JP6260822B2 - Distribution board cabinet and distribution board - Google Patents

Description

  The present invention relates generally to a cabinet for a distribution board and a distribution board, and more particularly to a cabinet for a distribution board provided with a conductive bar, and a distribution board using the same.

  Conventionally, a distribution board including a main breaker and a plurality of branch breakers is widely known (see, for example, Patent Document 1). The distribution board described in Patent Document 1 includes a current measuring device (current sensor unit) that detects a branch current flowing in a branch circuit, and a measurement control unit that outputs a signal based on data detected by the current measuring device. ing.

  This distribution board includes three conductive bars (main bars) that are electrically connected to the main breaker. These conductive bars are held on the base table, and the branch breaker is electrically connected to the conductive bars. Here, among the three conductive bars, in the voltage phase (L1, L2) conductive bar, one end in the short direction of the conductive bar (flat plate portion) is branched into a plurality of connection terminals (branch bars). The plurality of connection terminals are arranged in the longitudinal direction of the conductive bar, and a branch breaker is connected to each of the plurality of connection terminals.

  The current measuring instrument has a measuring unit (current sensor) that detects a current flowing through the connection terminal. The measurement unit is a Rogowski-type air core current transformer formed around the insertion hole of the printed circuit board through which the connection terminal passes. Thereby, the current measuring device can detect the current flowing through each branch breaker.

JP 2008-136283 A

  However, in the conventional distribution board as described above, since the total current flowing through the plurality of branch breakers passes through the conductive bar, the current flowing through the conductive bar increases as the number of branch circuits increases, and the current flows around the conductive bar. The strength of the generated magnetic field increases, and this magnetic field may act on the connection terminal. In this case, the magnetic field acting on the connection terminal may affect the measurement by the measurement unit formed around the connection terminal.

  The present invention has been made in view of the above reasons, and provides a distribution board cabinet in which a magnetic field generated when a current flows through a conductive bar hardly acts on a connection terminal, and a distribution board using the cabinet. Objective.

  The distribution board cabinet of the present invention includes a cabinet body and a conductive bar fixed to the cabinet body and forming a power path from a main breaker to a plurality of branch breakers, and the conductive bar includes the conductive bar. A plurality of connection terminals arranged in the longitudinal direction at one end in the short direction of the conductive bar, and the main breaker can be electrically connected to one end in the longitudinal direction of the conductive bar, and Each of the plurality of branch breakers can be electrically connected to each of the plurality of connection terminals, and the conductive bar includes a first lane and a second lane arranged in a short direction of the conductive bar, The first lane and the second lane are arranged in the order of the first lane and the second lane from the plurality of connection terminal sides, and the first lane has a current flowing in the longitudinal direction of the conductive bar. Wherein the electrical resistance is configured so as to be higher than the second lane.

  According to the present invention, since the electrical resistance to the current flowing in the longitudinal direction of the conductive bar is lower in the second lane than in the first lane, the current flowing through the conductive bar flows in the second lane than in the first lane. It becomes easy. Therefore, the conductive bar according to the present invention can flow current intensively in the second lane on the side opposite to the plurality of connection terminals in the short direction, and the main current path is located away from the plurality of connection terminals. Can be formed. As a result, there is an advantage that a magnetic field generated when a current flows through the conductive bar hardly acts on the connection terminal.

It is a perspective view which shows the electrically-conductive bar of the cabinet for distribution boards which concerns on Embodiment 1. FIG. It is a front view which shows the electricity distribution panel which concerns on Embodiment 1. FIG. It is a perspective view which shows the principal part of the electricity distribution panel which concerns on Embodiment 1. FIG. FIG. 3 is an exploded perspective view illustrating a main part of the distribution board according to the first embodiment. It is sectional drawing which shows the principal part of the electricity distribution panel which concerns on Embodiment 1. FIG. It is explanatory drawing of the electric current which flows through the electrically-conductive bar of the cabinet for distribution boards which concerns on Embodiment 1. FIG. It is a perspective view which shows the electrically-conductive bar of the cabinet for distribution boards which concerns on Embodiment 2. FIG. It is a perspective view which shows the electrically-conductive bar of the cabinet for distribution boards which concerns on Embodiment 3. FIG. It is sectional drawing which shows the electrically conductive bar which concerns on a modification. It is sectional drawing which shows the electrically conductive bar which concerns on another modification.

(Embodiment 1)
As shown in FIGS. 2 and 3, the distribution board cabinet 10 according to the present embodiment is fixed to the cabinet body 11 and the cabinet body 11, and power from the main breaker 2 to the plurality of branch breakers 3, 3. And conductive bars 41, 42, and 43 that form the path.

  Here, since a single-phase three-wire system is assumed as the power distribution method, the conductive bars 41, 42, and 43 include the conductive bar 41 of the first voltage pole (L1 phase) and the second voltage pole (L2 phase). ) Conductive bar 42 and neutral electrode (N-phase) conductive bar 43 in total. Hereinafter, among the three conductive bars 41, 42, 43, the conductive bars 41, 42 of the first and second voltage electrodes of interest are particularly referred to as “conductive bars”, and the neutral conductive bar 43 is referred to as “neutral pole”. Sometimes referred to as “bar”.

  As shown in FIG. 1, the conductive bar 41 of the first voltage electrode has a plurality of connection terminals 411, 411... Arranged in the longitudinal direction of the conductive bar 41 at one end in the short direction of the conductive bar 41. . The main breaker 2 can be electrically connected to one end of the conductive bar 41 in the longitudinal direction, and each of the plurality of branch breakers 3, 3. Connectable.

  The conductive bar 41 includes a first lane 412 and a second lane 413 arranged in the short direction of the conductive bar 41. The first lane 412 and the second lane 413 are arranged in the order of the first lane 412 and the second lane 413 from the plurality of connection terminals 411, 411. The first lane 412 is configured such that the electrical resistance to the current flowing in the longitudinal direction of the conductive bar 41 is higher than that of the second lane 413.

  As for the conductive bar 42 of the second voltage electrode, similarly to the conductive bar 41 of the first voltage electrode, a plurality of connection terminals 421, 421,. At one end. The main breaker 2 can be electrically connected to one end of the conductive bar 42 in the longitudinal direction, and each of the plurality of branch breakers 3, 3... Is electrically connected to each of the plurality of connection terminals 421, 421. Connectable.

  The conductive bar 42 includes a first lane 422 and a second lane 423 arranged in the short direction of the conductive bar 42. The first lane 422 and the second lane 423 are arranged in the order of the first lane 422 and the second lane 423 from the side of the plurality of connection terminals 421, 421. The first lane 422 is configured such that the electrical resistance to the current flowing in the longitudinal direction of the conductive bar 42 is higher than that of the second lane 423.

  That is, the distribution board cabinet 10 according to the present embodiment includes the first lane 412 (422) and the second lane 413 (423) in which the conductive bars 41 (42) are arranged in the short direction. Of the first lane 412 (422) and the second lane 413 (423), the first lane 412 (422) on the side of the connection terminals 411, 411... (421, 421. , Higher than the second lane 413 (423).

