JP2016005385A - Power unit and power conversion device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To protect an inrush current limiting resistor in a configuration that is simplified as further as possible, of a power unit employing a storage battery.SOLUTION: A power unit 100 includes: a DC bus 1 to which a DC load 7 is connected and a capacitor 6 connected thereto; a storage battery 5 which is charged on the basis of a voltage of the DC bus 1 and supplies power to the DC bus 1; an inrush current limiting circuit 3 provided between the DC bus 1 and the storage battery 5 and including a main cable run in which a charging/discharging current flows by closing a switch 31, and a sub cable run in which a charging current passes from the storage battery 5 through an inrush current limiting resistor 32 to the DC bus 1 while the switch 31 is opened; a protection switch 4 which is provided in series with the inrush current limiting resistor 32 and between the DC bus 1 and the storage battery 5; and a control section which cuts off the current flowing out of the storage battery 5 via the inrush current limiting resistor 32 by opening the protection switch 4 through a time-limited operation in the case where a voltage of the DC bus 1 is lower than a voltage of the storage battery 5.

Description

  The present invention relates to a power supply device using a storage battery and a power conversion device included therein.

  In a power supply device using a storage battery, for example, a chargeable / dischargeable storage battery is connected to a DC bus via a DC / DC converter (see, for example, FIG. 2 of Patent Document 1 and FIG. 2 of Patent Document 2). Generally, at the time of charging, the voltage of the DC bus is stepped down by a DC / DC converter to charge the storage battery. At the time of discharging, the voltage of the storage battery is boosted by a DC / DC converter to supply power to the DC bus.

  The DC bus is also connected to other power sources such as a commercial power source or a constant voltage power source based on the commercial power source and a solar power generation device. In addition, a load that consumes power is connected to the DC bus. In the case of an AC load, it is connected via an inverter, but in the case of a DC load, it may be directly connected to a DC bus. Further, a capacitor is connected to the DC bus for smoothing the voltage of the DC bus.

  In the power supply device as described above, in order to supply power to the load when a power source other than the storage battery cannot be used, the storage battery is discharged and power is supplied to the DC bus. At this time, if the storage battery is connected to the DC bus via the DC / DC converter in a state where the DC bus is not sufficiently charged (that is, the capacitor is not sufficiently charged), an inrush current flows at that moment. The DC / DC converter in this case can pass a current from the storage battery to the DC bus via an internal diode even when switching is stopped.

  An inrush current limiting circuit may be provided between the storage battery and the DC / DC converter so that the inrush current as described above does not become excessive (for example, paragraphs [0022] to [0024] in Patent Document 3). FIG. 1). The inrush current limiting circuit includes an electric circuit through which a current flows through a resistor at the time of inrush, and an electric circuit through which an electric current flows through the resistor at a steady state.

JP 2013-42627 A JP 2011-213321 A JP 2013-172536 A

Here, for example, a state is considered in which a DC voltage obtained by rectifying the commercial power supply voltage is stably supplied to the DC bus, and the storage battery is in a standby state for backup in a charged state. Further, it is assumed that a DC load is connected to the DC bus.
If a power failure occurs in the commercial power supply from this state, power can be supplied to the DC load by discharging the storage battery instead of the commercial power supply.

The operation sequence at this time should be as follows.
(1) The control unit of the DC / DC converter is activated (however, the switching operation has not started yet).
(2) The output of the storage battery is provided to the DC / DC converter via the resistance of the inrush current limiting circuit, and the DC bus (that is, the capacitor connected to the DC bus) is charged. The DC / DC converter at this time does not perform a switching operation, and allows current to pass through due to the presence of an internal diode.
(3) When the DC bus is charged and becomes the same voltage as the voltage of the storage battery, the current for charging the DC bus stops naturally, and the resistance of the inrush current limiting circuit is short-circuited or switched to a direct circuit. As a result, the output of the storage battery is directly provided to the DC / DC converter. The DC / DC converter starts a switching operation as a step-up chopper.
(4) Turn on the DC load.

