JP2018057203A - DC power converter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a DC power converter which can suppress variation of output voltage when reactor current becomes nearly 0A even if a tolerance of inductance value of the reactor or the like is fluctuated.SOLUTION: A DC power converter calculates value of voltage or current on the spot to be measured in a converter part 7, an integral value, a differential value, or a sensing value of an object parameter that is a changing amount. The DC power converter also calculates, on the assumption that current flow of a rectifier 4 is not controlled when turning off a switching element 3, an estimation value of the object parameter. The DC power converter performs estimation control changing on-off duty ratio D1 of the switching element 3 so that the sensing value of the object parameter comes close to the estimation value of the object parameter.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a DC power converter that converts DC power between an input electric wire and an output electric wire.

  Regarding the DC power converter as described above, a technique described in Patent Document 1 below is known. The DC power converter according to Patent Document 1 includes a first switching element and a second switching element connected in series, and a reactor connected to a connection point between the first switching element and the second switching element. In the technique of Patent Document 1, the first switching element and the second switching element are alternately turned on with a dead time interposed therebetween.

  As shown in FIG. 3 of Patent Document 1, when the current flowing through the reactor vibrates across 0 A, depending on whether the reactor current is positive or negative during the dead time period, The output voltage fluctuates because the current is switched through the antiparallel connection diode of the first switching element or the current flows through the antiparallel connection diode of the second switching element.

  In the technique of Patent Document 1, feedback control is performed to change the on / off duty ratio of the first and second switching elements so that the output voltage follows the target voltage. In order to suppress this, dead time compensation is performed. In the dead time compensation, an average current value of one cycle of the reactor current that should flow when there is no dead time is calculated, and based on the average current value, as shown in FIG. Judgment is made in which of the five current vibration positions, and the dead time compensation value for correcting the on / off duty ratio of each switching element is changed according to the determined classification and the average current value. It is configured to let you.

JP 2010-22136 A

  However, in the technique of Patent Document 1, as shown in FIG. 3 of Patent Document 1, only the classification 2 and the classification 4 need to change the dead time compensation value according to the average current value. The ratio of this area to the entire operation area is very small. Moreover, since the range of the classification 2 and the classification 4 changes with the amplitude of the reactor current, it is easily affected by the fluctuation of the inductance value. Therefore, in the technique of Patent Document 1 in which the dead time compensation value is set according to the calculated average current value, it is difficult to accurately determine this very small area in consideration of the tolerance of the inductance value of the reactor. Therefore, there is a problem that the dead-time compensation value cannot be set to an appropriate value at an appropriate timing by feedforward control, and the effect of suppressing fluctuations in output voltage depends on component variations and operating conditions.

  In addition, when a diode is used instead of one of the switching elements, a current discontinuous mode in which the reactor current does not flow at 0 A or less at a light load occurs, so that the output voltage fluctuates greatly when the load fluctuates. .

  Therefore, there is a demand for a DC power converter that can suppress fluctuations in the output voltage when the reactor current becomes close to 0 A, even if the tolerance of the inductance value of the reactor varies.

  A DC power converter according to the present invention is a DC power converter that converts DC power between an input electric wire and an output electric wire, and includes a reactor, a switching element, a diode, or a switching element for synchronous rectification that functions as a diode. A converter unit having at least one rectifier element and at least one output capacitor connected to the output wire; and a control unit that controls on / off of the switching element, the control unit being a voltage at a target location of the converter unit Or when calculating the sensing value of the target parameter that is a value, integral value, differential value, or change amount for the current, and assuming that the current flow of the rectifying element is not limited when the switching element is controlled to be off The estimated value of the target parameter is calculated, and the sensing value of the target parameter is As it approaches the estimated value of the parameter, and performs estimation control to change the on-off duty ratio of the switching element.

  According to the DC power converter according to the present invention, the sensing value of the target parameter approaches the estimated value of the target parameter when it is assumed that the current flow of the rectifying element is not limited when the switching element is controlled to be off. Since the on / off duty ratio of the switching element is changed by the feedback control, even if a tolerance of the inductance value of the reactor is generated, the feedforward control is performed as in Patent Document 1, so an appropriate value is obtained at an appropriate timing. The on / off duty ratio can be appropriately changed without being corrected.

It is the figure which showed the structure of the direct-current power converter which concerns on Embodiment 1 of this invention. It is the figure which showed the process of the current waveform and PWM signal generation part of the reactor which concern on Embodiment 1 of this invention. It is a current path in the ON period of the switching element. It is a current path in the OFF period of the switching element. It is the figure which showed the influence of the current waveform and dead time of a reactor. It is the figure which showed the influence of the current waveform and current discontinuous mode of a reactor. It is the figure which showed the behavior of the output voltage and reactor current at the time of the load change which concerns on Embodiment 3 of this invention. It is the figure which showed the structure of the direct-current power converter which concerns on Embodiment 4 of this invention. It is the figure which showed the current waveform of the reactor which concerns on Embodiment 4 of this invention, and the process of the PWM signal generation part. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention. It is a circuit diagram of one example of the converter part which concerns on other embodiment of this invention.

1. Embodiment 1
A DC power converter according to Embodiment 1 will be described with reference to the drawings. FIG. 1 is a configuration diagram of a DC power converter according to the present embodiment.

  The DC power converter is a DC-DC converter that converts DC power between the input electric wire 20 and the output electric wire 21. The DC power converter converts the DC voltage Vin of the input electric wire 20 into an arbitrary DC voltage Vout and outputs it to the output electric wire 21. The input electric wire 20 and the output electric wire 21 are each composed of a positive electric wire and a negative electric wire.

1-1. Converter part 7
In the present embodiment, the DC power source 1 is connected to the input electric wire 20, and the load 6 is connected to the output electric wire 21. A converter unit 7 is provided between the input electric wire 20 and the output electric wire 21. The converter unit 7 includes at least one reactor 2, a switching element 3, a rectifying element 4 including a diode or a switching element for synchronous rectification acting as a diode, and an output capacitor 5 connected to the output electric wire 21. In the present embodiment, the converter unit 7 includes a reactor 2, a switching element 3, a synchronous rectification switching element 4 as a rectifying element 4, and an output capacitor 5.

  The switching element 3 and the switching element 4 for synchronous rectification use MOSFET (Metal Oxide Semiconductor Field Effect Transistor), and have a function of a diode connected in reverse parallel. The switching element 3 and the synchronous rectification switching element 4 may be an IGBT (Insulated Gate Bipolar Transistor) in which diodes are connected in antiparallel.

  Between the positive side and the negative side of the output electric wire 21, the synchronous rectification switching element 4 and the switching element 3 are connected in series from the positive side. Specifically, the drain terminal of the synchronous rectification switching element 4 is connected to the positive side of the output electric wire 21, the source terminal of the synchronous rectification switching element 4 is connected to the drain terminal of the switching element 3, and The source terminal is connected to the negative side of the output electric wire 21. The negative side of the output electric wire 21 and the negative side of the input electric wire 20 are connected to each other.

One end of the reactor 2 is connected to the positive side of the input electric wire 20, and the other end of the reactor 2 is connected to a connection point between the synchronous rectification switching element 4 and the switching element 3. The voltage of the output electric wire 21 is higher than the voltage of the input electric wire 20. Since the rectifying element 4 is the switching element 4 for synchronous rectification, the DC conversion circuit receives the input from the output electric wire 21 side in addition to the step-up operation of transferring the electric power by increasing the voltage from the input electric wire 20 side to the output electric wire 21 side. A step-down operation is possible in which power is transferred by stepping down to the electric wire 20 side. When the rectifying element 4 is a diode, only the boosting operation is possible.

  The output capacitor 5 is connected between the positive side and the negative side of the output electric wire 21 closer to the load 6 than the switching element 3 and the rectifying element 4, and smoothes the voltage Vout of the output electric wire 21.

