DE2610967B2 - insulator - Google Patents

Description

The invention relates to an insulator with an insulating core, an insulating sheath of the same, whose inner diameter is larger than the outer diameter of the core and both on the core also on the casing adjacent spacers, which are arranged in the axial direction at a distance from one another and one compared to the axial length of the core

ϊ have a short length.

In a known insulator of this type (DE-AS 11 76 222), the spacers are as ring disks formed, which consist of an electrically insulating material and over the entire length of their-s

adhere to the outer and inner edge of the shell or the core, so that it is inside the insulator no continuous longitudinal cracks, for example as a result of thermal expansion, can occur. Such Longitudinal cracks can namely lead to under

ι ·> bridges conductive to the influence of moisture arise that extend over the entire length of the isolator. The spaces between the spacers can be filled with air or a solid insulating medium such as a resin.

> o It is also known in the case of rod insulators with a glass fiber dust core which, because of their high tensile strength compared to their weight, are used, for example, in section separators for overhead lines of railways, the space

-'j between the smooth fiberglass rod and the one through one Plastic tube formed. Covered with cast resin pour to protect the fiberglass rod from ultraviolet radiation. Despite the significant advantages, which such rod insulators because of their cheap

μ have the ratio of tensile strength to weight, these insulators had to be dispensed with in many cases because they are unreliable. On the one hand, their unreliability is due to the fact that when the cast resin is introduced, a> displacement of the glass fiber rod and the sheath relative to one another in the radial direction cannot be avoided the solicitation. The consequence

-in are damage to the fiberglass rod, especially as a result the no longer sufficiently strongly absorbed ultraviolet radiation. On the other hand, keep kicking electrical breakdowns, which can be attributed to the fact that because of different thermal expansions

t ". The cover of the cast resin, which is usually made of polyfluoroethylene, is in some places takes off.

The invention is based on the object of creating an insulator that is not just a cheap one

w has the ratio of tensile strength to weight but also maintains its quality over long periods of time. This job is with an isolator of the type mentioned according to the invention achieved in that the spacers over the circumference of the as

"'■ -> glass fiber rod formed core arranged distributed Spacer elements are and that the space left free by the spacer elements between the fiberglass rod and the sheath in a manner known per se with an insulating material

<ό is filled. The formation of the core as a fiberglass rod results in the favorable ratio of tensile strength to weight, and the spacer elements ensure as a result of being distributed not only in the longitudinal direction of the fiberglass rod, but also in its circumferential direction

"'Arrangement a concentric position of the envelope with respect to the fiberglass rod and prevent the formation of air gaps on the inner surface of the Wrapping. The latter causes an occurrence of electrical

shear flashovers avoided, and the uniform thickness of the space between the envelope and insulating material filling the fiberglass rod protects the fiberglass rod from damage due to it ultraviolet radiation. A particular advantage here is that the effort required to achieve this goal is extremely low

As a rule, adequate centering is obtained when the spacer elements are circumferentially rotated are offset from one another by 120 °. ι »

The arrangement of the spacer elements can be different. For example, they can lie on a helix. For manufacturing reasons, however, it is more advantageous if the spacer elements of the ring zones situated are arranged in a plurality in the axial direction at a distance from each other \ '·.

The spacer elements can, for example, be constructed in the manner of nubs and fastened to the glass fiber siab Be body, attachment with a pin penetrating into the fiberglass rod is possible Spacer elements can, however, also be spheres, which are lined up on rings encompassing the glass fiber rod are. In this case, it is useful to provide the fiberglass rod with a groove where a such a ring should lie so that the position of the rings is defined

In another advantageous embodiment, the spacer elements are through in the longitudinal direction The spacer elements are formed by interrupted longitudinal ribs of the cladding or the glass fiber rod provided on the envelope, then this is provided with the longitudinal ribs during manufacture, which then in the spaces between the spacer elements be turned off. The maximum insulator length therefore depends on how deep it is Tool can be inserted into the envelope when turning the longitudinal ribs in the axial direction. If the longitudinal ribs are carved out of the fiberglass rod, then there is no such length limitation. However, this processing reduces the diameter of the fiberglass rod.