However, when the DC load remains on even immediately after a power failure, the following inappropriate operation sequence may occur (improper example 1).
(1) The DC load is on (turned on).
(2) The control unit of the DC / DC converter is activated (however, the switching operation has not started yet).
(3) The output of the storage battery passes through the diode in the DC / DC converter through the resistance of the inrush current limiting circuit and tries to charge the DC bus. However, since the current is pulled to the DC load, the voltage of the DC bus is The voltage does not rise to.
(4) The current flowing to the DC load continues to flow through the resistor without increasing the voltage of the DC bus. As a result, the resistance of the inrush current limiting circuit may burn out. In addition, a resistor with a thermal fuse may be used as the resistor of the inrush current limiting circuit. However, in this case as well, inconvenience that the fuse is blown and needs to be replaced (the same applies hereinafter).

Further, when the DC load is kept on even immediately after a power failure, the following incorrect operation sequence may occur (improper example 2).
(1) The DC load is on (turned on). Further, the DC / DC converter is stopped due to an external command or a shortage of the remaining amount of the storage battery.
(2) The controller of the DC / DC converter does not bypass the resistance of the inrush current limiting circuit, and is in a state where current can flow through the resistance.
(3) The output of the storage battery passes through the diode in the DC / DC converter via the resistance of the inrush current limiting circuit, and continues to supply current to the DC load.
(4) The current flowing to the DC load continues to flow through the resistor without increasing the voltage of the DC bus. As a result, the resistance of the inrush current limiting circuit may burn out.

  If the load is an AC load, an inverter is interposed between the DC bus and the AC load. Therefore, as long as the inverter is stopped, no current is drawn to the load unintentionally. However, when an on-state DC load is connected to the DC bus, a situation occurs in which the current continues to flow to the DC load due to the voltage of the storage battery, as in the case of inappropriate cases 1 and 2 above. There is a possibility that the resistance limiting the heat burns out.

For example, a direct current relay or a full-scale current limiting circuit (for example, FIG. 3 of Patent Document 2) can be provided between the DC bus and the direct current load. However, these are not suitable for cost reduction and circuit simplification. Contrary.
In view of such a conventional problem, an object of the present invention is to protect an inrush current limiting resistor with a configuration as simple as possible in a power supply device using a storage battery.

The power supply device of the present invention is charged based on the voltage of the DC bus when charging, and a capacitor connected to the DC bus, a capacitor connected to the DC bus, and power to the DC bus when discharging. A storage battery to be supplied, a main electric circuit that is provided between the DC bus and the storage battery and flows charge / discharge current by closing the switch, and an inrush current limiting resistor from the storage battery when the switch is open An inrush current limiting circuit having a sub-electric path for passing a charging current to the DC bus; a protection switch provided between the DC bus and the storage battery in series with the inrush current limiting resistor; and a voltage of the DC bus A voltage sensor for detecting V _dc , a voltage sensor for detecting voltage V _b of the storage battery, and the inrush current limiting resistor from the storage battery when the voltage V _dc is lower than the voltage V _b. And a control unit that cuts off the current flowing through the resistor by opening the protective switch by a time-limited operation.

Further, the present invention is a power conversion device provided between a DC bus connected to a capacitor and a storage battery, wherein the storage battery is charged based on the voltage of the DC bus and discharged to the DC bus. A DC / DC converter that supplies power to the DC bus, a main circuit that is provided between the DC / DC converter and the storage battery and allows a charge / discharge current to flow by closing the switch, and the switch is open Sometimes, an inrush current limiting circuit having a secondary electric circuit for passing a charging current from the storage battery to the DC bus via an inrush current limiting resistor, and in series with the inrush current limiting resistor, between the DC bus and the storage battery. A protection switch provided; a voltage sensor that detects the voltage V _{dc of the} DC bus; a voltage sensor that detects the voltage V _b of the storage battery; and the voltage V _dc is lower than the voltage V _b. A controller that shuts off the current flowing out of the storage battery through the inrush current limiting resistor by opening the protective switch by a time-limited operation.

  According to the power supply device of the present invention, burning of the inrush current limiting resistor can be prevented with a simple configuration.

