JP2020076689A - Uninterruptible meter attachment tool - Google Patents

Abstract

To provide a technology which can surely prevent a short circuit failure in an erroneous connection state, in an uninterruptible meter attachment tool which can remove meters in an uninterruptible state by connectedly short-circuiting a power supply-side power feed cable and a load-side power feed cable.SOLUTION: An uninterruptible meter attachment tool comprises: a determination unit 5 for determining whether or not a power supply-side connection unit 20 and a load-side connection unit 30 are in correct connection states that the connection units are correctly connected to power feed cables, respectively; and a determination result display unit 3 for displaying a determination result of the determination unit 5. The uninterruptible meter attachment tool also comprises a relay unit 12 which is arranged at a contact point between the power supply-side connection unit 20 and the load-side connection unit 30 in a serial state serial to a manual switch 10a, and automatically switches the contact point between the power supply-side connection unit 20 and the load-side connection unit 30 to a closed state from an open state when the correct connection states are determined by the determination unit 5.SELECTED DRAWING: Figure 2

Description

  BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an uninterruptible meter replacement tool capable of short-circuiting a power supply cable and a load power supply cable and removing meters installed between them in an uninterruptible state.

The tool described in Patent Document 1 is known as the uninterruptible meter replacement tool.
The uninterruptible meter replacement tool described in Patent Document 1 includes a power supply side connection portion (power supply side connection terminal 4a) connected to a power supply side power supply cable (power supply side connection wire 2), and a load side power supply cable ( A load-side connecting portion (load-side connecting terminal 4b) connected to the load-side connecting wire 3), each connecting portion being connected to a corresponding power feeding cable, and a power-side connecting portion and a load. By connecting the power supply side power supply cable and the load side power supply cable, the meters (watt hour meter 1) interposed between the power supply side power supply cable and the load side power supply cable can be removed without interruption. ing.

  In addition, in the uninterruptible meter replacement tool described in Patent Document 1, a lamp (35, 36) that lights up when there is a potential difference between the mutually connected phases of the power supply side connection portion and the load side connection portion is provided. It is provided. That is, when the lamp is lit at the completion of the connecting work for connecting the respective connecting portions to the respective power feeding cables, it can be recognized that the respective phases of the respective cables are correctly connected. Then, the operator recognizes that the lamps are lit properly and that the connection is properly established, and then the manual switch (switches 17 and 18) capable of opening and closing the contacts between the power supply side connection portion and the load side connection portion is opened. Switch to the closed state. As a result, even if the meters are removed, the power supply cable and the load power cable are short-circuited via the uninterruptible meter replacement tool, so the power supply to the power load continues. Will be done.

Japanese Utility Model Publication No. 04-007572

  In the above-mentioned conventional uninterruptible meter replacement tool, even if the connection is not properly made at the time of completion of the connection work, the worker's body or other object unknowingly collides with the manual switch. Due to such reasons, the manual switch may be inadvertently operated from the open state to the closed state. If such an erroneous operation of the manual switch occurs, there is a possibility that a short-circuit accident such as a failure of the load-side electric device may occur.

  In view of this actual situation, the main problem of the present invention is an uninterruptible meter replacement tool capable of removing meters in a uninterruptible state by short-circuit connecting the power supply side power supply cable and the load side power supply cable, and an erroneous connection state. The point is to provide a technology that can reliably prevent a short-circuit accident in a vehicle.

A first characteristic configuration of the present invention is a power supply side connection portion connected to a power supply side power supply cable,
A load side connection part connected to the load side power supply cable,
A manual switch which is provided at a contact point between the power source side connecting portion and the load side connecting portion and which can be opened and closed,
The power supply side power supply cable by connecting the power supply side connection part and the load side connection part to the power supply side power supply cable and the load side power supply cable to electrically connect the power supply side connection part and the load side connection part. And an uninterruptible meter replacement tool that allows the meters installed between the load side power supply cable and the load side to be removed in an uninterruptible state,
A determination unit that determines whether or not the power supply-side connection unit and the load-side connection unit are in a positive connection state that is correctly connected to the power supply-side power supply cable and the load-side power supply cable,
With a determination result display unit that displays the determination result of the determination unit,
The contact between the power supply side connection part and the load side connection part is provided in series with the manual switch, and when the determination part determines that the positive connection state is established, the open state is automatically changed to the closed state. It has a relay section that switches to.

  According to this configuration, at the completion of the connecting work for connecting the respective connecting portions to the respective power feeding cables, if the connecting portions are not correctly connected to the power feeding cables, the determination unit is Therefore, it is determined that the connection is not in the normal connection state. The relay section provided at the contact point between the power supply side connection section and the load side connection section automatically changes from the open state to the closed state only when the determination section determines that the connection is in the positive connection state. Since the switching is performed, the contacts between the power supply side connection portion and the load side connection portion can be maintained in the open state in the above-mentioned erroneous connection state.

