KR102259502B1 - Leakage current measurement device - Google Patents

Abstract

Leakage current measuring apparatus of the present invention is located inside the junction box, the connection portion having a connection material for connecting the wires of the distribution line; an injection part having one end connected to the connection part, the injection part being formed to allow the inflow of water into the connection part; a wire part having one end connected to the connection part and formed so that a leakage current generated in the connection material can flow; and a measuring unit connected to the other end of the injection unit and the other end of the electric wire unit and formed on the cover of the junction box to measure the magnitude of the leakage current when the leakage current generated in the connecting material flows through the electric wire unit.

Description

Leakage Current Measurement Device {LEAKAGE CURRENT MEASUREMENT DEVICE}

The present invention relates to a leakage current measuring device, and more particularly, to a leakage current measuring device for measuring a leakage current of a low voltage line inside an underground low voltage junction box.

An underground low voltage junction box is an electrical installation required to interconnect underground wires (cables). The underground low-voltage junction is used by connecting the low-voltage cable of the underground distribution line underground or burying it in a branching place.

The underground low-pressure junction box is a small junction box of a plastic structure, covered with a plastic or steel lid.

In recent years, as the aesthetics of downtown are emphasized, the number of installation places of underground low voltage junction boxes is increasing every year due to underground distribution of distribution lines.

If you look at the installation location, it is installed at the branch connection or straight connection point of the underground low voltage cable, the entry point of the underground low voltage customer, and other places necessary for the site conditions.

Among them, the trunk line is large in size and is mainly installed on sidewalks where people pass frequently or on back roads with little traffic of heavy objects. The entrance is installed in the customer's premises, and if unavoidable, it is installed in a place close to the entry point.

The existing underground low-voltage junction box has a risk of general safety accidents if a failure occurs due to overheating of the connection point or grounding of the lid according to changes in the operating environment.

As an inspection method to prevent such safety accidents, check the installation status of the connection material during heavy rain, whether it is suitable through leakage current and earth voltage measurement, whether the junction box is damaged and dirt is attached, whether the frame is grounded, and whether an insulating rubber plate is installed, etc. There is this.

In particular, if the leakage current and ground voltage of the underground low voltage junction box exceed a certain standard, it causes a fatal risk to pedestrians.

Accordingly, in the case of measurement of leakage current and earth voltage, the leakage current and earth voltage are measured once every two years. In case of heavy rain, areas that are prone to flooding or areas prone to flooding are inspected once a year. In this case, the specified value is less than 10mA for leakage current and less than 10V for ground voltage.

In order to measure the leakage current and the earth voltage of the underground low voltage junction box, first, the lid of the underground low voltage junction box is opened and dirt in the junction box is removed. Then, wet the taped part of the wire (cable) connection point with water, wrap it with aluminum foil, and measure the leakage current and earth voltage using a measuring device.

In this case, it takes a lot of time to remove the dirt in order to measure the leakage current and the earth voltage. In addition, there is a problem in that the working time is prolonged in the process of injecting moisture into the taping part of the connection point and wrapping the aluminum foil, and there is a risk of electric shock.

It is an object of the present invention to provide a leakage current measuring device having a structure capable of solving the above-described problems.

First, when a user measures leakage current and earth voltage, an object of the present invention is to provide a leakage current measuring device capable of measuring leakage current and earth voltage without opening the cover of the junction box.

In addition, when the user measures the leakage current and the earth voltage, since the cover of the junction box is not opened, an object of the present invention is to provide a reduction in working time.

In addition, an object of the present invention is to provide a leakage current measuring device capable of preventing an electric shock accident due to water injection when a user measures the leakage current and the earth voltage.

In addition, an object of the present invention is to provide a leakage current measuring device capable of measuring leakage current and earth voltage without using an external professional service.

In addition, when a user measures the leakage current and the earth voltage, the purpose is to provide a leakage current measuring device that can measure the leakage current and the earth voltage at any time by avoiding the cumbersome work process.

