KR19990017058U - Temperature measuring device of large power cable using electromagnetic induction - Google Patents

Abstract

The present invention relates to a device for measuring the temperature of a high voltage high current cable such as power equipment.

The present invention consists of a current transformer 10, a rectifier 20, a converter 30 and a thermometer 40, the current transformer 10 is by the primary current (i ₁ ) flowing through the large power cable 50 In order to detect the induced secondary current (i ₂ ) is installed in the structure surrounding the large power cable 50, the rectifier 20 is a direct current of the secondary current detected by the current transformer 10 direct current It is installed at the other end of the current transformer 10 so as to convert to, and the converter 30 is installed at the other end of the rectifier 20 to convert the DC current signal rectified in the rectifier 20 into a temperature signal In addition, the thermometer 40 is installed at the other end of the transducer 30 so as to indicate the temperature according to the temperature signal converted by the transducer 30.

Therefore, according to the temperature measuring device of the high power cable of the present invention, the operator does not need to directly check whether the cable or the bus bar is overheated, and can check at all times, thereby preventing the waste of manpower and time, and additional expensive equipment Since it is not necessary, the cost of facility management is reduced, and when it is determined that it is overheated, it can automatically take necessary emergency measures quickly, and thus it is possible to prevent damages of the power supply board, the distribution board, and the distribution board beforehand. .

Description

Temperature measuring device of large power cable using electromagnetic induction

The present invention relates to a device for measuring the temperature of a high voltage high current cable such as power equipment.

In general, since high voltage and high current are applied to large power equipment of an industrial facility, a cable having a large diameter and excellent conductivity is used. For example, as shown in FIG. 1, a power supply panel or a distribution panel of a power facility is equipped with a conductor bar bus (BUS-BAR) to smoothly flow current, so that the bus bar can sufficiently withstand high voltage and high current. It is installed by plating silver on the copper plate.

However, since a high voltage high current always flows in the high-power cable or bus bar as described above, due to the intrinsic resistance of the cable or bus bar itself, a huge amount of resistance heat is generated over time, thereby increasing the temperature. In addition, since the cable or bus bar is used in a closed space while being blocked by an insulator, the temperature of the cable or bus bar is rapidly increased as the equipment is operated for a long time. At this time, the energy generated from the cable or bus bar is expressed by the following equation.

In Equation 1, H is a calorific value, 0.24 is a constant, I is a current of a cable or bus bar, R is a specific resistance of the cable or bus bar, and T is time.

On the other hand, bolts are generally fastened to connect the cables or busbars, and these connection parts are loosened or corroded due to repeated expansion and contraction due to changes in ambient temperature, causing vibration and bolt loosening of the contacts. As a result, heat is generated due to an increase in contact resistance, and when the bus bar (BUS-BAR) is burned out or the high-voltage line is shorted or severely, a spark may occur to cause a fire. Therefore, in order to prevent equipment damage and industrial accidents caused by accidents in the power system, there is a need for a bus bar temperature measuring device that can easily check whether a large-scale power cable or bus bar is heated or not.

However, in the related art, since there was no special method for measuring the heating state of the heat generating bus bar as described above, it was common for the operator to go directly to the installation site and visually check the physical condition of the cable or bus bar that is carrying the high voltage high current. Since it is possible to measure only by contacting, imports of expensive teramobel or portable pyromiter, which are not produced in Korea, were used to measure the heat generation. Such patrol and inspection methods not only induce excessive waste of time, money and money, but also could not immediately cope with an unexpected event such as heat generation of the cable or bus bar, there was a problem that there was always a risk factor.

In addition, the imported device has a problem in the reliability of the measured value when used for a long time, and if it is left unheated cable or bus bar as it is, an arc occurs due to loss of insulation resistance due to burnout, large damage to all related equipment There is a problem that can be expanded by accident.

Therefore, the present invention is intended to solve the above problems, it is possible to monitor the heating state of the large-power cable or bus bar accurately and easily by the operator to go directly to the site and check the heating state at all times, It is an object of the present invention to provide a device for measuring the temperature of a large power cable that can readily take appropriate countermeasures in case of an emergency such as heating of a cable or a bus bar.

