JP2023146027A - Circuit breaker and distribution board - Google Patents

Abstract

To provide a circuit breaker and the like that can easily update a software program for detecting abnormalities when a plurality of software programs are used.SOLUTION: A circuit breaker 100 includes: a first detection unit 11 that detects a first abnormality regarding an electrical path based on the current value or voltage value of an electrical path between an AC power source AC and a load 31 by executing a first software program; a second detection unit 12 that detects a second abnormality different from the first abnormality by executing a second software program different from the first software program; and a control unit that updates the first software program based on first update information for updating the first software program and updates the second software program based on second update information for updating the second software program. The acquisition route of the first update information and the acquisition route of the second update information are different.SELECTED DRAWING: Figure 1

Description

The present invention relates to a circuit breaker and a distribution board.

Patent Document 1 discloses a circuit breaker (earth leakage breaker) that includes an overcurrent detector that detects overcurrent in an electrical circuit and a leakage current detector that detects leakage current (that is, leakage) in the electrical circuit. There is. Such circuit breakers detect multiple types of abnormalities in the distribution board, such as overcurrent and leakage.

Japanese Patent Application Publication No. 2017-045706

By the way, in recent years, new types of electrical appliances have been created, and these electrical appliances are connected to an AC power supply as a new type of load different from existing loads, for example in houses. Even when such new types of loads are used, it is necessary to detect abnormalities in the distribution board.

However, when the above-mentioned new types of loads are connected to the distribution board and in use, it is possible to detect abnormalities in the electrical circuit by running the software stored in the distribution board at the time of manufacturing or shipping the distribution board. If so, false detection may occur. An example of false detection is a case where it is mistakenly detected that an abnormality has occurred even though no abnormality has occurred. For example, in the circuit breaker and distribution board disclosed in Patent Document 1, even if a new type of load is used, it is assumed that the software stored at the time of manufacture will be executed to perform detection. , there is a risk of frequent false positives.

Therefore, in order to prevent false detection from occurring when a new type of load is connected to the distribution board, it is necessary to update the software stored at the time of manufacture.

Further, as in Patent Document 1, a plurality of abnormalities, for example, a first abnormality and a second abnormality that are different from each other, may be detected. In this case, the first software for detecting the first abnormality and the second software for detecting the second abnormality are different software. Even when multiple pieces of software are used in this way, if the software for detecting anomalies can be easily updated, false detections can easily occur even when a new type of load is connected to the distribution board. can be suppressed.

The present invention provides a circuit breaker and the like in which software for detecting an abnormality can be easily updated when multiple pieces of software are used.

A circuit breaker according to one aspect of the present invention includes a circuit breaker that detects a first abnormality regarding an electric circuit between an AC power source and a load based on a current value or voltage value of the electric circuit between an AC power source and a load by executing first software. a second detection unit that detects a second abnormality different from the first abnormality by executing second software different from the first software; and a second detection unit that updates the first software. a control unit that updates the first software based on first update information for updating the second software, and updates the second software based on second update information for updating the second software; The first update information acquisition route and the second update information acquisition route are different.

A distribution board according to one aspect of the present invention includes the circuit breaker described above and a distribution board cabinet that stores the circuit breaker.

When a plurality of pieces of software are used in the circuit breaker or the like of the present invention, the software for detecting an abnormality can be easily updated.

FIG. 1 is a block diagram showing the functional configuration of a circuit breaker according to an embodiment. FIG. 2 is a flowchart of operation example 1 according to the embodiment. FIG. 3 is a flowchart of operation example 2 according to the embodiment. FIG. 4 is a flowchart of operation example 3 according to the embodiment.

Hereinafter, embodiments will be specifically described with reference to the drawings. Note that the embodiments described below are all inclusive or specific examples. The numerical values, shapes, materials, components, arrangement positions and connection forms of the components, steps, order of steps, etc. shown in the following embodiments are merely examples, and do not limit the present invention. Further, among the constituent elements in the following embodiments, constituent elements that are not described in the independent claims will be described as arbitrary constituent elements.

Note that each figure is a schematic diagram and is not necessarily strictly illustrated. Further, in each figure, substantially the same configurations are denoted by the same reference numerals, and overlapping explanations may be omitted or simplified.

(Embodiment)
[composition]
First, the configuration of circuit breaker 100 according to the embodiment will be described.

FIG. 1 is a block diagram showing the functional configuration of a circuit breaker 100 according to this embodiment.

The circuit breaker 100 according to the present embodiment is a device for detecting an abnormality and interrupting an electric path, and is used, for example, in a distribution board 50 installed in a building B such as a detached house. The distribution board 50 is installed, for example, on the wall of the building B. In this embodiment, a plurality of types of abnormalities are detected, for example, two types of abnormalities (first abnormality and second abnormality) are detected. Further, the distribution board 50 communicates with a server device 200, which is an example of an external device. Note that the server device 200 is a device operated by an administrator who manages the circuit breaker 100.