Leakage current measuring apparatus for achieving the object of the present invention is located inside the junction box, the connection portion having a connection material for connecting the wires of the distribution line; an injection part having one end connected to the connection part, the injection part being formed to allow the inflow of water into the connection part; a wire part having one end connected to the connection part and formed so that a leakage current generated in the connection material can flow; and a measuring unit connected to the other end of the injection unit and the other end of the electric wire unit and formed on the cover of the junction box to measure the magnitude of the leakage current when the leakage current generated in the connecting material flows through the electric wire unit.

According to an example related to the present invention, the connection part may include an absorbent material that surrounds the connection material and can absorb the introduced water.

According to another example related to the present invention, the connection part may include a grid-shaped shield wire surrounding the absorbent material.

According to another example related to the present invention, the injection unit, water is injected and the injection port formed in the measuring unit; a first packing connected to the inlet and fixed to the cover of the junction box; a pipe through which the injected water moves; a connection part connecting the first packing and the pipe; and a discharge part connected to the pipe and discharging the introduced water to the connection part.

According to another example related to the present invention, the discharge unit may have holes disposed at predetermined intervals on the exterior thereof, and the water may be discharged through the holes.

According to another example related to the present invention, the discharge unit may include a fixing device formed at a connection portion of the pipe and the discharge unit to fix the discharge unit to the connection unit and coupled to the connection unit.

According to another example related to the present invention, the electric wire unit, a terminal connected to the measuring unit to measure voltage and current; a second packing for fixing to the cover of the junction box; and an outgoing wire having one end connected to the shield wire and the other end connected to the measuring unit, through which the leakage current flows. and a coupling part for coupling the second packing and the outgoing wire.

According to another example related to the present invention, the connection part may include a temperature sensor configured to detect temperature information of the surface of the connection material.

According to another example related to the present invention, the wire unit may further include a coupling wire having one end coupled with the temperature sensor and the other end coupled with the measuring unit.

According to another example related to the present invention, the measuring unit may further include a temperature display unit for displaying the temperature of the surface of the connection material sensed by the temperature sensor.

According to another example related to the present invention, it may include a moisture sensor attached to a predetermined height of the inner wall of the junction box, configured to detect the level of influent water flowing into the junction box.

According to another example related to the present invention, the electric wire may further include a connecting wire having one end connected to the moisture sensor and the other end connected to the measuring unit.

According to another example related to the present invention, the measuring unit may further include a moisture display unit for displaying whether the level of the inflow water inside the junction box measured by the moisture sensor is detected.

According to another example related to the present invention, the measuring unit may include a ground terminal, and the ground terminal may be connected to a ground point outside the junction box through a ground wire.

According to the present invention, the following effects can be achieved.

First, since the leakage current measuring device has a wire part and an injection part, it is possible to measure the leakage current and the earth voltage without opening the cover of the junction box.

Accordingly, since the user does not directly spray water on the connecting material, the risk of electric shock is reduced.

In addition, the absorbent present in the connection part of the leakage current measuring device absorbs a small amount of water for a certain period of time, and the water absorbed by the absorber evaporates and disappears after a period of time.

Accordingly, there is no need for the user to directly remove the injected water by opening the cover of the junction box. Accordingly, work efficiency can be improved when measuring leakage current and earth voltage.

In addition, since the user does not open the cover of the junction box when measuring leakage current and earth voltage, there is no need to remove dirt inside the junction box every time leakage current and earth voltage are measured.

Therefore, there is an effect that the user can further reduce the work time that has been taken longer due to the conventional removal of dirt.

In addition, since a temperature sensor exists on the surface of the connecting material, the temperature of the surface of the connecting material is displayed in the temperature display part of the measuring unit.

Therefore, it is possible to determine the possibility that the leakage current is occurring without directly measuring the leakage current and the earth voltage, so that the probability of preventing the occurrence of a safety accident is further increased.

In addition, a moisture sensor is attached to a predetermined height of the inner wall of the junction box. If there is influent water flowing into the junction box, the moisture sensor detects it when the water level exceeds a certain level.

