JP6458189B1 - Bypass tool for electricity meter - Google Patents

Abstract

An object of the present invention is to provide a bypass tool for a watt hour meter capable of preventing a short circuit of a connection terminal of a terminal block. The present invention relates to a terminal block 51 provided in an watt-hour meter 5 and a case 2 applied to the front surface of a terminal block 51 in which each of a plurality of connection terminals 510 arranged side by side is fixed with a screw. The case 2 is erected on the upper surface and in a state where the case 2 is applied to the front surface of the terminal block 51, a region in front of the screws adjacent to each other in the lateral direction in which the plurality of connection terminals 510 are arranged. A bypass tool for the watt-hour meter 5 having a wall 202 disposed therebetween. [Selection] Figure 9

Description

  The present invention relates to a bypass tool for a watt hour meter that is attached to a watt hour meter to form a bypass circuit that connects a power source side and a load side.

  2. Description of the Related Art Conventionally, there is known a bypass tool that newly forms a bypass circuit for connecting a power source side and a load side with respect to a watt hour meter installed on an electric path connecting a power source and a load.

  For example, Patent Document 1 targets a watt-hour meter including a terminal block (so-called terminal block) provided with a plurality of wire connection portions for connecting wires, and is attached to the terminal block to thereby bypass the watt-hour meter. A bypass tool configured to form a circuit is disclosed.

  The bypass tool includes a case applied to the front surface of the terminal block, a plurality of screws inserted into the case from the front surface side and having a distal end protruding and retracted from the back surface of the case, and a plurality of screws in the case. And a bus bar connected to the device.

  Therefore, the bypass tool, when the case is applied to the front surface of the terminal block, the tip of the screw is advanced from the back of the case, and further, the tip of the screw is screwed into the female screw portion of the wire connecting portion. Is fixed in a state where it is electrically connected to the electric wire connecting portion, whereby the bypass circuit can be formed in the terminal block.

Japanese Patent Laid-Open No. 2006-80687

  By the way, the terminal block of the watt hour meter is fixed with screws to the terminal block main body as a base with a plurality of electric wire connecting portions arranged side by side, and when using the above-mentioned conventional bypass tool The case is attached to the terminal block at a position shifted downward from the screw.

  As a result, the screw can be operated from the terminal block even when the bypass tool is attached to the terminal block. However, the loosened screw is detached from the terminal block body, and the screw contacts separate wire connection portions. There was something to do. For this reason, in the conventional bypass tool described above, the wire connection portions constituting separate circuits may be short-circuited.

  Then, this invention makes it a subject to provide the bypass tool for watt-hour meters which can prevent the short circuit of the connecting terminal of a terminal block in view of this situation.

Bypass tool for watt-hour meter of the present invention,
A terminal block provided in the watt-hour meter, and a case having a back surface arranged opposite to the front surface of the terminal block in which each of a plurality of connection terminals arranged side by side is fixed with a screw ;
A bypass circuit disposed in the case;
A bypass terminal connected to the bypass circuit in the case and connected to the connection terminal in a state of extending from the back to the outside of the case; and
The plurality of connection terminals include a connection terminal for a ground circuit and a connection terminal for a circuit different from the ground circuit,
On both sides of the connection terminal for the earth circuit in the lateral direction in which the plurality of connection terminals are arranged, connection terminals constituting the other circuit are arranged,
In the case where the back surface is applied to the front surface of the terminal block, the upper surface of the case itself has a screw for fixing the connection terminal for the ground circuit, and the connection terminal for the other circuit. It is configured to be arranged below the screw that is fixed,
In the state where the back surface is applied to the front surface of the terminal block on the upper surface of the case, a region in front of the screw fixing the connection terminal for the ground circuit, and the connection terminal for the ground circuit wall portion disposed between the front region of the screw securing the connection terminals arranged next to it are formed.

  According to such a configuration, when the case is applied to the front surface of the terminal block, the space between the front portions of the screws adjacent in the lateral direction is partitioned by the wall portion, so that the screws removed from the connection terminals are connected to other connections. Contact with the terminal is prevented.

In the bypass tool for the watt-hour meter of the present invention,
Before Kikabe unit, in the transverse direction, it may be configured to be disposed on opposite sides of the front region of the screw for fixing the connection terminals for the ground circuit.

