KR101304553B1 - Apparatus for observation load of voltage transformer - Google Patents

Abstract

PURPOSE: A load monitoring device is provided to be connected to an electric wire with a worker being apart at a fixed distance without approaching a high voltage electric wire, thereby preventing the safety accident due to the contact between the high voltage electric wire and the worker or the load monitoring device. CONSTITUTION: A load monitoring device of a transformer includes: a measurement cable (30) which includes a coil coated with a coating material of an insulation material so as to measure load by being installed in an electric wire outputting current from the transformer; a transferring cable (32) which is connected to the measurement cable so as to transfer load data measured from the measurement cable; a T-shaped bracket (50) having a coupling hole portion inserted so that the one end portion of measurement cable and the transferring cable are connected, and the other end portion of the measurement cable is electrically connected to the one end portion of the measurement cable; an insertion member (54) which is installed at the other end portion of the measurement cable and is inserted to be detachable to the coupling hole portion; a coupling jig (70) on which the measurement cable, the transferring cable, and the T-shaped bracket are mounted, and which is located so that the measurement cable surrounds the electric wire, couples the insertion member to the coupling hole portion, and electrically connects the one end portion and the other portion of the measurement cable; and a control unit which is connected to the transferring cable, transfers a driving signal to the coupling jig, and transfers the output signal by determining whether the load data received along the transferring cable is overloaded or not.

Description

Load monitoring device for transformers {APPARATUS FOR OBSERVATION LOAD OF VOLTAGE TRANSFORMER}

The present invention relates to a load monitoring device for a transformer, and more particularly, to a load monitoring device for a transformer that can perform load measurement to prevent the overload operation of the transformer, and can easily install and remove the load monitoring device. It is about.

In general, the ground transformer installed in the ground sidewalk (human road) or the columnar transformer installed in the pole is responsible for transforming the high voltage sent from the substation to a low voltage that can be used in factories and homes.

In other words, KEPCO, which supplies electricity, produces electricity from power plants hundreds of kilometers away from the load center to supply power to consumers.

At this time, increase the voltage to reduce the loss caused by the transmission. Therefore, install a substation where the load is crowded and lower it to the distribution voltage (22,900V in the case of KEPCO), then transfer it to the transformer near the user through underground lines or overhead lines and finally step down to the normal voltage of 380V / 220V.

The transformer transforms a high voltage into a low voltage, so the primary voltage (voltage input into the transformer) and the secondary voltage (voltage output from the transformer) are very high, so that a small malfunction in the transformer causes a fatal safety accident.

This malfunction of the transformer is mainly caused by the overload of the transformer. If the overload condition lasts for a long time, the transformer may be fatally damaged.

If the normal transformer function cannot be performed due to a malfunction due to the overload of the transformer, a large voltage or a very low voltage may be supplied to the factory or home, and a high voltage may be supplied even if a high voltage is supplied. There is a problem that leads to.

That is, in the pole, the primary wire through which power is transmitted from the substation passes through the top of the pole, and a predetermined wire is branched from the primary wire so that the primary voltage is input to the transformer.

The primary voltage input to the transformer is reduced in voltage by a decompression circuit in the transformer to generate a secondary voltage, and is transmitted to the customer by the secondary wire.

Since the above-mentioned decompression process is carried out at a considerable high pressure, there is a large amount of current change, and a large amount of heat is generated when depressurizing, so that the transformer frequently suffers from heat. Thus, if a transformer fails, hundreds or thousands of households The electricity supply is cut off, which causes a lot of inconvenience to users.

Therefore, a device for monitoring the load of the secondary wire flowing from the transformer to the customer in real time is needed. A load monitoring device for real-time monitoring of the voltage and current of the secondary wire and the internal and external temperatures of the transformer is provided. Has been proposed

Background art of the present invention is disclosed in Republic of Korea Patent Publication No. 10-0689226 (announced March 2, 2007, the name of the invention: load monitoring device of the transformer).

In general, the load sensing device of a transformer has a problem that a safety accident may occur when a worker contacts a high voltage wire or a load monitoring device contacts a load monitoring device because the operator must install a load monitoring device directly on the wire to which the load is directly measured. have.

Therefore, there is a need for improvement.

