JP5426622B2 - Boost control device for fuel injection valve - Google Patents

Description

  The present invention relates to a boost control device for a fuel injection valve that controls boosting of a voltage applied to the fuel injection valve in order to drive an electromagnetic fuel injection valve provided in an internal combustion engine or the like.

  As a conventional boost control device of this type, for example, one disclosed in Patent Document 1 is known. This boost control device includes a charging circuit that boosts the voltage of a power supply and a capacitor that stores the boosted voltage, and the fuel injection valve is driven by applying the voltage of the capacitor to the fuel injection valve.

  Further, in this boost control device, when continuously driving the fuel injection valve, the power supply voltage and the capacitor voltage are detected, and the time from the detected value until the capacitor reaches the upper limit value of overcharge is determined. Based on this time, the charging start timing for the capacitor is set so that the capacitor reaches the upper limit of overcharging immediately before the first drive of the fuel injection valve is started.

Japanese Patent No. 4609903

  However, this conventional step-up control device needs to detect both the power supply voltage and the capacitor voltage in order to set the charging start timing for the capacitor. Moreover, since the charging start timing for the capacitor is set in advance based on the detected values of both voltages, the voltage actually charged in the capacitor is likely to be excessive or insufficient. For this reason, when the voltage charged in the capacitor is excessive, the amount of heat generation increases and energy is wasted. Conversely, when the voltage charged in the capacitor is insufficient, the operation of the fuel injection valve is hindered.

  In addition, it is also known to use a current detection circuit together to monitor overcurrent in the capacitor, but in that case, the manufacturing cost increases and the amount of heat generated by the heat generation of the current detection circuit also increases. Resulting in.

  The present invention has been made to solve such a problem, and can use the detected value of the voltage of the capacitor to boost the voltage applied to the fuel injection valve without excess or deficiency. An object of the present invention is to provide a boost control device for a fuel injection valve that can suppress heat generation and save energy while ensuring an appropriate operation.

In order to achieve this object, the invention according to claim 1 is a boost control device for a fuel injection valve that controls boosting of a voltage applied to the fuel injection valve 4 in order to drive the electromagnetic fuel injection valve 4. The booster circuit 20 for boosting the voltage (battery voltage VB) of the power source (battery 11 in the embodiment (hereinafter the same in this section)) and the boosted voltage to be applied to the fuel injection valve 4 The capacitor 25 to be charged with voltage, the voltage detection means (voltage detection circuit 51 , CPU 40 ) for detecting the voltage of the capacitor 25 (capacitor voltage VC), and the booster circuit 20 when driving of the fuel injection valve 4 is started. to start the boosting operation, when during driving of the fuel injection valve 4, while continuing the boosting operation of the booster circuit 20, a non-driven in the fuel injection valve 4, the voltage of the detected capacitor 25 is predetermined When it is less than the lower limit value VREFL, to start the boosting operation of the booster circuit 20, a non-driven in the fuel injection valve 4, when the voltage of the capacitor 25 exceeds a predetermined upper limit value VREFH, the booster circuit 20 And a step-up operation control means (CPU 40, steps 5 to 9 in FIG. 4).

  According to this configuration, the voltage of the power supply is boosted by the booster circuit and charged to the capacitor. The boosted capacitor voltage is applied to the electromagnetic fuel injection valve, whereby the fuel injection valve is driven and fuel is injected.

Further, the boost operation of the booster circuit is started when the drive of the fuel injection valve is started, and the boost operation of the booster circuit is continued when the fuel injector is being driven . Furthermore, detects the capacitor voltage, in a non-driven fuel injection valve, the detected capacitor voltage sometimes becomes less than a predetermined lower limit value, the boosting operation of the booster circuit is started. As a result, a boosted voltage sufficient to drive the fuel injection valve can be ensured.

Further, in the non-driving in the fuel injection valve, the detected capacitor voltage sometimes becomes more than a predetermined upper limit value, the boosting operation of the booster circuit is stopped. Thereby, excessive boosting can be avoided reliably, so that heat generation can be suppressed, wasteful consumption of energy can be prevented, and energy saving can be achieved.

