JP2017055485A - Power distribution board - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power distribution board, having compact wiring for a shunt trip signal, preventing a space in a power supply box from being pressed.SOLUTION: On a power distribution board 10, there are mounted a master breaker 20, a plurality of branch breakers 30 with a shunt function, and a current detection board 50 which detects a current flowing through each branch breaker 30. The current detection board 50 includes a mounted current transformer 51, which is a current sensor for detecting the current of the branch breaker 30, and a printed wiring circuit 52 for transmitting a shunt trip signal which cuts off the electric conduction of the branch breaker 30.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a distribution board equipped with a shunt breaker that is turned off when an abnormality such as an overcurrent occurs.

  A distribution board disposed in a power supply box in a house or factory building is equipped with a main breaker and a branch breaker for overcurrent, short circuit current and leakage protection. The main breaker includes a neutral wire phase loss detection circuit, and functions as an earth leakage breaker that interrupts energization when an earth leakage that impedes circuit balance occurs (see, for example, Patent Document 1). Patent Document 1 discloses a configuration in which a neutral wire phase loss detection circuit is provided in a distribution board, and a shunt trip signal is output in the event of an abnormality to shut off the main breaker.

  By the way, abnormalities on the load side of electrical equipment may be caused by disasters such as earthquakes. However, in general distribution boards for ordinary houses, the vibration of the earthquake itself is detected, the breaker is cut off, and the fire It does not have a function to prevent secondary disasters.

  In recent years, the tracking phenomenon has been regarded as a problem as one of the causes of fires in ordinary houses. The tracking phenomenon is a phenomenon in which since the power plug has been inserted into the outlet tap for a long time, dust accumulates between the plug electrodes, the dust further attracts moisture, the insulation state deteriorates, and the periphery of the plug generates heat. . If the tracking phenomenon is neglected, spark discharge may be induced between the electrodes, or carbonized insulating resin may be ignited, which may cause serious damage leading to a fire.

  For this reason, for example, Patent Document 2 proposes a current interrupting device for detecting heat generated by an earthquake or heat generation due to a tracking phenomenon and operating a leakage breaker to prevent a fire.

JP 7-327305 A JP 9-327119 A

  The current interrupting device provided in the above-described conventional distribution board etc. can prevent secondary damage such as fire by shutting off the main breaker when an abnormality such as earthquake or tracking phenomenon is detected. it can. However, if the main breaker is interrupted due to an abnormality that has occurred in some branch circuits, all the power supplied to the main breaker is lost, which is not desirable because it is problematic. On the other hand, when the circuit breaker of the circuit where the abnormality is detected is identified and shut off, a protective circuit wiring is required for each branch breaker, and as a result, shunt trips in the distribution board There has been a problem that the signal wiring is radiated and the space in the power supply box is compressed.

  Therefore, the present invention is a distribution board equipped with a shunt breaker that is cut off in the event of an abnormality, and has a shunt trip signal wiring that is compact and does not compress the space in the power supply box. The purpose is to provide a board.

  In order to solve the above-described problem, the present invention provides a distribution board including a breaker with a shunt and a current detection board that detects a current flowing through the breaker. The current detection board includes a current of the breaker. And a wiring circuit for transmitting a shunt trip signal for shutting off the breaker is printed.

  According to the distribution board having this configuration, the shunt trip signal wiring can be prevented from being radiated and the space in the power supply box can be prevented from being compressed.

  In the above configuration, it is preferable that a relay circuit for controlling on / off of the shunt trip signal is mounted on the wiring circuit of the current detection board.

  According to the distribution board having this configuration, in addition to the above effects, a shunt trip signal having a current sufficient for breaking the breaker can be generated by the relay circuit. Therefore, sensor outputs such as a temperature sensor in a building and an acceleration sensor for detecting an earthquake can be directly connected to the current detection board.

  The distribution board having the above-described configuration may be mounted with a determination circuit that controls the output of the shunt trip signal based on at least the output of the current sensor.

  According to the distribution board having this configuration, in addition to the above effects, the determination circuit can determine abnormality based on the output of the current sensor, thereby improving the accuracy of abnormality determination.

In the above configuration, an external sensor may be mounted adjacent to the current sensor, and the determination circuit may control the output of the shunt trip signal based on at least the outputs of the current transformer and the external sensor. .
According to the distribution board having this configuration, in addition to the above effects, the determination circuit determines abnormality based on at least the outputs of the current sensor and the external sensor, so that the accuracy of abnormality determination can be further improved.

