JP5978146B2 - Power supply system and power supply device - Google Patents

Description

  The present invention relates to a power supply system and a power supply device, and more particularly to a power supply system including a plurality of power supply devices connected in series and a power supply device constituting such a power supply system.

  A regenerative power supply device (regenerative charge / discharge device) is used for a charge / discharge test of a hybrid car battery or the like. Recently, a power supply device of this type has been developed that realizes series-parallel expansion. (For example, refer nonpatent literature 1). Series-parallel expansion is the use of multiple power supply units of the same type connected in series or in parallel, which makes it possible to perform charge / discharge tests with voltage and current values exceeding the rating of each power supply unit. Become.

pCUBE (registered trademark) catalog, [online], Myway Plus Co., Ltd., [Search May 9, 2012], Internet <URL: http://www.myway.co.jp/products/pcube.html>

  However, if a plurality of regenerative charge / discharge devices described above are connected in series and used as one constant current source, the risk of failure of the power supply device may increase, or some regenerative charge / discharge devices may The load may become temporarily excessive. Hereinafter, it will be described in detail with reference to the drawings.

FIG. 13 is a diagram showing a power supply system 1a configured by connecting three power supply devices 2a to 2c, each of which is a regenerative charge / discharge device, in series. When this power supply system 1a is used for the charge / discharge test of the load 3, it is necessary to control these so that each of the power supply apparatuses 2a to 2c outputs a current equal to the current command value I ^* supplied from the outside. As shown in the figure, the simplest control method for realizing this is that the current command value I ^* is supplied to each of the power supply devices 2a to 2c and detected by a built-in ammeter for each power supply device. Current control (CC control) is performed so that the monitor current value of the output current becomes equal to the current command value I ^* . Although this method is simple, there is actually a risk of failure of the power supply device and it cannot be used.

  explain in detail. Since the power supply apparatuses 2a to 2c are connected in series, the current values of the respective output currents are equal to each other. In FIG. 13, this is Iout. However, the monitor current values detected by the built-in ammeters of the power supply devices 2a to 2c are not necessarily equal to each other. In the example of FIG. 13, the monitor current value input to the power supply devices 2b and 2c is Iout, whereas the monitor current value input to the power supply device 2a is Iout−α. This difference is due to a detection error in the built-in ammeter.

Referring to the example of FIG. 13, since the power supply device 2a has a monitor current value smaller than the normal value, if Iout is equal to the current command value I ^* , the output current is increased. Current control is performed in the direction. As a result, Iout becomes larger than the current command value I ^* . Then, current control in a direction to reduce the output current is performed by the power supply devices 2b and 2c to which the correct monitor current value is supplied. As a result, Iout decreases and approaches the current command value I ^*, and accordingly, the power supply device 2a again performs current control in a direction to increase the output current. That is, since the power supply device 2a continues to increase the output current and the power supply devices 2b and 2c continue to decrease the output current, the load on the power supply devices 2a to 2c becomes excessive and the risk of failure increases.

  Accordingly, one of the objects of the present invention is to provide a power supply system that can reduce the risk of failure of each power supply apparatus when a plurality of power supply apparatuses are connected in series, and a power supply apparatus that realizes such a power supply system. is there.

  On the other hand, as one of the methods for solving such problems, a master / slave configuration is adopted in which one of a plurality of power supply devices connected in series is a master and the other is a slave. A configuration in which voltage control (CV control) is performed so that the current control similar to the above is performed and the output voltage of the slave power supply device becomes equal to the monitor voltage value of the output voltage of the power supply device that is the master is conceivable. According to this configuration, the power supply apparatuses 2b and 2c perform an operation in accordance with the power supply apparatus 2a. Therefore, unlike the power supply system 1a, the output current is not continuously increased or decreased. However, even if such a configuration is adopted, if the current command value changes greatly, the load on the power supply device that is a master may become excessive, although temporarily. This will be described in detail below.

FIG. 14 is a diagram showing a power supply system 1b obtained by changing the configuration of the power supply system 1a shown in FIG. 13 to the master / slave configuration described above. In the power supply system 1b, the power supply device 2a is a master, and the power supply devices 2b and 2c are slaves. In the power supply device 2a which is a master, the same current control as that in the power supply system 1a is performed. On the other hand, in the power supply apparatuses 2b and 2c as slaves, the monitor voltage value Vout ₂ of the output voltage detected by the built-in voltmeter is equal to the monitor voltage value Vout ₁ of the output voltage of the power supply apparatus 2a for each power supply apparatus. Thus, voltage control is performed.

  FIG. 15 is a diagram illustrating functional blocks of the power supply devices 2a to 2c constituting the power supply system 1b. As shown in the figure, each of the power supply apparatuses 2a to 2c includes a main circuit 4 that generates DC power and a current control unit 5 that performs current control. Each of the power supply devices 2b and 2c further includes a voltage control unit 6 that performs voltage control.

The main circuit 4 is a switching power supply that generates DC power from system power supplied from a system power supply (not shown). The modulation factor (open / close ratio) of the switch elements constituting the switching power supply is controlled by the modulation factor m supplied from the current control unit 5. The current control unit 5 of the power supply device 2a generates the modulation factor m so that the current command value I ^* supplied from the outside is equal to the monitor current value Iout. Thereby, the current value of the output current of the power supply device 2a becomes equal to the current command value I ^* . However, if there is an error in the monitor current value as described above, the output current will deviate from the current command value I ^{* by the} error.