  The DC power converter includes an input voltage sensor that senses the voltage Vin of the input wire 20 between the input side and the output side of the input wire 20, a reactor current sensor that senses the current IL flowing through the reactor 2, and the output wire 21. An output voltage sensor that senses the voltage Vout of the output wire 21 between the input side and the output side, and an output current sensor that senses a current flowing from the output wire 21 to the load 6 side (not shown). The control unit 13 calculates the sensing value of each parameter based on the output signal of each sensor.

The inductance component of the reactor 2 is represented by L, and the DC resistance component of the reactor 2 is represented by RL. A capacitance component of the output capacitor 5 is represented by Cout, and a DC resistance component of the output capacitor 5 is represented by Rc. The resistance component of the load 6 is represented by Rout, and the other components of the load 6 are represented by 61.

1-2. Control unit 13
The DC power converter includes a control unit 13 that controls the converter unit 7. The control unit 13 performs on / off control of the switching element 3. The control unit 13 performs on / off control of the switching element 3 by PWM control that changes the on / off duty ratio D1 of the rectangular pulse wave signal (PWM signal) having the PWM cycle Tsw. The PWM control is a pulse width modulation control. The on / off duty ratio D1 is a ratio of a period during which the switching element 3 is turned on with respect to the PWM cycle Tsw, and varies between 0 and 1. In the present embodiment, the rectifying element 4 is the synchronous rectifying switching element 4, and the control unit 13 performs on / off control to turn on the synchronous rectifying switching element 4 while the switching element 3 is off. .

  The control unit 13 includes a processing circuit that performs on / off control. The processing circuit of the control unit 13 may be configured by a digital electronic circuit such as an arithmetic processing device or a storage device, or may be configured by an analog electronic circuit such as a comparator, an operational amplifier, a differential amplifier circuit, or the like. You may be comprised by both a circuit and an analog electronic circuit.

また、スイッチング素子３がオフしている期間（同期整流用スイッチング素子４がオンしている期間）では、図４に示す経路で電流が流れる。リアクトル２の電流ＩＬは、リアクトル２の直流抵抗成分ＲＬが０とすると式（２）で表される。

During the period when the switching element 3 is on, a current flows through the path shown in FIG. Reactor 2 current IL is expressed by equation (1) assuming that DC resistance component RL of reactor 2 is zero.

Further, during the period in which the switching element 3 is off (period in which the synchronous rectification switching element 4 is on), a current flows through the path shown in FIG. The current IL of the reactor 2 is expressed by the equation (2) when the DC resistance component RL of the reactor 2 is 0.

特に定常状態では、式（３）の左辺は０となるので、式（４）が成り立つ。

Further, an expression obtained by averaging Expressions (1) and (2) during the PWM cycle Tsw using the on / off duty ratio D1 of the switching element 3 is Expression (3).

Particularly in the steady state, the left side of equation (3) is 0, and equation (4) holds.

  From formula (3), it can be seen that the current IL of the reactor 2 can be adjusted by adjusting the on / off duty ratio D1 of the switching element 3. Further, it can be seen from the equation (4) that the voltage Vout of the output electric wire 21 in the steady state can be adjusted by adjusting the on / off duty ratio D1.

<Dead time generation unit 11>
The control unit 13 includes a dead time generation unit 11 that calculates the dead time Dd. The dead time Dd is a period in which both the switching element 3 and the synchronous rectification switching element 4 are turned off, which is provided between the ON period of the switching element 3 and the ON period of the synchronous rectification switching element 4. Due to the dead time Dd, it is possible to prevent an arm short circuit due to the two switching elements 3 and 4 being simultaneously turned on. The dead time generation unit 11 calculates the dead time Dd as a ratio with respect to the PWM cycle Tsw.

<PWM signal generator 12>
The control unit 13 includes a PWM signal generation unit 12 that generates PWM signals of the switching element 3 and the synchronous rectification switching element 4. As shown in FIG. 2, the PWM signal generation unit 12 includes a first compare level TH1 for the switching element 3 set based on the on / off duty ratio D1 and the dead time Dd, and a triangular wave that vibrates at the PWM cycle Tsw. A first gate signal G1 for turning on / off the switching element 3 is generated by comparing with the wave CA. The PWM signal generator 12 compares the second compare level TH2 for the synchronous rectification switching element 4 set based on the on / off duty ratio D1 and the dead time Dd with the carrier wave CA, and the synchronous rectification switching element A second gate signal G2 for turning on / off 4 is generated.

  The PWM signal generator 12 calculates a triangular carrier wave CA that oscillates between 0 and 1 in the PWM cycle Tsw. The PWM signal generator 12 calculates the first compare level TH1 by subtracting the dead time Dd from the on / off duty ratio D1. The PWM signal generator 12 adds the dead time Dd to the on / off duty ratio D1 to calculate the second compare level TH2. The PWM signal generation unit 12 sets the first gate signal G1 to ON when the carrier wave CA is smaller than the first compare level TH1, and otherwise sets the first gate signal G1 to OFF. The PWM signal generator 12 sets the second gate signal G2 on when the carrier wave CA is greater than the second compare level TH2, and sets the second gate signal G2 off otherwise.

  A value obtained by subtracting the dead time Dd from the on / off duty ratio D1 and the PWM cycle Tsw is the on period of the first gate signal G1 (switching element 3). A value obtained by subtracting the ON / OFF duty ratio D1 and the dead time Dd from 1 and the PWM cycle Tsw is the ON period of the second gate signal G2 (synchronous rectification switching element 4). A period obtained by multiplying the dead time Dd by the PWM cycle Tsw is set between the ON period of the first gate signal G1 and the ON period of the second gate signal G2.

<Calculation of on / off duty ratio D1>
The control unit 13 includes a feedback control unit 8, an estimation control unit 9, and a duty subtraction unit 10 for calculating the on / off duty ratio D1. The feedback control unit 8 performs feedback control to change the on / off duty ratio D1 of the switching element 3 so that the sensing value Vout of the voltage of the output electric wire 21 approaches the target output voltage Vout *. The estimation control unit 9 performs estimation control to change the on / off duty ratio D1 of the switching element 3 so that the sensing value of the target parameter approaches the estimated value of the target parameter. The duty subtraction unit 10 performs duty subtraction for reducing the on / off duty ratio D1 of the switching element 3 by a value obtained by multiplying the sensing value IL of the current of the reactor 2 by the proportional coefficient Kr. Only the feedback control can cause the sensing value Vout of the voltage of the output electric wire 21 to follow the target output voltage Vout *, but estimation control and duty subtraction are performed in order to improve responsiveness and stability.

In the present embodiment, as shown in Expression (5), the control unit 13 adds the estimated control duty ratio D1e calculated by the estimation control to the feedback control duty ratio D1c calculated by the feedback control, and subtracts the duty. The final on / off duty ratio D1 of the switching element 3 is calculated by subtracting the duty subtraction value D1r calculated by the above.

<Feedback control unit 8>
As described above, the feedback control unit 8 performs feedback control to change the on / off duty ratio D1 of the switching element 3 so that the sensing value Vout of the voltage of the output electric wire 21 approaches the target output voltage Vout *. In the present embodiment, the feedback control unit 8 performs a proportional operation and an integral operation on the voltage deviation Vout_error between the target output voltage Vout * and the sensing value Vout of the voltage of the output wire 21 as shown in Expression (6). And a differential operation are performed to calculate the feedback control duty ratio D1c. Where KPe
Is a proportional gain, KIe is an integral gain, and KDe is a differential gain. Instead of this PID control, other feedback control such as PI control with the differential gain KDe set to 0 and PD control with the integral gain KIe set to 0 may be used.

Further, as shown in Expression (7), a discrete expression may be used instead of the continuous expression in Expression (6). Here, n indicates the nth control cycle, and n-1 indicates the nth previous control cycle.

<Duty subtraction unit 10>
The duty subtraction unit 10 calculates a duty subtraction value D1r by multiplying the sensing value IL of the current of the reactor 2 by the proportional coefficient Kr, as shown in Expression (8).

