KR101354017B1 - An insulator-typed lighting arrester - Google Patents

Abstract

The present invention relates to a gapless insulator type lightning arrester for solving all the problems of a gap type lightning arrester and a gapless type lightning arrester. The gapless insulator type lightning arrester according to the present invention receives a continuous operation voltage without an electrical gap between a dead-end clamp of a conductive line side and a ground side.

Description

An insulator-typed lighting arrester

The present invention relates to a gapless type arrester, and more particularly, to a gapless type arrester of a type in which an insulator and an arrester are combined into a single unit.

In general, electric poles are made of concrete, wood, etc. in consideration of size, strength, economic feasibility, and local conditions, and are poles that support distribution lines, which are lines that directly supply electricity to consumers from nearby substations.

Since the electric pole is installed on the ground and supports the electric wire in the air, an abnormal voltage may be generated on the electric wire by lightning or other surge that strikes the electric pole, so that an arrester is used to prevent the electric voltage from occurring in the electric wire. It is installed at the upper end of the pole applied to the end, middle line, overhead line, underground inlet and high-voltage power facilities.

On the other hand, such an arrester is a gap type in which a gap exists between an electric wire and a ground, and is electrically isolated, and a gapless in which a continuous operating voltage flows from the electric wire to the ground electrically without a gap between the electric wire and the ground. ) Type.

As the gap type, there are those such as Japanese Patent Laid-Open Nos. 7-114846 and 9-198946. Among them, the technique of Japanese Patent Application Laid-open No. Hei 9-198946 is representatively described as the first conventional technology with reference to Figs.

That is, in the first conventional technology, an insulator having a gap arrester function is shown, and the insulator 10 is a dead-end insulator, and a core 11 of a predetermined length and a pair of nonlinear resistors are provided. By the non-linear resistance elements 12a and 12b, the pair of nut members 13 and 14, the insulating coating 15 and the pair of support holes 16 and 17, Consists of.

In the insulator 10, the core 11 is made of reinforced plastic, each of the nonlinear resistor elements 12a, 12b is made of a sintered body of zinc oxide, Each nut member 13 and 14 and each support sphere 16 and 17 are made of a conductive material, and the insulating coating 15 is made of a material such as soft synthetic rubber or synthetic resin. Is done.

The core 11 is a round rod-shaped with a predetermined length, and the threaded portions 11a and 11b are formed at predetermined positions at two intermediate portions in the longer direction. Each of the nonlinear resistance elements 12a and 12b is cylindrical and fitted to the outer periphery of the core 11 in a state of being fitted in the cylinder 12d via the thin plate 12c. It is located between both screw parts 11a and 11b. In this manner, the two nonlinear resistance elements 12a and 12b fitted to the outer circumference of the core 11 are both nut members 13 which are screwed into the threaded portions 11a and 11b of the core 11 in advance and retraction. , 14) can be firmly tightened through each of the soft plates 12c and is sandwiched.

Each nut member 13 and 14 is cylindrical and the same shape, and the annular projection 13b, 14b is shown in the middle part of the long direction of the nut main body 13a, 14a as shown to FIG. 1, FIG. Is being formed.

The insulating coating body 15 covers and insulates portions of each end side of the nonlinear resistance elements 12a and 12b, the nut members 13 and 14 and the core 11 at the outer circumference of the core 11. It is comprised by the normal body 15a which coat | covers each of these structural members, and the some umbrella part 15b formed keeping the space | interval fixed in the long direction from the outer periphery of the normal body 15a. . The insulating coating body 15 is formed by forming a non-linear resistance element 12a, 12b and a nut member 13, 14 integrally with the core 11 in an assembled state at a central portion thereof. It is becoming.

In this state, the outer circumferential surfaces of the annular protrusions 13b and 14b of the nut members 13 and 14 are located at the respective tip ends of the normal body 15a of the insulating coating 15. It is exposed from the tip side more. The outer circumferential surface of each annular projection 13b, 14b is exposed on the same surface as the outer circumferential surface of the normal body 15a, and does not protrude from the outer circumferential surface.

In addition, at the time of forming the insulating coating 15, a part of the raw material of the insulating coating 15 is firmly tightened between the cores 11 with both nut members 13 and 14, thereby providing a nonlinear resistance element ( The gap between the core 11 and the nonlinear resistance elements 12a and 12b fills the gap between the cores 12a and 12b and the core 11.