Power supply 2b, the voltage control unit 6 of 2c, each monitor voltage value Vout ₂ and that is equal to the monitor voltage value Vout ₁ output voltage of the power supply 2a, to generate an internal current command value ^I _{* i.} Then, the current control unit 5 of the power supply devices 2b and 2c generates the modulation factor m so that the internal current command value I ^* _i is equal to each monitor current value Iout. As a result of these controls, the output voltages of the power supply devices 2a to 2c are equal to each other.

Here, the current control is performed in the power supply devices 2b and 2c for the convenience of design and the like. As a result, as shown in FIG. A feedback loop (feedback of the monitor current value Iout and feedback of the monitor voltage value Vout ₂ ) is used. In such a case, the control of the feedback loop located outside is delayed with respect to the feedback loop located inside, so that when the current command value I ^* changes, the output voltages of the power supply devices 2b and 2c become stable. Takes a longer time than the time required for the output current of the power supply device 2a to stabilize.

This is because, for example, when the current command value I ^* rises rapidly, the power supply device 2a alone covers the current command value I ^* for a while (until the output voltages of the power supply devices 2b and 2c become sufficiently large). This means that a sufficient voltage must be output. In some cases, the output voltage of the power supply device 2a may exceed the rating. As described above, when the current command value I ^* changes greatly, the power supply system 1b may temporarily become overloaded with the power supply device 2a, and improvement is required.

  Therefore, another object of the present invention is to provide a power supply system that can suppress an increase in the load of the master power supply apparatus when the current command value changes greatly, and a power supply apparatus that realizes such a power supply system. is there.

  In order to achieve the above object, a power supply system according to the present invention includes first and second power supply devices connected in series, and the first power supply device performs first feedback current control based on a current command value. A first current control unit configured to generate a modulation rate; and a first main circuit configured to generate DC power based on the first modulation rate. A second current control unit that generates a second modulation factor by current control obtained by combining feedback control based on a related internal current command value and feedforward control based on a physical quantity related to the first power supply device; And a second main circuit that generates DC power based on the second modulation factor.

  According to the present invention, since the feedforward control based on the physical quantity related to the first power supply device is incorporated in the generation process of the second modulation factor, the first power supply device and the second power supply device are in opposite directions. Therefore, it is possible to suppress the occurrence of a situation where the control is continued. Therefore, the failure risk of the first and second power supply devices can be reduced.

  In the above power supply system, the second power supply device may further include a voltage control unit that generates the internal current command value by feedback voltage control based on an output voltage of the first power supply device. In this case, further, the physical quantity is the current command value, and the second current control unit adds a result of adding the physical quantity to a deviation between the internal current command value and the output current of the second power supply device. The second modulation factor may be generated by current control as an input value (first embodiment described later), the physical quantity is the first modulation factor, and the second current The control unit adds a result of adding the physical quantity to a third modulation factor obtained by current control using an input value as a deviation between the internal current command value and the output current of the second power supply device. It is good also as outputting as a rate (2nd Embodiment mentioned later).

  When the second power supply device is configured to generate the internal current command value by feedback voltage control based on the output voltage of the first power supply device, the failure risk of the first and second power supply devices also by itself. However, as described above, the load on the master power supply device when the current command value changes greatly may increase. In this respect, the physical quantity related to the first power supply device is directly reflected in the generation process of the second modulation factor by performing the above, so that the output of the second power supply device after the current command value changes greatly. The time until the voltage stabilizes can be shortened. Therefore, an increase in the load on the first power supply device that is the master can be suppressed.

  In the power supply system, the physical quantity is an output voltage of the first power supply device, and the second main circuit is configured to convert the first DC voltage to the second DC voltage based on the second modulation factor. The second current control unit is based on the internal current command value, and includes a DC / DC converter that generates the output, an output end, and an inductance provided between the DC / DC converter and the output end. Based on a PID control unit that generates a potential difference between both ends of the inductance by PID control, a result of adding the physical quantity to the potential difference between both ends generated by the PID control unit, and the first DC voltage. A modulation rate calculation unit that calculates the modulation rate may be included (third and fifth embodiments described later). According to this, the second main circuit generates a second DC voltage from the first DC voltage based on the second modulation factor, the output terminal, the DC / DC converter, and the output When configured to include an inductance provided between the first and second ends, the risk of failure of the first and second power supply devices can be reduced.

  In this power supply system, the PID control unit may generate the potential difference between both ends by current control using an input value as a deviation between the internal current command value and the output current of the second power supply device. Furthermore, the second power supply device may further include a voltage control unit that generates the internal current command value by feedback voltage control based on the output voltage of the first power supply device (a third implementation described later). The internal current command value may be the current command value (fifth embodiment to be described later).