SUMMARY OF THE INVENTION An object of the present invention is to provide a load monitoring device for a transformer that can perform load measurement to prevent overload operation of the transformer and can easily install and remove the load monitoring device.

The present invention includes a measuring cable including a coil which is installed on an electric wire from which a current is output from a transformer and is coated with an insulating coating material to measure a load; A transmission cable connected to the measurement cable to transmit load data measured from the measurement cable; A T-shaped bracket having a coupling hole connected between one end of the measurement cable and the transmission cable and the other end of the measurement cable electrically connected to one end of the measurement cable; An insertion member installed at the other end of the measurement cable and detachably inserted into the coupling hole; A fastening jig in which the measurement cable and the transmission cable are seated, the measurement cable is positioned to surround the wire, and the coupling member is coupled to the coupling hole to electrically connect one end and the other end of the measurement cable; And a control unit which transmits a driving signal to the fastening jig, determines load data received along the transmission cable, determines whether an overload occurs, and transmits an output signal.

In addition, the fastening jig of the present invention, the support cable is supported by the transmission cable and the T-shaped bracket, the handle portion and the insertion groove portion; A rotating member rotatably installed on the support, the measuring cable being supported and having an insertion protrusion inserted into and detachably inserted into the insertion groove; And rotatably installed between the protruding portion protruding from the support and the rotating member, and rotating the rotating member so that the insertion member is inserted into the coupling hole so that one end and the other end of the measuring cable are electrically connected. It characterized in that it comprises an actuator.

In addition, the operation unit for transmitting the operation signal generated by the operator's operation to the control unit to transmit a drive signal to the actuator of the present invention; And an output unit configured to output an overload signal transmitted from the control unit so that an operator can check the load signal transmitted from the measurement cable to the control unit along the transmission cable.

The load monitoring device of the transformer according to the present invention, the operator can connect the load monitoring device to the wire at a certain distance away from the high voltage without access to the high-voltage wire, safety generated when the high-voltage wire and the operator or load monitoring device is in contact There is an advantage to prevent accidents.

1 is an exploded perspective view showing a load monitoring apparatus of a transformer according to an embodiment of the present invention.
2 is a state diagram showing a load monitoring device of a transformer according to an embodiment of the present invention.
3 is a block diagram showing a load monitoring apparatus of a transformer according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of a load monitoring device of a transformer according to the present invention.

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms described below are terms defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator.

Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is an exploded perspective view showing a load monitoring device of a transformer according to an embodiment of the present invention, Figure 2 is a use state diagram showing a load monitoring device of a transformer according to an embodiment of the present invention, Figure 3 is A block diagram of a load monitoring apparatus of a transformer according to an embodiment of the present invention is shown.

1 to 3, the load monitoring device for a transformer according to an embodiment of the present invention, the coil is installed on the wire 10 that outputs the current from the transformer is coated with a coating material of insulating material to measure the load Measuring cable 30, including the transmission cable 32 is connected to the measurement cable 30 to transmit the load data measured from the measurement cable 30, one end of the measurement cable 30 and the transmission cable (32) ) And a T-shaped bracket 50 having a coupling hole 52 inserted into the other end of the measuring cable 30 so as to be electrically connected to one end of the measuring cable 30, and the measuring cable 30. The insertion member 54 and the measurement cable 30 and the transmission cable 32 which are installed in the other end of the coupling member and detachably inserted into the coupling hole 52 are seated, and the measurement cable 30 is connected to the wire 10. Position it so that it surrounds and couple the insertion member 54 to the coupling hole 52 to measure the measurement cable (30) And a driving signal transmitted to the fastening jig 70 and the fastening jig 70 electrically connecting one end of the other end to the other end, and determining the overload by determining the load data received along the transmission cable 32. And a control unit 80 for transmitting the output signal.

The measurement cable 30 is made of a coil to detect the load flowing in the wire 10 when the induction current flows when wrapped in the wire 10, and includes a flexible material by wrapping the coil with an insulating material To form a cable.

Since the measuring cable 30 is surrounded by an outer covering by an insulating coating material, the wire 10 and the measuring cable 30 are disposed when the measuring cable 30 is arranged to surround the wire 10 by the fastening jig 70. Sparks can be prevented from being contacted.

