JP4104498B2 - Piezo actuator drive circuit - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a piezoelectric actuator drive circuit.
[0002]
[Prior art]
The piezo actuator uses a piezoelectric action of a piezoelectric material such as PZT, and is applied to, for example, a fuel injection device of an internal combustion engine and used as a means for switching between fuel injection and its stop in a fuel injection injector. Things are known. The piezo actuator has a capacitor structure in which piezoelectric layers and electrode layers made of a piezoelectric material are alternately stacked, and expands by charging and discharges when contracting. This is an actuator that is energized only when the piezo stack is extended and contracted.
[0003]
The piezo actuator drive circuit switches the operation state of the piezo actuator between expansion and contraction by driving by charging or discharging, and a typical one having the following configuration is known. A first energization path connecting the power source and the piezo actuator via an inductor and a second energization path linking the inductor and the piezo actuator bypassing the capacitor are provided as means for adjusting the current. A charge switch for connecting / disconnecting one energization path and a discharge switch for connecting / disconnecting the second energization path are provided. When the piezo actuator is driven to charge, by repeatedly turning on and off the charging switch, a charging current that gradually increases during the on period of the charging switch is caused to flow through the first energization path, and gradually decreases by turning back at the peak current during the off period of the charging switch. A charging current is passed through the second energization path. Charging proceeds in a so-called step-down chopper method. During discharge driving of the piezo actuator, a discharge current that gradually increases during the ON period of the discharge switch is caused to flow through the second energization path by repeating ON / OFF of the discharge switch, and a discharge current that gradually decreases by returning to the peak current during the OFF period of the discharge switch. It flows in the first energization path.
[0004]
In Patent Document 1 below, the switch control means for controlling the charging switch and the like is set so that charging is terminated when the on-period of the charging switch is constant and the elapsed time from the start of driving reaches a predetermined time. There is something. This technique is intended to prevent the capacitance of the piezo actuator from fluctuating due to temperature fluctuations and the energy stored in the piezo actuator from fluctuating due to charging.
[0005]
[Patent Document 1]
JP 2002-136156 A
[0006]
[Problems to be solved by the invention]
However, the technique of Patent Document 1 is not always sufficient when the actual vehicle is used in a severe temperature environment and the capacity variation of the piezoelectric actuator is too large. In other words, in the step-down chopper circuit configuration, the difference between the output voltage of the power supply and the voltage between the terminals of the piezo actuator defines the charging speed. For example, if the capacity becomes too small, the voltage between the terminals of the piezo actuator is considerably high from the beginning of charging. As a result, the current increases and a sufficient current cannot flow to the piezo actuator.
[0007]
The present invention has been made in view of the above circumstances, and an object thereof is to provide a piezo actuator drive circuit with good charge energy controllability.
[0008]
[Means for Solving the Problems]
  According to the first aspect of the present invention, there is provided a drive circuit for driving a piezo actuator whose operation state is switched by driving by charging or discharging, and a first energization path that connects a power source and the piezo actuator via an inductor. A second energization path that bypasses the power supply and connects the inductor and the piezo actuator, a charge switch that connects and disconnects the first energization path, and controls the charge switch, and when the piezo actuator is driven to charge, By repeatedly turning on and off the charging switch, a charging current that gradually increases during the ON period of the charging switch is caused to flow through the first energization path, and a charging current that gradually decreases by turning back at a peak current during the OFF period of the charging switch In a piezo actuator drive circuit having switch control means for flowing in the energization path,
  A power source current flowing from the power source to the first energization path during the on period of the charging switch is detected, and based on the power source current,A discharge amount detecting means for detecting a discharge amount per unit time flowing through a non-common part of the first energization path with the power source as a supply source;
  SaidPer unit time flowing through a non-common part of the first energization path with the second energization path using the power source as the supply sourceTarget value output means for setting the target value of the discharge amount;
  The switch control means is configured to charge the piezo actuator during the charging drive.Flowing through a non-common part of the first energization path with the second energization path from the power sourceThe charging switch is controlled so that the detected value of the discharge amount per unit time becomes a target value, and the charging switch is fixed to be OFF when the elapsed time from the start of driving reaches a predetermined time. To do.