  In the watt-hour meter, the connection terminals constituting another circuit are arranged on both sides of the connection terminal for the ground circuit. According to the bypass tool for the watt-hour meter having the above configuration, the connection terminal for the ground circuit is provided. Since both sides of the region in front of the screw to be fixed can be partitioned by the wall portion, it is possible to prevent a short circuit between the ground circuit and another circuit other than the ground circuit that is caused by the contact of the screws.

Moreover, the bypass tool for the watt-hour meter of the present invention is
A mounting screw that is advanced from the back of the upper side of the case and attached to the terminal block,
The wall portion has a rear end surface extending straight upward from a position on the same plane or substantially the same plane as the back surface of the case.

  According to this configuration, the case can be applied to the front surface of the terminal block, and the rear end surface of the wall can be brought into contact with the front side of the terminal block on the upper side of the case. When an external force such as peeling off from the table is applied, the rear end surface of the wall is supported and the inclination of the case is suppressed.

  Thereby, the bypass tool for the watt-hour meter is attached to the terminal block on the upper side of the case by preventing the case from tilting (tilting so that the lower end side of the case moves forward and the upper end side moves rearward). The load applied to the screw can be suppressed.

  As described above, the bypass tool for a watt-hour meter of the present invention can exhibit an excellent effect that a short circuit of a connection terminal of a terminal block can be prevented.

FIG. 1 is a front view of a watt-hour bypass tool according to an embodiment of the present invention. FIG. 2 is a rear view of the watt-hour bypass tool according to the embodiment. FIG. 3 is a plan view of the watt-hour bypass tool according to the embodiment. 4 is a cross-sectional view taken along line IV-IV in FIG. 5A is a front view of the operation unit switched to the first posture, and FIG. 5B is a plan view of the operation unit switched to the first posture. 6A is a front view of the operation unit switched to the second posture, and FIG. 6B is a plan view of the operation unit switched to the second posture. 7A is a front view of the watt hour meter, and FIG. 7B is a bottom view of the watt hour meter. FIG. 8 is an explanatory diagram of the usage state of the watt-hour bypass tool according to the embodiment, and is an explanatory diagram of the state in which the bypass tool is fixed to the front surface of the terminal block. 9 is a cross-sectional view taken along line IX-IX in FIG. FIG. 10 is an explanatory diagram of a usage state of the watt-hour bypass tool according to another embodiment of the present invention, and is an explanatory diagram of a state in which the bypass tool is fixed to the front surface of the terminal block. 11 is a cross-sectional view taken along line XI-XI in FIG.

  Hereinafter, a bypass tool for a watt hour meter (hereinafter referred to as a bypass tool) according to an embodiment of the present invention will be described with reference to the accompanying drawings.

  As shown in FIGS. 7A and 7B, the watt-hour meter 5 includes a measuring unit 50 and a terminal block 51. The terminal block 51 includes a plurality of terminals arranged side by side. The connection terminal 510 is provided. In the present embodiment, the connection terminal 510 constituting the earth circuit is denoted by reference numeral “510E”.

  The terminal block 50 is configured such that a cable connected to the power supply side and a cable connected to the load side are connected, and the power supply side cable and the load side cable are electrically connected through the measuring unit 50. It has become so. The terminal block 51 is configured so that the cable can be inserted into the inside through the insertion hole 510a on the bottom surface (see FIG. 8B).

  An attachment screw S is inserted into the connection terminal 510 from the front side, and the connection terminal 510 is fixed to the front surface of the terminal block 51 by the attachment screw S. The mounting screw S is also a screw for fixing the measuring unit 50 to the terminal block 51.

  The bypass tool according to the present embodiment is used for the watt-hour meter 5 having the above-described configuration. The power supply side cable and the load side cable do not pass through the weighing unit 50 (bypass) with respect to the terminal portion. And a bypass circuit for electrically connecting the two.

  As shown in FIG. 1, the bypass tool according to the present embodiment includes a case 2 in which a bypass circuit is installed, and a bypass terminal provided in the case 2, and the bypass circuit includes a watt-hour meter 5 (this embodiment). Then, a bypass terminal 3 (see FIG. 2) for connection to the terminal block 51) and an operation unit provided in the bypass terminal 3, wherein the bypass terminal 3 is electrically connected to the terminal block 51 and bypassed. And an operation unit 4 for switching the terminal 3 to a disconnected state in which the terminal 3 is separated from the terminal block 51.

