-channel MOSFET is employed as the drive switch Q5, the source of the drive switch Q5 is connected to the ground, and the drain is connected to the downstream side of the solenoid 102a via the output terminal P22.

  The supply switch Q6 is provided on the power supply line 23 for supplying the output voltage VC of the booster circuit unit 20 to another electronic control unit 103 (hereinafter referred to as another ECU 103). The supply switch Q6 corresponds to a power supply switch, and the other ECU 103 corresponds to another device. The other ECU 103 includes, for example, a navigation ECU 103a, an air conditioner ECU 103b, a meter ECU 103c, and the like.

  The power supply line 23 electrically connects the booster circuit unit 20 and the output terminal P4. The source of the peak current switch Q2 is connected to a connection point 24 between the booster circuit unit 20 and the power supply line 23. The other ECU 103 is supplied with a voltage for operation from a vehicle-mounted battery (BATT) that is a supply source of the battery voltage VB via the power supply line 104. In the present embodiment, the power supply line 105 connected to the output terminal P4 is connected to the connection point 106 between the power supply line 104 and each other ECU 103 described above. A backflow prevention diode D4 is connected between the in-vehicle battery and the connection point 106 with the cathode at the connection point 106 side.

  The supply switch Q6 is a switch that, when turned on, supplies the output voltage VC of the booster circuit unit 20 to the power supply line 105 and eventually to the other ECU 103 via the output terminal P4. For example, when a p-channel MOSFET is employed as the supply switch Q6, the source of the supply switch Q6 is connected to the connection point 24 side of the power supply line 23, and the drain is connected to the output terminal P4 side of the power supply line 23. The A backflow prevention diode D5 is connected between the drain and the output terminal P4 with the cathode as the output terminal P4 side.

  The control unit 21 controls the operation of the booster circuit unit 20 and the fuel injection by the injector 100 according to information indicating the vehicle operation state acquired from various sensors (not shown), other electronic control devices, and the like. That is, on / off of the charge switch Q1, on / off of the peak current switch Q2, on / off of the constant current switch Q3, and on / off of the drive switches Q4, Q5 are controlled according to the driving state of the vehicle. Furthermore, the control part 21 controls on / off of the supply switch Q6 according to the above-mentioned vehicle operating state.

  Note that the control unit 21 acquires the value of the charging current flowing through the resistor R1 and the value of the driving current flowing through the resistor R2. Further, the control unit 21 acquires the voltage on the positive side of the capacitor C1, that is, the value of the output voltage VC and the battery voltage VB. The battery voltage VB is divided by a resistor (not shown) for convenience and input to the control unit 21. Similarly, the output voltage VC is also divided by a resistor (not shown) and input to the control unit 21.

  The means and / or function provided by the control unit 21 can be provided by software recorded in a substantial memory device and a computer that executes the software, only software, only hardware, or a combination thereof. For example, if the controller is provided by an electronic circuit that is hardware, it can be provided by a digital circuit including a number of logic circuits, or an analog circuit. The electronic control device 10 of the present embodiment is configured as an engine ECU as described above, and the control unit 21 is configured by a microcomputer and a drive IC (not shown). In FIG. 1, the charging switch Q1 is illustrated separately from the control unit 21 (driving IC), but the charging switch Q1 may be configured in the chip of the driving IC.

  The control unit 21 sets the target voltage of the booster circuit unit 20 according to the vehicle operating state, and controls the operation of the booster circuit unit 20, that is, the on / off of the charging switch Q1, according to the set target voltage. The target voltage is stored in advance in the memory. The control unit 21 uses a first target voltage (for example, 65V) for injecting fuel from the direct injection injector 101 as a target voltage of the booster circuit unit 20 during a driving period from when the engine is started to when an engine stop request is acquired. ) Is set. This first target voltage is a target voltage for controlling the peak current of the direct injection injector 101. Thereby, in the drive period, the booster circuit unit 20 boosts the battery voltage VB so that the output voltage VC becomes the first target voltage. The controller 21 turns off the supply switch Q6 during the driving period. Therefore, the output voltage VC is not supplied to the other ECU 103 during the driving period.

