JP2021108521A - Power supply controller - Google Patents

Abstract

To provide a technique related to a power supply controller that can easily suppress a decrease in an amount of electric power stored in a storage battery at the time of normality confirmation.SOLUTION: A power supply controller comprises a first conversion unit, a second conversion unit, a regulation unit, a control unit, and a measuring unit. The first conversion unit converts an AC power to a DC power to output it. The second conversion unit is connected in parallel with the first conversion unit, and converts an AC power to a DC power to output it. The regulation unit permits the flow of a current from the second conversion unit to the first conversion unit, and regulates the flow of a current from the first conversion unit to the second conversion unit. The control unit is configured so that control for regulating a voltage of a DC power output from the second conversion unit to a testing voltage, being a voltage lower than a predetermined voltage discharged from a storage unit connected between the second conversion unit and the regulation unit in an output side of the second conversion unit, is enabled. The measuring unit measures a voltage inputted from the second conversion unit and the storage unit to the regulation unit.SELECTED DRAWING: Figure 1

Description

The present invention relates to a power supply control device used in a power supply system.

A power supply system is known in which power is normally supplied to a facility using a commercial power source, and power is supplied to a facility using a storage battery provided in an emergency such as a power outage.

Japanese Unexamined Patent Publication No. 2013-046454

In such a power supply system, a technique for confirming normality for confirming whether or not the storage battery functions normally is known.
However, in a conventional power supply system as described in Patent Document 1, actual discharge is performed from the storage battery in checking the normality of the storage battery. Therefore, when the normality is confirmed, the amount of electric power stored in the storage battery is reduced due to the actual discharge from the storage battery.

An object of the present invention is to provide a technique relating to a power supply control device that can easily suppress a decrease in the amount of electric power stored in a storage battery when confirming normality.

One aspect of the present disclosure is a power supply control device, which includes a first conversion unit, a second conversion unit, a regulation unit, a control unit, and a measurement unit. The first conversion unit converts AC power into DC power and outputs the converted DC power. The second conversion unit is electrically connected in parallel with the first conversion unit, converts AC power into DC power, and outputs the converted DC power. The regulation unit is provided between the first conversion unit and the second conversion unit in the conducting wire to which the DC power is output from the first conversion unit and the second conversion unit, and goes from the second conversion unit to the first conversion unit. Allows the flow of current and regulates the flow of current from the first conversion unit to the second conversion unit. The control unit is the side from which the DC power of the second conversion unit is output, and is lower than the predetermined voltage output from the power storage unit that is rechargeably connected between the second conversion unit and the regulation unit. It is configured so that the test voltage, which is a voltage, can be controlled to adjust the voltage of the DC power output from the second conversion unit. The measuring unit measures the voltage input from the second conversion unit or the power storage unit to the regulation unit.

According to such a configuration, at the time of normality confirmation, the control unit adjusts the voltage output from the second conversion unit to a test voltage lower than the voltage output from the power storage unit. As a result, the voltage input from the second conversion unit or the power storage unit to the regulation unit is measured by the measurement unit, so that it is possible to determine whether or not the power storage unit is operating normally. Therefore, when confirming the normality, it is not necessary to supply the DC power by the power storage unit, and it is possible to suppress the consumption of the power of the power storage unit.

In one aspect of the present disclosure, a discharge unit configured to be able to discharge electric power between the second conversion unit and the power storage unit may be provided.
According to such a configuration, when the normality is confirmed and the voltage output from the second conversion unit is set to the test voltage by the control unit, the discharge unit controls the energized state, so that the power storage unit is normal. It becomes easier to perform sex confirmation more appropriately. That is, when there is an abnormality in the power supply from the power storage unit, the parasitic capacitance prevents the voltage output from the second conversion unit from dropping to the test voltage, and prevents the abnormality in the power supply from the power storage unit from being detected. can do.

One aspect of the present disclosure is a discharge control unit configured to perform discharge control for discharging from the power storage unit when the control unit controls to adjust the voltage output from the second conversion unit to the test voltage. , May be further provided.

According to such a configuration, by performing discharge control, it is possible to relatively reduce the influence of parasitic capacitance that prevents the voltage from dropping to the test voltage due to discharge from the power storage unit.

One aspect of the present disclosure may further include a conductor and a regulatory section. In addition, the conducting wire electrically connects the power storage unit and the regulation unit. The regulation unit is connected between the second conversion units, allows the current flow from the second conversion unit to the power storage unit or the regulation unit, and regulates the current flow from the power storage unit or the regulation unit to the second conversion unit. do.

According to such a configuration, it is possible to suppress the backflow of current from the regulating unit and the power storage unit to the second conversion unit.
In one aspect of the present disclosure, a conversion measurement unit that measures the voltage output from the second conversion unit toward the regulation unit may be provided.

According to such a configuration, the conversion measuring unit measures the voltage output from the second conversion unit and the voltage of the regulating unit and the power storage unit to compare each voltage and confirm the normality of the storage battery. It can be performed.

It is a figure which showed the example of the apparatus configuration of the power supply system in 1st Embodiment. FIG. 2A is a diagram showing an example of time fluctuations of the direct transmitter voltage Vp, the charger voltage Vc, and the battery voltage Vb in the normal state in the power supply system described in the embodiment. FIG. 2B is a diagram showing an example of time variation of the first voltage V1 and the second voltage V2 in the normal state in the power feeding system described in the embodiment. FIG. 3A is a diagram showing an example of time fluctuations of the direct transmitter voltage Vp, the charger voltage Vc, and the battery voltage Vb at the time of confirming the normality in the power supply system described in the embodiment. FIG. 3B is a diagram showing an example of time fluctuations of the first voltage V1 and the second voltage V2 at the time of normality confirmation in the power supply system described in the embodiment. FIG. 4A shows an example of time fluctuations of the direct transmitter voltage Vp, the charger voltage Vc, and the battery voltage Vb at the time of confirming the normality when there is an abnormality in the power supply from the power storage device of the power supply system described in the embodiment. It is a representation figure. FIG. 4B is a diagram showing an example of time fluctuations of the first voltage V1 and the second voltage V2 at the time of normality confirmation when there is an abnormality in the power supply from the power storage device of the power supply system described in the embodiment. be. It is a flowchart which showed the example of the normality confirmation processing which the test circuit executes in 1st Embodiment. It is a figure which showed the example of the time variation of the direct transmitter voltage Vp, the charger voltage Vc, and the battery voltage Vb at the time of normality confirmation in the conventional power supply system. It is a figure which showed the example of the apparatus configuration of the power supply system in 2nd Embodiment. It is a flowchart which showed the example of the normality confirmation processing which the test circuit executes in 2nd Embodiment. It is a figure which showed the example of the apparatus configuration of the power supply system in 3rd Embodiment. It is a flowchart which showed the example of the normality confirmation processing which the test circuit executes in 3rd Embodiment.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.
[1. First Embodiment]
[1-1. Constitution]
As shown in FIG. 1, the power supply system 1 in the present embodiment includes an AC power supply 10, a power supply control device 20, a load device 30, and a power storage device 40. The power supply system 1 is a system that supplies DC power from the AC power supply 10 or the power storage device 40 to the load device 30 via the power supply control device 20. In FIG. 1, the connection between the configurations included in the power feeding system 1 is represented by a double-track diagram that is electrically connected by a positive conductor and a negative conductor. Similarly, the connection of each configuration in the power supply control device 20 is also represented by a double-track diagram that is electrically connected by the positive conductor and the negative conductor. The positive conductor referred to here is a conductor that is electrically connected to the terminal of the positive pole with the terminal having a relatively high potential as the positive pole, and the negative conductor has a relatively low potential. It is a conducting wire that is electrically connected to the terminal of the negative pole with the terminal of the negative pole as the negative pole.