The electricity distribution board 50 includes a main breaker 10 having a circuit breaker 100, a measurement unit 20, and a plurality of branch breakers 30 in the electricity distribution cabinet 5. In other words, the electricity distribution board 50 includes the master breaker 10, the measurement unit 20, a plurality of branch breakers 30, and the electricity distribution board cabinet 5.

The distribution board 50 distributes AC power from the power line 40 to the plurality of branch breakers 30 via the main breaker 10. For example, a single-phase three-wire power distribution system may be used.

Here, the main breaker 10 connects a power line 40 electrically connected to an external AC power source AC such as a commercial power source, and a power line 41 electrically connected to a measurement unit 20 in a distribution board 50. electrically connected between them. Furthermore, the measurement unit 20 is electrically connected between a power line 41 and a power line 42 that is electrically connected to a plurality of branch breakers 30 in the distribution board 50 .

Each of the plurality of branch breakers 30 is electrically connected between the power line 42 and the power line 43. Each of the plurality of branch breakers 30 is connected to a load 31 via a power line 43.

In the present embodiment, the electrical circuits cut off by the circuit breaker 100 are electrical circuits between the alternating current power supply AC and the plurality of loads 31, and are, for example, the power line 40, the power line 41, and the power line 42.

The main breaker 10 has the circuit breaker 100 as described above.

The circuit breaker 100 detects the first abnormality and the second abnormality by executing the first software and the second software, and interrupts the electric circuit when the first abnormality and the second abnormality are detected. It is a device. That is, multiple pieces of software are used in the circuit breaker 100. The circuit breaker 100 includes a first detection section 11 , a cutoff section 13 , a first control section 14 , a first storage section 15 , and a first communication section 17 .

The first detection unit 11 is a processing unit that detects a first abnormality regarding the electrical circuit based on the current value or voltage value of the electrical circuit between the AC power source AC and the plurality of loads 31 by executing the first software. It is. That is, the first software is software for detecting the first abnormality. Note that the current value or voltage value of the electric path is a value measured by the measurement unit 20. Further, in the present embodiment, the first detection unit 11 constantly detects the first abnormality when the main breaker 10 is supplied with power from the AC power supply AC. The first detection unit 11 is implemented, for example, by a microcomputer, but may also be implemented by a processor or a dedicated circuit. The functions of the first detection section 11 are realized by hardware such as a microcomputer or processor constituting the first detection section 11 executing software (computer program) stored in the first storage section 15.

The first detection unit 11 detects, as a first abnormality, an abnormality that needs to be constantly detected while power is being supplied to the distribution board 50 from the alternating current power supply AC. More specifically, the first detection unit 11 detects at least one of overcurrent, electric leakage, and neutral wire loss as the first abnormality. 1 Overcurrent is detected as an abnormality.

When the first abnormality is at least one of overcurrent and leakage, the first detection unit 11 detects the first abnormality regarding the electrical circuit based on the current value of the electrical circuit by executing the first software. do. Moreover, when the first abnormality is a neutral line defect, the first detection unit 11 detects the first abnormality regarding the electrical circuit based on the voltage value of the electrical circuit by executing the first software.

Note that the method of detecting overcurrent, electric leakage, and neutral wire loss as the first abnormality by the first detection unit 11 executing the first software is not limited to the above method.

Further, in this embodiment, the first software is updated based on first update information for updating the first software.

The second detection unit 12 is a processing unit that detects a second abnormality different from the first abnormality by executing second software. The second software is software different from the first software. Further, the second software is software for detecting a second abnormality. The second detection unit 12 is implemented, for example, by a microcomputer, but may also be implemented by a processor or a dedicated circuit. The functions of the second detection section 12 are realized by hardware such as a microcomputer or processor constituting the second detection section 12 executing software (computer program) stored in the first storage section 15.

Note that, unlike the first abnormality, the second abnormality does not need to be constantly detected while power is being supplied to the distribution board 50 from the AC power supply AC. In other words, the second abnormality may not be detected even while power is being supplied to the distribution board 50 from the alternating current power source AC. The second detection unit 12 detects at least one of an arc, lightning, and an earthquake as the second abnormality, but in this embodiment, the second detection unit 12 detects an arc as the second abnormality.

For example, the second detection unit 12 detects an arc as the second abnormality based on the current value of the electric path between the AC power source AC and the load 31 by executing the second software.

Further, in this embodiment, the second software is updated based on second update information for updating the second software.

Note that in this embodiment, the second detection unit 12 detects an arc as the second abnormality, but it may also detect lightning, an earthquake, or the like.