According to a second aspect of the present invention, in the step-up control device for a fuel injection valve according to the first aspect, the step-up circuit 20 includes a switching element (first switch 21, second switch) that controls the step-up operation by ON / OFF switching. The voltage detection means detects the voltage of the capacitor according to the timing at which the switching element is switched on / off during the boosting operation of the booster circuit 20 (steps 2 to 4 in FIG. 4). ) .

According to this configuration, the booster circuit has the switching element , and the boosting operation is controlled by switching ON / OFF of the switching element . Further, the voltage detection circuit detects the voltage of the capacitor according to the timing when the switching element is switched ON / OFF during the boosting operation of the boosting circuit. As described above, since the sampling of the capacitor voltage is performed at a unified and clear timing synchronized with the switching of the switching element , the capacitor voltage can be accurately read without being affected by the fluctuation of the capacitor voltage between the switching operations. .

According to a third aspect of the present invention, in the boost control device for a fuel injection valve according to the second aspect, the booster circuit 20 has a coil 23 connected to a power source, and the switching element (first switch 21) is The electric energy of the power source is stored in the coil 23 in the ON state, and the electric energy stored in the coil 23 is supplied to the capacitor 25 in the OFF state. During the step-up operation, the voltage of the capacitor is detected when the switching element is switched from the ON state to the OFF state (steps 2 to 4 in FIG. 4).
According to a fourth aspect of the present invention, in the boost control device for a fuel injection valve according to any one of the first to third aspects, the voltage detecting means has different timings during execution and stop of the boosting operation of the booster circuit 20. Thus, the capacitor voltage is detected (steps 2 to 4 in FIG. 4).
According to this configuration, the capacitor voltage detection timing by the voltage detection circuit is made different between when the boosting operation is being performed and when the boosting operation is being stopped, so that the capacitor voltage is stable during the boosting operation in which the capacitor voltage fluctuates. In any case where the boosting operation is stopped, the capacitor voltage can be read with high accuracy. Therefore, by using the capacitor voltage read with high accuracy as described above, it is possible to appropriately determine whether or not to execute the boosting operation, and to perform boosting control more appropriately. As a result, it is possible to omit the current detection circuit that has been conventionally provided to monitor the overcurrent of the capacitor, thereby reducing the manufacturing cost and suppressing heat generation.

It is a figure which shows a fuel injection valve roughly. It is a circuit diagram which shows the drive circuit which drives a fuel injection valve. 6 is a timing chart showing a boosting operation of the boosting circuit. It is a flowchart which shows a pressure | voltage rise control process. It is a timing chart which shows the operation example obtained by a pressure | voltage rise control process.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. A fuel injection valve (hereinafter referred to as “injector”) 4 shown in FIG. 1 is provided for each cylinder in a gasoline engine (hereinafter referred to as “engine”) (not shown), for example, and is used to directly inject fuel into each cylinder. It is what

  The injector 4 is of an electromagnetic type, is accommodated in a casing 5, and is fixed to an upper end portion of an electromagnet 6, a spring 7, an armature 8 disposed below the electromagnet 6, and the armature 8. It is comprised by the valve body 9 etc. which were integrally provided in the lower side. High pressure fuel is supplied to the injector 4 from a fuel supply device (not shown).

  The electromagnet 6 includes a yoke 6a and a coil 6b wound around the yoke 6a. A drive circuit 10 shown in FIG. 2 is connected to the coil 6b. The spring 7 is disposed between the yoke 6a and the armature 8 and biases the valve body 9 toward the valve closing side.

  The drive circuit 10 includes a booster circuit 20 for boosting the voltage of the battery 11 and an injector drive circuit 30 for applying a voltage to the coil 6 b and driving the injector 4. The operations of these circuits 20 and 30 are controlled by a CPU 40 described later. The battery 11 is charged using a generator (not shown) that uses an engine as a power source.