Each supporter 16, 17 is composed of ordinary bodies 16a, 17a and connecting portions 16b, 17b which are formed at the tip of each ordinary body 16a, 17a and protrude, and each of the connecting portions 16b, The connection holes 16c and 17c are formed in 17b. Each supporter 16, 17 is fitted in the state which inserted each edge part of the core 11 into the outer periphery of the core 11 in predetermined length.

Moreover, the tip parts 16d and 17d of each normal body 16a, 17a are fitted to the outer periphery of each edge part of the insulation coating body 15, and compress each tip part 16d, 17d from the outside, Each support 16 and 17 is fixed to each tip of the core 11 in a state in which the outer periphery of each tip of the insulating coating 15 is covered. At each tip of the insulating coating 15, a plurality of lines of annular protrusions 15c are formed on the outer periphery thereof, and each of the protrusions 15c is the tip of each support hole 16, 17 with respect to the insulating coating 15. The fixing state of the portions 16d and 17d is further strengthened.

The tip portions 16d and 17d of the support branches 16 and 17 provided in this way are located on the outer circumferential side of the annular projection portions 13b and 14b of the nut members 13 and 14, and the respective tip portions 16d, The discharging gaps G1 and G2 are formed between 17d) and the outer peripheral surfaces of the annular projections 13b and 14b.

In the insulator 10 configured as described above, for example, the support is supported laterally by the shoulder straps (completed) of the poles through the connecting brackets at the support pins 16, and at the same time, the wires are clamped at the support pins 17 through the clamps. The electric wires on both sides of the pole are electrically connected by a wire jumper part supported by a bind wire to a supporting insulator installed in the shoulder strap (complete).

In the insulator 10, each nut member 13, 14 also functions as a discharge electrode, and the outer circumferential surface of each annular projection 13b, 14b of each nut member 13, 14, and each support hole ( The discharging gaps G1 and G2 are formed between the tips 16d and 17d of the 16 and 17.

For this reason, when the insulator 10 is provided, the annular protrusions 13b and 14b of the nut members 13 and 14 functioning as the discharge electrodes do not protrude to the outside, and each discharge electrode ( Discharge of the maintenance inspection and the electric pole work during construction due to the protruding discharge electrode can be solved, and the flying object is caught by each discharge electrode and the discharging gap There is an advantage that G1 and G2 do not degrade insulation.

However, the above-described gap type arrester is integral with the insulator and thus externally simple, but the inherent problems of the gap type cannot be solved.

That is, the above-described gap type lightning arrester is isolated under constant voltage between the wire and the ground, and when the abnormality such as lightning strikes, the discharge occurs in the gap firstly, and the material absorbs it secondarily, so the response characteristic is good. There is an inherent problem of non-existence, and furthermore, there is an inherent problem that the blocking may not be slow or not at all for currents such as the smaller abnormal voltage following the lightning strike, in particular the discharge gaps G1, In the case of G2), the discharge does not occur at both sides, and thus the operation may not be performed at all.

On the other hand, when a large surge occurs, various smaller surges are generated on the track. The surge is absorbed by the arrester, but the surge is small enough to generate a gap discharge. There is a fatal problem that a gap arrester cannot absorb.

Therefore, because of the fatal and inherent problems of the above gap type, the gapless type is more preferable as the pole arrester. The gapless type arrester has no discharge gap between the inverter and the ground, and the wire and the ground are electrically connected directly. In case of lightning, the response speed is fast and it is more efficient to block the upstream.

On the other hand, in the gapless type lightning arrester, in contrast to the gap type, the wires and the ground are directly electrically connected. For example, the constant operating voltage of 13.2 kV to 18 kV is applied. Because of the stress, there is a problem that there is a risk of explosion due to device degradation or failure, and there is a risk of an earth leakage accident in a ground fault. Therefore, the gapless type has generally been used separately from the insulator and the arrester because of the inherent problems described above.

That is, in the conventional gapless type lightning arrester, the arrester is installed separately from the insulator on the pole, and the power line and the arrester connecting wire are coupled to the sleeve, and the insulator is connected to the sleeve. The arrester is installed in the complete pole installed in the pole, the arrester is installed by the bracket with the insulator in the complete separately installed in the other position of the upper end of the pole, the wire connected to the ground to the output of the arrester complex installation It became.