  On the other hand, the control unit 21 is a voltage lower than the first target voltage as the target voltage in at least a part of the engine stop period, which is a period before the engine start and after acquisition of the engine stop request. A second target voltage (for example, 12V) capable of stable operation is set. As a result, the output voltage VC of the booster circuit unit 20 becomes a voltage according to the second target voltage, that is, about 12 V in at least a part of the stop period. When the output voltage VC reaches 12V after the second target voltage is set, the control unit 21 turns on the supply switch Q6. While the supply switch Q6 is turned on, the output voltage VC is supplied to the other ECU 103 via the output terminal P4. Note that the second target voltage is not limited to 12V. A voltage that is lower than the first target voltage and that allows the other ECU 103 to operate stably, that is, a voltage that is equal to or higher than the minimum operation guarantee voltage (for example, 8 V) of the other ECU 103 can be set.

  The control unit 21 can perform control so that at least one of the direct injection injector 101 and the port injection injector 102 becomes a fuel injection target for injecting fuel during the above-described driving period. For example, the fuel injection target can be switched between the direct injection injector 101 and the port injection injector 102 in accordance with the correspondence between the engine speed and the required torque for the engine. Further, the fuel injection target can be switched only by the port injector 102, both the direct injector 101 and the port injector 102, or only the direct injector 101 according to the correspondence relationship between the engine speed and the required torque. When the fuel injection targets are both the direct injection injector 101 and the port injection injector 102, the ratio of the fuel injection amounts of the direct injection injector 101 and the port injection injector 102 can be adjusted so as to suppress, for example, torque fluctuation. The correspondence between the engine speed and the required torque and the ratio of the fuel injection amount are, for example, mapped and stored in the memory.

  The microcomputer of the control unit 21 generates an injection signal (H level signal) corresponding to each injector 100 based on information indicating the vehicle operating state such as the engine speed and the accelerator opening, and outputs the injection signal to the drive IC. The drive IC of the control unit 21 controls on / off of the drive switch Q5 based on the injection signal, thereby energizing the solenoid 102a with the drive current and opening the port injection injector 102.

  Further, the drive IC of the control unit 21 controls the on / off of the peak current switch Q2, the on / off of the constant current switch Q3, and the on / off of the drive switch Q4 based on the injection signal, thereby energizing the solenoid 101a with the drive current, The direct injection injector 101 is opened. For example, the control unit 21 turns on the corresponding peak current switch Q2 and drive switch Q4 during the period when the injection signal is at the H level, that is, at the beginning of the injection period. When the peak current switch Q2 is turned on, an output voltage according to the first target voltage (65V) is applied to the solenoid 101a by the booster circuit unit 20, and the drive current flowing through the solenoid 101a suddenly rises and the direct injection injector 101 is turned on. Opens.

  When the drive current reaches a predetermined peak current value, the control unit 21 turns off the peak current switch Q2. Thereby, the peak current period (discharge period) in which the peak current switch Q2 is turned on ends. The drive switch Q4 is continuously turned on.

  In the constant current period from the end of the discharge period to the end of the injection period, the control unit 21 performs constant current processing. The controller 21 turns on the constant current switch Q3 when the drive current decreases to a predetermined lower limit current value. When the constant current switch Q3 is turned on, the drive current increases. When the drive current rises to a predetermined upper limit current value, the constant current switch Q3 is turned off. As a result, the drive current decreases. The upper current value is set to a value smaller than the peak current value. In this way, the control unit 21 controls the on / off of the constant current switch Q3 so that the drive current is not less than the lower limit current value and not more than the upper limit current value. As a result, in the constant current period, a predetermined holding current smaller than the peak current value, that is, a substantially constant current, is supplied to the solenoid 101a as the driving current. Thereby, the valve-open state of the direct injection injector 101 is maintained.

