DE1916767A1 - Electrical insulator with bell flanges - Google Patents

Description

DIPL-CHEM. DR. WERNER KOCH DIPL.-ING. KLAUS DELFS

HAMBURG

PATENT LAWYERS

DR.-ING. RICHARD GLAWE DIPL-PHYS. DR. WALTER MOLL

MONKS

2000 Hamburg 52 WaltiilraOo 12 Ruf 89 22 8000 MOnchen 22 ■ Llebherrjtra6e 20 · Ruf 22 6548

YOUR SIGN

REGARDS:

YOUR MESSAGE FROM OUR SIGN

A.

MONKS

TRANSMISSION DEVELOPMENTS LIMITED

125 Bristol Road, Gloucester, Gloucesterhire, England

Electrical insulator with bell flanges.

"The invention relates to high voltage electrical insulators with bell flanges (sheds) and especially: ©, however not exclusive, pole-type insulators for hanging outdoor power lines.

It is well known that the performance of an isolator for a high voltage power line under rigid conditions

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POSTAL CHECK,

909842/0338

HAMBURG 1476 07. BANK. COMMERZBANK A. G., HAMBURG, DEP.-KASSE 20/12029 · TELEGR.I SPECHTZIES HAMBURG, or SPECHTZIES MÖNCHEN

no atmospheric pollution a puncture of the Is the length of the creepage distance of the insulator. The longer the Creepage distance, the lower the risk of rollover. One way of a long creepage distance For a given overall length of the insulator, a large number of simple insulating bells can be used (plain sheds) of large diameter to be used. However, it is also known that when the air gap between the isolator bells is reduced, the risk of flashovers in the air between the isolator bells on its outer edge or between a drop of water an upper insulating bell and the one below Bell is enlarged.

The invention therefore aims to provide an isolator which, for a given axial length, has a very Great resistance to flashover of the operating voltage or circuit overvoltages as well exhibits wet air pollution under unfavorable conditions or in heavy rain, or that in the case of a given Flashover strength can be carried out with a particularly short axial length, without the bells of unreasonable large diameter must be used.

According to the invention is an electrical insulator with a number of axially arranged one behind the other

909842/0338

arranged insulating bells characterized in that adjacent bells have different diameters and that the total creepage distance between the ends of the insulating material is at least four times, preferably is at least eight times the axial length of the insulating material.

In such a construction, water droplets that collect on the periphery of a bell of larger diameter are not located immediately above the outer edge of the next bell below. Moreover, the width of the air gap between the ends of adjacent bells, which have different diameters, greater than the perpendicular distance of these two bells ^1. It has been found in practice that an insulator, the bells of which have alternately larger and smaller diameters, has a better performance than an insulator of the same length with bells of uniform diameter. However, as will be explained, more than two different diameters of the bells are preferably used.

Since the length of the creepage distance is the most important single parameter for the determination of the performance of a contaminated isolator, provided that

909842/0338 BATH ORIGINAL

the construction allows an effective use of the existing creep path (i.e. that the risk that larger parts of the creepage path is short-circuited by water droplets and / or air discharges between the bells, is as small as possible), it is according to the invention preferable to the ratio of the total length of the creepage path to the axial length of the insulating material of an isolator from. Rod type to give the high value of about Io.

According to a further preferred feature of the invention, an isolator of the type described the length (L) of the creepage distance between the lowest point of the edge of an insulating bell and that at perpendicular standing isolator axis immediately below the point of the next bell same or larger Diameter to the shortest distance (X) between these points of such a relationship that the maximum value of X / L for any two such points on the insulator or at least on a larger part the length of the isolator by no more than $ 50 from Minimum value deviates from X / L.

If two bell dimensions are used, then, as mentioned above, the larger bells and ground

BATH ORIGINAL 909842/0338

smaller diameter arranged alternately. If more than two sizes of globe are used, they are preferably arranged in a repeating pattern. This pattern is preferably designed in such a way that with N different bell sizes the pattern is repeated after each "* ■ £,! ^" Bells, the order in which the bells are arranged being determined in the following way.

Assume that there are bells of size zero, size 1, size 2 ... size (N-1) i, with the bell diameters increasing according to (but not necessarily proportionally) the size numbers. The position of the bells in a group is with; Position 1, Position 2 .... Position 2 ^ ¹ ~ ' denotes, where Position 1 denotes the lowest bell in each group. The size number of a bell in a respective position is then given? by the highest power of 2, by which the corresponding position can be divided without Rnst. For example, in the case of four different sizes of globes, size 0 is to be used for all uneven position figures, size number 1 for positions 2 and υ, size number 2 for position 4 and size number 3 for position 8

BATH ORIGINAL

909842/03 f8

Although N can be chosen to be 2, it should be provided that make it equal to 3 or larger, so that the pattern takes at least four bells repeated.

A complete isolator usually comprises a number of repeating patterns of Bells of the type described above. The topmost bell of the isolator is preferably the largest Size (i.e. the pattern is completely finished at the top), but the bottom bell needs does not necessarily complete the pattern in full.

