KR101417794B1 - Instrumentation device for remote telemeter using power line communication - Google Patents

Abstract

The present invention relates to a measuring apparatus for remote metering based on a power line communication, and more particularly, to a measuring apparatus for a remote meter reading based on a power line communication, a waterproof connector connected to the coupler by a wire and a second screw hole through which a probe screw is inserted at a position corresponding to the first screw hole are formed on the lower surface of the coupler, piercing a power cable, and a first groove portion through which a pair of fastening bands for fastening the power cable are inserted, the fastening band including a support plate formed on both ends of the fastening band, And more particularly, According to the present invention, it is possible to use a power cable having a simple construction and a coupling in a gripping portion to output only a PLC signal instead of a power output, thereby being electrically safe and having various diameters. It is possible to reduce the construction cost and apply the present invention to both the electric pole meter for Jeonju and the electric meter for KEPCO.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus for measuring telemeter using power line communication,

The present invention relates to a measuring apparatus for remote metering and, in particular, it can be used for a power cable having a simple construction, electrically safe, and having various sizes of diameters, And more particularly, to a measuring apparatus for remote meter reading based on a power line communication applicable to both a Jeonju and KEPCO electric meter box.

In general, the remote meter reading system refers to a system that converts measurement results from a measurement object at a remote location to an electrical signal, transmits data through a communication network, and processes the data in the terminal.

Remote meter reading has been developed as a new information communication service due to the development of communication technology, sensing technology and computer technology. Recently, it has been widely used in pollution monitoring, method, disaster prevention, power, water supply and gas system.

Such an automatic meter reading system is classified into a wireless system having no communication line and a wired system having a communication line according to the communication system to be used.

Here, the wired method is classified into a power line method, a cable method, a dedicated line method, and a telephone line method depending on the type of communication sill used.

At this time, the power line method is a method using power line communication (PLC), in which a power company uses a power line used for supplying electricity to a home, a factory, or an office as a signal transmission path.

The power line communication uses a commercial AC signal as a transmission medium and communicates data on a power line. Since the sine wave of 60 Hz, which is commercial AC power, and the communication signal (for example, several tens of KHz) are multiplexed and transmitted at the same time, Wherever power is available, communication is possible.

However, in the current power line communication method, a probe connected to a power line is located close to a transformer to add a communication signal to a power line, or a communication signal is extracted from a power line, have.

Therefore, various harmonics such as a corona and noise are generated from a transformer or an electric appliance, and the amount of electric power can not be detected properly.

This causes the remote meter reading itself to fail or errors in the meter itself. The meter reading rate is getting better at dawn time when there is no power use.

In order to solve this problem, attempts have been made to use a noise filter, but communication signals and noise are attenuated together, and in reality, remote meter reading by power line communication is practically performed.

FIG. 1 is a diagram illustrating an example of a conventional meter reading apparatus for remote meter reading based on a power line communication. Referring to FIG. 1, a conventional measuring apparatus for remote meter reading based on a power line communication includes a probe 10 for piercing a power cable installed in a pole P, a probe 10 for pivoting the probe 10, A flexible wire 30 surrounding the outer diameter of the wire 20 and a film band 40 of metal supporting the wire 30, Consists of components,

At this time, a coupler 60 for extracting only a PLC signal and an earth leakage breaker 70 are accommodated in the housing 50.

Such a conventional measuring apparatus for remote meter reading based on a power line communication has disadvantages in that a complex part is installed in Jeonju (P), and thus there is a disadvantage that aesthetics are hindered. In addition, since installation of various components is complicated, There is a problem that installation cost is very high due to installation of parts.

In addition, there is a very dangerous problem that electric shock occurs due to the gap between the screw of the probe (P) and the power cable when piercing a power cable having a diameter of various sizes.

In addition, since only one large probe 10 is used at first to pierce a power cable having a large diameter, it is disadvantageous in that it can not be applied to a small-sized KEPCO electric meter box.

In other words, if the probe 10 of different size for piercing a power cable of a small diameter to a large diameter is manufactured and operated, the operation cost is inevitably increased, and if the small probe 10 for a KEPCO electric meter is separately manufactured, There is also a problem that operating costs are inevitably rising.

Korea Patent Registration No. 10-0475977 Korean Registered Utility Model Registration No. 20-0448770

It is an object of the present invention to solve the above-mentioned problems and it is an object of the present invention to provide a power cable which is simple in construction, is electrically safe, can be used for a power cable having various diameters, And to provide a measuring device for remote meter reading based on a power line communication applicable to both a Jeonju and KEPCO electric meter box.