For example, when lightning is detected as the second abnormality, the second detection unit 12 detects the lightning as follows. For example, in this case, the circuit breaker 100 has a surge current measurement unit that measures surge current caused by lightning, and the second detection unit 12 detects the surge current measured by the surge current measurement unit by executing the second software. It is preferable to detect lightning as the second abnormality based on the following. Note that the means by which the second detection unit 12 detects lightning is not limited to the above.

For example, when an earthquake is detected as the second abnormality, the second detection unit 12 detects the earthquake as follows. For example, in this case, the circuit breaker 100 has a seismic sensor that measures acceleration due to an earthquake as a measured value, and the second detection unit 12 executes the second software to detect the measured value measured by the seismic sensor. Based on this, it is preferable to detect an earthquake as the second abnormality. Note that the means by which the second detection unit 12 detects an earthquake is not limited to the above.

The cutoff unit 13 cuts off the electrical circuit when the first detection unit 11 detects a first abnormality or the second detection unit 12 detects a second abnormality. More specifically, the cutoff unit 13 cuts off the electric path as follows. First, in this embodiment, a contact portion is provided between power line 40 and power line 41. The contact portion is configured to open in response to an open signal from the cutoff portion 13.

When the first abnormality or the second abnormality is detected, the cutoff section 13 generates an open signal to open the contact section according to the cutoff signal output from the first control section 14, and transmits the generated open signal to the contact section. Output to. In other words, the cutoff section 13 has a function of cutting off the electric path according to the detection results of the first detection section 11 and the second detection section 12.

The first control unit 14 updates the first software based on first update information for updating the first software, and updates the second software based on second update information for updating the second software. This is a processing unit that updates the software. Further, the first control unit 14 outputs a cutoff signal to the cutoff unit 13 when the first detection unit 11 detects a first abnormality or the second detection unit 12 detects a second abnormality. That is, when the first detection unit 11 detects a first abnormality, it outputs a detection result indicating that the first abnormality has been detected to the first control unit 14, and the first control unit 14 receives the output detection result. Accordingly, a cutoff signal is output to the cutoff section 13. Similarly, when the second detection unit 12 detects a second abnormality, it outputs a detection result indicating that the second abnormality has been detected to the first control unit 14, and the first control unit 14 outputs the output detection result. Accordingly, a cutoff signal is output to the cutoff section 13.

The first control unit 14 is realized, for example, by a microcomputer, but may also be realized by a processor or a dedicated circuit. The functions of the first control unit 14 are realized by hardware such as a microcomputer or processor constituting the first control unit 14 executing software (computer program) stored in the first storage unit 15.

The first storage unit 15 is a storage device in which information necessary for information processing for disconnecting an electric path, such as software executed by the disconnection unit 13 and the first control unit 14, is stored. The first storage unit 15 is realized by, for example, a semiconductor memory.

The adjustment unit 16 is a member for adjusting the sensitivity with which the first abnormality is detected by the first detection unit 11, and in this embodiment, is a switch.

The adjustment unit 16, which is a switch, is operated by a user, for example. The user is, for example, a resident of building B or a service person who repairs and inspects the circuit breaker 100. The sensitivity for detecting the first abnormality may be adjusted in multiple stages by operating the switch. In this embodiment, overcurrent is detected as the first abnormality. Therefore, in the adjustment unit 16, when the sensitivity is operated to be high, even a slight overcurrent is detected as the first abnormality, and when the sensitivity is operated to be low, a large overcurrent is detected as the first abnormality. Detected.

The first communication unit 17 is an example of a communication unit, and is a communication circuit for communicating with the measurement unit 20 and the server device 200. The first communication unit 17 acquires second update information for updating the second software. Here, the first communication unit 17 acquires the second update information from the server device 200. In the present embodiment, the first communication unit 17 is a circuit for performing wireless communication, and specifically, the first communication unit 17 is a circuit for performing wireless communication. Wireless communication is performed in accordance with communication standards such as (registered trademark). Note that the first communication unit 17 may be a circuit for performing wired communication. For example, the first communication unit 17 acquires the current value or voltage value measured by the measurement unit 20 from the measurement unit 20.

In addition, as shown in FIG. It is housed in a case 1 of 10. The housing 1 is an example of a housing section.

Here, the arrangement of the second detection section 12, first communication section 17, and cutoff section 13 will be explained. The second detection section 12, the first communication section 17, and the cutoff section 13 are installed on one circuit board within the housing 1. Note that it is preferable that the first detection section 11, the cutoff section 13, the first control section 14, the first storage section 15, and the first communication section 17 are installed on the one circuit board.

In this embodiment, the distance between the first communication section 17 and the second detection section 12 is shorter than the distance between the cutoff section 13 and the second detection section 12. More specifically, in a plan view of the one circuit board, the distance between the center of the first communication section 17 and the center of the second detection section 12 is equal to the distance between the center of the blocking section 13 and the center of the second detection section 12. shorter than the distance between.