  The booster circuit 20 includes first and second switches 21 and 22, a coil 23, a diode 24, and a capacitor 25. The first switch 21 is composed of an N-channel FET, and its drain is connected to the output side of the coil 23 connected to the battery 11. The source and gate of the first switch 21 are connected to the ground and the CPU 40, respectively. When the first drive signal SD1 is input to the gate from the CPU 40, the first switch 21 is turned on and the drain-source is energized.

  The second switch 22 is also composed of an N-channel FET, and its drain is connected between the first switch 21 and the coil 23. The source and gate of the second switch 22 are connected to the input side of the capacitor 25 and the CPU 40, respectively. When the second drive signal SD2 is input to the gate from the CPU 40, the second switch 22 is turned on and the drain-source is energized.

  The diode 24 is provided in parallel with the second switch 22, the anode side thereof being connected to the drain of the second switch 22, and the cathode side being connected to the source of the second switch 22.

  In the booster circuit 20, the boosting operation is performed as shown in FIG. 3. First, the first drive signal SD1 is output and the first switch 21 is turned ON. As a result, when the voltage VB of the battery 11 (hereinafter referred to as “battery voltage”) VB is applied to the coil 23, the coil current IL flows through the coil 23 and electric energy is stored.

  From this state, the output of the first drive signal SD1 is stopped, the first switch 21 is turned OFF, and immediately after that, the second drive signal SD2 is output and the second switch 22 is turned ON. As a result, the electrical energy stored in the coil 23 is supplied to the capacitor 25 via the second switch 22 and stored. As a result, the coil current IL decreases and the voltage of the capacitor 25 (hereinafter referred to as “capacitor voltage”) VC increases.

  Thereafter, the output of the second drive signal SD2 is stopped, the second switch 22 is turned off, and immediately after that, the first drive signal SD1 is outputted and the first switch 21 is turned on, whereby electric energy is supplied to the coil 23. Is stored again. Thereafter, similarly, the boosting operation is performed by alternately switching the ON operation of one of the first and second switches 21 and 22 and the OFF operation of the other of the first and second switches 21 and 22 in synchronism with each other. Hereinafter, such boost control is referred to as “synchronous rectification control”. Note that tsmp1 to tsmp4 in FIG. 3 indicate the sampling timing of the capacitor voltage VC described later.

  The injector drive circuit 30 includes third to fifth switches 31 to 33 each formed of an N-channel FET, a Zener diode 34, and the like.

  The drain, source, and gate of the third switch 31 are connected to the booster circuit 20, one end of the coil 6b of the electromagnet 6, and the CPU 40, respectively. When the third drive signal SD3 is input from the CPU 40 to this gate, the third switch 31 is turned on and the drain-source is energized.

  The drain, source, and gate of the fourth switch 32 are connected to the battery 11, one end of the coil 6b, and the CPU 40, respectively. When the fourth drive signal SD4 is input from the CPU 40 to this gate, the fourth switch 32 is turned on, and the drain-source is energized.

  The drain, source, and gate of the fifth switch 33 are connected to the other end of the coil 6b, the ground, and the CPU 40, respectively. When the fifth drive signal SD5 is input from the CPU 40 to this gate, the fifth switch 33 is turned on and the drain-source is energized.

  The Zener diode 34 has an anode side connected to the ground and a cathode side connected to the other end of the coil 6b.

  With the above configuration, in this injector drive circuit 30, the third to fifth switches 31 to 33 are switched ON / OFF according to the third to fifth drive signals SD3 to SD5 from the CPU 40, and the coil 6b of the injector 4 is switched. The operation of the injector 4 is controlled by controlling the voltage application state.

  Specifically, when the third to fifth switches 31 to 33 are in the OFF state, the coil 6b of the injector 4 is not applied, and the drive current IAC does not flow to the coil 6b, so that the valve body 9 of the injector 4 is The injector 4 is positioned at the valve closing position (FIG. 1A) by the urging force of the spring 7, and the injector 4 is held in the valve closing state.