Therefore, when the influent water flows into the junction box and the water level rises to a height near the connection material of the low-voltage wire (cable), the moisture sensor detects it and displays it on the moisture display part of the measurement unit. Accordingly, the user can prevent the occurrence of an electric shock accident due to leakage current generated from the junction material and the inflow water inside the junction box.

1 is a perspective view showing a conventional underground low-pressure junction box.
Figure 2 is a perspective view showing an underground low-pressure junction box according to an embodiment of the present invention.
3 is a perspective view showing the injection unit of the underground low-pressure junction box shown in FIG.
Figure 4 is a perspective view showing the electric wire of the underground low-voltage junction box shown in Figure 2;
5 is a perspective view illustrating a measurement unit of the underground low-pressure junction box shown in FIG. 2 .
FIG. 6 is a front view of the measuring unit shown in FIG. 5 .
7 is a conceptual diagram illustrating a combination of the injection unit shown in FIG. 3 and the wire unit shown in FIG. 4 .
FIG. 8 is a conceptual diagram illustrating another example of the electric wire unit shown in FIG. 4 .
9 is a conceptual diagram illustrating another example of the underground low-pressure junction box shown in FIG. 2 .
10 is a conceptual diagram illustrating another example of the underground low-pressure junction box shown in FIG. 2 .

Hereinafter, the leakage current measuring apparatus 10 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the present specification, the same and similar reference numerals are assigned to the same and similar components in different embodiments, and a redundant description thereof will be omitted.

In the following description, in order to clarify the characteristics of the present invention, descriptions of some components may be omitted.

Also, a structure applied to one embodiment may be equally applied to another embodiment as long as there is no structural or functional contradiction in the different embodiments.

The singular expression includes the plural expression unless the context clearly dictates otherwise.

The accompanying drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed in this specification is not limited by the accompanying drawings, and all changes and equivalents included in the spirit and scope of the present invention It should be understood to include water or substitutes.

Hereinafter, the configuration and operation process of the leakage current measuring apparatus 10 according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 9 .

1 is a perspective view showing a conventional underground low-pressure junction box (1a).

Referring to FIG. 1 , the underground distribution line is divided into extra high voltage and low voltage distribution lines (cables), and when the supply distance increases, the electric wire a3 is inevitably connected. The term 'connection material (101a)' of the conventional underground low-voltage junction box 1a mentioned in the following description refers to a portion insulated by covering the connection point with an insulating cover in the case of the low-voltage wire 3a and filling the inside with resin or silicon, etc. to be defined as

In the case of the underground low-voltage wire 3a, a function to detect and block a short circuit is not provided due to concerns about power failure, so if a short circuit occurs in the connection material 101a and an electric field is formed in the surrounding area, a very dangerous situation occurs. There are problems that lead to human accidents.

Accordingly, an insulating rubber plate was installed between the insulating lid and the junction box 1a and the connection material 101a was used as a waterproof type, but damage occurs over time after installation, which is not the ultimate solution.

Therefore, regular measurement of leakage current and earth voltage is required, and leakage current and earth voltage are measured once every two years. In case of heavy rain, areas that are prone to flooding or areas prone to flooding are inspected once a year. In this case, the specified value is less than 10mA for leakage current and less than 10V for ground voltage.

To measure the leakage current and the earth voltage of the underground low-voltage junction box 1a, first open the cover 2a of the underground low-voltage junction box 1a and remove the dirt in the junction box 1a. Then, the taped portion of the connecting material 101a of the electric wires 3a was wetted with water, wrapped in aluminum foil, and then the leakage current and the earth voltage were measured using a measuring device.

2 is a perspective view showing an underground low-pressure junction box 1 according to an embodiment of the present invention, and FIG. 3 is a perspective view showing the injection unit 110 of the underground low-pressure junction box 1 shown in FIG. , FIG. 4 is a perspective view showing the electric wire part 120 of the underground low-voltage junction box 1 shown in FIG. 2 .