It is a connection diagram which simplifies and shows the main circuit portion of the power unit concerning one embodiment of the present invention. It is a circuit diagram which shows the structure of the power converter device in FIG. 1 in detail. It is a connection diagram which shows the electric current flow (bold line) which may occur when a power failure occurs from a switching operation stop state. It is a flowchart which shows an example of the protection switch control operation of the control part performed after the switching operation stop of a DC / DC conversion part. It is a circuit diagram which shows the 2nd example of a power converter device. It is a circuit diagram which shows the 3rd example of a power converter device. It is a connection diagram which shows the 2nd example of a power supply device. It is a connection diagram which shows the 3rd example of a power supply device.

[Summary of Embodiment]
The gist of the embodiment of the present invention includes at least the following.

(1) This power supply device is charged based on the voltage of the DC bus when charging, and a capacitor connected to the DC bus, a capacitor connected to the DC bus, and power to the DC bus when discharging Is provided between the DC bus and the storage battery, and a main circuit that allows charging / discharging current to flow by closing the switch, and an inrush current limiting resistor from the storage battery when the switch is open. An inrush current limiting circuit having a sub-electric path for passing a charging current to the DC bus, a protection switch provided between the DC bus and the storage battery in series with the inrush current limiting resistor, A voltage sensor for detecting voltage V _dc , a voltage sensor for detecting voltage V _b of the storage battery, and the inrush current limit from the storage battery when the voltage V _dc is lower than the voltage V _b And a control unit that shuts off a current flowing through the resistor by opening the protective switch by a time-limited operation.

In the power supply device configured as described above, when the voltage V _{dc of the} DC bus is lower than the voltage V _{b of} the storage battery, the current flows from the storage battery through the inrush current limiting circuit even if the switch is open. Flows. In this case, if a DC load is connected to the DC bus, a current may flow to the DC load. If this is left as it is, the inrush current limiting resistor is burned out. However, in such a case, since the control unit opens the protection switch in a time-limited operation, the inrush current limiting resistor can be protected.

(2) Further, in the power supply device of (1), when the voltage V _dc is lower than the voltage V _b , the control unit determines the potential difference (V _b −V _dc ) and the resistance of the inrush current limiting resistor. A current value that flows based on the current value, and when the current value is equal to or greater than a threshold current and the time for which the current of the current value flows reaches a threshold time, the protection switch is opened. Also good.
In this case, it is possible to easily protect the inrush current limiting resistor by simply recognizing when the protection switch should be opened without providing a current sensor.

(3) Further, in the power supply device of (1), provided is a current sensor that detects a current flowing out from the storage battery through the inrush current limiting resistor when the voltage V _dc is lower than the voltage V _b , The control unit may open the protection switch when a current value detected by the current sensor is equal to or greater than a threshold current and a time during which the current of the current value flows reaches a threshold time.
In this case, the protection switch is opened at an accurate time based on the current value detected by the current sensor, and the inrush current limiting resistor can be reliably protected.

(4) Moreover, in the power supply device of (2) or (3), the threshold current is a current value when the storage battery covers standby power consumption when the operation of the power supply device is stopped by a discharge voltage lower limit value. A larger value is preferable.
In other words, the current value in the case where the storage battery covers standby power consumption with the lower limit voltage of the discharge is a normal maximum value. Therefore, since the threshold current is a value larger than the current value, the protection switch can be opened only by whatever current value flows in the inrush current limiting resistor when the standby power consumption is covered. Absent. Therefore, malfunction is prevented.

(5) Moreover, in the power supply device according to any one of (1) to (4), a DC / DC converter is provided between the DC bus and the inrush current limiting circuit, and the DC / DC The DC converter may include a diode that enables energization from the storage battery to the DC bus even when the switching operation is stopped.
In this case, the inrush current limiting resistor can be protected in the power supply device including the DC / DC converter.

(6) Further, in the power supply device of (5), when the control unit opens the protection switch in a time limit operation and the voltage V _dc becomes higher than the voltage V _b , The protection switch may be closed.
That is, when the DC bus voltage V _dc is higher than the storage battery voltage V _b , no current flows through the inrush current limiting resistor even if the protection switch is closed, so that the protection switch is returned to the closed state. Can do.

