JP6979616B2 - Measurement unit, expansion unit, measurement system and distribution board system - Google Patents

Description

The present disclosure generally relates to measurement units, expansion units, measurement systems and distribution board systems. More specifically, the present disclosure describes a measurement unit for measuring a physical quantity related to electricity passing through an electric circuit, an expansion unit for adding an expansion function to the measurement unit, a measurement system including a measurement unit and an expansion unit, a measurement unit, and a distribution board. Regarding a distribution board system equipped with a board.

Conventionally, a distribution board system including a distribution board and a power measuring device is known (see, for example, Patent Document 1).

The distribution board of Patent Document 1 includes a main breaker, a plurality of branch breakers, and a current sensor (CT: Current Transformer). The main circuit breaker supplies power to each branch breaker through the first voltage line (L1), the second voltage line (L2), and the neutral line (N). The branch breaker corresponding to the L1 phase is connected to the first voltage line and the neutral line. The branch breaker corresponding to the L2 phase is connected to the second voltage line and the neutral line. A total of 30 branch breakers are provided, 15 for each phase. The electric power from the branch breaker is supplied to each power supply target (load).

The current sensor corresponding to the L1 phase detects the current supplied from the corresponding branch breaker to the power supply target, and outputs the detection result to the power measuring device (L1 terminal) via the cable. The current sensor corresponding to the L2 phase detects the current supplied from the corresponding branch breaker to the power supply target, and outputs the detection result to the power measuring device (L2 terminal) via the cable.

The power measuring device acquires the detection result of the current sensor through the L1 and L2 terminals, and measures the power consumption based on the detection result.

Japanese Unexamined Patent Publication No. 2014-79115

The power measuring device described in Patent Document 1 has both an L1 terminal and an L2 terminal in advance so that all the detection results from the current sensors corresponding to the 30 branch breakers can be received. That is, the power measuring device of Patent Document 1 can be connected to more current sensors than the number of current sensors actually required depending on the usage environment, and even unnecessary functions are provided in advance depending on the usage environment. It will be.

The present disclosure has been made in view of the above reasons, and an object of the present invention is to provide a measurement unit, an expansion unit, a measurement system, and a distribution board system whose functions can be expanded according to the usage environment.

The measurement unit according to one aspect of the present disclosure includes a measurement unit, a housing, and an arrangement space. The measuring unit measures the physical quantity based on the signal from the sensor that outputs a signal corresponding to the physical quantity related to the electricity passing through the electric circuit. The housing houses the measuring unit. The arrangement space is a space for arranging an expansion unit to which an expansion function is added. The housing has one surface. The housing has a covering portion that covers at least a part of the expansion unit arranged in the arrangement space when viewed from the front of the one surface. The expansion unit has an expansion board and a terminal portion mounted on the expansion board and connected to an external device. The covering portion overlaps with at least a part of the expansion board of the expansion unit arranged in the arrangement space when viewed from the front of the one surface. When viewed from the front of the one surface, the terminal portion of the expansion unit arranged in the arrangement space is exposed.
The measurement unit according to one aspect of the present disclosure includes a measurement unit, a housing, and an arrangement space. The measuring unit measures the physical quantity based on the signal from the sensor that outputs a signal corresponding to the physical quantity related to the electricity passing through the electric circuit. The housing houses the measuring unit. The arrangement space is a space for arranging an expansion unit to which an expansion function is added. The housing has one surface. The housing has a covering portion that covers at least a part of the expansion unit arranged in the arrangement space when viewed from the front of the one surface. The electric circuit is composed of a plurality of electric lines. The sensor includes a plurality of sensors. The expansion unit is connected to at least a part of the plurality of sensors to receive a signal from the at least a part of the sensor, and is connected to the measurement unit to receive the input terminal part. It has an output terminal unit that outputs the signal received in the above to the measurement unit.
The measurement unit according to one aspect of the present disclosure includes a measurement unit, a housing, an arrangement space, and a mounting board. The measuring unit measures the physical quantity based on the signal from the sensor that outputs a signal corresponding to the physical quantity related to the electricity passing through the electric circuit. The housing houses the measuring unit. The arrangement space is a space for arranging an expansion unit to which an expansion function is added. An operation circuit component for accepting a manual operation is mounted on the mounting board and is housed in the housing. The housing has one surface. The housing has a covering portion that covers at least a part of the expansion unit arranged in the arrangement space when viewed from the front of the one surface. The covering portion houses at least a part of the mounting board inside the covering portion.

The expansion unit according to one aspect of the present disclosure adds the expansion function to the measurement unit.

The measurement system according to one aspect of the present disclosure includes the measurement unit and the expansion unit.

The distribution board system according to one aspect of the present disclosure includes the measurement unit and the distribution board having the electric circuit.

The measurement unit, extension unit, measurement system and distribution board system of the present disclosure have an advantage that their functions can be expanded according to the usage environment.

FIG. 1 is a perspective view of a measurement unit, an extension unit, a unit cover, and a mounting base according to an embodiment of the present disclosure. FIG. 2 is a perspective view of the measurement unit and the expansion unit as seen from the rear. FIG. 3 is a front view of the same measurement unit. FIG. 4 is a side view of the same measurement unit. FIG. 5 is a rear view of the same measurement unit. FIG. 6 is a perspective view of the measurement unit as seen from the front with the cover removed. FIG. 7 is a perspective view seen from the rear in a state where the expansion unit is attached to the measurement unit of the same. FIG. 8 is a front view showing a state in which an expansion unit is attached to the same measurement unit. FIG. 9 is a side view showing a state in which an expansion unit is attached to the same measurement unit. FIG. 10 is a rear view showing a state in which an expansion unit is attached to the same measurement unit. FIG. 11 is a cross-sectional view taken along the line AA of FIG. FIG. 12 is a schematic diagram of a distribution board system including the same measurement unit and distribution board. FIG. 13 is a block diagram of the same measurement unit and expansion unit.

FIGS. 1 to 13 described in the following embodiments and the like are schematic views, and the ratio of the size and the thickness of each component in FIGS. 1 to 13 does not necessarily reflect the actual dimensional ratio. Not always.

