KR20130003331A - Discharge gap device and manufaturing method for distribution line protection - Google Patents

Abstract

The present invention is a sealed discharge gap device manufactured so as not to be affected by the surrounding environment, such as temperature and moisture, ZnO element is installed between the primary bushing and the series discharge gap to protect the power system by discharging the rapid current when the abnormal voltage inflows In order to protect the ZnO device in transient state, it has a parallel discharge gap connected in parallel with the ZnO device for bypass.In order to extend the life by blocking ZnO leakage current and eliminating deterioration characteristics, It relates to a discharge line device and a manufacturing method for a distribution line protection consisting of a series discharge gap is installed between the secondary bushings, and a disconnecting device is installed on the outside in order to quickly block the current flow.

Description

Discharge Gap Device and Manufacturing Method for Distribution Line Protection {Discharge Gap Device and Manufaturing Method for Distribution Line Protection}

The present invention relates to a sealed discharge gap device manufactured not to be affected by the surrounding environment such as temperature and moisture, and a ZnO device between the primary bushing and the series discharge gap to discharge a rapid current to protect the power system when an abnormal voltage is introduced. Has a parallel discharge gap connected in parallel with the ZnO element for bypass protection in order to protect the ZnO element in transient state, and ZnO to extend the life by blocking leakage current and eliminating deterioration characteristics in normal state. The present invention relates to a discharge gap device and a manufacturing method for a distribution line protection, comprising a series discharge gap between an element and a secondary bushing, and a disconnecting device installed outside to quickly block the current.

Most current arresters use ZnO devices (Gapless), which have excellent voltage-current nonlinear resistance. ZnO arresters are currently used worldwide and are an essential overvoltage control device for power systems.

ZnO devices have a multi-connected structure in which micro-nonlinear resistors with symmetrical voltage and current characteristics are connected in parallel.

ZnO devices are used worldwide because of their excellent discharge characteristics with current technology. However, the frequency of lightning due to global warming and atmospheric instability is increasing more frequently, and exposed to the harsh external environment, the rapid deterioration of ZnO devices, the failure rate of the arrester in the field is in excess of about 10%.

According to KEPCO's blackout analysis of 2008 ~ 2009, it is reported that it occupies 6.84% in case of temporary power failure due to arrester failure and 10.6% in case of momentary power failure. The arrester failure can have various causes, and the specific cause of the failure can be explained as follows.

The current leakage to the ZnO element is 21.43 in the case of 1-line earth ground when the value is 1 in 3-phase equilibrium, which is the largest compared to 8.1 in the case of 2-line earth ground and 0.43 in case of short circuit between lines.

This is because a voltage larger than the starting voltage of the ZnO block varistor is applied, and thus the resistance leakage current is largely displayed at the overlapping voltage.

In the case of a two-wire ground fault, the leakage current was 8.1 and a large amount of leakage current flowed. In the case of the line short circuit, the leakage current hardly flowed.

As a result, in the case of single-line ground, the highest voltage was applied to each phase to generate the most leakage current in the ZnO device.

Looking at the research paper on the multi-brain impulse of the study on the deterioration of the ZnO device, it can be observed that a strong discharge light is generated between the ZnO device and the electrode in contact with it. The generation of discharge light at such a contact surface is accompanied by heat, and heat is also generated in the ZnO element.

If this effect is repeated and the effects accumulate, the properties of the ZnO element will change, and eventually the ZnO element will not be able to achieve its performance as a lightning arrester.

Therefore, a device is needed to cut off the leakage current to protect the ZnO device in the normal state. In particular, due to the reverse surge, the ZnO device is rapidly deteriorated, resulting in a shortened lifespan and a problem in that reliability cannot be guaranteed.

The problem to be solved by the present invention is a device for protecting the power system in the event of abnormal voltage, such as lightning and switching surge, ZnO element, parallel discharge gap, series discharge gap, safety resistor is installed in the internal insulation oil unlike the conventional one-time lightning arrester And the counter and disconnector are to be semi-permanently reused by the structure connected to the outside.