(7) On the other hand, this is a power converter provided between a DC bus to which a capacitor is connected and a storage battery, and the storage battery is charged based on the voltage of the DC bus and discharged to the DC bus. A DC / DC converter that supplies power to the DC bus, a main circuit that is provided between the DC / DC converter and the storage battery, and allows a charge / discharge current to flow by closing the switch, and the switch is opened. An inrush current limiting circuit having a secondary electric path for passing a charging current from the storage battery to the DC bus through an inrush current limiting resistor, and the DC bus and the storage battery in series with the inrush current limiting resistor. A protection switch provided therebetween, a voltage sensor that detects the voltage V _{dc of the} DC bus, a voltage sensor that detects the voltage V _b of the storage battery, and the voltage V _dc is the voltage V _b A control unit that cuts off current flowing from the storage battery through the inrush current limiting resistor when the protection switch is lower by opening the protective switch in a time limit operation.

In the power conversion device configured as described in (7) above, when the voltage V _{dc of the} DC bus is lower than the voltage V _{b of} the storage battery, even if the switch is open, the inrush current limiting circuit from the storage battery Current flows through. In this case, if a DC load is connected to the DC bus, a current may flow to the DC load. If this is left as it is, the inrush current limiting resistor is burned out. However, in such a case, since the control unit opens the protection switch in a time-limited operation, the inrush current limiting resistor can be protected.

[Details of the embodiment]
Next, details of the embodiment of the present invention will be described with reference to the drawings.

<Power supply unit>
FIG. 1 is a connection diagram showing a simplified main circuit portion of a power supply device according to an embodiment of the present invention. In the figure, a bidirectional DC / DC converter 2 is connected to the DC bus 1 of the power supply device 100. The DC / DC conversion unit 2 is connected to the storage battery 5 via the inrush current limiting circuit 3 and the protection switch 4. The inrush current limiting circuit 3 is formed by connecting a switch 31 (main electric circuit) and an inrush current limiting resistor 32 (sub electric circuit) in parallel with each other. The storage battery 5 is, for example, a lead storage battery or a lithium ion storage battery. The DC / DC converter 2 constitutes a power converter 200 in a broad sense, together with the accompanying inrush current limiting circuit 3 and the protection switch 4.

A smoothing capacitor 6 is connected to the DC bus 1. The DC load 7 is directly connected to the DC bus 1.
A stable DC voltage can be provided to the DC bus 1 from the AC commercial power supply 8 via the AC / DC converter 9.

《Power conversion device》
FIG. 2 is a circuit diagram showing in detail the configuration of power converter 200 in FIG. The same parts as those in FIG. 1 are denoted by the same reference numerals. The power conversion device 200 is provided between the DC bus 1 to which the capacitor 6 is connected and the storage battery 5. The DC / DC conversion unit 2 includes switching elements Q1 and Q2 connected in series with each other, a DC reactor 21 connected to their interconnection point, a voltage sensor 22 that detects the voltage of the DC bus 1, and a storage battery 5 The voltage sensor 23 for detecting the voltage of the current, the current sensor 24 for detecting the current flowing through the DC / DC converter 2, and the controller 10 are connected as shown in the figure.

  As the switching elements Q1 and Q2, IGBT (Insulated Gate Bipolar Transistor) or FET (Field Effect Transistor) can be used (the figure is an example of IGBT). The switching elements Q1 and Q2 have diodes Q1d and Q2d in parallel so that the high potential side becomes the cathode. On the other hand, the switch 31 does not perform switching at a high frequency, and therefore, not only a semiconductor switch but also a relay contact can be used. The protection switch 4 is also less frequently opened and closed. Therefore, in addition to the semiconductor switch, it is possible to use a relay contact or a breaker that can be controlled for opening and closing. The protection switch 4 is, for example, a so-called bi-directional switch (two-circuit open / close switch).

The switching elements Q1, Q2 and the switch 31 are on / off controlled by the control unit 10. The protection switch 4 is also controlled to be turned on / off by the control unit 10. Output signals from the voltage sensors 22 and 23 and the current sensor 24 are sent to the control unit 10.
The control unit 10 may include a CPU and operate mainly by software, or may realize a similar function by an analog circuit.