  In the power supply system, the physical quantity includes a first physical quantity that is the current command value and a second physical quantity that is an output voltage of the first power supply device, and the second main circuit includes: A DC / DC converter that generates a second DC voltage from the first DC voltage based on the second modulation factor, an output terminal, and an inductance provided between the DC / DC converter and the output terminal And the second current control unit is configured to perform current control with an input value obtained by adding the first physical quantity to a deviation between the internal current command value and the output current of the second power supply device. A PID control unit that generates a potential difference between both ends of the inductance, a result obtained by adding the first physical quantity to the potential difference between the both ends generated by the PID control unit, and the second DC voltage based on the first DC voltage Modulation rate Modulation factor calculating unit that calculates and may be as having a (fourth embodiment to be described later). In this case, the second power supply device may further include a voltage control unit that generates the internal current command value by feedback voltage control based on the output voltage of the first power supply device.

  Each of the power supply systems may further include a third power supply device having the same internal configuration as the second power supply device, and the first to third power supply devices may be connected in series.

  Further, the power supply device according to the present invention includes a first current control unit that generates a first modulation factor by feedback current control based on a current command value, and a first current that generates DC power based on the first modulation factor. A feedback control based on an internal current command value related to the current command value and a feedforward control based on a physical quantity related to the first power supply device. And a second main circuit that generates DC power based on the second modulation factor. The second current control unit generates a second modulation factor by current control.

  According to the present invention, since the feedforward control based on the physical quantity related to the first power supply device is incorporated in the generation process of the second modulation factor, the first power supply device and the second power supply device are in opposite directions. Therefore, it is possible to suppress the occurrence of a situation where the control is continued. Therefore, the failure risk of the first and second power supply devices can be reduced.

  In addition, since the time until the output voltage of the second power supply device stabilizes after the current command value largely changes can be shortened, the feedback voltage based on the output voltage of the first power supply device is used as the second power supply device. Even when the internal current command value is generated by the control, it is possible to suppress an increase in the load of the first power supply device that is the master.

1 is a schematic block diagram showing a system configuration of a power supply system according to a preferred first embodiment of the present invention. It is a schematic block diagram which shows the functional block of the power supply device by preferable 1st Embodiment of this invention. It is a schematic block diagram which shows an example of the functional block inside the main circuit by the preferable 1st Embodiment of this invention. It is a schematic block diagram which shows the system configuration | structure of the power supply system by preferable 2nd Embodiment of this invention. It is a schematic block diagram which shows the functional block of the power supply device by preferable 2nd Embodiment of this invention. It is a schematic block diagram which shows the system configuration | structure of the power supply system by preferable 3rd Embodiment of this invention. It is a schematic block diagram which shows an example of the functional block inside the main circuit by preferable 3rd Embodiment of this invention. It is a schematic block diagram which shows the functional block of the power supply device by preferable 3rd Embodiment of this invention. It is a schematic block diagram which shows the system configuration | structure of the power supply system by preferable 4th Embodiment of this invention. It is a schematic block diagram which shows the functional block of the power supply device by preferable 4th Embodiment of this invention. It is a schematic block diagram which shows the system configuration | structure of the power supply system by preferable 5th Embodiment of this invention. It is a schematic block diagram which shows the functional block of the power supply device by preferable 5th Embodiment of this invention. It is a figure which shows the power supply system by the background art of this invention. It is a figure which shows the other power supply system by the background art of this invention. It is a figure which shows the functional block of the power supply device which comprises the power supply system shown in FIG.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a schematic block diagram showing a system configuration of a power supply system 10 according to the first embodiment of the present invention. The figure also shows a load 20 that is a supply destination of DC power generated by the power supply system 10. Specific examples of the load 20 include a motor for a hybrid car or an electric vehicle, a battery for a hybrid car or an electric vehicle, a solar cell, and an electric double layer capacitor.

  The power supply system 10 includes three power supply devices 11a to 11c (first to third power supply devices) connected in series. Each of these power supply devices 11a to 11c is the regenerative charging / discharging device described above, and has the same hardware configuration. The power supply system 10 is configured to output three times the rated output voltage of each power supply by connecting the three power supply apparatuses 11a to 11c in series. In addition, the power supply system 10 is configured to have a function as a DC power supply device that generates DC power and supplies the DC power to the load 20 to be tested, and a function to absorb power regenerated from the load 20.

In the power supply system 10, the power supply device 11a is used as a master, and the power supply devices 11b and 11c are used as slaves. That is, the power supply device 11a controls its output current so that the current command value I ^* supplied from a control PC (not shown ⁾ and the monitor current value Iout of its output current are equal (current control). ). In this way, the control of the output value performed so that the command value and the output value are equal is referred to as “feedback control”. In contrast, the power supply device 11b, 11c, respectively, the monitor voltage value Vout ₁ output voltage of the power supply 11a, and a monitor voltage value Vout ₂ of its output voltage to control its output voltage to be equal ( Voltage control). The power supply apparatuses 11b and 11c are slaves of the power supply apparatus 11a in that the monitor voltage value Vout ₁ is used as a command value for voltage control. This voltage control is also the above “feedback control”.

Each of the power supply devices 11b and 11c has its own output so that the internal voltage command value I ^* _i generated as a result of the voltage control in addition to the voltage control is equal to the monitor voltage value Iout of its output current. It is configured to control current (current control). This current control is also the “feedback control”. Each of the power supply apparatuses 11b and 11c also performs control based on a physical quantity related to the power supply apparatus 11a. This control is to control various physical quantities relating to itself based on the physical quantities relating to the power supply device 11a, and such control is referred to as “feedforward control”. The “physical quantity related to the power supply device 11a” in the present embodiment is the current command value I ^* supplied to the power supply device 11a.