  By subtracting the duty subtraction value D1r, the on / off duty ratio D1 is decreased when the current IL of the reactor 2 is increased, and the on / off duty ratio D1 is increased when the current IL of the reactor 2 is decreased, so that the change in the current IL of the reactor 2 is decreased. The resonance suppression effect of the converter unit 7 can be obtained. This is because the reactor series resistance value RL, which is the sum of the resistance components of the reactor 2, such as the DC equivalent resistance of the reactor 2 and the switching element 3 or the synchronous rectification switching element 4 connected in series to the reactor 2, can be made from the viewpoint of efficiency and heat generation. Although it is designed to be as small as possible, it is preferable that the larger one is less likely to resonate from the viewpoint of control. The duty subtraction value D1r can provide the same resonance suppression effect as increasing the reactor series resistance value RL without increasing the reactor series resistance value RL.

  Similarly to the reactor series resistance value RL, by increasing the resistance value Rc of the output capacitor 5 designed to be as small as possible from the viewpoint of efficiency and heat generation, and by reducing the resistance value Rout of the load 6, A resonance suppression effect equivalent to increasing the reactor series resistance value RL can be obtained. When the reactor series resistance value RL is large, when the resistance value Rc of the output capacitor 5 is large, or when the resistance value Rout of the load 6 is small, the resonance suppression effect becomes unnecessary, and the proportionality coefficient Kr may be set to zero. Further, if the responsiveness of the feedback control unit 8 is sufficiently lower than the resonance frequency determined by the inductance component L of the reactor 2 and the capacitance component Cout of the output capacitor 5 (about 1/5 to 1/10), the resonance suppression effect. Therefore, the proportional coefficient Kr may be set to zero.

<Estimation control unit 9>
First, the necessity of estimation control will be described. As shown in FIG. 2, when the current IL of the reactor 2 is a positive value during the dead time period, a current flows through the diode portion of the synchronous rectification switching element 4. On the other hand, when the current IL of the reactor 2 is a negative value during the dead time period, the current flows through the diode portion of the switching element 3. When the current IL of the reactor 2 oscillates over 0 A, the synchronous rectification switching element 4 is switched depending on whether the current IL of the reactor 2 is a positive value or a negative value during the dead time period. Switching is made between whether a current flows through the diode portion or a current flows through the diode portion of the switching element 3. Therefore, a period in which a current flows through the switching element 3 with respect to the ON period of the first gate signal G1 depending on whether the current IL of the reactor 2 is a positive value or a negative value (ON period of the switching element 3) Expands and contracts.

  FIG. 5 shows a case where the current IL of the reactor 2 is around 0 A and the load fluctuates. When the current of the reactor 2 is larger than 0 A, when the first gate signal G1 is turned off and the switching element 3 is controlled to be turned off, the current flowing through the switching element 3 is cut off according to the off command, and the switching element for synchronous rectification The current flows through the diode portion 4 and the current of the reactor 2 gradually decreases.

  On the other hand, when the current of the reactor 2 is less than 0A across 0A, when the first gate signal G1 is turned off and the switching element 3 is controlled to turn off, as in the off command except in the dead time period. The current flowing through the switching element 3 is cut off, the current flows through the synchronous rectification switching element 4, and the current in the reactor 2 gradually decreases. However, in the dead time period, the switching element 3 (diode portion) is turned off against the OFF command. The current flows, the current flow of the switching element 4 for synchronous rectification is blocked, and the current of the reactor 2 gradually increases. Therefore, the OFF period of the switching element 3 is shorter by the dead time period than the OFF command, and the ON period of the switching element 3 is longer by the dead time period than the ON command.

  As a result, when the current of the reactor 2 oscillates over 0 A, the current of the reactor 2 greatly deviates from the expected current value according to the on / off command of the switching element 3 due to the influence of the dead time, and the output electric wire 21 The voltage Vout is significantly deviated from the target output voltage Vout *.

  Although different from the present embodiment, the case where the rectifying element 4 is a diode is shown in FIG. When the current of the reactor 2 is larger than 0A, as in the case of FIG. 5, when the first gate signal G1 is turned off, the current flowing through the switching element 3 is cut off according to the off command, and the current flows through the diode. The current of the reactor 2 gradually decreases.

  On the other hand, when the current of reactor 2 is smaller than 0 A, when switching element 3 is controlled to be off, the current flow of the diode is blocked against the off command, and the current of reactor 2 becomes 0 A. Therefore, the OFF period of the switching element 3 is shorter than the OFF command by a period during which the current of the reactor 2 is smaller than 0A. As a result, when the current of the reactor 2 oscillates over 0 A, the current discontinuous mode is set, and the current of the reactor 2 greatly deviates from the expected current value in accordance with the on / off command of the switching element 3, and the output The voltage Vout of the electric wire 21 is also greatly deviated from the target output voltage Vout *.

  As described above, when the current flow of the rectifying element 4 is restricted when the current of the reactor 2 oscillates over 0 A and the switching element 3 is controlled to be off, the current flow of the rectifying element 4 is not restricted. In this case, the current of the reactor 2 greatly deviates from the expected value, and the voltage Vout of the output wire 21 deviates greatly from the target output voltage Vout *. Even by feedback control of the output voltage, it is possible to cause the sensing value Vout of the voltage of the output wire 21 to follow the target output voltage Vout *, but a follow-up delay occurs. Therefore, in this embodiment, in addition to the feedback control of the output voltage, the estimation control is performed so as to follow up at a higher speed.

  That is, the estimation control unit 9 calculates a sensing value of the target parameter that is a value, an integral value, a differential value, or a change amount of the voltage or current at the target portion of the converter unit 7. The estimation control unit 9 calculates an estimated value of the target parameter when it is assumed that the current flow of the rectifying element 4 is not limited when the switching element 3 is off. And the estimation control part 9 performs the estimation control which changes the on-off duty ratio D1 of the switching element 3 so that the sensing value of an object parameter may approach the estimated value of an object parameter.

  In the present embodiment, a case will be described in which the estimation control unit 9 uses the current value, integral value, differential value, or change amount of the reactor 2 as a target parameter. First, the case where the estimation control unit 9 uses the current value of the reactor 2 as a target parameter will be described.

As shown in the first equation of equation (9), the estimation control unit 9 detects the voltage sensing value Vin of the input electric wire 20, the voltage sensing value Vout of the output electric wire 21, and the on / off control information of the switching element 3 (in this example, , A feedback control duty ratio D1c), and an estimated value of a differential value or change amount (differential value in this example) of the current of the reactor 2 as a target parameter based on the inductance value Le of the reactor 2, and the differential value Alternatively, an estimated value ILe of the reactor 2 as the target parameter is calculated by integrating or integrating (in this example, integrating) the estimated value of the change amount.

  Here, as shown in the first equation of the equation (9), the estimation control unit 9 represents a relational expression among the voltage Vin of the input electric wire 20, the voltage Vout of the output electric wire 21, and the on / off control information of the switching element 3. Thus, the estimated value ILe of the current of the reactor 2 is calculated. This relational expression represents that when the electromotive force generated in the reactor 2 is divided by the inductance value of the reactor 2 as in the above-described formula (3), the current change in the current of the reactor 2 (differential value) is obtained. The physical formula is used. By calculating Vin- (1-D1c) × Vout, an estimated value of the electromotive force generated in the reactor 2, and dividing the estimated value of the electromotive force by the inductance value Le of the reactor 2, the time of the current of the reactor 2 is calculated. The estimated value of the current of the reactor 2 is calculated by calculating the estimated value of the change and integrating the estimated value of the time change of the current. Note that the term -RLe × IL indicates that the calculated electromotive force of the reactor 2 is reduced due to a voltage drop due to the reactor current IL flowing through the reactor series resistance RL, and also has a resonance suppression effect described below. However, if the resonance suppression effect is not required or if it is desired to simplify the calculation, it may be omitted. This relational expression is the same for the following formulas (10) to (14).

