JP5884345B2 - Resonant power converter - Google Patents

Description

 The present invention relates to a resonant power converter.

2. Description of the Related Art Conventionally, a SAZZ (Snubber Assisted Zero Voltage and Zero Current Transition) type chopper circuit is known as one form of a resonant power conversion device that realizes soft switching of a switching element using a resonance phenomenon (the following non-disclosure circuit). (See Patent Documents 1 and 2).
Also, in Patent Document 1 below, in a resonant power converter that employs the SAZZ method, a delay time from when the auxiliary switch is turned on until the voltage of the auxiliary capacitor (snubber capacitor) is minimized is calculated. A technique for realizing soft switching of the main switch by turning on the main switch after a lapse of time is disclosed.

Japanese Patent No. 439738

Ito, Tsuruda, Kawamura: "Circuit Constant Design Method for SAZZ Boost Chopper Circuit", 2005 IEEJ Industrial Application Conference, 1-48, pp.223-224, 2005 Tsuruda, Ito, Bando, Kawamura: “High-efficiency, high-frequency, high-output chopper circuit SAZZ”, 2006 IEEJ Industrial Application Conference, 1-86, pp.475-480, 2006

  In the above prior art, since the delay time is calculated based on the measured values of the input / output voltage and current and the circuit constants of the auxiliary reactor and the auxiliary capacitor, there is a variation in hardware characteristics such as the temperature characteristics of the circuit elements. For this reason, there is a problem that the ON timing difference (that is, the delay time) between the auxiliary switch and the main switch cannot be optimally controlled, and switching loss increases (efficiency decreases).

    The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a resonance type power converter that can realize optimal soft switching control without being affected by variations in hardware characteristics of circuit elements. To do.

 In order to achieve the above object, according to the present invention, as a first solution for a resonant power converter, a switch that turns on a main switch when the voltage of the auxiliary capacitor becomes minimum after turning on the auxiliary switch In the unidirectional resonant power converter including the control unit, the switch control unit sets the voltage of the auxiliary capacitor to a minimum when the voltage of the auxiliary capacitor becomes equal to or lower than a threshold value after the auxiliary switch is turned on. A method of detecting as a certain time is adopted.

 According to the present invention, as the second solving means relating to the resonance type power converter, the switch control unit includes a current sensor for detecting a primary side current value or a secondary side current value in the first solving means. Employs means for setting the threshold based on the primary side current value or the secondary side current value detected by the current sensor.

 Further, in the present invention, as a third solving means relating to the resonant power converter, in the second solving means, the switch control unit is configured to detect the primary side current value or the secondary side detected by the current sensor. A means of determining whether to operate the auxiliary switch based on a current value is adopted.

 Further, in the present invention, as a fourth solving means related to the resonant power converter, in the second or third solving means, a voltage sensor for detecting the voltage of the auxiliary capacitor is provided, and the switch control unit includes: When the voltage of the auxiliary capacitor detected by the voltage sensor is higher than the threshold, the delay time is increased or decreased according to the relationship between the current value and the previous value of the voltage of the auxiliary capacitor, and the voltage of the auxiliary capacitor is In the following cases, a means is adopted in which the main switch is turned on after the delay time has elapsed since the auxiliary switch was turned on.

 Further, in the present invention, as a fifth solving means relating to the resonance type power converter, in the fourth solving means, the switch control unit may detect the primary side current value or the secondary side detected by the current sensor. A means is adopted in which a maximum delay time and a minimum delay time are set based on a current value, and the delay time is limited to be not less than the minimum delay time or not more than the maximum delay time.

 The resonant power converter according to the present invention can realize optimum soft switching control without being affected by variations in hardware characteristics of circuit elements.

1 is a schematic configuration diagram of a resonant power converter according to a first embodiment. FIG. 4 is a control block diagram (a) of the main switch 20 and a control block diagram (b) of the auxiliary switch 24. FIG. 5 is a flowchart (a) showing a method for calculating a delay time Td in the present embodiment and a diagram (b) showing a time change of the snubber capacitor voltage Vc. It is a block schematic diagram of the resonance type power converter concerning a 2nd embodiment.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
[First Embodiment]
First, a first embodiment of the present invention will be described. FIG. 1 is a schematic configuration diagram of a resonant power converter according to the first embodiment. As shown in FIG. 1, the resonant power converter according to the first embodiment converts the output voltage V1 of the DC power source E into a desired voltage value V2 (V1 <V2) and supplies it to a load L. The unidirectional DC / DC converter includes a SAZZ step-up chopper circuit 1, a snubber voltage sensor 2, a primary side current sensor 3, a secondary side voltage sensor 4, and a switch control unit 5.