[0009]
Since the on-time of the charging switch is set so that the discharge amount per unit time from the power source becomes the target value, the current to the piezo actuator is sufficient regardless of variations in the piezo actuator capacity, etc. Will be charged properly.
[0010]
  In addition, a change in charging energy accumulated in the piezo actuator is obtained based on a charge amount per unit time using a piezo actuator that passes through the piezo actuator and flows through a portion common to the first and second energization paths as a supply destination. Then, it is difficult to obtain with high accuracy because the voltage between the terminals of the piezo actuator changes due to charging, but the output voltage of the power supply is almost constant, so the change in the charging energy to the piezo actuator is the unit of the power supply. According to the present invention obtained based on the amount of discharge per hour, it can be obtained relatively easily with high accuracy.Rube able to. Therefore, the piezo actuator can be charged to the target energy with high accuracy only by ending the charging drive at the elapse of a predetermined time.
[0011]
  In the second aspect of the invention, in the configuration of the first aspect of the invention,,
  And voltage detection means for detecting the output voltage of the power supply,
  Target value correcting means for correcting the target value so that the target value becomes lower as the detected value of the output voltage of the power source becomes higher is provided.
[0012]
The power supplied from the power source is the product of the output voltage and current of the power source. By lowering the target value of the current as the detected value of the output voltage of the power source is higher, the charging process of the piezo actuator and fluctuations in the reached energy can be suppressed.
[0013]
  In the invention according to claim 3, in the configuration of the invention according to claim 1 or 2,,
  An averaging means for integrating the detected current value and averaging the detected current value in the integration period is provided.
[0014]
By averaging the current in each ON period of the charge switch, a representative value of the current can be given for each ON period of the charge switch.
[0015]
According to a fourth aspect of the present invention, in the configuration of the first to third aspects of the invention, the target value output means is a means for outputting a constant target value during the driving period.
[0016]
The integrated value of the discharge amount, that is, the amount charged in the piezo actuator changes linearly at a speed defined by the target value.
[0017]
According to a fifth aspect of the present invention, in the configuration of the first to third aspects of the invention, the target value output means is a means for switching the target value in accordance with an elapsed time from the start of driving.
[0018]
The integrated value of the discharge amount, that is, the amount charged to the piezo actuator changes at a speed defined by the profile of the target value over time. Accordingly, the behavior pattern of the piezo actuator can be freely set by setting the profile of the target value over time.
[0019]
According to a sixth aspect of the present invention, in the configuration of the first to fifth aspects of the invention, the switch control means compares the detected value with the threshold value using two values sandwiching the target value as threshold values. And a comparison means for binary determination of the magnitude, wherein a judgment output is generated when the detected value exceeds a large threshold value and when the detected value falls below a small threshold value. Comparing means having hysteresis for switching is provided, and based on the determination output, the charge switch is turned off when the detected value exceeds the large threshold value, and the detected value falls below the small threshold value. Set the charging switch to turn on.
[0020]
  Two thresholds across the target valuevalueIs set to a desired sandwiching width, a filter effect that excludes disturbance noise and the like can be exhibited, and a target charge amount can be controlled with high accuracy.
  In the invention of claim 7, in the structure of the invention of claims 1 to 6,The discharge amount detection means is a resistor that is provided in a non-common part of the first energization path with the second energization path and detects the power supply current.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
FIG. 1 shows a piezo actuator drive circuit of the present invention. The piezo actuator 2 to be driven by the piezo actuator drive circuit is mounted on, for example, an injector that injects fuel in an internal combustion engine. In the case of a configuration having an injector for each cylinder, the piezo actuators 2 are connected in parallel by the number of cylinders, and a switch for selecting a cylinder is provided in series corresponding to each piezo actuator 2 on a one-to-one basis. The cylinder selection switch is turned on for the piezo actuator 2 corresponding to the cylinder to be injected, and only the piezo actuator 2 is selectively driven. The piezo actuator drive circuit is externally supplied with drive signals that define the charge drive start time and the discharge drive start time of the piezo actuator 2. If the drive signal conforms to the internal combustion engine, the valve opening timing and the valve closing timing of the injector are defined, and the length thereof defines the injection time.