  In the present embodiment, the reactor series resistance value RLe used for the calculation of the first expression of Expression (9) is set to a value larger than the actual value. By this setting, the same resonance suppression effect as the duty subtraction value D1r can be obtained. When the resonance suppression effect is not necessary, the calculation can be simplified by setting the reactor series resistance value RLe to 0, similarly to the proportional coefficient Kr of the duty subtraction value D1r. The setting of the reactor series resistance value RLe is the same for the following formulas (10) to (14).

In the present embodiment, the estimation control unit 9 uses the on / off duty ratio D1 before being changed by the estimated control duty ratio D1e (in this example, the feedback control duty ratio D1c) as the on / off control information of the switching element 3. Yes. Since the duty ratio is used, the estimated value ILe of the current of the reactor 2 is not a value that oscillates in the PWM cycle Tsw as shown in FIG. 5, but an average value of the PWM cycle Tsw. As described above, even on average, the on / off duty ratio D1 is changed for each PWM cycle Tsw, so that it is acceptable in terms of control responsiveness.

  The estimation control unit 9 may use a duty ratio obtained by subtracting the dead time Dd from the feedback control duty ratio D1c as the on / off control information of the switching element 3. Alternatively, the estimation control unit 9 may use a value that becomes 1 when the first gate signal G1 is on and becomes 0 when the first gate signal G1 is off as the on / off control information of the switching element 3. .

The estimation control unit 9 is proportional to the current deviation ILe_error between the estimated value ILe of the current of the reactor 2 and the sensing value IL of the current of the reactor 2 as shown in the second and third expressions of the equation (9). The estimated control duty ratio D1e is calculated by performing calculation, integration calculation, and differentiation calculation. Here, KPe is a proportional gain, KIe is an integral gain, and KDe is a differential gain. Instead of this PID control, other feedback control such as PI control with the differential gain KDe set to 0 and PD control with the integral gain KIe set to 0 may be used.

Note that the same effect as that of the equation (9) can be obtained by the equation (10) obtained by discretizing the equation (9). Tc represents a control cycle. Unlike the equation (9), the estimation control unit 9 calculates an estimated value of the change amount of the current of the reactor 2 during the control period Tc, integrates the estimated value of the change amount, and estimates the current of the reactor 2. The value ILe is calculated. In addition, the equivalent thing which deform | transformed Formula (10) can also be used.

Next, the case where the estimation control unit 9 uses the differential value of the current of the reactor 2 as a target parameter will be described. As shown in the first equation of the equation (11), the estimation control unit 9 is similar to the calculation part of the differential value of the first equation of the equation (9), the sensing value Vin of the voltage of the input wire 20, the output wire 21 Of the current of the reactor 2 as the target parameter is estimated on the basis of the sensing value Vout of the current V, the on / off control information of the switching element 3 (in this example, the feedback control duty ratio D1c), and the inductance value Le of the reactor 2. The value dILe / dt is calculated.

  As shown in the second and third expressions of the equation (11), the estimation control unit 9 determines the estimated value dILe / dt of the differential value of the current of the reactor 2 and the sensing value dIL / dt of the differential value of the current of the reactor 2. The estimated control duty ratio D1e is calculated by performing a proportional operation, an integral operation, and a derivative operation on the deviation dILe_error / dt.

Note that the same effect as that of the equation (11) can be obtained by the equation (12) obtained by discretizing the equation (11). In addition, the equivalent thing which deform | transformed Formula (12) can also be used.

In addition, Formula (13) which is one of the formulas which transformed Formula (12) can also obtain an effect equivalent to Formula (12). In Expression (13), the estimated value ILe of the current of the reactor 2 is obtained by the sum of the previous value of the estimated value of the current of the reactor 2 and the estimated value of the change amount of the current of the reactor 2 during the control cycle Tc.

Next, the case where the estimation control unit 9 uses the amount of change in the current of the reactor 2 as a target parameter will be described. As shown in the first equation of the equation (14), the estimation control unit 9 performs the sensing value Vin of the voltage of the input electric wire 20 and the output electric wire 21 in the same manner as the calculation part of the change amount of the first equation of the equation (10). Of the current of the reactor 2 as a target parameter based on the sensing value Vout of the current of V, the on / off control information of the switching element 3 (in this example, the feedback control duty ratio D1c), the inductance value Le of the reactor 2, and the control cycle Tc. An estimated value ΔILe of the change amount is calculated.

  As shown in the second equation of the equation (14), the estimation control unit 9 detects the current sensing value IL (n−1) of the reactor 2 in the previous control cycle and the current sensing value of the reactor 2 in the current control cycle. Based on the difference from IL (n), the sensing value ΔIL of the amount of change in the current of the reactor 2 as the target parameter is calculated. Then, as shown in the third and fourth formulas of the equation (14), the estimation control unit 9 calculates the estimated value ΔILe of the change amount of the current in the reactor 2 and the sensing value ΔIL of the change amount of the current in the reactor 2. A proportional calculation, an integral calculation, and a differentiation calculation are performed on the deviation ΔILe_error to calculate an estimated control duty ratio D1e.

When the reactor series resistance value RLe used for the calculation of the estimation control unit 9 is set to a value larger than the actual value, the resonance suppression effect can be obtained even if the proportionality coefficient Kr of the duty subtraction unit 10 is zero. When the proportionality coefficient Kr of the duty subtraction unit 10 is larger than the actual reactor series resistance value RL, the resonance suppression effect can be obtained even if the reactor series resistance value RLe of the estimation control unit 9 is equal to or less than the actual reactor series resistance value RL. It is done. However, when both the estimation control unit 9 and the duty subtraction unit 10 are provided and the proportionality coefficient Kr is larger than the actual reactor series resistance value RL, the reactor series resistance value RLe of the estimation control unit 9 is The same value as the proportional coefficient Kr is used. Thereby, when calculating the estimated value ILe of the current of the reactor 2, it is calculated by a circuit set to a value larger than the actual reactor series resistance value RL, so that the change of the estimated value ILe of the current of the reactor 2 is changed. And the change in the estimated control duty ratio D1e can be reduced. Therefore, a greater resonance suppression effect can be obtained.

  As described above, according to the DC power converter of the first embodiment, the feedback control unit 8 performs the feedback control that causes the voltage Vout of the output wire 21 to follow the target output voltage Vout *, and the duty subtraction unit 10 performs the feedback control. A resonance suppression effect is obtained, and the dead time compensation by the estimation control of the current of the reactor 2 of the estimation control unit 9 or the response improvement of the current discontinuous mode can be performed. Furthermore, in addition to the duty subtraction unit 10, if the estimation control unit 9 also performs resonance suppression by setting the reactor series resistance value RLe, a greater resonance suppression effect can be obtained than when only the duty subtraction unit 10 is used.

2. Embodiment 2
Next, a DC power converter according to Embodiment 2 will be described. The description of the same components as those in the first embodiment is omitted. The basic configuration and processing of the DC power converter according to the present embodiment are the same as those of the first embodiment, but the target parameter and the method for calculating the estimated value of the target parameter are different from the first embodiment.

  In the present embodiment, unlike the first embodiment, the estimation control unit 9 uses a voltage value, an integral value, a differential value, or a change amount of the output electric wire 21 as a target parameter. First, the case where the estimation control unit 9 uses the value of the voltage of the output electric wire 21 as a target parameter will be described.

As shown in the first equation of equation (15), the estimation control unit 9 detects the sensing value IL of the current of the reactor 2, the sensing value Iout of the current of the output electric wire 21, the on / off control information of the switching element 3 (in this example, Based on the feedback control duty ratio D1c) and the capacitance value Cout of the output capacitor 5, an estimated value of the differential value or change amount (differential value in this example) of the voltage of the output electric wire 21 as the target parameter is calculated, and the differential The estimated value Vout of the voltage of the output electric wire 21 as the target parameter is calculated by integrating or integrating (in this example, integrating) the value or the estimated value of the change amount.