  The SAZZ boost chopper circuit 1 includes primary side terminals 11 and 12, secondary side terminals 13 and 14, a primary side smoothing capacitor 15, a secondary side smoothing capacitor 16, reactors 17 and 18, an output diode 19, The main switch 20, diodes 21 and 22, a snubber capacitor (auxiliary capacitor) 23, and an auxiliary switch 24 are included.

The primary side terminal 11 is connected to the positive terminal of the DC power source E, and the primary side terminal 12 is connected to the negative terminal and the secondary side terminal 14 of the DC power source E. The secondary side terminal 13 is connected to one end of the load L, and the secondary side terminal 14 is connected to the other end of the load L and the primary side terminal 12.
The primary side smoothing capacitor 15 has one end connected to the primary side terminal 11 and the other end connected to the primary side terminal 12. The secondary side smoothing capacitor 16 has one end connected to the secondary side terminal 13 and the other end connected to the secondary side terminal 14.

  Reactor 17 has one end connected to primary side terminal 11 and the other end connected to one end of reactor 18. Reactor 18 has one end connected to the other end of reactor 17 and the other end connected to the anode terminal of output diode 19. The output diode 19 has an anode terminal connected to the other end of the reactor 18 and a cathode terminal connected to the secondary terminal 13.

  The main switch 20 is, for example, an IGBT (Insulated Gate Bipolar Transistor), the collector terminal is connected to the anode terminal of the output diode 19, the emitter terminal is connected to the secondary side terminal 14, and the gate terminal is connected to the switch control unit 5. (The wiring is not shown). The main switch 20 is switched to an on state or an off state in accordance with a PWM (Pulse Width Modulation) signal input from the switch control unit 5 to the gate terminal.

  The diode 21 has an anode terminal connected to the other end of the reactor 18 and a cathode terminal connected to one end of the snubber capacitor 23. The diode 22 has an anode terminal connected to one end of the snubber capacitor 23 and a cathode terminal connected to the collector terminal of the auxiliary switch 24. The snubber capacitor (auxiliary capacitor) 23 has one end connected to the cathode terminal of the diode 21 and the anode terminal of the diode 22, and the other end connected to the secondary terminal 14.

  The auxiliary switch 24 is, for example, an IGBT, like the main switch 20, and has a collector terminal connected to the cathode terminal of the diode 22, an emitter terminal connected to the other end of the reactor 17, and a gate terminal connected to the switch control unit 5. (The wiring is not shown). The auxiliary switch 24 is switched to an on state or an off state in accordance with a PWM signal input from the switch control unit 5 to the gate terminal.

 The snubber voltage sensor 2 detects the voltage Vc of the snubber capacitor 23 and outputs an electric signal indicating the detection result to the switch control unit 5. The primary side current sensor 3 detects a current I1 (output current of the DC power supply E) flowing through the primary side terminal 11 and outputs an electrical signal indicating the detection result to the switch control unit 5. The secondary side voltage sensor 4 detects a voltage V <b> 2 (output voltage of the SAZZ boost chopper circuit 1) between the secondary side terminals 13 and 14, and outputs an electrical signal indicating the detection result to the switch control unit 5.

  The switch control unit 5 is a microcontroller that performs switching control of the main switch 20 and the auxiliary switch 24 based on output signals of the snubber voltage sensor 2, the primary side current sensor 3, and the secondary side voltage sensor 4. Outputs PWM signals having different duty ratios to the gate terminals of the main switch 20 and the auxiliary switch 24, respectively.

Next, the operation of the resonant power converter configured as described above will be described.
The operation principle of the resonance type power converter is already known as described in Japanese Patent No. 439738 and therefore will not be described in detail. However, the voltage of the snubber capacitor 23 is turned on after the auxiliary switch 24 is turned on. By turning on the main switch 20 when Vc becomes the minimum, soft switching of the main switch 20 can be realized.