  According to the distribution board of the present invention, the shunt trip signal wiring can be prevented from being radiated, and the space in the power supply box can be prevented from being compressed.

1 is an external perspective view of a distribution board according to an embodiment of the present invention. FIG. 2 is a schematic longitudinal sectional view of the distribution board of FIG. 1. It is a perspective view which shows the example of the electric current detection board | substrate mounted in a distribution board. It is a perspective view which shows the example of the electric current detection board | substrate mounted in a distribution board. It is a front view of the electric current detection board | substrate by 1st embodiment. It is a front view of the electric current detection board | substrate by 2nd embodiment. It is a circuit diagram which shows an example of a relay circuit. It is a circuit diagram which shows the other example of a relay circuit. It is a front view of the electric current detection board | substrate by 3rd embodiment. It is a front view of the electric current detection board | substrate by 4th embodiment. It is a front view of the electric current detection board | substrate by 5th embodiment.

  FIG. 1 is an external perspective view showing a configuration of a distribution board 10 according to an embodiment of the present invention. FIG. 2 is a schematic longitudinal sectional view of the distribution board 10. In FIGS. 1 and 2, the illustration of the power supply box that houses the distribution board 10 is omitted.

  The distribution board 10 includes a main breaker 20 and a plurality of branch breakers 30, 30,... On the side of the main breaker 20, and each breaker is mounted on the frame substrate 11. The main breaker 20 has a substantially rectangular parallelepiped shape, and an operation handle 21 projects from the front surface. A primary power supply terminal is provided in the terminal cover 22 of the main breaker 20, and a neutral wire cable (N) (not shown) which is, for example, an AA power supply from the system and a voltage line cable (L1, L2) are connected. The Further, in the lead cover 23 of the main breaker 20, a secondary side neutral wire load terminal (N) and voltage line load terminals (L1, L2) are provided.

  While the main breaker 20 is energized, the power sources N, L1, and L2 of the respective phases are supplied to the bus bars 42, 43, and 44 through the lead bars 41 that are connected to the respective secondary load terminals. In the distribution board 10 of the present embodiment, bus bars 42, 43, and 44 are stacked and arranged in a space between the branch breakers 30, 30,. .

  The branch breakers 30, 30,... Are provided for each power supply branch circuit (hereinafter referred to as “branch circuit”) to which the load device in the building is connected, and the overcurrent and the short circuit current of the connected branch circuit are provided. When detected, it is configured to shut off its own energization. In the bus bars 42, 43, and 44 described above, the power supply side terminal portions of the branch breakers 30 are connected in a plug-in form. In addition, load-side terminal portions 31 and 32 connected to the branch circuit are provided on the front side surface of each branch breaker 30.

  In the distribution board 10 of the present embodiment, each branch breaker 30, facing the plurality of branch breakers 30, 30,... (Surfaces to which the bus bars 42, 43, 44 are connected) at the upper and lower stages. Current detection boards 50 and 50 for detecting a current that is passed by 30 are mounted. Here, FIGS. 3 and 4 show an example of a typical current detection substrate 50. On the current detection board 50, current sensors 51, 51,... For detecting a current flowing through the voltage line terminal portion L1 or L2 of each branch breaker 30 are mounted. Although the current sensor according to the present embodiment is a current transformer (CT), other appropriate current detection elements such as a method using a shunt resistor (current shunt) and a method using a Hall element can be adopted.

  Each branch breaker 30 has a shunt trip (voltage trip) function. On the branch circuit to which the branch breaker supplies power, any abnormality (for example, a tracking phenomenon or an abnormal overheat state, an overcurrent for each branch circuit) When a fault is detected, or when such an abnormality is determined, a shunt trip (SHT) signal is generated to cut off energization of the branch circuit.

  Therefore, next, a plurality of embodiments of the shunt trip signal wiring means provided on the current detection board for detecting the currents of the branch breakers 30, 30,... And shutting off the branch breaker when the branch circuit is abnormal will be described. To do.

(First embodiment)
FIG. 5 is a front view of the current detection board 50 according to the first embodiment. Note that FIG. 5 schematically and schematically shows a four-circuit current transformer and a shunt trip wiring in order to illustrate the embodiment of the present invention. In carrying out the present invention, a current sensor (CT) and a shunt trip wiring corresponding to the actual number of branch breakers mounted on the distribution board are arranged on the current detection board (following implementations). The same applies to the description of the form).

