KR100682449B1 - Polymer line post insulator with forming structure as a single body - Google Patents

Abstract

A polymer line post insulator having an integrally formed body structure is provided to reduce a manufacturing cost and improve reliability by maximizing an insulation function without a sealing process through an insulation housing. A polymer line post insulator having an integrally formed body structure includes an FRP(Fiberglass Reinforced Plastic) core rod(100), a polymer insulation unit(210), an insulation housing(200), and a base metal unit(400). The polymer insulation unit(210) is coated to be formed on an outer peripheral surface of the FRP core rod(100) of a central unit. The insulation housing(200) has a shade structure having a different diameter which is integrated to the insulation unit(210). A resin material upper fixing unit(300) is formed on an upper part of the core rod(100). The base metal unit(400) of a metal material is pressed and assembled on a lower part. A part of the upper part of the core rod(100) is inserted into the upper fixing unit(300). The insulation housing(200) is integrated by surrounding the whole exposed surface of the base metal unit(400), the core rod(100), and the upper fixing unit(300) except a ground end surface of the base metal unit(400).

Description

POLYMER LINE POST INSULATOR WITH FORMING STRUCTURE AS A SINGLE BODY}

1 and 2 are cross-sectional views of the polymer line post insulator of the applicant's source technology.

3 is a perspective view of a preferred embodiment of the present invention.

4 is a cross-sectional view of the present invention.

5 is a cross-sectional plan view of the present invention.

Figure 6 is a perspective view of the coupling state of the upper fixture and the mandrel and the base bracket before forming the insulating housing as a component of the present invention.

Figure 7 is a cross-sectional view shown separately for a detailed description of the components of the present invention.

8 to 10 are steps of the manufacturing process of the present invention.

11 and 12 are cross-sectional views showing another embodiment of the present invention.

13 is a use embodiment of the present invention.

** Explanation of symbols for main parts of drawings **

100: mandrel 200: insulated housing

210: polymer insulator 220, 230: lampshade

220a, 230a: inclined shade 220b, 230b: spiral shade

300: upper fastener 310: through the processing line

330: engaging projection 400: base bracket

The present invention relates to a polymer insulator, and in particular, by eliminating the bonding process of the upper fixing means (upper fixing tool), a reduction in manufacturing cost and an increase in insulation function are provided, and an integrally molded body structure is provided for ease of handling by weight reduction of the product. It relates to a polymer line post insulator with.

Recently, in order to reduce the size and weight of electric power facilities and improve convenience of maintenance, existing magnetic material insulators are gradually being converted into polymer insulators.

Among them, polymer insulators have emerged as insulators (suspend insulators, long insulators, and support insulators) used in many power facilities.

In particular, suspension insulators, long insulators, and support insulators in which insulating housings are formed from polymer materials are well known as representative insulators for power distribution and transmission lines.

The polymer insulator is a core rod made of glass fiber reinforced plastic (FRP), which is a core material, and a polymer insulator coated with a material resistant to air pollution and ultraviolet rays on the outer circumferential surface of the core rod to impart mechanical stress. It is well known that it consists of a shed insulation housing which is integrally protruded into the insulation part and increases the leakage distance and flashover distance, and the upper fixture and the base bracket which are assembled by crimping by dies at both ends of the mandrel. have.

The production of such polymer insulator is carried out by inserting the FRP mandrel with adhesive on the surface into a heated mold and pushing the polymer rubber compound into the mold at high pressure to form an insulating housing on the surface of the mandrel. The mold is taken out (deformed), and the upper fixing tool and the base fitting are inserted at both ends of the core rod, and the bracket is crimped and fixed at a predetermined pressure by a die. Then, the joints (exposure joints) of the respective brackets and the insulating housing are treated with a sealing agent to produce a finished product.

However, these conventional polymer insulators have various disadvantages.

First, the conventional polymer insulator is fixed by pressing the upper fixture and the base bracket between the insulating housing and the ends of the mandrel in a state interposed therebetween, and must be treated with a sealing agent to seal the exposed joint portion, which is a coupling portion between the upper fixture and the base bracket. Insulation breakdown is prevented due to moisture infiltration, and manufacturing cost increases due to complexity of the manufacturing process.