  Hereinafter, these controls performed by the power supply apparatuses 11a to 11c will be described in more detail with reference to a functional block diagram.

FIG. 2 is a schematic block diagram showing functional blocks of the power supply apparatuses 11a to 11c. As shown in the figure, the functional blocks are different between the power supply device 11a as a master and the power supply devices 11b and 11c as slaves. Specifically, the power supply device 11a includes a main circuit 12 ₁ (first main circuit) that generates DC power and a current control unit 13 ₁ (first current control unit) that performs current control. Yes. Each of the power supply devices 11b and 11c has a main circuit 12 ₂ (second main circuit) that generates DC power, a current control unit 13 ₂ (second current control unit) that performs current control, and voltage control. And a voltage control unit 14 to perform. Current control unit 13 ₂ includes a current control unit 16 therein.

FIG. 3 is a schematic block diagram showing an example of functional blocks inside the main circuits 12 ₁ and 12 ₂ . The configuration shown in the figure is an example of the internal configuration of the main circuits 12 ₁ and 12 ₂ , and other configurations can be adopted. Moreover, the system | strain power supply 30 which supplies system | strain electric power to the power supply devices 11a-11c is also illustrated in the figure. As the system power, for example, a three-phase 200V commercial AC power supply can be used. In the following description focuses on the main circuit 12 _1, the same applies to the main circuit 12 _2.

The main circuit 12 ₁ is a switching power supply for generating a DC power from the system power supplied from the system power supply 30, as shown in FIG. 3, AC / DC converter 31, an insulating DC / DC converter 32, and the three-phase DC / DC converter 33 is comprised. The AC / DC converter 31 is a circuit that generates DC power from the system power. Although not shown, the insulated DC / DC converter 32 is a bidirectional converter including two inverters and a transformer provided between them, and receives the output of the AC / DC converter 31. Configured to work. By including the transformer, the isolated DC / DC converter 32 can boost or step down the output voltage of the AC / DC converter 31 and also can electrically isolate the two inverters. The three-phase DC / DC converter 33 is configured to operate in response to the output of the isolated DC / DC converter 32. The output of the three-phase DC / DC converter 33 becomes the output of the power supply device 11a.

Although not shown, the AC / DC converter 31, the insulated DC / DC converter 32, and the three-phase DC / DC converter 33 each include a plurality of switch elements therein. Opening and closing of these switching elements is controlled by the modulation index m ₁ supplied from the current control section 13 _1. Thereby, it is possible to control the output of the power supply device 11a under the control of the modulation index m _1.

Returning to FIG. Current control unit 13 ₁ is a circuit that generates a modulation ratio m _{1 (first} modulation ratio) by the current control based on the current command value I ^* (feedback control). In this current control, the modulation factor m ₁ is generated so that the current command value I ^* is equal to the monitor current value Iout detected by the built-in ammeter. Specifically, as shown in FIG. 2, the modulation factor m ₁ is generated by current control using the deviation between the current command value I ^* and the monitor current value Iout as an input value. Further, specifically, P control, PI control, PID control, or the like is preferably used as the current control. This also applies to various current control and voltage control described later.

Since the built-in ammeter has an error as described above, the monitor current value Iout is not necessarily equal to the actual current value of the output current of the power supply device 11a. However, since the power supply system 10 according to the present embodiment adopts a master / slave configuration like the power supply system 1b shown in FIG. 14 and realizes a feedback loop located outside by voltage control, each difference is caused by this difference. The power supply devices 11a to 11c do not continuously increase or decrease the output current, and the influence thereof is that there is an error between the current command value I ^* and the actual current value of the output current of the power supply device 11a. It will only occur. Therefore, the difference between the monitor current value Iout and the actual current value of the output current of the power supply device 11a is ignored here. The same applies to other built-in ammeters and built-in voltmeters mentioned below.

Voltage control unit 14, the voltage control of the voltage value of the output voltage of the power supply device 11a and the voltage command value V ^* (feedback control) circuit for generating an internal current command value I ^* _i related to the current command value I ^* It is. The voltage value of the output voltage of the power supply device 11a here is a monitor voltage value Vout ₁ detected by a voltmeter built in the power supply device 11a. In this voltage control, a monitor voltage value Vout _1, power supply 11b, 11c so that the monitor voltage value Vout ₂ detected by the respective internal voltmeter equal, the internal current command value ^I _{* i} is generated. Specifically, as shown in FIG. 2, the internal current command value I ^* is generated by voltage control using the deviation between the monitor voltage value Vout ₁ and the monitor voltage value Vout ₂ as an input value.

Current control unit 13 _2, the feedback control based on the internal current command value I ^* _i, the current control comprising a combination of feedforward control based on ^(a physical quantity related to power supply 11a) the current instruction value I ^*, any modulation ratio m ₂ This is a circuit for generating (second modulation factor). Specifically, the current command value I ^* is added to the deviation between the internal current command value I ^* _i and the monitor current value Iout detected by the built-in ammeter (feed-forward control), and the result is indicated by the current control unit 16. To supply. The current control unit 16 generates the modulation factor m ₂ by current control using the supplied addition result as an input value (feedback control).