  Hereinafter, the distribution board cabinet 10 according to the present embodiment and the distribution board 1 using the same will be described in detail. However, the configuration described below is only an example of the present invention, and the present invention is not limited to the following embodiment, and the technical idea according to the present invention is not deviated from this embodiment. Various changes can be made in accordance with the design or the like as long as they are not.

  In the present embodiment, the case where the power customer (customer's facility) on which the distribution board 1 is installed is a detached house, but the present invention is not limited to this example. Each dwelling unit, office, store, factory, etc. may be used. In the following, the top, bottom, left and right (up, down, left, and right in FIG. 2) when the distribution board 1 is attached to the wall are defined as top, bottom, left and right, and the direction perpendicular to the wall (the direction perpendicular to the sheet of FIG. However, it is not intended to limit the direction in which the distribution board 1 is attached.

<Basic configuration>
As shown in FIG. 2, the distribution board 1 according to the present embodiment includes a distribution board cabinet 10 and a distribution board inner unit (hereinafter simply referred to as “inner unit”) attached to the distribution board cabinet 10. ). The internal unit includes at least a main breaker 2 and a plurality of branch breakers 3, 3..., And in this embodiment, a current measuring device 5 (see FIG. 3), a measuring unit 6, a first communication adapter 71, a second communication. An adapter 72, a third communication adapter 73, and a secondary interconnection breaker 8 are included. In addition to the internal unit shown in FIG. 2, distribution cabinet 10 has a space for mounting an internal unit such as a primary interconnection breaker (not shown).

  First, the basic configuration of the distribution board cabinet 10 will be described.

  As shown in FIG. 2, the distribution board cabinet 10 is formed in a box shape in which the front view is a horizontally long rectangular shape and the front surface is open, and includes a cabinet body 11 that is used by being attached to a wall of a house. ing. Here, the cabinet body 11 is attached with an outer lid (not shown) that can be opened and closed between a position where the front opening is closed and a position where the opening is opened.

  Further, an inner lid (not shown) is attached to the inside of the outer lid of the cabinet body 11 so as to close the opening on the front surface of the cabinet body 11. The inner lid is formed with a window hole (not shown) for exposing at least a part of the main breaker 2 and the plurality of branch breakers 3, 3. FIG. 2 shows the distribution board 1 with the outer lid and the inner lid removed. Each of the outer lid and the inner lid may be included in the distribution board cabinet 10 or may not be included in the distribution board cabinet 10.

  The cabinet body 11 includes a frame 110 made of a synthetic resin and formed in a rectangular frame shape, and crosspieces 111 to 114 that are spanned between both sides of the opening of the frame 110 in the vertical direction. Yes. These four crosspieces 111 to 114 are arranged in the order of crosspieces 111, 112, 113, and 114 in order from the right side, and the crosspiece 112 and the crosspiece 113 are integrally formed. In this configuration, the cabinet body 11 is formed with a hole penetrating in the front-rear direction by an opening of the frame 110 in the rear wall, and wiring can be drawn into the interior from the back through this hole.

  Further, the cabinet body 11 includes a support plate 12 and a base 13 (see FIG. 3) that are attached across a pair of crosspieces 111 and 112. The support plate 12 is made of a magnetic material such as tin (tin-plated iron). The support plate 12 is fixed by screwing both ends in the left-right direction to the pair of crosspieces 111 and 112. The base table 13 is made of, for example, a nonmagnetic material such as synthetic resin, and is attached to the front surface that is one surface in the thickness direction of the support plate 12. Note that the support plate 12 is not limited to tinplate, and may be configured using, for example, a galvanized steel plate (SGCC).

  The cabinet body 11 has a space for mounting various internal devices such as a breaker. In the present embodiment, the cabinet body 11 includes a first space between the pair of crosspieces 112 and 113 in which the main breaker 2 is disposed. Further, the cabinet body 11 includes a second space in which the plurality of branch breakers 3, 3... Are arranged and a third space in which the current measuring device 5 is arranged in the base table 13.

  Here, the first space is provided at a position closer to the left and lower than the center of the front surface of the cabinet body 11. The cabinet body 11 secures sufficient space above, below, to the left, and to the right of the first space. The second space and the third space are provided on the right side of the first space. As will be described in detail later, the plurality of branch breakers 3, 3... Are divided into an upper side and a lower side of the neutral pole bar 43, and a plurality (11 in the example of FIG. 2) are arranged in the horizontal direction. Is done. Therefore, the second space for attaching the plurality of branch breakers 3, 3... Is provided on the right side of the first space in the cabinet body 11 and on the upper side and the lower side of the neutral electrode bar 43, respectively. . A third space for mounting the current measuring instrument 5 is provided behind the neutral electrode bar 43.

  The cabinet body 11 includes a fourth space between a pair of crosspieces 113 and 114 in which a primary interconnection breaker (not shown) described later is disposed. Moreover, the cabinet main body 11 is provided with the 5th space where the measurement unit 6 mentioned later is arrange | positioned under the 1st space. Furthermore, the cabinet body 11 includes a sixth space on the left side of the crosspiece 114 in which a first communication adapter 71, a second communication adapter 72, and a third communication adapter 73, which will be described later, are arranged.

  As described above, the distribution board cabinet 10 of the present embodiment is provided with the third to sixth spaces in the cabinet body 11, so that various internal devices other than the main breaker 2 and the plurality of branch breakers 3, 3. Additional attachment (retrofit) is possible. However, the cabinet body 11 only needs to have a first space to which the main breaker 2 is attached and a second space to which the plurality of branch breakers 3, 3. May be.

  By the way, as shown in FIG. 3, the distribution board cabinet 10 includes a first voltage electrode conductive bar 41, a second voltage electrode conductive bar 42, and a neutral electrode conductive bar (neutral electrode bar) 43. Is further provided. These three conductive bars 41, 42, and 43 are fixed to the cabinet body 11 by being attached to the base table 13, respectively.

  More specifically, the base 13 includes a back plate 131 attached to the support plate 12, and a pair of support columns 132 and 132 (the right support column is protruded forward from both left and right ends of the front surface of the back plate 131). 4). The pair of struts 132 and 132 are disposed at the center in the vertical direction on the front surface of the back plate 131.

  Furthermore, as shown in FIG. 4, the base table 13 has a partition wall 133 protruding forward from a center line along the left-right direction of the front surface of the back plate 131 and a space between the pair of columns 132, 132 in the left-right direction. A plurality of partitions 134, 134... Partitioning at equal intervals. In the present embodiment, the base table 13 is configured to be divided into a plurality (four in this case) in the left-right direction. However, the configuration is not limited to this configuration, and the base table 13 may be integrally formed.