Further, as described above, the first software and the second software according to this embodiment are updated. This update will be explained in more detail.

As described in "Problems to be Solved by the Invention," new types of electrical appliances have been created in recent years, and for example, in a house, which is an example of building B, this electrical appliance is connected to an alternating current power supply AC as a load. In the circuit breaker and distribution board disclosed in Patent Document 1, the software for detecting abnormalities is not updated, so the software stored at the time of manufacture continues to be used without being changed. . However, the software stored at the time of manufacture is software used to detect an abnormality when an existing load is connected to the circuit breaker and distribution board disclosed in Patent Document 1. Therefore, when an electrical appliance (that is, a new type of load) created after the circuit breaker and distribution board disclosed in Patent Document 1 is connected to an AC power source, the software is used. If detected, false positives may occur frequently.

Therefore, in the circuit breaker 100 and the distribution board 50 according to the present embodiment, the first software and the second software stored at the time of manufacture or the like are updated. Thereby, even if a new type of load is connected to the circuit breaker 100 and the distribution board 50, the occurrence of false detection is suppressed.

In this embodiment, as an example, a service person or an administrator creates first update information for updating the first software and second update information for updating the second software. After the service person or manager learns that an electrical appliance that can become a new type of load has been created, for example, after the electrical appliance has been sold, the service person or manager creates the first update information and the second update information. The first software and the second software are updated based on such first update information and second update information.

Next, the measurement unit 20 will be explained.

The measurement unit 20 measures the current value or voltage value flowing in the electric path between the alternating current power supply AC and the plurality of loads 31. The measurement unit 20 includes a measurement section 21 , an acquisition section 22 , a second control section 24 , a second storage section 25 , and a second communication section 27 .

The measuring unit 21 is a device that measures the current value or voltage value flowing in the electric path between the alternating current power supply AC and the plurality of loads 31. Here, the measurement unit 21 measures a current value, and is, for example, a current value sensor, more specifically a CT (Current Transformer) sensor.

The acquisition unit 22 is a processing unit that acquires the current value or voltage value of the electric path between the AC power source AC and the plurality of loads 31. In this embodiment, the acquisition unit 22 acquires the current value measured by the measurement unit 21. The acquisition unit 22 is implemented, for example, by a microcomputer, but may also be implemented by a processor or a dedicated circuit. The functions of the acquisition section 22 are realized by hardware such as a microcomputer or processor constituting the acquisition section 22 executing software (computer program) stored in the second storage section 25.

The second control unit 24 controls the second communication unit 27 to output the acquired current value or voltage value to the master breaker 10 when the acquisition unit 22 acquires the current value or voltage value. The second control unit 24 is realized, for example, by a microcomputer, but may also be realized by a processor or a dedicated circuit. The functions of the second control section 24 are realized by hardware such as a microcomputer or processor constituting the second control section 24 executing software (computer program) stored in the second storage section 25.

The second storage unit 25 is a storage device that stores information necessary for information processing for cutting off an electric path, such as software executed by the acquisition unit 22 and the second control unit 24. The second storage unit 25 is realized by, for example, a semiconductor memory.

The second communication section 27 is a communication circuit for the measurement unit 20 to communicate with the main breaker 10 and the server device 200. In the present embodiment, the second communication unit 27 is a circuit for performing wireless communication, and specifically, the second communication unit 27 complies with communication standards such as BLE or Wi-Fi (registered trademark). Therefore, wireless communication is performed. Note that the second communication unit 27 may be a circuit for performing wired communication.

Furthermore, as shown in FIG. It is accommodated. The housing 2 is an example of a housing section. Note that the present invention is not limited to this, and the housing 2 houses the acquisition section 22 , the second control section 24 , the second storage section 25 , and the second communication section 27 , and the measurement section 21 houses the acquisition section 22 , the second control section 24 , the second storage section 25 , and the second communication section 27 . It may be placed outside or inside the distribution board cabinet 5.

Note that in this embodiment, the housing 1 and the housing 2 are separate bodies and are separate housings.

Furthermore, the server device 200 will be explained.

Server device 200 is an example of an external device. Server device 200 is a cloud server in this embodiment. Further, for example, instead of the server device 200, a high-performance processor dedicated to the circuit breaker 100 or the like may be used as an external device. External devices such as the server device 200 are installed outside the building B, and more specifically, are installed at a remote location from the building B. Note that the external device may be installed inside the building B.

Server device 200 is a device used by an administrator who manages circuit breaker 100.

The server device 200 includes a third communication unit 201. The third communication unit 201 is a communication circuit for the server device 200 to communicate with the main breaker 10 and the measurement unit 20. In this embodiment, the third communication unit 201 is a circuit for performing wireless communication, and specifically, the third communication unit 201 complies with communication standards such as BLE or Wi-Fi (registered trademark). Therefore, wireless communication is performed. The third communication unit 201 outputs second update information for updating the second software to the master breaker 10. Note that the third communication unit 201 may be a circuit for performing wired communication.