According to an aspect of the present invention, there is provided a probe screw, comprising: a probe screw (100) having an electrically conductive tip, the tip of which is a threaded type; A coupler (200) having a first screw hole (210) through which the probe screw (100) passes; A connector 300 connected to the coupler unit 200 for transmitting a signal from the power cable C through the probe screw 100 to a data acquisition unit; And a second screw hole (410) fixed to the power cable (C) such that the probe screw (100) is pierced in a central portion of the power cable (C) And a support plate 400 formed thereon.
The support plate 400 may include a fastening band 500 that surrounds the power cable C together with the support plate 400 and fixes the support plate 420 to the power cable C. [
The support plate 400 may be formed with a first recessed portion 420 in which the fastening band 500 is inserted.
The support plate 400 may have a curved surface in which a surface contacting the power cable C is recessed inward.
The recessed surface 430 may be formed on the concave surface.
The power cable C may further include a top plate 600 formed in a tunnel shape to be fitted therein and detachably coupled to the support plate 400.
A first recessed portion 420 may be formed in the support plate 400 and a first engagement portion 610 may be formed in the upper plate 600 to be slidably coupled to the first recessed portion 420.
A plurality of protrusions 620 may be formed on a surface of the upper plate 600 on which the power cable C is contacted.
And a middle plate 700 which is detachably coupled to the power cable C between the support plate 400 and the upper plate 600 to extend a distance between the support plate 400 and the upper plate 600 can do.
The middle plate 700 includes a second engaging portion 710 formed at one end thereof to be engaged with a first recessed portion 420 formed in the support plate 400 and a first engaging portion 710 formed at the other end thereof A second recessed portion 720 in which the first and second recessed portions 610 are inserted can be formed.
The coupler unit 200 may further include a BNC or RF type input / output terminal 220.

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The present invention can be applied to a power cable having a variety of sizes, which is easy to construct, is electrically safe by outputting a PLC signal instead of a power output by designing a coupling in a grip portion, It is possible to reduce the cost, and it has an effect to be applied to both the electric pole meter for KEPCO and KEPCO.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the description, serve to further the understanding of the technical idea of the invention, And shall not be construed as interpretation.
1 is a diagram illustrating an example of a conventional measuring apparatus for remote meter reading based on a power line communication,
2 to 4 are perspective views showing a measuring apparatus for remote meter reading based on a power line communication according to a first embodiment of the present invention,
5 and 6 are perspective views showing a measuring apparatus for remote meter reading based on a power line communication according to a second embodiment of the present invention,
7 to 9 are perspective views showing a measuring apparatus for remote meter reading based on a power line communication according to a third embodiment of the present invention,
10 to 14 are diagrams illustrating an example of a measuring apparatus for remote meter reading based on a power line communication according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of a measuring apparatus for remote meter reading based on power line communication according to the present invention will be described in detail.

2 to 4 are perspective views showing a measuring apparatus for remote meter reading based on a power line communication according to a first embodiment of the present invention. 2 to 4, a measuring apparatus for remote meter reading based on a power line communication according to a first preferred embodiment of the present invention includes a probe screw 100, a coupler unit 200, a waterproof connector 300, and a support plate 400 ), Which will be described in detail as follows.

The probe screw 100 is pierced by a power cable C installed in an electric meter for electric pole or KEPCO and is used to extract a PLC (Power Line Communication) signal by directly contacting an electric wire located in the electric cable C Signal extraction member.

Here, the probe screw 100 is made of a conductive material, a predetermined thread is formed on an outer diameter surface thereof, and a tip end is formed as an auger type in order to pierce the power cable C.

That is, in order for the probe screw 100 to extract the PLC signal of the power cable C, the probe screw 100 is rotated by the user through the outer cover of the power cable C, (100) are in direct contact with each other.

The coupler 200 includes a first screw hole 210 through which the probe screw 100 passes. The waterproof connector 300 is connected to the coupler unit 200 by electric wires.

The power cable C is fixed to the support plate 400 in a state where the power cable C is in direct contact with the lower surface of the support plate 400.

The support plate 400 may be configured such that the power cable C fixed in contact with the lower surface of the support plate 400 is pierced by the probe screw 100. [ A second screw hole 410 is formed through the probe screw 100 to allow the power cable C to be pierced.

At this time, the second screw hole 410 is formed at a position corresponding to the first screw hole 210.