The solution of the present invention is a sealed discharge gap device that is not affected by the surrounding environment such as temperature and moisture, and the ZnO element between the primary bushing and the series discharge gap to discharge the current in order to protect the power system when an abnormal voltage is introduced. Has a parallel discharge gap connected in parallel with the ZnO element for bypass protection in order to protect the ZnO element in transient state, and extends the life by blocking ZnO leakage current and eliminating deterioration characteristics in normal state. A series discharge gap is installed between a ZnO element and a secondary bushing, and a discharge gap device for protecting a distribution line having an external disconnector is installed in order to quickly block the current.

Another solution of the present invention is to fasten the safety resistor between the series discharge gap and the enclosure ground connection terminal to manage the lightning frequency and the number of discharges by region, and fastening the signal line from both ends of the safety resistance with the counter installed outside The present invention provides a discharge gap device for protecting a distribution line.

Another solution of the present invention is to install a ZnO element between the primary bushing and the series discharge gap to discharge the rapid current to protect the power system when an abnormal voltage is introduced, and to protect the ZnO element in a transient state. A parallel discharge gap is installed in parallel with the ZnO element for bypass purposes, and a series discharge gap is formed between the ZnO element and the secondary bushing to extend the life by blocking the ZnO leakage current and removing the deterioration characteristic in the normal state. The present invention provides a method for manufacturing a discharge gap for protecting a sealed type distribution line configured to be not affected by the surrounding environment such as temperature and moisture, which is configured to install and to install a disconnector outside to quickly block the current.

The discharge gap for protecting the distribution line according to the present invention blocks the leakage current in an open state in a normal state, and operates only when an abnormal voltage such as a lightning strike and an open / close surge occurs, considering the characteristics of the discharge gap unlike a protection device of an arrester. It can be used as a permanent protection facility because the protection range and time can be set. Especially, unlike the general disposable lightning arrester, it can be semi-permanently reused only by replacing the disconnecting device, which has the advantageous effect of reducing the management cost and ensuring the reliability of operation.

1 is a conventional arrester installation diagram.
2 is an installation diagram of a discharge gap device for protecting a distribution line according to the present invention.
3 is an external configuration diagram of a discharge gap device for protecting a distribution line according to the present invention.
Figure 4 is a detailed assembly diagram of the disconnector according to the present invention.
5 is an internal configuration diagram of a discharge gap device for protecting a distribution line according to the present invention.
<Brief Description of Drawings>
11: power line 12: neutral line
13: Equipment earth wire 14: Lightning arrester earth wire
15: first drop line 16: lightning arrester
21: discharge gap for protection of distribution lines 31: primary bushing
32: counter 33: enclosure ground connection terminal
34: Grounding terminal 35: Disconnector
36: enclosure 41: secondary bushing
42: safety resistance 43: counter detection wire
44: series discharge gap 45: disconnector fixing bolt
51: parallel discharge gap 52: insulating oil
53: Zno element

Hereinafter, the present invention will be described in detail. The discharge gap device for protecting the distribution line according to the present invention is a sealed discharge gap device so as not to be influenced by the surrounding environment such as temperature and moisture, and between the primary bushing and the series discharge gap in order to protect the power system by discharging the rapid current when an abnormal voltage is introduced. ZnO element is installed in the circuit, and in order to protect the ZnO element in the transient state, the parallel discharge gap connected in parallel with the ZnO element is connected and installed for bypass. In order to extend the series discharge gap between the ZnO element and the secondary bushing is installed, in order to quickly block the current consists of a configuration in which the disconnecting device is connected to the outside. A specific embodiment according to the present invention will be described.

&Lt; Example 1 >

A first embodiment of the present invention will be described with reference to the drawings. Embodiment 1 relates to a discharge gap device for protecting a distribution line according to the present invention.

The present invention may be variously modified and may have various embodiments.

The discharge gap device for protecting the distribution line of Example 1 will be described in detail based on the matters shown in the drawings.

However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all transformations, equivalents, and substitutes included in the spirit and scope of the present invention.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In this specification, terms such as "comprise" or "have" are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described on the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

1 is a conventional arrester installation diagram. The arrester 16 is connected to the existing power line 11 for each phase by the first lowering line 15, and is connected to the arrester ground line 14 at the ground line connecting terminal of the arrester, and the arrester ground line is connected to the neutral line 12. It is configured to common ground.