The AC power source 10 is a power source for supplying AC power. The AC power supply 10 may be, for example, a general commercial power supply. The AC power supply 10 is not limited to a commercial power supply, and may be any power supply that can supply AC power.

The load device 30 is a device that operates or processes by receiving DC power.
The power storage device 40 is a device that charges and discharges DC power. As the power storage device 40, for example, various storage batteries and the like may be used.

The power supply control device 20 receives AC power from the AC power source 10, converts it into DC power, and supplies the converted DC power to the load device 30. Further, the power supply control device 20 supplies the converted DC power to the power storage device 40.

Further, the power supply control device 20 supplies DC power from the power storage device 40 to the load device 30.
The power supply control device 20 includes an AC input terminal 20a, a DC input / output terminal 20b, and a DC output terminal 20c.

The AC input terminal 20a is a terminal configured so that AC power can be input from the outside to the inside of the power supply control device 20. In this embodiment, an example in which the AC power supply 10 is electrically connected to the AC input terminal 20a will be described. That is, the AC power supply 10 supplies AC power to the power supply control device 20 via the AC input terminal 20a.

The DC input / output terminal 20b is a terminal configured to be capable of inputting DC power from the outside to the inside of the power supply control device 20 and outputting DC power from the inside to the outside of the power supply control device 20. In this embodiment, an example in which the power storage device 40 is electrically connected to the DC input / output terminal 20b will be described. That is, the power storage device 40 is charged by being supplied with DC power by the power supply control device 20 via the DC input / output terminal 20b, and supplies DC power to the power supply control device 20 via the DC input / output terminal 20b. This discharges.

The DC output terminal 20c is a terminal configured to be able to output DC power from the inside to the outside of the power supply control device 20. In this embodiment, the load device 30 will be described by applying it to an example in which the load device 30 is electrically connected to the DC output terminal 20c. That is, the load device 30 receives power supply of DC power from the power supply control device 20 via the DC output terminal 20c.

The AC input terminal 20a, the DC input / output terminal 20b, and the DC output terminal 20c each have a positive terminal having a positive polarity and a negative terminal having a negative polarity, and output according to the respective polarities. Further, the positive terminal and the positive conductor are connected, and the negative terminal and the negative conductor are connected.

The power supply control device 20 includes a first conversion unit 21, a second conversion unit 22, a regulation unit 23, a first voltmeter 241 and a second voltmeter 242, and a test circuit 25.
The first conversion unit 21 converts AC power into DC power supplied to the load device 30.

The first conversion unit 21 includes a plurality of first AC-DC converters 211. Each of the plurality of first AC-DC converters 211 has an input side and an output side, converts AC power input from the input side into DC power, and outputs DC power from the output side. Hereinafter, the input side of the first AC-DC converter 211 is also referred to as an AC side, and the output side of the first AC-DC converter 211 is also referred to as a DC side. Although the first conversion unit 21 shows two first AC-DC converters 211 in FIG. 1, the number of first AC-DC converters 211 included in the first conversion unit 21 is limited to two. It's not something. For example, the number of the first AC-DC converters 211 included in the first conversion unit 21 may be three or more. Further, the number of the first AC-DC converters 211 included in the first conversion unit 21 may be one instead of a plurality.

Further, a plurality of first AC-DC converters 211 provided in the first conversion unit 21 are arranged in parallel. In each of the plurality of first AC-DC converters 211 included in the first conversion unit 21, the input side and the AC input terminal 20a are electrically connected, and the output side and the DC input / output terminal 20b and the DC output terminal 20c are electrically connected. Connected to.

The connection between the plurality of first AC-DC converters 211 and the AC input terminal 20a, the DC input / output terminal 20b, and the DC output terminal 20c is electrically connected by a positive conductor and a negative conductor, respectively. The positive and negative conductors connected to the AC input terminal 20a, the DC input / output terminal 20b, and the DC output terminal 20c are branched into each of the plurality of first AC-DC converters 211 and electrically connected.

The second conversion unit 22 includes a plurality of second AC-DC converters 221. The plurality of second AC-DC converters 221 each have an input side and an output side, convert AC power input from the input side into DC power, and output DC power from the output side. Hereinafter, the input side of the second AC-DC converter 221 is also referred to as an AC side, and the output side of the second AC-DC converter 221 is also referred to as a DC side. Although the second conversion unit 22 shows two second AC-DC converters 221 in FIG. 1, the number of the second AC-DC converters 221 included in the second conversion unit 22 is limited to two. It's not something. For example, the number of the second AC-DC converter 221 included in the second conversion unit 22 may be three or more. Further, the number of the second AC-DC converter 221 included in the second conversion unit 22 may be one instead of a plurality.

Further, a plurality of second AC-DC converters 221 provided in the second conversion unit 22 are arranged in parallel. In each of the plurality of second AC-DC converters 221 included in the second conversion unit 22, the input side and the AC input terminal 20a are electrically connected, and the output side and the DC input / output terminal 20b and the DC output terminal 20c are electrically connected. Connected to.

Further, the conducting wire from which the DC power is output from the second conversion unit 22 and the conducting wire from which the DC power is output from the power storage device 40 via the DC input / output terminal 20b are electrically connected.
The connection between the plurality of second AC-DC converters 221 and the AC input terminal 20a, the DC input / output terminal 20b, and the DC output terminal 20c is made by a positive lead wire having a positive polarity and a negative lead wire having a negative polarity, respectively. It is electrically connected. Further, the positive conductor and the negative conductor are electrically connected by branching from the AC input terminal 20a, the DC input / output terminal 20b and the DC output terminal 20c to each of the plurality of second AC-DC converters 221.

The positive and negative conductors connected to the AC side of the plurality of first AC-DC converters 211 and the positive and negative conductors connected to the AC side of the plurality of second AC-DC converters 221 are positive and negative conductors. The conductors are electrically connected to each other.

Further, the positive and negative conductors connected to the DC side of the plurality of first AC-DC converters 211 and the positive and negative conductors connected to the DC side of the plurality of second AC-DC converters 221 are the positive conductors and the negative conductors. And the minus conductors are electrically connected to each other.

A regulation unit 23 is arranged between the positive conductor on the DC side of the first conversion unit 21 electrically connected and the positive conductor on the DC side of the second conversion unit 22.
The regulation unit 23 allows the outflow of DC power from the second conversion unit 22 to the first conversion unit 21, while prohibiting the outflow of DC power from the first conversion unit 21 to the second conversion unit 22, so-called. It is a diode. The regulating unit 23 is not limited to the diode element, and may not be an element as long as it has such a function.