[0022]
The power source 1 is a DC-DC converter, which boosts the output voltage (for example, 12V) of the on-vehicle battery 11 and charges the buffer capacitor 12 with the boosted voltage. The buffer capacitor 12 outputs a voltage for charging the piezoelectric actuator 2. A buffer capacitor having a sufficiently large capacitance is used. The battery 11 and the buffer capacitor 12 are connected via a boosting inductor 13 and a diode 14. The buffer capacitor 12 is charged by turning on and off a switch 15 that bypasses the buffer capacitor 12 and the diode 14. The diode 14 is for preventing the buffer capacitor 12 from discharging.
[0023]
A first energization path 31 connecting the buffer capacitor 12 and the piezo actuator 2 via the inductor 301 is provided. The first energization path 31 further includes a first energization path between the buffer capacitor 1 and the inductor 301 in series therewith. One switching element 4a is interposed. The first switching element 4a is composed of a MOSFET, and a parasitic diode (hereinafter referred to as a first parasitic diode) 41a has a voltage between terminals of the buffer capacitor 12 (hereinafter referred to as a buffer capacitor voltage as appropriate) to be reverse biased. Connected to.
[0024]
Further, the inductor 301 and the piezoelectric actuator 2 are connected by the second energization path 32. The energization path 32 has a second switching element 4b connected to the midpoint of connection between the inductor 301 and the first switching element 4a. The second energization path 32 bypasses the power source 1 and the first switching element 4a to form a closed circuit passing through the inductor 301, the piezo actuator 2 and the second switching element 4b. The second switching element 4b is also composed of a MOSFET, and its parasitic diode (hereinafter referred to as second parasitic diode) 41b is connected so that the buffer capacitor voltage is reverse-biased.
[0025]
Control signals are input to the respective gates of the switching elements 4a and 4b. When the switching elements 4a and 4b are turned on and off, a current (hereinafter referred to as a piezo actuator current as appropriate) is supplied to or supplied from the piezo actuator 2. To adjust). The switching element 4a is for driving the piezoelectric actuator 2 to be charged, and is hereinafter referred to as a charging switch 4a as appropriate. The switching element 4b is for discharge driving of the piezo actuator 2, and is hereinafter referred to as a discharge switch 4b as appropriate.
[0026]
Between the buffer capacitor 12 and the ground, a resistor 51 having a low resistance value (for example, 0.01Ω) as a discharge amount detecting means is provided. Based on the voltage between the terminals, a current that is a discharge amount per unit time flowing through the first energization path 31 using the buffer capacitor 12 as a supply source (hereinafter referred to as a buffer capacitor current as appropriate) is detected.
[0027]
A voltage between the terminals of the resistor 51 (hereinafter referred to as a current detection signal as appropriate) as a buffer capacitor current detection signal is input to the operational amplifier 521. The operational amplifier 521 constitutes an averaging circuit 52 that is an averaging means together with the resistor 522 and the capacitor 523. The resistor 522 and the capacitor 523 are an integration circuit, and an output signal of the operational amplifier 521 proportional to the buffer capacitor current is integrated. Hereinafter, the voltage between the terminals of the capacitor 523, that is, the output of the integrating circuit is referred to as an average signal.
[0028]
The average signal from the averaging circuit 52 is supplied to the control of the charging switch 4a in the switch control circuit 7 which is a switch control means. The switch control circuit 7 controls the charge switch 4a and the discharge switch 4b. However, for convenience of explanation, the circuit portion for controlling the discharge switch 4b is not shown.