As described above, according to the power supply system 10 according to this embodiment, the process of generating the modulation ratio m _2, the feedforward control is incorporated based on the current command value I ^*. Further, the power supply system 10 according to the present embodiment adopts a master / slave configuration like the power supply system 1b shown in FIG. 14, and realizes a feedback loop located outside by voltage control. Therefore, it is possible to suppress the occurrence of a situation in which the power supply device 11a and the power supply devices 11b and 11c continue to be controlled in opposite directions, so that the risk of failure of the power supply devices 11a to 11c can be reduced.

Further, since the current command value I ^* is reflected directly in the process of generating the modulation ratio m _2, the power supply device 11b from greatly changes the current command value I ^*, the output voltage of 11c is the time until stabilized, This is shortened compared to the conventional power supply devices 2b and 2b shown in FIG. Therefore, since the time required for the power supply device 11a as a master to output a voltage sufficient to cover the current command value I ^* is shortened, the power supply device 11a temporarily changes with the change of the current command value I ^*. Increase in load is suppressed.

FIG. 4 is a schematic block diagram showing a system configuration of the power supply system 10 according to the second embodiment of the present invention. The power supply system 10 according to the present embodiment is different from the power supply system 10 according to the first embodiment in that the modulation factor m ₁ is used instead of the current command value I ^* as the “physical quantity related to the power supply device 11a”. Hereinafter, the differences will be mainly described in detail.

FIG. 5 is a schematic block diagram showing functional blocks of the power supply devices 11a to 11c according to the present embodiment. As shown in FIG. 4 and FIG. 4, in the present embodiment, the modulation factor m ₁ is supplied from the master power supply device 11a to the slave power supply devices 11b and 11c. The current command value I ^* ₁ is not directly supplied to the power supply devices 11b and 11c.

Current control unit 16 provided inside the current controller 13 _2, and the internal current command value I ^* _i, the current control to the input value of the deviation between the monitor current value Iout that is detected by the built-in ammeter, modulation rate m ₃ (third modulation factor) is generated (feedback control). The current control unit 13 _2, the modulation factor _{m 3,} by adding the modulation ratio _{m 1} supplied from the power supply 11a (feed forward control), the modulation factor _m 1 + _{m 3} obtained as a result, the modulation ratio _{m 2} as supplied to the main circuit 12 _2.

As described above, according to power supply system 10 according to the present embodiment, feedforward control based on modulation factor m ₁ is incorporated in the generation process of modulation factor m ₂ . The power supply system 10 according to the present embodiment also employs a master / slave configuration as in the first embodiment, and realizes a feedback loop located outside by voltage control. Therefore, it is possible to suppress the occurrence of a situation in which the power supply device 11a and the power supply devices 11b and 11c continue to be controlled in opposite directions, so that the risk of failure of the power supply devices 11a to 11c can be reduced.

Also, since the modulation factor m ₁ are those current control section 13 ₁ of the power supply device 11a is generated based directly on the current command value I ^*, the delay for the current command value I ^* of the modulation factor m ₁ is the modulation index m It is smaller than that of ₃ . Therefore, it means that change in the current command value I ^* is supplied to the rapidly main circuit 12 ₂ in comparison with the conventional power supply device 11b from greatly changes the current command value I ^*, the output voltage of 11c stability The time until conversion is shortened compared to the conventional one (power supply devices 2b and 2b shown in FIG. 14). Therefore, a temporary load increase of power supply device 11a accompanying a change in current command value I ^* is suppressed.

FIG. 6 is a schematic block diagram showing a system configuration of the power supply system 10 according to the third embodiment of the present invention. The power supply system 10 according to the present embodiment is different from the power supply systems 10 according to the first and second embodiments in that the monitor voltage value Vout ₁ is used as “physical quantity related to the power supply device 11a”. The specific configuration of the main circuits 12 ₁ and 12 ₂ is different from that described in the first and second embodiments (see FIG. 3). Hereinafter, the differences will be mainly described in detail.

_First , a specific configuration of the main circuits 12 ₁ and 12 ₂ will be described. FIG. 7 is a schematic block diagram showing an example of functional blocks in the main circuits 12 ₁ and 12 ₂ according to the present embodiment. As shown in the figure, the main circuits 12 ₁ and 12 ₂ according to the present embodiment include a DC / DC converter 35 that generates a DC voltage Vdc_out by receiving a DC voltage Vdc_in as system power from an external electrolytic capacitor. configured to include a pair of output ends ₃₆ 1, 36 _2, the inductance 37 is provided between the DC / DC converter 35 and the output terminal 36 _1. The output voltage Vout of the main circuits 12 ₁ and 12 ₂ is a potential difference between the output terminals 36 ₁ and 36 _{2. When} the potential difference between both ends of the inductance 37 is a potential difference ΔV, Vout = Vdc_out−ΔV.

Although not shown, the DC / DC converter 35 includes a plurality of switch elements therein. That is, the main circuits 12 ₁ and 12 ₂ according to the present embodiment are also switching power supplies as in the first embodiment. Opening and closing of each switch element of the DC / DC converter 35, the modulation factor by the modulation index _{m 1} supplied from the main circuit 12 _1, the current control section 13 ₁ is supplied from the main circuit 12 ₂ in the current control unit 13 ₂ Each is controlled by m ₂ . As a result, the outputs of the power supply devices 11a to 11c can be controlled by controlling the modulation factors m ₁ and m ₂ .