A first voltmeter 241 is arranged between a positive conductor and a negative conductor connected to the DC side of a plurality of first AC-DC converters 211 on the side where DC power is output from the first conversion unit 21. NS. The first voltmeter 241 measures the potential difference between the positive conductor and the negative conductor on the output side of the plurality of first AC-DC converters 211. Here, the voltage measured by the first voltmeter 241 is also referred to as the first voltage V1.

Further, the potential difference between the positive conductor and the negative conductor connected to the side where the DC power is output from the second conversion unit 22, in other words, the DC side of the plurality of second AC-DC converters 221 is measured. Here, the voltage measured by the second voltmeter 242 is also referred to as the second voltage V2.

The first voltmeter 241 is arranged closer to the first conversion unit 21 than the regulation unit 23, and the second voltmeter 242 is arranged closer to the second conversion unit 22 than the regulation unit 23.
Further, the positive and negative conductors of the first conversion unit 21 and the second conversion unit 22 are electrically connected to the positive and negative terminals of the AC input terminal 20a, the DC input / output terminal 20b, and the DC output terminal 20c, respectively. Will be done.

The test circuit 25 performs a normality confirmation process. The normality confirmation process is control of the output voltage performed for each of the plurality of second AC-DC converters 221 provided by the second conversion unit 22.
The details of the normality confirmation process performed by the test circuit 25 will be described later.

In the power supply control device 20, when the test circuit 25 is not performing the normality confirmation process, the voltage of the conductor inside the power supply control device 20 is the voltage as shown in FIGS. 2 (A) and 2 (B). Is shown. The voltage of the conducting wire inside the power supply control device 20 referred to here is the potential difference between the positive conducting wire and the negative conducting wire in each conducting wire.

Hereinafter, the voltage of the DC power output from the first conversion unit 21 is referred to as a direct transmitter voltage Vp. The direct transmitter voltage Vp is measured by the first voltmeter 241.
Further, the voltage of the DC power output from the second conversion unit 22 is referred to as the charger voltage Vc. The charger voltage Vc is configured to be adjustable by the test circuit 25 executing a normality confirmation process on a plurality of second AC-DC converters 221 included in the second conversion unit 22.

The voltage of the DC power output from the power storage device 40 is also referred to as the battery voltage Vb.
The value of the direct transmitter voltage Vp is set by, for example, the AC power supply 10 and the first conversion unit 21. The direct transmitter voltage Vp also coincides with the first voltage V1 measured by the first voltmeter 241.

On the other hand, inside the power supply control device 20, the DC power of the battery voltage Vb is output from the power storage device 40 via the lead wire from which the DC power of the charger voltage Vc is output from the second conversion unit 22 and the DC input / output terminal 20b from the power storage device 40. It is electrically connected to the lead wire to be connected. Further, a second voltmeter 242 is arranged in the conducting wire.

That is, the second voltage V2 indicates the same voltage as the higher voltage of the charger voltage Vc and the battery voltage Vb. When the voltage discharged from the power storage device 40 is lower than the voltage of the DC power output from the second conversion unit 22, the DC power output from the second conversion unit 22 charges the battery.

Here, as shown in FIG. 3A, the test circuit 25 performs normality confirmation processing on the output voltages of the plurality of second AC-DC converters 221 included in the second conversion unit 22 by the normality confirmation processing. The test voltage is set to Vt, which is a lower value than the voltage in the normal state, which is not in the normal state. In this case, when the power storage device 40 is connected to the power supply control device 20 and is functioning normally, it is the voltage measured by the second voltmeter 242 as shown in FIG. 3 (B). The second voltage V2 shows the same voltage value as in the normal state.

On the other hand, when the power storage device 40 is not connected to the power supply control device 20, or when the power storage device 40 is not functioning normally due to a failure or the like, or when the power supply from the power storage device 40 is abnormal. As shown in FIG. 4A, the battery voltage Vb drops to the test voltage Vt, which is the charger voltage Vc set by starting the normality confirmation process. Here, as shown in FIG. 4B, when the second voltage V2 of the second voltmeter 242 is subjected to the normality confirmation process and drops to the test voltage Vt which is the charger voltage Vc, the parasitic wire is parasitic. Due to the influence of capacitance, the decrease of the second voltage V2 may be prevented. Then, when the normality confirmation process is completed, the charger voltage Vc is set to the same voltage as the normal state, so that the second voltage V2, which is the measured voltage of the second voltmeter 242, is the same voltage as the charger voltage Vc. Is shown.
As shown in FIG. 4A, for example, the power supply control device 20 may perform control to gradually increase the charger voltage Vc in accordance with the battery voltage Vb when the normality confirmation process is completed. ..

Further, the first conversion unit 21, the second conversion unit 22, the regulation unit 23, the second voltmeter 242, the test circuit 25, and the power storage device 40 in the present embodiment are the first conversion unit and the second conversion unit 40, respectively, within the scope of the claims. It corresponds to an example of the configuration as a conversion unit, a regulation unit, a measurement unit, a control unit, and a power storage unit.

[1-2. process]
Next, the normality confirmation process executed by the test circuit 25 will be described with reference to the flowchart of FIG. The normality confirmation process is a process for confirming the normality for confirming whether or not the power storage device 40 functions normally. The normality confirmation process may be started when, for example, the operator of the power supply control device 20 performs an operation to perform the normality confirmation process. Further, the start of the normality confirmation process is not limited to the time when the operation is performed so as to perform the normality confirmation process, and may be, for example, repeatedly executed at predetermined time intervals.

In S110, the test circuit 25 adjusts a plurality of second AC-DC converters 221 included in the second conversion unit 22, sets the charger voltage Vc to the test voltage Vt, and controls to lower the charger voltage Vc. Here, the test voltage Vt may be lower than the charger voltage Vc before starting the normality confirmation process, that is, in the normal state. The test voltage Vt determines that the second voltage V2, which will be described later, has decreased when a failure such as a failure of the power storage device 40, a connection failure, or a discharge failure occurs, or when the power storage device 40 is not connected. It is preferable that the size is set so that it can be used.

In S120, the test circuit 25 waits for a predetermined time. The predetermined time referred to here is longer than the time required for the second voltage V2 to change to the test voltage Vt when the charger voltage Vc is set to the test voltage Vt and there is an abnormality in the power storage device 40. It may be set. The predetermined time may be set to be longer than the discharge time at which the charge accumulated by the parasitic capacitance is sufficiently discharged, for example.

In S130, the test circuit 25 acquires the second voltage V2 measured by the second voltmeter 242.
In S140, the test circuit 25 determines whether or not the normal condition indicating that the second voltage V2 power storage device 40 is normal is satisfied based on the second voltage V2 measured in S130.

Here, the normal condition may be based on, for example, the second voltage V2 measured by the second voltmeter 242 and the test voltage Vt set in S110. Specifically, the normal condition may be that the second voltage V2 is included in the threshold range with respect to the test voltage Vt. Further, the threshold range may be set to a voltage range that can be determined to be about the same as the test voltage Vt.

When the test circuit 25 determines in S140 that the normal condition is satisfied, the process shifts to S150.
In S150, the test circuit 25 determines that the power supply from the power storage device 40 connected to the power supply control device 20 is normal, and shifts the process to S170, which will be described later.