[0029]
In the circuit portion for controlling the charge switch 4a of the switch control circuit 7, the comparator 71, resistors 72 and 73, the AND gate 74, and the one-shot circuit 75 constitute a circuit portion for controlling the charge switch 4a. The averaged signal is input to the (−) input terminal of the comparator 71. The output signal of the reference voltage generation circuit 61 serving as target value output means is input to the (+) input terminal of the comparator 71 via the resistor 72. The reference voltage generation circuit 61 generates a constant reference voltage. The input voltage at the (+) input terminal of the comparator 71 is subjected to hysteresis by the resistor 72 and the resistor 73 connected between the (+) input terminal and the output terminal of the comparator 71. If the average signal is sufficiently low, the logic output of the comparator 71 is “1” level. If the magnitude of the average signal exceeds the reference voltage + hysteresis, which is the threshold value on the large side, the comparator 71 As the logic output becomes “0” level, the input voltage at the (+) input terminal decreases to the reference voltage minus hysteresis which is the threshold value on the small side. On the other hand, when the magnitude of the average signal is lower than the reference voltage-hysteresis from this state, the logical output of the comparator 71 becomes “1” level and the input voltage at the (+) input terminal becomes the reference voltage + Increases to hysteresis.
[0030]
The logic output of the comparator 71 is input to an AND gate 74 that generates an input signal to the driver circuit 8 of the charge switch 4a. The driver circuit 8 turns on the charge switch 4a when the logic output of the AND gate 74 is at "1" level. To do. In addition to the output signal of the comparator 71, the output signal of the one-shot circuit 75 is input to the AND gate 74. The one-shot circuit 75 outputs a pulse signal having a fixed length (150 μsec) when an external drive signal is triggered at a rising edge. Therefore, when the drive signal rises to the “1” level, the charging switch 4a is switched on and off based on the magnitude of the averaged signal for the period of the certain length immediately after that. When the pulse signal is not output, the charging switch 4a is fixed off. That is, the pulse signal defines the length of the charging period of the piezo actuator 2.
[0031]
FIG. 2 is a timing chart showing the operation of each part of the piezo actuator drive circuit when the piezo actuator 2 is extended, that is, during charging. The charge switch 4a and the discharge switch 4b are off. The piezo actuator voltage is 0V and no energy is accumulated. Here, when the drive signal rises to the “1” level, the one-shot circuit 75 is triggered to output a pulse signal that defines the charging period. The average signal from the averaging circuit 52 is 0V, and the logical output of the comparator 71 is at “1” level. Accordingly, the charging switch 4 a is turned on, and charging of the piezo actuator 2 is started using the first energization path 31. The buffer capacitor current and the piezoactuator current rise, and as the charging proceeds, the piezo actuator voltage rises. As a result, the drive power also increases.
[0032]
On the other hand, as the buffer capacitor current flows, the averaged signal also increases. When the average signal exceeds the reference voltage + hysteresis, the logic output of the comparator 71 changes to “0” level and the charge switch 4a is turned off. However, the energy stored in the inductor 301 causes the second parasitic diode The gradually decreasing flywheel current continues to flow to the piezo actuator 2 using the second energization path 32 passing through 41b. At this time, the driving power gradually decreases. In addition, no current flows through the buffer capacitor 12 provided in a non-common part of the first energization path 31 with the first energization path 32. As a result, the capacitor 523 of the averaging circuit 52 starts discharging, and the averaged signal gradually decreases at a speed corresponding to the time constant of the integrating circuit.
[0033]
When the magnitude of the average signal falls below the reference voltage-hysteresis, the logic output of the comparator 71a becomes “1” level again, and the charge switch 4a is turned on. This is repeated. Therefore, the averaged signal is maintained substantially constant. The average of the buffer capacitor current at this time is defined by the reference voltage output from the reference voltage generation circuit 61, and the reference voltage generation circuit 61 outputs the target value of the average value of the buffer capacitor current during the ON period of the charge switch 4a. Will be.