2 to 4 , the leakage current measuring apparatus 10 according to the illustrated embodiment includes a connection part 100 , an injection part 110 , a wire part 120 , and a measurement part 130 . The term 'connection material 101' of the underground low-voltage junction box (1) referred to in the following description refers to a portion that is insulated by covering the connection point with an insulating cover and filling the inside with resin or silicone in the case of the low-voltage wire (3). define.

The connection part 100 is present in the underground low-pressure junction box (1). The junction box 1 has a general rectangular parallelepiped shape, but any shape is possible and exists underground. A hole is made in both sides of the junction box (1) and the low voltage wire (3) enters the inside of the junction box (1).

The low-voltage wires 3 coming from a predetermined space formed inside the junction box 1 are connected by the connection material 101 .

The injection unit 110 includes an injection port 111 , a first packing 112 , a pipe 113 , a connection unit 114 , and an exhaust unit 140 .

In the illustrated embodiment, the injection hole 111 is formed in the measurement unit 130 provided in the cover 2 of the junction box (1). Water 4 may be injected into the electric wire part 120 to be described later through the injection hole 111 .

Although not shown, a lid may be installed on the inlet 111 to open or close the inlet 111 . Through this, it is possible to prevent the water 4 from being injected into the injection unit 110 in an unintended situation.

The first packing 112 is connected to the inlet 111 and is configured so that the inlet 110 is fixed to the cover 2 of the junction box 1 .

In addition, if a gap exists between the cover 2 of the junction box 1 and the first packing 112 , the influent water may flow into the interior of the junction box 1 . Therefore, the first packing 112 is inserted into the cover 2 of the junction box 1 to maintain airtightness. And, since the first packing 112 should not be deformed even in the external environment, it is preferable to be made of a durable material.

For example, the first packing 112 may be made of synthetic rubber. However, the material of the first packing 112 is not limited to synthetic rubber, and may be configured by combining iron, copper, or an alloy thereof.

The first packing 112 may have a hole formed in the center so that the water 4 injected into the inlet 111 may pass.

In the illustrated embodiment, the connecting portion 114 connects the first packing 112 and the tube 113 to be described later. In this case, the connection part 114 may have an inner diameter that gradually decreases along a direction away from the first packing 112 .

The pipe 113 may serve as a path through which the water 4 injected through the inlet 111 moves to the electric wire 120 .

The tube 113 may be made of a deformable material. For example, the tube 113 may be formed of a flexible hose made of rubber or the like. For this reason, the position at which the injection hole 111 and the discharge part 140 to be described later are provided can be arbitrarily adjusted. In addition, since rubber has insulating properties, it is effective in preventing safety accidents due to electric shock when measuring leakage current and earth voltage.

The outer diameter of the connecting portion 114 of the portion that is located in the opposite direction to the first packing 112 and where the connecting portion 114 and the tube 113 is connected is smaller than the inner diameter of the tube 113 . For this reason, the inlet 111 , the first packing 112 , and the water 4 flowing along the connection part 114 are less likely to leak at the point where the connection part 114 and the pipe 113 meet.

The discharge unit 140 discharges the water 4 to the absorbent material 102 of the connection unit 100 . As shown, the discharge unit 140 is located in the opposite direction of the connection unit 114 and is connected to the pipe 113 . And the water 4 injected into the inlet 111 reaches the discharge unit 140 through the first packing 112 , the connection unit 114 , and the pipe 113 .

The inner diameter of the portion connected to the tube 113 of the discharge unit 140 is greater than the outer diameter of the tube 113 of the corresponding portion. Due to this, the possibility of water leakage when the water 4 flows from the pipe 113 to the discharge unit 140 is reduced. Accordingly, there is an effect of reducing unnecessary waste of water 4 and lowering the risk of electric shock when measuring leakage current and earth voltage.

The discharge unit 140 has an outer diameter and an inner diameter that are smaller as the distance from the tube 113 is increased. For this reason, the amount of water 4 discharged to the absorbent 102 of the connection part 100 can be adjusted to a small amount.