  When the third and fifth switches 31 and 33 are turned on from this state, the boosted capacitor voltage VC is applied to the coil 6b of the injector 4, so that a large drive current IAC flows through the coil 6b and the electromagnet 6 is excessive. Excited (overexcitation control). By this overexcitation, the armature 8 is attracted to the electromagnet 6 against the urging force of the spring 7, whereby the injector 4 is opened (FIG. 1B), and fuel is injected from the injector 4. Thus, when the injector 4 is driven, first, overexcitation control is performed, so that a sufficient magnetic force is secured to quickly open the injector 4 against high fuel pressure.

  After that, when the third switch 31 is turned off to finish the application of the capacitor voltage VC and the fourth switch 32 is turned on, the battery voltage VB is applied to the coil 6b of the injector 4. As a result, when the small drive current IAC flows through the coil 6b, the injector 4 is held in the valve open state, and fuel injection is continued (holding control). In this holding control, the battery voltage VB is intermittently applied, and the drive current IAC is controlled to a small value within a predetermined range.

  When the fourth and fifth switches 32 and 33 are turned off from this state, the application of the battery voltage VB is completed, and the valve body 9 is returned to the valve closing position by the biasing force of the spring 7 accordingly. Closes and fuel injection ends. Further, the current remaining in the coil 6b flows to the ground via the Zener diode 14, so that the electromagnet 6 is in a non-excited state.

  The booster circuit 20 is provided with a voltage detection circuit 51. The voltage detection circuit 51 detects the capacitor voltage VC and outputs a detection signal to the CPU 40. Further, a detection signal indicating the ON / OFF state is input to the CPU 40 from an ignition switch (not shown).

  The CPU 40 constitutes a microcomputer together with a RAM, a ROM, an I / O interface (all not shown), and the like. The CPU 40 controls ON / OFF of the first and second switches 21 and 22, and controls boosting control for controlling the boosting operation of the boosting circuit 20 and ON / OFF of the third to fifth switches 31 to 33. Thus, the injector 4 is driven to execute fuel injection control for controlling the fuel injection amount and fuel injection timing. In the embodiment, the CPU 40 corresponds to a step-up operation control unit and a voltage sampling unit.

  FIG. 4 is a flowchart showing the above-described boost control process. This process is repeatedly executed at a predetermined period ΔT (for example, 1 ms). In this process, first, in step 1 (illustrated as “S1”, the same applies hereinafter), it is determined whether or not the ignition switch is in an ON state. When this answer is NO, this processing is terminated as it is.

  If the answer to step 1 is YES and the ignition switch is in an ON state, it is determined whether or not the boost flag F_VCUP is “1” (step 2). As will be described later, the boost flag F_VCUP is set to “1” when the booster circuit 20 is performing a boost operation.

  If the answer to step 2 is YES and the boosting operation is being performed, it is determined whether or not it is immediately after the first drive signal SD1 changes from ON to OFF (step 3). When this answer is NO, this processing is terminated as it is.

  On the other hand, the answer to the above step 3 is YES, and this time is the timing immediately after the first drive signal SD1 is switched from ON to OFF, that is, the timing immediately before the second drive signal SD2 is switched from OFF to ON (timing in FIG. 3). When it corresponds to tsmp1 to tsmp4), the capacitor voltage VC detected by the voltage detection circuit 51 is sampled (step 4).

  On the other hand, if the answer to step 2 is NO and the step-up operation is not being performed, the process proceeds directly to step 4 to sample the capacitor voltage VC.

  In step 5 following step 4, it is determined whether or not the injector 4 is being driven. If the answer to this question is YES and the injector 4 is being driven, the boosting flag F_VCUP is set to “1” (step 6) to execute the boosting operation, and this process is terminated. Specifically, synchronous rectification control as shown in FIG. 3 is executed to boost the capacitor voltage VC.