1 is a structural diagram of a conventional current transformer

2 is a device configuration diagram of a temperature measuring device of the present invention

3 is a rectifier circuit diagram of a temperature measuring device of the present invention.

4 is an overall circuit diagram of a temperature measuring device of the present invention

<Description of Symbols for Main Parts of Drawings>

1: Iron Core 2: Through Hole

3: Secondary winding 4: Insulator

5: Mounting plate 6: Secondary terminal

7: Test Terminal

10: current transformer 20: rectifier

30: Temperature Transducer 40: Thermometer

50: high power cable 60: correction signal

70: selector switch

C1, C2, C3: Condenser

R: Resistor R2: Load regulating resistor

In order to achieve the above object, the present invention includes a rectifier 20 connected to the other end of the rectifier 10 and the rectifier 20 that surrounds a large power cable 50 that is a bus conductor as shown in FIG. 2. The transducer 30 is connected to the other end, the thermometer 40 is connected to the other end of the transducer 30.

The current transformer 10 is installed in a structure surrounding the large power cable 50 to measure the current (i ₁ ) flowing in the large power cable 50, 1 flowing in the large power cable 50 The voltage is induced by the magnetic field generated by the secondary current i ₁ so that the secondary current i ₂ can easily flow, and the joule heat generated from the busbars and the load current flowing through the current transformer 10 It is composed of a material that can be used semi-permanently without fear of dielectric breakdown.

The rectifier 20 is installed at the other end of the current transformer 10, and serves to convert an alternating current, which is a secondary current detected by the current transformer 10, into a direct current. Referring to the circuit configuration of the rectifier 20 of FIG. 3, an RC circuit coupled in parallel with a capacitor C1 and a resistor R is installed in order to prevent unstable rectification in the process of converting alternating current into direct current. . At this time, the rectified current is converted into a direct current in a diode and then converted into a good direct current signal after the ripple is reduced in a smoothing circuit composed of two capacitors C2 and C3.

The converter 30 is installed at the other end of the rectifier 20, and serves to extract a temperature signal from the DC current signal stably rectified by the rectifier 20.

Finally, the thermometer 40 is installed at the other end of the transducer 30, and serves to indicate the temperature according to the temperature signal extracted from the transducer 30. At this time, the correction signal 60 for correcting the temperature output by measuring the ambient temperature of the ambient temperature to the temperature signal extracted from the transducer 30 is processed together to configure only the actual bus bar temperature. When the temperature signal is used as a general control signal, when the cable or bus bar is detected to be in an overheating state, emergency measures such as blocking current applied thereto and lighting an emergency lamp may be automatically taken.

4 is a diagram showing the overall circuit diagram of the temperature measuring device of the high-power cable of the present invention having the configuration as described above, selection switch 70 to measure the temperature of each phase (Phase) of the cable or busbar separately ) Was installed.

Therefore, according to the temperature measuring device of the high power cable of the present invention, the operator does not need to directly check whether the cable or the bus bar is overheated, and can check at all times, thereby preventing the waste of manpower and time, and additional expensive equipment Since it is not necessary, the cost of facility management is reduced, and when it is determined that it is overheated, it can automatically take necessary emergency measures quickly, and thus it is possible to prevent damages of the power supply board, the distribution board, and the distribution board beforehand. .

Claims (1)

In a device for measuring the temperature of a high voltage high current cable, such as power equipment, comprising a current transformer 10, a rectifier 20, a converter 30 and a thermometer 40, the current transformer 10 is a high power cable ( The high power cable 50 is surrounded by a structure that can detect the secondary current i ₂ induced by the primary current i ₁ flowing in the 50, and the rectifier 20 is the current transformer It is installed at the other end of the current transformer 10 so as to convert the alternating current, which is the secondary current detected at 10, into direct current, and the converter 30 converts the direct current current rectified by the rectifier 20 into a temperature signal. It is installed on the other end of the rectifier 20 so that the conversion, and the thermometer 40 is installed on the other end of the transducer 30 so as to indicate the temperature in accordance with the temperature signal converted in the converter 30 Temperature side of large power cable using electromagnetic induction Equipment