(1) Overview As shown in FIG. 12, the measurement unit 1 (and the expansion unit 2) according to the present embodiment constitutes the distribution board system 5 together with the distribution board 4, and the electric circuit (main trunk) in the distribution board 4. It is used to measure physical quantities related to electricity passing through a circuit and / or a branch circuit). The measurement unit 1 of the present embodiment is particularly used for measuring the current flowing through the measurement points set in the electric circuit in the distribution board 4.

The measurement unit 1 of the present embodiment acquires a signal corresponding to the current value from the current sensor (CT) 8 provided in the electric circuit (measurement point) and measuring the current flowing through the electric circuit. The measuring unit 1 obtains a current (for example, a current waveform, an effective value, etc.) flowing through (a measurement point) of an electric circuit corresponding to the current sensor 8 based on a signal acquired from the current sensor 8. The measuring unit 1 may obtain the electric power passing through each electric circuit by using the current value acquired from the current sensor 8 and the voltage value of each electric circuit acquired from the voltage sensor (not shown).

In the present embodiment, the measurement unit 1 includes a main input terminal unit 1501 and a branch input terminal unit 1502. The main trunk input terminal unit 1501 can be connected to the main trunk current sensor (main trunk CT) 81 for measuring the main trunk current flowing through the main trunk circuit (measurement point set in) of the distribution board 4 via a cable 9. .. The branch input terminal unit 1502 is provided with eight input terminals, and is connected to eight branch current sensors (branch CT) 82 for measuring the branch current flowing through each of the eight branch circuits (measurement points set in). It is possible to connect via 9.

The measuring unit 1 acquires a signal (current value) from the main current sensor 81 connected to the main input terminal unit 1501. Further, the measurement unit 1 acquires a signal (current value) from each branch current sensor 82 connected to the branch input terminal unit 1502. That is, the measurement unit 1 connects the main trunk current sensor 81 to the main trunk input terminal unit 1501 and connects the eight branch current sensors 82 to the branch input terminal unit 1502 to form a main trunk circuit and eight branch circuits. It is possible to obtain the current flowing through (measurement points) of a total of nine electric circuits.

Further, the measurement unit 1 according to the present embodiment constitutes the measurement system 3 together with the expansion unit 2.

The expansion unit 2 adds an expansion function to the measurement unit 1. In the present embodiment, the expansion unit 2 has a function of increasing the number of current sensors 8 that can be connected to the measurement unit 1 as an expansion function.

Specifically, the expansion unit 2 includes three input terminal portions 21. Each input terminal portion 21 can be connected to 10 branch current sensors (branch CT) 82 for measuring the branch current flowing through the 10 branch circuits (measurement points set in) via a cable. .. That is, the expansion unit 2 can acquire signals (current values) from a total of 30 current sensors 8.

Further, the expansion unit 2 further includes an output terminal unit 22, and the measurement unit 1 further includes a connection terminal unit 1503 connected to the output terminal unit 22 (via a cable). The expansion unit 2 outputs a signal (current value) acquired from the current sensor 8 via each input terminal unit 21 to the measurement unit 1 from the output terminal unit 22. The measuring unit 1 obtains a current (current waveform, effective value, etc.) flowing through the corresponding electric circuit from the signal (current value) received from the expansion unit 2 by the connection terminal unit 1503.

As a result, it is possible to increase the number of current sensors 8 that can be connected to the measurement unit 1, and it is possible to increase the number of electric circuits (measurement points) that can measure current by the measurement unit 1.

The number of current sensors 8 to be connected to the measurement unit 1 is equal to or less than the number of current sensors 8 that can be connected to the input terminal portions (main trunk input terminal portion 1501 and branch input terminal portion 1502) of the measurement unit 1. For example, the expansion unit 2 is unnecessary. That is, the user may retrofit the expansion unit 2 when the number of electric circuits (measurement points) for which the current should be measured exceeds the number that can be handled by the measurement unit 1 alone.

(2) Details Hereinafter, the measurement unit 1, the expansion unit 2, the measurement system 3, the distribution board 4, and the distribution board system 5 according to the present embodiment will be described in detail with reference to FIGS. 1 to 13.

(2.1) Measurement Unit First, the measurement unit 1 of the present embodiment will be described with reference to FIGS. 1 to 6, 11 and 13.

As shown in FIG. 13, the measurement unit 1 includes a measurement unit 11, an operation unit 12, a communication unit 13, and a power supply in addition to the main input terminal unit 1501, the branch input terminal unit 1502, and the connection terminal unit 1503. A unit 14 is provided.

The measuring unit 11 performs arithmetic processing of the signal (measured value) acquired from each current sensor 8 to obtain the current flowing through the electric circuit (measurement point) corresponding to the current sensor 8. The operation unit 12 accepts a manual operation by the user. The communication unit 13 has a wireless communication function in the present embodiment, and wirelessly transmits and receives information such as a current obtained by the measurement unit 11 to and from an external device. The power supply unit 14 converts the electric power obtained from an external power source (system power supply, etc.) into the operating power of the measurement unit 11, the operation unit 12, and the communication unit 13, and causes the measurement unit 11, the operation unit 12, and the communication unit 13. Supply.

Further, the measurement unit 1 includes a housing 10 that houses the measurement unit 11, the operation unit 12, the communication unit 13, and the power supply unit 14. As shown in FIG. 2, the housing 10 is configured by combining two members, a body 111 and a cover 112. Further, as shown in FIGS. 6 and 11, the measurement unit 1 further includes a mounting board 16 and a power supply board 17. The mounting board 16 and the power supply board 17 are housed in the housing 10. Here, the measurement unit 11, the operation unit 12, and the communication unit 13 each have a plurality of circuit components (a plurality of measurement circuit components 110, a plurality of operation circuit components 120, and a plurality of communication circuit components 130) mounted on the mounting board 16. ). The power supply unit 14 is composed of a plurality of circuit components (plurality of power supply circuit components 140) mounted on the power supply board 17.