Therefore, in the conventional gapless type lightning arrester, since the completion for installing the arrester, sleeve and insulator, etc. for installing the arrester on the upper part of the pole is separately installed, the components of the upper part of the pole are very large, and thus the installation and maintenance cost is high. It takes a disadvantage, which is a factor that causes a safety accident of the worker.

In addition, in the conventional gapless type lightning arrester, since the wires are very complicatedly entangled in the upper part of the pole, the space becomes narrow, the external objects are easily caught, and the magpie house is built on the pole installed with the lightning arrester by creating a good environment for building the magpie. Therefore, there is a disadvantage in that breakage due to a short circuit of the electric wire installed on the upper pole frequently occurs.

In order to solve the problems of the conventional conventional gapless type arrester technology, a technology such as Japanese Patent Application Laid-Open No. 2008-0034266 (electric pole arrester installation structure) has been proposed as a second conventional technology.

That is, the second prior art arranges the wires formed on the upper part of the pole by connecting the arrester, the dead and clamp, and the insulator in series, and prevents the top of the pole from being complicated to prevent damage by the magpie house, and the sleeve Simplified installation process by reducing work, etc., to facilitate installation work, reduce maintenance costs, and reduce the cost of materials by reducing the number of other components installed with the arrester. Doing.

3 is a view illustrating a gapless type lightning arrester mounting structure according to the second prior art, wherein the lightning arrester 10 is installed between the power line 3 and the stub 2 installed on the pole 1. Made of structure.

In addition, the installation structure according to the second prior art is a structure in which the arrester 10, the def and clamp 11, the connecting wire 12, and the insulator 13 are connected in series.

The dead end clamp 11 and the connecting wire 12 are connected to one end of the lightning arrester 10, that is, the voltage inflow portion, and the insulator 13 is connected to the other end of the arrester 10, that is, the voltage leakage portion. In addition to the connection, the disconnector 14 and the ground line 15 are connected.

That is, an end portion of the dead end clamp 11 connected to the power line 3 is connected to one end of the arrester 10 by a first pin 11a, and a center portion of the dead end clamp 11 and the The voltage inflow portion of the arrester 10 is connected to the connecting wire 12.

Of course, both ends of the connecting wire 12 is connected to the ring-shaped connector (12a) by the clamping force of the screw (12b) and the nut (11c) to make an electrical connection between the dead clamp 11 and the arrester 10 It's perfect.

On the other hand, one end of the insulator 13 is connected to the other end of the arrester 10 by a second pin 13a, and the other end of the insulator 13 is connected to the chain claw 16 to complete the The insulator 13 is connected to (2).

The disconnector 14 is connected to the voltage leakage portion of the arrester 10, and the ground line 15 is connected to the output portion of the disconnector 14 to allow the abnormal voltage to flow into the ground.

In the second conventional technology, the insulation cover 17 for blocking the power line 3 and the dead and clamp 11 from the outside surrounds the dead and clamp 11.

The installation structure of the electric pole arrester for the second prior art functions as follows.

First, the worker connects the dead clamp 11 and the arrester 10 to the first pin 11a, and the insulator 13 and the arrester 10 coupled to the claw 16 to the second pin 13a. After connecting, the chain claw 16 is connected to the upper end of the pole (1) and coupled to the upper end 2 of the pole (1).

The dead end clamp 11 is connected to the center of the stripped power line 3 and the dead end clamp 11 by the U bolt 11b and the nut 11c, and the dead end clamp 11 and the arrester 10 are connected to the wire 12. After the connection, and wrap the dead clamp 11 with an insulating cover (17).

Finally, when the ground wire 15 is connected to the disconnector 14, the installation of the arrester 10 is completed, and the components are combined with screws and pins as a whole. Compared to this, the working process is greatly simplified.

However, since the insulator, lightning arrester, and dead-and-clamp are connected in series, the second conventional pole arrester made in this way may cause the power line connected to the dead-and-clamp to fall down when the arrester is broken down by lightning or the like. There was a problem that could cause a safety accident.

On the other hand, in order to solve the problems of the second prior art, a technique such as Japanese Patent Laid-Open No. 2012-0011903 is disclosed as the third conventional technology.