  The neutral pole bar 43 is an electrically conductive metal plate and is formed in a long plate shape that is long in the left-right direction, and is arranged at each end in the left-right direction so as to be bridged between the pair of columns 132, 132. Are fixed to the front end portion (front end portion) of the support column 132. Here, the protruding height of the partition wall 133 from the front surface of the back plate 131 is lower than that of the support columns 132 and 132 and the partitions 134, 134..., And a gap is formed between the neutral electrode bar 43 and the partition wall 133. The

  The conductive bar 41 of the first voltage electrode is formed of a conductive metal plate, and is attached to a region above the partition wall 133 on the front surface of the back plate 131. The conductive bar 41 has a long plate shape that is long in the left-right direction and is disposed along the front surface of the back plate 131 (first) flat plate 414 and protrudes forward from the lower end edge of the flat plate 414 (first block). And a protruding piece 415.

  Here, the protruding piece 415 is formed so as to rise forward from the flat plate 414 along the partition wall 133 between the pair of support columns 132 and 132, and is divided into a plurality of parts by a plurality of partitions 134, 134. Has been. In other words, the projecting pieces 415, 415,... Divided into a plurality are arranged between adjacent struts 132 and partitions 134 or between a pair of adjacent partitions 134 and 134, respectively.

  The tip of each protruding piece 415 is divided into two forks, one of which is an upwardly projecting (first) connecting terminal 411 and the other of which is a downwardly projecting (second) connecting terminal 411. The connection terminal 411 that protrudes downward is located in front of the connection terminal 411 that protrudes upward, and protrudes to the lower side of the partition wall 133 through the gap between the partition wall 133 and the neutral electrode bar 43.

  The conductive bar 42 of the second voltage electrode adopts a shape that is substantially symmetrical to the conductive bar 41 of the first voltage electrode with respect to the partition wall 133, and the basic configuration is the conductive bar of the first voltage electrode. 41. That is, the conductive bar 42 of the second voltage electrode is formed of a conductive metal plate, and is attached to a region below the partition wall 133 on the front surface of the back plate 131. The conductive bar 42 has a long plate shape that is long in the left-right direction and is disposed along the front surface of the back plate 131 (second) flat plate 424, and protrudes forward from the upper end edge of the flat plate 424 (second second). And a protruding piece 425.

  The protruding piece 425 is divided into a plurality of pieces by a plurality of partitions 134, 134. The tip of each protruding piece 425 is divided into two forks, one being a (third) connecting terminal 421 protruding downward and the other being a (fourth) connecting terminal 421 protruding upward. The connection terminal 421 protruding upward is located in front of the connection terminal 421 protruding downward, and protrudes above the partition wall 133 through the gap between the partition wall 133 and the neutral electrode bar 43.

  With the above-described configuration, as shown in FIG. 5, on the upper side of the partition wall 133, the three conductive bars 41, 42, 43 are electrically connected to the neutral bar 43, conductive from the front side (opposite to the wall) in the front-rear direction. The bars (connection terminals 421) 42 and the conductive bars (connection terminals 411) 41 are arranged in this order. On the lower side of the partition wall 133, the three conductive bars 41, 42, 43 are arranged in the front-rear direction from the front side (the side opposite to the wall) to the neutral electrode bar 43, the conductive bar (connection terminal 411) 41, the conductive bar. (Connection terminal 421) 42 are arranged in this order.

  The conductive bar 41 only needs to have a plurality of connection terminals 411, 411,... Arranged in the longitudinal direction of the conductive bar 41 at one end portion in the short direction of the conductive bar 41. 411 ... need not be separated (divided) from each other. That is, it is not essential that one end portion in the short direction of the conductive bar 41 is branched into a plurality of connection terminals 411, 411,... Arranged in the longitudinal direction of the conductive bar 41, and the connection to which the branch breaker 3 is connected. There may be a plurality of terminals 411. The same applies to the plurality of connection terminals 421, 421,.

  Next, an internal unit of the distribution board 1 (an internal unit that can be attached to the cabinet body 11) will be described.

  The main breaker 2 is electrically connected to a primary side terminal 21 of a single-phase three-wire lead-in line of a system power supply (commercial power supply). The above-mentioned three conductive bars 41, 42, 43 are electrically connected to the secondary side terminal (not shown) of the main breaker 2. The main breaker 2 is configured to be switchable between an on state in which power from a system power source connected to the primary side is supplied to the secondary side and an open state in which the supply of the power is cut off.

  The plurality of branch breakers 3, 3... Are divided into an upper side and a lower side of the partition wall 133 on the front surface of the base table 13 of the cabinet body 11, and are arranged so as to be arranged in the left-right direction. Each branch breaker 3 has a primary side terminal 32 (see FIG. 5) and a secondary side terminal (not shown), and the primary side terminal 32 is electrically connected to the conductive bars 41, 42, 43. Each of a plurality of electric circuits (not shown) is connected to the secondary side terminal. Each branch breaker 3 is formed in a contracted dimension. Here, the agreement type dimension means a dimension (and shape) of a circuit breaker for a light distribution board in accordance with “JIS C 8201-2-1”.

  Each of the plurality of branch breakers 3, 3... Is disposed between adjacent struts 132 and partitions 134 or between a pair of adjacent partitions 134 and 134. In other words, each branch breaker 3 is attached to each space partitioned by the partitions 134, 134... In the left-right direction.

  Connected to the electrical circuit connected to the secondary terminal of each branch breaker 3, for example, one or more devices such as lighting fixtures and hot water supply facilities, outlets of plug connection devices, and wiring fixtures such as wall switches are connected as loads. And constitutes a branch circuit. In other words, each of the branch breakers 3, 3... Is electrically connected to the branch circuit, and switches between a power-on state in which power from the main breaker 2 is supplied to each branch circuit and an open state in which the power supply is cut off. It is configured to be possible.

  Each branch breaker 3 has an insertion port 31 (see FIG. 5) into which each conductive bar 41, 42, 43 is inserted on the surface facing the partition wall 133. Three insertion ports 31 are provided in each branch breaker 3 in the front-rear direction. The primary side terminal 32 is provided so as to be exposed in two of the three insertion ports 31, 31, 31. Thereby, in the state where each branch breaker 3 is attached to the cabinet body 11, each conductive bar 41, 42, 43 is inserted into the insertion port 31, and the primary side is inserted into any one of the pair of conductive bars 41, 42, 43. Terminal 32 is electrically connected. The connection terminal 411 is inserted into the insertion port 31 corresponding to the conductive bar 41, and the connection terminal 421 is inserted into the insertion port 31 corresponding to the conductive bar 42.

  A branch breaker (hereinafter also referred to as a “100 V branch breaker”) 3 connected to the first voltage electrode or the second voltage electrode and the neutral electrode has three primary terminals 32 and 32 plugged in. Of the ports 31, 31, 31, it is provided so as to be exposed in the two insertion ports 31, 31 at both ends. As a result, the 100 V branch breaker 3 is electrically connected to the first voltage electrode and the neutral electrode and attached to the lower side of the partition wall 133 when attached to the upper side of the partition wall 133. Then, the second voltage electrode and the neutral electrode are electrically connected.