As shown in FIGS. 2 to 6 and 11, the housing 10 has a hollow rectangular parallelepiped shape that is long in one direction. The measuring unit 1 is attached to, for example, a building material (for example, gypsum board) so that the longitudinal direction of the housing 10 is along the vertical direction and the body 111 faces the building material.

In the following, the direction (orthogonal) perpendicular to the horizontal plane (longitudinal direction of the housing 10) with the measuring unit 1 attached to the construction material is defined as the "vertical direction", and the downward direction (vertical direction) is defined as "vertical direction". It will be explained as "downward". Further, the direction orthogonal to the vertical direction, in which the body 111 and the cover 112 in the housing 10 are combined (the thickness direction of the housing 10) is defined as the "front-back direction", and the direction from the body 111 to the cover 112. Is described as "forward". Further, the direction orthogonal to both the vertical direction and the front-rear direction (width direction of the housing 10) is defined as the "left-right direction", and when the housing 10 is viewed from the front, the right side is "right" and the left side is "left". I will explain it as "one". It should be noted that the arrows indicating the "vertical direction", the "front-back direction", and the "horizontal direction" in the drawings are shown only for the sake of explanation and are not accompanied by an entity. Further, these directions are not intended to limit the usage mode of the measurement unit 1.

The housing 10 is made of, for example, a synthetic resin. As described above, the housing 10 is configured by combining the body 111 and the cover 112 in the front-rear direction. The front surface of the body 111 is open, and the rear surface of the cover 112 is open. The body 111 and the cover 112 are coupled in the front-rear direction so as to align the openings with each other. As a result, a storage space for accommodating the mounting board 16 and the power supply board 17 is formed inside the housing 10. The body 111 and the cover 112 are connected to each other by screwing.

The housing 10 has one surface (first surface) and another surface (second surface) on both sides in the front-rear direction (thickness direction). The first surface is the front surface of the cover 112, and constitutes the front surface of the housing 10. The second surface is the rear surface of the body 111 and constitutes the rear surface of the housing 10.

As shown in FIGS. 2 to 5 and 11, the housing 10 is composed of a first block 113, a second block 114, and a third block 115. The first block 113, the second block 114, and the third block 115 are arranged in this order from the upper side in the longitudinal direction (vertical direction) of the housing 10. Each of the first block 113, the second block 114 and the third block 115 is a part of the housing 10.

As shown in FIG. 11, the first block 113 has a hollow rectangular parallelepiped shape and has an opening in the front portion of the lower surface.

As shown in FIG. 11, the second block 114 has a hollow rectangular parallelepiped shape and has openings on the upper surface and the lower surface. The edge of the opening on the upper surface of the second block 114 is connected to the edge of the opening on the lower surface of the first block 113. That is, the first block 113 and the second block 114 are continuous in the vertical direction, and the internal space of the first block 113 and the internal space of the second block 114 are connected in the vertical direction. The front surface of the second block 114 is continuous with the front surface of the first block 113. On the other hand, the rear surface of the second block 114 is in front of the rear surface of the first block 113. That is, the dimension in the front-rear direction of the second block 114 (the dimension of the second block 114 in the thickness direction of the housing 10) is smaller than the dimension in the front-rear direction of the first block 113.

As shown in FIG. 11, the third block 115 has a hollow rectangular parallelepiped shape having an inclined surface on the lower front side, and has an opening on the front side portion of the upper surface. The edge of the opening on the upper surface of the third block 115 is connected to the edge of the opening on the lower surface of the second block 114. That is, the second block 114 and the third block 115 are continuous in the vertical direction, and the internal space of the second block 114 and the internal space of the third block 115 are connected in the vertical direction. The front surface of the third block 115 is continuous with the front surface of the second block 114. On the other hand, the rear surface of the third block 115 is behind the rear surface of the second block 114.

Then, as shown in FIG. 2, it is surrounded by the lower surface (rear side portion) of the first block 113, the rear surface of the second block 114, and the upper surface (rear side portion) of the third block 115. Space 100 is formed. Space 100 is a rectangular parallelepiped recess. The space 100 is between the first block 113 and the third block 115 in the vertical direction when viewed from the front (the front of the first surface of the housing 10), and is behind the second block 114. .. In the present embodiment, this space 100 constitutes an arrangement space for arranging the expansion unit 2 afterwards.

Further, as shown in FIGS. 3 and 4, in the first block 113, a portion above the center on the right side of the front surface and a portion above the center on the front side of the right side surface are cut out to form an opening. Has been done. From this opening, the power supply terminal portion 171 mounted on the power supply board 17 is exposed. Further, on the front surface of the first block 113, a rectangular opening is formed below the opening. The power switch 172 mounted on the power supply board 17 is exposed from this opening. As shown in FIG. 3, on the lower left portion of the front surface of the first block 113, a protrusion 101 that advances and retreats in the front-rear direction according to a manual operation by the user is provided. Further, a semicircular protruding plate 102 having an insertion hole is formed so as to project to the right from the upper portion of the right side surface of the first block 113.

As shown in FIGS. 1, 3, and 4, eight protrusions 103 that advance and retreat in the front-rear direction in response to a manual operation by the user are provided side by side in the upper right portion of the front surface of the second block 114. .. Further, in the lower right portion (below the area where the protrusion 103 is provided) on the front surface of the second block 114, the main input terminal portion 1501 mounted on the mounting board 16, the branch input terminal portion 1502, and the connection are connected. An opening for exposing the terminal portion 1503 is formed. An opening for exposing the connector insertion hole of the LAN connector 1504 mounted on the mounting board 16 is formed in the lower left portion on the front surface of the second block 114.

As shown in FIG. 2, a substantially U-shaped groove is formed in the central portion on the rear surface of the second block 114, and a fitting claw 104 that can bend in the front-rear direction is formed so as to be surrounded by the groove. It is formed long in the vertical direction. Further, at the left end of the rear surface of the second block 114, a protruding wall 105 projecting rearward is formed along the left end of the rear surface. The protruding tip of the protruding wall 105 is flush with the rear surface of the first block 113 and the rear surface of the third block 115. A circular hole 106 that penetrates the projecting wall 105 in the left-right direction is formed in the center of the projecting wall 105 in the vertical direction.

