KR102621829B1 - Changing device for low voltage electric meter - Google Patents

Abstract

An embodiment of the present invention is intended to provide a low-voltage watt-hour meter replacement device that not only enables uninterrupted low-voltage watt-hour meter replacement by applying a bypass function when replacing a low-voltage watt-hour meter, but also can continuously and stably supply high-quality power without power outage. The low-voltage watt-hour meter replacement device according to an embodiment of the present invention has an uninterruptible replacement structure and includes a main body portion electrically connected to the terminal portion of the low-voltage watt-hour meter, and the main body portion includes a first main body portion on which one side of the power-side wire and the load-side wire are mounted and supported. , and a second main body that is coupled to the first main body in an opening and closing structure, supports the other side of the power wire and the load wire, and forms a bypass path between the power wire and the load wire.

Description

Low voltage power meter replacement device {CHANGING DEVICE FOR LOW VOLTAGE ELECTRIC METER}

The present invention relates to a low-voltage power meter replacement device.

In order to measure the power usage of customers supplied by low voltage (1-phase 220V, 3-phase 380V), a low-voltage power meter must be installed. These low-voltage watt-hour meters can be used until the expiration of the certification validity period after being certified by a testing agency in accordance with the Metering Act. In order to accurately measure power usage, they must be replaced with a new low-voltage watt-hour meter that has been certified before the expiration of the testing period.

Currently, in order to replace a low-voltage power meter, it is necessary to set a time zone when a power outage is possible with electricity customers and replace the low-voltage power meter at that time. It is impossible to replace it without a power outage. However, it is difficult to negotiate with customers who are sensitive to power outages and do not allow short-term power outages, or customers who use traffic lights, communication and security facilities, and CCTV, and cannot replace a new low-voltage power meter before the expiration of the low-voltage power meter test period.

Therefore, the inability to replace low-voltage power meters in a timely manner leads to an increase in meter error, which results in inaccurate power usage measurements, which reduces reliability in rate calculation. In addition, the current low-voltage watt-hour meter replacement method involves removing the power and load-side wires connected to the low-voltage watt-hour meter and then inserting the power-side and load-side wires again after replacing the low-voltage watt-hour meter, which inevitably causes problems with customer outages during the low-voltage watt-hour meter replacement time. do. Therefore, a time zone during which a power outage is possible is set with electricity customers, and low-voltage power meters can only be replaced during that time period.

An embodiment of the present invention is intended to provide a low-voltage watt-hour meter replacement device that not only enables uninterrupted low-voltage watt-hour meter replacement by applying a bypass function when replacing a low-voltage watt-hour meter, but also can continuously and stably supply high-quality power without power outage.

The low-voltage watt-hour meter replacement device according to an embodiment of the present invention has an uninterruptible replacement structure and includes a main body portion electrically connected to the terminal portion of the low-voltage watt-hour meter, and the main body portion includes a first main body portion on which one side of the power-side wire and the load-side wire are mounted and supported. , and a second main body that is coupled to the first main body in an opening and closing structure, supports the other side of the power wire and the load wire, and forms a bypass path between the power wire and the load wire.

The first main body may have fastening holes on both sides along the longitudinal direction and may include a first mounting groove provided on the inside at a preset interval to hold one side of the power wire and the load side wire.

The second main body is provided at preset intervals along the longitudinal direction and has a second mounting groove for holding the other side of the power wire and the load side wire, and is provided in the second mounting groove to connect the power wire and the load wire to each other to form a bypass path. It may include a bypass terminal that can be formed.

The bypass path may include a first bypass circuit connecting the power-side terminal and the load-side terminal of the low-voltage watt-hour meter, and a second bypass circuit connecting the power-side terminal and the load-side terminal of the low-voltage watt-hour meter.

The main body may further include a bypass terminal bolt that pressurizes the power-side wire and the load-side wire.

It may further include an insulating material provided on the bypass terminal bolt to insulate it.

One side of the first main body and the second main body may be hinged.

The first main body and the second main body may be fastened with fastening bolts.

As the pressing force of the bypass terminal bolt is transmitted, it may further include a wire wrapping device that covers the covering portion of the corresponding power-side wire and load-side wire.

The wire wrapping device may include a first wire wrapping device of a three-blade structure provided in the first mounting groove of the first main body, and a second wire wrapping device of a four-blade structure provided in the second mounting groove of the second main body.