  On the current detection board 50 of the first embodiment, a wiring 52 for transmitting a shunt trip signal (trip signal) for interrupting the branch breaker 30 is printed. The wiring 52 is, for example, a seismic device (such as a vibration sensor or an acceleration sensor) that detects an earthquake, a power supply box of the distribution board 10, a temperature sensor or a humidity sensor disposed in a building, a load-side current sensor, or the like. Transmits signals from external sensors. A sensor output from an external sensor or the like is input to the input terminal portion 53 and output from the output terminal portion 55 to the corresponding branch breaker 30 via the wiring 52. Further, the current detection board 50 is provided with current transformers 51, 51,... As current sensors corresponding to the position of the branch breaker 30, and the output of each current transformer 51 is supplied from the CT output terminal section. It is output to an external control device such as a HEMS (Home Energy Management System).

  In addition, you may provide the output terminal part 55 corresponding to the position of the branch breaker 30. FIG. Moreover, you may arrange | position an external sensor for every branch row | line | column.

  As another example, the input terminal unit 53 may be connected to the above-described external control device such as HEMS. In this case, in an external control device such as HEMS, detection of an abnormality and processing for specifying a branch circuit in which the abnormality has occurred are performed. When the shunt trip signal is generated by the external control device, the shunt trip signal is input to the input terminal portion 53 and transmitted to the corresponding branch breaker 30 via the wiring 52 and the output terminal portion 55.

  Thus, by printing the shunt trip signal wiring circuit on the current detection board 50, the shunt trip signal wiring in the distribution board 10 can be prevented from being radiated and the wiring can be made compact. Therefore, the space in the power supply box can be prevented from being compressed.

(Second embodiment)
FIG. 6 is a front view of the current detection board 60 according to the second embodiment. A wiring 62 for transmitting a shunt trip signal is printed on the current detection board 60 of the second embodiment, and a relay circuit 67 is mounted on the wiring circuit. Here, one example of the relay circuit 67 is shown in FIG. Each relay switch 671, 672, 673, 674 can be turned on / off according to an abnormality detection signal from the outside, and can switch a shunt trip signal having a current sufficient to shut off the branch breaker 30. Further, in order to reduce the number of wirings, a decoding circuit 68 for converting the coded abnormality detection signal may be provided as shown in FIG.

  For example, an external sensor such as the above-described seismic sensor can be directly connected to the input terminal portion 63. When these external sensors have a level value equal to or higher than a predetermined threshold, the corresponding relay switch of the relay circuit 67 is turned on, and a shunt trip signal is output to the branch breaker 30 via the wiring 62. Thereby, the energization of the branch breaker 30 of the branch circuit where the abnormality has occurred can be cut off.

  Further, similarly to the first embodiment, for example, an external control device such as HEMS may be connected to the input terminal unit 63. In that case, an abnormality is detected in an external control device such as a HEMS, and a process for specifying a branch circuit in which the abnormality has occurred is performed. Based on the abnormality detection signal generated by the external control device, the corresponding relay of the relay circuit 67 The switch turns on. The shunt trip signal from the relay circuit 67 is transmitted to the corresponding branch breaker 30 via the wiring 62, and the energization is cut off. Thereby, it is possible to prevent the wiring of the shunt trip signal in the distribution board 10 from being radiated and to be compact.

(Third embodiment)
FIG. 9 is a front view of the current detection board 70 according to the third embodiment. A wiring 72 for transmitting a shunt trip signal is printed on the current detection board 70 of the third embodiment, and a relay circuit 77 and an abnormality determination circuit 78 are mounted. The abnormality determination circuit 78 is connected to turn on and off the relay circuit 77 based on the current flowing through the branch breaker 30 obtained from the current transformers 51, 51,. For example, the abnormality determination circuit 78 includes a pulsating component having a period other than a predetermined period (50 Hz or 60 Hz) and a current waveform of a tracking phenomenon when the current flowing through the branch breaker 30 is equal to or greater than a predetermined value (for example, at a short circuit). Sometimes, it may be determined that an abnormality has occurred in the branch circuit, and a shunt trip signal for shutting off the branch breaker 30 connected to the branch circuit may be output.

  Further, an external control device such as HEMS may be connected to the input terminal portion 73 of the abnormality determination circuit 78. In that case, the determination criterion for determining whether there is an abnormality in the abnormality determination circuit 78 may be set or updated by an operation on the external control device or an automatic determination process by the external control device. Further, the abnormality determination circuit 78 may include the relay circuit 77 in one package.