For rod-type suspension insulators for outdoor power lines the bell diameter are preferably chosen so that drops from the edge of a any bell normally and regularly not fall on a smaller bell underneath, regardless of whether it is caused by electrical forces and / or be influenced or not by the wind or by a deflection of the insulator from the vertical. This is effectively accomplished by making the isolator so that. one the outer Line touching the edge of a larger bell at an angle of 150 ° to the axis of the isolator

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does not cut a smaller bell underneath, before cutting a bell of equal or greater diameter.

The shortest distance between the bottom of any bell and the top of any other The bell should not be smaller than 8 mm (with a vertical insulator).

Preferably there should be a line that is furthest away from the axis Point any bell with the center of the bell root, where it goes into the insulator shaft passes over, connects and lies in the same plane as the first-mentioned point and the isolator axis with which Isolator axis an angle between 5o and. Include 65 °. For each individual isolator, this angle for each bell will normally be essentially substantial be the same.

The bells are preferably thin-walled and conical in shape, the upper and lower surfaces of the bells each consisting of substantially one rectilinear generatrices intersecting the isolator axis by rotating these generators around the isolator axis can be thought of generated. Instead of a straight generating line, the bells can also have a

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909842/0338

broadly conical in shape, the upper and lower surfaces being produced by the rotation of gently curved generatrixes of such shape that the maximum deviation from the straight line is no greater than the average thickness of the bell. Either the top or bottom surface of a bell or both may be formed with steps or ridges provided that the maximum depth of each step or flute is no more than Ko% of the average thickness of the bell.

Each bell can have a substantially uniform thickness or a tapered cross-section with a tapering angle of up to 15.

The described, preferred conical shape of the Bells has the advantage that when the insulator is using a hydrocarbon or other lubricant must be greased, this lubricant can be easily applied by spraying and

away

fold scraping tool can be scratched.

The invention can be applied to a porcelain insulator with end caps. In this case, the Insulator bodies are formed in one piece with the bells as a one-piece porcelain element, with the Ends of the porcelain element in a known manner end

9Q9842 / 03S8

caps are put on. However, the invention can also be applied to rod-type insulators that are constructed in a different way, for example from a large number of assembled individual elements, such as cast synthetic resin insulators on a core made of synthetic resin bonded glass fibers. -With With this material it is possible to produce a high ratio between the bell overhang and the thickness, as required when more than two bell diameters are used.

Embodiments of the invention are set out below explained in more detail with reference to the drawings.

Fig. 1 shows in side view, partially in section, an embodiment of a rod-type isolator.

Fig. 2 shows, in side view, partly in section, another construction of the isolator.

, FIG. 3 shows a view similar to FIG slightly different design of the: isolator.

In Fig. 2, a rod type insulator is for hanging an extra-high voltage overhead line.

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The insulator has a body 1 made of porcelain, on which bells are formed in one piece, which alternate are of larger and smaller diameter. In the embodiment under consideration here, the insulator has fourteen bells 11 of larger diameter and thirteen bells 12 of smaller diameter. Each bell has a concave or conical bottom and a generally convex top surface, these surfaces smoothly transitioning into the body of the isolator pass over. The top and bottom of the bells are designed sloping radially outward, so that rainwater runs down the bells and forms drops, which are located at the lowest points of a Collect the bell, this point being on or near the very edge. The ends of the Isolators are fastened in metal end caps 13, 14 in a known manner.

Fig. 2 shows part of an insulator molded from synthetic resin. The isolator is more suitable V / is molded from synthetic resin and can be attached to a central core made from synthetic resin-bonded glass fibers be. The molding is preferably carried out by vacuum casting an epoxy resin. Because of the high Ratio of the bell overhang to the thickness, which is with Resin can be obtained can be more than two

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Bell diameter can be used. Pig. 2 shows such an isolator with three bell diameters. The advantage of such an arrangement over one An arrangement with two bell sizes is that, for a given overall diameter, the ratio the creepage distances to the widths of the air gaps can be increased, thereby increasing the efficiency the isolator is improved in the event of contamination.

2 shows two bells 2o, 21 with the largest diameter, one bell 22 with a medium diameter, and two bells 2j5, 24 with the smallest diameter. There are air gaps of size X between the bells 2o, 21, of size X ¹ between the bells 22 and 21, of size X "between the bells 2j> and 22 and of size X"'between the bells 24 and 21. The air gaps X, X ¹ , X "and X ^{111 are} assigned the creepage distances L _3, L ¹ , L" and L ¹ ", these creepage lengths being the shortest lengths (in a plane containing the insulator axis) along the surface of the bells are between the two ends of the respective air gaps. In Fig., the values of X ,, X ..... L ⁿ / L ^M lie between O and so on, and O75 & O, o935, the taper angle of the bell is 5 °, the The cone angle of the bells is 63 ⁰ and that

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BATH 909842/0338

Ratio of the creepage path length to the length of the insulating part of the insulator. Amounts to Io.

In the embodiment shown in FIG. 3, which is slightly modified compared to FIG. 2, the corresponding values O, loj? to 0, l> 5, 5 , 6j5 and 6.9 · In both figures the number of bell sizes is N = 3, so that the pattern is repeated after every four bells.