[0034]
Since the average signal is an average of the buffer capacitor current that changes during the ON period of the charge switch 4a, by making it within the range of reference voltage-hysteresis and reference voltage + hysteresis, The buffer capacitor current changes at a substantially constant value. As a result, the charge supplied from the buffer capacitor 12 rises substantially in proportion to the elapsed time from the start of charging. On the other hand, the buffer capacitor voltage is relatively constant. Therefore, the accumulated energy of the piezo actuator 2 given as an integrated value of the electric power supplied from the buffer capacitor 12 increases substantially in proportion to the elapsed time from the start of charging, that is, the elapsed time after the drive signal is output.
[0035]
When the pulse signal from the one-shot circuit 75 is in a non-output state and the input signal of the AND gate 74 becomes “0” level, the charging switch 4a is fixed to OFF and the charging of the piezo actuator 2 is completed.
[0036]
As described above, the accumulated energy of the piezo actuator 2 (hereinafter referred to as “charge energy” as appropriate) increases in direct proportion to the elapsed time from the start of charging. The process that energy follows, that is, the charging process is uniform. Further, after a predetermined time from the start of charging, the stored energy when the charging switch 4a is fixed to OFF, that is, when the charging is completed can be made constant.
[0037]
Thus, according to this piezo actuator drive circuit, the charging process of the piezo actuator 2 is uniform, and the final reached energy is also constant. Variations in the behavior (extension) of the piezoelectric actuator 2 can be reduced. Thereby, for example, the injection timing and the injection amount can be made constant.
[0038]
Since the on-period of the charging switch 4a is set so that the average value of the buffer capacitor current during the on-period is a target value defined by the reference voltage, the piezo actuator 2 is not affected by variations in capacity, etc. A sufficient current flows to the piezo actuator 2 and charging is performed properly.
[0039]
The change in the accumulated energy of the piezo actuator 2 is represented by the product of the piezo actuator current and the piezo actuator voltage that flow through the piezo actuator 2 and flows through the common part of the first and second energization paths 31 and 32. If this is obtained, it is difficult to obtain with high accuracy since the piezoelectric actuator voltage changes due to charging. On the other hand, the change in the stored energy of the piezo actuator 2 can also be expressed by the product of the buffer capacitor current and the buffer capacitor voltage. Here, the buffer capacitor voltage is substantially constant. Therefore, when the change in the charging energy of the piezo actuator 2 is determined based on the amount of discharge per unit time from the buffer capacitor 12 as in this piezo actuator drive circuit, it can be obtained relatively easily with high accuracy. Further, in the present embodiment, utilizing the fact that the buffer capacitor voltage that defines the drive power is substantially constant, the change in charging energy is determined based on the buffer capacitor current as the discharge amount per unit time. It is simpler.
[0040]
The discharge drive for the piezo actuator 2 is performed by turning on and off the discharge switch 4b. That is, a discharge current that gradually increases during the ON period of the discharge switch 4b is caused to flow through the second energization path 32, and during the OFF period of the discharge switch 4b, a discharge current that gradually decreases by turning back at the peak current due to the flywheel action. Flow in path 31. This is repeated, and the accumulated energy of the piezo actuator 2 is recovered in the buffer capacitor 12. Here, the timing for switching the discharge switch 4b from on to off is the time when the current flowing through the piezo actuator 2 reaches the upper threshold value corresponding to the peak current, and the timing for switching from the off to on is the piezo actuator 2 When the current flowing through reaches the lower threshold. Accordingly, the discharge switch 4b may be switched on and off by comparing the discharge current detection signal with the reference voltage ± hysteresis by a comparator having hysteresis as controlled by the charge switch 4a. Various known methods can be used to complete the discharge period. For example, a piezo actuator voltage is detected, and when it becomes substantially zero, it is determined that the discharge period is complete.
[0041]
(Second Embodiment)
FIG. 3 shows a piezoelectric actuator drive circuit according to a second embodiment of the present invention. The basic structure of this piezo actuator drive circuit is the same as that of the first embodiment. In the figure, the same reference numerals are given to the parts that operate in the same way as in the first embodiment, and the differences from the first embodiment. The explanation will be focused on.
