DE2046774A1 - Insulator support - incorporating reinforcing glass fibre tube in its structure - Google Patents

Abstract

The glass fibre tube is located between the central resin core, and teh outer mantle with its protective ribs, bonded into place by resin in a centrifugal process. Process provides a light insulator with good mechanical stability.

Description

Glass fiber reinforced post insulator made of synthetic resin Larger plastic post insulators are, according to the current state of plastic development, preferably with casting resins to manufacture. If these are installed outdoors, they are weather-resistant and to choose casting resins resistant to tracking, for example cycloaliphatic epoxy resins. However, these cycloaliphatic casting resins are relatively expensive. This is used to compare with porcelain, the price of finished products increased sharply. Despite sufficient mechanical strengths are important for plastic insulators for outdoor installations, especially for tropical areas to provide larger reserves for aging, i.e. a plastic insulator must be designed in advance for a greater breaking load.

This measure leads to a further increase in the cost of the support, if this is built up only from resin-hardener-filler mixtures. Lately it's for the practice is desirable to manufacture lightweight isolator units, so that devices, scaffolding and assembly are cheaper.

According to the invention, the disadvantages mentioned are eliminated by that the support is provided with a tubular glass fiber reinforcement. The fiberglass reinforcement 4 can be attached to the core 1 and sheath with screens 5.

This fold can also be completely covered with a fiberglass strand Be surrounded by insulating layer 6. A particularly old efficiency is achieved when the glass fiber reinforcement 9 is arranged just below the jacket surface of the support is.

Such an arrangement increases the strength of the fiberglass reinforcement fully exploited and prevents excessive deflection of the insulator under bending stress.

In some cases, a cylindrical one has proven to be particularly advantageous Tube 4 proved to be glass fiber reinforcement. In other cases it showed a conical Fiberglass tube 43 advantages.

The glass fiber reinforcement according to the invention makes one sufficient good mechanical strength achieved. It is not required for the under the Glass fiber reinforced core to provide a mechanically high quality insulating material.

While weatherproof and leakage current-proof for the outer surface and umbrellas Insulating materials are to be chosen, the manufacture of the core can be done with a cheap one Insulating material done.

The tubular glass fiber reinforcement ensures a good mechanical Strength achieved. A post insulator constructed according to the invention is light and has high levels of upheaval.

The constructions are particularly characterized by the use of glass fiber reinforcement and an inexpensive, heavily filled synthetic resin for the support core. Thanks to the tubular, in particular cylindrical, glass fiber reinforcement that is filled on the inside the post becomes relatively rigid. The deflection of the same under bending stress is greatly reduced as a result.

For the core, for example, polyester and epoxy resins are with a high filler content, for example quartz powder, and higher heat-resistant foams with a small pore volume, the cavities of which are filled with an electronegative gas are suitable.

The tubular glass fiber reinforcement is advantageously made of Glass fiber mats, glass fiber fabric or bonded with polyester or epoxy resin cross-wound fiberglass rovings. It can also be made of mats, fabrics or rovings organic materials, e.g. polyesters, polyurethane and polyamide used will. In many cases, cylindrical reinforcement has been pre-fabricated Impregnated fiberglass mats, which compared to fiberglass fabrics and rovings a ensure greater security against electrical breakdown than in particular proven favorable.

The casting, namely coat, umbrella, head and foot are made from one Weatherproof and tracking current-resistant plastic, especially casting resins, for example with hardener provided cycloaliphatic epoxy resins, cycloaliphatic glycidyl esters produced the appropriate fillers, especially quartz powder or aluminum oxide trihydrate may contain. To compensate for different expansion coefficients, should the free-air-resistant casting resins used to reproduce the jacket and the screens be elasticized.

Head fittings and pushrods are preferably made of stainless steel Material such as brass, aluminum, copper.

If foot fittings or caps made of gray or malleable cast iron are also known as Have proven particularly advantageous, they can also be made of plastic, for example made of glass fiber reinforced or mineral fillers containing epoxy resin.

A plastic adhesive can be used as a cement material for connecting the fittings be used with conductive or non-conductive filler.

Exemplary embodiments of the invention are shown in FIGS. 1 to 8 and are described in more detail below: FIG. 1 shows a support, wherein the fiberglass cylinder is arranged on the shank surface. The core 1 takes the Head fittings 2 and 3 open. Around the core 1 is used as a carrier of mechanical strength a fiberglass cylinder 4 attached.

To the glass fiber cylinder 4 are the same on the outer periphery of the screens 5 arranged. With 6 a thin cover layer of insulating material is referred to on the screen base. In the cylindrical base of the post insulator there is a fitting 7 with putty 8 attached.

In the case of a post insulator according to FIG. 1, the rotationally symmetrical geometry has, the outer shell (glass fiber cylinder 4, screen 5 and cover layer 6) of the Insulating body can be produced by means of spinning. A non-soaked Fiberglass cylinders are inserted into the centrifugal mold. He lies down against the wall the centrifugal shape. When the mold is rotated, the pre-dosed amount of casting resin in poured the centrifugal mold (horizontal centrifugal direction). At higher speed The casting resin wets and penetrates the glass fibers. The screens are formed 5 and also a thin cover layer 6 around the stalk.

When using a casting resin with a high filler content for the Casting is first introduced into the centrifugal mold while rotating. The umbrellas are filled. Following this, the glass fiber cylinder that has not been impregnated with casting resin is inserted inserted. During rotation, unfilled casting resin is applied to it.

This wets and penetrates the glass fibers and during curing there is a solid bond with the glass fibers and the encapsulation resin.