On the other hand, when the test circuit 25 determines in S140 that the normal condition is not satisfied, the process shifts to S160.
In S160, the test circuit 25 determines that there is an abnormality in the power supply from the power storage device 40 connected to the power supply control device 20. Here, an abnormality in the power supply from the power storage device 40 means that, for example, a failure of the power storage device 40, a connection failure, a discharge failure, or the like occurs, or when the power storage device 40 is not connected, the power storage device 40 It means that power of a predetermined voltage is not supplied.

In S170, the test circuit 25 controls the voltage to be restored with respect to the voltage control performed in S110, and then ends the normality confirmation process. That is, the charger voltage Vc is controlled to the voltage in the normal state before the voltage is lowered in S110, and then the normality confirmation process is terminated.

[1-3. effect]
According to the first embodiment described in detail above, the following effects are obtained.
(1) According to the first embodiment, when the normality confirmation process is performed, the charger voltage Vc, which is the voltage of the DC power output from the second conversion unit 22, is the voltage output from the power storage device 40. The test voltage Vt is adjusted to be lower than a certain battery voltage Vb. As a result, the voltage input from the second conversion unit 22 or the power storage device 40 is measured by the second voltmeter 242, so that it is possible to determine whether or not the power storage device 40 is operating normally.

For example, when the power storage device 40 is not connected or a problem such as a failure occurs and the normality confirmation process is performed, the second voltage V2 measured by the second voltmeter 242 becomes the test voltage Vt. Become. Thereby, it can be determined whether or not the power storage device 40 is appropriate. Here, the DC power output from the first conversion unit 21 is supplied to the load device 30 even during the normality confirmation process. Therefore, the power of the power storage device 40 is supplied to the load device 30 for normality confirmation, and it becomes easy to suppress the consumption of the power charged in the power storage device 40.

(2) Further, it is suppressed that the electric power of the power storage device 40 is consumed because the normality is confirmed. As a result, when the power is output from the power storage device 40 when the supply of AC power to the power supply control device 20 is stopped, the power of the power storage device 40 is consumed because the normality is confirmed, and the power storage device 40 It becomes easy to suppress the decrease in the amount of charge.

Specifically, in the conventional power supply system, for example, as shown in FIG. 6, when the normality confirmation is started, the direct transmitter voltage Vp and the charger voltage Vc are lowered, and DC power is output from the power storage device. .. Then, it was determined whether or not the power storage device was normal by measuring the voltage of the output DC power. Therefore, the electric power stored in the power storage device is consumed by the normality confirmation.

Therefore, when the direct transmitter voltage Vp is returned to the original value after the normality confirmation is completed, both the power for charging the consumed electric energy of the power storage device and the power to be supplied to the load device are consumed. , The power consumption increases temporarily. In the conventional power supply system, for example, when the normality confirmation is completed, the charger voltage Vc is gradually increased in accordance with the battery voltage Vb.

Further, since the power of the power storage device is consumed for the normality confirmation, for example, when the power supply from the power storage device is required after the power of the power storage device is consumed by the normality check, the normality confirmation is performed. Since the power of the power storage device is consumed, the amount of power that can be supplied from the power storage device is reduced.

On the other hand, according to the power supply control device 20 described in the first embodiment, even if the normality confirmation process is started, the DC power is not output from the power storage device 40, and the power storage device 40 is in a normal state. It can be determined whether or not. As a result, it becomes easy to suppress an increase in power consumption after the normality confirmation process is completed. In addition, it becomes easy to prevent the amount of electric power that can be supplied from the power storage device 40 from being reduced by the normality confirmation process.

(3) Further, the power of the power storage device 40 is consumed when the normality is confirmed, and the number of charge / discharge cycles for the power storage device 40 is reduced as compared with the case where the power of the power storage device 40 is charged again after the normality is confirmed. be able to. Therefore, it is possible to prevent the power storage device 40 from being consumed by the charge / discharge cycle. As a result, it becomes easy to prevent the battery life of the power storage device 40 from being shortened.

(4) According to the power supply control device 20 described in the first embodiment, the regulation unit 23 suppresses the DC power output by the first conversion unit 21 from flowing back to the output side of the second conversion unit 22. can do. In particular, even when the output voltage of the first conversion unit 21 is higher than the output voltage of the second conversion unit 22, it is possible to prevent the power of the first conversion unit 21 from flowing back to the output side of the second conversion unit 22. Can be done.

(5) According to the power supply control device 20 described in the first embodiment, the measured value by the second voltmeter 242 is used as a parameter for determining whether the power supply from the power storage device 40 is normal or abnormal. The second voltage V2 is obtained.

(6) Further, according to the power supply control device 20 described in the first embodiment, the second voltage V2, which is a parameter for determining whether the power supply from the power storage device 40 is normal or abnormal, is set in advance. It is possible to determine whether or not the power storage device 40 is normal by determining whether or not it is equal to or greater than a predetermined threshold value.

(7) According to the power supply control device 20 described in the first embodiment, even if the positive conductor and the negative conductor have a parasitic capacitance in the normality confirmation process, the charge accumulated by the parasitic capacitance is sufficient. After a predetermined standby time longer than the discharge time to be discharged to, it is determined whether or not the power storage device 40 is in a normal state. As a result, it becomes easy to suppress a decrease in the accuracy of determining whether or not the state is normal due to the influence of the parasitic capacitance. Therefore, it is possible to improve the accuracy of determining whether or not the state is normal.

Specifically, even if the charger voltage Vc is set low in S110, the measured value of the second voltmeter 242 is gentle due to the influence of parasitic capacitances such as the plus lead wire and the minus lead wire connected to the second conversion unit 22. May drop to. Therefore, the difference between the measured value of the second voltmeter 242 in the normal state and the measured value of the second voltmeter 242 in the abnormal state becomes large enough to determine the state. Wait for the time. As a result, if there is a problem such as when the power storage device 40 is not connected or the power storage device 40 is out of order and power is not supplied correctly from the power storage device 40, it is based on the measurement by the second voltmeter 242. The accuracy of determining the normal state and the abnormal state can be further improved.

[1-4. Modification example of the first embodiment]
(1) The timing at which the normality confirmation process is started is not limited to those operated by the operator of the power supply control device 20, but is limited to those that are repeatedly executed at predetermined time intervals. is not it. For example, the normality confirmation process may be executed when a signal indicating an abnormality of power supply from the power storage device 40 is received from a peripheral device of the power storage device 40 such as the power storage device 40 or the DC input / output terminal 20b. According to such a configuration, when a signal indicating an abnormality is received, the power supply control device 20 also measures the voltage of the power storage device 40 to determine whether the power storage device 40 is normal or abnormal. Can be done.

(2) In the normality confirmation process of the first embodiment, the normal condition is based on, for example, the second voltage V2 measured by the second voltmeter 242 and the test voltage Vt set in S110. It is stated that it may be used.

However, the normal conditions are not limited to those based on the second voltage V2 and the test voltage Vt. For example, the difference between the second voltage V2 measured by the second voltmeter 242 and the second voltage V2 measured by the second voltmeter 242 in the normal state before the start of the test in which the voltage is controlled in S110. It may be smaller than a predetermined threshold.