Furthermore, in the state in which it is determined by the determination unit at the time of completion of the connection work that it is in the positive connection state, the contact provided between the power supply side connection unit and the load side connection unit is provided in series with the relay unit. By switching the manual switch from the open state to the closed state, it is possible to short-circuit the power supply side power supply cable and the load side power supply cable via the manual switch. Then, it is possible to remove the meters or the like from the uninterruptible state in which the power supply to the power load is continued.
On the other hand, in the erroneous connection state other than the normal connection state, the relay section is maintained in the open state even when the manual switch is switched from the open state to the closed state. As a result, it is possible to reliably prevent a short circuit between the power supply cable and the load power supply cable.

  Therefore, according to the present invention, in the uninterruptible meter replacement tool capable of short-circuit connection between the power supply cable and the load power supply cable to remove the meters in an uninterruptible state, a short circuit accident in an erroneous connection state is ensured. Can be prevented.

A second characteristic configuration of the present invention includes a breaker that opens the contact when a current of a certain capacity flows to the contact between the power supply side connection section and the load side connection section,
The manual switch is a return manual switch capable of switching the shutoff unit from an open state to a closed state.

According to this configuration, when the power supply side power supply cable and the load side power supply cable are short-circuited in spite of the incorrect connection due to the failure of the determination unit or the relay unit, the short circuit When a certain amount of current flows through the contact point between the power supply side connection section and the load side connection section due to the connection, the contact is opened by the breaker section, so prevent the expansion of short circuit accidents. You can
Then, as a manual switch capable of opening and closing the contacts between the power source side connecting portion and the load side connecting portion, a manual switch for returning the relay portion can be used.

  In a third characteristic configuration of the present invention, the determination unit determines a connection of a power supply side connection unit to the power supply side power supply cable, and a connection of the load side connection unit to the load side power supply cable. And a phase determination unit that determines the phase difference of the load side power supply cable to which the load side connection part is connected to the power supply side power supply cable to which the power supply side connection part is connected. And a connection completion determining unit that determines whether or not the power source side connection determining unit, the load side connecting determining unit, and the phase determining unit determine whether or not the connection is in the normal connection state. ..

According to this configuration, in the power source side connection work for connecting the power source side power supply cable to the power source side power supply cable, by checking the determination result of the power source side connection determination unit, the power supply for each phase of the power source side power supply cable It is possible to recognize whether or not each phase of the side connection portion is normally connected in a conductive state. Similarly, in the load side connection work for connecting the load side power supply cable to the load side connection part, the load side connection part is connected to each phase of the load side power supply cable by checking the determination result of the load side connection determination part. It is possible to recognize whether or not each phase is normally connected in a conductive state.
Then, at the time of completion of these power supply side connection work and load side connection work, it is determined that the power supply side connection determination unit and the load side connection determination unit are normally connected in any determination result, and further, In the determination result of the phase determination unit, when it is determined that the power supply side power supply cable and the load side power supply cable are connected to the same phase, the power supply side connection unit and the load side connection unit supply the power supply side power supply. The connection completion determination unit can determine that the cable and the load-side power supply cable are correctly connected and are in the normal connection state.

A fourth characteristic configuration of the present invention is, in addition to the third characteristic configuration, a power distribution system determination that determines a power distribution system of the power supply cable based on the determination states of the power supply side connection determination unit and the load side connection determination unit. Section,
The connection completion determination unit determines whether or not it is in the normal connection state by using the determination result of the power distribution system determination unit.

  According to this configuration, the worker automatically performs the connection work for connecting the respective connection parts to the respective power supply cables corresponding thereto by the power distribution system determination part without requiring special setting work by the worker. It is possible to determine the power distribution system of the power supply cable, and use the determination result to determine whether the connection completion determination unit is in the normal connection state. Further, the power distribution system determination unit, depending on the determination state of the power supply-side connection determination unit and the load-side connection determination unit, such as the number of phases that are determined to be connected in the power supply-side connection determination unit and the load-side connection determination unit. The power distribution system can be easily determined.

Schematic external view of uninterruptible meter replacement tool Schematic circuit diagram showing the configuration of the uninterruptible meter replacement tool Block diagram showing the configuration of each determination unit in the control circuit Diagram showing the status of the tool installation process during replacement work Diagram showing the state of the power supply side connection process in replacement work Diagram showing the state of the load side connection process in replacement work Diagram showing the state of the loading process in replacement work The figure which shows the example of the display state in the judgment result indicator in replacement construction The figure which shows the example of the display state in the judgment result indicator in replacement construction The figure which shows the example of the display state in the judgment result indicator in replacement construction The figure which shows the example of the display state in the judgment result indicator in replacement construction The figure which shows the example of the display state in the judgment result indicator in replacement construction The figure which shows the example of the display state in the judgment result indicator in replacement construction The figure which shows the example of the display state in the judgment result indicator in replacement construction The figure which shows the example of the display state in the judgment result indicator in replacement construction

An embodiment of an uninterruptible meter replacement tool according to the present invention will be described with reference to the drawings.
1 to 3 show the configuration of the uninterruptible meter replacement tool 1 according to the present embodiment (hereinafter, may be referred to as "the actual replacement tool 1"), and FIG. 7 to FIG. 7 show the state of the replacement work of the electric energy meter EM (an example of meters) using the replacement tool 1, and FIGS. 8 to 15 show the determination in the replacement work. The example of a display state in the result display part 3 is shown. In the LED lamps shown in each of FIGS. 4 to 7 and FIGS. 8 to 15, those in the lit state are shaded and those in the unlit state are outlined.