<Operation during charging / discharging>
When charging the storage battery 5, the control unit 10 closes the protection switch 4 and the switch 31. In this state, the control unit 10 fixes the switching element Q2 to be off and controls the switching element Q1 to be on / off at a high frequency. By performing chopper control so that the on-duty becomes an appropriate value, the voltage of the DC bus 1 is stepped down, smoothed by the DC reactor 21, and becomes a DC voltage suitable for charging the storage battery 5. The storage battery 5 is charged by the DC voltage through the closed switch 31 and the protection switch 4.

  On the other hand, when the commercial power supply 8 (FIG. 1) fails, the storage battery 5 can be discharged to supply power to the DC load 7 (FIG. 1). First, at the start of discharging the storage battery 5, the control unit 10 closes the protection switch 4 and opens the switch 31. In this state, the storage battery 5 passes from the plus side of the storage battery 5 through the closed protection switch 4 (plus side), the inrush current limiting resistor 32, the DC reactor 21, the diode Q1d, the capacitor 6, and the protection switch 4 (minus side). A current path returning to is formed, and the capacitor 6 is initially charged.

  When the control unit 10 recognizes that the voltage of the capacitor 6, that is, the voltage of the DC bus 1 is substantially equal to the voltage of the storage battery 5 based on the output signals of the voltage sensors 22 and 23, the control unit 10 closes the switch 31. As a result, the output of the storage battery 5 is directly supplied to the DC / DC converter 2 without going through the inrush current limiting resistor 32. Then, the control unit 10 operates so that the switching elements Q1, Q2 are alternately turned on. As a result, the voltage of the storage battery 5 is boosted to a predetermined voltage and provided to the DC bus 1. Thus, power can be supplied from the storage battery 5 to the DC load 7.

<< Stopped state of DC / DC conversion unit >>
In a state where a constant voltage is normally supplied from the commercial power supply 8 to the DC bus 1, even if the power demand of the DC load 7 increases or decreases, power is supplied without any particular problem. Therefore, unless the AC / DC converter 9 is intentionally stopped for the purpose of peak shift or the like, there is no turn of the storage battery 5. Further, if the storage battery 5 is fully charged, it is not necessary to perform charging, so the control unit 10 stops the switching operation of the DC / DC conversion unit 2 and opens the switch 31. However, the control unit 10 closes the protection switch 4.

  In the switching stop state, both switching elements Q1 and Q2 are off. Therefore, no current flows from the DC bus 1 to the storage battery 5 side. However, a current can flow from the storage battery 5 to the DC bus 1 depending on conditions. That is, from the plus side of the storage battery 5, the closed protection switch 4 (plus side), the inrush current limiting resistor 32, the DC reactor 21, the diode Q 1 d, the capacitor 6, and the protection switch 4 (minus side) return to the storage battery 5. A current path may be formed. However, due to the presence of the diode Q1d, the current actually flows through this current path only when the voltage of the DC bus is lower than the voltage of the storage battery 5. When power is stably supplied from the commercial power supply 8, the voltage of the DC bus 1 is higher than the voltage of the storage battery 5. Therefore, no current flows.

<< Power outage from DC / DC converter stop >>
FIG. 3 is a connection diagram showing a current flow (bold line) that can occur when a power failure occurs from the switching operation stop state.
When a power failure occurs in the commercial power supply 8 from the switching operation stop state of the DC / DC conversion unit 2, the DC load 7 discharges the capacitor 6 in an attempt to draw current from the DC bus 1, and the voltage of the DC bus 1 drops rapidly. . As a result, DC voltage _{V dc} bus 1, when the voltage of the battery 5 and _{V b,} a relationship of V dc _{<V b.}

  Therefore, as shown by the thick line in FIG. 3, the storage battery 5 passes through the closed protection switch 4, the inrush current limiting resistor 32, and the diode Q1d (FIG. 2) of the DC / DC conversion unit 2 via the DC bus 1. A current flows to the DC load 7. In this case, unlike the transient charging of the capacitor 6, the DC load 7 continuously demands a large amount of power, so that the voltage of the DC bus 1 does not rise to the voltage of the storage battery 5 but remains in a low state. If this state continues for a long time, the inrush current limiting resistor 32 is burned out. Therefore, the control unit 10 performs the following operation.