(3) In the normality confirmation process of the first embodiment, when the test circuit 25 executes the normality confirmation process and determines that the normal condition is satisfied, the power supply from the power storage device 40 is normal in S150. When it was determined that the normal condition was not satisfied, it was determined in S160 that the power supply from the power storage device 40 was abnormal. However, the determination of whether the power supply from the power storage device 40 is normal or abnormal is not limited to those determined in this way, and the power storage device satisfies the abnormality condition corresponding to the abnormality of the power supply. It may be determined that the power supply from 40 is abnormal. Specifically, for example, assuming that the value of the second voltage V2 is equal to or less than a predetermined voltage threshold value, it is determined that the power supply from the power storage device 40 is abnormal when the abnormal condition is satisfied. You may.

(4) Further, in the first embodiment, the test circuit 25 determines whether the power supply from the power storage device 40 is normal or abnormal, and further determines whether the power supply is normal or abnormal. It may have a configuration to be displayed.

(5) Further, the test circuit 25 does not have to determine whether the power supply from the power storage device 40 is normal or abnormal. Further, the power supply control device 20 does not have to have a configuration for determining whether the power supply from the power storage device 40 is normal or abnormal. For example, the power supply control in which the test circuit 25 or another configuration included in the power supply control device 20 measures a parameter for determining whether the power supply from the power storage device 40 is normal or abnormal, and acquires the parameter. It may be determined whether the other configuration included in the device 20 or the external configuration of the power supply control device 20 is normal or abnormal in the power supply from the power storage device 40.

(6) In the first embodiment, in the normality confirmation process, S120 waits for a predetermined time in order to determine whether the power supply from the power storage device 40 is normal or abnormal. However, the process of waiting for a predetermined time to determine whether the power supply from the power storage device 40 is normal or abnormal may not be performed. According to such a configuration, it is possible to quickly determine whether the power supply from the power storage device 40 is normally output or abnormal. Further, for example, the change in the potential of the voltage measured by the second voltmeter 242 per unit time is measured, and when a change having a magnitude equal to or greater than the threshold value of the rate of change representing a predetermined abnormality occurs, storage is stored. It may be determined that the power supply from the device 40 is abnormal. The magnitude of the threshold value of the rate of change indicating that the power supply from the power storage device 40 is abnormal is, for example, when the power supply from the power storage device 40 is abnormal and is affected by the parasitic capacitance of the conducting wire. It may be set to be smaller than the changing rate of change and larger than the rate of change of the charger voltage Vc that changes due to fluctuations and variations when the power supply from the power storage device 40 is normal.

Further, in the first embodiment, it is determined whether the power supply from the power storage device 40 is normal or abnormal based on the voltage measured by the second voltmeter 242, but whether it is normal or abnormal is determined. The configuration for determining is not limited to the measurement value of the second voltmeter 242. For example, in the positive conductor in which the regulation unit 23 is arranged, the determination may be made by measuring the potentials at both ends of the regulation unit 23. That is, it may be determined whether or not the power supply from the power storage device 40 is abnormal based on the DC power output from the first conversion unit 21 and the DC power output from the second conversion unit 22. Specifically, when there is a difference in magnitude between the DC power output from the first conversion unit 21 and the DC power output from the second conversion unit 22 by a predetermined threshold value or more, the power storage device It may be determined that the power supply from 40 is abnormal.

The direct current voltage Vp, which is the voltage of the DC power output from the first conversion unit 21, is substantially constant even if the normality confirmation is started. On the other hand, the charger voltage Vc, which is the voltage of the DC power output from the second conversion unit 22, decreases due to the normality confirmation, and the regulation unit 23 tells the battery, which is the voltage of the DC power output from the power storage device 40. A voltage Vb is applied. Here, if there is no abnormality in the power supply from the power storage device 40, the voltage on the side connected to the second conversion unit 22 of the regulation unit 23 and the power storage device 40 does not decrease. As a result, the potential difference between the first conversion unit 21 side and the second conversion unit 22 and the power storage device 40 side across the regulation unit 23 is the same after the start of the normality confirmation as before the start of the normality confirmation.

On the other hand, when there is an abnormality in the power supply from the power storage device 40, the voltage on the side connected to the second conversion unit 22 of the regulation unit 23 and the power storage device 40 decreases. As a result, the potential difference between the first conversion unit 21 side and the second conversion unit 22 and the power storage device 40 side across the regulation unit 23 becomes larger after the start of the normality confirmation than before the start of the normality confirmation.

From the above, by measuring the voltage across the first conversion unit 21 side of the regulation unit 23, the second conversion unit 22, and the power storage device 40 side, it can be determined whether the power supply from the power storage device 40 is normal or abnormal. You may judge.

(7) In the first embodiment, the number of the first AC-DC converter 211 provided in the first conversion unit 21 and the number of the second AC-DC converter 221 provided in the second conversion unit 22 is a plurality. However, the number of the first AC-DC converters 211 provided in the first conversion unit 21 and the number of the second AC-DC converters 221 provided in the second conversion unit 22 are not limited to a plurality, and each is one. There may be.

(8) In the first embodiment, for example, a breaker or a switch may be arranged between the power storage device 40 and the power supply control device 20. Further, the number of breakers and switches to be arranged may be plural. The switch may be opened so as to perform work such as replacement of the power storage device 40, and may be configured so that power from the power storage device 40 is not supplied. With such a configuration, since power is not supplied from the power storage device 40 in the open state, it is possible to detect forgetting to return the switch to the power storage device 40 after work.

(9) Further, the first voltmeter 241 and the second voltmeter 242 are arranged between the plus lead wire and the minus lead wire that output DC power from the first AC-DC converter 211 and the second AC-DC converter 221 respectively. It is illustrated as. However, the position where the first voltmeter 241 and the second voltmeter 242 are arranged is not limited to such a position, and the first voltmeter 241 is the DC power output from the first conversion unit 21. The position of the second voltmeter 242 is not particularly limited as long as it can measure the voltage of the DC power output from the first conversion unit 21 and the voltage of the DC power output from the power storage device 40.

[2. Second Embodiment]
[2-1. Differences from the first embodiment]
Since the basic configuration of the second embodiment is the same as that of the first embodiment, the differences will be described below. The same reference numerals as those in the first embodiment indicate the same configurations, and the preceding description will be referred to.

Instead of the power supply control device 20 provided in the power supply system 1 in the first embodiment described above, the power supply system 2 in the second embodiment will be described by applying it to an example in which the power supply control device 50 is provided.
As shown in FIGS. 1 and 7, the power supply control device 20 and the power supply control device 50 have the same basic configuration.

That is, the first conversion unit 51, the second conversion unit 52, the regulation unit 53, the first voltmeter 541, the second voltmeter 542, the test circuit 55, the AC input terminal 50a, the DC input / output terminal 50b, and the power supply control device 50. The DC output terminal 50c is the first conversion unit 21, the second conversion unit 22, the regulation unit 23, the first voltmeter 241 and the second voltmeter 242, the test circuit 25, the AC input terminal 20a, and the DC input in the power supply control device 20. The configuration corresponds to the output terminal 20b and the DC output terminal 20c, respectively.

Further, the first AC-DC converter 511 and the second AC-DC converter 521 in the power supply control device 50 correspond to the first AC-DC converter 211 and the second AC-DC converter 221 in the power supply control device 20, respectively.