  When the injection signal becomes L level, the control unit 21 turns off the constant current switch Q3 and the drive switch Q4, and ends the valve opening process. The control unit 21 charges the capacitor C1 during the injection of each cylinder, that is, after the discharge from the capacitor C1 for injection, until the next discharge is started.

  Next, a process executed by the control unit 21 during cranking for starting the engine during the stop period will be described with reference to FIG. During this process, the control unit 21 does not turn on the peak current switch Q2, the constant current switch Q3, and the drive switch Q4. That is, it is turned off continuously.

  When the control unit 21 acquires the starter drive signal, the control unit 21 executes the process shown in FIG. The starter drive signal is a signal for turning on a starter relay to drive a starter (starter motor), and is acquired from another device when a device other than the electronic control device 10 controls the drive of the starter. . Further, when the electronic control device 10 also controls the drive of the starter, it is obtained from a control unit that controls the starter drive.

  As shown in FIG. 2, first, the control unit 21 sets a second target voltage (12V) as a target voltage (step S10). That is, the control unit 21 starts controlling the booster circuit unit 20 according to the second target voltage. Therefore, when the battery voltage VB is lower than the second target voltage, the booster circuit unit 20 boosts the battery voltage VB and outputs the output voltage VC. Even if the battery voltage VB falls below the minimum operation guarantee voltage (for example, 8V) of the other ECU 103 by driving the starter, the output voltage VC increases toward the second target voltage by the boosting operation of the boosting circuit unit 20.

  Next, the control unit 21 acquires the output voltage VC, that is, the positive electrode potential of the capacitor C1 (step S11). Then, it is determined whether or not the output voltage VC has reached the second target voltage (12V), that is, whether or not the output voltage VC is equal to or higher than the second target voltage (step S12).

  If it is determined in step S12 that the output voltage VC has reached 12V, which is the second target voltage, the control unit 21 turns on the supply switch Q6 (step S13). As a result, the output voltage VC boosted to 12 V or higher is supplied to the power supply line 105 via the supply switch Q6, the diode D5, and the output terminal P4. As described above, even if the voltage of the in-vehicle battery (BATT) becomes less than 12V by driving the starter, the other ECU 103 can stably operate by supplying the output voltage VC. In particular, even if the voltage of the in-vehicle battery falls below the minimum operation guarantee voltage (for example, 8V) of the ECU 103, the microcomputer included in the other ECU 103 is not reset by the supply of the output voltage VC. Therefore, the other ECU 103 can operate stably.

  If it is determined in step S12 that the output voltage VC has not reached the second target voltage of 12V, the control unit 21 repeats the processes of steps S11 and S12 until the output voltage VC reaches the second target voltage.

  Next, the control unit 21 starts port injection control (step S14). The control unit 21 controls fuel injection by the port injector 102 so as to start the engine (operate the engine independently). And the control part 21 determines whether the engine started (step S15). In this determination, when the engine speed is equal to or higher than a predetermined speed set in advance, the control unit 21 determines that the engine has started. Control unit 21 repeats step S15 until the engine is started. If the engine does not start within a predetermined time set in advance, a series of processing may be terminated by notifying the user or the like.

  Next, the control unit 21 determines whether or not the starter has stopped (step S16). In this determination, when the control unit 21 acquires the starter drive stop signal, it determines that the starter has stopped. The starter drive stop signal can also be obtained in the same manner as the starter drive signal. The control unit 21 repeats step S16 until the starter stops. Also in this case, if the starter does not stop within a predetermined time set in advance, a series of processing may be terminated by notifying the user or the like.

  Next, the control unit 21 determines whether or not the battery voltage VB is 12 V or higher (step S17). That is, it is determined whether or not the voltage drop due to cranking has been recovered. The determination threshold is not limited to 12V. Any other voltage may be used as long as the other ECU 103 can operate stably. For example, 11V may be set as the determination threshold value. The control unit 21 repeats the process of step S17 until the battery voltage VB returns to 12 V due to the stop of the starter.