Further, the first update information for updating the first software is not output from the server device 200 to the distribution board 50 (that is, the master breaker 10 and the measurement unit 20).

The second update information is information created by an administrator who manages the circuit breaker 100 or the like. As described above, the administrator creates the second update information when an electrical appliance that can become a new type of load is created and sold. By updating the second software using the second update information, the second software becomes compatible with a new type of load. Even if the second detection unit 12 executes this updated second software, the second abnormality will not be falsely detected.

Next, the operation of circuit breaker 100 in this embodiment configured as above will be explained.

First, operation example 1 in which a first abnormality and a second abnormality are detected will be described.

[Operation example 1]
FIG. 2 is a flowchart of operation example 1 according to the present embodiment. The operation in FIG. 2 is performed, for example, after the electricity distribution board 50 (circuit breaker 100) is installed in the building B and the plurality of loads 31 are connected to the electricity distribution board 50 in the building B.

First, the measurement unit 21 measures the value of current flowing in the electrical path between the AC power supply AC and the plurality of loads 31 (S10).

The acquisition unit 22 acquires the current value measured by the measurement unit 21 (S12). The second communication unit 27 outputs the current value acquired by the acquisition unit 22 to the first communication unit 17. In addition, more specifically, the acquisition unit 22 outputs to the first communication unit 17 current value information that links the measured current value and the time at which the current value was measured. The first communication unit 17 acquires the current value information output by the second communication unit 27.

Further, in the present embodiment, in step S10, the measurement unit 21 constantly measures the current value flowing through the electric path, and in step S12, the acquisition unit 22 acquires the constantly measured current value, and furthermore, the second communication unit 27 outputs the current value to the first communication section 17. That is, in the measurement unit 20, the measurement section 21 constantly measures (monitors) the value of the current flowing through the electric circuit, all the current values are acquired by the acquisition section 22, and outputted to the master breaker 10 by the second communication section 27. Ru.

Next, the first detection unit 11 executes the first software stored in the first storage unit 15 to detect the current value in the electric circuit based on the current value information (current value) acquired by the second communication unit 27. A first abnormality is detected for (S14). For example, in the first detection unit 11 that has executed the first software, when the acquired current value is larger or smaller than the first threshold value, a first abnormality in the electric circuit is detected, that is, the first detection It is preferable that the unit 11 detects that the first abnormality exists, but the present invention is not limited to this.

When the first detection unit 11 does not detect the first abnormality, that is, when there is no first abnormality (No in S14), the second detection unit 12 detects the second abnormality by executing the second software. An abnormality is detected (S16). More specifically, the second detection unit 12 detects a second abnormality regarding the electrical circuit based on the current value information (current value) acquired by the second communication unit 27 by executing the second software. Detect arc. For example, in the second detection unit 12 running the second software, if the acquired current value is larger or smaller than the second threshold value, the second abnormality is detected, that is, the second detection unit 12 detects the second abnormality. It is preferable to detect that there is a second abnormality, but the present invention is not limited to this.

If the first detection unit 11 detects the first abnormality, that is, the first abnormality exists (Yes in S14), or if the second detection unit 12 detects the second abnormality, that is, the second abnormality exists. (Yes in S16), the cutoff unit 13 cuts off the electric circuit (S18).

When the first abnormality or the second abnormality is detected, the first control section 14 outputs a cutoff signal to the cutoff section 13. Furthermore, the cutoff section 13 generates an open signal to open the contact section in response to the cutoff signal outputted by the first control section 14, and outputs the generated open signal to the contact section. The contact section opens in response to an open signal from the interrupting section 13, thereby interrupting the electrical circuit.

Further, if the second detection unit 12 does not detect the second abnormality, that is, if there is no second abnormality (No in S16), the operation ends.

Note that in this operational example, step S16 is performed after step S14, but the order may be reversed. Moreover, step S14 and step S16 may be performed simultaneously. Even in these cases, if there is a first abnormality or a second abnormality, the cutoff section 13 cuts off the electrical circuit.

Next, an operation example 2 in which the first software executed by the first detection unit 11 is updated and an operation example 3 in which the second software executed by the second detection unit 12 is updated will be described.

[Operation example 2 and operation example 3]
FIG. 3 is a flowchart of operation example 2 according to the present embodiment. More specifically, FIG. 3 shows an example in which the first software is updated.

FIG. 4 is a flowchart of operation example 3 according to the present embodiment. More specifically, FIG. 4 shows an example in which the second software is updated.