  Here, as shown in the first equation of the equation (15), the estimation control unit 9 determines the current IL of the reactor 2, the current Iout of the output wire 21, the on / off control information of the switching element 3, and the output capacitor 5. The estimated value Vout of the voltage of the output electric wire 21 is calculated using a relational expression with the capacitance value Cout. This relational expression is a physical expression representing that a value obtained by dividing the charge stored in the output capacitor 5 by the capacitance value of the output capacitor 5 becomes a voltage between terminals of the output capacitor 5 (voltage of the output electric wire 21). . The estimated value of the current flowing into the output capacitor 5 is calculated by (1-D1c) × IL-Iout, and the estimated value of the charge stored in the output capacitor 5 is calculated by integrating the estimated value of the flowing current. The estimated value of the inter-terminal voltage of the output capacitor 5 is calculated by dividing the estimated value of the charge by the capacitance value Cout of the output capacitor 5. In addition, although the term of -Vout / Route is provided for the resonance suppression effect described below, it may be omitted when the resonance suppression effect is not necessary. Further, the estimated value of the voltage drop caused by the current flowing into the output capacitor 5 is calculated by Rce × {(1−D1c) × IL−Iout}, and this estimated value of the voltage drop is calculated as the voltage across the terminals of the output capacitor 5. The estimated value Vout of the voltage of the output electric wire 21 is calculated by adding to the estimated value. Note that this voltage drop term also serves as a resonance suppression effect described below, but may be omitted when the resonance suppression effect is not necessary or when it is desired to simplify the calculation. This relational expression is the same for the following formulas (16) to (20).

  The resistance value Route of the load 6 used for calculating the first expression of Expression (15) is set to a value smaller than the actual value. By this setting, a resonance suppression effect can be obtained by making it appear controlly as if a small resistance value Rout is connected. When the resonance suppression effect is not necessary, the calculation can be simplified by making the resistance value Route of the load 6 infinite.

  In the present embodiment, the resistance value Rce of the series equivalent resistance of the output capacitor 5 used for the calculation of the first expression of Expression (15) is set to a value larger than the actual value. By this setting, a resonance suppression effect can be obtained by making it appear controlly as if a large resistance value Rc is connected. When the resonance suppression effect is not necessary, the calculation can be simplified by setting the resistance value Rce of the output capacitor 5 to zero. The setting of the resistance value Route of the load 6 and the resistance value Rce of the output capacitor 5 is the same for the following equations (16) to (20).

As shown in the second expression and the third expression of the equation (15), the estimation control unit 9 performs the voltage deviation Vout_error between the estimated value Vout of the voltage of the output electric wire 21 and the sensing value Vout of the voltage of the output electric wire 21. The estimated control duty ratio D1e is calculated by performing proportional calculation, integral calculation, and differential calculation. Here, KPe is a proportional gain, KIe is an integral gain, and KDe is a differential gain. Instead of this PID control, other feedback control such as PI control with the differential gain KDe set to 0 and PD control with the integral gain KIe set to 0 may be used.

It should be noted that the same effect as Expression (15) can be obtained by Expression (16) obtained by discretizing Expression (15). Tc represents a control cycle. Unlike the equation (15), the estimation control unit 9 calculates an estimated value of the change amount of the voltage of the output electric wire 21 during the control period Tc, integrates the estimated value of the change amount, and calculates the voltage of the output electric wire 21 An estimated value Vout is calculated. In addition, the equivalent thing which deform | transformed Formula (16) can also be used.

Next, a case where the estimation control unit 9 uses the differential value of the voltage of the output electric wire 21 as a target parameter will be described. As shown in the first equation of the equation (17), the estimation control unit 9 is similar to the calculation part of the differential value of the first equation of the equation (15). Based on the current sensing value Iout, the on / off control information of the switching element 3 (in this example, the feedback control duty ratio D1c), and the capacitance value Coute of the output capacitor 5, the differential value of the voltage of the output wire 21 as the target parameter Estimated value dVoute / dt is calculated.

  As shown in the second and third formulas of Expression (17), the estimation control unit 9 determines the estimated value dVoute / dt of the differential value of the voltage of the output wire 21 and the sensing value dVout of the differential value of the voltage of the output wire 21. A proportional calculation, an integral calculation, and a differential calculation are performed on the deviation dVout_error / dt from / dt to calculate the estimated control duty ratio D1e.

Note that the same effect as that of the equation (17) can be obtained by the equation (18) obtained by discretizing the equation (17). In Expression (18), the resistance value Route of the load 6 is set to 0 in order to prevent the expression from becoming complicated. An equivalent of equation (18) can also be used.

It should be noted that Expression (19), which is one of Expressions obtained by transforming Expression (18), can obtain the same effect as Expression (18). In Expression (19), the estimated value Vout of the voltage of the output electric wire 21 is obtained by the sum of the previous value of the estimated value of the voltage of the output electric wire 21 and the estimated value of the amount of change in the voltage of the output electric wire 21 during the control cycle Tc. It is done.

Next, the case where the estimation control unit 9 uses the amount of change in the voltage of the output electric wire 21 as a target parameter will be described. As shown in the first equation of the equation (20), the estimation control unit 9 performs the sensing value IL of the current of the reactor 2 and the output electric wire 21 in the same manner as the calculation part of the change amount of the first equation of the equation (16). Based on the current sensing value Iout, the on / off control information of the switching element 3 (in this example, the feedback control duty ratio D1c), the capacitance value Cout of the output capacitor 5, and the control cycle Tc, the voltage of the output wire 21 as the target parameter An estimated value ΔVoute of the amount of change is calculated.

  As shown in the second equation of Equation (20), the estimation control unit 9 determines the sensing value Vout (n−1) of the voltage of the output wire 21 in the previous control cycle and the voltage of the output wire 21 in the current control cycle. Based on the difference from the sensing value Vout (n), the sensing value ΔVout of the amount of change in the voltage of the output wire 21 as the target parameter is calculated. Then, as shown in the third and fourth expressions of Expression (20), the estimation control unit 9 estimates the voltage change amount ΔVoute of the output electric wire 21 and the sensing value ΔVout of the voltage change amount of the output electric wire 21. A proportional calculation, an integral calculation, and a differentiation calculation are performed on the deviation ΔVout_error with respect to the difference ΔVout_error to calculate the estimated control duty ratio D1e.

When the resistance value Rce of the series equivalent resistance of the output capacitor 5 used for the calculation of the estimation control unit 9 is set to a value larger than the actual value, the proportionality coefficient Kr of the duty subtraction unit 10
Even if is zero, a resonance suppression effect can be obtained. Further, when the resistance value Route of the load 6 used for the calculation of the estimation control unit 9 is set to a value smaller than the actual value, even if the proportionality coefficient Kr of the duty subtraction unit 10 is 0, the resonance suppression effect is obtained. It is done.

  As described above, according to the DC power converter of the second embodiment, the duty subtraction unit 10 performs the feedback control that causes the voltage Vout of the output wire 21 to follow the target output voltage Vout * by the feedback control unit 8. A resonance suppression effect is obtained, and the dead time compensation by the estimation control of the voltage of the output electric wire 21 of the estimation control unit 9 or the response improvement of the current discontinuous mode can be performed.

3. Embodiment 3
Next, a DC power converter according to Embodiment 3 will be described. The description of the same components as those in the first embodiment is omitted. The basic configuration and processing of the DC power converter according to the present embodiment are the same as those in the first embodiment, but the method for calculating the estimated value of the target parameter is different from those in the first and second embodiments.

  In the first embodiment, the estimated value of the current of the reactor 2 is calculated in consideration of the time change of the current of the reactor 2 caused by the inductance of the reactor 2. In the present embodiment, as described in the above equation (4), the estimated value of the target parameter is calculated on the assumption that the current state of the reactor 2 is in a steady state without considering the time change of the current of the reactor 2. Here, the case where the value of the voltage of the output electric wire 21 is the target parameter will be described.