As shown in FIGS. 1 and 11, an opening for exposing the expansion terminal portion 173 mounted on the power supply board 17 is formed on the front lower inclined surface of the third block 115.

As shown in FIG. 6, the mounting board 16 is composed of one printed circuit board in the present embodiment, the longitudinal direction thereof is along the longitudinal direction (vertical direction) of the housing 10, and the thickness direction thereof is the casing. It has a substantially rectangular plate shape along the thickness direction (front-back direction) of the body 10. The mounting board 16 has a size (one size smaller than the housing 10) that overlaps with almost the entire housing 10 when viewed from the front.

As described above, a plurality of measurement circuit components 110 constituting the measurement unit 11 are mounted on the mounting board 16. The plurality of measurement circuit components 110 include an integrated circuit 1101 for performing arithmetic processing. The plurality of measurement circuit components 110 are arranged in a region of the mounting board 16 accommodated in the first block 113 of the housing 10.

Further, as described above, a plurality of operation circuit components 120 constituting the operation unit 12 are mounted on the mounting board 16. The plurality of operation circuit components 120 include a plurality of (11 in this case) operation buttons 1201. Nine of the eleven operation buttons 1201 are located behind a total of nine protrusions 101 and 103 in the housing 10 (see FIGS. 1, 6 and 11), and the corresponding protrusions 101, It is pressed according to the user's pressing operation on 103. The plurality of operation circuit components 120 are arranged in a region accommodated in the first block 113 and a region accommodated in the second block 114 of the housing 10 on the mounting board 16.

Further, as described above, a plurality of communication circuit components 130 constituting the communication unit 13 are mounted on the mounting board 16. The plurality of communication circuit components 130 include an antenna 1301 for wireless communication. The plurality of communication circuit components 130 are arranged in a region of the mounting board 16 accommodated in the first block 113 of the housing 10.

Further, a plurality of connection circuit components 150 for connecting to an external device are also mounted on the mounting board 16. The plurality of connection circuit components 150 include the main input terminal unit 1501, the branch input terminal unit 1502, the connection terminal unit 1503, and the LAN connector 1504. The plurality of connection circuit components 150 are arranged in a region of the mounting board 16 accommodated in the second block 114 of the housing 10.

In the present embodiment, the front surface of the mounting board 16 is a component surface and the rear surface is a solder surface, and a plurality of measurement circuit components 110, a plurality of operation circuit components 120, a plurality of communication circuit components 130, and a plurality of communication circuit components 130 are provided on the front surface of the mounting board 16. A plurality of connection circuit components 150 are mounted.

As shown in FIG. 6, the power supply board 17 is composed of one printed circuit board in the present embodiment, the longitudinal direction thereof is along the longitudinal direction (vertical direction) of the housing 10, and the thickness direction thereof is the casing. It has a substantially rectangular plate shape along the thickness direction (front-back direction) of the body 10. The power supply board 17 has a size (one size smaller than the housing 10) that overlaps with almost the entire housing 10 when viewed from the front. Further, as shown in FIGS. 6 and 11, the power supply board 17 is arranged behind the mounting board 16. Further, the power supply board 17 is arranged so that at least a part thereof overlaps with the mounting board 16 when viewed from the front.

As shown in FIG. 6, the power supply terminal portion 171, the power supply switch 172, and the expansion terminal portion 173 are mounted on the power supply board 17. The power supply terminal portion 171 and the power supply switch 172 and the expansion terminal portion 173 are mounted on the front surface of the power supply board 17. The power terminal unit 171 is connected to an external power source. The power switch 172 is interposed in the electric circuit between the power supply terminal portion 171 and the power supply unit 14, and opens and closes the electric circuit between the external power supply unit and the power supply unit 14. The expansion terminal unit 173 is connected to, for example, a device for measuring energy consumption other than electric power, such as a water meter or a gas meter, and receives measurement data or the like from these devices.

Further, as shown in FIG. 11, a plurality of power supply circuit components 140 constituting the power supply unit 14 are mounted on the power supply board 17. The plurality of power supply circuit components 140 are mounted on the power supply board 17 in a region accommodated in the first block 113 of the housing 10. Further, as shown in FIGS. 4 and 10, the plurality of power supply circuit components 140 (at least a part thereof) are arranged at positions adjacent to the space 100 in the front-rear direction.

In the present embodiment, the rear surface of the power supply board 17 is a component surface and the front surface is a solder surface, and a plurality of power supply circuit components 140 constituting the power supply unit 14 are mounted on the rear surface of the power supply board 17.

As shown in FIGS. 6 and 11, in the housing 10, the mounting board 16 and the power supply board 17 are arranged in parallel with each other so that the solder surfaces face each other. The mounting board 16 and the power supply board 17 are connected to each other by a connector (not shown) arranged in the center of each board.

(2.2) Expansion Unit Next, the expansion unit 2 will be described with reference to FIGS. 1, 2, 6 to 10.

As shown in FIGS. 1, 2, and 10, the expansion unit 2 includes a housing 20 and an expansion board 23 in addition to the above three input terminal portions 21 and output terminal portions 22. The housing 20 is configured by combining two members, a body 211 and a cover 212.

The housing 20 is made of, for example, a synthetic resin. The housing 20 has a hollow rectangular parallelepiped shape, and the extension board 23 is housed inside the housing 20. As shown in FIG. 8, four openings are formed side by side in the vertical direction in the right side portion of the front surface of the housing 20, and three input terminal portions mounted on the expansion board 23 are formed from the four openings. 21 and the output terminal portion 22 are exposed. Further, as shown in FIG. 1, a fitting groove 201 into which the fitting claw 104 of the housing 10 of the measuring unit 1 is fitted is formed long in the vertical direction in the center left portion of the front surface of the housing 20. There is. Further, a cylindrical protrusion 202 is provided on the left side surface of the housing 20.