The wire sheath may include a conductor with mechanical strength that can withstand bypass current when the bypass terminal bolt is tightened and the wire sheath passes through the covering portion of the wire.

The conductor may include brass or an equivalent material.

It may further include an LED indicator provided on one side of the main body to indicate whether the bypass path is energized and the current value.

When replacing a low-voltage power meter, not only can it be replaced without interruption, but it also has the effect of stably supplying high-quality power continuously without a power outage.

In addition, safety accidents can be prevented by preventing workers from receiving electric shocks and arcing due to phase-to-phase short-circuiting, and the occurrence of damage and defects in terminal blocks can be reduced.

In addition, when installing a new watt-hour meter, it is possible to prevent incorrect wiring and reverse wiring, and it has the effect of increasing watt-hour meter operation efficiency by shortening work time and increasing work efficiency.

Figure 1 is a diagram showing a low-voltage power meter replacement device according to an embodiment of the present invention.
Figure 2 is a diagram showing a state in which a bypass terminal bolt and a fastening bolt are coupled to the first main body according to an embodiment of the present invention.
Figure 3 is a diagram showing a bypass terminal bolt according to an embodiment of the present invention.
Figure 4 is a diagram showing a bypass terminal in the second main body according to an embodiment of the present invention.
Figure 5 is a construction flowchart showing an uninterrupted low-voltage power meter replacement operation using a low-voltage power meter replacement device according to an embodiment of the present invention.

The terminology used herein is only intended to refer to specific embodiments and is not intended to limit the invention. As used herein, singular forms include plural forms unless phrases clearly indicate the contrary. As used in the specification, the meaning of "comprising" is to specify a specific characteristic, area, integer, step, operation, element and/or component, and to specify another specific property, area, integer, step, operation, element, component and/or group. It does not exclude the existence or addition of .

Although not defined differently, all terms including technical and scientific terms used herein have the same meaning as those generally understood by those skilled in the art in the technical field to which the present invention pertains. Terms defined in commonly used dictionaries are further interpreted as having meanings consistent with related technical literature and currently disclosed content, and are not interpreted in ideal or very formal meanings unless defined.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein.

Figure 1 is a diagram showing a low-voltage power meter replacement device according to an embodiment of the present invention, and Figure 2 is a diagram showing a state in which a bypass terminal bolt and a fastening bolt are coupled to the first main body according to an embodiment of the present invention. am. And Figure 3 is a diagram showing a bypass terminal bolt according to an embodiment of the present invention, and Figure 4 is a diagram showing a bypass terminal portion in the second main body according to an embodiment of the present invention. Referring to Figures 1 to 4, the low-voltage watt-hour meter replacement device according to an embodiment of the present invention has an uninterruptible replacement structure and includes a main body 100 that is electrically connected to the terminal portion of the low-voltage watt-hour meter, and is used when replacing the low-voltage watt-hour meter. By applying the bypass function, not only can low-voltage power meters be replaced without interruption, but high-quality power can be continuously and stably supplied without power outages.

The main body 100 includes a first main body 110 at the front and a second main body 120 at the rear. The first body 110 and the second body 120 may be coupled on one side with a hinge 10. And the first main body 110 and the second main body 120 may be fastened with a fastening bolt 140. The exterior of the main body 100 can be made of polyvinyl chloride (PVC) or an equivalent or better material that is resistant to wear, is easy to manufacture, and has excellent insulation performance. For example, the main body 100 may be made of a plastic material called polyacetal, acetal, or poly oxy methylene (POM). The main body 100 can be made of a material with good fatigue resistance, creep resistance, durability, formability, long-term dimensional stability, and long-term durability. Additionally, a cicada ring may be installed on the side to prevent the first body 110 and the second body 120 from being separated.

The first main body 110 may be supported by mounting one side of the power wire and the load side wire. The first body portion 110 may have fastening holes on both sides along the longitudinal direction and may include a first mounting groove 112 provided on the inside at a preset interval to hold one side of the power wire and the load side wire. The first mounting grooves 112 may be provided in four pieces so that the power-side wire and the load-side wire are respectively inserted into the internal space.