In the present embodiment, unlike the second embodiment, the sensing value Vin of the voltage of the input electric wire 20 and the on / off control information of the switching element 3 (in this example, feedback) as shown in the first expression of the expression (21). Based on the control duty ratio D1c), an estimated value Vout of the voltage of the output wire 21 as a target parameter is calculated.

  Here, the estimation control unit 9 uses the relational expression between the voltage Vin of the input electric wire 20 and the on / off control information of the switching element 3 as shown in the first equation of the equation (21), so that the voltage of the output electric wire 21 is calculated. The estimated value Vout is calculated. This relational expression is a physical expression indicating that Vin / (1-D1c) becomes the voltage of the output electric wire 21 when it is assumed that the current of the reactor 2 does not change with time and is in a steady state. In addition, the term of -RLe × IL represents that the voltage of the output electric wire 21 decreases due to the voltage drop due to the reactor current IL flowing through the reactor series resistance RL, and also serves as a resonance suppression effect described below. If the resonance suppression effect is not necessary, or if it is desired to simplify the calculation, it may be omitted. As in the first and second embodiments, an equivalent one obtained by modifying and discretizing Equation (21) can be used.

In the present embodiment, the reactor series resistance value RLe used for the calculation of the first expression of Expression (21) is set to a value larger than the actual value. By this setting, the same resonance suppression effect as the duty subtraction value D1r can be obtained. When the resonance suppression effect is not necessary, the calculation can be simplified by setting the reactor series resistance value RLe to 0, similarly to the proportional coefficient Kr of the duty subtraction value D1r.

As shown in the second and third formulas of the formula (21), the estimation control unit 9 determines the voltage deviation Vout_error between the estimated value Vout of the voltage of the output wire 21 and the sensing value Vout of the voltage of the output wire 21. The estimated control duty ratio D1e is calculated by performing proportional calculation, integral calculation, and differential calculation. Here, KPe is a proportional gain, KIe is an integral gain, and KDe is a differential gain. Instead of this PID control, other feedback control such as PI control with the differential gain KDe set to 0 and PD control with the integral gain KIe set to 0 may be used.

  Although the duty subtraction value D1r can be omitted, if it is not omitted, the on / off duty ratio D1 decreases when the current IL of the reactor 2 increases, and the on / off duty ratio D1 increases when the current IL of the reactor 2 decreases. Therefore, when the estimation control is not performed, or in the calculation methods according to the first and second embodiments, the voltage of the output electric wire 21 is also obtained in the operation region A, the operation region C, and the operation region E when the load fluctuates as shown in FIG. Vout varies. If the reactor series resistance value RLe of the first equation of the equation (21) in the present embodiment is set to 0, the voltage of the output wire 21 corresponding to the feedback control duty ratio D1c is set to the estimated value Vout, and the estimated value Voute The on / off duty ratio D1 is changed so as to follow. As a result, since the on / off duty ratio D1 is controlled to be the feedback control duty ratio D1c, fluctuations in the voltage Vout of the output electric wire 21 in the operation region A, the operation region C, and the operation region E can be suppressed. is there.

  As described above, according to the DC power converter of the third embodiment, the duty subtraction unit 10 performs the feedback control that causes the feedback control unit 8 to follow the voltage Vout of the output wire 21 to the target output voltage Vout *. A resonance suppression effect is obtained, and the dead time compensation by the estimation control of the voltage of the output electric wire 21 of the estimation control unit 9 or the response improvement of the current discontinuous mode can be performed.

4). Embodiment 4
Next, a DC power converter according to Embodiment 4 will be described. The description of the same components as those in the first embodiment is omitted. FIG. 8 is a configuration diagram of a DC power converter according to the fourth embodiment. Unlike Embodiment 1, converter unit 7 includes a plurality of conversion circuits each including a reactor, a switching element, and a rectifying element. A plurality of sets of conversion circuits are provided in parallel to form an interleaved configuration. In this embodiment, two sets of conversion circuits are provided. That is, the first set of conversion circuits includes a first reactor 2a, a first switching element 3a, and a first synchronous rectification switching element 4a as the first rectification element 4a. The second set of conversion circuits includes a second reactor 2b, a second switching element 3b, and a second synchronous rectifying switching element 4b as the second rectifying element 4b.

  Between the positive side and the negative side of the output electric wire 21, a first series circuit in which the first synchronous rectification switching element 4a and the first switching element 3a are connected in series from the positive side, and a second synchronous rectification from the positive side. A switching element 4b and a second series circuit in which the second switching element 3b are connected in series are provided.

One end of the first reactor 2a is connected to the positive side of the input electric wire 20, and the other end of the first reactor 2a is connected to a connection point between the first synchronous rectification switching element 4a and the first switching element 3a. . One end of the second reactor 2b is connected to the positive side of the input electric wire 20, and the other end of the second reactor 2b is connected to a connection point between the second synchronous rectification switching element 4b and the second switching element 3b. . The output capacitor 5 is connected between the positive side and the negative side of the output electric wire 21 closer to the load 6 than the switching element and the rectifying element, and smoothes the voltage Vout of the output electric wire 21.

  The DC power converter senses an input wire voltage sensor that senses the voltage Vin of the input wire 20, a first reactor current sensor that senses the current IL1 that flows through the first reactor 2a, and a current IL2 that flows through the second reactor 2b. A second reactor current sensor, an output wire voltage sensor that senses the voltage Vout of the output wire 21, and an output current sensor that senses a current flowing from the output wire 21 to the load 6 (not shown) are provided. The control unit 13 calculates the sensing value of each parameter based on the output signal of each sensor.

  The control unit 13 includes a feedback control unit 8 shared by the first and second switching elements 3a and 3b, a first estimation control unit 9a for the first switching element 3a, a second estimation control unit 9b for the second switching element 3b, And a duty subtraction unit 10 shared by the first and second switching elements 3a and 3b. In addition, the control unit 13 includes a dead time generation unit 11 that calculates the dead time Dd, as in the first embodiment.

In the present embodiment, the control unit 13 is calculated by the estimation control of the first estimation control unit 9a to the feedback control duty ratio D1c calculated by the feedback control, as shown in the first equation of the equation (22). The first estimated control duty ratio D1e is added, and the duty subtraction value D1r calculated by duty subtraction is subtracted to calculate the final first on / off duty ratio D1 for the first switching element 3a. Further, as shown in the second equation of the equation (22), the control unit 13 adds the second estimated control duty calculated by the estimation control of the second estimation control unit 9b to the feedback control duty ratio D1c calculated by the feedback control. The ratio D2e is added, and the duty subtraction value D1r calculated by duty subtraction is subtracted to calculate the final second on / off duty ratio D2 for the second switching element 3b.

  Similarly to the first embodiment, the feedback control unit 8 uses the equation (6) to perform proportional calculation and integration on the voltage deviation Vout_error between the target output voltage Vout * and the sensing value Vout of the voltage of the output wire 21. Calculation and differential calculation are performed to calculate the feedback control duty ratio D1c.

The duty subtraction unit 10 multiplies the total current value of the sensing value IL1 of the current of the first reactor 2a and the sensing value IL2 of the current of the second reactor 2b by a proportional coefficient Kr, as shown in Expression (23). A duty subtraction value D1r is calculated.

The PWM signal generation unit 12 performs interleave control that turns on instead of the switching elements 3a and 3b of each set. The PWM signal generation unit 12 shifts the phase with each other by a cycle (Tsw / 2 in this example) obtained by dividing the PWM cycle Tsw by the number of sets, and sets each switching element 3.
Turn on a and 3b.

