SE464898B - CONDENSOR BODY CONTAINS FAULT CONTROL OF A TRANSFORMER TRANSMISSION CONNECTOR TO A TRANSFORMER WIRING CONNECTOR WITH CIRCUIT TRANSFORMERS - Google Patents

Description

464 898 and J; Journal 1981, Volume 73, Booklet 2, pages 27-32. Consistent and typical of the design of the capacitor bodies is that they has a central circular-cylindrical part. This part is transferred from both ends in outwardly straight truncated cones whose cross-sectional areas have a decreasing radius.

A variant of the design of a capacitor body is shown in GB 1,025,686, "Pothead for connecting oil-filled cables to transformers and other electrical apparatus ".

As above, the capacitor body has one against the transformer final conical part. Towards the cable connection ends, however the capacitor body with a cross-sectional area equal to the cross-sectional area of the circular-cylindrical part.

Another variant of the design of a capacitor body reported in an MlCAFlL publication MNJ 11/12 from June 1969 where a so-called "Re-Entrant Type Bushing" is described.

This bushing is also for use within AC area. Electrically, it is built in the same way as a conventional AC bushing with a capacitor body made of oil-impregnated paper, bakelite paper or is cast resin impregnated and with concentric coatings of a leading material. The principle of manufacture is that of the body first, the cone is wound outwards to a diameter where about 70% of the tension lies, then the body is coiled back to the final outer diameter by 0% of the voltage.

The advantage of such an embodiment is that one obtains one shorter penetration on the oil side. In addition, can the fender is excluded.

Power transformers used in converters facilities have special insulation technical problems such as on some way must be mastered to ensure satisfactory function. In high-voltage direct current HVDC systems are often used at least one converter per pole and station. Often is also several bridges connected in series. One of the poles of a bridge f \ 3 464 898 usually connected to ground, the other pole is connected to the next bridge so that series cup '* i is obtained. Thereby increases respectively bridged DC PC. .sitial relative soil depending on how many bridges that are connected in series.

Each bridge in the series connection is supplied with alternating voltage from each transformer. With increasing DC potential on the bridges relative to soil, the insulation also comes on bushings and windings on the transformers that are connected to the bridges to be exposed to an ever higher DC potential with superimposed AC voltage. The insulation of these must therefore be dimensioned so that they can withstand the ever-increasing insulation stresses such as it is thereby exposed to.

The increasing DC potential leads to special problems not present in transformers such as was used for pure AC transformation.

For inverter transformers, the sub-insulator and the transition between the transformer winding conductor and implementation problem areas from insulation technology point of view. This is described, among other things, in "Power transmission by direct current "by E Uhlman, Springer Verlag 1975, page 327- 328.

The electric DC field has a different distribution than the AC voltage field. The distribution of the direct voltage is determined mainly by the resistivity of the various insulation media.

Admittedly, both are transformer oil, cellulosic material and porcelain good insulators, but some small electrical current 'is conducted in these materials. The ratio between the resistivity of cellulosic materials and transformer oil is about 100. This means that the cellulose in series with oil exposed to significantly higher fields than oil, which in turn therefore sets requirements for a sufficient amount insulation material so as not to exceed the electrical the strength. The field distribution and also field directions will be 464 898 4 thus different than in the case of alternating voltage.

Electricity transport also means a redistribution of charges in input isolation media.

Due to the strong dependence of resistivity on moisture content, field strength, temperature, etc., the DC voltage distribution is difficult to predict. In addition, the DC voltage provides the physical nature, ie charge transport, charging, time-dependent processes etc., a very complex and difficult-to-interpret picture of them isolation problems that arise in HVDC contexts. l "Space charge and field distribution in transformers under DC- stress "by U Gäfvert and E Spicar, CIGRE Int. Conference on Large High Voltage Electric Systems, 1986 Session, 12-04, the complexity of the DC voltage distribution is illustrated. As previously mentioned, problems have arisen at the connection between the transformer bushing and the transformer winding trainer. This has meant that the electrical porcelain insulator must be removed to cope the stresses in the HVDC terminal at the higher voltage levels.

There is no simple explanation for this phenomenon emerged. But one has reason to suspect that the long surfaces that occur in connection with penetrations too high stresses in combination with the direction of the field along the long ones the surfaces are important in the context. Admittedly is also the alternating voltage field directed along the surface of the sub-porcelain, but its physical nature is different. One hypothesis is that the distribution of the DC voltage field risks becoming unstable and unevenly distributed along sufficiently long surfaces. Another interesting hypothesis is described in an article "Effect of duct configuration on oil activity at liquid / solid dielectric interfaces "by R E James, F E Trick, R Willoughby in Journal of Electrostatics, 12, 1982, pages 441-447. In this article it is claimed that increased charge transport at surfaces caused by turbulence and access to charge are the cause of low electrical strength. 5 5: 64- 898 A way to master these problems is presented in Swedish patent application 89022180 "Control body for field control at transformer bushings ". The transformer bushing in this case comprises a sub-insulator. To achieve it desired field control a control body with internal was used cones that with a certain oil spait joins partly to the outer conical part of the sub-insulator and partly to the conical part shaped insulation enclosing the transformer trainer.

Disclosure of the invention, advantages The invention comprises, as mentioned, a capacitor body for field control at transformer bushings for transformers used in converter systems.