  Further, a branch breaker (hereinafter also referred to as a “200 V branch breaker”) 3 connected to the first voltage electrode and the second voltage electrode has three primary terminals 32, 32 having three insertion ports 31, 31 and 31 are provided so as to be exposed in the two rear insertion ports 31 and 31. Thereby, the 200 V branch breaker 3 is electrically connected to the first voltage electrode and the second voltage electrode, regardless of whether the 200 V branch breaker 3 is attached to the upper side or the lower side of the partition wall 133.

  The current measuring device 5 is a sensor for detecting the power consumption of a load (electric circuit) connected to each of the plurality of branch breakers 3, 3. Here, a pair of current measuring devices 5 are provided, and are attached to the upper side and the lower side of the partition wall 133 as shown in FIG.

  The current measuring device 5 attached to the upper side of the partition wall 133 is attached to the plurality of connection terminals 411, 411, and the plurality of connection terminals 421, 421, and measures the value of the current flowing through each of the connection terminals 411, 411,. . This current measuring instrument 5 includes a branch breaker 3 attached on the upper side of the partition wall 133, for example, a 100V branch breaker 3 connected between a first voltage electrode and a neutral electrode, or a first voltage electrode-second voltage. The value of the current flowing through the 200V branch breaker 3 connected between the electrodes is measured. FIG. 3 shows a state where the current measuring instrument 5 is attached and the branch breaker 3 is removed.

  The current measuring instrument 5 attached to the lower side of the partition wall 133 is attached to the plurality of connection terminals 411, 411, and the plurality of connection terminals 421, 421, and measures the value of the current flowing through each of the connection terminals 421, 421,. To do. This current measuring instrument 5 includes a branch breaker 3 attached to the lower side of the partition wall 133, for example, a 100V branch breaker 3 connected between the second voltage electrode and the neutral electrode, or a first voltage electrode-second electrode. The value of the current flowing through the 200 V branch breaker 3 connected between the voltage electrodes is measured.

  Next, a specific configuration of the current measuring instrument 5 will be described with reference to FIGS. 3 and 4. The current measuring instrument 5 includes a substrate 501 (see FIG. 4) and a case 502 that accommodates the substrate 501. In FIG. 4, the current measuring instrument 5 is illustrated with the case 502 omitted and the substrate 501 exposed.

  A plurality of current sensors 503, 503... Are mounted on the substrate 501. The plurality of current sensors 503, 503,... Are configured to measure the value of the current flowing through each of the plurality of branch breakers 3, 3,. In the current measuring instrument 5, through holes 504, 504... Penetrating the substrate 501 and the case 502 in the thickness direction of the substrate 501 are formed at positions corresponding to the connection terminal 411 and the connection terminal 421, respectively. As a result, the current measuring instrument 5 has a plurality of connection terminals 411, 411, and a plurality of connection terminals 421, 421,. It will be attached to the connection terminals 421, 421. In this state, the connection terminals 411 of the first voltage electrode conductive bar 41 and the connection terminals 421 of the second voltage electrode conductive bar 42 pass through the through holes 504, 504,. Thus, the branch breaker 3 is connected.

  In the current measuring instrument 5, current sensors 503 are formed around the respective through holes 504 in the substrate 501. Each current sensor 503 is a sensor such as a current transformer (current transformer), a Hall element, a magnetoresistive element, a GMR (Giant Magnetic Resistances) element, or a shunt resistance. As an example, each current sensor 503 is a Rogowski coil that includes an air core coil that does not use a core (coreless), and generates an output corresponding to a current passing through the through hole 504. The current measuring device 5 calculates the value of the current flowing through each of the plurality of branch breakers 3, 3... Based on the output of each current sensor 503. The value of the current flowing through each of the plurality of branch breakers 3, 3... Is the same as the value of the current flowing through each of the plurality of electric circuits connected to the plurality of branch breakers 3, 3..

  However, the current sensor 503 does not have to be provided around all the through holes 504, 504, and in this embodiment, the rear side (wall side) of the pair of through holes 504, 504 arranged in the front-rear direction. It is provided only around the through hole 504. That is, in the present embodiment, the rectangularly shaped through hole 504 and the circularly shaped through hole 504 are formed side by side in the front-rear direction, and of these, the circular shape that is the rear side (wall side) The current sensor 503 is provided only around the through hole 504. Thus, the current sensor 503 measures the current value of the first voltage electrode when the current measuring instrument 5 is attached to the upper side of the partition wall 133, and the second voltage electrode when the current sensor 5 is attached to the lower side of the partition wall 133. The current value is measured.

  In the present embodiment, the through holes 504 are formed so as to open in a circular shape or a rectangular shape in a plane orthogonal to the thickness direction of the substrate 501, but the present invention is not limited to these shapes. That is, each through-hole 504 is only required to penetrate in the thickness direction of the substrate 501, and the opening shape in a plane orthogonal to the thickness direction may be a shape other than a circle or a rectangle. The shape opened in one direction as shown in FIG.

  Further, in the present embodiment, the current measuring instrument 5 has a computing device 505 on the substrate 501 that calculates the instantaneous power of each of the plurality of electric paths using the output of each current sensor 503. The arithmetic device 505 acquires voltage information indicating the value of the line voltage of each of the plurality of electric circuits from the measurement unit 6, and based on the current value obtained from the output of each current sensor 503 and the voltage information, the instantaneous power Is obtained as power information of the branch circuit. The current measuring instrument 5 is electrically connected to the first communication adapter 71 via the measurement unit 6 and transmits the power information of the branch circuit to the first communication adapter 71 via the measurement unit 6.

  The measurement unit 6 is electrically connected to the above-described three conductive bars 41, 42, and 43, receives electric power from the conductive bars 41, 42, and 43, and receives the electric current from the current measuring instrument 5 and the first communication adapter 71. Including a power supply circuit (not shown) for generating power for operating the internal unit. Further, the measuring unit 6 has a function of measuring the voltage between the conductive bars 41, 42, 43 and outputting the measured voltage value to the current measuring instrument 5 as voltage information.

  Further, the measurement unit 6 is configured to measure electric power for a specific circuit other than the branch circuit that is a measurement target in the current measuring instrument 5. Specifically, the measurement unit 6 is electrically connected to a current sensor (not shown) made of a current transformer (CT), and measures the value of the current passing through the main breaker 2, for example, by this current sensor. And the measurement unit 6 is comprised so that the value of instantaneous electric power may be calculated | required as electric power information of a specific circuit based on the value of the measured electric current, and voltage information. The measurement unit 6 is electrically connected to the first communication adapter 71 and transmits power information of the specific circuit to the first communication adapter 71.

  The current measuring instrument 5 and the measuring unit 6 are configured to obtain power information in the present embodiment, but the present invention is not limited to this example, and at least the value of the current flowing in each electric circuit (branch circuit or specific circuit). Any configuration can be used. For example, the current measuring instrument 5 and the measuring unit 6 may be configured to transmit the measured current value to the first communication adapter 71.