In a preferred embodiment, the insulating material is in the space between the Fiberglass rod and the sheath a permanently elastic resin. Such a resin reliably prevents that Creation of lift-offs between it and the envelope.

In the case of very long rod lengths, it can be difficult to wipe the gap between the glass fiber » rod and the envelope without the formation of air pockets and the like to fill. These Difficulties are avoided in another advantageous embodiment in that as an insulating material In the space between the fiberglass rod and the sheath, an insulating oil is provided However, in view of the thermal expansion that occurs, an expansion tank is required when using insulating oil required, but it can be very small.

Embodiments of the invention are shown in the drawing and will be described in more detail below described. It shows

F i g. 1 is an incomplete view of a first exemplary embodiment;

F i g. 2 shows a section along line 11-11 of FIG. 1;

F i g. 3 is an incomplete view of a second exemplary embodiment;

F i g. 4 shows a section along the line IV-IV of FIG. 3;

F i g. 5 is a perspective view of a third and partially sectioned in the longitudinal direction Embodiment;

F i g. 6 is a view corresponding to FIG. 5 of a fourth embodiment.

A rod insulator, shown without its fittings at both rod ends, has a fiberglass rod J. on, which consists in a known manner of a large number of glass fibers that are embedded in cast resin. The cross section of the fiberglass rod 1 is, as shown in FIG. 2 shows circular. On the fiberglass rod 1 are nub-shaped spacer elements 2 attached, which are made of metal or plastic and in the exemplary embodiment have a pin 3 which penetrates into the glass fiber rod 1 in the radial direction and thereby the spacer element at the desired point of the fiberglass rod in contact with his Outer jacket surface halL Of course, could but the spacer elements 2 can also be attached to the fiberglass rod t in another way, for example by gluing. The spacing. ^ Elements 2 are in ring zones whose spacing in the axial direction in the exemplary embodiment is about three times as large as that Diameter of the fiberglass rod 1, attached to the latter, namely three offset by 120 ° ii £ gcMu € Aua? 5jluuaitcfc! cnicm6 ίΩ jcdcf RifigZünc.

The radial height of the spacer elements 2 is selected to be equal to the distance that the inner circumferential surface des au :. Polyfluoroethylene existing, circular cylindrical Tube 4 should have from the outer jacket surface of the fiberglass rod 1. The wall thickness of this Tube 4 has the usual value for sheathing in insulators with glass fiber rods. Tube 4 is smooth on the outside The envelope could, however, also carry umbrellas, for example.

The space between the tube 4 and the glass fiber rod 1 is covered with a permanently elastic resin 5 completely filled in. The spacer elements 2 hold the tube 4 in a concentric arrangement to the fiberglass rod 1, so that the thickness of the layer formed from the permanently elastic resin 5 everywhere Due to its permanently elastic property, the resin 5 prevents the tube 4 from lifting off due to thermal expansion or the like. As a result of the small dimensions of the spacer elements 2 and their relatively large distance in the axial direction from each other, it is not disturbing that in the area of Spacer elements 2, the layer formed from the resin 5 is interrupted

The exemplary embodiments described below differ from that according to FIGS. 1 and 2 only by a different design of the spacer elements. Therefore, the following are essentially only still these »■ riedert

In the embodiment according to FIG. 3 and 4 are the spacer elements 12 short sections of Longitudinal ribs with which the made of polyfluoroethylene, the envelope forming tube 14 in the Manufacturing is provided. These longitudinal ribs are arranged offset from one another by 120 ° over the circumference after the pipe 14 has been brought to the required length, except for the Abslandh.iltcrelemente 12 removed, preferably by unscrewing. The advantage of this embodiment is that that the position of the spacer elements 12 is unchangeable, so that when assembling the Rod insulator no longer needs to be taken care of in the correct position of the spacer elements.