As shown in FIG. 8, the expansion board 23 is composed of one rectangular printed circuit board in the present embodiment, and three input terminal portions 21 and an output terminal portion 22 are vertically oriented along the right end thereof. It is implemented side by side.

Here, the dimensions of the housing 20 of the expansion unit 2 in the front-rear direction are substantially equal to (slightly smaller) the dimensions of the space 100 formed by the housing 10 of the measurement unit 1 in the front-rear direction. The vertical dimension of the housing 20 is substantially equal to (slightly smaller) the vertical dimension of the space 100. The left-right dimension of the housing 20 is larger than the left-right dimension of the space 100, and is larger than the left-right dimension of the housing 10.

(2.3) Installation of Expansion Unit to Measurement Unit Next, installation of the expansion unit 2 to the measurement unit 1 will be described. As described above, when it is desired to add an expansion function to the measurement unit 1, the expansion unit 2 is retrofitted to the measurement unit 1.

In the present embodiment, the expansion unit 2 can be physically attached to the measurement unit 1 so that at least a part thereof is located in the space (arrangement space) 100.

In the present embodiment, the expansion unit 2 is attached to the measurement unit 1 by being inserted into the space 100 along the width direction (left-right direction) of the measurement unit 1. Therefore, the housing 10 of the measurement unit 1 is provided with a guide mechanism for guiding the movement of the housing 20 of the expansion unit 2 in the left-right direction. In the present embodiment, the guide mechanism has three first projection pieces 107 protruding downward from the rear end edge of the lower surface of the first block 113 and three protruding upwards from the rear end edge of the upper surface of the third block 115. It is composed of a second projection piece 108 (see FIG. 2). The three first projection pieces 107 are provided side by side at the left and right ends and the center of the rear end edge of the lower surface of the first block 113. The three second projection pieces 108 are provided side by side at the left and right ends and the center of the rear end edge of the upper surface of the third block 115.

In order to attach the expansion unit 2 to the measurement unit 1, first, as shown in FIG. 2, the housing 20 of the expansion unit 2 is arranged on the right side of the housing 10 of the measurement unit 1. Then, the housing 20 is inserted between the leftmost first protrusion piece 107 and the leftmost second protrusion piece 108 of the housing 10 and the rear surface of the second block 114 of the housing 10. Then, by sliding the housing 20 to the left along the rear surface of the second block 114, the expansion unit 2 is inserted into the space 100. In the present embodiment, an inclined surface having a shape that moves away from the lower surface toward the left end is formed at the left lower end and the upper left end of the rear surface of the housing 20 of the extension unit 2. This facilitates the work of inserting the housing 20 between the leftmost protrusions 107 and 108 and the rear surface of the second block 114.

Further, in the present embodiment, the housing 10 of the measurement unit 1 has a holding structure for holding the housing 20 of the expansion unit 2 arranged in the space (arrangement space) 100. Specifically, when the expansion unit 2 is inserted into the space 100, the movement of the expansion unit 2 in the front-rear direction is restricted by the three first projection pieces 107, the three second projection pieces 108, and the second block 114. Will be done. Further, when the expansion unit 2 is inserted into the space 100, the vertical movement of the expansion unit 2 is restricted by the lower surface of the first block 113 and the upper surface of the third block 115. Further, when the expansion unit 2 is inserted into the space 100, the fitting claw 104 on the rear surface of the second block 114 of the housing 10 is fitted into the fitting groove 201 on the front surface of the housing 20, whereby the expansion unit is inserted. The movement of 2 in the left-right direction is restricted. As a result, the movement of the expansion unit 2 with respect to the measurement unit 1 is restricted while the expansion unit 2 is arranged in the space 100.

The measurement unit 1 and the expansion unit 2 are electrically connected to each other by connecting the connection terminal portion 1503 of the measurement unit 1 and the output terminal portion 22 of the expansion unit 2 with a cable. The electrical connection between the measurement unit 1 and the expansion unit 2 may be performed before or after the expansion unit 2 is attached to the measurement unit 1.

Here, in the present embodiment, the dimensions of the expansion unit 2 and the space 100 are set so that the expansion unit 2 fits in the space 100 in the vertical direction and the front-back direction. On the other hand, when the expansion unit 2 is arranged in the space 100, the expansion unit so that the right portion of the expansion unit 100 where the terminal portions (input terminal portion 21 and output terminal portion 22) are provided is exposed to the front. The width dimension (dimension in the left-right direction) of 2 is set (see FIG. 8). As a result, even after the expansion unit 2 is arranged in the space 100, it becomes easy to connect the connector or the like to the terminal portion.

Further, as shown in FIG. 8, a part of the expansion unit 2 arranged in the space 100 (a part other than the area where the input terminal portion 21 and the output terminal portion 22 are provided) is a second block when viewed from the front. Covered by 114. Further, as shown in FIGS. 8 and 11, the second block 114 overlaps with at least a part of the expansion board 23 of the expansion unit 2 arranged in the space 100 when viewed from the front. That is, in the housing 20 of the expansion unit 2, at least a part of the portion accommodating the expansion board 23 is hidden by the second block (covering portion) 114 when viewed from the front. As a result, the arrangement space 100 can be made inconspicuous, and the expansion unit 2 arranged in the arrangement space 100 can be made inconspicuous.

Further, as shown in FIG. 11, in the projection plane of the housing 10 when viewed from the front, the expansion unit 2 arranged in the space 100 is a plurality of power supply circuits mounted on the power supply board 17 of the measurement unit 1. Adjacent to at least some of the parts 140. Generally, the power supply circuit component 140 constituting the power supply unit 14 includes many circuit components having a high height (height from the substrate) such as a transformer and a capacitor. Therefore, a space for arranging the power supply circuit component 140 is required in the housing 10. In the present embodiment, by providing a space (arrangement space) 100 for arranging the expansion unit 2 adjacent to the power supply circuit component 140, the housing 10 is miniaturized and adjacent to the power supply circuit component 140. It is possible to effectively use the matching space.