As shown in FIGS. 1 and 6, the replacement tool 1 includes a power supply side connection cable 20 connected to the power supply side power supply cable SC and a load side connection cable 30 connected to the load side power supply cable LC. A tool body 2 is provided.
Then, the replacement tool 1 connects the power supply side connection cable 20 and the load side connection cable 30 to the power supply side power supply cable SC and the load side connection cable 30 to connect the power supply side connection cable 20 and the load side connection cable 30. By making it conductive, the power meter EM interposed between the power supply cable SC and the load power supply cable LC can be removed in an uninterruptible state.

Although details will be described later, for example, replacement work of the electric energy meter EM using the replacement tool 1 is executed in the following flow.
First, by hanging the hanging strap 19 (see FIG. 1) on the installation part of the electric energy meter EM, etc., the replacement tool 1 is installed in the vicinity of the electric energy meter EM to be replaced, as shown in FIG. The tool installation process is performed.
Next, as shown in FIG. 5, a power supply side connection step of connecting the power supply side connection cable 20 to the power supply side power supply cable SC is executed.
Next, as shown in FIG. 6, a load side connection step of connecting the load side connection cable 30 to the load side power supply cable LC is executed.

  Then, at the time of completion of the power source side connecting step and the load side connecting step, the power source side connecting cable 20 and the load side connecting cable 30 are correctly connected to the power source side feeding cable SC and the load side feeding cable LC. Suppose In this case, the connection completion lamp 59o arranged on the front surface of the tool body 2 is turned on. Then, when the lighting of the connection completion lamp 59o is confirmed, as shown in FIG. 7, a closing process for switching the manual switch 10a from the OFF state (open state) to the ON state (closed state) is executed.

  Then, the power supply side connection cable 20 connected to the power supply side power supply cable SC and the load side connection cable 30 connected to the load side power supply cable LC are short-circuited and connected. In this state, power is supplied from the power supply cable SC to the load power supply cable LC even when the power meter EM interposed between the power supply cable SC and the load power supply cable LC is removed. Will continue uninterrupted. Therefore, in such an uninterruptible state, the electric energy meter EM can be replaced with an inspected one or the like.

  In the replacement work of the electric energy meter EM as described above, the manual switch 10a may be erroneously operated despite the erroneous connection state in which the connection is not correctly made when the connection work is completed. Therefore, the replacement tool 1 has a characteristic configuration for surely preventing a short-circuit accident even when such an erroneous operation of the manual switch 10a occurs, and the replacement tool 1 includes the characteristic configuration. The detailed configuration and the like of the tool 1 will be described below.

  In the following description, the first electric wires S1 and L1 of the power supply cables SC and LC are voltage lines on the non-grounded side provided with a black insulating coating. The second electric wires S2 and L2 of the power supply cables SC and LC are ground-side neutral wires with a white insulating coating. The third electric wires S3, L3 of the power supply cables SC, LC are non-grounded voltage lines provided with a red insulating coating.

  On the other hand, regarding the connection cables 20 and 30 provided in the tool main body 2, the first electric wires 21 and 31 for the voltage wire with the black insulation coating and the neutral wires with the white insulation coating are also used. Of the second electric wires 22 and 32 and the third electric wires 23 and 33 for the voltage wires to which the red insulating coating is applied are configured as a three-wire type cable.

  As shown in FIG. 1, the ends of the electric wires 21, 22, 23, 31, 32, 33 of the respective phases of the connection cables 20, 30 are easily attached to the terminals T attached to the power supply cables SC, LC. A detachable plug P is attached to. The terminal T connects the wires S1, S2, S3, L1, L2, L3 to the wires S1, S2, S3, L1, L2, L3 of the respective phases of the power supply cables SC, LC while pressing the insulating coating. It is configured as a push-cut screw type terminal that is sandwiched to conduct electricity.

  That is, the terminal T is attached to the electric wires S1, S2, S3, L1, L2, L3 of the respective phases of the power supply cables SC, LC connected to the electric energy meter EM. Then, the plugs P of the electric wires 21, 22, 23, 31, 32, and 33 of the respective phases of the connection cables 20 and 30 are attached to the attached terminals T. As a result, the electric wires 21, 22, 23, 31, 32, 33 of the respective phases of the respective connection cables 20, 30 are connected to the electric wires S1, S2, S3, L1, L2 of the respective phases of the power supply cables SC, LC. , L3 are connected in a conductive state.