  As already described, in the technique described in Japanese Patent No. 4397938, the on-timing difference between the auxiliary switch and the main switch is based on the measured values of the input / output voltage and current and the circuit constants such as the reactor and the snubber capacitor. Since (delay time Td) has been calculated, the delay time Td cannot be optimally controlled due to variations in hardware characteristics such as temperature characteristics of circuit elements, and switching loss increases (efficiency decreases). ).

  The resonant power converter according to the present embodiment is similar to the prior art in that the main switch 20 is turned on when the voltage Vc of the snubber capacitor 23 is minimized after the auxiliary switch 24 is turned on. The control method of the ON timing difference between the switch 24 and the main switch 20 (setting method of the delay time Td) is completely different.

  FIG. 2A is a control block diagram of the main switch 20, and FIG. 2B is a control block diagram of the auxiliary switch 24. Each control block shown in FIG. 2 is a visualization of software functions realized by the switch control unit 5 executing various arithmetic processes in accordance with a control program, and hardware corresponding to each control block. The circuit is not built in the switch control unit 5.

  As shown in FIG. 2A, the switch controller 5 includes a voltage controller 5a, a current controller 5b, and a main switch duty calculator 5c as software functions for controlling the main switch 20. .

The voltage control unit 5a is configured such that the primary side current command value is such that the deviation between the secondary side voltage value V2 detected by the secondary side voltage sensor 4 and the preset secondary side voltage command value V2ref becomes zero. I1ref is calculated by PI calculation.
The current control unit 5b calculates an operation amount such that the deviation between the primary side current value I1 detected by the primary side current sensor 3 and the primary side current command value I1ref obtained from the voltage control unit 5a is zero by PI calculation. calculate.
The main switch duty calculator 5c calculates the duty ratio Dm of the PWM signal to be output to the main switch 20 based on the operation amount obtained from the current controller 5b.

 On the other hand, as shown in FIG. 2B, the switch control unit 5 includes a delay time on / off determination unit 5d, a maximum delay time setting unit 5e, a minimum delay as software functions for controlling the auxiliary switch 24. A time setting unit 5f, a delay time calculating unit 5g, a delay time limiting unit 5h, an auxiliary switch operation switching unit 5i, and an auxiliary switch duty calculating unit 5j are provided.

 The delay time on / off determination unit 5d determines whether to set the delay time Td based on the primary side current value I1 detected by the primary side current sensor 3, in other words, whether to operate the auxiliary switch 24 in advance. Determine. Specifically, the delay time on / off determination unit 5d determines that the delay time Td is not set (the auxiliary switch 24 is not operated in advance) when the primary side current value I1 is equal to or less than a predetermined value. That is, when the primary side current value I1 is less than or equal to a certain value, even if the auxiliary switch 24 is operated in advance and soft switching of the main switch 20 is attempted, the effect of reducing the switching loss is small, so the auxiliary switch 24 is not operated in advance. The main switch 20 is hard-switched.

 The maximum delay time setting unit 5e sets the maximum delay time Tdmax based on the primary side current value I1 detected by the primary side current sensor 3. Specifically, table data indicating a correspondence relationship between the maximum delay time Tdmax (which may be a test value or a theoretical value) and the primary current value I1 is created in advance, and the maximum delay time setting unit 5e The maximum delay time Tdmax corresponding to the primary side current value I1 detected by the sensor 3 is acquired from the table data.

 The minimum delay time setting unit 5f sets the minimum delay time Tdmin based on the primary side current value I1 detected by the primary side current sensor 3. Specifically, table data indicating the correspondence relationship between the minimum delay time Tdmin (which may be a test value or a theoretical value) and the primary current value I1 is created in advance, and the minimum delay time setting unit 5f The minimum delay time Tdmin corresponding to the primary current value I1 detected by the sensor 3 is obtained from the table data.

 Based on the snubber capacitor voltage Vc detected by the snubber voltage sensor 2 and the primary side current value I1 obtained from the primary side current sensor 3, the delay time calculation unit 5g performs the snubber capacitor voltage Vc according to the flowchart shown in FIG. The delay time Td that minimizes is calculated.