  After completion of step S17, that is, after determining that the battery voltage VB has returned to 12V, the control unit 21 turns off the supply switch Q6 (step S18). Thereby, the power supply line 23 is interrupted between the connection point 24 and the output terminal P4, and the supply of the output voltage VC to the other ECU 103 is stopped. As described above, since the supply switch Q6 is turned off after the battery voltage VB returns to the predetermined voltage (12V), the other ECU 103 can continuously operate stably.

  Next, the control unit 21 sets the first target voltage (65V) as the target voltage (step S19). That is, the target voltage is switched from the second target voltage (12V) to the first target voltage (65V). Thereby, the control unit 21 starts control of the booster circuit unit 20 according to the first target voltage. Therefore, the output voltage VC rises toward the first target voltage by the boosting operation of the boosting circuit unit 20.

  Next, the control unit 21 ends the port injection control for cranking (step S20). Then, a series of processing ends. In addition, the control part 21 performs the process of a drive period partially in parallel with the process at the time of the above-mentioned cranking. For this reason, the control part 21 starts the fuel injection control of a drive period substantially with execution of the process of step S20. That is, the port injection control during cranking is switched to the fuel injection control during the driving period. During the drive period, the control unit 21 controls fuel injection by the direct injection injector 101 and the port injection injector 102 in accordance with the driving state of the vehicle. The control unit 21 switches from port injection control during cranking to, for example, direct injection control.

  Next, effects of the electronic control device 10 according to the present embodiment will be described.

  In the present embodiment, the control unit 21 sets the first target voltage (65V) as the target voltage for the driving period. Thereby, on / off of the charging switch Q1 of the booster circuit unit 20 is controlled so that the output voltage VC becomes the first target voltage, and the booster circuit unit 20 outputs the output voltage VC according to the first target voltage. Therefore, fuel can be injected from the direct injection injector 101 during the drive period. Further, the supply switch Q6 is turned off during the driving period in which the first target voltage is set. Therefore, supply of the output voltage VC according to the first target voltage to the other ECU 103 can be suppressed.

  On the other hand, the control unit 21 sets the second target voltage (12 V) as the target voltage in at least a part of the stop period. As a result, the booster circuit unit 20 outputs the output voltage VC according to the second target voltage. Then, when the output voltage VC reaches the second target voltage, the control unit 21 turns on the supply switch Q6. Thereby, the output voltage VC according to the second target voltage is supplied to the other ECU 103. Therefore, even if the voltage supplied from the in-vehicle battery through the power supply line 104 decreases during the stop period, the operation of the other ECU 103 can be stabilized.

  As described above, according to the present embodiment, the direct injection injector 101 can be opened by the common booster circuit unit 20, and the operation of the other ECU 103 can be stabilized. The device configuration can be simplified by sharing the booster circuit unit 20.

  Particularly in the present embodiment, at the time of cranking in the stop period, the control unit 21 sets the second target voltage (12 V) as the target voltage, and among the direct injection injector 101 and the port injection injector 102, the port injection Control is performed so that fuel is injected only from the injector 102. Thus, at the time of cranking, since the fuel is not injected from the direct injection injector 101 but only from the port injection injector 102, the second target voltage (12V) can be set as the target voltage. Accordingly, the engine can be operated independently by fuel injection during cranking, and the output voltage VC according to the second target voltage can be supplied to the other ECU 103. That is, the operation of the other ECU 103 can be stabilized even at the time of cranking when the voltage supplied from the in-vehicle battery decreases.

(Second Embodiment)
This embodiment can refer to the preceding embodiment. For this reason, the description about the part which is common in the electronic control apparatus 10 shown to previous embodiment is abbreviate | omitted.

  As shown in FIG. 3, the electronic control device 10 shown in the present embodiment has a configuration in which a discharge switch Q7 and a resistor R3 are added to the electronic control device 10 shown in the first embodiment.