  As shown in FIG. 2, the tool body 2 has breakers at the contacts of the electric wires 21, 22, 23 of the respective phases of the power supply side connecting cable 20 and the electric wires 31, 32, 33 of the respective phases of the load side connecting cable 30. 10 and the electromagnetic relay 12 are provided in series. Further, there is provided a control circuit unit 5 and the like that executes various predetermined processes while measuring the potentials of the electric wires 21, 22, 23, 31, 32, 33 of the respective phases of the connection cables 20, 30.

  As shown in FIG. 2, the breaker 10 is installed at the contact points between the electric wires 21, 22, 23 of each phase of the power supply side connection cable 20 and the electric wires 31, 32, 33 of each phase of the load side connection cable 30. There is. The breaker 10 is configured as a breaker that opens the contact when a current having a constant capacity flows. Further, the breaker 10 is provided with a manual switch 10a for return that can be switched from the open state to the closed state. The manual switch 10a is arranged on the front surface of the tool body 2 as shown in FIG.

As shown in FIG. 2, the electromagnetic relay 12 is provided at the contact points between the electric wires 21, 22, 23 of each phase of the power supply side connection cable 20 and the electric wires 31, 32, 33 of each phase of the load side connection cable 30. ing. The electromagnetic relay 12 is configured as a relay unit that automatically opens and closes according to a control signal from the control circuit unit 5.
In the present embodiment, the breaker 10 is arranged on the power supply side and the electromagnetic relay 12 is arranged on the load side at the contact points of the electric wires 21, 22, 23 on the power supply side and the electric wires 31, 32, 33 on the load side. The arrangement order of these may be reversed.

  As shown in FIG. 2, the control circuit unit 5 determines whether or not the power supply side connection cable 20 and the load side connection cable 30 are correctly connected to the power supply side power supply cable SC and the load side power supply cable LC. It functions as a determination unit that determines whether or not. Further, as shown in FIG. 1, on the front surface of the tool body 2, there is provided a determination result display section 3 in which a plurality of LED lamps are arranged. The determination result display unit 3 is configured to display the determination result of the determination unit in which the control circuit unit 5 functions, in the form of turning on or off the respective LED lamps.

  As will be described later in detail, as shown in FIG. 1, the power source side (power source side connection cable 20 side) of the determination result display unit 3 has a first power source side connection determination lamp 51o and a second power source side connection determination. LED lamps such as the lamp 52o are arranged. In addition, LED lamps such as a first load side connection determination lamp 56o and a second load side connection determination lamp 57o are arranged on the load side (load side connection cable 30 side) of the determination result display unit 3. Further, on the center side of the determination result display unit 3, the first correctness determination lamp 53o, the first false determination lamp 53x, the second correctness determination lamp 54o and the second false determination lamp 54x, and the third correctness determination lamp 55o and LED lamps such as the third erroneous determination lamp 55x are arranged. In addition, LED lamps such as a connection completion lamp 59o are arranged at the upper left of the determination result display unit 3.

  As shown in FIG. 3, the power supply side connection determination sections 51 and 52, the load side connection determination sections 56 and 57, and the phase determination sections 53, 54 and 55, as the determination section in which the control circuit section 5 functions, A power distribution system determination unit 58 and a connection completion determination unit 59 are provided. The details of the determination unit and the determination result display unit that displays the determination result of the determination unit will be described below.

  The power supply side connection determination units 51 and 52 in which the control circuit unit 5 functions are configured to determine the connection of the power supply side connection cable 20 to the power supply side power supply cable SC in the power supply side connection step (see FIG. 5) described above. ing. As this determination unit, as shown in FIG. 3, a first power supply side connection determination unit 51 and a second power supply side connection determination unit 52 are provided.

The first power supply side connection determination unit 51 detects the presence or absence of a potential difference between the first electric wire 21 and the second electric wire 22 on the power supply side so that the first electric wire 21 and the second electric wire 22 are on the power supply side. It is determined whether or not the power supply cable SC is properly connected in a state where it is in good conduction.
That is, the worker connects the first electric wire 21 on the power supply side to the power supply cable SC (see FIG. 8) and then connects the second electric wire 22 on the power supply side to the power supply cable SC (see FIG. 9). ). Then, at this time point, if a potential difference is generated between the first electric wire 21 and the second electric wire 22, the first power supply side connection determination unit 51 causes the first electric wire 21 of the power supply side connection cable 20 and the first electric wire 21 to be connected to each other. Assuming that the two electric wires 22 are properly connected to the power supply side power supply cable SC, as shown in FIG. 9, the first power supply side connection determination lamp 51o is turned on.