[0042]
In this piezo actuator drive circuit, two resistors 621 and 622 connected in series are provided between the positive terminal of the buffer capacitor 12 and the ground, and the buffer capacitor voltage is divided. Resistors 621 and 622 are of high resistance. For example, the resistor 621 is 900 kΩ and the resistor 622 is 100 kΩ. Resistors 621 and 622 together with a buffer 623 that receives the divided voltage constitute a voltage detection circuit 62 that is a voltage detection means for detecting a buffer capacitor voltage. The output of the buffer 623 is used to correct the reference voltage by the reference voltage correction circuit 63 as target value correction means (hereinafter, the output signal of the buffer 623 will be referred to as a voltage detection signal as appropriate).
[0043]
The reference voltage correction circuit 63 includes an operational amplifier 631 and resistors 632, 633, and 634. The reference voltage from the reference voltage generation circuit 61 is input to the (+) input terminal of the operational amplifier 631 through the first resistor 632. The voltage detection signal from the voltage detection circuit 62 is input to the (−) input terminal of the operational amplifier 71 a of the reference voltage correction circuit 63 via the second resistor 633. The third resistor 634 is connected between the (−) input terminal and the output terminal, and negative feedback is applied. Therefore, the output signal of the operational amplifier 631 as the reference voltage input to the (+) input terminal of the comparator 71 via the resistor 72 is lower than the reference voltage from the reference voltage generation circuit 61 according to the voltage detection signal. Will be corrected. The sensitivity of negative feedback is defined by the ratio of the resistance values of the resistors 633 and 634. Hereinafter, the output signal of the operational amplifier 631 of the reference voltage correction circuit 63 will be referred to as a current command signal).
[0044]
As a result, when the buffer capacitor voltage increases, the negative feedback amount of the operational amplifier 631 of the reference voltage correction circuit 63 increases, and the current command signal compared with the average signal by the comparator 71 decreases, and the average current of the buffer capacitor 12 decreases. Is also suppressed to a low level. On the other hand, when the buffer capacitor voltage decreases, the negative feedback amount of the operational amplifier 631 is suppressed, the current command signal becomes close to the reference voltage output from the reference voltage generation circuit 61, and the average current of the buffer capacitor 12 is also set higher. The
[0045]
FIG. 4 shows an example of how the accumulated energy (target energy value) reached at the completion of the charging period changes when the buffer capacitor voltage is changed in the piezoelectric actuator of the first embodiment. Thus, the higher the buffer capacitor voltage, the higher the target energy value, and the lower the buffer capacitor voltage, the lower the target energy value. This is because the drive power output from the buffer capacitor 12 is proportional to the buffer capacitor voltage. FIG. 5 shows a result of measuring how the charging energy changes when the reference voltage is changed. The charging energy decreases as the reference voltage is reduced. This is because when the reference voltage is reduced, the timing at which the charging switch 4a is turned off shifts to the side where the average signal is low, and the average value of the buffer capacitor current becomes small.
[0046]
According to the present embodiment, as shown in FIG. 6, the voltage detection circuit 62 and the reference voltage correction circuit 63 provide a current command defined by the magnitude of the current command signal with respect to an increase in the buffer capacitor voltage (power supply voltage). A negative feedback characteristic is provided in which the value decreases, and the current command value is automatically adjusted according to the buffer capacitor voltage. As a result, the charging process is made more uniform, and the energy error at the completion of charging can be reduced.
[0047]
Further, since the average value of the buffer capacitor current can be changed by changing the current command value as described above, the charging energy may be adjusted by changing the reference voltage. For example, in a common rail type fuel injection device, the injector operates the common rail fuel pressure (common rail pressure) in one direction on the valve member for switching the opening and closing of the common actuator. Some are arranged so as to act in the determination direction. The valve member or the like moves back and forth by switching between the charge drive and the discharge drive of the piezoelectric actuator. In such a fuel injection device, the common rail pressure is adjusted in accordance with the operating state, and the fuel injection pressure is adjusted. However, the operation characteristics of the piezo actuator change depending on the common rail pressure. By changing the reference voltage according to the common rail pressure, the influence of the common rail pressure can be offset and the behavior of the valve member can be made uniform. FIG. 7 shows an example of the correspondence relationship between the reference voltage and the charging energy.