The second main body 120 is coupled to the first main body 110 in an opening and closing structure, and the other side of the power wire and the load wire are supported and can form a bypass path between the power wire and the load wire. The second main body 120 is provided at preset intervals along the longitudinal direction and is provided in the second mounting groove 122 to hold the other side of the power wire and the load side wire, and is provided in the second mounting groove 122 to hold the power wire and the other side of the load side wire. It may include a bypass terminal portion 126 that can form a bypass path by interconnecting load-side wires. The second mounting grooves 122 may be provided in four pieces so that the power supply side wire and the load side wire are respectively inserted into the internal space at a position corresponding to the first mounting groove 112.

The bypass path includes a first bypass circuit (126a1) connecting the power supply terminal (126S1) and the load terminal (126L1) of the low-voltage power meter, and a second bypass circuit (126a1) connecting the power supply terminal (126S2) and the load terminal (126L2) of the low-voltage power meter. It may include a bypass circuit 126b1.

Meanwhile, the main body 100 may further include a bypass terminal bolt 130 that pressurizes the power supply side wire and the load side wire to the bypass terminal part 126. It may further include an insulating material 132 provided on the bypass terminal bolt 130 to insulate it. The bypass terminal bolt 130 includes an upper head portion 133, an energized body portion 134, and a wire contact portion 136 that is in contact with the wire.

As the pressing force of the bypass terminal bolt 130 is transmitted, it may further include a wire wrapping device that covers the covering portion of the corresponding power-side wire and load-side wire. The wire wrapping device includes a first wire wrapping device 114 of a triple-blade structure provided in the first mounting groove 112 of the first main body 110, and a second mounting groove 122 of the second main body 120. It may include a second wire peeler 124 of a four-blade structure provided in.

The wire sheath may include a conductor with mechanical strength that can withstand bypass current when the bypass terminal bolt 130 is tightened and the wire sheath passes through the covering portion of the wire. Here, the conductor may include brass or a material equivalent to it. That is, the wire stripping machine can facilitate wire stripping by providing the first wire stripping machine 114 with a three-blade structure and the second wire stripping machine 124 with a four-blade structure. In addition, when the bypass terminal bolt 130 is tightened and the wire strip passes through the covering portion, brass or a material equivalent thereto with sufficient mechanical strength to withstand the bypass current can be applied.

Meanwhile, it may further include an LED indicator light 150 provided on one side of the main body 100 to indicate whether the bypass path is energized and the current value. When the wire sheath is sheathed inside the main body 100 for bypass, the LED indicator 150, which displays the status of energization and current value, can be made of flame-retardant polycarbonate synthetic resin whose material does not change due to electrical shock such as arcs. . It may further include a meter to check whether the bypass path is properly connected.

As described above, the low-voltage power meter replacement device according to the embodiment of the present invention uses a bypass circuit interconnected between the low-voltage power meter power supply terminal (126S1) and the load side terminal (126L1), and the power supply terminal (126S2) and the load terminal (126L2). Therefore, when replacing a low-voltage watt-hour meter, it is possible to replace the low-voltage watt-hour meter without a power outage.

Figure 5 is a construction flowchart showing an uninterrupted low-voltage power meter replacement operation using a low-voltage power meter replacement device according to an embodiment of the present invention. Referring to Figure 5, the construction steps of the low-voltage power meter uninterruptible replacement work will be explained.

First, the power-side wire and the load-side wire at the bottom of the low-voltage watt-hour meter are inserted into the second mounting groove 122 of the second main body 120 of the low-voltage watt-hour meter replacement device (S510). Next, cover the front part of the uninterruptible replacement device and tighten the fastening bolt 140 and bypass terminal bolt 130 (S520). And to check whether the uninterruptible replacement device is connected, connect a hook-on meter to the bypass terminal bolt 130 to measure the current and check the LED indicator 150 (S530). Next, the old low-voltage power meter is removed and a solid silicon cover is inserted into the separated power wire and load wire (S540). Then, a new low-voltage power meter is installed and the power and load side wires are connected respectively to match the power and load sides (S550). Next, the bypass terminal bolt 130 and the fastening bolt 140 are sequentially loosened, and the low-voltage power meter replacement device according to the embodiment of the present invention is separated (S560). Cover Cover the surface of the damaged power-side wire and load-side wire with a solid silicon (HCR) cover (S570). To insulate the wrapped wire, solid silicon (HCR) or an insulating material with performance equivalent to or higher can be applied.