  Therefore, if the first power supply side connection determination lamp 51o is lit at the time when the connection of the first electric wire 21 and the second electric wire 22 to the power supply side power supply cable SC is completed, the worker should make the connection. Can be recognized as appropriate. On the contrary, when the first power supply side connection determination lamp 51o is off, the worker recognizes that the connection is not appropriate, confirms the connection state, and takes corrective action such as reconnection. be able to.

The second power supply side connection determination unit 52 detects the presence or absence of a potential difference between the second electric wire 22 and the third electric wire 23 on the power supply side so that the second electric wire 22 and the third electric wire 23 are on the power supply side. It is determined whether or not the power supply cable SC is properly connected in a state where it is in good conduction.
That is, the worker connects the second electric wire 22 on the power supply side to the power supply side power supply cable SC (see FIG. 9) and then connects the third electric wire 23 of the power supply side connection cable 20 to the power supply side power supply cable SC ( (See FIG. 10). Then, at this point, if there is a potential difference between the second electric wire 22 and the third electric wire 23, the second power supply side connection determination unit 52 causes the second electric wire 22 and the second electric wire 22 of the power supply side connection cable 20 to come into contact with each other. Assuming that the three electric wires 23 are properly connected to the power supply cable SC, the second power supply connection determination lamp 52o is turned on as shown in FIG.

  Therefore, when the second power supply side connection determination lamp 52o is lit at the time when the connection of the second electric wire 22 and the third electric wire 23 to the power supply cable SC is completed, the worker makes the connection. Can be recognized as appropriate. On the contrary, when the second power supply side connection determination lamp 52o is turned off, the worker recognizes that the connection is not appropriate, confirms the connection state, and takes corrective action such as performing reconnection. be able to.

  On the other hand, the load-side connection determination units 56 and 57 in which the control circuit unit 5 functions determine the connection of the load-side connection cable 30 to the load-side power supply cable LC in the load-side connection step (see FIG. 6) described above. It is configured. As this determination unit, as shown in FIG. 3, a first load-side connection determination unit 56 and a second load-side connection determination unit 57 are provided.

The first load-side connection determination unit 56 detects whether or not there is a potential difference between the load-side first electric wire 31 and the second electric wire 32, and thus the first electric-wire 31 and the second electric wire 32 are connected to the load-side. It is determined whether or not the power supply cable LC is properly connected to the power supply cable LC with good conduction.
That is, the worker connects the first electric wire 31 on the load side to the power feeding cable LC on the load side (see FIG. 11), and then connects the second electric wire 32 on the load side to the power feeding cable LC on the load side (see FIG. 12). ). Then, at this time point, if a potential difference is generated between the first electric wire 31 and the second electric wire 32, the first load-side connection determination unit 56 causes the first electric wire 31 and the first electric wire 31 of the load-side connection cable 30 to move. Assuming that the two electric wires 32 are properly connected to the load side power supply cable LC, as shown in FIG. 12, the first load side connection determination lamp 56o is turned on.

  Therefore, if the first load-side connection determination lamp 56o is lit at the time point when the connection of the first electric wire 31 and the second electric wire 32 to the load-side power supply cable LC is completed, the worker makes the connection. Can be recognized as appropriate. On the contrary, when the first load-side connection determination lamp 56o is off, the worker recognizes that the connection is not appropriate, confirms the connection state, and takes corrective action such as reconnection. be able to.

The second load-side connection determination unit 57 detects the presence or absence of a potential difference between the load-side second electric wire 32 and the third electric wire 33, and thereby detects that the second electric wire 32 and the third electric wire 33 are on the load side. It is determined whether or not the power supply cable LC is properly connected to the power supply cable LC with good conduction.
That is, the worker connects the second electric wire 32 on the load side to the load side power supply cable LC (see FIG. 12) and then connects the third electric wire 33 of the load side connection cable 30 to the load side power supply cable LC ( (See FIG. 13). Then, at this time point, if there is a potential difference between the second electric wire 32 and the third electric wire 33, the second load-side connection determination unit 57 causes the second electric wire 32 of the load-side connection cable 30 and the second electric wire 32. Assuming that the three electric wires 33 are properly connected to the load side power supply cable LC, the second load side connection determination lamp 57o is turned on as shown in FIG.

  Therefore, if the second load-side connection determination lamp 57o is lit at the time when the connection of the second electric wire 32 and the third electric wire 33 to the load-side power supply cable LC is completed, the worker makes the connection. Can be recognized as appropriate. On the contrary, when the second load side connection determination lamp 57o is off, the worker recognizes that the connection is not appropriate, confirms the connection state, and takes corrective action such as reconnection. be able to.

  The phase determination units 53, 54, 55 on which the control circuit unit 5 functions perform the above-mentioned power supply side connection step (see FIG. 5) and then the above-mentioned load side connection step (see FIG. 6), The power supply side power supply cable SC to which the power supply side connection cable 20 is connected and the load side power supply cable LC to which the load side connection cable 30 is connected are configured to determine the phase difference. As the phase determination units 53, 54, 55, as shown in FIG. 3, a first phase determination unit 53, a second phase determination unit 54, and a third phase determination unit 55 are provided.