Similar to the power supply control device 20 of the first embodiment, the AC power supply 10 is electrically connected to the AC input terminal 50a, the power storage device 40 is electrically connected to the DC input / output terminal 50b, and the load device 30 is electrically connected to the DC output terminal 50c. It will be explained by applying it to the example of being connected.

On the other hand, the power supply control device 50 is different from the power supply control device 20 in that the configuration includes a switch 56 and a resistance portion 57.
The switch 56 and the resistance portion 57 are arranged in series on the same conducting wire connecting the positive conducting wire and the negative conducting wire from which the DC power is output from the second conversion unit 52. In other words, the conducting wire in which the switch 56 and the resistance portion 57 are arranged in series is connected to the positive conducting wire and the negative conducting wire of the second conversion unit 52 so as to be in parallel with the second voltmeter 542.

The switch 56 is an openable / closable switch that adjusts the conductors in which the switch 56 and the resistance portion 57 are arranged in series to a state in which they are electrically connected and a state in which they are not electrically connected.
The switch 56 is open / closed controlled by the test circuit 55. That is, the test circuit 55 has the same basic configuration as the test circuit 25 of the first embodiment, but differs in that the switch 56 is controlled.

The resistance portion 57 is a discharge load used for discharging the electric charge accumulated by the parasitic capacitance, and for example, an element such as an electric resistance is used. The resistance portion 57 is not limited to a configuration in which an element such as an electric resistance is used, and is electric as long as it has a configuration capable of discharging the electric charge accumulated by the parasitic capacitance like the element such as the electric resistance. It may have a configuration other than an element such as a resistor.

The first conversion unit 51, the second conversion unit 52, the regulation unit 53, the second voltmeter 542, the test circuit 55, the switch 56, and the resistance unit 57 in the present embodiment are the first conversion units within the scope of the claims. , Corresponds to an example of the configuration as the second conversion unit, the regulation unit, the measurement unit, the control unit, the discharge control unit, and the discharge unit.

[2-2. process]
Next, the normality confirmation process executed by the test circuit 55 of the second embodiment instead of the normality confirmation process of the first embodiment will be described with reference to the flowchart shown in FIG.

The normality confirmation process executed by the test circuit 55 and the normality confirmation process of the first embodiment executed by the test circuit 25 are basically the same. Specifically, the processes S110 to S170 in the normality confirmation process of the first embodiment shown in FIG. 5 are S210 and S230 to S280 in the normality confirmation process of the second embodiment shown in FIG. Corresponds to processing. That is, the normality confirmation process executed by the test circuit 55 of the second embodiment is basically the same as the normality confirmation process executed by the test circuit 25 of the first embodiment except for S220 and S290. be.

On the other hand, in the normality confirmation process executed by the test circuit 55, the process shifts to S220 after S210. Note that S220 is not limited to what is performed after S210, and may be simultaneous with S210 or before S210.

In S220, the test circuit 55 controls the switch 56 to be closed, that is, the positive lead wire and the negative lead wire are electrically connected by the lead wire to which the switch 56 and the resistance portion 57 are connected in series, and the test circuit 55 is connected to S230. Migrate processing.

Further, in the test circuit 55, after the processing of S280, the positive lead wire and the negative lead wire are electrically connected so that the switch of the switch 56 opens in S290, that is, the lead wire in which the switch 56 and the resistance portion 57 are connected in series. Controlled to connect to.

[2-3. effect]
According to the second embodiment described in detail above, the effect of the above-mentioned first embodiment is obtained, and the following effects are further obtained.

(1) In the second embodiment, the power supply control device 50 is further provided with a switch 56 and a resistance portion 57. The switch 56 opens at the start of normality confirmation, and the charge accumulated due to the influence of parasitic capacitance due to the positive and negative conductors being electrically connected via the conductor to which the switch 56 and the resistance portion 57 are connected in series. Can be discharged. As a result, when the normality confirmation process is started, the voltage value measured by the second voltmeter 542 can reduce the influence of the parasitic capacitance as compared with the case where the switch 56 and the resistor portion 57 are not arranged. .. As a result, when there is an abnormality in the power supply from the power storage device 40 arranged in the power supply system 2, the voltage value measured by the second voltmeter 542 is compared with the case where the switch 56 and the resistor portion 57 are not arranged. It can be lowered sharply. As a result, it is possible to more quickly determine whether the power supply from the power storage device 40 is normal or abnormal. In addition, it is possible to improve the accuracy of determining whether the power supply from the power storage device 40 is normal or abnormal.

[2-4. Modification example of the second embodiment]
(1) The normality confirmation process executed by the test circuit 55 of the second embodiment is basically the same as the normality confirmation process executed by the test circuit 25 of the first embodiment except for S220 and S290. It was described.

However, the normality confirmation process executed by the test circuit 55 may be different from the normality confirmation process executed by the test circuit 25. For example, the test circuit 25 of the first embodiment performs a process of waiting for a predetermined time in S120 of the normality confirmation process. However, the test circuit 55 of the second embodiment may omit the process of waiting for a predetermined time in S230 in the normality confirmation process. In the normality confirmation process of the second embodiment, since the switch 56 is closed in S220 and the charge accumulated by the parasitic capacitance is consumed by the resistance portion 57, the normality confirmation process of the first embodiment is performed. Compared with the case where there is an abnormality in the power supply of the power storage device 40, the time until the voltage drops is shorter. Therefore, even if the device does not wait for a predetermined time, it is easy to prevent the voltage drop from being delayed. Therefore, as compared with the configuration without the resistor portion 57, it is possible to improve the accuracy of the determination while shortening the time for determining whether the power supply from the power storage device 40 is normal or abnormal.

(2) Similarly, the switch and the resistor are not limited to those arranged inside the power supply control device 50, and may be arranged outside.
Further, the resistor functions as a discharge load, but the discharge load may be realized by the resistor, and if it has a function of performing discharge, it is not limited to the resistor. do not have. For example, it may be an electronic load. Further, the resistor may be a variable resistor.

Further, the resistance is not limited to one that functions as a discharge load for consuming parasitic capacitance. For example, in order to diagnose the deterioration state based on the transition of the storage battery voltage, which is the voltage of the power output from the power storage device 40 at the time of discharging, the power charged in the power storage device 40 is discharged with an arbitrary resistance value or current value. It may further have a function as a discharge load.

[3. Third Embodiment]
[3-1. Differences from the second embodiment]
Since the basic configuration of the third embodiment is the same as that of the second embodiment, the differences will be described below. The same reference numerals as those in the second embodiment indicate the same configuration, and the preceding description will be referred to.

As shown in FIG. 9, instead of the power supply control device 50 provided in the power supply system 2 in the second embodiment described above, the power supply system 3 in the third embodiment will be described by applying it to an example in which the power supply control device 60 is provided. ..

As shown in FIGS. 7 and 9, the power supply control device 50 and the power supply control device 60 have the same basic configuration.
That is, the first conversion unit 61, the second conversion unit 62, the regulation unit 63, the first voltmeter 641, the second voltmeter 642, the test circuit 65, the switch 66, the resistance unit 67, and the AC input terminal 60a in the power supply control device 60. The DC input / output terminal 60b and the DC output terminal 60c are the first conversion unit 51, the second conversion unit 52, the regulation unit 53, the first voltmeter 541, the second voltmeter 542, and the test circuit 55 in the power supply control device 50. The configuration corresponds to the switch 56, the resistance portion 57, the AC input terminal 50a, the DC input / output terminal 50b, and the DC output terminal 50c, respectively.