  The first communication adapter 71 has a communication function with a controller (not shown) that controls a device (not shown). The device here is a device compatible with HEMS (Home Energy Management System). The HEMS-compatible device only needs to be a management target of power consumption, for example, eight devices important in HEMS (smart meter, solar power generation device, power storage device, fuel cell, electric vehicle, air conditioner, lighting fixture, hot water supply device), etc. including. Further, the HEMS compatible device may include the other two of the four large power consumption sources, a refrigerator, a television receiver, and the like. However, the purpose is not to limit the HEMS compatible devices to these devices.

  The first communication adapter 71 is configured to receive the branch circuit power information from the current measuring instrument 5 and the specific circuit power information from the measurement unit 6. The first communication adapter 71 has a function of collecting instantaneous power data of each of the plurality of electric circuits by acquiring the power information. Further, the first communication adapter 71 may have a function of calculating the amount of power obtained by integrating the instantaneous power over a predetermined time for each of the plurality of electric circuits.

  The first communication adapter 71 transmits the power information (instantaneous power or power amount) to the controller. The controller is configured to control the device using the power information (HEMS compatible). Thereby, the controller can control an apparatus based on the power consumption in each of several electric circuit.

  Here, the controller is a HEMS controller. The HEMS controller has a function of visualizing (visualizing) power information by controlling a display terminal (not shown) and controlling a device (compatible with HEMS) based on the power information. It is installed outside the electrical panel 1. According to this controller, it becomes possible to manage the state of power consumption in the device, and wasteful consumption of power can be suppressed.

  The controller is installed in the house, and communicates with the first communication adapter 71 by, for example, wireless communication using radio waves as a medium, or wired communication such as a wired LAN (Local Area Network), or in-home (HEMS compatible) equipment. To control. The controller is connected to a network (not shown) such as the Internet, and communicates with the first communication adapter 71 by communication via the network, or controls home (HEMS compatible) devices. There may be.

  The first communication adapter 71 may have a function corresponding to the controller described above. Thereby, the 1st communication adapter 71 can control an apparatus based on the power consumption in each of a some electric circuit.

  The second communication adapter 72 has a function of communicating with a power meter (not shown) having a communication function. The second communication adapter 72 is mechanically coupled to and electrically connected to the first communication adapter 71. In the present embodiment, the first communication adapter 71 and the second communication adapter 72 are connected by a board-to-board connection with a part of each of the first communication adapter 71 and the second communication adapter 72 overlapping in the front-rear direction. Therefore, a part of the sixth space to which the first communication adapter 71 is attached also serves as an attachment space for the second communication adapter 72.

  The power meter here is a so-called smart meter, which measures the amount of power used by consumers and enables remote meter reading by communicating with a concentrator (not shown) connected to the distribution line. To do. Furthermore, request information, which is a request for suppressing power consumption, may be transmitted from a power company that is a supply company or a server operated by a power saving company to each customer's power meter. . The power meter can send a measured value (power consumption), request information, and the like to the second communication adapter 72 through communication with the second communication adapter 72.

  The 3rd communication adapter 73 is a communication function with the energy management apparatus (not shown) which consists of at least 1 of the power converter electrically connected to a gas meter, a water meter, a solar power generation device, an electrical storage device, and an electric vehicle. have. The power conversion device here refers to both power conversion for performing unidirectional charging from the distribution board 1 side to the electric vehicle, as well as both charging and discharging of the storage battery of the electric vehicle by performing bidirectional power conversion. The structure used for may be sufficient. However, the power conversion device may be configured to transfer power to and from the storage battery, and may be configured to perform only one of charging and discharging of the storage battery.

  The third communication adapter 73 is mechanically coupled to and electrically connected to the first communication adapter 71. In this embodiment, the 1st communication adapter 71 and the 3rd communication adapter 73 are connected by the board-to-board connection in the state in which each part overlapped in the front-back direction. Therefore, a part of the sixth space in which the first communication adapter 71 is attached also serves as an attachment space for the third communication adapter 73.

  The communication method between the first communication adapter 71 and the controller may be wireless communication using radio waves such as 920 MHz band specific low power radio, Zigbee (registered trademark), Bluetooth (registered trademark), or the like. Further, the communication method between the first communication adapter 71 and the controller may be wired communication such as a wired LAN. In addition, as a communication protocol in communication between the first communication adapter 71 and the controller, for example, Ethernet (registered trademark), ECHONET (registered trademark) Lite, or the like may be used. Note that wired communication includes power line communication (PLC) that performs communication using a power line as a transmission medium.

  Similarly, an appropriate method can be applied to the communication method between the second communication adapter 72 and the power meter regardless of wireless communication or wired communication. Further, as a communication method between the third communication adapter 73 and the energy management device, an appropriate method can be applied regardless of wireless communication or wired communication.

  Further, the primary interconnection breaker (not shown) is electrically connected to the primary side terminal 21 of the main breaker 2 and is electrically connected to a distributed power source (not shown) that allows reverse power flow to the power system. Connected to. As this type of distributed power source, for example, there is a solar power generation device. In addition, so-called creation cooperation, where the solar power generation device and the power storage device are integrated to store the generated power of the solar cell in the storage battery and supply the power of the storage battery to the device connected to the distribution board 1. The system may be connected to the primary interconnection breaker as a distributed power source.

  The primary interconnection breaker is electrically connected between the primary side of the main breaker 2 and the distributed power source. As a result, the primary grid breaker disconnects (disconnects) the distributed power source from the power system, for example, when the power supply from the system power source stops or when an abnormality occurs in the system power source or the distributed power source. Operate. The primary interconnection breaker has a primary side terminal (not shown) and a secondary side terminal (not shown), and the primary side terminal is electrically connected to the primary side terminal 21 of the main breaker 2, A distributed power source is connected to the secondary terminal. The primary interconnection breaker is 3P3E (number of poles 3, number of elements 3), and the dimension in the left-right direction is a size corresponding to a plurality of (three) branch breakers 3.

  The secondary interconnection breaker 8 is electrically connected to the conductive bars 41, 42, and 43, and is electrically connected to a distributed power source (not shown) that is not allowed to flow backward to the power system. Examples of this type of distributed power source include a fuel cell, a gas power generation device, and a power storage device. The secondary interconnection breaker 8 is electrically connected between the secondary side terminal of the main breaker 2 and the distributed power supply. Thereby, the secondary interconnection breaker 8 disconnects (disconnects) the distributed power source from the power system, for example, when the power supply from the system power source is stopped or when an abnormality occurs in the system power source or the distributed power source. To work.