As shown in FIG. 11, the first phase determination unit 53 connects the first electric wire 21 of the power supply side connection cable 20 to the power supply side power supply cable SC and also connects the first electric wire 31 of the load side connection cable 30 to the load side power supply cable. By detecting the potential difference and the phase difference between the first electric wire 21 on the power supply side and the first electric wire 31 on the load side at the time of connection to the LC, each of the first electric wires 21 and 31 is connected to the power supply side power supply cable SC. Also, it is determined whether or not each of the load side power supply cables LC is connected to the electric wires S1 and L1 of the same phase.
That is, when there is no potential difference or phase difference between the first electric wire 21 and the first electric wire 31, each of the first electric wires 21 and 31 has the same phase as the electric wire S1. , L1, the first correct determination lamp 53o is turned on and the first false determination lamp 53x is turned off. On the contrary, when there is a potential difference or a phase difference between the first electric wire 21 and the first electric wire 31, each of the first electric wires 21 and 31 has a different phase. Assuming that the electric wires S2, S3, L2, and L3 are connected, the first correctness determination lamp 53o is turned off and the first erroneous determination lamp 53x is turned on.

  Therefore, when the first correctness determination lamp 53o is lit, the worker can recognize that the connection of the respective first electric wires 21 and 31 is appropriate. On the contrary, when the first erroneous determination lamp 53x is turned on, the operator recognizes that the connection of the first electric wires 21 and 31 is not appropriate, confirms the connection state, and performs reconnection. Corrective actions such as

As shown in FIG. 12, the second phase determination unit 54 connects the second electric wire 22 of the power supply side connection cable 20 to the power supply side power supply cable SC and also connects the second electric wire 32 of the load side connection cable 30 to the load side power supply cable. By detecting the potential difference and the phase difference between the second electric wire 22 on the power supply side and the second electric wire 32 on the load side at the time of connection to the LC, each of the second electric wires 22 and 32 is connected to the power supply side power supply cable SC. Also, it is determined whether or not each of the load side power supply cables LC is connected to the electric wires S2 and L2 of the same phase.
That is, when there is no potential difference or phase difference between the second electric wire 22 and the second electric wire 32, the second phase determination unit 54 determines that each of the second electric wires 22 and 32 has the same phase S2. , L2, the second correct determination lamp 54o is turned on and the second false determination lamp 54x is turned off. On the contrary, when there is a potential difference or a phase difference between the second electric wire 22 and the second electric wire 32, the second phase determination unit 54 determines that each of the second electric wires 22 and 32 has a different phase. Assuming that the wires are connected to the electric wires S1, S3, L1 and L3, the second correct determination lamp 54o is turned off and the second erroneous determination lamp 54x is turned on.

  Therefore, when the second correct determination lamp 54o is turned on, the worker can recognize that the connection of the respective second electric wires 22 and 32 is appropriate. On the contrary, when the second erroneous determination lamp 54x is turned on, the operator recognizes that the connection of the respective second electric wires 22 and 32 is not appropriate, confirms the connection state, and performs reconnection. Corrective actions such as

As shown in FIG. 13, the third phase determination unit 55 connects the third electric wire 23 of the power supply side connection cable 20 to the power supply side power supply cable SC and also connects the third electric wire 33 of the load side connection cable 30 to the load side power supply cable. By detecting the potential difference and the phase difference between the third electric wire 23 on the power supply side and the third electric wire 33 on the load side at the time of connection to the LC, each of the third electric wires 23 and 33 is connected to the power supply side power supply cable SC. Also, it is determined whether or not each of the load side power supply cables LC is connected to the electric wires S3 and L3 of the same phase.
That is, when there is no potential difference or phase difference between the third electric wire 23 and the third electric wire 33, the third phase determination unit 55 determines that each of the third electric wires 23 and 33 has the same phase as the electric wire S3. , L3, the third correct determination lamp 55o is turned on and the third erroneous determination lamp 55x is turned off. On the contrary, when a potential difference or a phase difference is generated between the third electric wire 23 and the third electric wire 33, the third phase determination unit 55 determines that each of the third electric wires 23 and 33 has a different phase. Assuming that the electric wires S1, S2, L1 and L2 are connected, the third correct determination lamp 55o is turned off and the third erroneous determination lamp 55x is turned on.