  In the present embodiment, as shown in FIG. 9, the PWM signal generator 12 generates a carrier wave CA that is common to the first set and the second set. The carrier wave CA is a triangular wave that oscillates between 0 and 1 in the PWM cycle Tsw. The PWM signal generator 12 compares the first compare level TH1 (= D1-Dd) for the first switching element 3a calculated by subtracting the dead time Dd from the first on / off duty ratio D1 and the carrier wave CA. The first gate signal G1 for turning on / off the first switching element 3a is generated. Further, the PWM signal generator 12 adds the second compare level TH2 (= D1 + Dd) for the first synchronous rectification switching element 4a calculated by adding the dead time Dd to the first on / off duty ratio D1, and the carrier wave CA. And a second gate signal G2 for turning on / off the first synchronous rectification switching element 4a is generated.

  The PWM signal generator 12 subtracts the second on / off duty ratio D2 from 1 and adds the dead time Dd to the third compare level TH3 (= 1−D2 + Dd) for the second switching element 3b, and the carrier wave Compared with CA, a third gate signal G3 for turning on and off the second switching element 3b is generated. Further, the PWM signal generator 12 subtracts the second on / off duty ratio D2 and the dead time Dd from 1, and the fourth compare level TH4 (= 1−D2−Dd) for the second synchronous rectification switching element 4b. And the carrier wave CA are generated, and a fourth gate signal G4 for turning on and off the second synchronous rectification switching element 4b is generated.

  In the first set, the PWM signal generator 12 sets the first gate signal G1 to ON when the carrier wave CA is smaller than the first compare level TH1, and otherwise the first gate signal G1 is set to ON. Set it to off. The PWM signal generator 12 sets the second gate signal G2 on when the carrier wave CA is greater than the second compare level TH2, and sets the second gate signal G2 off otherwise. In the second set, the PWM signal generator 12 sets the third gate signal G3 to ON when the carrier wave CA is larger than the third compare level TH3 so that the phase is opposite to that of the first set. In other cases, the first gate signal G1 is set to OFF. The PWM signal generator 12 sets the fourth gate signal G4 to ON when the carrier wave CA is smaller than the fourth compare level TH4, and otherwise sets the fourth gate signal G4 to OFF.

In the present embodiment, the first and second estimation control units 9a and 9b use the reactor current as a target parameter. The first and second estimation control units 9a and 9b calculate an estimated current value ILe of one reactor common to each set, as shown in the first expression of Expression (24). Similar to the first expression of Expression (9), the estimation control unit 9 detects the voltage sensing value Vin of the input electric wire 20, the voltage sensing value Vout of the output electric wire 21, and on / off control information of the switching element 3 (in this example, Based on the feedback control duty ratio D1c) and the inductance value Le of the reactor, an estimated value of the differential value of the reactor current as the target parameter is calculated, and the estimated value of the differential value is integrated to be common as the target parameter. The estimated value ILe of the reactor current is calculated. The inductance value Le of the reactor is an average value of the inductance value L1 of the first reactor 2a and the inductance value L2 of the second reactor 2b.

  The term −RLe × IL represents that the calculated electromotive force of the reactor is reduced due to the voltage drop due to the reactor current IL flowing through the reactor series resistance RL, as in the first equation of the equation (9). Although it also serves as a resonance suppression effect described below, it may be omitted when the resonance suppression effect is not necessary or when it is desired to simplify the calculation. For reactor series resistance value RLe, an average value of reactor series resistance value RL1 of first reactor 2a and reactor series resistance value RL2 of second reactor 2b may be used, but in this embodiment, an actual average value is used. Is set to a larger value. As the sensing value IL of the reactor current, an average value of the current IL1 of the first reactor 2a and the current IL2 of the second reactor 2b is used.

  As shown in the second and third formulas of the equation (24), the estimation control unit 9 calculates the current deviation ILe1_error between the common reactor current estimation value ILe and the first reactor 2a current sensing value IL1. Then, a proportional calculation, an integral calculation, and a differential calculation are performed to calculate the first estimated control duty ratio D1e. Further, as shown in the fourth and fifth formulas of the formula (24), the proportional calculation is performed with respect to the current deviation ILe2_error between the common reactor current estimation value ILe and the second reactor 2b current sensing value IL2. , Integral calculation and differential calculation are performed to calculate the second estimated control duty ratio D2e. Here, KPe is a proportional gain, KIe is an integral gain, and KDe is a differential gain. Instead of this PID control, other feedback control such as PI control with the differential gain KDe set to 0 and PD control with the integral gain KIe set to 0 may be used.

  As in the first embodiment, the equation (24) may be discretized, or the target parameter may be a differential current value or change amount instead of the reactor current. Good.

  Here, in the calculation of the first and second estimated control duty ratios D1e and D2e, the current value IL1 of the first reactor 2a and the current IL2 of the second reactor 2b are obtained by using the estimated current value ILe of the common reactor. The first set of conversion circuits and the second set of conversion circuits are aligned in terms of efficiency, surge voltage and heat generation of switching elements and diodes, and both are operated in the best current state. Can do.

As described above, according to the DC power converter of the fourth embodiment, the feedback control unit 8 performs the feedback control for causing the voltage Vout of the output wire 21 to follow the target output voltage Vout *, and the duty subtraction unit 10 performs the feedback control. A resonance suppression effect can be obtained, dead time compensation by estimation control of the voltage of the output wire 21 of the estimation control unit 9, or response improvement of the current discontinuous mode can be performed, and the current IL1 of the first reactor 2a and the second The current IL2 of the reactor 2b can be matched to operate in the best current state in terms of efficiency, surge voltage and heat generation of the switching element and the diode.

[Other Embodiments]
Finally, other embodiments of the present invention will be described. Note that the configuration of each embodiment described below is not limited to being applied independently, and can be applied in combination with the configuration of other embodiments as long as no contradiction arises.

(1) In each of the embodiments described above, the rectifying element 4 is the synchronous rectifying switching element 4, and in addition to the switching element 3, the synchronous rectifying switching element 4 is also controlled to be turned on / off. The case is described as an example. However, the embodiment of the present invention is not limited to this. That is, as shown in FIG. 10, the rectifying element 4 may be a diode 4 and only the switching element 3 may be on / off controlled.

(2) In each of the embodiments described above, the converter unit 7 includes the reactor 2, the switching element 3, the synchronous rectification switching element 4 as the rectifying element 4, and the output capacitor 5 one by one, The case where a bidirectional DC conversion circuit capable of a step-down operation is described as an example. However, the embodiment of the present invention is not limited to this. That is, a DC power converter that converts DC power between an input electric wire and an output electric wire, wherein the converter unit is a reactor, a switching element, a diode or a rectifying element composed of a synchronous rectifying switching element serving as a diode, and Any type of DC power converter (DC-DC converter) may be used as long as it has at least one output capacitor connected to the output wire. For example, DC power converters such as step-up, step-down, transformer insulation type, and interleave configuration type as shown in the circuit diagrams of FIGS. 11 to 23 may be used. 11 to 23, 20 represents an input electric wire, 21 represents an output electric wire, 2, 2a, 2b, 2c represent a reactor, a transformer functioning as a reactor, or a magnetically coupled reactor, 3, 3a, 3b, 3c and 3d represent switching elements, 4, 4a, 4b, 4c and 4d represent diodes as rectifier elements, 5 represents an output capacitor, 22, 22a and 22b represent charge / discharge capacitors, and 1 represents a DC power source. , 6 represents a load, and 7 represents a converter unit. 4, 4a, 4b, 4c, and 4d may be synchronous rectification switching elements instead of diodes. 11 to 23, the resistance component illustrated in FIGS. 1, 8, and 10 is omitted.