[0048]
Further, by making the length of the pulse signal output from the one-shot circuit 75 together with the reference voltage variable, the charging process can be changed while making the charging energy substantially constant. FIG. 8 shows an example of the charging process when the reference voltage and the length of the pulse signal from the one-shot circuit 75 (charging time) are changed. In the figure, for the charging energy, the time on the horizontal axis is the elapsed time from the start of charging, and the graph line shows the charging energy profile within the charging time. As for the reference voltage, the time on the horizontal axis is the charging time, and the graph line shows the relationship between the charging time and the reference voltage. The reference voltage and the charging time are set so that the product of both is substantially the same. As a result, the energy charged during the charging period is constant, and the charging process can be made different. In this case, if the reference voltage is reduced and the charging time is increased, the rate of increase in charging energy is reduced. That is, the rise of the operation (extension) of the piezo actuator becomes gradual. Thereby, in the example of the fuel injection device, the injection rate can be controlled, and the optimum fuel injection according to the operation state can be realized.
[0049]
Note that the lengths of the reference voltage and the pulse signal may be changed in stages, or may be continuously variable. By setting the reference voltage and the charging time so that the product of both is substantially the same, it is possible to change the energy aging profile while keeping the charging energy constant.
[0050]
(Third embodiment)
FIG. 9 shows a piezo actuator drive circuit according to the third embodiment of the present invention. The basic structure of this piezo actuator drive circuit is the same as that of the first embodiment. In the figure, the same reference numerals are given to the parts that operate in the same way as in the first embodiment, and the differences from the first embodiment. The explanation will be focused on.
[0051]
In this piezo actuator drive circuit, the reference voltage generation circuit 61A can output the first and second reference voltages with a configuration in which the reference voltage is variable in two stages (the first reference voltage is low, the second reference voltage is The reference voltage is high). The reference voltage generation circuit 61A triggers the rising of the drive signal to the “1” level, outputs the first reference voltage for the first fixed period (initial charge) from the trigger point, and the next period (mid charge period) Outputs the second reference voltage, and outputs the first reference voltage during the last period (end of charge).
[0052]
FIG. 10 is a timing chart showing the operation of each part of the piezo actuator drive circuit when the piezo actuator 2 is extended, that is, during charging. The basic operation is the same as that of the first embodiment, but since the buffer capacitor current is controlled by the first reference voltage in the initial stage of charging, the charging energy of the piezo actuator 2 rises slowly and is in the middle of charging. When switched to the second reference voltage, the charging energy of the piezo actuator 2 increases at a rising speed. At the end of charging, the voltage returns to the first reference voltage again, and the charging energy of the piezo actuator 2 slows down and converges toward the final value (target energy) of the charging energy.
[0053]
In this embodiment, the reference voltage is described as being output in two stages, but it goes without saying that the reference voltage may be three or more. Further, the reference voltage may be continuously variable. Further, the output pattern of the reference voltage is not only increased in the middle of the charging period, but can also be appropriately set according to the required operating characteristics.
[0054]
In each of the embodiments described above, the buffer capacitor current detection signal is input to the averaging circuit. However, the drive power is calculated by multiplying the buffer capacitor voltage detection signal and the buffer capacitor current detection signal. The output circuit of the driving power may be provided as an amount of discharge per unit time of the buffer capacitor and input to the averaging circuit. In this case, as in the second embodiment, the influence of the fluctuation of the buffer capacitor voltage can be avoided and the charging energy of the piezo actuator can be made constant with higher accuracy.
[0055]
In the above embodiments, the buffer capacitor is charged with the voltage obtained by boosting the battery voltage with the DC-DC converter. However, the piezo actuator 2 is directly driven from the capacitor 12 charged with the battery voltage. The present invention can also be applied.
[Brief description of the drawings]
FIG. 1 is a circuit diagram of a first piezoelectric actuator drive circuit according to the present invention.