The discharge unit 140 includes a hole 141 and a fixing device 142 .

A plurality of holes 141 are formed at predetermined intervals on the exterior of the discharge unit 140 . The water 4 introduced into the discharge unit 140 through the pipe 113 through the hole 141 may be discharged in a small amount to the absorbent material 102 of the connection unit 100 in the same area.

The fixing device 142 is formed at the connection portion between the discharge unit 140 and the pipe 113 , and serves to fix the discharge unit 140 in the absorber 102 of the connection unit 100 .

The wire part 120 is a part through which the leakage current generated in the connection material 101 flows. Users should be careful of electric shock due to leakage current.

The wire unit 120 is configured such that the leakage current generated in the connection material 101 is transmitted to the measurement unit 130 to measure the leakage current and the earth voltage.

To this end, the wire part 120 is electrically connected to the shield wire 103 of the connection part 100 .

The wire part 120 includes a terminal 121 , a second packing 122 , and an outgoing wire 123 .

The terminal 121 is connected to a measurement unit 130 to be described later in order to measure the leakage current and the earth voltage generated in the connection material 101 .

Since the terminal 121 is connected to the measuring unit 130 , it is possible to measure the leakage current and the earth voltage without opening the junction box 1 . Therefore, it is more convenient to measure than the existing underground low-pressure junction box (1).

The second packing 122 is configured such that the injection unit 110 is fixed to the cover 2 of the junction box 1 .

In addition, if there is a gap between the cover 2 of the junction box 1 and the second packing 122 , the influent water may flow into the interior of the junction box 1 . Therefore, the second packing 122 is inserted into the cover 2 of the junction box 1 to maintain airtightness. In addition, the second packing 122 should not be deformed even in the external environment, so it is configured to be made of a durable material.

For example, the second packing 122 may be made of synthetic rubber. However, it is not limited to synthetic rubber, and it may be configured by combining iron, copper, or an alloy thereof.

A hole is formed in the center of the second packing 112 so that a terminal 121 connected to an outgoing wire 123, which will be described later, protrudes.

In the illustrated embodiment, the coupling part 124 connects the second packing 122 and an outgoing wire 123 to be described later. At this time, the coupling portion 124 may have an inner diameter that gradually decreases along a direction away from the second packing 122 .

The lead wire 123 is a wire through which the leakage current generated in the connection material 101 flows.

The lead wire 123 has one end connected to the shield wire 103 and the other end connected to the terminal 121 .

For example, the lead wire 123 may be formed of a copper wire having a diameter of 7 mm and an outer diameter of 2 mm. However, the present invention is not limited thereto.

The leakage current generated in the connection material 101 energizes the shield wire 103 due to the water 4 absorbed by the absorber 102 . Accordingly, a leakage current flows through the lead wire 123 connected to the shield wire 103 and is transmitted to the terminal 121 . Therefore, when an ammeter or a voltmeter is connected to the terminal 121, the leakage current and the earth voltage can be measured.

Measuring part 130 is formed in the cover (2) of the junction box (1). The user can observe various measurement data through the measurement unit 130 without opening the cover 2 .

The measurement unit 130 includes an injection port 111 of the injection unit 110 , a terminal 121 of the wire unit 120 , a temperature display unit 131 , a moisture display unit 132 , a recess unit 133 , and a cover 134 . ), and a ground terminal 135 .

The injection hole 111 is a part capable of injecting moisture into the connection part 100 .

The terminal 121 may connect an ammeter for measuring the leakage current of the connection material 101 or connect a part of an electrode of the voltmeter for measuring the earth voltage.

The temperature display unit 131 is a portion that displays information about the temperature of the surface of the connection material 101 sensed by the temperature sensor 104, which will be described later. The moisture display unit 132 is a part that displays information about the level of influent water flowing into the junction box 1 sensed by the moisture sensor 105 to be described later.