The third prior art has been devised to solve the problems of the second prior art, and an object of the third prior art is to connect an arrester and a power line to the insulator connected in series with the dead clamp. By preventing the lead wires from being exposed, even if the arrester breaks down, the sagging of the power line is prevented, the wires formed at the top of the pole are arranged neatly, and the top of the pole is not complicated. It is to provide a gapless type lightning arrester installation structure that can prevent the installation, and facilitate the installation work and reduce the maintenance cost.

FIG. 4 is a view showing a gapless type lightning arrester mounting structure according to the third conventional technology, and in the third conventional technology, between the complete line 2 and the power line 3 provided on the upper pole 1. A lightning arrester 4 is installed, a dead end clamp 5 and an insulator 6 are connected between the complete 2 and the power line 3, and the insulator 6 is connected in parallel with the arrester 4. do.

That is, the dead end clamp 5 connected to the power line 3 is connected in series with the insulator 6 to the finishing 2, and the first connector 7 coupled to one end of the arrester 4 is A second connector 8 connected to one end of the insulator 6 and coupled to the other end of the arrester 4 is disposed between the other end of the insulator 6 and the dead end clamp 5. Is connected to the connection portion of the arrester 4 is to be installed in parallel with the insulator (6).

In the third prior art, one end of the first connector 7 is fitted to one end of the arrester 4 and is connected by a nut 4a, and the other end of the first connector 7 is Is wrapped around one end of the insulator 6 to be connected by a pin 6a and a dowel pin 6b, and the insulator 6 is commonly referred to as a suspension insulator.

In addition, one end of the second connector 8 is fitted to the other end of the arrester 4 and is connected by a nut 4b, and the other end of the second connector 8 is the dead end. It is installed by wrapping the connecting portion of the clamp (5) and the insulator (6) is connected by the pin (6c) and dowel pin (6d).

In any case, in the third conventional technology, the disconnector 9 is connected to the voltage leakage portion of the arrester 4, and the ground wire 10 for flowing the abnormal voltage of the output portion of the disconnector 9 to the ground is used. It is connected to the output of the disconnector 9.

In addition, a clamp insulation cover 5a for shielding one end of the power line 3, the dead end clamp 5, and the second connector 8 from the outside surrounds the dead end clamp 5.

In particular, in the third conventional technology, as illustrated in FIG. 4, a connector insulation cover 8a for blocking a connection between the arrester 4 and the second connector 8 from the outside is provided with the arrester 4 and the second connector. Wrapping the connecting portion between the connector (8), covering the surface of the exposed portion of the second connector (8) formed between the clamp insulating cover (5a) and the connector insulating cover (8a) with an insulating synthetic resin (8b) Include a structure.

The gapless type lightning arrester mounting structure of the third prior art functions as follows.

First, the worker connects the insulator 6 and the first connector 7 to the pin 6a and the dowel pin 6b, and the dead and clamp 5, the insulator 6, and the second connector 8 Connect with pin 6c and dowel pin 6d.

The lightning arrester 4 having the lightning arrester 4 or the insulation reinforcing insulator 11 is disposed between the first connector 7 and the second connector 8, and then connected by nuts 4a and 4b.

In this state, the center portion of the stripped power line 3 and the dead end clamp 5 are connected, and the lead wire (not designated) between the second connector 8 and the dead end clamp 5 is connected. Cover the clamp insulation cover (5a) and the connector insulation cover (8a), and connect the ground wire (10) to the disconnector (9) to complete the installation of the arrester (3), each of the components with screws and pins Since the combination is also very convenient to replace the work is very simplified compared to the conventional work process.

In particular, as in the third conventional art, the arrester 4 is installed at the lower side of the dead and clamp 5 and the insulator 6 side by side to discharge the surge voltage generated during lightning or induction lightning and operation of the switch. Can be maintained normally.

In addition, since the lead wire connecting the second connector 8 and the dead end clamp 5 is not exposed to the outside, the magpie house or the magpie does not come into contact with each other. Even if the insulation is broken, the secondary side is not generated by maintaining the insulation with the ground side.

However, the third conventional gapless type lightning arrester made in this way is still located near the insulator's facility position of the arrester, and in particular, a large number of installation sites of the arrester are complicated as they are installed between power lines. (The circumference, cable head, equipment facility, etc.) is more complicated, and this has the problem that it is easy to contact the magpie or magpie, causing the related accident.