  Similar to the branch breaker 3, the secondary interconnection breaker 8 has a primary side terminal (not shown) and a secondary side terminal 81, and the primary side terminal is electrically connected to the conductive bars 41, 42, 43. The distributed power source is connected to the secondary side terminal 81. The secondary interconnection breaker 8 is a breaker having 3P3E (number of poles 3, number of elements 3) and having a size in the left-right direction corresponding to a plurality of (three) branch breakers 3. In the example of FIG. 2, the secondary interconnection breaker 8 is replaced with the third branch breakers 3, 3, 3 from the right among the plurality of branch breakers 3, 3. And attached to the cabinet body 11. That is, the secondary interconnection breaker 8 is attached to a part of the second space below the partition wall 133.

<Feature configuration>
The cabinet 10 for the distribution board according to the present embodiment includes a first voltage electrode and a first voltage electrode among the first voltage electrode conductive bar 41, the second voltage electrode conductive bar 42, and the neutral electrode conductive bar 43. The configuration described below is adopted for the conductive bars 41 and 42 of the two voltage electrodes. The first voltage electrode conductive bar 41 and the second voltage electrode conductive bar 42 have the same basic configuration and adopt a shape that is substantially symmetrical in the vertical direction. Therefore, in the following description, the conductive bar 41 and the conductive bar 42 will be described by paying attention to the conductive bar 42 of the second voltage electrode, but unless otherwise specified, the configuration of the conductive bar 42 of the second voltage electrode is the first. This is also common to the conductive bar 41 of the voltage electrode.

  As shown in FIG. 1, the conductive bar 42 includes a first lane 422 and a second lane 423 arranged in the short direction (vertical direction) of the conductive bar 42. The first lane 422 and the second lane 423 are arranged in the order of the first lane 422 and the second lane 423 from the connection terminals 421, 421. The first lane 422 is configured such that the electrical resistance to the current flowing in the longitudinal direction of the conductive bar 42 is higher than that of the second lane 423.

  Specifically, in the conductive bar 42, the flat plate 424 is divided into a first lane 422 and a second lane 423 in the short direction of the flat plate 424. However, the first lane 422 and the second lane 423 are not physically separated, but are integrally formed from a single metal plate. Here, a plurality of through holes 426, 426... Are formed at equal intervals on the boundary line between the first lane 422 and the second lane 423. That is, in the conductive bar 42, a region of the flat plate 424 closer to the partition wall 133 (upper side) than the plurality of through holes 426, 426,... Constitutes the first lane 422, and the plurality of through holes 426, 426,. A region on the opposite side (lower side) to the first lane 422 constitutes the second lane 423.

  A mounting hole 427 for fixing the conductive bar 42 to the base table 13 is formed in the second lane 423. Further, a connection hole 428 for connecting a secondary terminal of the main breaker 2 is formed at the end of the first lane 422 on the main breaker 2 side (left side) in the longitudinal direction of the conductive bar 42. .

  Here, the first lane 422 has a high resistance portion 420 having a higher electrical resistivity than the second lane 423 between a pair of adjacent connection terminals 421, 421 of the plurality of connection terminals 421, 421. doing. As a result, the first lane 422 has a higher electrical resistance to the current flowing in the longitudinal direction of the conductive bar 42 than the second lane 423. That is, in the first lane 422, a plurality of high resistance portions 420, 420... Are formed at equal intervals in the longitudinal direction (left-right direction) of the flat plate 424. Each of the plurality of high resistance portions 420, 420... Is formed between a pair of adjacent connection terminals 421, 421 among the plurality of connection terminals 421, 421.

  Here, although the high resistance part 420 may be provided between all the adjacent pairs of connection terminals 421 and 421, this configuration is not essential. That is, the high resistance part 420 does not need to be provided one-on-one with respect to all the connection terminals 421, 421,. In the present embodiment, the connection terminal 421 protruding downward and the connection terminal 421 protruding upward are taken as one set, and one high resistance portion 420 is provided for each set of connection terminals 421 and 421.

  In the present embodiment, the high resistance portion 420 is a hole that penetrates the conductive bar 42 in the thickness direction. More specifically, the high resistance section 420 is cut from the edge of the first lane 422 in the short-side connection terminals 421, 421... (Upper side) toward the edge of the second lane 423 (lower side). It consists of a slit. The high resistance portion 420 is long in the short direction of the first lane 422, and the width dimension thereof is set smaller than the interval between the pair of adjacent connection terminals 421 and 421. As described above, the high resistance portion 420 including the holes is naturally higher in electrical resistivity than the metal material constituting the second lane 423 when the hole is filled with air.

  In the first lane 422, the area of the cross section perpendicular to the left-right direction is smaller in the portion where the high resistance portion 420 is formed in the longitudinal direction (left-right direction) of the conductive bar 42 than in other portions. Therefore, the first lane 422 has a higher electrical resistance to the current flowing in the longitudinal direction of the conductive bar 42 than the second lane 423.

  The high resistance portion 420 is formed at each position where the conductive bar 42 is abutted against the plurality of partitions 134, 134... With the conductive bar 42 attached to the base table 13 (see FIG. 4). That is, the positions of the high resistance portions 420 and the partitions 134 are aligned in the left-right direction. Therefore, each of the plurality of branch breakers 3, 3... Is arranged between a pair of adjacent high resistance portions 420, 420, respectively.

  In the example of FIG. 1, the high resistance portion 420 is formed over substantially the entire width between both ends of the first lane 422 in the short direction. However, the high resistance portion 420 is not limited to this example. The hole may be formed in at least a part of 422 in the short direction. That is, the high resistance part 420 may be, for example, a round hole formed in the center of the first lane 422 in the short direction.

  In addition, since the conductive bar 41 of the first voltage electrode and the conductive bar 42 of the second voltage electrode adopt a shape that is substantially symmetrical in the vertical direction as described above, the conductive bar 41 is Although the bottom is reversed, the basic configuration is common to the conductive bar 42.

  That is, the conductive bar 41 includes a first lane 412 and a second lane 413, and the first lane 412 has an electric resistance higher than that of the second lane 413 with respect to the current flowing in the longitudinal direction of the conductive bar 41. It is configured. Further, a plurality of through holes 416, 416,... Are formed at equal intervals on the boundary line between the first lane 412 and the second lane 413.

  The second lane 413 is formed with an attachment hole 417 for fixing the conductive bar 41 to the base table 13. Further, a connection hole 418 for connecting a secondary terminal of the main breaker 2 is formed at the end of the first lane 412 on the main breaker 2 side (left side) in the longitudinal direction of the conductive bar 41. .

  The first lane 412 has a high resistance portion 410 having a higher electrical resistance than the second lane 413 between a pair of adjacent connection terminals 411, 411 of the plurality of connection terminals 411, 411. As a result, the first lane 412 has a higher electrical resistance to the current flowing in the longitudinal direction of the conductive bar 41 than the second lane 413. In the present embodiment, the high resistance portion 410 is a hole that penetrates the conductive bar 41 in the thickness direction.