The recessed portion 133 is formed in the cover 2 of the junction box 1 . The injection hole 111 , the terminal 121 , the temperature display unit 131 , the moisture display unit 132 , and the ground terminal 135 are located inside the recess.

The cover 134 is formed in the recess 133 to block the outside from the recess 133 and can be opened and closed.

The ground terminal 135 is formed in the measurement unit 130 to measure the ground voltage. The ground terminal 135 may be connected to the ground point 5 provided on the outside of the junction box 1 through the ground wire 127 .

The grounding wire 127 connected to the grounding terminal 135 and the inside of the junction box 1 may pass through the wall surface of the junction box 1 and be connected to the grounding point 5 .

The portion included in the measurement unit 130 for measurement is not limited to the terminal 121, the temperature display unit 131, the moisture display unit 132, and the ground terminal 135. parts can be added.

FIG. 5 is a perspective view showing a measuring part of the underground low-pressure junction box 1 shown in FIG. 2 , and FIG. 6 is a front view of the measuring part shown in FIG. 5 .

Hereinafter, the measuring unit 130 of the leakage current measuring apparatus 10 according to an embodiment of the present invention will be described in detail with reference to FIGS. 5 and 6 .

The measuring unit 130 measures various kinds of information inside the junction box 1 and displays the information. For example, information such as the temperature of the surface of the connection material 101 and the level of the inflow water flowing into the junction box 1 is displayed. At this time, the information to be measured is not limited to the temperature and the water level.

The measuring unit 130 is located on the cover 2 of the junction box 1 . Specifically, it may be formed in the recess 133 provided in the cover (2). The cross section of the recess 133 may be rectangular as shown, but is not limited thereto.

As illustrated, a cover 134 may be formed in the recess 133 in which the measurement unit 130 is located. The cover 134 can be opened and closed. Accordingly, when the cover 134 is closed, it is possible to prevent the measurement unit 130 from being damaged by external factors.

Water 4 for measuring leakage current and earth voltage may be put into the inlet 111 of the injection unit 110 . The user can put the water 4 directly into the inlet 111 of the measuring unit 130 without having to open the cover 2 of the junction box 1, so that the working time is reduced compared to the conventional underground low-pressure junction box 1 It has the advantage of being shortened.

Although the first packing 112 connected to the injection hole 111 passes through the cover 2, there is an effect that a gap is not formed because the cover 2 and the injection unit 110 are in close contact with each other. Therefore, foreign substances do not easily enter the inside of the junction box (1).

The injection hole 111 may have any shape capable of injecting water 4 . The position of the injection hole 111 in the measurement unit 130 is not limited to the illustrated bar.

Although not shown, an opening/closing member may be formed in the injection hole 111 . In addition, the opening and closing member may be formed of an insulating material. For this reason, it is possible to prevent an electric shock accident when the leakage current flows through the tube 113 and the user comes into contact with the inlet.

The terminal 121 is a piece of metal attached to connect the electrode to the output portion of the outgoing wire 123 . The terminal 121 is formed to protrude a predetermined length from the recess 133 .

An ammeter for measuring a leakage current generated in the connection material 101 may be connected to the terminal 121 , or a part of an electrode of a voltmeter for measuring a ground voltage may be connected to the terminal 121 .

The position of the terminal 121 in the measurement unit 130 is not limited to the illustrated bar.

Although the second packing 122 connected to the terminal 121 passes through the cover 2 , there is an effect that a gap is not formed because the cover 2 and the electric wire 120 are brought into close contact with each other. Therefore, foreign substances do not easily enter the inside of the junction box (1).

The temperature display unit 131 may have any shape capable of displaying information on the temperature of the surface of the connecting material 101 . The position of the temperature display unit 131 in the measurement unit 130 is not limited to the illustrated bar.

The moisture display unit 132 may have any shape capable of displaying information on the level of the influent flowing into the junction box 1 . The position of the moisture display unit 132 in the measurement unit 130 is not limited to the illustrated bar.