As described above, using the low-voltage power meter replacement device according to the embodiment of the present invention, the power side wire and the load side wire are connected to the first mounting groove 112 of the first body 110 and the second mounting groove 112 of the second body 120. Each is mounted so that it is fixed in the mounting groove 122. Next, the first body 110 and the second body 120 are covered and the bypass terminal bolt 130 and fastening bolt 140 are tightened to bypass the current flowing through the low-voltage power meter through the bypass path. . In addition, uninterrupted replacement of low-voltage power meters can be performed by replacing low-voltage power meters that have expired and installing protective insulating caps on the bare wires.

Although preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and can be implemented with various modifications within the scope of the claims, the detailed description of the invention, and the accompanying drawings, and this is also possible. It is natural that it falls within the scope of the present invention.

100 ; Main body 110; 1st main body
112 ; First mounting groove 114; 1st wire peeling
120 ; second main body 122; 2nd home
124 ; 2nd wire peeling 126; Bypass terminal section
126a1 ; first bypass circuit 126b1; Second bypass circuit
130 ; Bypass terminal bolt 132 ; insulation material
140 ; fastening bolt 150; LED indicator light

Claims (13)

The main body has an uninterruptible replacement structure and is electrically connected to the terminal part of the low-voltage power meter.
Includes,
The main body part
A first main body in which one side of the power-side wire and the load-side wire are mounted and supported, and
A second body part that is coupled to the first body part in an opening and closing structure, supports the other side of the power wire and the load wire, and forms a bypass path between the power wire and the load wire, and
A wire wrapping device is provided at each part of the first body part and the second main body part where the power wire and the load wire are mounted, and wraps the covering portion of the power wire and the load wire as external force is transmitted.
Including,
The wire peeling is
A first wire stripping device of a three-blade structure provided in a portion of the first main body where one side of the power side wire and the load side wire are mounted, and
A low-voltage power meter replacement device comprising a second wire peeler of a four-blade structure provided in a portion of the second main body where the other side of the power wire and the load wire is mounted. In paragraph 1:
The first body part has fastening holes on both sides along the longitudinal direction and is provided at a preset interval on the inside, and includes a first mounting groove for mounting one side of the power wire and the load wire. In paragraph 2,
The second body portion includes a second mounting groove provided at preset intervals along the longitudinal direction to hold the other side of the power wire and the load wire, and
A bypass terminal unit provided in the second mounting groove to form a bypass path by interconnecting the power supply side wire and the load side wire.
A low-voltage power meter replacement device including a. In paragraph 3,
The bypass path is
A first bypass circuit connecting the power terminal and the load terminal of the low-voltage power meter, and
A low-voltage watt-hour meter replacement device comprising a second bypass circuit connecting a power-side terminal and a load-side terminal of the low-voltage watt-hour meter. In paragraph 4,
The low-voltage power meter replacement device further includes a bypass terminal bolt that pressurizes the power wire and the load wire to the bypass terminal portion of the main body. In paragraph 5,
A low-voltage power meter replacement device further comprising an insulating material provided on an upper portion of the bypass terminal bolt. In paragraph 1:
A low-voltage power meter replacement device in which one side of the first main body and the second main body is hinged. In paragraph 7:
A low-voltage power meter replacement device in which the first main body and the second main body are fastened with fastening bolts. In paragraph 6:
A low-voltage power meter replacement device that sheaths the covering portion of the corresponding power-side wire and the load-side wire as the pressing force of the bypass terminal bolt is transmitted to the wire sheather. In paragraph 9:
The first wire wrapping device is provided in the first mounting groove of the first body portion,
The second wire wrapping device is a low-voltage power meter replacement device provided in the second mounting groove of the second main body. In paragraph 10:
The wire wrapping device is a low-voltage power meter replacement device comprising a conductor having a mechanical strength that can withstand bypass current when the wire wrapping device tightens the bypass terminal bolt and passes through the covering portion of the wire corresponding to the wire wrapping device. In paragraph 11:
The conductor is a low-voltage power meter replacement device comprising a brass material. In paragraph 1:
A low-voltage power meter replacement device further comprising an LED indicator provided on one side of the main body to indicate whether the bypass path is energized and a current value.