Next, FIG. 8 is a schematic block diagram showing functional blocks of the power supply apparatuses 11a to 11c according to the present embodiment. As shown in FIG. 6 and FIG. 6, in the present embodiment, only the monitor voltage value Vout ₁ is supplied from the master power supply device 11a to the slave power supply devices 11b and 11c.

Current control unit 16 provided inside the current controller 13 _2, as shown in FIG. 8, and a PID operation unit 17 and a modulation factor calculating unit 18. The PID calculation unit 17 has a function of generating a potential difference ΔV between both ends of the inductance 37 shown in FIG. 7 by PID control based on the internal current command value I ^* _i . More specifically, the PID calculation unit 17 generates a potential difference ΔV at both ends by current control using the deviation between the internal current command value I ^* _i and the monitor current value Iout detected by the built-in ammeter as an input value. It is configured as follows.

The current control unit 16 adds the monitor voltage value Vout ₁ supplied from the power supply device 11 a to the both-end potential difference ΔV generated by the PID calculation unit 17. Output voltage Vdc_out is obtained, a current control unit 16 of the DC / DC converter 35 in the main circuit 12 ₁ by the addition supplies the output voltage Vdc_out to the modulation factor calculation unit 18. The modulation factor calculation unit 18 is preset with a voltage value of the DC voltage Vdc_in, which is the system power, and the modulation factor calculation unit 18 is based on the preset voltage value and the supplied output voltage Vdc_out. calculates a modulation ratio _{m 2} Te. Specifically, the modulation factor m ₂ is calculated from m ₂ = Vdc_out / Vdc_in. Calculated modulation factor _{m 2} is supplied to the main circuit 12 _2.

Control of the current control unit 13 ₂ in this embodiment is as described above, a portion PID calculating unit 17 generates a potential difference across the [Delta] V, and, the portion modulation factor calculator 18 calculates the modulation ratio m ₂ Feedback In the control, the portions where the monitor voltage value Vout ₁ is added to the potential difference ΔV generated by the PID calculation unit 17 correspond to the feedforward control. That is, the current control unit 13 ₂ in this embodiment, the middle of the feedback control, feedforward control is incorporated.

As described above, according to power supply system 10 according to the present embodiment, feedforward control based on monitor voltage value Vout ₁ is incorporated in the process of generating modulation factor m ₂ . The power supply system 10 according to the present embodiment also employs a master / slave configuration as in the first and second embodiments, and realizes a feedback loop located outside by voltage control. Therefore, it is possible to suppress the occurrence of a situation in which the power supply device 11a and the power supply devices 11b and 11c continue to be controlled in opposite directions, so that the risk of failure of the power supply devices 11a to 11c can be reduced.

The delay for the current command value ^{I *} of the monitor voltage value Vout ₁ supplied to the current controller 13 _2, than that of the receiving monitor voltage value Vout ₁ power supply 11b, the potential difference across ΔV generated in 11c It is getting smaller. Therefore, since the change in the current command value I ^* is reflected in the modulation factor m ₂ more quickly than in the conventional case, the output voltages of the power supply devices 11b and 11c are stable after the current command value I ^* changes greatly. The time until conversion is shortened compared to the conventional one (power supply devices 2b and 2b shown in FIG. 14). Therefore, a temporary load increase of power supply device 11a accompanying a change in current command value I ^* is suppressed.

FIG. 9 is a schematic block diagram showing a system configuration of the power supply system 10 according to the fourth embodiment of the present invention. The power supply system 10 according to the present embodiment is different from the power supply system according to the third embodiment except that not only the monitor voltage value Vout ₁ but also the current command value I ^* is used as the “physical quantity related to the power supply device 11a”. Similar to system 10. Hereinafter, the differences will be mainly described in detail.

FIG. 10 is a schematic block diagram showing functional blocks of the power supply devices 11a to 11c according to the present embodiment. As shown in FIG. 9 and FIG. 9, in this embodiment, the monitor voltage value Vout ₁ (second physical quantity) and the current command value I are transferred from the master power supply device 11a to the slave power supply devices 11b and 11c. ^* (First physical quantity) is supplied.

Current control unit 13 ₂ of the present embodiment, like the current control unit 13 ₂ of the first embodiment, the internal current command value I ^* _i, the monitor current value Iout that is detected by the built-in ammeter The current command value I ^* is added to the deviation (feed forward control), and the result is supplied to the current control unit 16. In response to this, the operation of the current control unit 16 is the same as that described in the third embodiment.

As described above, according to power supply system 10 according to the present embodiment, feedforward control based on monitor voltage value Vout ₁ and internal current command value I ^* _i is incorporated in the process of generating modulation factor m ₂ . The power supply system 10 according to the present embodiment also employs a master / slave configuration as in the first to third embodiments, and realizes a feedback loop located outside by voltage control. Therefore, it is possible to suppress the occurrence of a situation in which the power supply device 11a and the power supply devices 11b and 11c continue to be controlled in opposite directions, so that the risk of failure of the power supply devices 11a to 11c can be reduced.