The power cable C is fixed to the support plate 400 in a state where the power cable C is in contact with the lower surface of the support plate 400 by using a predetermined fastening band 500, .

The first recessed portion 420 is formed in the support plate 400. The first recessed portion 420 may be formed in a shape corresponding to that of the support plate 400 And each of the fastening bands 500 is formed with a predetermined groove in a direction in which the power cable C is wrapped.

The pair of fastening bands 500 surround one surface of the first yaw trough 420 to fasten the power cable C to the support plate 400 while surrounding the power cable C, 400 are formed with through holes 421 through which the fastening bands 500 can pass.

That is, a power cable C of about 160 square millimeters or more is fastened to the support plate 400 through the fastening band 500. The power cable C is curved inward at the lower surface of the support plate 400, So that the power cable C can be fastened to the support plate 400 in such a manner as to surround the outer diameter of the power cable C. [

Here, the structure in which the power cable C is fastened to the support plate 400 using the fastening band 500 will be described in more detail. First, a power cable C of about 160 square millimeters or more is cut into a concave And is brought into close contact with the lower surface of the support plate 400 made of a curved surface.

Then, when a pair of fastening bands 500 is provided, the power cable C is fastened to the support plate 400 using the fastening band 500, Passes through the through hole 421 formed in the one recessed portion 420 and winds the power cable C.

In this case, the power cable C is fixed to the support plate 400 by the fastening band 500. For reference, the material of the fastening band 500 is preferably plastic or stainless steel.

This is because the lower surface of the support plate 400 and the outer surface of the power cable C can contact each other on a wider surface and the lower surface of the support plate 400 is curved, And the power cable (C) is fastened to the support plate (400) more tightly because it is fixed by the fastening band (500).

A predetermined concavity and convexity 430 may be formed on the lower surface of the support plate 400 having the curved surface. This is because the unevenness 430 is formed between the power cable C and the support plate 400 to prevent the power cable C from slipping on the lower surface of the support plate 400, There is an advantage to be able to do.

5 and 6 are perspective views illustrating a measuring apparatus for remote meter reading based on a power line communication according to a second embodiment of the present invention. Referring to FIGS. 5 and 6, an upper plate 600 having a tunnel shape opened in both directions may be coupled to an upper portion of the support plate 400. Referring to FIG.

A first engaging portion 610 is formed at both lower portions of the upper plate 600 so as to be slidably engaged with the first recessed portion 420.

That is, since the first coupling portion 610 is formed in a block type in which both the central portion and the first coupling portion 610 are bent inward, the first coupling portion 610 may be formed through the through hole 421 of the first yaw groove portion 420, 1 coupling portion 610 is slidably inserted into the first recessed portion 420 and finally the upper plate 600 is coupled to the support plate 400 in a block manner.

This is because the power cable C of about 160 square millimeters or more is not fastened to the lower surface of the support plate 400 by the fastening band 500 but is fastened to the power cable C of less than about 60 square millimeters to be.

The power cable C is positioned between the upper surface of the support plate 400 and the inner surface of the upper plate 600 and the power cable C is supported by the support plate 400 and the upper plate 600, C).

At this time, a plurality of protrusions 620 are further formed on the inner surface of the upper plate 600 so that the power cable C is securely fastened and fixed between the upper surface of the support plate 400 and the upper plate 600.

7 to 9 are perspective views showing a measuring apparatus for remote meter reading based on a power line communication according to a third embodiment of the present invention. 7 to 9, a separate middle plate 700 may be further provided between the support plate 400 and the upper plate 600.

That is, the middle plate 700 is further disposed between the support plate 400 and the upper plate 600, so that the power cable C can be fastened with a power cable C of more than about 60 square millimeters and less than about 160 square millimeters.

Here, the middle plate 700 has a lower portion formed with a second coupling portion 710 having the same shape as the first coupling portion 610 formed at the lower portion of the upper plate 600. A second recessed portion 720 having the same shape as that of the first recessed portion 420 of the support plate 400 is formed on the upper portion.

That is, the second engaging portion 710 formed at the lower portion of the middle plate 700 is slidably engaged with the first recessed portion 420 of the supporting plate 400 to fasten the middle plate 700 to the supporting plate 400 And the first engaging portion 610 formed at the lower portion of the upper plate 600 is slidably coupled to the second recessed portion 720 formed on the upper portion of the middle plate 700. Thus, And the upper plate 600 is formed of a single body.

10 to 14 are diagrams illustrating an example of a measuring apparatus for remote meter reading based on a power line communication according to an embodiment of the present invention. 10 to 14, the coupler unit 200 further includes a BNC or RF type input / output terminal 220.