To remove the expansion unit 2 from the measurement unit 1, for example, through the hole 106 provided in the protruding wall 105 of the housing 10 of the measurement unit 1, the protrusion 202 of the expansion unit 2 is inserted from the left side (with a finger, a jig, or the like). ) Just press. By doing so, the fitting claw 104 bends backward and comes off from the fitting groove 201. Therefore, by moving the extension unit 2 to the right along the first protrusion piece 107 and the second protrusion piece 108, the extension unit 2 can be moved. It can be taken out from the space 100.

(2.4) Attaching the measuring unit to the building material The measuring unit 1 is attached to the building material by using, for example, the mounting base 6 and the unit cover 7 shown in FIG.

The mounting base 6 has a rectangular plate shape that is long in the vertical direction. The mounting base 6 is attached to the building material by, for example, passing wood screws through a total of six through holes 61 provided at the four corners and the center of the mounting base 6 and screwing the wood screws to the building material.

Here, on the rear surface of the housing 10 of the measurement unit 1, a total of four hooks 109 are provided at the center and the lower positions in the vertical direction at both the left and right ends. Further, on the front surface of the mounting base 6, a total of four hooks 62 are provided at the center and lower positions in the vertical direction at both the left and right ends. Further, a screw hole 63 is formed at the upper right position on the front surface of the mounting base 600. The four hooks 109 of the housing 10 are hooked on the four hooks 62 of the mounting base 6, respectively, and the screws are passed through the insertion holes of the protruding plate 102 of the housing 10 from the front and connected to the screw holes 63 of the mounting base 6. As a result, the measurement unit 1 can be attached to the attachment base 600.

The expansion unit 2 is not directly attached to the attachment base 6, but is indirectly attached to the attachment base 6 by being attached to the measurement unit 1 attached to the attachment base 6.

A through hole 64 penetrating in the front-rear direction is formed in the lower region of the mounting base 6, and a cable or the like connected to the main input terminal portion 1501 or the like of the measurement unit 1 can be passed through. Is.

The unit cover 7 has a hollow rectangular parallelepiped shape with an open rear surface, and can accommodate the measurement system 3 (measurement unit 1 and extension unit 2) inside the unit cover 7. The unit cover 7 has two insertion holes 71 formed on the lower surface thereof. The unit cover 7 is attached to the mounting base 6 by fitting the opening edge of the rear surface of the unit cover 7 to the mounting base 6 and connecting the screws to the screw holes 65 provided on the lower side of the mounting base 6 through the insertion holes 71. Can be attached to.

(2.5) Distribution Board System Next, the distribution board system 5 will be described with reference to FIG. 12.

The distribution board system 5 includes a measurement system 3 (measurement unit 1 and an expansion unit 2 as an option) and a distribution board 4.

The distribution board 4 includes a main breaker 41 and a plurality of (here, 19) branch breakers 42.

The main breaker 41 is connected to the system power supply via the connection line 43, the current limiter 44, and the power supply line 45. In the present embodiment, the power supply system from the grid power supply is a single-phase three-wire system, and the connection line 43 and the power supply line 45 are a neutral line (N phase), a first voltage line (L1 phase), and a second. It is composed of three wires of the voltage line (L2 phase) of. The current limiter 44 is, for example, a device used for a charge contract for the maximum current usage value between an electric power company (supplier of system power supply) and a consumer of a facility in which a distribution board is installed. The current limiter 44 automatically turns off electricity when the consumer uses electricity in excess of the contracted current value. The connection line 43 and the current limiter 44 are optional and can be omitted, and the power line 45 may be connected to the main breaker 41.

A plurality of branch breakers 42 are connected to the main breaker 41. The plurality of branch breakers 42 branch the main circuit into which the main breaker 41 is inserted into a plurality of (here, 19) branch circuits. Here, the main circuit means an electric circuit from the power supply line 45 to the terminal on the power supply side of each branch breaker 42 inside the distribution board 4, and the branch circuit is downstream from the terminal on the power supply side of each branch breaker 42. It means the electric circuit on the side. As an example, each branch circuit contains one load. The load receives power from the grid power supply via the corresponding branch breaker 42. Here, one of the plurality of branch breakers 42 (421) is connected to the power supply terminal portion 171 of the measurement unit 1. The measurement unit 1 receives electric power from the system power supply via the branch breaker 421 and operates using the received electric power.

Further, the distribution board 4 is provided with a plurality of current sensors 8. The plurality of current sensors 8 include a main current sensor 81 and a plurality of branch current sensors 82.

The main current sensor 81 includes a first main sensor 811 that measures the current flowing through the first voltage line of the power line 45, and a second main sensor 812 that measures the current flowing through the second voltage line of the power line 45. To prepare for. Each of the first main sensor 811 and the second main sensor 812 is a CT. Each of the first main sensor 811 and the second main sensor 812 outputs an electric signal corresponding to the current flowing through the corresponding electric wire.

Each branch current sensor 82 measures the current flowing through the voltage line (L phase) of the corresponding branch circuit. Each branch current sensor 82 is a CT. Each branch current sensor 82 outputs an electric signal corresponding to the current flowing through the corresponding electric wire.

Each current sensor 8 is connected to the measuring unit 1 via a corresponding cable 9. Specifically, the main trunk current sensor 81 is connected to the main trunk input terminal portion 1501 of the measurement unit 1 via a cable 9, and the branch current sensor 82 connects the cable 9 to the branch input terminal portion 1502 of the measurement unit 1. It is connected via. The electric signal from each current sensor 8 is transmitted to the measuring unit 1 via the corresponding cable 9. In this embodiment, a connector is provided in the middle of the cable 9, and in FIG. 11, the cable 9 is simplified on the measurement unit 1 side of the connector.

The measurement unit 1 can obtain the current of the electric circuit (measurement point) corresponding to each current sensor 8 by arithmetically processing the signal transmitted from each current sensor 8 in the measurement unit 11.