  In the present embodiment, the direction in which the front surface and the back surface of the case 2 are aligned is the front-rear direction, the direction corresponding to the top and bottom of the case 2 is the vertical direction, and the direction orthogonal to the front-back direction and the vertical direction (that is, the lateral width of the case 2). The direction below is referred to as a horizontal direction and will be described below.

  Further, the bypass tool according to the present embodiment is provided with two bypass circuits, and one bypass circuit is connected with two bypass terminals 3, and the two bypass terminals 3 have one common one. An operation unit 4 is provided. Two bypass terminals 3 are also connected to the other bypass circuit, but each of the two bypass terminals 3 is provided with a separate operation unit 4 (see FIGS. 1 and 2).

  As shown in FIG. 4, the case 2 includes a case body 20 having a back surface 200 applied to the front surface of the terminal block 51 and a front surface 201 opposite to the back surface 200, and the bypass terminal 3 as the case body 20. A sliding structure 21 for sliding in the front-rear direction, a biasing member 22 for biasing the bypass terminal 3 rearward in the front-rear direction, and a terminal position where the bypass terminal 3 can be positioned in the front-rear direction The fixing portion 23 and a fixing structure 24 (see FIG. 1) for fixing the case main body 20 to the terminal block 51 are provided.

  The case body 20 is formed in a box shape, and the bypass terminal 3 is disposed inside. Note that a substrate and an electronic component for constituting a bypass circuit are also arranged in the case body 20.

  Moreover, the case main body 20 has the wall part 202 standingly arranged by the upper surface, as shown in FIG. The wall portion 202 is configured to partition between the regions in front of the fixing screws of the two connection terminals 510 adjacent in the lateral direction when the case 2 is applied to the front surface of the terminal block 51.

  The wall 202 extends from the position corresponding to the back surface 200 of the case body 20 toward the front surface 201 side of the case body 20 along the front-rear direction. As shown in FIG. 3, the rear end surface 202a of the wall portion 202 is formed at a location coinciding with the back surface 200 of the case main body 20 in the front-rear direction, and upward from the upper surface of the case main body 20 in the vertical direction. It extends straight towards you. Therefore, the rear end surface 202a of the wall 202 and the back surface 200 of the case 2 are located on the same plane or substantially the same plane.

  Further, the wall portion 202 is configured to partition between a region in front of the mounting screw S for fixing the ground connection terminal 510 and a region in front of the mounting screw S for fixing the other connection terminal 510. In the present embodiment, the region in front of the mounting screw S that fixes the ground connection terminal 510 and the connection terminal 510 that is adjacent to the ground connection terminal 510 on one side in the lateral direction are fixed. On the other side in the lateral direction with respect to the wall 202 that separates the area in front of the screw S, the area in front of the mounting screw S that fixes the ground connection terminal 510 and the connection terminal 510 for ground. A wall portion 202 is provided to partition the area between the front of the mounting screw S that fixes the adjacent connection terminal 510.

  The slide structure 21 is an operation portion insertion portion 210 through which the operation portion 4 is slidable in the front-rear direction, and includes a cylindrical operation portion insertion portion 210 that opens at the front surface 201 of the case body 20. The terminal insertion portion 211 that allows the bypass terminal 3 to be slidable in the front-rear direction and has a terminal insertion portion 211 provided on the back surface 200 of the case body 20.

  The operation portion insertion portion 210 extends from the inner side of the front surface 201 of the case body 20 (one surface side located in the case body 20) toward the rear side in the front-rear direction.

  Further, in the operation portion insertion portion 210, the inner diameter on the distal end side is larger than the inner diameter on the proximal end side. Therefore, in the boundary between the inner peripheral surface on the distal end side and the inner peripheral surface on the proximal end side of the operation portion insertion portion 210, the radial direction from the position corresponding to the inner peripheral surface on the proximal end side of the operation portion insertion portion 210. An inner plane 212 that extends outward (outward in the radial direction of the operation portion insertion portion 210) is formed.