A hollow body made in this way made of glass fiber cylinder 4, screens 5 and cover layer 6 is now filled with a cheap insulating material. It educates the Sern 1. The head sockets 2 and 3 can be inserted during the potting will. To avoid shrinkage between fiberglass cylinders 4 and core 1, it is advisable to apply light pressure during the curing process exercise the core. Finally, the caps are cemented onto the foot.

Fig. 2 shows in principle the same arrangement. However, it is the fiberglass cylinder 9 arranged just below the stalk surface. The fiberglass reinforcement is completely covered with an insulating layer. This is so thick that moisture diffusion to the glass fiber reinforced cylinder is prevented and the electrical puncture of the Mantle is satisfied.

The production of such a post insulator can, as described above, take place, it is useful to slightly harden the stalk and umbrellas so that the Glass fiber insert 9, which is located below the jacket in the trunk, is fixed before the impregnation resin is added.

In the support according to FIG. 3, the glass fiber cylinder is just below it the stem surface with a foot made of insulating material.

The outer jacket consists of the same insulating material. At 31 is denotes the core, which has an auxiliary reinforcement 32.

On the core 31 is the glass fiber reinforcement 34, its thickness is based on the necessary power of upheaval. The casting around the core 31 and fiberglass reinforcement 34 is applied, consists of the jacket with screen 33, the head and the foot 36. In the head 35 are the connecting reinforcements 37 and 38 and in the foot 36 are the sockets 39 for mounting the post by means of screw bolts on the nut. With 30 is a conical bore on the support foot 36 is designated.

The fiberglass cylinder, which is fixed to the insulator base by pouring it into place is connected, takes over the mechanical stress when the post is loaded. The core should lie just below the cast resin layer of the encapsulation. The casting thickness should be chosen so thin that it only takes on the electrical function.

The core 31 with the auxiliary reinforcement 32 can be in a casting or compression mold be produced or by foaming. On a finished part manufactured in this way the glass fiber reinforcement 34 impregnated with an impregnating resin becomes non-positive wound and pre-hardened. There is a firm bond between the introduced Fiberglass and core.

The preform can also be produced, for example, by that first the glass fiber reinforcement 34 is made, for example after known winding and impregnation processes. The pre-hardened preforxing is then compare Fig. 4, placed in an auxiliary device, the cylindrical Glass fiber core 10 is fixed in the base plate 11, which has a cylindrical guide will. The base plate 11 has a bore that has a screw bolt 12 for fixing the auxiliary reinforcement 18 receives. Clamping bolts 13 can be seen on the base plate 11. A support ring 14, on which the retaining ring 15 rests, is firmly connected to these hangs up.

By tightening the screw bolts 16, the cylindrical fiberglass core firmly guided and held in the device.

After filling in the so-called cheap mass and hardening the same Core 19. To avoid shrinkage phenomena between the fiberglass cylinder and core, the due to the chemical reaction arising, to avoid it is necessary while the hardening of the mass via a pressure disc 17 a slight pressure (P) on the Exercise mass.

Another advantageous embodiment of the invention is shown in Fig. 5 shown. While in Fig. 4 the thickness of the cylindrical glass fiber reinforcement is uniform from top to bottom, i.e. a cylinder with the same wall thickness is present, has according to FIG. 5, the glass fiber reinforcement 43 with the same inner diameter of the Core 41 differently graduated outer diameters. At the top of the core the glass fiber reinforcement has a smaller outer diameter than below. This geometric design of the load-bearing glass fiber reinforcement has the advantage that the glass fiber reinforcement follows the course of the bending moment on the supporter foot is greatest, can be adjusted well.

6 shows a suitable casting mold for producing a composite post insulator according to the invention. The base plate 29 is attached to the divided casting mold 28. The foot plate 29 receives the foot reinforcements 59 in the pins 20. Important is however, that the base plate 29 also consists of the glass fiber reinforced core from the parts 51, 52 and 53 receives and fixed. The auxiliary reinforcement 52 of the core 51 is by means of the screw 21 belonging to the form on the also the cone 22 belonging to the shape is screwed on tightly. By this measure, the eggs fixed and held inside the mold.

The casting mold 28 is open at the support head. Just a dashboard holder 23, which is connected to the mold 28 by means of bolts 24, carries and fixes the head reinforcements 57 and 58 by means of the screw bolts and spacer 25.

After the casting resin mixture has been poured and hardened, the composite body becomes demoulded by opening the mold and loosening the screw bolts. It is important to do this point out that by loosening the screw connection 21 on the base plate 29, the auxiliary reinforcement 52 is released. When the footplate 29 is pulled off, the metal cone becomes at the same time 22, which belongs to the base plate 29, is removed from the cast body and it is created according to FIG 3 shows the cavity 50 in the support foot 56.

7 claims 6 figures

Claims (7)

Patent claims Reinforced glass fiber made of core and jacket with shades Post insulator made of synthetic resin, in particular cast resin, characterized in that the support is provided with a tubular glass fiber reinforcement. 2. Post insulator according to claim 1, characterized in that the Glass fiber reinforcement (4) attached between core (1) and sheath with screens (5) is. 3. Post insulator according to claim 1, characterized in that the Glass fiber reinforcement (9) is attached just below the jacket surface. 4. Post insulator according to claim 2, characterized in that the Glass fiber reinforcement (4) is surrounded by an insulating layer (6). 5. Post insulator according to claim 1 to 4, characterized. that the fiberglass reinforcement has the shape (? lflt'S cylindrical tube (4) has. 6. Post insulator according to claim 1 to 4, characterized in that the glass fiber reinforcement has the shape of a cone @@ hr @ s (45). 7. Post insulator according to claim 1 to 6, characterized in that the core made of a highly filled epoxy resin, bran tubular glass fiber reinforcement made of glass fiber mats impregnated with epoxy resin and a jacket with screens made of one flexible, outdoor-resistant epoxy resin. Blank page