FIG. 4 is a flowchart illustrating an example of the protection switch control operation of the control unit 10 that is executed after the switching operation of the DC / DC conversion unit 2 is stopped. In the figure, when the switching operation of the DC / DC converter 2 is stopped, the controller 10 starts this operation. First, in step S1, it is determined whether or not to resume the switching operation. Here, assuming “No”, the control unit 10 compares the voltage V _dc of the DC bus 1 and the voltage V _{b of the} storage battery 5 with each other based on the output signals of the voltage sensors 22 and 23. , V _dc <V _b is determined (step S2). In addition, since it can be arbitrarily determined whether to handle the case of V _dc = V _b as Yes / No, the case of an equal sign is omitted here. The same applies to the following steps S4 and S7.

If “No”, that is, if V _dc > V _b , the control unit 10 keeps the protection switch 4 closed (step S3), returns to step S1, and repeats the same processing. If “Yes”, that is, V _dc <V _b in step S2, the control unit 10 next determines whether or not the current I detected by the current sensor 24 is I _th <I compared with the threshold current I _th. Is determined (step S4). If “No”, that is, I _th > I, the control unit 10 resets a time T described later to 0 (step S5), returns to step S1, and repeats the same processing.

If “Yes” in step S4, that is, I _th <I, the control unit 10 then counts the time T that has elapsed since I _th <I (step S6). Next, the control unit 10 compares the time T with the threshold time T _th and determines whether or not T _th <T (step S7). If “No”, that is, T _th > T, the control unit 10 returns to step S1 and repeats the same processing.

If “Yes”, that is, T _th <T in step S7, the control unit 10 opens the protection switch 4 (step S8). Thereafter, the process of the control unit 10 returns to step S1, and the same process is repeated.
If “No” in step S2, that is, if V _dc > V _b , the control unit 10 closes the protection switch 4 (step S3), returns to step S1, and repeats the same processing. That is, when the voltage V _{dc of the} DC bus is higher than the voltage V _{b of the} storage battery, no current flows through the inrush current limiting resistor 32 even if the protection switch 4 is closed, so that the protection switch 4 is closed. Can return.
When the switching operation is resumed in step S1, the control unit 10 closes the protection switch 4 (or keeps it closed) in step S9 and ends the process.

By performing the processing of the above flowchart, when V _dc <V _b and I _th <I exceeds the threshold time T _th , the protection switch 4 is opened to stop the current, thereby limiting the inrush current. The resistor 32 can be protected.

That is, in the power supply device 100 configured as described above, the switch 31 is open when the voltage V _dc of the DC bus 1 is lower than the voltage V _{b of the} storage battery 5 as shown in FIG. However, current flows from the storage battery 5 through the inrush current limiting circuit 3. In this case, if the DC load 7 is connected to the DC bus 1, a current may flow to the DC load 7. If this is left as it is, the inrush current limiting resistor 32 is burned out. However, in such a case, since the control unit 10 opens the protection switch 4 with a time limit operation, the inrush current limiting resistor 32 can be protected with a simple configuration.

In the power conversion device 200 (FIG. 2) of the power supply device 100, the current sensor 24 is provided. In this case, the protection switch 4 can be opened at an accurate time based on the current value detected by the current sensor 24, and the inrush current limiting resistor 32 can be reliably protected.
However, it is also possible to obtain the current value by omitting the current sensor 24 and performing the following calculation by the control unit 10. That is, when the DC / DC conversion unit 2 stops the switching operation and the voltage V _dc of the DC bus 1 is lower than the voltage V _{b of the} storage battery 5, the current I flowing through the inrush current limiting resistor 32 is the inrush current limiting. When the resistance value of the resistor 32 is R,
I = (V _b −V _dc ) / R
Can be obtained. That is, in this case, it is possible to easily protect the inrush current limiting resistor 32 by recognizing when to open the protection switch 4 without providing a current sensor.