Since the T-shaped bracket 50 and the inserting member 54 are also made of a synthetic resin material including an insulating material, the T-shaped bracket 50 and the inserting member (when the measuring cable 30 is disposed to surround the electric wire 10). 54 and the wire 10 is in contact with each other to prevent the spark is generated.

One end of the measuring cable 30 and one end of the transmission cable 32 are connected to both upper ends of the T-shaped bracket 50 so that the measurement cable 30 and the transmission cable 32 are electrically connected to each other.

Since the coupling hole 52 is formed at the lower end of the T-shaped bracket 50, when the other end of the measurement cable 30 is moved toward the coupling hole 52 by the fastening jig 70, the other end of the measurement cable 30 is formed. One end and the other end of the measuring cable 30 are electrically connected while the insertion member 54 is inserted into the coupling hole 52.

Therefore, the measuring cable 30 forms a ring shape surrounding the wire 10 so that an induced current flows in the measuring cable 30 by the current passing through the wire 10 to measure the load generated in the wire 10. It becomes possible.

The fastening jig 70 is supported by the transmission cable 32 and the T-shaped bracket 50 and is rotatable to the support 72 and the support 72 provided with the handle portion 72c and the insertion groove 72a. Installed, the measuring cable 30 is supported, the rotating member 74 is provided with an insertion protrusion (74a) detachably inserted in the insertion groove portion (72a), and the projection (72b) protruding from the support (72) And rotatably installed between the rotary member 74 and one end and the other end of the measuring cable 30 are electrically connected by inserting the insertion member 54 into the coupling hole 52 by rotating the rotary member 74. Actuator 76 to be connected.

The support 72 is formed in the shape of a long panel, the handle portion 72c is formed at one end so that the operator grasps the handle portion 72c and extends the support 72 to the electric wire 10 side of the transformer to rotate the member 74. To hang the wires (10).

The support 72 is made of an insulating material to prevent the spark generated by contact with the wire 10, the transmission cable 32 and the T-shaped bracket 50 is installed, made of a good strength wood Can lose.

The rotating member 74 is rotatably installed by the hinge member 74b at the other end of the support 72 and is formed in a ring shape so as to easily wrap the wire 10.

The measuring cable 30 is seated on the upper surface of the rotating member 74, and a plurality of fastening holes 78a are formed on the upper surface of the support 72 and the rotating member 74, and the plurality of fixing pieces 78b are fastened. It is coupled to the fastening hole portion 78a by a member.

Therefore, since the transmission cable 32 and the measurement cable 30 seated on the support 72 and the rotating member 74 are constrained by the fixing piece 78b, the transmission cable 32 on the support 72 and the rotating member 74. ) And the measuring cable 30 can be prevented from being separated.

A protrusion 72b is formed in a lateral direction from one side of the support 72, and an actuator 76 is rotatably installed at an end of the protrusion 72b, and an end of the rod coming out of the actuator 76 is a rotating member. One side of the 74 is rotatably installed.

Therefore, when the rod protrudes from the actuator 76, the outer end of the rotating member 74 is rotated toward the support 72, and the insertion protrusion 74a formed at the end of the rotating member 74 is the other side of the support 72. It is inserted into the insertion groove (72a) formed in.

At this time, since the other end of the measuring cable 30 seated on the rotating member 74 is moved to the T-type bracket 50 side, the insertion member 54 installed at the other end of the measuring cable 30 is a T-type bracket 50. One end and the other end of the measurement cable 30 is electrically connected while being inserted into the coupling hole 52 of the).

In addition, in the present embodiment, the operation unit 82 for transmitting the operation signal generated by the operator's operation to the control unit 80 to transmit the drive signal to the actuator 76, and the transmission cable 32 from the measurement cable 30. If the load signal transmitted to the control unit 80 is greater than or equal to the set value according to the) further comprises an output unit 84 for outputting the overload signal transmitted from the control unit 80 so that the operator can check.

The operation unit 82 may be installed in the handle portion 72c to transmit a driving signal to the actuator 76, and implements the forward or reverse rotation of the rotating member 74 by releasing the rod from the actuator 76. The measurement cable 30 can be wrapped around the wire (10).