  In the present embodiment, the four operation portion insertion portions 210 are arranged at intervals in the lateral direction.

  The terminal insertion portion 211 has a cylindrical shape, and extends from the outside of the back surface 200 of the case body 20 (one surface located outside the case body 20) toward the rear side in the front-rear direction. Further, the terminal insertion portion 211 has an opening on the base end side that opens toward the inside of the case body 20.

  In the present embodiment, as described above, since the four bypass terminals 3 are arranged so as to be arranged at intervals in the lateral direction of the case 2, the arrangement positions of the bypass terminals 3 are arranged on the back surface 200 of the case body 20. Accordingly, two terminal insertion portions 211 are formed so as to be arranged at intervals in the lateral direction.

  The terminal insertion part 211 is provided at a position shifted upward with respect to the operation part insertion part 210.

  The urging member 22 is a compression coil spring. The urging member 22 is inserted on the distal end side of the terminal insertion portion 211, and is disposed so that one end in the expansion / contraction direction contacts the inner plane 212. In addition, it is preferable that the urging member 22 is configured such that the total length in the expansion / contraction direction is less than the known total length in a state where the bypass terminal 3 is disposed at the advance position described later. In this way, it is possible to always apply a biasing force acting on the rear side in the front-rear direction with respect to the bypass terminal 3. The urging member 22 may be configured by a leaf spring or the like.

  As shown in FIGS. 5 (b) and 6 (b), the terminal position determining unit 23 includes an advancing position determining unit 230 that positions the bypass terminal 3 at the advancing position that is slid rearward in the front-rear direction. And a backward positioning portion 231 for positioning the bypass terminal 3 at the backward position in which the bypass terminal 3 is slid forward in the front-rear direction.

  The advanced position is a position where the bypass terminal 3 contacts (conducts) the connection terminal 510 of the terminal block 51 while the case 2 (the back surface 200 of the case body 20) is placed on the front surface of the terminal block 51. is there. The retracted position is a position where the bypass terminal 3 is not in contact with the connection terminal 510 of the terminal block 51 when the case 2 (the back surface 200 of the case body 20) is placed on the front surface of the terminal block 51. It is.

  As shown in FIG. 5B, the advancing position determining unit 230 holds the operating unit 4 on the advancing receiving unit 230a and the advancing receiving unit 230a that receives the operating unit 4 on the rear side in the front-rear direction. And an advancement detent portion 230b for advancement.

  As shown in FIG. 6 (b), the backward positioning unit 231 is configured to hold the operating portion 4 on the backward receiving portion 231a and the backward receiving portion 231a that receives the operating portion 4 on the rear side in the front-rear direction. And a reverse stopper portion 231b.

  Here, the terminal positioning unit 23 (advance positioning unit 230, retreat positioning unit 231) according to the present embodiment is configured to position the bypass terminal 3 via the operation unit 4.

  More specifically, the terminal positioning portion 23 is configured by a cylindrical portion 232 that extends forward from the front surface 201 of the case body 20.

  The cylindrical portion 232 is formed with a recess 232a that is recessed from the distal end surface toward the proximal end in the front-rear direction. In addition, the cylindrical portion 232 is formed with a plurality of (two in the present embodiment) recesses 232a spaced from each other in the circumferential direction (its own circumferential direction).

  In the advance receiving portion 230a, as shown in FIG. 5B, the advance receiving portion 230a is constituted by the bottom surface 232b of the recess 232a, and the advancement detent portion 230b is constituted by the side surface 232c of the recess 232a.

  In the retreat receiving portion 231a, as shown in FIG. 6B, the front end surface 232d of the cylindrical portion 232 (the front end surface 232d between the concave portion 232a and the concave portion 232a adjacent in the circumferential direction of the cylindrical portion 232). Thus, a retreat receiving portion 231a is formed, and a retraction detent 231b is formed by a bulging portion 232e that bulges from the both end portions of the front end surface 232d to the front side (the front side in the front-rear direction). Yes.