The measuring unit 1 is attached adjacent to the distribution board 4 on the outside of the distribution board 4, for example. For example, the measurement unit 1 is attached adjacent to the distribution board 4 on one surface of the construction material to which the distribution board 4 is attached. However, the mounting position of the measuring unit 1 is not particularly limited, and for example, the measuring unit 1 may be mounted away from the distribution board 4 or may be mounted in the cabinet of the distribution board 4.

Here, there may be a request to increase the number of current sensors 8 connected to the measurement unit 1. In this case, the expansion unit 2 may be attached to the measurement unit 1, and the output terminal portion 22 of the expansion unit 2 may be connected to the connection terminal portion 1503 of the measurement unit 1 as shown by the dotted line in FIG. As a result, the measurement unit 1 can receive a signal (measured value) from the current sensor 8 via the expansion unit 2, and can obtain the current of the electric circuit (measurement point) corresponding to a larger number of current sensors 8. It will be possible.

Further, the measurement unit 1 has a space (arrangement space) 100 for arranging the expansion unit 2 behind the second block (covering portion) 114. Therefore, even when the expansion unit 2 is attached to the measurement unit 1, the size of the entire measurement system 3 including the measurement unit 1 and the expansion unit 2 does not become excessively large.

(3) Modifications The above embodiment is only one of the various embodiments of the present disclosure. The above-described embodiment can be variously modified depending on the design and the like as long as the object of the present disclosure can be achieved. Hereinafter, modified examples of the above-described embodiment will be listed. Hereinafter, the above-described embodiment will be referred to as a “basic example”. The modifications and basic examples described below can be applied in combination as appropriate.

The expansion unit 2 may have an expansion function different from that of the basic example. For example, the expansion unit 2 may include a terminal portion connected to a device for measuring energy consumption other than electric power, such as a water meter or a gas meter, such as the expansion terminal portion 173, or may have a wireless communication function. May be provided. In this case, the expansion terminal unit 173 or the communication unit 13 can be omitted from the measurement unit 1. Further, the expansion unit 2 may be configured to receive a signal from a device that measures the amount of power generated by the photovoltaic power generation device.

One expansion unit 2 selected from a plurality of expansion units 2 having different functions may be attached to the measurement unit 1. That is, if necessary, the expansion unit 2 having a desired function may be configured to be attached to the measurement unit 1.

The arrangement space 100 does not have to be open to the rear. For example, the arrangement space 100 may be a slit-shaped hole provided on the left side surface or the right side surface of the housing 10.

When the arrangement space 100 is provided on the rear surface of the housing 10, even if the guide mechanism guides the expansion unit 2 in the front-rear direction so that the expansion unit 2 can move in the front-rear direction along the guide mechanism. good.

The expansion unit 2 and the measurement unit 1 may be electrically connected to each other by a so-called BtoB (Board to Board).

The target for measuring the physical quantity by the measuring unit 11 of the measuring unit 1 is not limited to the circuit of the distribution board 4.

(4) Aspect As is clear from the basic example and the modified example described above, the measurement unit (1) of the first aspect includes the measurement unit (11), the housing (10), and the arrangement space (space 100). And prepare. The measuring unit (11) measures the physical quantity based on the signal from the sensor (current sensor 8) that outputs a signal corresponding to the physical quantity related to electricity passing through the electric circuit (main circuit and / or branch circuit). The housing (10) houses the measuring unit (11). The arrangement space is a space for arranging the expansion unit (2) to which the expansion function is added. The housing (10) has one surface. The housing (10) has a covering portion (second block 114) that covers at least a part of the expansion unit (2) arranged in the arrangement space when viewed from the front of one surface.

According to this configuration, the function of the measurement unit (1) can be expanded according to the usage environment of the measurement unit (1). Further, since the measurement unit (1) is provided with a covering portion (second block 114), the arrangement space (space 100) and the expansion unit (2) arranged in the arrangement space when viewed from the front of one surface. ), But it becomes less noticeable.

In the first aspect, the measurement unit (1) of the second aspect has the extension unit (2) having the extension board (23). The covering portion (second block 114) overlaps with at least a part of the expansion board (23) of the expansion unit (2) arranged in the arrangement space (space 100) when viewed from the front of one surface.

According to this configuration, when viewed from the front of one surface, at least a part of the expansion board (23) of the expansion unit (2) arranged in the arrangement space (space 100) is a covering portion (second block 114). ). Therefore, when viewed from the front of one surface, the expansion unit (2) arranged in the arrangement space becomes more inconspicuous.

In the second aspect, the measurement unit (1) of the third aspect is a terminal portion (2) mounted on the extension board (23) and connected to an external device (current sensor 8). It further has an input terminal unit 21). In the measurement unit (1), the terminal portion (input terminal portion 21) of the expansion unit (2) arranged in the arrangement space (space 100) is exposed when viewed from the front of one surface.

According to this configuration, the work of connecting the terminal portion of the expansion unit (2) arranged in the arrangement space (space 100) and the external device becomes easy.

In the measurement unit (1) of the fourth aspect, in any one of the first to third aspects, the electric circuit is composed of a plurality of electric circuits, and the sensor (current sensor 8) includes the plurality of sensors. The expansion unit (2) has an input terminal portion (21) and an output terminal portion (22). The input terminal unit (21) is connected to at least a part of the sensors of the plurality of sensors and receives a signal from the at least a part of the sensors. The output terminal unit (22) is connected to the measurement unit (1) and outputs the signal received by the input terminal unit (21) to the measurement unit (1).

According to this configuration, the measurement unit (1) can receive a signal from the sensor (current sensor 8) via the expansion unit (2). Therefore, it is possible to increase the number of sensors (current sensor 8) for which the measurement unit (1) receives a signal.

The measurement unit (1) of the fifth aspect further includes a holding structure for holding the expansion unit (2) arranged in the arrangement space (space 100) in any one of the first to fourth aspects.

According to this configuration, it is possible to hold the expansion unit (2) arranged in the arrangement space (space 100).

The measurement unit (1) of the sixth aspect further includes a mounting board (16) in any one of the first to fifth aspects. An operation circuit component (120) for accepting a manual operation is mounted on the mounting board (16). The mounting board (16) is housed in the housing (10). The covering portion (second block 114) houses at least a part of the mounting substrate (16) inside the covering portion (second block 114).