  If the answer to step 5 is NO and the injector 4 is not being driven, it is determined whether or not the capacitor voltage VC sampled in step 4 is equal to or lower than the lower limit value VREFL (step 7). If the answer to this question is YES and the capacitor voltage VC decreases to the lower limit value VREFL or less while the injector 4 is not driven, the process proceeds to step 6 to increase the capacitor voltage VC, and the boosting operation is executed.

  On the other hand, when the answer to step 7 is NO, it is determined whether or not the capacitor voltage VC is equal to or higher than the upper limit value VREFHL (step 8). When this answer is YES, that is, when the capacitor voltage VC rises to the upper limit value VREFHL or more by the boosting operation while the injector 4 is not driven, the boost flag F_VCUP is set to “0” (step 9), The step-up operation is stopped and this process is terminated. Specifically, the boosting of the capacitor voltage VC is stopped by holding both the first and second switches 21 and 22 in the OFF state.

  On the other hand, if the answer to step 8 is NO, and VREFL <VC <VREFH when the injector 4 is not driven, this processing is terminated. That is, in this case, the execution state or stop state of the previous boosting operation is maintained.

  FIG. 5 shows an operation example obtained by the above-described boost control process. First, when driving of the injector 4 is started at the timing t1, the answer to step 5 in FIG. 4 is YES, the boost flag F_VCUP is set to “1”, and the boost operation is started. In this case, since overexcitation control using the capacitor voltage VC is performed at the initial stage of driving the injector 4, the drive current IAC supplied to the coil 6b of the injector 4 increases rapidly and the capacitor voltage VC decreases. .

  Thereafter, the overexcitation control is completed, and the drive current IAC is held in a smaller range by shifting to the hold control using the battery voltage VB (t2). During this holding control, the capacitor voltage VC increases by continuing the boosting operation.

  Further, the capacitor voltage VC further increases by continuing the boosting operation after the end of driving of the injector 4 (t3). When the capacitor voltage VC reaches the upper limit value VREFH (t4), the answer to step 8 in FIG. 4 is YES, whereby the boost flag F_VCUP is set to “0” and the boost operation is stopped.

  Thereafter, when the next drive of the injector 4 is started (t5), the boost flag F_VCUP is set to “1”, and the boost operation is started. The subsequent operation until the end of driving of the injector 4 (t5 to t7) is the same as in the case of t1 to t3 described above, and the boosting operation is continued during this time.

  Then, after the drive of the injector 4 is finished, when the capacitor voltage VC rises to the upper limit value VREFH (t8), the boost flag F_VCUP is set to “0” and the boost operation is stopped. Further, when the capacitor voltage VC decreases to the lower limit value VREFL as the boost operation is stopped (t9), the answer to step 7 in FIG. 4 becomes YES, so that the boost flag F_VCUP is set to “1”. The boosting operation is resumed.

  As described above, according to the present embodiment, when the injector 4 is being driven or when the injector 4 is not being driven and the detected capacitor voltage VC is equal to or lower than the predetermined lower limit value VREFL, Since the boosting operation is performed (steps 5 to 7 in FIG. 4), a boosted voltage sufficient to drive the injector 4 can be ensured.

  Further, when the injector 4 is not driven and the capacitor voltage VC is equal to or higher than the predetermined upper limit value VREFH, the boosting operation of the booster circuit 20 is stopped (steps 8 and 9), so that excessive boosting is reliably avoided. Thus, heat generation can be suppressed, wasteful consumption of power from the battery 11 can be prevented, and fuel consumption can be improved.

  Further, during the boosting operation of the booster circuit 20, the sampling of the capacitor voltage VC is performed immediately after the first drive signal SD1 that drives the first switch 21 is switched from ON to OFF, that is, the second switch 22 that drives the second switch 22. 2 Since the drive signal SD2 is performed at the timing (tsmp1 to tsmp4) immediately before the switch from OFF to ON (steps 2 to 4), the capacitor voltage VC is not affected by the fluctuation of the capacitor voltage VC between these timings. It can be read with high accuracy.

