DE7408004U - Protective cover for electrical conductors - Google Patents

Description

THE ELECTRICITY COUMCIL

30 Millbank

London SWlP 4 R ", England

Protective cover for electrical conductors

The Crfinduna concerns protective covers for underground leate high voltage electrical cables.

It is known per se to provide high-voltage cables, in particular cables for voltages up to 11,000 volts and above, with a protective cover when they are laid underground, with thick layers of clay or concrete ceilings being used as protective covers, which are at a vertical distance above the cable are arranged. The purpose of these ceilings is to indicate the point where the cables are leashed in excavations and to protect the cables from contact rr.it ircrendeir.ero tool. It goes without saying that einr serious danger occurs,

V7enn a high-voltage cable from a tool mechanically gets destroyed.

The cable protection covers produced up to now usually consist of elongated elements which have a rectangular, flat shape, the surface sloping on both sides of a central edge extending in the longitudinal direction of the protection cover. The sloping surface serves to deflect objects hitting the protective cover. Because of the weight of the clay layer or the concrete material, the total length of the individual covers must be kept quite small in order to make the covers easier to handle. Uicss ^Ä .V> dsckuncren are therefore 2u schitiel- mn for? to act a satisfactory protection against mechanical backhoe excavators, which lift the narrow covers and carry away with the remaining excavated earth in the form of gravel, without the worker noticing that it is a protective cover for an electrical cable. Another disadvantage of the protective covers used hitherto is that one impact with a tool, such as a hoe, is sufficient to break the concrete or clay cover, so that mechanical protection against further impacts is no longer available. In addition, the weakness inherent in the known protective covers leads to a high loss during transport and installation.

It has already been suggested the strength of the protective covers to reinforce and thus to reduce or complete damage during transport To prevent destruction from impacts exerted by tools on the protective covers by one

the protective covers with steel reinforcing rods provides. These reinforced protective covers have significantly improved properties compared to the unreinforced ones Protective covers, however, still leave something to be desired in terms of their efficiency, since they are used to achieve a weight that is limited for handling are still too small. They are also much more expensive as unreinforced protective covers.

The invention is therefore directed to providing an improved protective covering for underground power cables to accomplish.

According to the invention is a protective cover for an under Cable laid in the ground is provided, which is characterized in that the plate element is a fiber-reinforced Has concrete wall which encloses an inner filling made of polymeric or elastomeric material. The polymer or elastomeric material of the inner filling is preferably in the form of small particles, namely in the form of particles, crumbs or balls made of polymeric material, such as from polystyrene, polyethylene or polyvinyl chloride or from an elastomeric material such as from Natural rubber or man-made rubber. The inner material is surrounded by the concrete mass, which is made of cement, fine minerals and a fiber reinforcement wherein at least one synthetic resin is added to the mixture. Conventional polypropylene or polypropylene are used as fiber reinforcement Glass or nylon or ceramic fibers. These fibers sirad in the mortar mass distributed as desired, and they make the concrete essentially impact-resistant. The synthetic resin can be

detached form e.g. from a latex or art been formed. A thermosetting resin such as polyester, epoxy resin could also be used or polyurethane. Concrete mixed with such synthetic resins has improved elasticity, so that the concrete can be stretched without breaking and so that the elastic properties of the reinforcing fibers are fully used Geltuna can. In practice, the effectiveness of the Protective cover is retained even if a mechanical workpiece hits the cover several times be guided. By using the reinforcement material the SchutzabdecVuna can be much thinner in cross-section are performed than with conventional massive Concrete protective covers, although they are the same mechanical Strength indicator .. However, since it is polymeric or elastomeric Material filled into the hollow interior of the 3et.on construction is it possible to make a thicker protective cover without d- ^ f? the weight increases significantly. if the protective cover according to the invention with a cover compares with the same dimensions from solid praying, then the protective cover according to the invention is not only stronger, but aich lighter, and can therefore be handled better v / earth. The inner filling also forms another very important advantage, which is that the energy introduced by a tool hitting the protective cover is absorbed.

Since the protective cover η lighter for a given size than the conventional protective covers made of solid Concrete, they can also be run longer, and nevertheless have a suitable handling

Protective covers, if e.g. a mechanical backhoe Auscrrabunaen i

üin another essential advantage c-er according to the invention Construction consists in the fact that the material is essentially one Offers total protection against impact from tools, so there is no need for a sloping surface to be provided, as is the case with conventional Schutzabdekkunaen is the case, which is intended to serve to deflect impacts on the protective cover. The invention Covers can therefore be made as simple flat, rectangular plates of the same thickness. Through this v / make the transport and the installation of the protective covers much easier.