According to this configuration, the mounting board (16) is in front of the expansion unit (2) arranged in the arrangement space (space 100) when viewed from the front of one surface. Therefore, for example, the mounting board (16) can be arranged along one surface of the housing (10), and the size of the mounting board (16) can be reduced in the limited space inside the housing (10). It can be made larger.

The measurement unit (1) of the seventh aspect further includes a power supply board (17) in the sixth aspect. A plurality of power supply circuit components (140) constituting the power supply unit (14) for supplying electric power to the measurement unit (11) are mounted on the power supply board (17). The power supply board (17) is housed in the housing (10). In the measuring unit (1), the power supply board (17) is behind the mounting board (16) when viewed from the front of one surface.

According to this configuration, the power supply circuit component (140) that can be a source of noise is mounted on a board (power supply board 17) different from the mounting board (16). Therefore, it is possible to reduce the influence of noise on the circuit components mounted on the mounting board (17) from the power supply circuit board (140).

In the seventh aspect, the measurement unit (1) of the eighth aspect is an expansion unit arranged in the arrangement space (space 100) in the projection plane of the housing (110) when viewed from the front of one surface. (2) is adjacent to at least a part of the plurality of power supply circuit components (140).

According to this configuration, the expansion unit (2) can be arranged in a space adjacent to the area where the power supply circuit component (140) having a relatively large size is arranged. Therefore, the expansion unit (2) is attached as compared with the case where the expansion unit (2) arranged in the arrangement space (space 100) is not adjacent to at least a part of the plurality of power supply circuit components (140). It is possible to reduce the size of the measurement unit (1) at that time.

The expansion unit (2) of the ninth aspect adds an expansion function to the measurement unit (1) of any one of the first to eighth aspects.

According to this configuration, it is possible to provide an expansion unit (2) that adds an expansion function to the measurement unit (1).

The measurement system (3) of the tenth aspect includes a measurement unit (1) of any one of the first to eighth aspects and an expansion unit (2).

According to this configuration, it is possible to provide a measurement system (3) including a measurement unit (1) whose function has been expanded by an expansion unit (2).

The distribution board system (5) of the eleventh aspect is a distribution board (4) having a measurement unit (1) of any one of the first to eighth aspects and an electric circuit (main circuit and / or branch circuit). And.

According to this configuration, the measurement unit (1) makes it possible to measure the physical quantity related to electricity passing through the electric circuit (main circuit and / or branch circuit) of the distribution board.

1 Measuring unit 10 Housing 114 Second block (covering part)
100 space (placement space)
11 Measurement unit 120 Operation circuit parts 14 Power supply unit 140 Power supply circuit parts 16 Mounting board 17 Power supply board 2 Expansion unit 21 Input terminal unit (terminal unit)
22 Output terminal 23 Expansion board 3 Measurement system 4 Distribution board 5 Distribution board system 8 Current sensor (sensor)

Claims (9)

A measuring unit that measures the physical quantity based on the signal from the sensor that outputs a signal corresponding to the physical quantity related to the electricity passing through the electric circuit.
A housing for accommodating the measuring unit and
Placement space for arranging expansion units to add expansion functions,
Equipped with
The housing has one surface
Wherein the housing covers at least a portion of the expansion unit that is disposed on the arrangement space when viewed from the front of the one surface, have a covering portion,
The expansion unit is
With an expansion board
The terminal part mounted on the expansion board and connected to an external device,
Have,
The covering portion overlaps with at least a part of the expansion board of the expansion unit arranged in the arrangement space when viewed from the front of the one surface.
A measurement unit in which the terminal portion of the expansion unit arranged in the arrangement space is exposed when viewed from the front of the one surface. It ’s a measurement unit.
A measuring unit that measures the physical quantity based on the signal from the sensor that outputs a signal corresponding to the physical quantity related to the electricity passing through the electric circuit.
A housing for accommodating the measuring unit and
Placement space for arranging expansion units to add expansion functions,
Equipped with
The housing has one surface
The housing has a covering portion that covers at least a part of the expansion unit arranged in the arrangement space when viewed from the front of the one surface.
The electric circuit is composed of a plurality of electric lines.
The sensor includes a plurality of sensors.
The expansion unit is
An input terminal unit that is connected to at least a part of the plurality of sensors and receives a signal from the at least a part of the sensor.
An output terminal unit that is connected to the measurement unit and outputs the signal received by the input terminal unit to the measurement unit.
Have
Measurement unit. A measuring unit that measures the physical quantity based on the signal from the sensor that outputs a signal corresponding to the physical quantity related to the electricity passing through the electric circuit.
A housing for accommodating the measuring unit and
Placement space for arranging expansion units to add expansion functions,
A mounting board on which operation circuit components for accepting manual operations are mounted and housed in the housing, and a mounting board.
Equipped with
The housing has one surface
The housing has a covering portion that covers at least a part of the expansion unit arranged in the arrangement space when viewed from the front of the one surface.
The covering portion houses at least a part of the mounting board inside the covering portion.
Measurement unit. A power supply circuit component that constitutes a power supply unit that supplies power to the measurement unit is mounted, and a power supply board housed in the housing is further provided.
The power supply board is behind the mounting board when viewed from the front of the one surface.
The measuring unit according to claim 3. In the projection plane of the housing when viewed from the front of the one surface, the expansion unit arranged in the arrangement space is adjacent to at least a part of the plurality of power supply circuit components.
The measuring unit according to claim 4. Further provided with a holding structure for holding the expansion unit arranged in the arrangement space.
The measuring unit according to any one of claims 1 to 5. The extended function is added to the measurement unit according to any one of claims 1 to 6.
Expansion unit. The measuring unit according to any one of claims 1 to 6 and the measuring unit.
With the expansion unit
A measurement system equipped with. The measuring unit according to any one of claims 1 to 6 and the measuring unit.
A distribution board having the electric circuit and
Distribution board system equipped with.

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