JP2020080618A - Discharge accident detection system - Google Patents

Abstract

To provide a system capable of determining whether or not an abnormality is a discharge accident when an abnormality is found by comparison of wavelength data.SOLUTION: A discharge accident detection system 1 for detecting a discharge accident that occurs on a wiring channel, comprises: a current detection unit 11 that measures current waveform data on a wiring to which an electric device 7 is connected; a storage unit 12 that stores the measured current waveform data of the electric device; a computation unit 17 that compares the current waveform data measured by the current detection unit with the current waveform data of the storage unit; a filter unit 16 having a filter body 14 which can cut a part of noise output and a noise detection unit 15 that detects noise output in a target frequency band which is a frequency serving as a target for detecting noise generated by a discharge accident which has passed through the filer body; and a discharge accident determination unit that determines that a discharge accident has occurred when the noise detection unit detects an output of a threshold value or more.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a discharge accident detection system.

  As described in Patent Document 1, a system is known in which waveform data of each electric device is stored and an abnormality is detected based on a difference between the measured waveform data and the stored waveform data.

International Publication No. 2015/063943

  By the way, there are various abnormalities, and one of them is a discharge accident. It is necessary to detect the occurrence of a discharge accident because it may cause a serious accident indoors. However, as in the technique described in Patent Document 1, it is not possible to grasp whether or not the influence of the discharge accident is caused only by comparing the waveform data with each other and determining the abnormality.

  The inventor of the present case has tried to solve the problem by diligently examining this point. An object of the present invention is to provide a system capable of determining whether or not the abnormality is a discharge accident when the abnormality is found by comparing the waveform data with each other.

  In order to solve the above problems, a discharge accident detection system for detecting a discharge accident that occurs on a wiring path, a current detection unit for measuring current waveform data on the wiring to which the electric device is connected, and the measured electric device A storage unit that stores current waveform data, a calculation unit that compares the current waveform data measured by the current detection unit with the current waveform data in the storage unit, a filter body that can cut a part of noise output, and a filter body A noise detection unit that detects a noise output in a target frequency band that is a target frequency in order to detect noise generated by a discharge accident that has passed through When a discharge accident determination unit that determines that a discharge accident has occurred when is detected, and the current waveform data measured by the current detection unit is different from the current waveform data in the storage unit based on the calculation result of the calculation unit. In addition, a discharge accident detection system that confirms the noise output in the target frequency band that has passed through the filter body.

  Further, it is preferable that the discharge accident determination unit is configured to determine that a discharge accident has occurred when the noise output measured by the noise detection unit exceeds the first threshold for a predetermined time.

  Further, an opening control unit that can be controlled to open a switch connected to the electric device is provided, and when a discharge accident is detected, the opening control unit controls to open the switch connected to the electric device. It is preferable to adopt a configuration.

  Further, the discharge accident detection system detects a discharge accident that occurs on a wiring path, and stores a voltage detection unit that measures voltage waveform data on a wiring to which an electric device is connected and a voltage waveform data of the measured electric device. The storage unit, the calculation unit that compares the voltage waveform data measured by the current detection unit with the voltage waveform data in the storage unit, the filter body that can cut a part of the noise output, and the discharge accident that has passed through the filter body. A noise detection unit that detects the noise output in the target frequency band that is the target frequency to detect the noise generated by the filter unit, and discharge when the noise detection unit detects an output above the threshold value. A discharge accident determination unit that determines that an accident has occurred, and when the voltage waveform data measured by the voltage detection unit is different from the voltage waveform data in the storage unit based on the calculation result of the calculation unit, the filter main body is The discharge accident detection system is used to confirm the noise output in the passed target frequency band.

  According to the present invention, it is possible to provide a system capable of determining whether or not the abnormality is a discharge accident when the abnormality is found by comparing the waveform data.

It is the figure which showed the example which applied the electric discharge accident detection system to the distribution board. It is the figure which showed the electric current waveform for every electric equipment. It is the figure which showed the example which the current waveform memorize|stored in the memory|storage part and the measured current waveform have the same tendency. It is the figure which showed the example which the current waveform memorize|stored in the memory|storage part and the measured current waveform tend to differ. A circle is attached near the point where a different peak appears. It is the figure which showed comparing some current waveforms memorize|stored in the memory|storage part, and some current waveforms measured. It is the figure which showed the example of the frequency characteristic of the filter circuit which comprises a filter main body. It is the figure which showed the structural example of the noise detection part connected to a filter main body. It is a figure showing the relation between the target frequency band noise level and the 1st threshold. However, the horizontal axis is time. It is a figure which shows the example which provided the signal wire between the output part and the switch. It is a figure which shows the example using the unit provided with the electric current detection part and the filter part. It is the figure which showed the application example of the filter part in the case of sending an electric current from a DC power supply to a load, without passing through a distribution board. It is the figure which showed the example which applied the other discharge accident detection system to the distribution board.