Furthermore, as described above, the gapless type lightning arrester as in the second and third prior arts has a wire electrically connected to the ground directly as opposed to the gap type, so that the constant operating voltage of 13.2 kV to 18 kV is, for example, As a result, there is a problem that there is a risk of explosion due to element degradation or failure since the lightning arrester continues to operate and is constantly stressed at the power supply.

Accordingly, the present invention has been made to solve both the problems of the gap type and the problem of the gapless type, while solving the problem of the gapless type, while simultaneously performing the functions of the insulator and lightning arrester and simplifying the jangju accident, etc. The purpose of the present invention is to provide a gapless type arrester that can prevent accidents, and in particular, the arrester and insulator are installed at the same time only by the insulator installation.

Moreover, it is the first product attempted at home and abroad to develop an existing lightning arrestor element from cylindrical to donut type and insert a FRP that can withstand the tensile force inside to provide a gapless type insulator polymer arrester that acts as both an insulator and an arrester. There is a purpose.

The gapless insulator type arrester of the present invention for achieving the above object is a gapless insulator type arrester in which a constant operating voltage is applied without having an electric gap between the dead end clamp of the ground side and the conductor side, Non-conductive steel support rods; A first mounting bracket (41) formed at one end of the support rod and a second mounting bracket (42) formed at the other end of the dead and clamp side; A varistor block having a non-linear characteristic formed in the center between the first and second mounting brackets 41 and 42 and surrounding at least a portion of the support rod; Between the first conductive charging part 47 and the varistor block and the second mounting bracket 42 which are charged between the varistor block and the first mounting bracket 41 and electrically disconnected from the first mounting bracket 41. A second conductive charging portion (48) charged and having an extension portion (48a) for electrically connecting the varistor block and the second mounting bracket (42); And a housing 46 made of a non-conductive material surrounding the varistor block, the first and second conductive charging parts 47 and 48, and the exposed portion of the support rod. The housing 46 includes a plurality of disc-shaped protrusions. Is formed side by side in the longitudinal direction, and the first conductive charging portion 47 is electrically connected to the ground line 49b so as to flow the overcurrent to the ground during a lightning strike, and the lightning arrester in the event of an abnormal current between the ground line It is electrically connected to the ground line 49b through the disconnector 49 which is a lightning arrester disconnector for disconnection from the ground, so that the dead end clamp of the ground side and the conducting side is always applied, but the operation voltage of the varistor block Only a weak current flows due to a relatively large resistance compared to the resistance of the ground side and the conductor side, and during lightning strikes, the resistance of the varistor block Non-linearly smaller than the relatively large resistance when the weak current flows, causing an overcurrent to flow to ground, but within a short time that is not sufficient to destroy the disconnector 49; When the overcurrent continues to flow for more than enough time for the connector 49 to break, the disconnector 49 is broken so as to be electrically disconnected from the ground line.

Preferably, the FRP windings (45) formed outside the varistor block; The housing 46 further includes an FRP winding 45, the first and second conductive charging parts 47 and 48, and an exposed portion of the support rod.

Also preferably, the support rod is an FRP core 43, the varistor block is characterized in that the doughnut-shaped zinc oxide block 44.

As described above, according to the gapless type arrester of the present invention, while simplifying the structure, simplifying the construction and simplifying the construction, integrating the simple functions of the insulator and the gapless type arrester, which has been separately operated, reduces the failure factor and construction. It is a breakthrough gapless type arrester that has been improved for simplicity.

In the future, this technology can be applied to transmission line lightning arresters, and can also be applied to numerous applications such as a combination of a lightning arrester and COS, a combination of support insulators and lightning arresters, which are similar multifunctional products.

Therefore, according to the present invention, not only reduce the product price of the insulator and the arrester, but also significantly reduce the construction time and installation cost accordingly, the budget saving effect will be greater (especially the construction cost is 60% reduction), Since there is no line exposure, there is no breakdown caused by falling wires, and it is a structure that does not come into contact with foreign objects (such as magpies) or birds, which prevents the breakdown of the glass. It is safe and can prevent foreign contact accidents.

Further objects and effects of the present invention will become more apparent from the following detailed description for carrying out the present invention described with reference to the drawings.