2 is an installation diagram of a discharge gap device for protecting a distribution line according to the present invention.

As shown in Figure 2 is connected to the primary bushing as the primary lowering line 15 to the existing power line 11 for each phase, the arrester ground line is connected at the disconnecting terminal end ground line connection terminal of the present invention, the present invention The equipment ground line is connected at the enclosure ground connection terminal of the discharge gap device for protecting the distribution line.

In addition, in order to reduce the reduction ratio of the induced voltage, it is preferable that the voltage reduction effect is excellent, and the insulator separately reinforces the thickness and ground of the ground wire of 100 mm2 or more of GV (grounding PVC insulated wire) having self-extinguishing property.

The thickness of the ground wire is configured to have a larger discharge capacity than the existing lightning arrester because it greatly affects the discharge of large energy generated by lightning strikes in the distribution line in the shortest time.

3 is an external configuration diagram of a discharge gap device for protecting a distribution line according to the present invention.

As shown in FIG. 3, a disconnecting connector 34 is provided to connect the primary bushing 31 terminal and the arrester ground line to connect the three-phase power line.

In addition, the counter grounding terminal 33 and the counter 32 is connected to the outside to check the number of operations of the arrester so as to connect the device ground wire, and the secondary bushing ( 41) It is connected to the side.

Figure 4 is a detailed assembly diagram of the disconnector according to the present invention.

As shown in FIG. 4, when the current is interrupted from the disconnector when the current exceeds the rated discharge capacity, the disconnector fixing bolt 45 is loosened and configured to be replaced with a new disconnector 35. Conventional lightning arrester has been a problem that the management cost is generated a lot because it is to be removed by a live line when disconnecting the disconnector for a single use, and to install a new arrester in the live state.

The present invention is configured to install a safety resistor 42 inside the device to make a double safety ground is configured to replace the arrester in the oblique state. The safety resistor 42 is connected between one side between the series discharge gap 44 and the secondary bushing, and the enclosure 36 of the discharge gap device for protecting the distribution line.

Therefore, compared to the conventional lightning arrester can significantly reduce the management cost, there is an advantage that can be operated semi-permanently.

5 is an internal configuration diagram of a discharge gap device for protecting a distribution line according to the present invention.

As shown in FIG. 5, the single phase and the third phase can be manufactured according to the phase-specific circuit. It is connected to the primary bushing 31 in the power line to withstand high dielectric strength when abnormal voltage occurs, and is connected to the lightning arrester ground line in the disconnecting terminal 35 connection terminal, and the ZnO element inside the device in the primary bushing 31. 53 is connected to one side, the other side of the ZnO element 53 is connected to one side of the series discharge gap 44, the other side of the series discharge gap 44 is the secondary bushing (41) outside the device Is connected to one side of, the other side of the secondary bushing 41 is connected in series with the disconnector (35).

Further, the ZnO element and the parallel discharge gap 51 are fastened in parallel. One side of the safety resistor 42 is connected to the terminal connecting the series discharge gap 44 and the secondary bushing 41, and the other side of the safety resistor is connected to the device enclosure 36.

The counter 32 is configured to connect the signal lines to both terminals of the safety resistor 42 so as to manage the lightning frequency and the discharge frequency for each region.

In order to maintain the insulation, the oil is filled up to the lower connection terminal of the primary bushing, and the ZnO element, the parallel discharge gap, the series discharge gap, the safety resistor, and the secondary bushing connection terminal are all configured in the insulation oil.

The discharge electrode tip of the parallel discharge gap 51 is sharply formed because the electric field is concentrated as the tip is sharper, and the discharge is easily performed. Formed.

&Lt; Example 2 >

Example 2 relates to a method for manufacturing a discharge gap for protecting a distribution line according to the present invention.

Example 2 is a method of manufacturing a discharge gap for protecting a sealed distribution line so as not to be affected by the surrounding environment such as temperature and moisture. The method of manufacturing a discharge gap for protecting a sealed distribution line includes installing a ZnO element between the primary bushing and the series discharge gap to protect the power system by discharging the rapid current when an abnormal voltage is introduced, and to protect the ZnO element in a transient state. Installing a parallel discharge gap connected in parallel with the ZnO element for the pass, and series discharge gap between the ZnO element and the secondary bushing in order to cut off the ZnO leakage current in the steady state and to extend the life by eliminating degradation characteristics It is composed of the step of installing, and the step of installing the disconnector to the outside in order to quickly block the upstream.