Further, the current command value I ^* is reflected directly in the process of generating the modulation ratio m _2, as in the third embodiment, the current from the point where the monitor voltage value Vout ₁ to the current controller 13 ₂ is supplied Since the change in the command value I ^* is reflected in the modulation factor m ₂ more quickly than in the prior art, the time from when the current command value I ^* changes greatly until the output voltages of the power supply devices 11b and 11c stabilize. This is shortened compared to the conventional one (power supply devices 2b and 2b shown in FIG. 14). Therefore, a temporary load increase of power supply device 11a accompanying a change in current command value I ^* is suppressed.

FIG. 11 is a schematic block diagram showing a system configuration of the power supply system 10 according to the fifth embodiment of the present invention. Power system 10 according to this embodiment, except for using the current command value I ^* as the internal current command value I ^* _i is supplied to the current controller 13 ₂ is the same as the power supply system 10 according to the third embodiment . Hereinafter, the differences will be mainly described in detail.

FIG. 12 is a schematic block diagram showing functional blocks of the power supply devices 11a to 11c according to the present embodiment. As shown in FIG. 11 and FIG. 11, in the present embodiment, the monitor voltage value Vout ₁ and the current command value I ^* are supplied from the master power supply device 11a to the slave power supply devices 11b and 11c. In the first to fourth embodiments, the voltage controller 14 generates the internal current command value I ^* _i . However, in this embodiment, the current command value I ^* is used as the internal current command value I ^* _i. Therefore, the voltage control unit 14 is not provided. That is, in this embodiment, voltage control as a feedback loop located outside is not performed.

The power supply apparatuses 11b and 11c use the current command value I ^* supplied from the power supply apparatus 11a for feedback control instead of feedforward control. More specifically, the PID calculation unit 17 in the current control unit 16 performs a potential difference between both ends by current control using the deviation between the current command value I ^* and the monitor current value Iout detected by the built-in ammeter as an input value. It is configured to generate ΔV. In response to this, the operation of the current control unit 16 is the same as that described in the third embodiment.

As described above, according to power supply system 10 according to the present embodiment, feedforward control based on monitor voltage value Vout ₁ is incorporated in the process of generating modulation factor m ₂ . Therefore, it is possible to suppress the occurrence of a situation in which the power supply device 11a and the power supply devices 11b and 11c continue to be controlled in opposite directions, so that the risk of failure of the power supply devices 11a to 11c can be reduced.

In this embodiment, since the current command value I ^* is used as the internal current command value I ^* _i , the current command value I ^* has changed greatly unlike the first to fourth embodiments. The problem of increasing the load of the power supply device 11a at the time is not at least a big problem.

  As mentioned above, although preferable embodiment of this invention was described, this invention is not limited to such embodiment at all, and this invention can be implemented in various aspects in the range which does not deviate from the summary. Of course.

  For example, in each of the above embodiments, an example in which two slave power supply devices are prepared has been described. However, the present invention can be suitably applied to the case where one or more power supply devices that are slaves are provided.

In each of the above embodiments, the current command value I ^* , the modulation factor m ₁ , and the monitor voltage value Vout ₁ are given as specific examples of “physical quantities related to the power supply device 11a”. However, the physical quantity that can be used as the “physical quantity concerning” is not limited to these. By being used for feedforward control in the power supply devices 11b and 11c, the power supply device 11a and the power supply devices 11b and 11c can be prevented from being controlled in opposite directions, and the power supply Other types of physical quantities can be used as long as the time until the output voltages of the devices 11b and 11c are stabilized can be shortened. Further, as illustrated in the fourth embodiment, a plurality of physical quantities can be used, and combinations thereof can be selected in various ways.

I ^* current command value I ^* _i internal current command value Iout monitor current value Vout ₁ monitor voltage value Vout ₂ monitor voltage value m _{1 to} m ₃ modulation factor 10 power supply system 11a to 11c power supply devices 12 ₁ and 12 ₂ main circuit 13 ₁ , 13 ₂ , 16 Current control unit 14 Voltage control unit 17 PID calculation unit 18 Modulation rate calculation unit 20 Load 30 System power supply 31 AC / DC converter 32 Insulated DC / DC converter 33 Three-phase DC / DC converter 35 DC / DC converter 36 ₁ , 36 ₂ Output 37 Inductance

Claims (13)