(3) In each of the above embodiments, the switching element 3 used for the DC power converter and the switching element 4 for synchronous rectification have been described as an example using a silicon (Si) semiconductor. However, the embodiment of the present invention is not limited to this. That is, a wide band gap semiconductor having a wider band gap than silicon (Si) may be used for some or all of the switching elements and diodes used in the DC power converter. For example, silicon carbide (SiC), a gallium nitride-based material, or diamond may be used as the wide band gap semiconductor. Wide bandgap semiconductors have a lower loss than silicon (Si) semiconductors, so that the switching frequency (PWM period) can be increased. The switching frequency and the control frequency (control cycle) have a correlation, and when the switching frequency is increased, the control frequency can be increased at the same time. As the control frequency increases, the follow-up speed of the estimation control increases, so that the effect of suppressing the voltage fluctuation of the output wire 21 at the time of dead time compensation or discontinuous mode operation is increased.

  In the present invention, the embodiments can be appropriately modified or omitted within the scope of the invention.

2 reactors, 3 switching elements, 4 switching elements for synchronous rectification (rectifier elements)
5, output capacitor, 7 converter unit, 13 control unit, 20 input wire, 21 output wire, capacity value of output capacitor, on / off duty ratio of D1 switching element, D1c feedback control duty ratio, D1e estimated control duty ratio, D1r duty Subtracted value, Dd dead time, sensing value of IL reactor current, estimated value of ILe reactor current, sensing value of current of Iout output wire, Le reactor inductance value, RLe reactor series resistance value, series equivalent of Rce output capacitor Resistance resistance value, Route load resistance value, Tc control cycle, Vin input wire voltage sensing value, Vout * target output voltage, Vout output wire voltage sensing value, Vout output wire voltage estimate, dIL Sensing value of differential value of current of dt reactor, estimated value of differential value of current of dILe / dt reactor, sensing value of differential value of voltage of dVout / dt output wire, estimation of differential value of voltage of dVoute / dt output wire Value, sensing value of change amount of current of ΔIL reactor, estimated value of change amount of current of ΔILe reactor, sensing value of change amount of voltage of ΔVout output wire, estimated value of change amount of voltage of ΔVout output wire

Claims (18)

A DC power converter that converts DC power between an input wire and an output wire,
A reactor, a switching element, a diode or a rectifying element comprising a synchronous rectifying switching element serving as a diode, and a converter unit having at least one output capacitor connected to the output wire;
A control unit for controlling on / off of the switching element,
The control unit calculates a sensing value of a target parameter that is a value, an integral value, a differential value, or a change amount of a voltage or current at a target location of the converter unit, and
When assuming that the current flow of the rectifier element is not limited when the switching element is controlled to be off, calculate the estimated value of the target parameter,
A DC power converter that performs an estimation control that changes an on / off duty ratio of the switching element so that a sensing value of the target parameter approaches an estimated value of the target parameter.   The DC power converter according to claim 1, wherein the control unit uses the current value, integral value, differential value, or change amount of the reactor as the target parameter. The control unit, the amount of change in the current of the reactor as the target parameter,
Based on the difference between the current sensing value of the reactor in the previous control cycle and the current sensing value of the reactor in the current control cycle, a sensing value of the amount of change in the reactor current as the target parameter is calculated.
Based on the sensing value of the voltage of the input wire, the sensing value of the voltage of the output wire, the on / off control information of the switching element, the inductance value of the reactor, and the control period, the current of the reactor as the target parameter The DC power converter according to claim 1 or 2, wherein an estimated value of the amount of change is calculated. The control unit sets the current value of the reactor as the target parameter,
Calculate the sensing current value of the reactor,
Based on the sensing value of the voltage of the input wire, the sensing value of the voltage of the output wire, the on / off control information of the switching element, and the inductance value of the reactor, the differential value or change of the current of the reactor as the target parameter The DC power conversion according to claim 1 or 2, wherein an estimated value of the reactor is calculated, and an estimated value of the current of the reactor as the target parameter is calculated by integrating or integrating the estimated value of the differential value or the change amount. vessel. The control unit uses a differential value of the current of the reactor as the target parameter,
Calculate the sensing value of the differential value of the reactor current,
Based on the sensing value of the voltage of the input wire, the sensing value of the voltage of the output wire, the on / off control information of the switching element, and the inductance value of the reactor, the differential value of the current of the reactor as the target parameter is estimated. The direct-current power converter according to claim 1 or 2 which calculates a value. The control unit calculates the estimated value of the target parameter using a DC equivalent resistance of the reactor and a reactor series resistance value that is a sum of resistance components connected in series to the reactor,
The direct-current power converter according to any one of claims 2 to 5, wherein the reactor series resistance value is set to a value larger than an actual value. The converter unit includes a plurality of conversion circuits including the reactor, the switching element, and the rectifying element,
The control unit performs interleave control to turn on instead of switching the switching elements of each set,
The reactor current is the target parameter,
Calculate the sensing value of the current of each reactor of the reactor,
Calculate an estimated value of the current of one reactor common to each set,
The on / off duty ratio of the switching element is changed according to any one of claims 2 to 6 so that a sensing value of the current of the reactor approaches a common estimated value of the current of the reactor for each set. DC power converter.   The DC power converter according to claim 1, wherein the control unit uses a voltage value, an integral value, a differential value, or a change amount of the output electric wire as the target parameter. The control unit, the amount of change in the voltage of the output wire as the target parameter,
Based on the difference between the sensing value of the voltage of the output wire in the previous control cycle and the sensing value of the voltage of the output wire in the current control cycle, a sensing value of the amount of change in the voltage of the output wire as the target parameter is obtained. Calculate
Based on the sensing value of the current of the reactor, the sensing value of the current of the output wire, the on / off control information of the switching element, the capacitance value of the output capacitor, and the control cycle, the voltage of the output wire as the target parameter The DC power converter according to claim 1 or 8, wherein an estimated value of the amount of change is calculated. The control unit sets the voltage value of the output wire as the target parameter,
Calculate the sensing value of the voltage of the output wire,
Based on the sensing value of the reactor current, the sensing value of the output wire current, the on / off control information of the switching element, and the capacitance value of the output capacitor, the differential value of the voltage of the output wire as the target parameter or The direct current according to claim 1 or 8, wherein an estimated value of the amount of change is calculated, and the estimated value of the voltage of the output wire as the target parameter is calculated by integrating or integrating the estimated value of the differential value or the amount of change. Power converter. The control unit, the differential value of the voltage of the output wire as the target parameter,
Calculate the sensing value of the differential value of the voltage of the output wire,
Based on the sensing value of the reactor current, the sensing value of the current of the output wire, the on / off control information of the switching element, the capacitance value of the output capacitor, and the control cycle, the voltage of the output wire as the target parameter The DC power converter according to claim 1 or 8, wherein an estimated value of the differential value is calculated. The control unit calculates an estimated value of the target parameter using a resistance value of a load connected to the output electric wire,
The DC power converter according to any one of claims 8 to 11, wherein a resistance value of the load is set to a value smaller than an actual value. The control unit calculates an estimated value of the target parameter using a resistance value of a series equivalent resistance of the output capacitor,
The DC power converter according to any one of claims 8 to 12, wherein a resistance value of the series equivalent resistance is set to a value larger than an actual value.   The said control part calculates the estimated value of the said object parameter using the relational expression of the voltage of the said input electric wire, the voltage of the said output electric wire, and the on-off control information of the said switching element. The direct-current power converter as described in any one of Claims.   The control unit calculates an estimated value of the target parameter using a relational expression of the current of the reactor, the current of the output wire, the on / off control information of the switching element, and the capacitance value of the output capacitor. The DC power converter according to any one of claims 8 to 13, which is performed.   In addition to the estimation control, the control unit provides a feedback control for changing the on / off duty ratio so that the sensing value of the voltage of the output wire approaches a target output voltage, and a proportionality factor for the sensing value of the current of the reactor. The DC power converter according to any one of claims 1 to 15, wherein duty subtraction for reducing the on / off duty ratio is performed by a multiplied value.   The DC power converter according to any one of claims 1 to 16, wherein the switching element and the switching element for synchronous rectification use a wide band gap semiconductor.   The DC power converter according to claim 17, wherein the wide band gap semiconductor uses silicon carbide, a gallium nitride-based material, or diamond.

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