Second, the conventional polymer insulator has a disadvantage in that handling and installation work are inconvenient due to the increase in the overall volume and the increase in the length and weight of the product due to the complexity of the structure because the upper fixing tool, which is a fixing means of the processing line, is provided.

Third, the upper fixture is provided with a metal material has a disadvantage of poor insulation.

Thus, as shown in FIG. 1, the present applicant has a FRP inside the insulating housing 2 made of EPDM or silicon, in which shades 2a and 2b having different diameters are formed on the outer surface as in the prior art. Combine the core rod (1) by insert molding, and the upper fixture (3) separately formed with an epoxy resin having excellent tracking and weather resistance in a state of covering the upper portion of the core rod (1) and the upper end of the insulating housing (2) to the adhesive Was previously registered in Utility Model Registration No. 315371 for the 'Polymer Line Post Insulator' in which the base bracket 4 was pressed and assembled under the core rod 1.

The applicant's pre-registration technology effectively improves the disadvantages of various types of polymer line post insulators, thereby providing a reduction in manufacturing cost as well as simplification of structure, weight reduction, and ease of handling. However, the insulating housing 2 Workability and manufacturing cost were not greatly reduced due to the work process of treating the exposed joint of the base bracket (4) with a sealing agent and the bonding process and hardening process according to the combination of the upper fixing tool (3) and the mandrel (1). .

Thus, the present applicant has shown that the base bracket 40 and the insulating housing (as shown in FIG. 2) to provide a shortening of the sealing agent treatment and effective insulating structure of the base bracket 4 and the core rod 1 of the above-described registration technique. 'Polymer line post' with a structure that is formed by insert molding on the outside of the base bracket 40 so as to seal the exposed joint with 20) so as to enclose the insulating portion of the insulating housing 20, thereby reinforcing the insulating length and increasing the sealing effect. 'Aja' was pre-registered as Utility Registration No. 356265.

However, the latter pre-registration technology also does not provide a solid sealing as well as a solid sealing of the upper fixture 30 and the insulating housing 20.

That is, in the applicant's pre-registered technology of Figs. 1 and 2, the coupling between the upper fixing spheres 3 and 30 and the core rods 1 and 10 of the epoxy material separately molded is combined in an bonding process by an adhesive, and then the insulating housing ( Bonding process for bonding the upper fixtures 3 and 30 to the core rods 1 and 10 by providing a seal with a separate sealant on the exposed joints of the 2 and 20 and the upper fixtures 3 and 30. And after the bonding hardening process and the bonding is required a sealing process by the sealing agent of the bonding portion of the insulating housing (2, 20) and the upper fixing sphere (3, 30) has a disadvantage that it does not provide a great cost savings.

Furthermore, the sealing agent treated at the exposed junction between the upper fixtures 3 and 30 and the insulating housings 2 and 20 by the sealing agent causes deterioration and breakage due to temperature deviation and humidity caused by external weather caused by long term use. There was also a disadvantage that can not guarantee long-term insulation life.

In addition, the upper fasteners (3,30) is formed in the form of a reduction as a whole has a disadvantage of increasing the manufacturing cost because of the high consumption of materials.

The present invention was developed to effectively solve the problems of the prior art and the applicant's prior registration techniques as described above,

SUMMARY OF THE INVENTION The present invention provides a polymer line post insulator having a rigid body of a top body and a mandrel together with an integrally molded body structure that eliminates breakdown elements by insulated housing and a complete sealing of the top fixture.

In addition, the present invention provides a polymer line post insulator having an integrally molded body structure which minimizes manufacturing cost and product defect rate by eliminating the bonding process by joining and molding the upper fixture by insert molding on the core rod.

In addition, the present invention provides a polymer line post insulator having an integrally molded body structure, which provides a further reduction in manufacturing cost by simplifying a work process since no sealing treatment of exposed joints between the upper fixture and the mandrel is provided.

In addition, the present invention is a polymer line having an integral molded body structure that ensures long-term lifespan by eliminating the source of the insulating fracture element due to the perfect sealing structure by the insulating housing formed by surrounding the exposed junction between the upper fixture and the base bracket and the mandrel In providing post insulators.