Comprising first and second power supply devices connected in series;
The first power supply device
A first current control unit that generates a first modulation factor by feedback current control based on a current command value;
A first main circuit for generating DC power based on the first modulation factor,
The second power supply device
A second current that generates a second modulation factor by current control obtained by combining feedback control based on an internal current command value related to the current command value and feedforward control based on a physical quantity related to the first power supply device. A control unit;
A second main circuit for generating DC power based on the second modulation factor;
The first of said internal current system power you characterized by chromatic and a voltage control unit for generating a command value by a feedback voltage control based on the output voltage of the power supply. The physical quantity is the current command value,
The second current control unit sets the second modulation factor by current control using an input value obtained by adding the physical quantity to a deviation between the internal current command value and the output current of the second power supply device. The power supply system according to claim 1 , wherein the power supply system is generated. The physical quantity is the first modulation rate;
The second current control unit adds a result of adding the physical quantity to a third modulation rate obtained by current control using a deviation between the internal current command value and the output current of the second power supply device as an input value. The power supply system according to claim 1 , wherein the power supply system outputs the second modulation factor. Comprising first and second power supply devices connected in series;
The first power supply device
A first current control unit that generates a first modulation factor by feedback current control based on a current command value;
A first main circuit for generating DC power based on the first modulation factor,
The second power supply device
A second current that generates a second modulation factor by current control obtained by combining feedback control based on an internal current command value related to the current command value and feedforward control based on a physical quantity related to the first power supply device. A control unit;
A second main circuit for generating DC power based on the second modulation factor,
The physical quantity is an output voltage of the first power supply device;
The second main circuit includes a DC / DC converter that generates a second DC voltage from the first DC voltage based on the second modulation factor, an output terminal, the DC / DC converter, and the output terminal. And an inductance provided between
The second current controller is
A PID control unit that generates a potential difference between both ends of the inductance by PID control based on the internal current command value;
A modulation rate calculation unit that calculates the second modulation rate based on a result of adding the physical quantity to the potential difference between the both ends generated by the PID control unit and the first DC voltage; It is that power supply system. The PID control unit, the current control to the input value of deviation between the output current of the internal current command value and the second power supply apparatus, according to claim 4, characterized in that to generate the potential difference across the Power system. The power supply system according to claim 5 , wherein the second power supply device further includes a voltage control unit that generates the internal current command value by feedback voltage control based on an output voltage of the first power supply device. . The power supply system according to claim 5 , wherein the internal current command value is the current command value. Comprising first and second power supply devices connected in series;
The first power supply device
A first current control unit that generates a first modulation factor by feedback current control based on a current command value;
A first main circuit for generating DC power based on the first modulation factor,
The second power supply device
A second current that generates a second modulation factor by current control obtained by combining feedback control based on an internal current command value related to the current command value and feedforward control based on a physical quantity related to the first power supply device. A control unit;
A second main circuit for generating DC power based on the second modulation factor,
The physical quantity includes a first physical quantity that is the current command value and a second physical quantity that is an output voltage of the first power supply device,
The second main circuit includes a DC / DC converter that generates a second DC voltage from the first DC voltage based on the second modulation factor, an output terminal, the DC / DC converter, and the output terminal. And an inductance provided between
The second current controller is
A PID control unit that generates a potential difference between both ends of the inductance by current control with an input value obtained by adding the first physical quantity to a deviation between the internal current command value and the output current of the second power supply device;
A modulation rate calculating unit that calculates the second modulation rate based on a result of adding the first physical quantity to the potential difference between the both ends generated by the PID control unit and the first DC voltage; system power characterized. The power supply system according to claim 8 , wherein the second power supply device further includes a voltage control unit that generates the internal current command value by feedback voltage control based on an output voltage of the first power supply device. . A third power supply device having the same internal configuration as the second power supply device;
The power supply system according to any one of claims 1 to 9, wherein the first to third power supply devices are connected in series. A first current control unit that generates a first modulation factor by feedback current control based on a current command value;
A first main circuit having a first main circuit for generating DC power based on the first modulation factor, and connected in series;
A second current that generates a second modulation factor by current control obtained by combining feedback control based on an internal current command value related to the current command value and feedforward control based on a physical quantity related to the first power supply device. A control unit;
A second main circuit for generating DC power based on the second modulation factor ;
And a voltage control unit that generates the internal current command value by feedback voltage control based on an output voltage of the first power supply device. A first current control unit that generates a first modulation factor by feedback current control based on a current command value;
A first main circuit for generating DC power based on the first modulation factor;
Connected in series with a first power supply having
A second current that generates a second modulation factor by current control obtained by combining feedback control based on an internal current command value related to the current command value and feedforward control based on a physical quantity related to the first power supply device. A control unit;
A second main circuit for generating DC power based on the second modulation factor,
The physical quantity is an output voltage of the first power supply device;
The second main circuit includes a DC / DC converter that generates a second DC voltage from the first DC voltage based on the second modulation factor, an output terminal, the DC / DC converter, and the output terminal. And an inductance provided between
The second current controller is
A PID control unit that generates a potential difference between both ends of the inductance by PID control based on the internal current command value;
A modulation rate calculation unit that calculates the second modulation rate based on a result of adding the physical quantity to the potential difference between the both ends generated by the PID control unit and the first DC voltage;
A power supply device characterized by that. A first current control unit that generates a first modulation factor by feedback current control based on a current command value;
A first main circuit for generating DC power based on the first modulation factor;
Connected in series with a first power supply having
A second current that generates a second modulation factor by current control obtained by combining feedback control based on an internal current command value related to the current command value and feedforward control based on a physical quantity related to the first power supply device. A control unit;
A second main circuit for generating DC power based on the second modulation factor,
The physical quantity includes a first physical quantity that is the current command value and a second physical quantity that is an output voltage of the first power supply device,
The second main circuit includes a DC / DC converter that generates a second DC voltage from the first DC voltage based on the second modulation factor, an output terminal, the DC / DC converter, and the output terminal. And an inductance provided between
The second current controller is
A PID control unit that generates a potential difference between both ends of the inductance by current control with an input value obtained by adding the first physical quantity to a deviation between the internal current command value and the output current of the second power supply device;
A modulation rate calculation unit that calculates the second modulation rate based on the result of adding the first physical quantity to the potential difference between the both ends generated by the PID control unit and the first DC voltage;
A power supply device characterized by that.

Images