  Modes for carrying out the invention are shown below. The discharge accident detection system 1 of this embodiment detects a discharge accident that occurs on a wiring path. The discharge accident detection system 1 includes a current detection unit 11 that measures current waveform data on a wiring to which the electric device 7 is connected, a storage unit 12 that stores the measured current waveform data of the electric device 7, and a current detection unit. The calculation unit 17 is provided for comparing the current waveform data measured by the reference numeral 11 and the current waveform data in the storage unit 12. The filter unit 16 includes a filter body 14 that can cut a part of the noise output, and a noise detection unit 15 that detects the noise output in the target frequency band that has passed through the filter body 14. Further, a discharge accident determination unit 52 that determines that a discharge accident has occurred when the noise detection unit 15 detects an output equal to or higher than a threshold value is provided. Further, based on the calculation result of the calculation unit 17, when the current waveform data measured by the current detection unit 11 is different from the current waveform data of the storage unit 12, the noise output in the target frequency band passing through the filter body 14 is output. Is to confirm. Therefore, when the abnormality is found by comparing the waveform data with each other, it is possible to provide a system capable of determining whether or not the abnormality is a discharge accident. The discharge accidents that occur on the wiring path include tracking of the plug 65 and the outlet 64, discharge due to poor contact of the plug 65, disconnection of the wiring path, spark discharge or arc discharge caused by a ground fault, and the like.

  In addition, the target frequency in the present embodiment refers to a target frequency for detecting noise generated by a discharge accident. By the way, noise generated by a discharge accident can be detected even in the frequency band of conduction noise. However, noise in such a frequency band includes noise generated during the operation of home appliances and the like. Therefore, it is preferable that the target frequency band is the frequency band of radiated noise that does not include noise from home appliances. In this case, noise generated by a discharge accident on the wiring path must be transmitted through the wiring path. It can be taken out by a filter circuit provided as the filter body 14.

  The discharge accident detection system 1 according to the embodiment detects a current flowing through a wiring that connects the electric device 7 that is a load included in the distribution board 8 and the branch breaker 82. In the example shown in FIG. 1, the filter unit 16 and the like that form a part of the discharge accident detection system 1 are arranged inside the distribution board 8, and the database or the like that serves as the storage unit 12 corresponds to the distribution board 8. It is provided on the server 30 provided outside. In the embodiment, a plurality of branch breakers 82 are connected to the secondary side of the main breaker 81 arranged inside the distribution board 8.

  In the example shown in FIG. 1, the current detection unit 11 is provided on the secondary side of the branch breaker 82, and information about the current waveform detected by the current detection unit 11 is sent from the communication unit 21 to the server 30. The storage unit 12 provided in the server 30 stores information on current waveforms in a normal state. That is, the information about the electric device 7 measured in the past is stored. The current detection unit 11 detects current waveform data, and the current waveform data is time-series data of current values measured by the current detection unit 11 within a predetermined period. The magnitude of the amplitude represents the magnitude of current consumption.

  As can be understood from FIG. 2, the current waveform in the normal state is determined to some extent for each load, and therefore the stored information and the newly detected information should be compared for a specific load. Thus, it is possible to determine whether or not the state is normal. Although only one current waveform is shown for each load in FIG. 2, various variations of current waveforms that actually occur in each load are stored in each load. The current waveform detected by the current detector 11 is compared with these current waveforms by the calculator 17. In addition, at least one cycle of waveform data is stored in the storage unit 12.

  If the measured current waveform is similar to the current waveform stored in the storage unit 12 as in the example shown in FIG. 3, the state is normal. On the other hand, if the measured current waveform tends to be different from the current waveform stored in the storage unit 12 as in the example shown in FIG. 4, the state is abnormal.

  In FIG. 3 and FIG. 4, the entire measured current waveform is compared with the current waveform stored in the storage unit 12. However, as can be understood from FIG. 5, it is extracted from the measured current waveform. A part may be compared with a part of the stored current waveform to determine whether or not an abnormality has occurred. In the example shown in FIG. 5, waveform data for multiple cycles is stored, and data for one cycle is extracted and compared at the time of comparison.