The ground terminal 135 may be provided in the measurement unit 130 to measure the ground voltage. The ground wire 127 connected to the ground terminal 135 passes through the cover 2 . And it is connected to the grounding point (5) formed in the ground through the inner wall surface of the junction box (1). For this reason, it is possible to prevent a situation in which the ground wire 127 is exposed to the ground and damaged.

7 is a conceptual diagram illustrating a combination of the injection unit 100 shown in FIG. 3 and the electric wire unit 120 shown in FIG. 4 .

Referring to FIG. 7 , the discharge unit 140 is positioned inside the absorbent material 102 . The fixing device 142 is sandwiched between the shield wires 103 of the connection part 100 so as not to move. Due to this, the water 4 discharged from the groove 141 of the discharge unit 140 is transferred to the absorbent 102 .

A small amount of water 4 is introduced into the inlet 111 to measure the leakage current. At this time, a small amount of water 4 absorbed by the absorbent 102 is evaporated after a certain period of time.

An end of the lead wire 123 is connected to the shield wire 103 . For this reason, the leakage current flowing to the shield wire through the water 4 absorbed by the absorbent 102 is conducted to the lead wire 123 .

A portion where the lead wire 123 and the shield wire 103 are connected is formed to be separated from the discharge part 140 by a predetermined distance. This is because, when the connected portion and the position where the discharge portion 140 is fixed to the absorbent 102 are close, the water 4 may directly contact the outgoing wire 123 and cause a fire accident.

FIG. 8 is a conceptual diagram illustrating another example of the electric wire unit 120 shown in FIG. 4 .

A temperature sensor 104 is attached to the surface of the connection material 101 , and a coupling wire 125 is coupled to the temperature sensor 104 .

When a leakage current occurs in the connection material 101 , the temperature of the surface of the connection material 101 may increase, and the temperature sensor 104 is used to measure the temperature.

When the distance between the part where the discharge part 140 is fixed to the absorber 102 and the temperature sensor 104 attached to the surface of the connection material 101 is close, the temperature of the surface of the connection material 101 may be measured lower than the actual temperature. . Therefore, the temperature sensor 104 is attached to the discharge unit 140 at a predetermined interval.

As shown in FIG. 8 , the coupling wire 125 may be connected to the coupling part 124 together with the outgoing wire 123 . And the coupling wire 125 may protrude through the coupling part 124 and the second packing 122 in order. The protruding coupling wire 125 is coupled to the temperature display unit 131 .

Although not shown, the coupling wire 125 may be coupled to the temperature display unit 131 directly through the cover 2 without being connected to the coupling unit 124 .

9 is a conceptual diagram illustrating another example of the underground low-pressure junction box 1 shown in FIG. 2 .

Referring to FIG. 9 , information about the temperature of the surface of the connection material 101 sensed by the temperature sensor 104 is transmitted to the temperature display unit 131 located in the measurement unit through the coupling wire 125 .

When leakage current occurs, the temperature of the surface of the connection material 101 may increase due to this. In this case, information about the temperature displayed on the temperature display unit 131 will be higher than usual. That is, the user can open the junction box 1 and determine the possibility of leakage current without directly looking at the connection material 101 .

10 is a conceptual diagram illustrating another example of the underground low-pressure junction box 1 shown in FIG. 2 .

Referring to FIG. 10 , the moisture sensor 105 may detect the level of the influent flowing into the junction box 1 .

Since most of the water 4 artificially injected by the user through the inlet 111 will be absorbed by the absorbent 102 and then evaporate, the effect on the moisture sensor 105 will be less. However, when heavy rain or the like occurs, the inflow water may invade the inside of the junction box 1, and thus, when the connection material 101 is submerged in the inflow water, the risk of a safety accident may increase. Therefore, the moisture sensor 105 detects the water level of the inflow water inside the junction box 1 to prevent this.

The moisture sensor 105 for detecting the water level is mounted on the inner wall of the junction box (1). Specifically, in order to prevent the connection material 101 from being submerged by inflow water, it is preferable to install it at a lower position than the connection material 101 .