 As shown in FIG. 3A, the delay time calculation unit 5g sets the threshold value Vcth of the snubber capacitor voltage Vc based on the primary current value I1 detected by the primary current sensor 3 (step S1). As shown in FIG. 3B, when the auxiliary switch 24 is turned on while the main switch 20 is kept in the off state, the snubber capacitor voltage Vc exhibits a behavior in which the snubber capacitor voltage Vc drops from the maximum value to the minimum value. The minimum value also changes depending on the current value I1. Therefore, the threshold value Vcth may be set to a value close to the minimum value of the snubber capacitor voltage Vc (a value that can be approximated to be the minimum) according to the primary side current value I1.

 Specifically, table data indicating a correspondence relationship between the threshold value Vcth of the snubber capacitor voltage Vc (this threshold value Vcth may be a test value or a theoretical value) and the primary side current value I1 is created in advance. The time calculator 5g sets the threshold value Vcth of the snubber capacitor voltage Vc corresponding to the primary current value I1 detected by the primary current sensor 3 using the table data.

 Further, when the delay time calculation unit 5g acquires the snubber capacitor voltage Vc from the snubber voltage sensor 2, the delay time calculation unit 5g substitutes the value of the variable Vc1 indicating the current value of Vc for the variable Vc0 indicating the previous value of Vc, and acquires the current value. The value of Vc is substituted for variable Vc1 (step S2). Then, the delay time calculation unit 5g determines whether or not the value of the variable Vc1, that is, the current value of the snubber capacitor voltage Vc is higher than the threshold value Vcth set in step S1 (step S3).

 If “Yes” in step S3 (when Vc1> Vcth), the delay time calculation unit 5g determines whether or not the difference value (= Vc1−Vc0) between the variable Vc1 and the variable Vc0 is greater than zero, that is, a snubber capacitor It is determined whether or not the current value of the voltage Vc is higher than the previous value (step S4).

When “Yes” is determined in Step S4 (when Vc1−Vc0> 0), the delay time calculation unit 5g calculates the change amount ΔTd of the delay time Td using the following equation (1) (Step S5). If “No” in step S4 (if Vc1−Vc0 ≦ 0), the process jumps to step S6.
ΔTd = −1 × ΔTd (1)

The delay time calculation unit 5g calculates the delay time Td using the following equation (2) when “No” in Step S4 or after the completion of Step S5 (Step S6).
Td = Td + ΔTd (2)

 On the other hand, if “No” in step S3, that is, if the current value of the snubber capacitor voltage Vc is less than or equal to the threshold value Vcth, the delay time calculation unit 5g omits the processes in steps S4, S5, and S6, The change of the time Td is stopped.

 Thus, when the current value of the snubber capacitor voltage Vc is higher than the threshold value Vcth and the current value of the snubber capacitor voltage Vc is equal to or lower than the previous value, it is estimated that the snubber capacitor Vc is decreasing toward the minimum value. When the current value of the capacitor voltage Vc is larger than the previous value, it is estimated that the snubber capacitor Vc is increasing. At this time, the descending speed or ascending speed of the snubber capacitor Vc varies depending on variations in hardware characteristics such as temperature characteristics of circuit elements.

 Therefore, in the above case, the delay time Td is increased / decreased at a constant rate (ΔTd) until the snubber capacitor voltage Vc becomes equal to or lower than the threshold value Vcth, so that the optimum delay time Td ( The time when the snubber capacitor voltage Vc becomes approximately minimum after the auxiliary switch 24 is turned on can be obtained.

The above is the description regarding the calculation process of the delay time Td by the delay time calculation unit 5g. Hereinafter, the description will be continued by returning to FIG.
The delay time limiting unit 5h is configured such that the delay time Td calculated by the delay time calculating unit 5g includes the maximum delay time Tdmax set by the maximum delay time setting unit 5e and the minimum set by the minimum delay time setting unit 5f. Limiting to be within the range of the delay time Tdmin. Specifically, when the delay time Td exceeds the maximum delay time Tdmax, the delay time Td is reset to the maximum delay time Tdmax, while when the delay time Td falls below the minimum delay time Tdmin, the delay time Td Is reset to the minimum delay time Tdmin.