1 is a partially cutaway side view of a gap type insulator according to a first prior art;
2 is a cross-sectional view of a gap type insulator according to the first prior art;
3 is a front view showing a gapless type lightning arrester mounting structure according to the second prior art;
4 is a cross-sectional view illustrating a gapless type lightning arrester mounting structure according to a third conventional art;
Fig. 5 is a partial cutaway sectional view of a gapless type insulator for lightning arrester according to the present invention;
6 is an external view of a gapless type insulator type lightning arrester according to the present invention;
7 is a conceptual diagram in which a gapless type insulator type lightning arrester according to the present invention is installed on a pole.
8 is an equivalent circuit of a disconnector.

Hereinafter, an embodiment of a gapless type insulator arrester according to the present invention will be described in detail with reference to FIGS. 5 to 8.

However, the accompanying drawings and embodiments are merely described to more easily disclose the contents of the present invention, the scope of the present invention is not limited to the scope of the accompanying drawings and embodiments of the general knowledge in the art If you have it, you will easily know.

(Example)

Now, the gapless type insulator arrester according to the embodiment of the present invention will be described in detail with reference to FIGS.

Fig. 5 is a partial cutaway sectional view of a gapless type insulator rod for lightning rod according to the present invention, and Fig. 6 is an external view of a gapless type insulator rod for lightning rod according to the present invention, and Fig. 7 is a view of the present invention. It is a conceptual diagram which installed the gapless type insulator type lightning arrester in the pole, and FIG. 8 is an equivalent circuit of a disconnector.

First, as shown in Fig. 5 to Fig. 7, the gapless type insulator type lightning arrester 40 according to the present invention comprises: an FRP core 43 as a supporting rod of a non-conductive steel material; First mounting brackets 41 and second mounting brackets 42 formed at both ends of the FRP core 43, respectively; A zinc oxide block (44) formed between the first and second mounting brackets (41, 42) and a donut-shaped varistor surrounding at least a portion of the FRP core (43); The first conductive charging portion 47 and the zinc oxide block, which are filled between the zinc oxide block 44 and the first mounting bracket 41 and filled with a conductive material such as Al, electrically disconnected from the first mounting bracket 41. Filled between the 44 and the second mounting bracket 42 and filled with a conductive material such as Al, having an extension 48a to electrically connect the zinc oxide block 44 and the second mounting bracket 42. Second conductive charging unit 48; A portion of the first and second conductive charging parts 47 and 48 and an FRP winding 45 formed outside the zinc oxide block; And a housing 46 made of a non-conductive material surrounding the zinc oxide block 44, the exposed portions of the first and second conductive charging parts 47 and 48, and the FRP core 43.

At this time, the housing 46 has a plurality of disc-shaped protrusions 46a, 46b, 46m, 46n are formed side by side in the longitudinal direction, the first conductive charging portion 47 to send an overcurrent to the ground during lightning strikes It is electrically connected to the ground line 49b, and is electrically connected to the ground line 49b through a disconnector 49, which is a disconnector for lightning arrester which disconnects the arrester from the ground line in case of an abnormal current between the ground line. Normal operation voltage is normally applied between the dead end clamp and the side of the lead wire, but only a weak current flows due to the relatively large resistance of the varistor block. If the overcurrent continues to flow, such as a ground fault, the disconnector 49 is destroyed and electrically connected to the ground line. It characterized by that stage.

In addition, the first mounting bracket 41 and the second mounting bracket 42 are provided with a binding portion that is engaged with the complete 2 and the electric wire clamp 5 of the electric pole 1, for example, the first mounting bracket The fastening method between the bracket 41 and the stub 2 is a split pin after inserting the cotter pin 41c into the cotter pin insertion hole 41b formed at the end of the U-shaped connector 41a of the first mounting bracket 41. A method of fixing to 41d (see the lower left of FIG. 5) may be used, or a binding method between the second mounting bracket 41 and the clamp 5 may be formed at an end of the second mounting bracket 42. After inserting the cotter pin (not shown) into the binding hole 42a, a method of fixing the splitter pin 42 (not shown) may be used.

In addition, the zinc oxide block 44 may be formed in the form of a disk having a core insertion hole in the center, but for convenience of assembly, it is preferable that the zinc oxide block 44 is made in the form of a block body having a core through hole in the center, and is necessarily limited to ZnO. SiC varistors are also possible. In other words, any nonlinear variable resistor for high power, which operates as an insulator below the threshold voltage at the normal voltage and becomes a conductor during abnormal voltage such as lightning or excessive surge voltage generation, can be used.