FIG. 2 is a timing chart showing an operating state of the piezo actuator drive circuit.
FIG. 3 is a circuit diagram of a second piezo actuator drive circuit according to the present invention.
FIG. 4 is a first graph illustrating the operation of the piezo actuator drive circuit.
FIG. 5 is a second graph illustrating the operation of the piezo actuator drive circuit.
FIG. 6 is a third graph for explaining the operation of the piezo actuator drive circuit.
FIG. 7 is a graph for explaining the operation of a modification of the piezo actuator drive circuit.
FIG. 8 is a graph for explaining the operation of another modified example of the piezo actuator driving circuit.
FIG. 9 is a circuit diagram of a third piezo actuator drive circuit according to the present invention.
FIG. 10 is a timing chart showing an operating state of the piezo actuator drive circuit.
[Explanation of symbols]
1 Power supply
11 battery
12 capacitors
2 Piezo actuator
31 First energization path
32 Second energization path
301 inductor
4a Charge switch
4b Discharge switch
51 Resistor (Discharge detection means)
52 Averaging circuit (averaging means)
61, 61A Reference voltage generation circuit (target value output means)
62 Voltage detection circuit (voltage detection means)
63 Reference voltage correction circuit (target value correction means)
7 Switch control circuit (switch control means)
71 Comparator (comparison means)

Claims (7)

A drive circuit for driving a piezo actuator whose operating state is switched by driving by charging or discharging, a first energization path connecting a power source and the piezo actuator via an inductor, and bypassing the power source and the inductor A second energization path connecting the first and second energization paths, a charge switch connecting and disconnecting the first energization path, and controlling the charge switch, and by repeatedly turning on and off the charge switch when charging the piezoelectric actuator, Switch control means for causing a charging current that gradually increases during an ON period of the charging switch to flow through the first energization path, and a charging current that is gradually reduced by turning back with a peak current during the OFF period of the charging switch; In a piezoelectric actuator drive circuit having
A power supply current flowing from the power supply to the first energization path during the ON period of the charging switch is detected, and based on the power supply current, the second of the first energization paths using the power supply as a supply source. A discharge amount detecting means for detecting a discharge amount per unit time flowing through a non-common part with the energization path;
Target value output means for setting a target value of a discharge amount per unit time flowing through a non-common part of the first energization path with the second energization path from the power source ;
The switch control means detects a discharge amount per unit time flowing through a non-common part of the first energization path with the second energization path when the piezoelectric actuator is charged. A piezo actuator drive circuit configured to control the charge switch so that becomes a target value and to fix the charge switch to OFF when an elapsed time from the start of driving reaches a predetermined time set in advance. The piezoelectric actuator drive circuit according to claim 1 ,
And voltage detection means for detecting the output voltage of the power supply,
A piezo actuator driving circuit comprising target value correcting means for correcting the target value so that the target value becomes lower as the detected value of the output voltage of the power source becomes higher. In the piezo actuator drive circuit according to claim 1 or 2 ,
A piezoelectric actuator drive circuit comprising an averaging means for integrating the detected current values and averaging the detected current values in the integration period.   4. The piezo actuator drive circuit according to claim 1, wherein the target value output means outputs a constant target value during a drive period.   4. A piezo actuator drive circuit according to claim 1, wherein the target value output means switches the target value in accordance with an elapsed time from the start of driving.   6. The piezo actuator driving circuit according to claim 1, wherein the switch control means compares the detected value with the threshold value using two values sandwiching the target value as a threshold value, and compares the detected value with the magnitude. Comparing means for binary determination, wherein a hysteresis output is switched between when the detected value exceeds a large threshold value and when the detected value falls below a small threshold value. Comparing means having a charging switch is turned off when the detected value exceeds a large threshold value and charged when the detected value falls below a small threshold value based on the determination output. Piezo actuator drive circuit set to switch on. 7. The piezo actuator drive circuit according to claim 1, wherein the discharge amount detection means is provided in a non-common part of the first energization path with a second energization path to detect the power supply current. Piezo actuator drive circuit that is a resistor.

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