  When it is determined that an abnormality has occurred in the current by comparing the measured current waveform and the current waveform stored in the storage unit 12 in the calculation unit 17, noise is generated in the wiring in which the current waveform is recognized. Check the output. In the embodiment, frequency analysis is performed at the time of this confirmation. In addition, in the embodiment, when it is determined that the current is abnormal as a result of the comparison in the calculation unit 17, the noise output is detected based on the determination result.

  In the example shown in FIG. 1, a filter body 14 capable of cutting a part of noise is provided on the secondary side of the current detection unit 11. The noise detection section 15 detects the noise output in the target frequency band that has passed through the filter body 14. In this way, the filter body 14 cuts noise output in the vicinity of the target frequency band, and thus it is possible to prevent the noise detection unit 15 from detecting noise output that is not related to a discharge accident. That is, it is possible to improve the accuracy of determining whether or not a discharge accident has occurred.

  The filter body 14 of the embodiment has a frequency characteristic as shown in FIG. 6, and is a so-called high pass filter. The filter body 14 of the embodiment can cut the frequency components in the low frequency band, while allowing the frequency components in the high frequency band, which is the frequency band of the radiation noise, to pass.

  Output noise that has passed through the filter body 14 is detected by the noise detection unit 15. As shown in FIG. 7, the noise detection unit 15 of the embodiment includes an amplification unit 51 and a discharge accident determination unit 52. The amplification unit 51 functions to amplify the small noise output that has passed through the filter body 14 to such an extent that the discharge accident determination unit 52 can make a determination. The discharge accident determination unit 52 is set with a first threshold value used for determining the presence or absence of a discharge accident. When the noise level of the noise extracted by the filter body 14 and amplified by the amplification unit 51 exceeds the first threshold value, it may be determined that a discharge accident has occurred.

  In addition, the noise detection unit 15 of the embodiment includes the output unit 53, and can output the determination result and the like to the outside. In the example shown in FIG. 1, the output unit 53 is used to wirelessly output information to the server 30. When the discharge accident determination unit 52 determines that a discharge accident has occurred, the output unit 53 of the embodiment is used to display that fact. For example, by operating the output unit 53, the display lamp may be turned on, or characters or voice may be output.

  By the way, in the embodiment, in order for the discharge accident determination unit 52 to determine that a discharge accident has occurred, the condition is that the noise output measured by the noise detection unit 15 exceeds the first threshold value. However, the first threshold value may be exceeded for a moment due to a switch operation of a home electric appliance such as a dryer. Therefore, when the time that exceeds the first threshold value exceeds a predetermined time, a discharge accident occurs. It is preferable to make a judgment. For example, when the first threshold value and the predetermined time are set as shown in FIG. 8, it is not determined that a discharge accident has occurred in the state shown in FIG.

  If it can be determined that a discharge accident has occurred, this information may be provided to the outside via the output unit 53, but a switch such as a branch breaker 82 on the wiring that is determined to have a discharge accident has occurred. It is preferable to control so as to open. In this way, when a discharge accident occurs, the switch can be automatically opened based on the determination result, so it is possible to prevent current from flowing on this wiring at an early stage. it can.

  In order to enable such a thing, in the embodiment, the opening control unit 54 that can be controlled to open the switch connected to the electric device 7 is provided. Further, when a discharge accident is detected, the opening control unit 54 controls to open the switch connected to the electric device 7. Note that, in the example shown in FIG. 9, the part that also serves as the output part 53 and the opening control part 54 and the switch are connected by the signal line 41.

  As shown in FIG. 10, the monitoring unit interposed between the switch and the load includes a current detection unit 11, a filter body 14, an amplification unit 51, a discharge accident determination unit 52, an output unit 53, and an opening control unit 54. It is also possible to adopt a configuration including the above. This monitoring unit is configured to include a connection terminal 43 connected to the secondary side of the switch and a connection terminal 44 connected to the primary side of the load.

  Further, the filter body 14 and the like need not be attached to the distribution board 8. For example, as shown in FIG. 11, the filter main body 14 and the like may be interposed between the DC power source 61 such as a solar power generator and a storage battery and the load. In the example shown in FIG. 11, the filter body 14 is arranged on the secondary side of the converter 62 provided on the secondary side of the DC power supply 61, and the outlet 64 is provided on the secondary side of the filter body 14. ing. The user can cause the DC power supply 61 to supply power to the load by inserting a plug 65 provided in the load into the outlet 64.