The output unit 84 displays the overload signal transmitted from the control unit 80 to the central processing unit so that the operator can check or outputs a warning signal so that the operator can perform a repair work to eliminate the overload generated in the transformer. do.

Looking at the operation of the load monitoring device of a transformer according to an embodiment of the present invention configured as described above are as follows.

First, the operator grasps the handle portion 72c of the support 72 and moves the support 72 to the wire 10 side so that the wire 10 is caught by the measuring cable 30 and the rotating member 74, When the operation unit 82 is operated, the rod protrudes from the actuator 76 to rotate the rotating member 74 and the measuring cable 30.

When the rotating member 74 and the measuring cable 30 is rotated, the insertion protrusion 74a is inserted into the insertion groove 72a, and the insertion member 54 is inserted into the coupling hole 52 of the T-shaped bracket 50. One end and the other end of the measurement cable 30 is electrically connected.

When the measuring cable 30 forms a ring shape to surround the wire 10, a flow current is generated in the measuring cable 30 by the current flowing along the wire 10, so that the load generated in the wire 10 is measured. It becomes possible to measure by (30).

The load signal generated by the measuring cable 30 is transmitted to the control unit 80 along the transmission cable 32, and the overload signal transmitted from the control unit 80 is output when the load data generated in the control unit 80 is greater than or equal to the set value. The transfer to the unit 84 allows the operator to recognize whether the wire 10 is overloaded.

By the operation as described above, the operator can connect the load monitoring device to the wire 10 at a predetermined distance without approaching the high voltage wire 10, so that the high voltage wire 10 and the worker or the load monitoring device Safety accidents caused by contact can be prevented.

As a result, load measurement for preventing overload operation of the transformer can be performed, and the load monitoring value of the transformer can be provided which can easily install and remove the load monitoring value.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. .

In addition, although the load monitoring market value of the transformer has been described as an example, this is merely exemplary, and the load monitoring device of the present invention may be used in other products other than the load monitoring device of the transformer.

Accordingly, the true scope of the present invention should be determined by the following claims.

10: wire 30: measurement cable
32: Transmission cable 50: T-type bracket
52: coupling hole 54: insertion member
70: fastening jig 72: support
72a: insertion groove 72b: protrusion
72c: handle portion 74: rotating member
74a: insertion protrusion 74b: hinge member
76: actuator 78a: fastening hole
78b: fixed piece 80: control part
82: operation unit 84: output unit

Claims (3)

A measurement cable including a coil installed on an electric wire from which a current is output from the transformer and coated with an insulating coating material to measure a load;
A transmission cable connected to the measurement cable to transmit load data measured from the measurement cable;
A T-shaped bracket having a coupling hole connected between one end of the measurement cable and the transmission cable and the other end of the measurement cable electrically connected to one end of the measurement cable;
An insertion member installed at the other end of the measurement cable and detachably inserted into the coupling hole;
The measurement cable, the transmission cable and the T-shaped bracket is seated, the measurement cable is positioned to surround the wire, and the insertion member is coupled to the coupling hole to electrically connect one end and the other end of the measurement cable. A fastening jig for connecting; And
And a control unit connected to the transmission cable, transmitting a driving signal to the fastening jig, and determining an overload by determining load data received along the transmission cable to determine whether an overload occurs. Surveillance device. The method of claim 1, wherein the fastening jig,
A support for supporting the transmission cable and the T-shaped bracket and having a handle part and an insertion groove part;
A rotating member rotatably installed on the support, the measuring cable being supported and having an insertion protrusion inserted into and detachably inserted into the insertion groove; And
An actuator rotatably installed between the protrusion projecting from the support and the rotating member, and the actuator rotates the rotating member so that the insertion member is inserted into the coupling hole so that one end and the other end of the measuring cable are electrically connected. Load monitoring device of a transformer comprising a. The method of claim 2,
An operation unit connected to the control unit and transmitting an operation signal to the control unit to transmit a drive signal to the actuator; And
And an output unit for outputting the overload signal transmitted from the control unit so that an operator can check if the load signal transmitted from the measurement cable to the control unit along the transmission cable is equal to or larger than a set value.

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