  As shown in FIG. 9, the fixing structure 24 includes a front insertion portion 240 that forms a continuous insertion region from the front surface 201 to the rear surface 200 of the case body 20 along the front-rear direction, and the fixing insertion portion 24 with respect to the fixing insertion portion. A fixing insertion portion 241 provided at a position aligned on the rear side in the front-rear direction, a fixing screw 242 inserted from the front side in the front-rear direction with respect to the fixing insertion portion 241, and a fixing screw in the fixing insertion portion 241 Push-back means 243 for urging 242 toward the front surface 201 of the case body 20 is provided.

  The insertion region of the front insertion portion 240 is formed so as to be opened at the front surface 201 of the case body 20 and the back surface 200 of the case body 20.

  The fixing insertion portion 241 is cylindrical and extends from the back surface 200 of the case body 20 toward the rear side in the front-rear direction. Further, the fixing insertion portion 241 is provided inside the terminal insertion portion 211 in the lateral direction. The fixing insertion portion 241 is also a screw accommodating portion that can accommodate the fixing screw 242.

  The fixing screw 242 is inserted into the fixing insertion portion 241 so as to be slidable in the front-rear direction. In addition, the fixing screw 242 has an exposed state in which the distal end portion of the male screw portion is exposed (advanced) from the fixing insertion portion 241 to the rear side in the front-rear direction by sliding in the fixing insertion portion 241 and the male screw portion. It is possible to switch to an accommodation state in which the entire distal end portion is accommodated in the fixing insertion portion 241 (that is, a state in which the distal end of the male screw portion is located on the front side in the front-rear direction from the distal end of the fixing insertion portion 241).

  When the fixing screw 242 is switched to the exposed state, the male screw portion can be screwed into a bypass tool mounting location (for example, a screw hole formed in the connection terminal 510) in the watt-hour meter 5 (terminal block 51). It becomes a state. On the other hand, when the fixing screw 242 is switched to the accommodated state, the male screw portion cannot be screwed into the attachment location.

  The push-back means 243 is composed of a compression coil spring, and is arranged in the front insertion part 240 so as to expand and contract in the front-rear direction, and is slid rearward in the front-rear direction in the front insertion part 240. The fixing screw 242 is configured to push back toward the front side.

  As shown in FIG. 4, the bypass terminal 3 connects the shaft-shaped terminal main body 30, a connection structure 31 that connects the terminal main body 30 and the operation unit 4, and the terminal main body 30 to an electric circuit of the bypass circuit. And a conductive connection part 32 for the purpose.

  The terminal main body 30 is disposed in a state in which the axial center direction coincides or substantially coincides with the front-rear direction, and is inserted through the terminal insertion portion 211.

  Further, the terminal main body 30 is configured to slide in the front-rear direction within the terminal insertion portion 211 when the bypass terminal 3 is changed to the advanced position or the retracted position. Then, when the bypass terminal 3 is arranged at the advanced position with the case 2 attached to the front surface of the terminal block 51, the distal end portion of the terminal main body portion 30 advances from the terminal insertion portion to the outside (that is, the terminal insertion). The contact terminal 510 comes into contact with the connection terminal 510 by moving forward in the front-rear direction from the portion. On the other hand, when the bypass terminal 3 is disposed at the retracted position with the case 2 attached to the front surface of the terminal block 51, the distal end portion of the terminal main body portion 30 is retracted into the terminal insertion portion and separated from the connection terminal 510. In this way, the state in which the bypass terminal 3 is conductively connected to the connection terminal 510 and the state in which the bypass terminal 3 is disconnected from the connection terminal 510 are switched.

  The connection structure 31 includes a connection plate portion 310 to which the terminal main body portion 30 is attached, and a connection shaft portion 311 that connects the connection plate portion 310 and the operation portion 4.

  One end (hereinafter referred to as a base end) of the terminal main body portion 30 in the axial direction is attached to the connecting plate portion 310. Further, the connecting plate portion 310 has an elongated shape (in this embodiment, a rectangular shape), the bypass terminal 3 is attached to one end portion in the longitudinal direction, and the connecting shaft portion 311 is attached to the central portion in the longitudinal direction. .

  The connecting shaft portion 311 is inserted into the operation portion insertion portion 210 from the distal end side of the operation portion insertion portion 210 in a posture in which the axial center direction matches or substantially matches the front-rear direction.