  Further, during the non-boosting operation of the booster circuit 20 in which the capacitor voltage VC is stable, the capacitor voltage VC is sampled at the execution period ΔT of the boosting control process of FIG. Similarly, VC can be read with high accuracy. Therefore, it is possible to appropriately determine whether or not to execute the boosting operation using the capacitor voltage VC read with high accuracy, and to perform the boosting control more appropriately. As a result, it is possible to omit the current detection circuit that has been conventionally provided to monitor the overcurrent of the capacitor, thereby reducing the manufacturing cost and suppressing heat generation.

  In addition, this invention can be implemented in various aspects, without being limited to the described embodiment. For example, in the embodiment, the second switch 22 is provided in the booster circuit 20, but a circuit in which the second switch 22 is omitted, that is, a circuit including the first switch and a diode may be used. Also with this configuration, the above-described effect according to the first aspect can be similarly obtained.

  The sampling timing of the capacitor voltage VC during the boosting operation is set immediately after the first switch 21 is switched from ON to OFF (immediately before the second switch 22 is switched from OFF to ON). Not limited to this, it may be set immediately after the second switch 22 is switched from ON to OFF (immediately before the first switch 21 is switched from OFF to ON).

  Further, in the embodiment, the sampling of the capacitor voltage VC during the non-boosting operation of the booster circuit 20 is performed every predetermined time which is the execution period of the boost control process. However, the crank angle of the engine is calculated and the predetermined crank You may go for every corner.

  In addition, the fuel injection valve of the embodiment is for a direct injection gasoline engine for a vehicle, but is not limited thereto, a port injection engine, a diesel engine, and an outboard where a crankshaft is arranged vertically. It may be used for various industrial internal combustion engines such as marine propulsion engine. In addition, it is possible to appropriately change the detailed configuration within the scope of the gist of the present invention.

4 Injector (fuel injection valve)
11 Battery (Power)
20 Booster Circuit 21 First Switch 22 Second Switch 23 Coil 25 Capacitor 40 CPU (Boosting Operation Control Unit, Voltage Sampling Unit)
51 Voltage detection circuit (voltage detection means)
VB battery voltage (power supply voltage)
VC capacitor voltage (capacitor voltage)
VREFH upper limit value VREFF lower limit value tsmp1 to 4 sampling timing (predetermined timing)
ΔT Predetermined period

Claims (4)

A boost control device for a fuel injection valve that controls boosting of a voltage applied to the fuel injection valve to drive an electromagnetic fuel injection valve,
A booster circuit for boosting the voltage of the power supply;
A capacitor to which the boosted voltage is charged for application to the fuel injector;
Voltage detecting means for detecting the voltage of the capacitor;
When the driving of the fuel injection valve is started, the to start the boosting operation of the booster circuit, when in the driving of the fuel injection valve, while continuing the boosting operation of the booster circuit, of the fuel injection valve in not driven, when the voltage of the detected capacitor is equal to or less than a predetermined lower limit value, to start the boosting operation of the boosting circuit, a non-drive in the fuel injection valve, the voltage of the capacitor is given when it is more than the upper limit value of the boost operation control means for stopping the boosting operation of the booster circuit,
A boost control device for a fuel injection valve, comprising: The step-up circuit has a switching element that controls step-up operation by ON / OFF switching,
2. The boost control device for a fuel injection valve according to claim 1, wherein the voltage detection unit detects the voltage of the capacitor in accordance with a timing when the switching element is turned on / off . The booster circuit has a coil connected to the power source;
The switching element is configured such that electrical energy of the power source is stored in the coil when in an ON state, and electrical energy stored in the coil is supplied to the capacitor when in an OFF state,
3. The fuel according to claim 2, wherein the voltage detection unit detects the voltage of the capacitor when the switching element is switched from an ON state to an OFF state during the boosting operation of the boosting circuit. Boost control device for injection valve. The fuel injection according to any one of claims 1 to 3, wherein the voltage detection unit detects the voltage of the capacitor at different timings during execution and stop of the boosting operation of the booster circuit. Boost control device for valves.

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