The greater strength of the material of the invention compared with the solid concrete, therefore, still has an economic advantage that the loss of the protective covers is significantly reduced during transport and use. Another advantage of the shape of the inventive Protective covers are that they can be made in longer pieces, so that the connection between the requirements placed on the adjacent protective covers are significantly lower. The protective covers can be connected to one another in a known manner by projecting parts on one protective cover with corresponding molded parts of the next protective cover are brought into engagement.

Further features, advantages and details emerge

from the following description of the drawing.

The protective cover 1 shown in the drawing is in the form of a rectangular plate of uniform thickness formed, of which one corner to clarify the discovery is cut off so that you can see the inner filling 2 made of polymer particles, which are approximately 50% of the total volume of the plate. About these polymer particles around the plate has a wall 3 acts fiber-reinforced Concrete on. In a typical embodiment, the concrete consists of a weight proportion of cement with 3 to 8 parts by weight of sand and a fiber reinforcement with 0.1 to 1.0% polypropylene fibers and / or 0.5 to 5% glass fibers, the fiber percentages being based on the weight of the total dry mortar mass. That Water and then a certain amount of a synthetic resin emulsion, which is sufficient to give the concrete mass a desired To give elasticity, are added to the mixture in a manner known per se to the fiber-reinforced Manufacture of concrete that will be used for the pouring of the protective cover. If the cement is portland cement it is about dsn glass fibers to alkali-resistant glass fibers, as they are used in a known manner to reinforce 3eton.

In a typical exemplary embodiment for production a concrete protection cover, the mixture is produced by a mechanical mixer in a period of time, which is not less than 30 minutes, so that an intimate and satisfactory mixture is achieved. the Resin emulsion is then added and the wet

mix is then poured into the mold so that one of the larger fleeing of the protective cover is formed, the henisch either by an introduction under pressure or is compacted by mechanical vibration of the casting mold. Then the polymeric filler material and others Filled with concrete, the concrete being placed on the top and side of the filler material, around the Filling the mold completely, and the compaction again by the action of pressure or by mechanical vibrations of the mold, is achieved.

Geiräß another possibility for the production of a concrete chutr cover v / ground the cement, sand, reinforcing fibers and water in a conventional manner in a mixer mixed. Then the wet concrete mix Additives added to form a blowing agent of a two-part foamed polyurethane. Once the mixture is completed, the combined is made Mixture introduced into the mold, which consists of two parts. The mold is then kept closed until the concrete has set. The inner filling material is placed in the form of a block in one part of the mold, before the concrete is poured, and there are small supports that hold the block of filler material from the Keep the bottom of the casting mold free so that a concrete wall can be made that surrounds the block in uniform thickness. With the completed protective cover affect the small block spacings that go into the Concrete «and intervene, in practice, not the effect of the Protective cover.

Claims (10)

Protection claims 1. Plate-shaped protective cover for an underground laid cable, characterized that the plate element (IJ is a fiber-reinforced concrete wall (3), which has an inner filling (2) made of polymer o ^ it encloses elastomeric material. 2. Protective cover according to claim 1, characterized in that the polymeric or elastomeric material is in the form of small particles. 3. Protective cover according to claim 1 or 2, characterized in that the interior space with is filled with the polymeric or elastomeric material, essentially 50% of the total volume of the element (i) matters. 4. Protective cover according to one of claims 1 to 3, characterized gekennzei cn η et that the inner filling material is polystyrene, PolvHthylen or polyvinylchloride is. 5. Protective cover according to one of claims 1 to 3, characterized marked that the inner The filling material is natural rubber or man-made rubber. 6. Protective cover according to a dor ^ .npr'iche 1 to 5, thereby 7 e k ο η η ζ e ic 'η. η e t, ΓΪ.τβ the iiotoriverst ^ 'rVunrTifnsorr. Made of Polvnrorvlcn, .ivlon, glass or odor KeraiP.Ü: fas «rr> h ^ stehnn. 7. Protective cover according to one of claims 1 to C, characterized in that the fiber-reinforced De to η for the plittonf ^ ni ^ o i'l? Nent (1) is made from a moist Detonerisch which contains at least one synthetic resin . 8. Protective cover ave a "? Of claims 1 to 7, characterized in that the synthetic resin is a latex or synthetic resin emulsion
or that the synthetic ^ synthetic resin is polyester resin or oOOxvharz or polyurethane. 9. Protective cover according to einpm der. \ Nsprüche 1 to 8, characterized in that the dry fiber-reinforced Hetongenisch consists of a weight portion Zenent with 3 to 8 parts by weight of sand and a weight portion % Polypropylene fibers and / or O.5% to 5 % glass fibers, the percentages of the fibers being based on the weight of the total dry Leton mass. 10. Protective cover where portland cement and fiberglass are used to make the fiber reinforced concrete according to one of Claims L to 9, characterized in that the glass fibers are alkali-resistant Fibers are.