  Therefore, when the third correct determination lamp 55o is turned on, the worker can recognize that the connection of the respective third electric wires 23 and 33 is appropriate. On the contrary, when the third erroneous determination lamp 55x is turned on, the worker recognizes that the connection of the respective third electric wires 23 and 33 is not appropriate, confirms the connection state, and performs reconnection. Corrective actions such as

The connection completion determination unit 59 in which the control circuit unit 5 functions is, as shown in FIG. 3, the power supply side connection determination units 51, 52, the load side connection determination units 56, 57, and the phase determination units 53, 54, 55 described above. Based on the result of the determination, it is determined whether or not the power supply side connection cable 20 and the load side connection cable 30 are correctly connected to the power supply side power supply cable SC and the load side power supply cable LC. It is configured.
That is, as shown in FIG. 7 and FIG. 13, it is determined that the electric power lines 21, 22, and 23 of each phase of the power supply side connection cable 20 are properly connected to the power supply side power supply cable SC by the power supply side connection determination units 51 and 52. All the connection determination lamps 51o and 52o on the power supply side are lit up, and the load side connection determination sections 56 and 57 cause the electric wires 31, 32, and 33 of each phase of the load side connection cable 30 to be connected to the load side power supply cable LC. Is determined to be properly connected, all the connection determination lamps 56o and 57o on the load side are turned on, and the phase determination units 53, 54 and 55 cause the electric wires 21, 22, 23 of the power supply side connection cable 20 to be connected. And the electric wires 31, 32, 33 of the load-side connection cable 30 are all determined to be connected to the electric wires S1, S2, S3, L1, L2, L3 of the power supply cables SC, LC of the same phase, respectively. When the positive determination lamps 53o, 54o, and 55o are lit, the connection completion determination unit 59 determines that the connection in the normal connection state is completed, and lights the connection completion lamp 59o.

  Therefore, the electric wires 21, 22, 23, 31, 32, 33 of the respective phases of the connection cables 20, 30 on the power supply side and the load side are connected to the electric wires S1, S2 of the respective phases of the power supply cables SC, LC on the power supply side and the load side. When the connection completion lamp 59o is lit at the time of connection to S3, L1, L2, and L3, the worker determines that the power supply side connection cable 20 and the load side connection cable 30 are the power supply side power supply cable SC and the load side. It can be recognized that the power cable LC is properly connected. Then, as shown in FIG. 7, the operator who recognizes in this way performs the above-described closing process to switch the manual switch 10a from the OFF state (open state) to the ON state (closed state), thereby breaking the breaker. It is possible to switch 10 from the open state to the closed state.

  2 and 3, the control circuit unit 5 opens the electromagnetic relay 12 when the connection completion determination unit 59 determines that the connection is normally connected and the connection completion lamp 59o is lit. It is configured to automatically switch from the closed state to the closed state. That is, the electromagnetic relay 12 is provided in series with the manual switch 10a at the contact point between the power supply side connection cable 20 and the load side connection cable 30, and when the control circuit unit 5 determines that the connection is normal. It functions as a relay that automatically switches from the open state to the closed state. As a result, the power supply-side connection cable 20 connected to the power supply-side power supply cable SC and the load-side connection cable 30 connected to the load-side power supply cable LC are short-circuited and the amount of power in the uninterruptible state is high. The meter EM is ready to be removed.

On the other hand, the control circuit unit 5 determines that the connection completion determination unit 59 has not determined that the connection is in the normal connection state due to an erroneous connection or the like, and the connection completion lamp 59o is off. Is configured to be maintained in the open state without switching to the closed state.
Therefore, even if the manual switch 10a is erroneously operated from the open state to the closed state in this state, the contacts of the power supply side connection cable 20 and the load side connection cable 30 are maintained in the open state by the electromagnetic relay 12. In this case, a short circuit accident due to a wrong connection can be surely prevented.

  With reference to FIG. 3, the power distribution system determination unit 58 in which the control circuit unit 5 functions is specifically based on the determination states of the power supply side connection determination units 51 and 52 and the load side connection determination units 56 and 57. The power supply side connection determination units 51 and 52 and the load side connection determination units 56 and 57 are configured to determine the distribution system of the power supply cables SC and LC based on the number of phases determined to be connected. Then, the connection completion determination unit 59 determines whether or not it is in the normal connection state by using the determination result of the power distribution system determination unit 58.

That is, as illustrated in FIG. 10, the power distribution system determination unit 58 determines that all of the first electric wire 21, the second electric wire 22, and the third electric wire 23 included in the power supply side connection cable 20 are connected to the power supply side power supply cable SC. When it is determined by the side connection determination units 51 and 52, it is determined that the power distribution system of the power supply cables SC and LC is the single-phase three-wire system.
When the power distribution system determination unit 58 determines that the single-phase three-wire system is used, all the connection determination lamps 51o, 52o on the power supply side and the load side, as shown in FIG. When 56o and 57o are lit and all the positive determination lamps 53o, 54o, and 55o are lit, the connection completion determination unit 59 (see FIG. 3) causes the connection cables 20 and 30 to supply power to the single-phase three-wire system. It is determined that the connection cables 20 and 30 are correctly connected to the cables SC and LC, and the connection completion lamp 59o is turned on, and the electromagnetic relay 12 is automatically switched from the open state to the closed state. It will be.