  The discharge switch Q7 is provided between a connection point 24 between the booster circuit unit 20 and the power supply line 23 and the ground. As the discharge switch Q7, for example, a MOSFET can be employed. On / off of the discharge switch Q7 is controlled by a drive signal output from the control unit 21. The resistor R3 is connected in series with the discharge switch Q7 and is disposed on the ground side with respect to the discharge switch Q7.

  Next, a process executed by the control unit 21 when an engine stop request is acquired will be described with reference to FIG. When acquiring the engine stop request signal, the control unit 21 executes the process shown in FIG. The engine stop request signal is output when the engine is stopped, for example, when the brake is depressed by the user and the vehicle speed satisfies a condition equal to or lower than a predetermined value. The predetermined value may be zero vehicle speed or may be several km / h to several tens km / h. The stop request is also referred to as an idle stop command. The engine stop request signal output may be executed by the electronic control device 10 or may be executed by another device.

  As shown in FIG. 4, first, the control unit 21 sets the second target voltage (12V) as the target voltage (step S30). The target voltage is switched from the first target voltage (65V) set during the driving period to the second target voltage. Instead of setting the second target voltage, the charging switch Q1 may be continuously turned off, that is, the boosting operation by the boosting circuit unit 20 may be stopped.

  Next, the control unit 21 obtains the output voltage VC, that is, the positive electrode potential of the capacitor C1 (step S31). Then, it is determined whether or not the output voltage VC is higher than the second target voltage (12V) (step S32).

  If it determines with output voltage VC being higher than 12V which is 2nd target voltage in step S32, the control part 21 will turn ON discharge switch Q7 (step S33). Then, due to the resistor R3, the charge (energy) accumulated in the capacitor C1 is quickly discharged, and the output voltage VC decreases. If it is determined in step S32 that the output voltage VC is not higher than 12V, that is, 12V or less, the control unit 21 ends the series of processes.

  Next, the control unit 21 determines whether or not the output voltage VC has become equal to or lower than the second target voltage (12V) (step S34). If it determines with output voltage VC being 12V or less in step S34, the control part 21 will turn off the discharge switch Q7 (step S35). And the control part 21 complete | finishes a series of processes. If it is determined in step S34 that the output voltage VC is higher than 12V, the control unit 21 repeats the process of S34 until the output voltage VC becomes equal to or lower than 12V, which is the second target voltage.

  Next, effects of the electronic control device 10 according to the present embodiment will be described.

  In the present embodiment, if the output voltage VC is higher than the second target voltage at the time of obtaining the engine stop request, the control unit 21 turns on the discharge switch Q7 and reduces the output voltage VC to the second target voltage or less. Therefore, for example, when the engine is restarted after an idle stop, it is possible to suppress a voltage higher than the second target voltage from being supplied to the other ECU 103. In other words, the output voltage VC boosted to inject fuel from the direct injection injector 101 does not decrease during engine stop and can be suppressed from being supplied to the other ECU 103 during restart.

  In addition, although the control part 21 showed the example which sets a 2nd target voltage (12V) as a target voltage by step S30, you may stop operation | movement of the voltage booster circuit part 20. FIG.

  Note that the above-described control can also be applied when the power source of the electronic control device 10 is turned off. When acquiring the ignition switch OFF signal, the control unit 21 executes the control shown in FIG. 4 before turning off the main relay and cutting off the voltage supply from the in-vehicle battery. According to this, when the power source of the electronic control device 10 is turned on again, it is possible to suppress a voltage higher than the second target voltage from being supplied to the other ECU 103.

  The disclosure of this specification is not limited to the illustrated embodiments. The disclosure encompasses the illustrated embodiments and variations by those skilled in the art based thereon. For example, the disclosure is not limited to the combination of elements shown in the embodiments. The disclosure can be implemented in various combinations. The technical scope disclosed is not limited to the description of the embodiments. The several technical scopes disclosed are indicated by the description of the claims, and should be understood to include all modifications within the meaning and scope equivalent to the description of the claims. .