The housing 46 is formed to have the same material and appearance as the insulator, and a plurality of disc-shaped protrusions are formed side by side in the longitudinal direction to operate as a housing lightning rod.

In addition, the insulator type arrester of the present invention is a gapless insulator type arrester in which a constant operating voltage is applied without having an electric gap between the ground side and the dead end clamp of the conductor side, and thus, the inverter on the wire side (second Located on the mounting bracket side, not shown) should be grounded through the arrester 40 of the present invention, and should be insulated from the pole (located on the first mounting bracket side, not shown), the zinc oxide block (44) Of the first and second conductive charging portions 47 and 48 functioning as the electrodes on both sides, the second conductive charging portion 48 functioning as the inverter side electrode is the second mounting bracket 42 through the extension portion 48a. Is electrically connected to the ground-side electrode, and is electrically securely separated from the first mounting bracket 41 attached to the pole, while being grounded through the disconnector 49. Should be.

To this end, the first connecting portion 49a of the disconnector 49 is coupled to the first conductive charging part 47, and for example, the coupling bolt of the first connecting portion 49a of the disconnector 49 is connected to the housing 46. Is electrically and mechanically coupled to the first conductive charging portion 47 through a bolt hole of the coupling hole, and a coupling bolt of the second connection portion 49c of the disconnector 49 is electrically and mechanically coupled to the ground line 49b. , The ground wire 49b extends underground along the electric pole 1.

In particular, in the case of the delta-wai connection, an electric shock accident may occur due to a short circuit during a ground fault due to an accident.In order to prevent this, an excessive current flows for a predetermined time during a ground fault, and it detects and bursts. FIG. 8 shows an equivalent circuit of the disconnector 49, which is a lightning arrester disconnector for disconnecting the ground wire and the arrester.

That is, as shown in Figures 5 to 8, the arrester is connected to the ground through a disconnector (disconnector), when the operation of the arrester is abnormal, the disconnector operates to separate the arrester and the ground, so the arrester is disconnected from the system Will be.

More specifically, if a leakage current flows between both terminals of the breaker when the arrester breaks down, a voltage is generated at both ends of the resistor R, and an arc is generated in the gap G. When the ignition point is reached, the gunpowder explodes and the disconnector is activated. Eventually, due to the internal pressure rise of the disconnector, the plastic body explodes and the arrester is disconnected from the system.

Based on the principle of operation, the operation area of the disconnector is divided into three parts. 1) The gap is not operated, that is, the terminal voltage of the resistor connected in parallel to the gap is less than the discharge voltage of the gap. If the leakage current is normal, it is a normal state of the arrester in which only the leakage current of the usual operating voltage flows.

2) The gap is operated but the disconnector is not operated, that is, when the arc energy of the spark delivered to the gunpowder is less than the explosive energy of the gunpowder, a lightning current such as a brain surge flows through the arrester. In this case, the arrester should operate normally and disconnector does not work either. That is, the magnitude of the current is large, but it is a surge flowing in a very short time. Therefore, the energy is calculated so that the disconnector is designed not to operate on the surge.

Finally, 3) the disconnector is operated, the leakage current increases due to deterioration of the arrester, the terminal voltage of the resistor is higher than the discharge voltage of the gap, the gap is operated, and the explosive is exploded after a certain time. Is the case.

That is, when the arrester is in a fault state and excessive current flows due to a short circuit, the discharge is performed for a sufficiently long time over a predetermined voltage, so that the explosive is exploded, the connector is broken, and the ground side is separated from the line. Will be

In this case, it is more preferable that the red flag or the fluorescent material is embedded in the disconnector so that when the disconnector is operated, a visible material such as the red flag or the fluorescent material is ejected and displayed.

Finally, the FRP windings 45 have a function of protecting the zinc oxide blocks as if they were wrapped around each other with ribbon-shaped FRP wires as if the zinc oxide blocks were continuously stressed and aged under constant power. If not, if the zinc oxide block tries to explode in a ground fault for some reason, it serves to prevent this as much as possible. The FRP windings 45 and the FRP cores are not necessarily made of FRP, and may be replaced with other non-conductive materials having the required strength and tensile strength.