In addition, the present invention provides a polymer line post insulator having an integrally molded body structure which can reduce manufacturing cost by minimizing waste of materials by chamfering both sides of the upper fixture in the range not affected by the support of the processing line. Is in.

In addition, the present invention is a polymer line post insulator having an integral molded body structure in which the upper fastener protrudes a plurality of engaging projections on the outer circumferential surface and the chamfering surface and the insert is coupled with the insulating housing to ensure the firmness of the coupling and demoldability of the upper fastener. In providing.

Polymer line post insulator having a unitary body structure of the present invention for achieving the above object,

After the upper part of the FRP material mandrel is inserted, the upper fixing tool is molded (insert molding), and the base fitting is pressed and assembled on the other side of the mandrel. And integrally molded insulation housings having different diameters (sheds) to extend the insulation length by enclosing the entire outside of the upper fixture, thereby shortening the coupling process by the bonding process of the mandrel and the upper fixture, and exposing each component. The sealing of the junction part is completely sealed by the insulating housing, which maximizes the service life by reducing the manufacturing cost and maximizing the insulating performance.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings 3 to 7.

That is, the polymer line post insulator of the present invention is assembled to the both ends of the core rod 100 and the insulating housing 200 of the polymer material molded surrounding the core rod 100 and the core rod 100 having a predetermined diameter as in the conventional configuration. And the upper fixing tool 300 of the resin material, which is a clamp means for supporting and fixing the processing line, and a metal base bracket 400 fixed to the electric pole.

More specifically, the insulating housing is composed of the FRP core rod 100 of the core material, the polymer insulation portion 210 formed on the outer circumferential surface of the core rod, and the shades 220 and 230 having different diameters integrally formed on the insulation portion. (200), and the resin material upper fixing tool 300 is formed on the upper portion of the core rod 100 and the base metal fitting 400 of the metal material is pressed and assembled to the lower,

The upper fixture 300 is inserted into a part of the upper portion of the mandrel 100 is molded by combining,

A single body is formed by integrally forming the insulating housing 100 by surrounding the entire exposed surface of the base bracket 400, the core rod 100, and the upper fixing tool 300 except for the ground end surface 410 of the base bracket 400. It consists of.

The mandrel 100 is made of a glass fiber reinforced plastic (FRP) material with excellent mechanical strength mentioned above, and use the one manufactured by the drawing method.

And the core rod 100, as shown in Figure 8, the coupling portion 110 is formed a plurality of annular groove 120 is processed on the upper outer peripheral surface is inserted into the upper fixture 300.

The FRP core rod 100 thus processed is placed in a mold (not shown) to surround the coupling part 110 to form the upper fixture 300.

At this time, the upper fixture 300, as shown in Figure 5 and 6, the same as the applicant's pre-registered technology to form a hemispherical ring groove 320 on the upper end of the processing line passage groove 310 and its lower peripheral surface By molding, both sides are chamfered and molded for the purpose of minimizing material consumption, and each coupling protrusion 330 is integrally formed on the outer circumferential surface and the chamfered molding surface on both sides.

The upper fixture 300 is formed in this way is provided by the coupling portion 110, that is, a plurality of annular grooves 120 of the mandrel 100 is a rigid coupling to each other by the uneven coupling.

Therefore, as in the prior art, in the bonding of the upper fixture 300 and the core rod 100, the bonding process of using the adhesive and the curing process after bonding is shortened.

In addition, the plurality of coupling protrusions 330 protrudingly formed on the outer circumferential surface and the chamfering molding surface of the upper fixing tool 300 may be rigidly coupled with the insulating housing 200 formed on the outer circumference, as well as a mold during the molding process (not shown). Ease of demolding from the

The material of the upper fixture 300 is preferably a material resistant to ultraviolet light and easy to mold, and preferably an inexpensive epoxy resin.

The present invention, as shown in Figure 8, the upper fixing tool 300, the coupling portion 110 and the insert of the mandrel 100 in the state in which the core rod 100 is processed into the molding space of the mold (not shown) After forming by bonding, as shown in Figure 9 to the other side of the core rod 100, the base bracket 400 is compressed and assembled as in the prior art.

