DE908153C - Insulator for antenna guy ropes - Google Patents

Description

Antenna guy rope isolator Addition to patent 855 734 The invention relates to an insulator for antenna guy ropes according to patent 855 734.

In the patent 855,734 a guy insulator is described which is particularly favorable properties in electrical (high flashover voltage) and mechanical (high tensile stress) united with each other. Depending on the high electrical or high mechanical load capacity or both is required at the same time special embodiments of the subject matter of the invention. The longer the operating wave of the station, the higher the self-oscillating antenna tower generally becomes and so the higher the tension in the guys, which through the area of the tower exposed to wind is given. On the other hand, the electrical voltage increases with the size of the transmission power.

The size of the mechanical Pardun train determines the contact area and thus primarily the size of the insulator while the electrical voltage determines the required breakdown voltage of the guy insulator chain. This flashover voltage depends on the breakdown voltage of the individual insulator as well as on the number of series-connected isolators. Their number is also determined by the subdivision of the guy rope, what to avoid the electric Swinging of the rope is required.

The high mechanical stress now makes it necessary that the isolator is sanded for the purpose of even pressure transfer on the support surfaces. According to the invention the boundary lines of the isolator are two sore at right angles penetrating Cylinders that delimit the bearing surfaces and those in Fig. I a and i b in the two Side cracks are shown. As a result, at a given mechanical Load area achieves the highest rollover strength in that the profile of the insulator just fits into this cladding cylinder. Fig.i a and i b show an embodiment. Due to the mechanical load, for a given diameter a .of the isolator the projection of the bearing surface b. a given; the support surface is therefore proportional to the width. The larger the ratio b, the smaller is the a electrical breakdown voltage of the insulator. The width b of the support surface has a minimum value from mechanical security, which is given by the fact that eats the isolator must not tip out of the hanger.

Fig.2 shows the embodiment of a webbing insulator for wire ropes existing belt straps, which may be flattened on the support surface with a Sleeve are held together.

With high mechanical loads and low electrical loads Shapes such as that shown in FIG. 3, an embodiment example, are advantageous. here the contact surface is wide, while the rollover distance is relatively short. Ever the higher the mechanical load, the wider the insulator inevitably becomes, the more greater its ceramic mass and weight. The increase in weight is in mechanically undesirable, as it unnecessarily increases the lady's pull. The growth the mass of a body is also, for technical reasons, when it is manufactured limited. The following Figs. 4, 5 and 6 show embodiments according to the invention of bodies with saved ceramic masses. Fig. 4 shows a flattened one at the bottom Shape. In Fig. 5, the ceramic saved has been replaced by a metal prosthesis, and in Fig. 6 there are two semicircular bodies that are each burned for themselves can, placed crosswise on top of each other and possibly against tilting by one : inside ceramic prison pin .secured. - Another metal saving can also be achieved according to the invention in that the ceramic body is inside is made hollow, for example by having a cylindrical bore in its axis receives. According to the invention, this cavity, which may be at the ends again can be closed to accommodate apparent resistances (capacitance, inductance, Oil resistance) or measuring devices can be used.

In the forms described up to now, the pressure transfer from the parallel Pardune belts to the insulators takes place on a semicircular cylinder surface. As a result, in addition to the compressive stress in the ceramic, there is also a certain bending stress in certain zones. This limits the mechanical load capacity of the isolator. According to a further invention, the bending stress in the body is reduced in that the parts of the belt strap extending from the insulator on both sides are no longer parallel, but at a certain angle to one another. Figs. 7 and 8 show examples of this. As shown in Fig. 7, the straps are pressed against each other by the cross member T. This ensures that the cross section of the isolator is given a smaller than semicircular segment and the bending stress in it is reduced as a result. At the same time, the flashover voltage is increased. To shorten the length of the hanger, instead of the pressure rods T, which shorten the rollover path, you can choose an annular construction R as shown in Fig. 8, so that the two straps a and b can come closer together again.

Figs. G a and g b show an isolator according to the invention, in which the creepage path or the path of the sliding discharge along the insulator surface is increased is. This is done in the illustrated embodiment by means of a corrugation or corrugation of the insulator surface or by ribs on the insulator surface are put on.

Claims (5)

PATENT CLAIMS: i. Guy insulators according to patent 855 734, thereby characterized, that the outline of the insulator body by two see vertically penetrating: Cylinder is formed, which limit the contact surface of the guards rope. 2. Insulator according to Claim i, characterized in that electrical components are dispensable Ceramic parts are replaced by metal prostheses. 3. isolator according to claim i, characterized in that d: ate the support of the Pardunensz @ ils designed as a strap has a sector smaller than 18 ° on the insulator body. 4. Insulator after Claim i, characterized in that it consists of two semicircular or circular Plates, the axes of which are perpendicular to each other, is composed. 5. Guy insulator according to claims i to 3, characterized in that the creepage path is along the insulator is enlarged by corrugation.