  The auxiliary switch operation switching unit 5i switches the operation of the auxiliary switch 24 off when the delay time on / off determination unit 5d determines that the delay time Td is not set (the auxiliary switch 24 is not operated in advance), In other cases, the operation of the auxiliary switch 24 is switched on (the auxiliary switch duty calculation unit 5j is allowed to use the delay time Td).

  The auxiliary switch duty calculation unit 5j is configured based on the duty ratio Dm of the main switch 20 calculated by the main switch duty calculation unit 5c and the delay time Td obtained from the delay time limit unit 5h. The duty ratio Ds of the auxiliary switch 24 is calculated so that the on-timing difference from 20 becomes the delay time Td.

 When calculating the duty ratio Dm of the main switch 20 and the duty ratio Ds of the auxiliary switch 24 as described above, the switch control unit 5 generates a PWM signal having the duty ratio Dm and outputs the PWM signal to the main switch 20. A PWM signal having the ratio Ds is generated and output to the auxiliary switch 24.

 As a result, the main switch 20 and the auxiliary switch 24 perform the switching operation with the respective duty ratios, and the output of the DC power source E so that the secondary side voltage value V2 of the SAZZ boost chopper circuit 1 becomes the secondary side voltage command value V2ref. When the voltage V1 is boosted and the snubber capacitor voltage Vc is approximately minimized after the auxiliary switch 24 is turned on regardless of the variation in the hardware characteristics of each circuit element (after the elapse of the delay time Td). The main switch 20 is turned on.

 As described above, according to the resonant power conversion device according to the first embodiment, optimum soft switching control is realized without being affected by variations in hardware characteristics of each circuit element constituting the SAZZ boost chopper circuit 1. can do.

[Second Embodiment]
Next, a second embodiment of the present invention will be described. FIG. 4 is a schematic configuration diagram of a resonance type power converter according to the second embodiment. As shown in FIG. 4, the resonant power converter according to the second embodiment converts the output voltage V1 of the DC power source E into a desired voltage value V2 (V1> V2) and supplies it to the load L. The unidirectional DC / DC converter includes a SAZZ step-down chopper circuit 100, a snubber voltage sensor 200, a primary side current sensor 300, a secondary side voltage sensor 400, and a switch control unit 500.

  SAZZ step-down chopper circuit 100 includes primary side terminals 101 and 102, secondary side terminals 103 and 104, primary side smoothing capacitor 105, secondary side smoothing capacitor 106, reactors 107 and 108, main switch 109, The snubber capacitor 110, diodes 111, 112, and 113, and an auxiliary switch 114 are included.

  The primary side terminal 101 is connected to the positive terminal of the DC power source E, and the primary side terminal 102 is connected to the negative terminal and the secondary side terminal 104 of the DC power source E. The secondary side terminal 103 is connected to one end of the load L, and the secondary side terminal 104 is connected to the other end of the load L and the primary side terminal 102. The primary side smoothing capacitor 105 has one end connected to the primary side terminal 101 and the other end connected to the primary side terminal 102. The secondary smoothing capacitor 106 has one end connected to the secondary terminal 103 and the other end connected to the secondary terminal 104.

  Reactor 107 has one end connected to secondary terminal 103 and the other end connected to one end of reactor 108. Reactor 108 has one end connected to the other end of reactor 107 and the other end connected to the emitter terminal of main switch 109.

  The main switch 109 is, for example, an IGBT (Insulated Gate Bipolar Transistor), a collector terminal is connected to the primary terminal 101, an emitter terminal is connected to the cathode terminal of the diode 111, and a gate terminal is connected to the switch control unit 500. (The wiring is not shown). The main switch 109 is switched to an on state or an off state in accordance with a PWM signal input from the switch control unit 500 to the gate terminal.

  The snubber capacitor 110 has one end connected to the primary terminal 101 and the other end connected to the anode terminal of the diode 112. The diode 111 has an anode terminal connected to the primary terminal 102 and a cathode terminal connected to the emitter terminal of the main switch 109. The diode 112 has an anode terminal connected to the other end of the snubber capacitor 110 and a cathode terminal connected to the emitter terminal of the main switch 109. The diode 113 has an anode terminal connected to the emitter terminal of the auxiliary switch 114 and a cathode terminal connected to the other end of the snubber capacitor 110.