It can be seen that in all the embodiments shown, a considerable difference in the bell diameter is provided in order to prevent drops from falling from the edge of any bell onto a smaller bell underneath, regardless of whether the drops are caused by electrical forces and / or by wind or by a Deflection of the isolator can be influenced by the perpendicular. "More precisely, the differences in the ¹ diameter are chosen to be so large that a line which touches the outer end of a larger bell and runs at an angle of 30 ° to the isolator axis does not hit a smaller bell below it before it hits a Bell of the same or larger diameter hits.

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^ß AD OBIGSHAL 90984 2/0318

In all the embodiments shown, the shortest distance between the lowest part of any bell with a vertical insulator and the Surface of any other bell larger than 8 mm.

909842 / 03ta

Claims (1)

Claims "1Λ electrical insulator with a number of in Axially arranged bells one behind the other, characterized in that adjacent Bells have different diameters and that the entire creepage distance between the ends of the insulating material is at least four times the axial length of the insulating material. . . 2. Electrical insulator according to claim 1, characterized characterized in that the total length of the creepage path between the ends of the insulating material is at least eight times the axial length of the insulating material amounts to. 3 · Electrical insulator according to claim 1 or Qj- characterized in that the. Length (L) of the creepage distance between the lowest point of the edge of a bell and the point immediately below it of the next bell of the same or larger diameter with the vertical axis of the insulator to the shortest distance (X) between these points in such a region 909842/0318 Draw stands that the maximum value of X / L for any two points at least on most of the axial Length of the isolator by no more than $ 50 from the minimum value deviates from X / L. 4. Electrical insulator according to one of the claims 1 to 5, characterized in that the Bells are alternately larger and smaller in diameter. 5. Electrical insulator according to one of claims 1 to 3, characterized in that the bells N have different diameters and are arranged in a repeating pattern, where N is a is an integer that is 3 or greater than 3. 6. Electrical insulator according to claim 5, characterized in that the bells have the size numbers 0, 1, 2 ..... (NI), the diameter of the bells increasing in accordance with the size numbers that the bells in a repeating pattern with groups of 2 ^ ~ ' bells arranged that the positions of the bells each group as position 1, Position 2 Position 2 ^V " ~ ^J in numerical order are marked from the bottom bell upwards, - 15 -. BATH ORIGINAL 909842/0338 and that the size number of each bell is given by, the highest power of 2 by which the position number is divisible without a remainder. 7. Electrical insulator according to one of Claims 1 to 6, characterized in that the top bell is a bell of the largest diameter. 8 * Electrical insulator according to any one of claims 1 to 7j characterized in that the bells are arranged such that the outer _k rim of a larger bell-contacting smaller at an angle of 3o ° to the insulator axis downwardly extending line on any underlying bell, before it hits a bell of the same or larger diameter. 9 · Electrical insulator NaCN one of claims 1 to 8, characterized ge e ic η η ζ η calibration .et that derkür zeste distance between the lowest part of each bell ^ not less at-true insulator and the surface of any other bell than 8 mm is. Io. Electrical insulator according to one of Claims 1 to 9, characterized in that g'.eke -ri η ζ e ich ne t that - 16 - 909842/0338 BAD ORiGfNAL - - ^; ; ■.: ■ '. 1S1S767 a Ji $ nie _¥ the one point furthest from the axis of any-: 'bigeri: {& Qefe ^ rä ^ where it meets orsqhaft ^ iin $ sp3, verbindetund in the gle ^ ^ öheii radial pene as the first-mentioned point andt the: · Jsölatoraohse is, an angle between 30 and 65 ° Rait the insulator axis einsGhließli, 11. Elektrispher insulator according to claim Io, thereby g e ken ή 2 ei c h n. e t that this angle is essentially the same for each bell, 12. Electrical insulator according to one of claims 1 to 11 / characterized geke η η ζe ί without t, that the bells are of conical shape, their upper and lower sides are generated by rotation of a straight line, the insulator axis intersecting generators. IJ. Electrical insulator according to one of the claims 1 to 11, characterized in that the bells have a conical shape in a broader sense are with upper and lower surfaces created by rotation of gently curved generatrices of such that the maximum deviation from a straight line is no greater than the average Thickness of the bell is. - 17 - ^ßAD 909842/0350 14. Electrical insulator next to 1 to 5, thereby geke ηη 'ζ ei ^ the upper and / pdep Iftiteräeite of a bell stepped odei? grooved formed 'the maximum depth' de ^ ^: "step-: or as ho% of the average thickness «tei * ßlöaifca 15.. Electrical ¹ insulator nacix eiwem -1 to 15, ;; thereby, - g; e ^ k "e _r η η ζ e \ ί '-'. c la Ä -.- ^ f every bell is essentially identical Iliöke 16. Electrical insulator according to one of claims 1 to 15, characterized geke η η ζ e ie ine t that each bell has a tapering cross-section in a radial plane extending through the isolator axis. has, the taper angle not greater than 15 ° is. -18 - 909842/03 3 8