The operations shown in FIGS. 3 and 4 are performed, for example, after a service person or administrator learns that an electrical appliance that can become a new type of load has been created and creates the first update information and second update information. be exposed. As described above, when a new type of load is connected, the first software and the second software need to be updated in order to suppress the occurrence of false detection. Note that the operations shown in FIGS. 3 and 4 are performed after the new type of load explained in "Problems to be Solved by the Invention" is connected to the distribution board 50 as one load 31 among the plurality of loads 31. It would be good if it were done.

First, an example in which the first software is updated will be described.

Before explaining using FIG. 3, the preconditions for updating the first software will be explained. If the first software is updated while the first detection unit 11 detects the first abnormality, there is a possibility that false detection will occur during the update. Further, the first detection unit 11 constantly detects the first abnormality while the distribution board 50 is being supplied with power from the alternating current power supply AC. Therefore, the first software needs to be updated while power is not being supplied to the distribution board 50 from the alternating current power supply AC. Here, an example will be shown in which the first software is updated while power is not being supplied to the distribution board 50 from the AC power source AC by removing the distribution board 50 from the wall of the building B by a service person.

More specifically, an example in which the first software is updated will be described using operation example 2 shown in FIG. 3.

To update the first software, a service person works in building B. First, the service person removes the distribution board 50 from the wall of the building B (S40). In other words, the electrical connection between the distribution board 50 and the AC power source AC and the electrical connection between the distribution board 50 and the plurality of loads 31 are cut off.

Furthermore, the dedicated device carried by the service person outputs first update information for updating the first software (S42). The dedicated device is a device that stores the first update information, and outputs the stored first update information to the distribution board 50 (more specifically, the circuit breaker 100). For example, the dedicated device is a tablet terminal, a personal computer, a mobile phone terminal, a dedicated control device, or the like, and is carried to building B by a service person. As an example, the dedicated device outputs the first update information stored in the dedicated device to the distribution board 50 via an information interface that the distribution board 50 has. The information interface is, for example, a USB (Universal Serial Bus) port. As a result, in the distribution board 50, the first update information is stored in the first storage unit 15. Note that at this time, it is preferable that power is supplied to the distribution board 50 from a dedicated device. In this way, the distribution board 50 (circuit breaker 100) acquires the first update information from, for example, a dedicated device. That is, the first update information acquisition path is a path from the dedicated device to the circuit breaker 100.

Next, in the main breaker 10, the first control unit 14 updates the first software executed by the first detection unit 11 based on the first update information stored in the first storage unit 15 (S44 ). By being updated, the first software becomes first software that is compatible with a new type of load. By executing the updated first software, the first detection unit 11 does not erroneously detect the first abnormality based on the acquired current value or voltage value.

Examples of the first software update include the following. As described above, the first abnormality is detected when the acquired current value is larger or smaller than the first threshold, but the first threshold is changed by updating the first software. Therefore, the occurrence of false detection of the first abnormality is suppressed.

Thereafter, the distribution board 50 is attached to the wall of the building B by a service person. That is, the electricity distribution board 50 and the alternating current power supply AC are electrically connected, and the electricity distribution board 50 and the plurality of loads 31 are electrically connected.

Note that the first abnormality detected by the first detection unit 11 is an abnormality that is constantly detected while the main breaker 10 is being supplied with power from the alternating current power supply AC. Therefore, the first detection unit 11 does not detect the first abnormality after the distribution board 50 is removed from the wall of the building B in step S40 until it is reattached.

Furthermore, in this operation example, while the first detection unit 11 detects the first abnormality, the first software is not updated, so false detection may occur while the first software is being updated. suppressed.

Furthermore, operation example 3 shown in FIG. 4 will be explained.

The server device 200 outputs the second update information created by the service person or administrator to the first communication unit 17 (S50). The first communication unit 17 acquires the output second update information. In this way, the distribution board 50 (circuit breaker 100) acquires the second update information from the server device 200 via the first communication unit 17 and the like. That is, the second update information acquisition path is a path from the server device 200 to the circuit breaker 100.

In the main breaker 10, the first control unit 14 updates the second software executed by the second detection unit 12 based on the second update information acquired by the first communication unit 17 (S52). When the second software is updated, it becomes second software compatible with a new type of load. The second detection unit 12 does not falsely detect the second abnormality by executing the updated second software.

Examples of the second software update include the following. As described above, the second abnormality is detected when the acquired current value is larger or smaller than the second threshold, but this second threshold is changed by updating the second software. Therefore, the occurrence of false detection of the second abnormality is suppressed.

Furthermore, in the present embodiment, when the second software is updated using the acquired second update information, the second detection unit 12 suspends detection of the second abnormality. That is, during the period when the second software is updated by the first control section 14, the second detection section 12 does not detect the second abnormality. Similar to the first detection unit 11, if the second software is updated while the second detection unit 12 detects the second abnormality, there is a possibility that false detection will occur during the update. When the second software is updated, the second detection unit 12 suspends detection of the second abnormality, so that such false detection does not occur.