<Effect>
According to the distribution board cabinet 10 of the present embodiment described above, the conductive bar 42 includes the first lane 422 and the second lane 423 arranged in the short direction. Of the first lane 422 and the second lane 423, the first lane 422 on the side of the plurality of connection terminals 421, 421,... Has a higher electrical resistance to the current flowing in the longitudinal direction of the conductive bar 42 than the second lane 423. It is configured as follows.

  Here, the main breaker 2 is connected to one end of the conductive bar 42 in the longitudinal direction, and a plurality of branch breakers 3, 3... Are connected to each of the plurality of connection terminals 421, 421. The total current flowing through the breakers 3, 3... Passes through the conductive bar 42. However, since the electrical resistance to the current flowing in the longitudinal direction of the conductive bar 42 is lower in the second lane 423 than in the first lane 422, the current flowing through the conductive bar 42 is in the second lane 423 than in the first lane 422. It becomes easy to flow.

  Therefore, the conductive bar 42 having the above-described configuration can cause a current to flow intensively to the second lane 423 on the side opposite to the plurality of connection terminals 421, 421,. It can be formed at a position away from the terminals 421, 421. In other words, the conductive bar 42 can keep the main current path away from the plurality of connection terminals 421, 421, ... by diverting the current to the second lane 423 side. As a result, even if the total current flowing through the plurality of branch breakers 3, 3... Increases, the magnetic field generated around the conductive bar 42 due to this current acts on the plurality of connection terminals 421, 421. It becomes difficult to do.

  FIG. 6 schematically shows the current flowing through the conductive bar 42. A main current I1 flows through the conductive bar 42 mainly along the longitudinal direction of the conductive bar 42, and a part of the main current I1 is branched to the branch breaker 3 as a branch current I2. The first lane 422 and the second lane 423 are set in the conductive bar 42, but the current flowing in the longitudinal direction of the conductive bar 42 is easier to pass through the second lane 423 than the first lane 422. The main current I1 flows mainly to the second lane 423.

  That is, a portion of the conductive bar 42 that is closer to the plurality of connection terminals 421, 421,... (Leftward in FIG. 6) in the short direction of the conductive bar 42 is formed with the high resistance portion 420 and becomes the first lane 422. Therefore, the main current I1 is located on the opposite side of the plurality of connection terminals 421, 421... In the short direction of the conductive bar 42 (rightward in FIG. 6), that is, the second lane 423 where the high resistance portion 420 is not formed. Will flow mainly. Then, a part of the main current I1 flowing through the second lane 423 is branched, and flows to the branch breaker 3 via the first lane 422 and the connection terminal 421 as the branch current I2.

  Similarly, with respect to the conductive bar 41 as well, a current can be intensively passed through the second lane 413 that is opposite to the plurality of connection terminals 411, 411,. 411, 411... In other words, the conductive bar 41 can keep the main current path away from the plurality of connection terminals 411, 411, ... by diverting the current to the second lane 413 side. As a result, even if the total current flowing through the plurality of branch breakers 3, 3... Increases, the magnetic field generated around the conductive bar 41 due to this current acts on the plurality of connection terminals 411, 411. It becomes difficult to do.

  In short, the distribution board cabinet 10 of the present embodiment has an advantage that the magnetic field generated when a current flows through the conductive bar 41 (42) hardly acts on the connection terminals 411, 411 (421, 421 ...). is there.

  .. (421, 421...), The current flowing through each of the plurality of connection terminals 411, 411... (421, 421. It is preferable that the current measuring device 5 to be measured is attached. According to this configuration, the magnetic field generated when a current flows through the conductive bar 41 (42) is less likely to affect the current measuring instrument 5. Therefore, the current measuring instrument 5 becomes less susceptible to the influence of the external magnetic field when measuring the current flowing through each of the plurality of connection terminals 411, 411... (421, 421...), And the measurement accuracy is improved.

  Further, as in the present embodiment, the first lane 412 (422) is between a pair of adjacent connection terminals 411, 411 (421, 421) among a plurality of connection terminals 411, 411 (421, 421 ...). Further, it is preferable that the high resistance portion 410 (420) is formed. The high resistance portion 410 (420) has a higher electrical resistance than the second lane 413 (423). As a result, the first lane 412 (422) has a high electrical resistance to the current flowing in the longitudinal direction of the conductive bar 41 (42).

  According to this configuration, the first lane 412 (422) has a high electrical resistance to a current flowing in the longitudinal direction of the conductive bar 41 (42) due to the locally formed high resistance portion 410 (420). Therefore, the first lane 412 (422) is connected to the second lane 413 (423) without connecting the high resistance portion 410 (420) between the second lane 413 (423) and the connection terminal 411 (421). Loss of current flowing between the terminals 411 (421) can be reduced. That is, it is conceivable that the entire first lane 412 (422) is made of a material having a higher electrical resistivity than the second lane 413 (423), but in this case, the second lane 413 (423). -A loss occurs in the current flowing between the connection terminals 411 (421). On the other hand, according to the configuration of the present embodiment, portions other than the high resistance portion 410 (420) have the same electrical resistivity as the second lane 413 (423) even in the first lane 412 (422). Therefore, the loss can be kept small.

  Moreover, it is preferable that the high resistance part 410 (420) is a hole penetrating the conductive bar 41 (42) in the thickness direction as in the present embodiment. According to this configuration, the conductive bar 41 (42) can be formed by one member without using materials having different electric resistivity, and thus the manufacturing cost can be kept low.

  Further, the distribution board 1 according to the present embodiment includes a distribution board cabinet 10, a main breaker 2 electrically connected to the conductive bars 41, 42, and a plurality of connection terminals 411, 411 (421, 421). Are provided with a plurality of branch breakers 3, 3... Electrically connected to each of. According to this configuration, the distribution board 1 has an advantage that a magnetic field generated when a current flows through the conductive bar 41 (42) hardly acts on the connection terminals 411, 411 (421, 421, ...).

  By the way, in this embodiment, among the three conductive bars 41, 42, 43, only the first and second voltage electrode conductive bars 41, 42 are provided in the first lane 412 (422) and the second lane 413 ( 423) is shown, but the present invention is not limited to this configuration. That is, the first lane and the second lane may also be set for the neutral electrode bar 43. In this case, also for the neutral electrode bar 43, as in the case of the conductive bars 41 and 42 of the present embodiment, the main current path is diverted to the second lane so that the main current path is connected to the connection terminals 411, 411. 421...). As a result, even if the total current flowing through the plurality of branch breakers 3, 3... Increases, the magnetic field generated around the neutral pole bar 43 due to this current is applied to the plurality of connection terminals 421, 421. It becomes difficult to influence.

  The neutral pole bar 43 is connected to the branch breaker 3 on both sides in the short direction, so the second lane is formed in the center in the short direction, and the first lane is formed on both sides of the second lane. It is preferred that That is, it is preferable that the neutral electrode bar 43 is formed with high resistance portions at both ends in the short direction and the first lane is set.