In addition, in the method of manufacturing a discharging gap for protecting a distribution line, one side of the safety resistor 42 is connected at one terminal connected to the series discharge gap 44 and the secondary bushing 41, and the other side of the safety resistor is connected to the apparatus. And connecting to 36).

The method may further include connecting to both terminals of the safety resistor 42 with the counter 32 located outside by a signal line.

In Embodiment 2, in order to avoid duplication of the matters described in Embodiment 1, description thereof is omitted for a technical configuration applicable to the method of manufacturing a discharge gap for protecting a distribution line from the above-described matters.

The above descriptions of the first and second embodiments are merely illustrative of the technical spirit of the present invention, and various modifications and changes may be made without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited thereto. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

The present invention is a sealed discharge gap device manufactured so as not to be affected by the surrounding environment such as temperature and moisture, ZnO element is installed between the primary bushing and the series discharge gap in order to block the current flow in case of abnormal voltage inflow to protect the power system In order to protect the ZnO device in transient state, it has a parallel discharge gap connected in parallel with the ZnO device for bypass.In order to extend the life by blocking ZnO leakage current and eliminating deterioration characteristics, The series discharge gap is connected between the secondary bushings, and the discharge gap device and the manufacturing method for protecting the distribution line, which are composed of a disconnecting device installed outside to quickly block the current, can be used semi-permanently. high.

Claims (7)

In the discharge gap device for protecting the distribution line,
A ZnO element disposed between the primary bushing and the series discharge gap to protect the power system by discharging the rapid current when an abnormal voltage is introduced;
A parallel discharge gap coupled in parallel with the ZnO device for bypass to protect the ZnO device in transient state; And
Discharge gap device for protection of power distribution line composed of series discharge gap between ZnO element and secondary bushing to cut off ZnO leakage current in normal state and remove deterioration characteristics and extend life. The method of claim 1,
The discharging gap device for protecting the distribution line further comprises a disconnecting device connected to one side of the secondary bushing so as to quickly block the current flow. The method according to claim 1,
The discharge gap device for protecting the distribution line has a double safety ground, and installs a safety resistor between one side between the series discharge gap and the secondary bushing and the enclosure of the device so that the lightning arrester can be replaced in a diagonal state.
Discharge gap device for protection of the distribution line further installed with a counter to manage the frequency of lightning and the number of discharges by connecting the signal line to both terminals of the safety resistor. The method according to claim 3,
In order to maintain an insulation state, the discharge gap device for protecting the distribution line is filled with insulating oil to the lower connection terminal of the primary bushing, and the ZnO element, parallel discharge gap, series discharge gap, safety resistance, and secondary bushing connection terminal are all insulated oil. Discharge gap device for protection of distribution lines configured to be inside. In the method of manufacturing a discharge gap device for protecting a sealed distribution line,
Installing a ZnO element between the primary bushing and the series discharge gap to discharge the rapid current when the abnormal voltage is introduced to protect the power system;
Installing a parallel discharge gap coupled in parallel with the ZnO device for bypass to protect the ZnO device in a transient state;
Installing a series discharge gap between the ZnO element and the secondary bushing to block the ZnO leakage current in the steady state and to remove the deterioration characteristic and to prolong the life; And
A method of manufacturing a discharge gap device for protecting a sealed distribution line, comprising the steps of installing a disconnector outside to quickly block the current. The method according to claim 5,
The method of manufacturing a discharge gap device for protecting a distribution line further comprises connecting a side of the secondary bushing to install a disconnector externally so as to quickly block the current flow. The method according to claim 5 or 6,
The method of manufacturing a discharge gap device for protecting a distribution line includes installing safety resistors between one side between a series discharge gap and a secondary bushing and an enclosure of a device so that a lightning arrester can be replaced in a diagonal state with a safety ground configured to double; And
And connecting the signal lines to both terminals of the safety resistor to connect and install counters to manage lightning frequency and discharge frequency for each region.

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