The moisture sensor 105 may use a contact-type water level sensor. For this reason, only when water touches the moisture sensor 105 , current may flow through the connection wire 126 connected to the moisture sensor 105 .

The connection wire 126 is connected to the moisture display unit 132 , and whether a current flows in the connection wire 126 can be known through the moisture display unit 132 .

Although described above with reference to the preferred embodiment of the present invention, those of ordinary skill in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention described in the claims below. You will understand that you can.

1: Junction box 1a: Junction box
2: Cover 2a: Cover
3: wire 3a: wire
4: water 5: ground point
10: leakage current measuring device 100: connection
101: connection material 101a: connection material
102: absorbent material 103: shield wire
104: temperature sensor 105: moisture sensor
110: injection part 111: injection hole
112: first packing 113: tube
114: connection part 120: wire part
121: terminal 122: second packing
123: lead wire 124: coupling part
125: combination wire 126: connection wire
127: ground wire 130: measurement unit
131: temperature display 132: moisture display
133: recess 134: cover
135: ground terminal 140: discharge part
141: hole 142: fixing device

Claims (14)

a connection part located inside the junction box and having a connection material for connecting the wires of the distribution line;
an injection part having one end connected to the connection part, the injection part being formed to allow the inflow of water into the connection part;
a wire part having one end connected to the connection part and formed so that a leakage current generated in the connection material can flow; and
A measuring unit connected to the other end of the injection unit and the other end of the electric wire unit and formed on the cover of the junction box to measure the magnitude of the leakage current when the leakage current generated in the connecting material flows through the electric wire unit;
The injection unit,
an inlet for injecting water and formed in the measuring unit;
a first packing connected to the inlet and fixed to the cover of the junction box;
a pipe through which the injected water moves;
a connection part connecting the first packing and the pipe; and
A discharge part connected to the pipe and discharging the introduced water to the connection part
includes,
The connection portion is formed to have an inner diameter that gradually decreases in a direction away from the first packing, the leakage current measuring device. According to claim 1,
The connection part is a leakage current measuring device, characterized in that it includes an absorbent material that surrounds the connection material and can absorb the introduced water. 3. The method of claim 2,
The connection part, the leakage current measuring device, characterized in that it comprises a grid-shaped shield wire surrounding the absorber. delete According to claim 1,
The discharge unit is provided with holes arranged at predetermined intervals on the exterior, and the water is discharged through the holes. According to claim 1,
The discharge unit is formed at a connection portion of the pipe and the discharge unit to fix the discharge unit to the connection unit, and comprises a fixing device coupled to the connection unit. 4. The method of claim 3,
The wire part,
a terminal connected to the measuring unit to measure voltage and current;
a second packing for fixing to the cover of the junction box; and
an outgoing wire having one end connected to the shield wire and the other end connected to the terminal, through which the leakage current flows; and
and a coupling part for coupling the second packing and the outgoing wire. 8. The method of claim 7,
and a temperature sensor configured to detect temperature information on the surface of the connection material in the connection part. 9. The method of claim 8,
Leakage current measuring device, characterized in that the wire part further comprises a coupling wire having one end coupled to the temperature sensor and the other end coupled to the measuring unit. 10. The method of claim 9,
The measuring unit further comprises a temperature display unit for displaying the temperature of the surface of the connection material sensed by the temperature sensor. 8. The method of claim 7,
and a moisture sensor attached to a predetermined height of the inner wall of the junction box and configured to detect a level of influent water flowing into the junction box. 12. The method of claim 11,
Leakage current measuring device, characterized in that the wire part further comprises a connection wire having one end connected to the moisture sensor and the other end connected to the measuring unit. 13. The method of claim 12,
The measuring unit, Leakage current measuring device, characterized in that it further comprises a moisture display for displaying whether the level of the inflow water inside the junction box measured by the moisture sensor is detected. According to claim 1,
The measuring unit includes a ground terminal,
The ground terminal is a leakage current measuring device that is connected to a ground point outside the junction box through a ground wire.

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