  In the present embodiment, the connecting shaft portion 311 is also inserted inside the biasing member 22 in the operation portion insertion portion 210, and the connecting plate portion 310 is in the expansion and contraction direction of the biasing member 22. It is configured to receive the other end (hereinafter referred to as the tip).

  Further, the axial center of the connecting shaft portion 311 is located at a location away from the axial center of the terminal body portion 30 (location away in the radial direction of the terminal body portion 30). Therefore, the terminal main body 30 is rotatable in the circumferential direction around the axis of the connecting shaft 311 and moves in the lateral direction within a range allowed by the space between the terminal insertion portion 211. It is configured to be able to.

  The conductive connection portion 32 is formed integrally with a part of the connection structure 31. In the present embodiment, the conductive connection portion 32 is configured by the other end portion in the longitudinal direction of the connecting plate portion 310. And in this embodiment, one bypass circuit is comprised because the conduction | electrical_connection connection parts 32 of each bypass terminal 3 are electrically connected.

  The operation unit 4 extends from the operation unit main body 40 and is slidable in the front-rear direction with respect to the guide unit for the operation unit 4. And a guided portion 41 to be inserted.

  The operation portion main body 40 has an elongated shape (in the present embodiment, a rectangular shape), and the dimension in the longitudinal direction is larger than the outer diameter of the terminal positioning portion 23 (tubular portion 232). In the operation unit main body 40 according to the present embodiment, both sides in the longitudinal direction are hooked to the terminal positioning portion 23 (the advance receiving portion 230a or the backward receiving portion 231a) from the front side, and It has become.

  The guided portion 41 extends from the center side in the longitudinal direction of the operation portion main body 40. Therefore, each latching part 400 can be rotated along the circumferential direction with the guided part 41 as the center.

  The configuration of the bypass tool according to the present embodiment is as described above. Then, the usage of the bypass tool which concerns on this embodiment is demonstrated.

  When the bypass circuit is connected to the terminal block 51 using the bypass tool, each bypass terminal 3 is disposed in the retracted position. At this time, the distal end of the terminal main body 30 is arranged in the terminal insertion portion 211. Further, in the operation unit main body 40, the latching portion 400 is latched from the front side with respect to the retreat receiving portion 231a.

  When the latching portion 400 tries to rotate along the circumferential direction with the guided portion 41 as the center, the reverse displacement preventing portion 231b interferes. Therefore, the latching part 400 is fastened on the retreating receiving part 231a by the retreating detenting part 231b.

  In order to attach the bypass tool to the terminal block 51, first, the case 2 (the back surface 200 of the case body 20) is applied to the front surface of the terminal block 51. In the present embodiment, the case 2 is applied to the front surface of the terminal block 51 such that the upper surface of the case body 20 is positioned below the mounting screw S.

  In a state where the back surface 200 of the case main body 20 is applied to the front surface of the terminal block 51, each terminal main body portion 30 is disposed in front of a separate connection terminal 510, and the fixing screw 242 is connected to the fixing portion (in this embodiment, the connection position). The screw hole is formed in front of the terminal 510. Then, the case 2 is fixed to the terminal block 51 by screwing the fixing screw 242 into the fixing portion.

  In a state where the back surface 200 of the case body 20 is applied to the front surface of the terminal block 51, the back surface 200 and the rear end surface 202 a of each wall portion 202 abut on the front surface of the terminal block 51.

  Further, when the case 2 is applied to the front surface of the terminal block 51, one wall portion 202 is lateral to the region in front of the mounting screw S for fixing the ground connection terminal 510 and the ground connection terminal 510. The other wall portion 202 is disposed between a region in front of the mounting screw S that fixes the connection terminal 510 adjacent on one side of the direction, and the other wall portion 202 is a region in front of the mounting screw S that fixes the connection terminal 510 for grounding. And a region in front of the mounting screw S for fixing the connecting terminal 510 adjacent to the ground connecting terminal 510 on the other side in the lateral direction.

  Therefore, both sides (both sides in the lateral width direction) of the area in front of the mounting screw S that fixes the ground connection terminal 510 are partitioned by the pair of wall portions 202. Thereby, for example, when the mounting screw S of the ground connection terminal 510 is loosened to remove the measuring unit 50 from the terminal block 51, even if the mounting screw S is completely removed from the ground connection terminal 510, A mounting screw S can be secured between the walls 202.