(Embodiment 2)
In the distribution board cabinet 10 according to the present embodiment, as shown in FIG. 7, the high resistance portion 410 (420) has a smaller thickness dimension of the conductive bar 41 (42) than the second lane 413 (423). It differs from the distribution board cabinet 10 of the first embodiment in that it is a thin portion. Hereinafter, the same configurations as those of the first embodiment are denoted by common reference numerals, and description thereof is omitted as appropriate.

  That is, in the present embodiment, the high resistance portion 410 is not a hole penetrating the conductive bar 41 in the thickness direction, but a thin portion having a thickness dimension smaller than that of the portion other than the high resistance portion 410 of the conductive bar 41. Similarly for the conductive bar 42, the high resistance portion 420 is not a hole penetrating the conductive bar 42 in the thickness direction, but is a thin portion having a thickness dimension smaller than that of the portion other than the high resistance portion 420 of the conductive bar 42.

  The first lane 412 (422) has a cross-sectional area perpendicular to the left-right direction at the portion where the thin high resistance portion 410 (420) is formed in the longitudinal direction (left-right direction) of the conductive bar 41 (42). It becomes smaller than the part of. Therefore, the first lane 412 (422) has a higher electrical resistance to the current flowing in the longitudinal direction of the conductive bar 41 (42) than the second lane 413 (423).

  According to this configuration, the conductive bar 41 (42) has an advantage that the rigidity can be kept high compared to the case where the high resistance portion 410 (420) is a hole.

  Other configurations and functions are the same as those of the first embodiment.

(Embodiment 3)
In the distribution board cabinet 10 according to the present embodiment, as shown in FIG. 8, the high resistance portion 410 (420) is formed of a material having a higher electrical resistivity than the second lane 413 (423). Thus, it is different from the distribution board cabinet 10 of the second embodiment. Hereinafter, the same configurations as those of the second embodiment are denoted by common reference numerals, and the description thereof is omitted as appropriate.

  In the present embodiment, the high resistance portion 410 has the same thickness as the portion other than the high resistance portion 410 of the conductive bar 41, but is different from the portion other than the high resistance portion 410 of the conductive bar 41. Similarly, for the conductive bar 42, the high resistance portion 420 has the same thickness as the portion of the conductive bar 42 other than the high resistance portion 420, but is different from the portion of the conductive bar 42 other than the high resistance portion 420. .

  The first lane 412 (422) has a higher electrical resistivity at the location where the different high resistance portion 410 (420) is formed in the longitudinal direction (left-right direction) of the conductive bar 41 (42) than at other locations. Become. Therefore, the first lane 412 (422) has a higher electrical resistance to the current flowing in the longitudinal direction of the conductive bar 41 (42) than the second lane 413 (423).

  According to this configuration, the conductive bar 41 (42) has an advantage that the rigidity can be further increased as compared with the case where the high resistance portion 410 (420) is a thin portion.

  Other configurations and functions are the same as those of the second embodiment.

(Modification)
As a modification of each of the embodiments described above, the shape of the conductive bar 41 (42) is increased so as to increase the distance between the plurality of connection terminals 411, 411 (421, 421 ...) and the first lane 412 (422). It is possible to change. 9 and 10 exemplify the conductive bar 41 of the first voltage electrode, but since the same configuration is adopted for the conductive bar 42 of the second voltage electrode, the description of the conductive bar 42 will be described below. Is omitted.

  Specifically, as shown in FIG. 9, for example, the conductive bar 41 has a first lane 412 extending rearward from the rear end of the protruding piece 415, a front end extending upward, and a front end extending frontward. It is formed in a substantially C shape. Thereby, the electrically conductive bar 41 can widen the space | interval in the front-back direction of several connection terminal 411,411, ... and the 1st lane 412. FIG.

  According to this configuration, the magnetic field generated due to the current flowing through the conductive bar 41 is less likely to act on the connection terminals 411, 411,. That is, basically, the conductive bar 41 can flow current intensively in the second lane 413 on the opposite side to the plurality of connection terminals 411, 411. However, current does not flow. The shape of the conductive bar 41 as shown in FIG. 9 makes it difficult for the magnetic field generated due to the current flowing through the first lane 412 to act on the connection terminals 411, 411.

  As another example, as shown in FIG. 10, the conductive bar 41 has a first lane 412 extending rearward from the rear end of the protruding piece 415, and its front end extending upward to form a substantially L shape. May be. As a result, the conductive bar 41 increases not only the distance between the plurality of connection terminals 411, 411, and the first lane 412 in the front-rear direction, but also the distance between the plurality of connection terminals 411, 411, and the second lane 413. Can do.

  According to this configuration, the conductive bar 41 has a magnetic field generated due to the current flowing through the second lane 413 because the distance between the second lane 413 and the connection terminals 411, 411,. It becomes difficult to act on the connection terminals 411, 411. As a result, the magnetic field generated due to the current flowing through the conductive bar 41 is less likely to act on the connection terminals 411, 411,.

  In addition, the structure of a modification can be combined with each of Embodiment 1-3.

1 distribution board 10 cabinet for distribution board 11 cabinet body 2 main breaker 3 branch breaker 41, 42 conductive bar 410, 420 high resistance part 411, 421 connection terminal 412, 422 1st lane 413, 423 2nd lane 5 current measurement vessel

Claims (7)

The cabinet body,
A conductive bar fixed to the cabinet body and forming a power path from the main breaker to the plurality of branch breakers;
The conductive bar has a plurality of connection terminals arranged in the longitudinal direction of the conductive bar at one end portion in the short direction of the conductive bar, and the main breaker is electrically connected to one end portion in the longitudinal direction of the conductive bar. Each of the plurality of branch breakers can be electrically connected to each of the plurality of connection terminals,
The conductive bar includes a first lane and a second lane arranged in a short direction of the conductive bar,
The first lane and the second lane are arranged in the order of the first lane and the second lane from the plurality of connection terminal sides,
The first lane is configured such that an electrical resistance to a current flowing in a longitudinal direction of the conductive bar is higher than that of the second lane. The distribution board cabinet according to claim 1, wherein a current measuring device that measures a current flowing through each of the plurality of connection terminals based on magnetic flux is attached to the plurality of connection terminals. In the first lane, a high resistance portion having a higher electrical resistivity than the second lane is formed between a pair of adjacent connection terminals among the plurality of connection terminals, thereby increasing the length of the conductive bar. The distribution board cabinet according to claim 1 or 2, wherein an electrical resistance to a current flowing in a direction is increased. The distribution board cabinet according to claim 3, wherein the high resistance portion is a hole penetrating the conductive bar in a thickness direction. The distribution panel cabinet according to claim 3, wherein the high resistance portion is a thin portion in which a thickness dimension of the conductive bar is smaller than that of the second lane. The distribution board cabinet according to claim 3, wherein the high resistance portion is made of a material having a higher electrical resistivity than the second lane. A cabinet for a distribution board according to any one of claims 1 to 6,
The main breaker electrically connected to the conductive bar;
The distribution board comprising: the plurality of branch breakers electrically connected to each of the plurality of connection terminals.

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