As shown in operation example 2 and operation example 3 in FIGS. 3 and 4, in this embodiment, the first update information acquisition route and the second update information acquisition route are different.

The circuit breaker 100 obtains the first update information from, for example, a dedicated device. That is, the first update information acquisition path is a path from the dedicated device to the circuit breaker 100. Note that, as described above, the dedicated device is a device that stores the first update information and outputs the first update information to the circuit breaker 100. For example, the dedicated device is a device that stores the first update information and outputs the first update information to the circuit breaker 100. This is a device carried by a person and carried to building B.

On the other hand, the circuit breaker 100 acquires the second update information from the server device 200. That is, the second update information acquisition path is a path from the server device 200 to the circuit breaker 100.

Therefore, in this embodiment, the first update information acquisition route and the second update information acquisition route are different.

That is, if the second software for detecting the second abnormality is updated, the service person does not need to work in building B. In the main breaker 10, the second software is updated based on the second update information output from the server device 200 located remotely from the building B. Therefore, for example, a service person works in the building B. The second software is easily updated compared to the case where the second software is updated.

Note that, in practice, the first software is rarely updated, while the second software is often updated frequently. The frequency with which the first software is updated is overwhelmingly lower than the frequency with which the second software is updated, for example, one-tenth or less. In other words, the circuit breaker 100 can be realized by easily updating the frequently updated second software, which saves the effort of updating.

[Effects etc.]
Circuit breaker 100 according to this embodiment includes a first detection section 11, a second detection section 12, and a control section. The first detection unit 11 detects a first abnormality regarding the electrical circuit based on the current value or voltage value of the electrical circuit between the AC power source AC and the load 31 by executing the first software. The second detection unit 12 detects a second abnormality different from the first abnormality by executing second software different from the first software. The control unit (first control unit 14) updates the first software based on first update information for updating the first software, and updates the second software based on second update information. and update the second software. The first update information acquisition route and the second update information acquisition route are different.

As mentioned above, an electrical appliance (that is, a new type of load) that was created after the circuit breaker and distribution board disclosed in Patent Document 1 were manufactured was connected to the circuit breaker and the distribution board. In this case, the following problems are expected. In such a case, if software stored at the time of manufacturing the circuit breaker and distribution board disclosed in Patent Document 1 is used, a problem may arise in which false detections occur frequently. On the other hand, in the present embodiment, the first software and the second software stored at the time of manufacture are updated, and as a result, a new type of load is connected to the circuit breaker 100 and the distribution board 50. Even in the case of false detection, the occurrence of false detection is suppressed.

Furthermore, in this embodiment, the first update information acquisition route and the second update information acquisition route are different. More specifically, the circuit breaker 100 obtains the first update information from a dedicated device carried by a serviceman working in building B, for example. That is, the first update information acquisition path is a path from the dedicated device to the circuit breaker 100. On the other hand, the circuit breaker 100 acquires the second update information from the server device 200. That is, the second update information acquisition path is a path from the server device 200 to the circuit breaker 100.

In this way, if the second software for detecting the second abnormality is updated, the service person does not need to work in building B. In the main breaker 10, the second software is updated based on the second update information output from the server device 200 located remotely from the building B. Therefore, for example, a service person works in the building B. Compared to the case, the second software is updated easily.

In summary, when a plurality of pieces of software are used in the circuit breaker 100, the software for detecting an abnormality can be easily updated. More specifically, when the first software and the second software are used, the circuit breaker 100 can easily update at least the second software.

Furthermore, in the circuit breaker 100, if the second software can be easily updated, even if a new type of load is connected to the distribution board, the occurrence of false detection regarding the second abnormality can be easily suppressed. can be done.

For example, the circuit breaker 100 according to the present embodiment includes a communication unit (first communication unit 17) that acquires the second update information. When the second software is updated using the acquired second update information, the second detection unit 12 stops detecting the second abnormality.

Since the circuit breaker 100 according to the present embodiment includes the first communication unit 17, when the second software for detecting the second abnormality is updated, the service person works in the building B. There's no need. For example, compared to when a service person works in building B, the second software can be updated more easily.

Therefore, when a plurality of pieces of software are used in the circuit breaker 100, the software for detecting an abnormality can be easily updated. More specifically, when the first software and the second software are used, the circuit breaker 100 can easily update at least the second software.

Moreover, if the second software is updated while the second detection unit 12 detects the second abnormality, there is a possibility that false detection will occur during the update. However, in this embodiment, when the second software is updated, the second detection unit 12 suspends detection of the second abnormality, so such false detection does not occur.

For example, the communication unit (first communication unit 17) obtains the second update information from the cloud server (server device 200).

Thereby, the first communication unit 17 can acquire the second update information from the cloud server (server device 200).