  The bypass circuit is connected to the terminal block 51 by moving each bypass terminal 3 from the retracted position to the advanced position.

  More specifically, after the operation unit main body 40 is pulled out to the near side of the backward movement stopping portion 231b, the operation portion main body 40 is rotated so that the respective latching portions 400 are moved from the front of the backward receiving portion 231a. It moves to the front of the advance receiving part 230a. And each latching part 400 is arrange | positioned in the advance receiving part 230a, and it leaves to the energizing force of an urging means, and latches each latching part 400 to the advance receiving part 230a.

  In addition, if the latching part 400 tries to turn along the circumferential direction centering on the to-be-guided part 41 in the state latched by the advance receiving part 230a, the advancement stopper part 230b interferes. Therefore, the latching part 400 will be in the state in which the rotation in the circumferential direction centering on the to-be-guided part 41 was controlled.

  In addition, the terminal body 30 slides forward in the front-rear direction as the latch 400 is switched from the retreat receiving portion 231a to the advance receiving portion 230a. Therefore, the distal end portion of the terminal main body portion 30 moves outward from the terminal insertion portion 211, and the distal end portion (front end surface 232d) of the terminal main body portion 30 comes into contact with the front surface of the connection terminal.

  The terminal body 30 is conductively connected to the connection terminal in this way. The bypass circuit can be connected to the terminal block 51 by electrically connecting the terminal body 30 of each bypass terminal 3 to the connection terminal.

  When the bypass circuit is disconnected from the terminal block 51, each bypass terminal 3 is moved from the advanced position to the retracted position.

  More specifically, after the operation unit main body 40 is pulled out to the near side from the advancement detents 230b and the retraction detents 231b, the operation unit main body 40 is rotated to advance each latching unit 400. It moves from the front of the receiving part 230a to the front of the backward receiving part 231a. And each latching part 400 is arrange | positioned in the receiving part 231a for retraction | retreat, and each latching part 400 is latched to the receiving part 231a for a retreating by energizing force of a biasing means.

  As the latching portion 400 is switched from the advance receiving portion 230a to the backward receiving portion 231a, the terminal main body portion 30 slides rearward in the front-rear direction. Therefore, the distal end portion of the terminal body portion 30 moves into the terminal insertion portion 211, and the distal end portion (tip surface 232d) of the terminal body portion 30 moves away from the front surface of the connection terminal.

  The terminal body 30 that is conductively connected to the connection terminal 510 is thus disconnected from the connection terminal. The bypass circuit can be disconnected from the terminal block 51 by disconnecting the terminal body 30 of each bypass terminal 3 from the connection terminal.

  As described above, according to the bypass tool according to the present embodiment, when the case 2 is applied to the front surface of the terminal block 51, in the front of the terminal block 51, each of the regions in front of each of the screws adjacent in the lateral direction. Since the space is partitioned by the wall portion 202, contact between the screw detached from the connection terminal 510 and the other connection terminal 510 is prevented. Therefore, the excellent effect that the short circuit of the connection terminal 510 of the terminal block 51 can be prevented can be obtained.

  In particular, in the bypass tool 1, the connection terminals 510 constituting another circuit are arranged on both sides of the ground circuit connection terminal 510. According to the bypass tool for the watt-hour meter 5 according to the present embodiment, Since both sides of the area in front of the screw for fixing the connection terminal 510 for the earth circuit can be partitioned by the wall portion 202, a short circuit between the earth circuit causing the contact of the screw and a circuit different from the earth circuit Can be prevented.

  Further, when the case 2 is applied to the front surface of the terminal block 51, the rear end surface 202 a of the wall 202 can be brought into contact with the front of the terminal block 51 on the upper side of the case 2. On the other hand, when an external force is applied to peel the lower side of the case 2 from the terminal block 51, the rear end surface 202a of the wall 202 is supported, and the inclination of the case 2 is suppressed.

  Thereby, the bypass tool for the watt-hour meter 5 prevents the inclination of the case 2 (inclination such that the lower end side of the case 2 moves forward and the upper end side moves rearward). The load applied to the mounting screw S attached to 51 can be suppressed.