That is, a BNC or RF type input / output terminal 220 is separately installed in the coupler unit 200 to transmit a PLC signal probed through the probe screw 100 to a data acquisition unit (DCU) . This means that the PLC signal is transmitted to the data acquisition unit via the BNC or RF terminal.

For example, when the measurement apparatus according to the present invention is applied to a pole for a single-phase consisting of N-phase and R-phase, a coupler unit 200 having a BNC or RF type input / output terminal 220 is provided on the N-phase, Or the RF type input / output terminal 220 is provided. At this time, the N phase and the R phase are connected to each other through the waterproof connector 300.

When applied to a three-phase electric pole consisting of N-phase, R-phase, S-phase and T-phase, the N phase transmits the PLC signal probed through the probe screw 100 to a data acquisition unit (DCU) A coupler unit 200 having a BNC or RF type input / output terminal 220 for the BNC or RF type and a coupler unit 200 having the BNC or RF type input / ). At this time, the couplers 200 are connected in parallel to each other through the waterproof connector 300.

An R phase coupler unit 200 of the same type as the N phase coupler unit 200 having no BNC or RF type input / output terminal 220 will be described with reference to FIG. Is connected to a predetermined modem through a waterproof connector (300).

That is, when the measuring device of the present invention is installed in the electric pole for electric power rather than in the KEPCO electric meter as described above, the N phase coupler unit 200 having the BNC or RF type input / output terminal 220 and the BNC or RF type And a coupler unit 200 having no input / output terminal 220 is provided.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And will fall within the scope of the appended claims.

100: Probe screw 200: Coupler part
210: first screw hole 220: input / output terminal
300: Waterproof connector 400: Support plate
410: second screw hole 420: first recessed groove
430: uneven 500: fastening band
600: upper plate 610: first coupling portion
620: protrusion 700: middle plate
710: second coupling portion 720: second yaw groove portion
C: Power cable

Claims (11)

A probing screw (100) having an electrically conductive tip whose tip is an auger type and a thread is formed on an outer diameter surface;
A coupler (200) for outputting only a power line communication signal, not a power output, through the probe screw (100);
A connector 300 connected to the coupler unit 200 for transmitting the power line communication signal probed in the power cable C to the data collecting unit via the probe screw 100;
A second screw hole 410 for fixing the power cable C so that the probe screw 100 is pierced at a central portion of the power cable C and screwed to the thread of the probe screw 100; A support plate 420 having a through hole 421 communicating with the first recessed portion 420 and the first recessed portion 420 selectively engaged with the upper plate 600 or the fastening band 500 according to the diameter of the power cable C, (400); / RTI >
The first recessed portion 420 of the support plate 400 is selectively slidably engaged with the first engagement portion 610 of the upper plate 600 or the fastening band 500 passes through the through hole 421 Wherein the power line communication-based remote meter reading device is a structure that can be used for remote meter reading based on power line communication. delete delete The method according to claim 1,
The support plate (400)
And a surface contacting the power cable (C) by fixing the power cable (C) by the fastening band (500) is a curved surface recessed inward. 5. The method of claim 4,
And the concave and convex curved surfaces are formed with concavities and convexities (430). The method according to claim 1,
The upper plate (600)
Wherein the power cable (C) is formed in a tunnel shape so as to fit the power cable (C). delete The method according to claim 6,
The top plate (600)
And a plurality of protrusions (620) are formed on a surface where the power cable (C) is contacted. The method according to claim 1,
And a middle plate (700) detachably coupled between the support plate (400) and the upper plate (600) and extending a distance between the support plate (400) and the upper plate (600) Measuring device for meter reading. 10. The method of claim 9,
The middle plate (700)
A second engaging portion 710 fitted to the first recessed portion 420 formed on the support plate 400 is formed at one end and a first engaging portion 610 formed at the upper plate 600 is inserted at the other end. And a second recessed portion (720) is formed in the second recessed portion (720). A probing screw (100) having an electrically conductive tip whose tip is an auger type and a thread is formed on an outer diameter surface;
A coupler (200) for probing a power line communication signal through the probe screw (100);
A connector 300 connected to the coupler unit 200 and connected to the single or three-phase measurement apparatus for remote meter reading; And
And a BNC or RF type input / output terminal 220 for transmitting the power line communication signal probed by the other remote metering measuring device connected by the connector and the power line communication signal probed through the probe screw to the data collecting unit A measuring device for remote meter reading based on power line communication.

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