  The auxiliary switch 114 is, for example, an IGBT, like the main switch 109, and has a collector terminal connected to one end of the reactor 108, an emitter terminal connected to the anode terminal of the diode 113, and a gate terminal connected to the switch control unit 500. (The wiring is not shown). The auxiliary switch 114 is switched to an on state or an off state in accordance with a PWM signal input from the switch control unit 500 to the gate terminal.

 The snubber voltage sensor 200 detects the voltage Vc of the snubber capacitor 110 and outputs an electrical signal indicating the detection result to the switch control unit 500. The primary side current sensor 300 detects a current I1 (output current of the DC power supply E) flowing through the primary side terminal 101 and outputs an electrical signal indicating the detection result to the switch control unit 500. The secondary side voltage sensor 400 detects a voltage V <b> 2 between the secondary side terminals 103 and 104 (output voltage of the SAZZ step-down chopper circuit 100), and outputs an electrical signal indicating the detection result to the switch control unit 500.

  The switch control unit 500 is a microcontroller that performs switching control of the main switch 109 and the auxiliary switch 114 based on output signals of the snubber voltage sensor 200, the primary side current sensor 300, and the secondary side voltage sensor 400. Outputs PWM signals having different duty ratios to the gate terminals of the main switch 109 and the auxiliary switch 114, respectively.

 In the resonant power converter according to the second embodiment configured as described above, the control method of the ON timing difference between the auxiliary switch 114 and the main switch 109 (setting method of the delay time Td) is the same as that of the first embodiment. Since there is, explanation regarding the control method is omitted.

 According to the resonant power conversion device according to the second embodiment as described above, similarly to the first embodiment, without being affected by variations in hardware characteristics of each circuit element constituting the SAZZ step-down chopper circuit 100, Optimal soft switching control can be realized.

In addition, this invention is not limited to the said 1st and 2nd embodiment, In the range which does not deviate from the meaning of this invention, it can change variously.
For example, in the first and second embodiments, the threshold Vcth, the maximum delay time Tsmax, and the minimum delay time Tdmin are set based on the primary current value I1 of the SAZZ step-up chopper circuit 1 or the SAZZ step-down chopper circuit 100. Although the case where the setting and the on / off determination of the delay time Td are performed is illustrated, the secondary side current value (current flowing between the secondary side terminals) may be used instead of the primary side current value I1.

 DESCRIPTION OF SYMBOLS 1 ... SAZZ step-up chopper circuit, 100 ... SAZZ step-down chopper circuit, 2, 200 ... Snubber voltage sensor, 3, 300 ... Primary side current sensor 4, 400 ... Secondary side voltage sensor 5, 500 ... Switch control part

Claims (4)

In the unidirectional resonance type power converter including a switch control unit that turns on the main switch when the voltage of the auxiliary capacitor becomes minimum after turning on the auxiliary switch,
It has a current sensor that detects the primary side current value or the secondary side current value,
The switch control unit detects a time when the voltage of the auxiliary capacitor becomes equal to or lower than a threshold value after turning on the auxiliary switch as a time when the voltage of the auxiliary capacitor becomes the minimum, and the primary detected by the current sensor The threshold value is set based on a side current value or a secondary side current value . The said switch control part determines whether the said auxiliary | assistant switch is operated based on the said primary side current value or the secondary side current value detected by the said current sensor. Resonant power converter. A voltage sensor for detecting the voltage of the auxiliary capacitor;
When the voltage of the auxiliary capacitor detected by the voltage sensor is higher than the threshold, the switch control unit increases or decreases the delay time according to the relationship between the current value and the previous value of the voltage of the auxiliary capacitor. 3. The resonant power conversion according to claim 1, wherein when the voltage of the capacitor becomes equal to or lower than the threshold, the main switch is turned on after the delay time elapses after the auxiliary switch is turned on. apparatus. The switch control unit sets a maximum delay time and a minimum delay time based on the primary side current value or the secondary side current value detected by the current sensor, and the delay time is greater than or equal to the minimum delay time or the maximum delay time. 4. The resonance type power converter according to claim 3, wherein the resonance type power converter is limited to be equal to or shorter than the delay time .

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