  In the power conversion device 200 of the power supply device 100 described above, the control power supply voltage is normally generated from the voltage of the DC bus 1 by a control power supply circuit (not shown). When the commercial power supply 8 fails, the storage battery 5 provides a voltage to the DC bus 1 via the closed protection switch 4, the inrush current limiting resistor 32, and the diode Q1d, whereby the power converter 200 and the AC / DC A control power supply voltage necessary for the converter 9 is obtained.

Therefore, the standby power consumption (power consumed by the power supply apparatus 100 during standby) is set to P _c, and the voltage lower limit value at the time of discharging the storage battery is set to V _{b_min} . That is, except for the incorrect status of pulled the current from the DC load 7 in the event of a power failure, the maximum current value _{I max} when a normal state _{is I max = P c / V b_min} . Therefore, the threshold current _{I th} is should be a larger value than the _{I max.}
Since the threshold current I _th is a value larger than the current value I _max , the protection switch 4 can be used only by whatever current value flows in the inrush current limiting resistor 32 when the standby power consumption is covered. Never open. Therefore, malfunction is prevented.

For the threshold time T _th , assuming that the capacitance of the capacitor 6 is C and the voltage upper limit value of the storage battery 5 is V _{b_max} , for example,
_{T th> -C × R × log} e {(P c × R) / (V b_max × V b_min)}
Can be obtained as

<< Second Example of Power Converter >>
FIG. 5 is a circuit diagram showing a second example of the power conversion device 200.
The difference from FIG. 2 is that the protection switch 4 and the BMS control unit 10 </ b> B that controls the protection switch 4 are provided separately from the power converter 200. The control unit 10 and the BMS control unit 10B are connected so that they can communicate with each other. When the protection switch 4 is opened and closed, the control unit 10 is performed via the BMS control unit 10B. Such a configuration is suitable when the protection switch 4 and the BMS control unit 10B are equipped as the BMS (Battery Management System) 300 on the storage battery 5 side. That is, the protection switch 4 and its control unit may belong to the power conversion device 200 as in the first example, or may belong to an external device such as a BMS as in the second example. The control operation is the same as in the first example (FIG. 2).

<< Third example of power conversion apparatus >>
FIG. 6 is a circuit diagram illustrating a third example of the power conversion apparatus 200.
The difference from FIG. 2 is the inrush current limiting circuit 3. In FIG. 6, the inrush current limiting circuit 3 is configured by the switch 31 as the main electric circuit, and the inrush current limiting resistor 32 and the protection switch 4 as the sub electric circuit. The protection switch 4 is turned on / off by the control unit 10. That is, in this case, the protection switch 4 in the first example (FIG. 2) is “cut off” in the inrush current limiting circuit 3. This can be said to be a simpler configuration than the first example. The control operation is the same as in the first example.

<< Second Example of Power Supply >>
FIG. 7 is a connection diagram illustrating a second example of the power supply device. The difference from the first example (FIG. 1) is that power can be sent from the photovoltaic power generation panel 11 to the DC bus 1 via the DC / DC converter 12.
In this case, even if the protection switch 4 is opened after a power failure of the commercial power supply 8, if the voltage V _dc recovers to a state higher than the voltage V _b by solar power generation, the protection switch 4 is immediately closed. (Step S2 to Step S3 in FIG. 4).
That is, when the voltage V _{dc of the} DC bus is higher than the voltage V _{b of the} storage battery, no current flows through the inrush current limiting resistor 32 even if the protection switch 4 is closed, so that the protection switch 4 is closed. Can return.

<< Third example of power supply apparatus >>
FIG. 8 is a connection diagram illustrating a third example of the power supply device. The difference from the first example (FIG. 1) is that the combination of the power conversion device 200 and the storage battery 5 is a plurality of sets. The power conversion apparatus 200 can be easily expanded by unitizing the power conversion apparatus 200 together with the DC / DC conversion unit 2 including the inrush current limiting circuit 3 and the protection switch 3.