On the other hand, as shown in FIG. 14, the power distribution system determination unit 58 determines that only the first electric wire 21 and the second electric wire 22 included in the power supply side connection cable 20 are connected to the power supply side power supply cable SC. After being determined by 51 (see FIG. 3), as shown in FIG. 15, the first electric wire 31 of the load-side connection cable 30 is fed to the load-side power supply without the third electric wire 23 of the power-source-side connection cable 20 being connected. When it is determined by the first load side connection determination unit 56 (see FIG. 3) that the power supply cables SC and LC are connected to the cable LC, the power distribution system of the power supply cables SC and LC is determined to be a single-phase two-wire system.
In this way, when the power distribution system determination unit 58 determines that it is the single-phase two-wire system, the first power supply side connection determination lamp 51o and the first load side connection determination lamp 56o are turned on as shown in FIG. In addition, when the first correctness determination lamp 53o and the second correctness determination lamp 54o are lit, the connection completion determination unit 59 (see FIG. 3) causes the connection cables 20 and 30 to be the single-phase two-wire power supply cable SC. , It is determined that the connection cables 20 and 30 are correctly connected to the LC, and the connection completion lamp 59o is turned on, and the electromagnetic relay 12 is automatically switched from the open state to the closed state. Become.

[Another embodiment]
Another embodiment of the present invention will be described. The configurations of the respective embodiments described below are not limited to being applied individually, but may be applied in combination with the configurations of other embodiments.

(1) In the above embodiment, an example of removing the electric energy meter EM in the uninterruptible state by using the uninterruptible meter replacement tool 1 in the replacement work of the electric energy meter EM has been described. Even when replacing the meters other than the electric energy meter EM interposed between the SC and the load-side power supply cable LC, the uninterruptible meter replacement tool 1 is used to perform uninterrupted operation. Meters can be removed.

(2) In the above embodiment, the breaker 10 having the manual switch 10a is provided, but a manual switch may be provided separately from the breaker, or the breaker may be omitted and only the manual switch may be provided.

(3) In the above embodiment, the power distribution system determination unit 58 that determines the power distribution system of the power supply cables SC and LC is provided. However, in the case where the power distribution system of the power supply cables is specified in advance, the power distribution system determination unit 58 is provided. You can omit it.

1 Uninterruptible meter replacement tool 3 Judgment result display unit 5 Control circuit unit (judgment unit)
10 breakers (blocking section)
10a Manual switch 12 Electromagnetic relay (relay section)
20 Power supply side connection cable (power supply side connection part)
30 Load side connection cable (load side connection part)
51, 52 Power supply side connection determination section 53, 54, 55 Phase determination section 56, 57 Load side connection determination section 58 Distribution method determination section 59 Connection completion determination section EM Electric energy meter (meters)
LC Load side power supply cable SC Power supply side power supply cable

Claims (4)

A power supply side connection part connected to the power supply side power supply cable,
A load side connection part connected to the load side power supply cable,
A manual switch which is provided at a contact point between the power source side connecting portion and the load side connecting portion and which can be opened and closed,
The power supply side power supply cable by connecting the power supply side connection part and the load side connection part to the power supply side power supply cable and the load side power supply cable to electrically connect the power supply side connection part and the load side connection part. And an uninterruptible meter replacement tool that allows the meters installed between the load side power supply cable and the load side to be removed in an uninterruptible state,
A determination unit that determines whether or not the power supply-side connection unit and the load-side connection unit are in a positive connection state that is correctly connected to the power supply-side power supply cable and the load-side power supply cable,
With a determination result display unit that displays the determination result of the determination unit,
The contact between the power supply side connection part and the load side connection part is provided in series with the manual switch, and when the determination part determines that the positive connection state is established, the open state is automatically changed to the closed state. An uninterruptible meter replacement tool with a relay section that switches to. A contact portion between the power source side connecting portion and the load side connecting portion, and a disconnecting portion that opens the contact when a current of a certain capacity flows,
The uninterruptible meter replacement tool according to claim 1, wherein the manual switch is a return manual switch capable of switching the shutoff unit from an open state to a closed state.   A power supply side connection determination unit that determines whether the power supply side connection unit connects to the power supply side power supply cable; and a load side connection determination unit that determines connection of the load side connection unit to the load side power supply cable. A phase determination unit that determines the phase difference of the load side power supply cable in which the load side connection unit is connected to the power supply side power supply cable in which the power supply side connection unit is connected, and the power supply side connection determination unit, The uninterruptible meter pickup according to claim 1 or 2, further comprising: a load-side connection determination unit, and a connection completion determination unit that determines whether or not the normal connection state is established based on a determination result of the phase determination unit. Replacement tool. A power distribution system determination unit that determines a power distribution system of the power supply cable based on a determination state in the power supply side connection determination unit and the load side connection determination unit,
The uninterruptible meter replacement tool according to claim 3, wherein the connection completion determining unit determines whether or not the power supply system is in the normal connection state by using a determination result of the power distribution system determining unit.

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