  Although the example in which the electronic control device 10 is applied to a gasoline engine has been shown, it can also be applied to a diesel engine.

  Although not specifically mentioned, the electronic control device 10 may further include a recovery unit that recovers the energy stored in the corresponding solenoid 101a to the capacitor C1 when the drive switch Q4 is turned off. A switch such as a diode or MOSFET can be employed as the recovery unit. For example, in the case of a diode corresponding to the solenoid 101a, the anode of the diode is connected to the output terminal P21, and the cathode is connected to the connection point between the diode D1 and the capacitor C1, that is, the positive electrode of the capacitor C1.

  In the above-described embodiment, an example in which the battery voltage VB is supplied to the upstream terminal of the solenoid 102a of the port injector 102 via the power terminal P3, the power supply line 22, and the output terminal P12 of the electronic control device 10 has been shown. . However, the method for supplying voltage to the solenoid 102a is not limited to the battery voltage VB, and an on-board battery (BATT) or a voltage (IG) supplied from the on-board battery by an ignition switch can be adopted.

DESCRIPTION OF SYMBOLS 10 ... Electronic control unit, 20 ... Boosting circuit part, 21 ... Control part, 22, 23, 104, 105 ... Power supply line, 24, 106 ... Connection point, 100 ... Injector, 101 ... Direct injection injector, 102 ... Port injection Injector, 101a, 102a ... Solenoid, 103 ... Other electronic control unit (other ECU), 103a ... Navi ECU, 103b ... Air conditioner ECU, 103c ... Meter ECU, C1 ... Capacitor, D1, D2, D3, D4, D5 ... Diode P1, P2, P3 ... output terminal, P4 ... power supply terminal, Q1 ... charge switch, Q2 ... peak current switch, Q3 ... constant current switch, Q4, Q5 ... drive switch, Q6 ... supply switch, Q7 ... discharge switch, R1 , R2, R3 ... Resistance

Claims (4)

A step-up circuit unit (20) that receives a voltage supplied from a DC power supply and outputs an output voltage according to a target voltage;
Fuel injection is performed by a direct injection injector (101) that injects fuel into the combustion chamber of the internal combustion engine and a port injection injector (102) that injects fuel into the intake port of the internal combustion engine in accordance with the driving state of the vehicle acquired from the outside. A control unit (21) for controlling, setting the target voltage, and controlling the operation of the booster circuit unit according to the set target voltage;
A power supply line (23) for supplying the output voltage to another device (103) which operates by being supplied with a voltage from the DC power supply;
A power supply switch (Q6) provided in the power supply line,
The controller is
A first target voltage for injecting fuel from the direct injection injector is set as the target voltage in a drive period from when the internal combustion engine is started to when a request to stop the internal combustion engine is acquired, and the power supply switch Turn off
In at least a part of the stop period of the internal combustion engine, a second target voltage that is lower than the first target voltage and that allows the other device to stably operate is set as the target voltage, and the output voltage is An electronic control unit that turns on the power supply switch when the second target voltage is reached.   The control unit sets the second target voltage as the target voltage during cranking for starting the internal combustion engine in the stop period, and the port among the direct injector and the port injector The electronic control unit according to claim 1, wherein control is performed so that fuel is injected only from an injector. A discharge switch (Q7) provided between a connection point between the booster circuit unit and the power supply line and the ground;
When the stop request is acquired, the control unit sets the second target voltage as the target voltage or stops the operation of the booster circuit unit, and the output voltage becomes equal to or lower than the second target voltage. The electronic control device according to claim 1 or 2, wherein the discharge switch is turned on. A discharge switch (Q7) provided between a connection point between the booster circuit unit and the power supply line and the ground;
When the ignition switch OFF signal is acquired, the control unit sets the second target voltage as the target voltage or stops the operation of the booster circuit unit before cutting off the voltage supply from the DC power supply. The electronic control device according to claim 1 or 2, wherein the discharge switch is turned on so that the output voltage is equal to or lower than the second target voltage.

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