Further, for example, the circuit breaker 100 according to the present embodiment includes a cutoff section 13 that cuts off the electrical path when the first abnormality is detected or when the second abnormality is detected. The distance between the communication section (first communication section 17 ) and the second detection section 12 is shorter than the distance between the cutoff section 13 and the second detection section 12 .

As a result, the cutoff section 13 is placed at a position farther from the second detection section 12 than the first communication section 17 . Therefore, the blocking section 13 is less susceptible to the influence of digital noise output from the second detecting section 12.

For example, the circuit breaker 100 according to the present embodiment includes an adjustment section 16 for adjusting the sensitivity with which the first detection section 11 detects the first abnormality.

Thereby, for example, the sensitivity at which the first abnormality is detected is adjusted by operating the adjustment unit 16 by the user.

For example, the first detection unit 11 detects at least one of overcurrent, electric leakage, and neutral wire loss as the first abnormality. The second detection unit 12 detects at least one of arc, lightning, and earthquake as the second abnormality.

Thereby, the circuit breaker 100 can detect at least one of overcurrent, electric leakage, and neutral wire loss as the first abnormality, and can detect at least one of arc, lightning, and earthquake as the second abnormality.

For example, the electricity distribution board 50 includes the above-described circuit breaker 100 and a electricity distribution board cabinet 5 that stores the circuit breaker 100.

As described above, when a plurality of pieces of software are used in the circuit breaker 100, the software for detecting an abnormality can be easily updated. Therefore, when a plurality of pieces of software are used in the distribution board 50 including the circuit breaker 100, the software for detecting an abnormality can be easily updated.

(Other embodiments)
Although the embodiments have been described above, the present invention is not limited to the above embodiments.

Further, the communication method between devices described in the above embodiment is an example. There are no particular limitations on the method of communication between devices.

Further, in the above embodiments, the processing executed by a specific processing unit may be executed by another processing unit. Further, the order of the plurality of processes may be changed, or the plurality of processes may be executed in parallel.

Further, in the embodiments described above, components such as the control unit may be realized by executing a software program suitable for each component. Each component may be realized by a program execution unit such as a CPU or a processor reading and executing a software program recorded on a recording medium such as a hard disk or a semiconductor memory.

Further, components such as the control unit may be realized by hardware. For example, components such as the control unit may be circuits (or integrated circuits). These circuits may constitute one circuit as a whole, or may be separate circuits. Further, each of these circuits may be a general-purpose circuit or a dedicated circuit.

Further, general or specific aspects of the present invention may be implemented in a system, apparatus, method, integrated circuit, computer program, or computer-readable recording medium such as a CD-ROM. Further, the present invention may be realized by any combination of a system, an apparatus, a method, an integrated circuit, a computer program, and a recording medium. For example, the present invention may be realized as the power distribution board or server device of the above embodiment, or may be realized as an information processing method executed by the power distribution board. The present invention may be realized as a program for causing a computer to execute such an information processing method, or may be realized as a non-temporary recording medium on which such a program is recorded. Such programs include application programs for causing a computer such as a general-purpose information terminal to function as the server device of the above embodiment.

Other embodiments may be obtained by making various modifications to each embodiment that those skilled in the art can think of, or by arbitrarily combining the components and functions of each embodiment without departing from the spirit of the present invention. The present invention also includes such forms.

5 Distribution board cabinet 11 First detection section 12 Second detection section 13 Cutoff section 50 Distribution board 100 Circuit breaker AC AC power supply

Claims (7)

a first detection unit that detects a first abnormality regarding the electrical circuit based on the current value or voltage value of the electrical circuit between the AC power source and the load by executing first software;
a second detection unit that detects a second abnormality different from the first abnormality by executing second software different from the first software;
The first software is updated based on first update information for updating the first software, and the second software is updated based on second update information for updating the second software. a control unit to
The acquisition route of the first update information and the acquisition route of the second update information are different from each other.Circuit breaker. comprising a communication unit that acquires the second update information,
The circuit breaker according to claim 1, wherein the second detection unit suspends detecting the second abnormality when the second software is updated by the acquired second update information. The circuit breaker according to claim 2, wherein the communication unit acquires the second update information from a cloud server. comprising a cutoff unit that cuts off the electric circuit when the first abnormality is detected or when the second abnormality is detected,
The circuit breaker according to claim 2 or 3, wherein a distance between the communication section and the second detection section is shorter than a distance between the cutoff section and the second detection section. The circuit breaker according to claim 1, further comprising an adjustment section for adjusting the sensitivity with which the first abnormality is detected by the first detection section. The first detection unit detects at least one of overcurrent, electric leakage, and neutral wire loss as the first abnormality,
The circuit breaker according to claim 1, wherein the second detection unit detects at least one of arc, lightning, and earthquake as the second abnormality. The circuit breaker according to any one of claims 1 to 6,
A power distribution board, comprising: a power distribution board cabinet that stores the circuit breaker.

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