Further, the first AC-DC converter 611 and the second AC-DC converter 621 in the power supply control device 60 and the first AC-DC converter 511 and the second AC-DC converter 521 in the power supply control device 50 are basically the same. It is a configuration.

However, the first AC-DC converter 611 and the second AC-DC converter 621 in the power supply control device 60 and the first AC-DC converter 511 and the second AC-DC converter 521 in the power supply control device 50 are different in the following points.

That is, the first conversion unit 61 is different in that the first conversion unit 51 is further provided with a backflow prevention unit 611a. Specifically, in the plus lead wire for which DC power is output from each of the plurality of first AC-DC converters 611 included in the first conversion unit 61, the direction of output from the first AC-DC converter 611 to the DC output terminal 60c. A backflow prevention unit 611a that allows current to flow and prohibits current from flowing in the opposite direction is arranged therein.

Further, the second AC-DC converter 621 of the second conversion unit 62 and the second AC-DC converter 621 of the second conversion unit 52 are different in the following points. That is, the plurality of second AC-DC converters 621 of the second conversion unit 62 are different from the second AC-DC converter 521 in that they include a backflow prevention unit 621a and a third voltmeter 621b. Specifically, in the positive conductor connected to the DC side of the plurality of second AC-DC converters 621 provided in the second conversion unit 62, current is allowed to flow in the direction of output from the second AC-DC converter 621. A backflow prevention unit 621a that prohibits the flow of current in the opposite direction is arranged on each of the positive conductors of the plurality of second AC-DC converters 621. Further, the third voltmeter 621b transfers the voltage between the second AC-DC converter 621 and the backflow prevention unit 621a in the positive conductor of the second AC-DC converter 621 and the voltage between the negative conductor of the second AC-DC converter 621. Measure. Here, the voltage measured by the third voltmeter 621b is also referred to as the third voltage V3 below.

The first conversion unit 61, the second conversion unit 62, the backflow prevention units 621a, 622a, the regulation unit 63, the second voltmeter 642, the test circuit 65, the switch 66, and the resistance unit 67 in the present embodiment are claimed for patent. It corresponds to an example of the configuration as the first conversion unit, the second conversion unit, the backflow prevention unit, the regulation unit, the measurement unit, the control unit, the discharge control unit, and the discharge unit in the range.

[3-2. process]
Next, the normality confirmation process executed by the test circuit 65 of the third embodiment instead of the normality confirmation process of the second embodiment will be described with reference to the flowchart shown in FIG.

The normality confirmation process executed by the test circuit 65 and the normality confirmation process of the second embodiment executed by the test circuit 55 are basically the same.
On the other hand, in S240 of the normality confirmation process of the second embodiment executed by the test circuit 55, whether or not the power supply control device 60 is in the normal state by acquiring the voltage measured by the second voltmeter 542. Was judged. However, in the normality confirmation process executed by the test circuit 65, the second voltage V2 measured by the second voltmeter 542 and the third voltage V3 measured by the third voltmeter 621b in S340 are acquired, and the second voltage is obtained. The difference is that it is determined whether or not the power supply control device 60 is in the normal state by comparing V2 with the third voltage V3.

Specifically, when the third voltage V3 is smaller than the second voltage V2, it is determined that the power supply from the power storage device 40 is normal, and when the third voltage V3 is the second voltage V2 or more. It is determined that the power supply from the power storage device 40 is abnormal.

[3-3. effect]
(1) According to the third embodiment, it is possible to determine whether the power supply from the power storage device 40 is normal or abnormal based on the third voltage V3 measured by the third voltmeter 621b. ..

Specifically, by comparing the third voltage V3 and the second voltage V2, it is possible to determine whether the power supply from the power storage device 40 is normal or abnormal.
That is, the side connected to the positive conductor of the third voltmeter 621b has the same potential as the positive conductor output from the second AC-DC converter 621, and the side connected to the negative conductor of the third voltmeter 621b has the same potential. The potential is the same as that of the negative lead wire to which DC power is output from the power storage device 40. The potential difference between these positive and negative conductors is measured as the third voltage V3.

On the other hand, the side connected to the positive conductor of the second voltmeter 642 has the same potential as the positive conductor output from the power storage device 40, and the side connected to the negative conductor of the second voltmeter 642 has the same potential as the power storage device 40. It becomes the same potential as the minus lead wire from which DC power is output. The potential difference between these positive and negative conductors is measured as the second voltage V2.

Here, since the potentials of the negative conducting wires being measured are the same for the third voltage V3 and the second voltage V2, the DC power is output from the second AC-DC converter 621 by measuring the potential difference. It is possible to compare the potential of the lead wire with the potential of the positive lead wire to which DC power is output from the power storage device 40.

As a result, when the potential difference between the positive and negative conductors of the power storage device 40 is larger than the potential difference between the positive and negative conductors of the second AC-DC converter 621, the output voltage of the power storage device 40 is the second AC-DC converter. It can be determined that the voltage is higher than the output voltage output from 621, and it can be determined that the power supply from the power storage device 40 is normal.

Therefore, if the third voltage V3 is smaller than the magnitude of the second voltage V2, it is determined that the power supply from the power storage device 40 is normal, and conversely, if the third voltage V3 is the second voltage V2 or more, the power storage is performed. It can be determined that the power supply from the device 40 is abnormal.

(2) Further, in the third voltmeter 621b, since the backflow prevention unit 621a and the third voltmeter 621b are arranged in each of the plurality of second AC-DC converters 621, any of the plurality of second AC-DC converters 621 is tentatively arranged. If there is an abnormality, the second AC-DC converter 621 that has an abnormality based on the output voltage of the second AC-DC converter 621 measured by the third voltmeter 621b corresponding to the second AC-DC converter 621 is used. Can be identified.

[3-4. Modification example of the third embodiment]
(1) Although the differences from the second embodiment have been described in the third embodiment, the third embodiment is not limited to the configuration including the configuration of the second embodiment. For example, even if the configuration of the power supply control device 20 of the first embodiment, that is, a configuration that does not include the switch 56 and the resistance portion 57, includes a backflow prevention unit 611a, a backflow prevention unit 621a, and a third voltmeter 621b. good. Further, in S130 of the normality confirmation process executed by the test circuit 25 of the power supply control device 20 of the first embodiment, the second voltage V2 and the third voltage V3 are acquired, and are based on the second voltage V2 and the third voltage V3. Therefore, it may be determined whether or not the power supply from the power storage device 40 is normal.

(2) Further, different test voltages Vt may be set for each of the plurality of first AC-DC converters 611 and the plurality of second AC-DC converters 621.
In this case, it may be determined whether or not the power supply from the power storage device 40 is normal by comparing the highest test voltage Vt and the second voltage V2 among the different set test voltages Vt.

[4. Other embodiments]
Although the embodiments of the present disclosure have been described above, the present disclosure is not limited to the above-described embodiments, and can be implemented in various modifications.