  In addition, the bypass tool of this invention is not limited to the said embodiment, Of course, a various change can be added in the range which does not deviate from the summary of this invention.

  In the above-described embodiment, the wall 202 includes a region in front of the mounting screw S that fixes the ground connection terminal 510 and the connection terminal 510 adjacent on one side in the lateral direction with respect to the ground connection terminal 510. The wall 202 that partitions the front portion of the mounting screw S to be fixed, the front portion of the mounting screw S that fixes the ground connection terminal 510 and the ground connection terminal 510 in the lateral direction. Although the wall portion 202 is provided to partition the front side of the mounting screw S that fixes the adjacent connection terminal 510 on the other side, the present invention is not limited to this configuration. For example, a wall portion 202 that partitions one side or both sides in the lateral direction of a region in front of the mounting screw S different from the mounting screw S that fixes the ground connection terminal 510 may be provided.

  Although the bypass tool 1 which concerns on the said embodiment was comprised so that it might have two bypass circuits, it is not limited to this structure. For example, the bypass tool 1 may have one bypass circuit as shown in FIGS.

  In the above embodiment, the upper ends of the wall portions 202 adjacent in the horizontal direction are discontinuous, but the present invention is not limited to this configuration. For example, the upper end of the wall 202 may be continuous as shown in FIG.

DESCRIPTION OF SYMBOLS 1 ... Bypass tool, 2 ... Case, 3 ... Bypass terminal, 4 ... Operation part, 5 ... Electricity meter, 20 ... Case main body, 21 ... Slide structure, 22 ... Biasing member, 23 ... Positioning part for terminals, 24 DESCRIPTION OF SYMBOLS Fixed structure, 30 ... Terminal body part, 31 ... Connection structure, 32 ... Conduction connection part, 40 ... Operation part main body, 41 ... Guide part, 50 ... Measuring part, 51 ... Terminal block, 200 ... Back surface, 201 ... Front surface , 202 ... wall part, 202a ... rear end surface, 210 ... operation part insertion part, 211 ... terminal insertion part, 212 ... inner plane, 230 ... advance positioning part, 230a ... advance reception part, 230b ... advance Detachment part, 231 ... Retraction positioning part, 231a ... Retraction receiving part, 231b ... Retraction detent part, 232 ... Cylindrical part, 232a ... Recess, 232b ... Bottom face, 232c ... Side face, 232d ... Tip face, 232e ... bulge part, 240 ... front side insertion part 241 ... fixing inserting portion, 243 ... push-back means, 310 ... connecting plate, 311 ... connection shaft section, 400 ... hook portion, 510 ... connection terminal, 510a ... insertion hole

Claims (3)

A terminal block provided in the watt-hour meter, and a case having a back surface arranged opposite to the front surface of the terminal block in which each of a plurality of connection terminals arranged side by side is fixed with a screw ;
A bypass circuit disposed in the case;
A bypass terminal connected to the bypass circuit in the case and connected to the connection terminal in a state of extending from the back to the outside of the case; and
The plurality of connection terminals include a connection terminal for a ground circuit and a connection terminal for a circuit different from the ground circuit,
On both sides of the connection terminal for the earth circuit in the lateral direction in which the plurality of connection terminals are arranged, connection terminals constituting the other circuit are arranged,
In the case where the back surface is applied to the front surface of the terminal block, the upper surface of the case itself has a screw for fixing the connection terminal for the ground circuit, and the connection terminal for the other circuit. It is configured to be arranged below the screw that is fixed,
In the state where the back surface is applied to the front surface of the terminal block on the upper surface of the case, a region in front of the screw fixing the connection terminal for the ground circuit, and the connection terminal for the ground circuit wall portion disposed between the front region of the screw securing the connection terminals arranged next to it are formed,
Bypass tool for watt-hour meter. Before Kikabe portion, in the lateral direction, configured to be placed on opposite sides of the front region of the screw for fixing the connection terminals for the ground circuit,
The bypass tool for the watt-hour meter according to claim 1. A mounting screw that is advanced from the back of the upper side of the case and attached to the terminal block,
The wall portion has a rear end surface extending straight upward from a position on the same plane or substantially the same plane as the back surface of the case,
The bypass tool for watt-hour meters according to claim 1 or 2.

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