In this way, assembling and pressing of the upper fixing tool 300 and the base bracket 400 on both sides of the mandrel 100, as shown in Figure 10, the ground of the base bracket 400 in the mold (not shown) again Extending the surface leakage distance of the insulating function and the polymer insulating portion 210 and the insulating function that covers the entire exposed surface of the base bracket 400, the core rod 100 and the upper fixture 300 except the end surface 410 is covered with a certain thickness In order to increase the flashover distance due to the shape of the disks having different diameters 220,230 as an integral structure by molding the insulating housing 200 composed of alternating protrusions to manufacture the finished product.

In this case, the insulating housing 200 is formed by molding a shade of larger diameter than the shorter shaded shade on the lower outer peripheral surface of the upper fixture 300 for a longer insulating length.

As shown in the embodiment of FIG. 11, the polymer line post insulator of the present invention prevents water from being soaked on the surface caused by rain, snow, etc. in the plurality of shades 220 and 230 integrally formed on the polymer insulator 210. It is also possible to apply the structure formed by the inclined shades 220a, 230a integrally formed with a constant inclination (about 30 degrees) in one direction so that,

As shown in the embodiment of Figure 12, it is possible to apply a structure in which the spiral shades 220b, 230b having different diameters integrally molded.

The sloped shades 220a and 230a and the spiral shades 220b and 230b having such slopes include salts accumulated on the surface of the shade to allow the drainage of water to flow well, or water containing foreign matter (dirty water) such as dust. By dripping well, the life and safety by the improvement of the electrical properties are ensured by minimizing the surface residual of water which has a big influence on the leakage current increase.

The present invention, as shown in Figure 13, the screw groove 420 to the ground end surface 410 of the base bracket 400 in the same manner as the usual method to the iron (PN) is installed on the pole (EP) Fastening and fastening by using the bolt (B), mounting the processing line (OW) to the processing line passage groove 310 formed in the upper fixing sphere 300 and using a hemispherical ring groove 320 fastening means such as a binder (US) Combined) to complete the installation.

The present invention has the effect of reducing the manufacturing cost by shortening the work process by combining the upper fixture and the mandrel as a concept without bonding process, the entire exposed surface of each component (except the ground end of the base bracket) By enclosing the insulation housing, the insulation function can be maximized without additional sealing treatment by the perfect sealing of the junction of the components, which can further reduce the manufacturing cost and maintain the insulation function even after long-term use. In addition to the guarantee of lifetime, the reliability of the product is also guaranteed.

Claims (6)

FRP mandrel of core material, polymer insulating part molded on outer circumferential surface of mandrel, insulating housing with different diameter formed integrally with this insulating part, and resin top fixing device formed on top of the mandrel And including the base bracket of the metal material to be assembled to the lower portion, The upper fixture is joined by molding the upper part of the mandrel, A polymer line post insulator having an integrally molded body structure formed by integrally molding the insulating housing by enclosing the entire exposed surface of the base bracket, the mandrel, and the upper fixture except the ground end surface of the base bracket. The method of claim 1, The mandrel and the upper fixture is a polymer line post insulator having an integrally formed body structure, characterized in that the coupling portion is formed by receiving and engaging the plurality of annular groove processing on the upper outer peripheral surface of the mandrel. The method according to claim 1 or 2, The upper fixture is a polymer line post insulator having an integrally molded body structure, characterized in that both sides are chamfered molded and the outer circumferential surface and the chamfered molding surface protrudes a plurality of coupling projections. The method according to claim 1 or 2, The insulating housing is a polymer line post insulator having an integrally molded body structure, characterized in that formed by forming a shade having a larger diameter than the short diameter shade on the lower outer peripheral surface of the upper fixture for a longer insulating length. The method of claim 1, A plurality of shades integrally formed in the polymer insulation portion is a polymer line post insulator having an integrally formed body structure, characterized in that composed of a sloped shade formed integrally with a certain slope in one direction. The method of claim 1, The plurality of shades integrally formed in the polymer insulation portion is a polymer line post insulator having an integrally formed body structure, characterized in that the configuration consists of a spiral shade formed integrally with a spiral having a different diameter.

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