<Others>
In addition, although each said power supply device 100 showed the example provided with the DC / DC conversion part 2, it replaced with the DC / DC conversion part 2, for example, the direction which goes to the DC bus 1 from the storage battery 5 side is set as a forward direction. The inrush current limiting circuit 3 and the DC bus 1 may be connected to each other only through the diode that performs the above operation. Even in this case, when the voltage V _dc of the DC bus 1 is lower than the voltage V _b of the storage battery 5, the current that flows out from the storage battery 5 through the inrush current limiting resistor 32 is opened by the time limit operation. The inrush current limiting resistor 32 can be protected by shutting off.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

DESCRIPTION OF SYMBOLS 1 DC bus 2 DC / DC conversion part 3 Inrush current limiting circuit 4 Protection switch 5 Storage battery 6 Capacitor 7 DC load 8 Commercial power supply 9 AC / DC converter 10 Control part 10B BMS control part 11 Solar power generation panel 12 DC / DC converter 21 Reactor 22, 23 Voltage sensor 24 Current sensor 31 Switch 32 Inrush current limiting resistor 100 Power supply device 200 Power conversion device 300 BMS
Q1 switching element Q1d diode Q2 switching element Q2d diode

Claims (7)

A DC bus to which a DC load is connected;
A capacitor connected to the DC bus;
A storage battery that is charged based on the voltage of the DC bus during charging, and that supplies power to the DC bus during discharging;
A main circuit that is provided between the DC bus and the storage battery and allows a charge / discharge current to flow by closing the switch, and when the switch is open, from the storage battery to the DC bus via an inrush current limiting resistor An inrush current limiting circuit having a secondary electric circuit for passing the charging current;
A protective switch provided between the DC bus and the storage battery in series with the inrush current limiting resistor;
A voltage sensor for detecting the voltage V _{dc of the} DC bus;
A voltage sensor for detecting the voltage _Vb of the storage battery;
A power supply device comprising: a control unit configured to cut off a current flowing out of the storage battery through the inrush current limiting resistor when the voltage V _dc is lower than the voltage V _b by opening the protection switch by a time-limited operation; . When the voltage V _dc is lower than the voltage V _b , the control unit obtains a flowing current value based on the potential difference (V _b −V _dc ) and the resistance value of the inrush current limiting resistor, and the current 2. The power supply device according to claim 1, wherein the protection switch is opened when a value is equal to or greater than a threshold current and a time during which a current having the current value flows reaches a threshold time. A current sensor for detecting a current flowing out of the storage battery through the inrush current limiting resistor when the voltage V _dc is lower than the voltage V _b ;
The said control part opens the said protection switch, when the electric current value which the said current sensor detects is more than threshold current, and the time when the electric current of the said electric current value flows reaches threshold value time. Power supply.   4. The power supply device according to claim 2, wherein the threshold current is a value larger than a current value when the storage battery covers a standby power consumption when the operation of the power supply device is stopped by a lower voltage limit value of discharge. 5. .   A DC / DC converter is provided between the DC bus and the inrush current limiting circuit, and the DC / DC converter is energized from the storage battery to the DC bus even when the switching operation is stopped. The power supply device according to any one of claims 1 to 4, further comprising a diode that enables the operation. Wherein, after opening the protective switch time limit operation, when the voltage V _dc becomes higher than the voltage V _b is the power supply device according to claim 5, closing the protection switch. A power conversion device provided between a DC bus to which a capacitor is connected and a storage battery,
A DC / DC converter that charges the storage battery based on the voltage of the DC bus, discharges the DC bus, and supplies power to the DC bus;
A main circuit that is provided between the DC / DC converter and the storage battery and flows a charging / discharging current by closing the switch, and the DC through the inrush current limiting resistor from the storage battery when the switch is open. An inrush current limiting circuit having a secondary electric circuit for passing a charging current to the bus;
A protective switch provided between the DC bus and the storage battery in series with the inrush current limiting resistor;
A voltage sensor for detecting the voltage V _{dc of the} DC bus;
A voltage sensor for detecting the voltage _Vb of the storage battery;
A power conversion unit comprising: a control unit configured to cut off a current flowing out of the storage battery through the inrush current limiting resistor when the voltage V _dc is lower than the voltage V _b by opening the protective switch in a time-limited operation. apparatus.

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