(1) In each of the above embodiments, the power storage device 40 is arranged outside the power supply control devices 20, 50, 60. However, the position where the power storage device 40 is arranged is not limited to the outside of the power supply control devices 20, 50, 60. For example, the power storage device 40 may be arranged inside the power supply control devices 20, 50, 60.

(2) Further, in each of the above embodiments, the test circuits 25, 55, 65 are arranged inside the power supply control devices 20, 50, 60. However, the positions where the test circuits 25, 55, 65 are arranged are not limited to the inside of the power supply control devices 20, 50, 60. For example, the test circuits 25, 55, 65 may be arranged outside the power supply control devices 20, 50, 60.

(3) In each of the above embodiments, the polarities of the conductors described as positive conductors and negative conductors and the terminals described as positive terminals and negative terminals may be reversed. That is, the power may be supplied by the positive terminal and the positive conductor and grounded by the negative terminal and the negative conductor, or conversely, the power may be supplied by the positive terminal and the positive conductor and the power may be supplied by the negative terminal and the negative conductor.

(4) In the normality confirmation process of each of the above embodiments, it is determined in S140, S250, and S350 whether or not the normal condition is satisfied, and if it is determined that the normal condition is satisfied, S150, S260, and S360 respectively. It was determined that the power supply from the power storage device 40 was normal.

However, the determination of whether or not the power supply from the power storage device 40 is normal is not limited to such a method.
For example, the determination as to whether or not the normal condition is satisfied may be performed a plurality of times. Further, it is determined whether or not the normal condition is satisfied a plurality of times, and if it is determined that the normal condition is not satisfied even once among the determinations made a plurality of times, the power supply from the power storage device 40 is abnormal. It may be determined that there is.

By determining whether or not the normal condition is satisfied a plurality of times in this way, when there is an abnormality in the power supply from the power storage device 40, the abnormality is more likely to be detected.
Further, in the case of determining whether or not the normal condition is satisfied a plurality of times, if it is determined that the normal condition is not satisfied once, the subsequent process of determining whether or not the normal condition is satisfied is omitted, and the power storage device 40 It may be determined that the power supply from is abnormal.

According to such a configuration, if it is determined that the normal condition is not satisfied once, then the determination as to whether or not the normal condition is satisfied a plurality of times is omitted, so that the processing load due to the multiple determinations is performed. And the processing time and the like can be reduced.

Further, when it is determined whether or not the normal condition is satisfied a plurality of times, and if it is determined that the normal condition is not satisfied even once, it is always determined that the power supply from the power storage device 40 is abnormal. Not limited to things.

For example, when it is determined that the abnormality condition is satisfied more than a predetermined number of times, the power supply from the power storage device 40 may be determined to be abnormal.
According to such a configuration, for example, even if a measurement error or the like is included in the numerical value for determining whether or not the normal condition is satisfied and it is determined to be abnormal, the measurement error causes an abnormality. It becomes easy to suppress the judgment that there is, and it is possible to improve the judgment system as to whether or not it is normal.

Further, when the determination as to whether or not the normal condition is satisfied is performed a plurality of times, the repetition cycle of the determination may be performed at a predetermined time interval. In this case, the time interval of the repetition cycle may be arbitrarily set.

According to such a configuration, for example, when the change from normal to abnormal along the time can be detected, the change can be detected.
(5) The power control devices 20, 50, 60 and the method thereof described in the present disclosure constitute a processor and a memory programmed to execute one or more functions embodied by a computer program. It may be realized by a dedicated computer provided by. Alternatively, the power control devices 20, 50, 60 and methods thereof described in the present disclosure may be realized by a dedicated computer provided by configuring the processor with one or more dedicated hardware logic circuits. Alternatively, the power control devices 20, 50, 60 and methods thereof described in the present disclosure consist of a processor and memory programmed to perform one or more functions and one or more hardware logic circuits. It may be realized by one or more dedicated computers configured in combination with a processor. The computer program may also be stored on a computer-readable non-transitional tangible recording medium as an instruction executed by the computer. The method for realizing the functions of each part included in the power control devices 20, 50, and 60 does not necessarily include software, and even if all the functions are realized by using one or more hardware. good.

(6) A plurality of functions possessed by one component in the above embodiment may be realized by a plurality of components, or one function possessed by one component may be realized by a plurality of components. .. Further, a plurality of functions possessed by the plurality of components may be realized by one component, or one function realized by the plurality of components may be realized by one component. Further, a part of the configuration of the above embodiment may be omitted. In addition, at least a part of the configuration of the above embodiment may be added or replaced with the configuration of the other above embodiment.

(7) In addition to the power supply control devices 20, 50, 60 described above, a system having the power supply control devices 20, 50, 60 as components, and a program for operating a computer as the power supply control devices 20, 50, 60. The present disclosure can also be realized in various forms such as a non-transitional actual recording medium such as a semiconductor memory in which this program is recorded, a power supply control method, and the like.

1,2,3 ... Power supply system, 10 ... AC power supply, 20, 50, 60 ... Power control device, 20a, 50a, 60a ... AC input terminal, 20b, 50b, 60b ... DC input / output terminal, 20c, 50c, 60c ... DC output terminal, 21,51,61 ... 1st conversion unit, 22,52,62 ... 2nd conversion unit, 23,53,63 ... Regulation unit, 241 ... 1st voltmeter, 242 ... 2nd voltmeter, 25, 55, 65 ... Test circuit, 56, 66 ... Switch, 57, 67 ... Resistance part, 30 ... Load device, 40 ... Power storage device, 211,511,611 ... First AC-DC converter, 221,521,621 ... Second AC-DC converter, 611a, 621a ... Backflow prevention unit.

Claims (5)

The first conversion unit that converts AC power into DC power and outputs the converted DC power,
A second conversion unit that is electrically connected in parallel with the first conversion unit, converts AC power into DC power, and outputs the converted DC power.
In a conducting wire to which DC power is output from the first conversion unit and the second conversion unit, the first conversion unit is provided between the first conversion unit and the second conversion unit, and the second conversion unit to the first conversion unit. A regulation unit that allows the current flow toward the second conversion unit and regulates the current flow from the first conversion unit to the second conversion unit.
A voltage on the side where DC power is output from the second conversion unit, which is lower than a predetermined voltage output from a power storage unit which is rechargeably connected between the second conversion unit and the regulation unit. A control unit configured to be able to control the voltage of the DC power output from the second conversion unit to the test voltage.
A measuring unit that measures the voltage input from the second conversion unit or the power storage unit to the regulating unit,
A power control unit. The power supply control device according to claim 1.
A discharge unit configured to be able to discharge electric power between the second conversion unit and the power storage unit,
A power control unit. The power supply control device according to claim 2.
A discharge control unit configured to perform discharge control for discharging from the power storage unit when the control unit controls to adjust the voltage output from the second conversion unit to the test voltage.
A power control device further equipped with. The power supply control device according to any one of claims 1 to 3.
It is connected between the conducting wire that electrically connects the power storage unit and the regulation unit and the second conversion unit, and allows the flow of current from the second conversion unit to the power storage unit or the regulation unit. A power supply control device further comprising a backflow prevention unit that regulates the flow of current from the power storage unit or the regulation unit to the second conversion unit. The power supply control device according to claim 4.
A conversion measuring unit that measures the voltage output from the second conversion unit toward the backflow prevention unit,
A power control unit.

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