On the other hand, the gapless type arrester of the present invention also simplifies the installation process, the installation of the gapless type arrester and the arrester of the third prior art and the installation of the present invention, In comparison, it is as follows.

Third prior art (eight phase construction) The present invention (three phases construction) 1) Assembling the arrester body and bracket
2) installed on the finish
3) Connect the insulation cable for lowering and the arrester body
4) Mounting Branch Sleeve Cover
5) Mount the arrester cover
6) Power line and branch sleeve compression
7) Ground Wire Connection
8) Branch sleeve cover mounting and taping treatment
Construction proceeds in the order of 8 steps. 1) Dowel pin binding
2) braided wire connection
3) Ground Wire Connection
Construction is carried out in the order of three stages.

That is, when the eight-step process of the third prior art applies the gapless type arrester of the present invention, there is an advantage that the three-step process can be simplified.

As mentioned above, although this invention was demonstrated with the pole arrester, this invention is not necessarily limited only to the pole type, Even in all cases of the gapless type to which an insulator and an arrester should be applied simultaneously in the same place, it is within the technical idea of this invention. It is immediately applicable without additional technical ideas.

Therefore, the present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be apparent to those of ordinary skill in Esau.

(Third prior art)
1: last week 2: complete
3: power line 4: lightning arrester
4a, 4b: Nut 5: Dead & Clamp
5a: clamp insulation cover 6: insulator
6a, 6c: pin 6b, 6d: dowel pin
7,8: 1st, 2nd connector 8a: connector insulation cover
8b: insulating synthetic resin 10: ground wire
(Invention)
40: insulator arrester of the present invention
41: first mounting bracket 41a: U-shaped connector
41b: cotter pin insertion hole 41c: cotter pin
41d: split pin
42: second mounting bracket 42a: binding hole
43: FRP Core 44: ZnO Block
45: FRP winding 46: housing
46a and 46b: housing lightning rod 47: first conductive live part
48 second conductive charging portion 48a: extension portion
49: disconnector 49a: first connection portion
49b: ground wire 49c: second connection portion

Claims (3)

A gapless insulator type arrester in which a constant operating voltage is applied without an electric gap between the ground and dead wire clamps,
Non-conductive steel support rods;
A first mounting bracket (41) formed at one end of the support rod and a second mounting bracket (42) formed at the other end of the dead and clamp side;
A varistor block having a non-linear characteristic formed in the center between the first and second mounting brackets 41 and 42 and surrounding at least a portion of the support rod;
Between the first conductive charging part 47 and the varistor block and the second mounting bracket 42 which are charged between the varistor block and the first mounting bracket 41 and electrically disconnected from the first mounting bracket 41. A second conductive charging portion (48) charged and having an extension portion (48a) for electrically connecting the varistor block and the second mounting bracket (42); And
A housing 46 made of a non-conductive material surrounding the varistor block, the first and second conductive charging parts 47 and 48 and the exposed portions of the supporting rods;
/ RTI >
The housing 46 has a plurality of disc-shaped protrusions formed side by side in the longitudinal direction,
The first conductive charging unit 47 is electrically connected to the ground wire 49b to allow an overcurrent to flow to the ground during a lightning strike, and disconnects the arrester from the ground wire when the abnormal current is between the ground wire. By being electrically connected to the ground wire 49b through the disconnector 49,
Normally, the operating voltage is always applied between the ground side and the dead end clamp on the lead side, but only a weak current flows due to a relatively large resistance compared to the resistance of the ground side and the lead side of the varistor block. A short time in which the resistance of the varistor block is nonlinearly smaller than the relatively large resistance when the weak current flows so that the overcurrent flows to the ground, but not enough to break the disconnector 49. Gap-type insulator characterized in that the disconnector 49 is broken and electrically disconnected from the ground line when the overcurrent continues to flow for more than a time sufficient to break the disconnector 49. Type lightning arrester. The method of claim 1,
An FRP winding (45) formed outside the varistor block; Further comprising:
The housing 46 is a gapless type arrester of the FRP winding (45), the first and second conductive charging portion (47, 48) and the exposed portion of the support rod, characterized in that it wraps. The method of claim 1,
The support rod is an FRP core (43), the varistor block is a donut-type zinc oxide block 44, characterized in that the gapless type arrester.

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