  In the present embodiment, an external sensor such as the above-described seismic device may be connected to the input terminal portion 73. In that case, the abnormality determination circuit 78 determines whether or not an abnormality has occurred in the branch circuit based on the outputs of the current transformers 51, 51,... And information of various sensors input from the outside. be able to. By considering the information of various sensors together with the output of the current transformer 51, the accuracy of branch circuit abnormality determination by the abnormality determination circuit 78 can be increased.

(Fourth embodiment)
FIG. 10 is a front view of a current detection board 80 according to the fourth embodiment. The current detection board 80 of the fourth embodiment has temperature sensors 87, 87,... As external sensors adjacent to the current transformers 51, 51,.・ ・ Is implemented. In the present embodiment, temperature sensors 87, 87,... Are provided corresponding to the respective branches.

  On the current detection board 80, wiring 82 for transmitting a shunt trip signal is printed, and an abnormality determination circuit 88 is mounted. The abnormality determination circuit 88 determines the abnormality of the branch circuit based on the outputs of the current transformers 51, 51,... And the outputs of the temperature sensors 87, 87,. For example, in a certain branch circuit, when the relationship curve between the current value detected by the current transformer 51 and the temperature detected by the temperature sensor 87 is different from the normal one, the abnormality determination circuit 88 determines that the branch circuit is abnormal and responds accordingly. A shunt trip signal is output to the branch breaker 30. As a result, energization of the branch circuit for which an abnormality has been determined is cut off.

  Note that a thermometer for measuring the ambient temperature may be disposed in the distribution board 10 or the power supply box, and the abnormality determination circuit 88 may consider the temperature measured by the thermometer in the abnormality determination. Further, an external sensor such as the above-described seismic device may be connected to the input terminal portion 83. In these cases, the abnormality determination circuit 88 is based on the outputs of the current transformers 51, 51,..., The outputs of the temperature sensors 87, 87,. Thus, it can be determined whether or not an abnormality has occurred in the branch circuit. By considering the information of various sensors together with the output of the current transformer 51, the accuracy of determination by the abnormality determination circuit 88 can be further increased.

(Fifth embodiment)
Further, as shown in FIG. 11, abnormality determination circuits 98, 98,... May be provided for each branch circuit. Each abnormality determination circuit 98 can determine the abnormality of the branch circuit based on the output of the current transformer 51 and the output of the temperature sensor 97 adjacent to the current transformer 51. For example, if the relationship between the current value detected by the current transformer 51 and the temperature detected by the temperature sensor 97 is different from the normal value, the abnormality determination circuit 98 determines that there is an abnormality and responds to the shunt trip signal via the output terminal unit 55. Output to the branch breaker 30. As a result, it is possible to cut off the energization to the corresponding branch circuit with a simplified circuit configuration that does not require a processing circuit that identifies the branch where the abnormality has occurred.

10 Distribution board 11 Frame substrate 20 Main breaker 30 Branch breaker 50 Current detection substrate (first embodiment)
51 Current sensor (current transformer)
52 Wiring 53 Input Terminal Unit 60 Current Detection Board (Second Embodiment)
62 wiring 63 input terminal portion 67 relay circuit 70 current detection board (third embodiment)
72 Wiring 73 Input terminal section 77 Relay circuit 78 Abnormality determination circuit 80 Current detection board (fourth embodiment)
82 Wiring 87 Temperature sensor 88 Abnormality determination circuit 90 Current detection board (fifth embodiment)
92 Wiring 97 Temperature sensor 98 Abnormality judgment circuit

Claims (4)

A distribution board comprising a breaker with a shunt and a current detection board for detecting a current flowing through the breaker,
A current distribution board on which a current circuit for detecting a current of the breaker is mounted and a wiring circuit for transmitting a shunt trip signal for interrupting the breaker is printed on the current detection board. .   The distribution board according to claim 1, wherein a relay circuit that controls on / off of the shunt trip signal is mounted on the wiring circuit of the current detection board.   The distribution board according to claim 2, wherein a determination circuit that controls the output of the shunt trip signal based on at least the output of the current sensor is mounted.   The external sensor is mounted adjacent to the current sensor, and the determination circuit controls the output of the shunt trip signal based on at least the outputs of the current transformer and the external sensor. The distribution board described in 1.