  Further, in the above embodiment, the current waveform data measured by the current detection unit 11 for measuring the current waveform data is compared with the current waveform data in the storage unit 12, but the voltage waveform data is the comparison target. It is also possible. In that case, for example, as shown in FIG. 12, on the secondary side of the main breaker 81, the filter main body 14 and the noise detection unit 15 for detecting noise are provided on the secondary side, and the voltage detection for seeing the voltage It is conceivable that the configuration includes the unit 71. When a discharge accident is detected by using such a configuration, the measured voltage waveform data of the electric device is stored in the storage unit 12 as in the case of comparing the current waveforms, and the voltage detection unit is stored. The voltage waveform data measured by 71 and the current waveform data of the storage unit 12 are compared by the calculation unit 17, and the voltage waveform data measured by the voltage detection unit 71 is stored in the storage unit 12 based on the calculation result of the calculation unit 17. When it is determined that the tendency is different from the voltage waveform data, the noise output in the target frequency band passing through the filter body 14 may be confirmed.

  Although the present invention has been described above by taking the embodiment as an example, the present invention is not limited to the above-described embodiment, and various modes are possible. For example, all of the discharge accident detection system may be arranged inside the distribution board, or all may be arranged outside the distribution board.

  In addition, the exchange of information between the communication unit or the noise detection unit and the server is not limited to be performed wirelessly, and may be performed by wire.

  It may be a unit in which a storage unit, a determination unit, and the like are combined with a filter unit and the like. Further, such a unit may be arranged inside or outside the distribution board.

  The method of confirming the noise output can also take various forms. For example, when it is determined that the current is abnormal as a result of the comparison in the calculation unit, the noise output continuously detected in advance may be collated with the first threshold value or the like.

  The calculation unit may play the role of the discharge accident determination unit.

1 Discharge accident detection system 7 Electric equipment (load)
Reference Signs List 11 current detection unit 12 storage unit 14 filter body 15 noise detection unit 16 filter unit 17 arithmetic unit 54 open control unit 71 voltage detection unit

Claims (4)

A discharge accident detection system for detecting a discharge accident that occurs on a wiring path,
A current detection unit that measures current waveform data on wiring to which electrical equipment is connected,
A storage unit that stores the measured current waveform data of the electric device,
A current waveform data measured by the current detection unit, a calculation unit for comparing the current waveform data of the storage unit,
A filter body that can cut a part of the noise output, a noise detection unit that detects the noise output in the target frequency band that is the target frequency to detect the noise generated by the discharge accident that has passed through the filter body, And a filter section having
A discharge accident determination unit that determines that a discharge accident has occurred when the noise detection unit detects an output that is equal to or greater than a threshold value,
A discharge accident detection system that confirms the noise output in the target frequency band that has passed through the filter main unit when the current waveform data measured by the current detection unit differs from the current waveform data in the storage unit based on the calculation result of the calculation unit. ..   The discharge accident detection system according to claim 1, wherein the discharge accident determination unit determines that a discharge accident has occurred when the time when the noise output measured by the noise detection unit exceeds the first threshold value exceeds a predetermined time. .. An opening control unit that can be controlled to open a switch connected to an electric device is provided,
3. The discharge accident detection system according to claim 1, wherein, when a discharge accident is detected, the opening control unit controls to open a switch connected to an electric device. A discharge accident detection system for detecting a discharge accident that occurs on a wiring path,
A voltage detection unit that measures voltage waveform data on wiring to which electrical equipment is connected,
A storage unit that stores the measured voltage waveform data of the electric device,
A voltage waveform data measured by the current detection unit, an arithmetic unit that compares the voltage waveform data of the storage unit,
A filter body that can cut a part of the noise output, a noise detection unit that detects the noise output in the target frequency band that is the target frequency to detect the noise generated by the discharge accident that has passed through the filter body, And a filter section having
A discharge accident determination unit that determines that a discharge accident has occurred when the noise detection unit detects an output that is equal to or greater than a threshold value,
A discharge accident detection system that confirms the noise output in the target frequency band that has passed through the filter body when the voltage waveform data measured by the voltage detection unit differs from the voltage waveform data in the storage unit based on the calculation result of the calculation unit. ..