The space between the glass fiber slab 11 and tube 14 is covered with a permanently elastic resin IS completely failed

Since the length with which a rod insulator according to FIG. 3 and 4 can be produced, is limited in that the removal of the inner ribs of the tube 14 can only be carried out up to a certain tube length, are in the Embodiment according to Figure 5, the spacer elements 22 short pieces of longitudinal ribs of the fiberglass rod 21. The fiberglass rod 21 is thus initially processed or manufactured so that the longitudinal ribs arise, which in the embodiment around Are arranged offset from one another by 120 °. Then these longitudinal ribs are down to the short ones Spacer elements 22 forming pieces removed.

The space between the fiberglass rod 21 and the one made of polyfluoroethylene, the envelope forming tube 24 is as in the other Auslührungsbeispielen with a permanently elastic resin 25 completed in full.

The embodiment according to Figure 6 has spacer elements 32 in the form of balls made of plastic or metal and rings 36 are lined up, which the fiberglass rod 3! include and are arranged at a distance from one another in the longitudinal direction thereof. The rings 316 can be made of wire exist. So that the spacer elements 32 maintain the desired position, they are on the Rings 36 set, in the exemplary embodiment in one

■> arrangement offset by 120 ". In addition, in the fiberglass rod 21 where each ring should come to rest, cut a groove 37, which the Partially absorbs balls. Of course, the rings 36 can also lie in the grooves 37.

in the space between the outer jacket surface of the fiberglass rod 31 and that through the land holder elements 32 held in a concentric arrangement, made of polyfluoroethylene tube 34 is with a permanently elastic resin 35 completely filled.

ι "> Instead of the permanently elastic resin, all Embodiments of the space between the fiberglass rod and the pipe with an insulating oil, preferably a black oil. be filled. It but then at least had one with this intermediate

: <i room-connected expansion tank available be, for example at one end of the rod insulator. Furthermore, the spacer elements could also be offset from one another by 90 °, for example.

For this purpose 2 sheets of drawings

Claims (1)

Patent claims: I, insulator with an insulating core, one insulating covering of the same, the inner diameter of which is larger than the outer diameter of the core, and spacers resting on both the core and the cladding, which in axial direction are arranged at a distance from each other and a compared to the axial length of the Core have short length, characterized in that the spacers over the Spacer elements arranged in a distributed manner around the circumference of the core designed as a glass fiber rod (1; 21; 31) (2; 12; 22; 32) and that the space left free by the spacer elements between the fiberglass rod and the sheath (4; 14; 24; 34) in a manner known per se is filled with an insulating material Z insulator according to claim 1, characterized in that the spacer elements (2; 12; 22; 32) in Circumferential direction iun are each offset from one another by a maximum of 120 ° 3. Insulator according to claim 1 or 2, characterized in that the spacer elements (2; 12; 22; 32) arranged in several annular zones spaced apart from one another in the axial direction are. 4. Insulator according to one of claims 1 to 3, characterized in that the spacer elements (2) on the fiberglass rod (1) attached, knob-like formed body. 5. Insulator according to one of claims 1 to 3, characterized in that the A ^} jtandhalterelemente (32) are balls, the to the glass fiber rod (31) comprehensive rings (36) lined up sr 'id. 6. Insulator according to claim 5, characterized in that the glass fiber rod (31) each with a groove (37) to partially accommodate the balls (32) lined up on the associated rings (37) is. 7. Insulator according to one of claims 1 to 3, characterized in that the spacer elements (12; 22) by longitudinal ribs interrupted in the longitudinal direction of the casing (14) or of the Fiberglass rod (21) are formed. 8. Insulator according to one of claims 1 to 7, characterized in that the insulating material in the space between the glass fiber rod (It; 11; 21; 31) and the casing (4; 14; 24; 34) permanently elastic resin (5; 15; 25; 35) is. 9. Insulator according to one of claims 1 to 7, characterized in that the insulating material there is an insulating oil in the space between the fiberglass rod and the sheath 10. Insulator according to claim 9, characterized in that the space containing the insulating oil with is connected to at least one compensation tank, which is preferably provided at one end of the rod. II. Insulator according to one of Claims 1 to 10, characterized in that the casing (4; 14; 24; 34) consists of polyfluoroethylene.