The function of the capacitor body is to master the projections which have been shown to occur in transformer implementations. It is then designed so that it should act as a barrier with both capacitive and resistive control of the electric field and dimensioned so that the steering body can withstand current stresses and fields in the penetration and especially in the sensitive area at the connection between transformer conductor and bushing.

It is assumed that it from the transformer winding future trainer to be connected 'to the current conductor is surrounded by a conductive tube which has a surface-wound wound electrical insulation. This insulation is designed from the end of the conductive pipe as one straight truncated cone with cross-sectional areas with increasing radius as then changes to a circular-cylindrical part towards the transformer. The lead-through current conductor also exists often by a conductive tube.

The part of the capacitor body that is on the air side of the transformer bushing is designed as one conventional capacitor body. This means that it from the fixed flange of the transformer bushing has one 464 898 é circular-cylindrical part which merges into a straight truncated part outward con. Also other embodiments of this part occurs. n) The part of the capacitor body which the invention comprises, ie on the oil side of the transformer bushing, as a rule from the mounting flange of the bushing, starting with a circular-cylindrical part and terminates with an inward straight line truncated cone. The axial length of the circular-cylindrical the part located on the oil side of the bushing is in large adapted so that its end coincides with the transition from conical to circular-cylindrical part of the isolator's isolation. The inward cone from there conicity largely coincides, however, see below, with the conicity of the conductor's insulation with room for one intermediate oil gap.

Such a construction of a capacitor body means that a conventional capacitor body is integrated with a steering body. The electric field is controlled in the desired way while obtaining a shielding of transformer trainer. This is how it works the capacitor body according to the invention as a control body both for DC and AC fields.

The capacitor body according to the invention is otherwise constructed as a conventional capacitor body, i.e. it consists of wrapped insulating material with concentrically inlaid therein foil type capacitor coating. Internal capacitor body radius corresponds to the continuous throughput of the transformer bushing current-carrying tube outer radius.

The capacitor body is manufactured as mentioned by one insulating medium interspersed with conductive evidence to obtain it desired capacitive control of the electric gear field.

The innermost and with the current conductor concentric the capacitor coating has an axial length of approximately corresponds to the internal axial length of the capacitor body. -Outside 7 464 sas these are located concentric coatings interspersed in radial direction and stepped in axial direction. The phasing out is made so that the evidence in step with increasing radius of the capacitor body from the first coating is inserted axial direction so that their outer edges connect to the straight-out truncated cone of the capacitor body on it one side, the air side, and a steadily decreasing tapering from the first coating counted against the mounting flange of the bushing the other side. In addition, there is short evidence that is added as such that in step with increasing radius of the capacitor body from the first innermost bearing is laid in the axial direction so that their outer edges connect to those of the capacitor body incoming straight mutilated wife. These short ones are coated axially length is adjusted so that their area is constant, ie that it axial length decreases with increasing radius of the capacitor body.

To obtain the desired field control, it is connected innermost occupancy to the centrally set to high voltage the conductive tube and the outermost coating at the mounting flange connected to ground.

The DC field is controlled as mentioned earlier by several factors. This is, for example, the medium with the lowest resistivity field controller. Between the insulator body and the surrounding inwardly straight truncated cone of the capacitor body formed as mentioned an oil gap. Because the oil has the lowest resistivity is mostly conducted current in the oil gap which thus controls field parallel to surrounding surfaces. To get an even a distribution of the field along these surfaces, it is therefore important that the width of the oil gap increases with decreasing radius. in another case the field would be concentrated towards the part where the radius is smallest, ie where you have at least axial cross-sectional area. The conicity of the inwardly truncated cone of the capacitor body and the conicity of the conical part of the insulator body is therefore chosen preferably so that the radial cross-sectional area of the oil gap becomes about the same along the conical part of the bodies. 464 898 f: Another field controlling part is the radial distribution of the field in it part of the capacitor body that does not contain evidence, ie around about the innermost voltage set at high voltage. Between the oil gap against the insulation on the conductor and this area in the case of direct current, the evidence acts as potential lines, which prevents the field from being concentrated on any part of said oil channel. With a properly designed oil channel, the above factors interact to a smooth distribution of the field in the oil channel, whereby the field is controlled over to desired method of insulation on the conductor.

It is highly desirable that the oil systems in the transformer and in the bushing consist of separate system. To achieve this, there are two different ones main faults of the capacitor body. These should be closer described under description of embodiments, why here only a brief statement of principle shall be given. One the alternative is that the capacitor body is designed as a tight unit, for example, molded in and impregnated with some suitable casting compound. The second option means that the capacitor body is enclosed in a tight housing. Thereby formed two oil gaps at the transition between the conductor's insulation.and the capacitor body.

An advantage of the capacitor body with the integrated the guide body according to the invention relative to that in SE 89022180 describe the concept of separate steering body years that the external the dimensions of the system can be made smaller. In addition achieved that the boundary surfaces that have tangential field stress decreases in scope.

List of figures Figures 1 and 2 show two alternative embodiments of one capacitor body according to the invention. To in the best way show the invention are the proportions between 7 464 ses capacitor body diameter and axial length not scalable. The same applies to the conicity of the wives.

Description of embodiments One main embodiment where the capacitor body is designed as a tightly molded unit is shown in Figure 1.

The capacitor body 1 is, as has been mentioned, constructed as a rotating body consisting of wound insulating material with concentrically inserted capacitor coatings of foil type. To i to some extent show the capacitor body in its proper context also shown in figure 1 is the central live part 2, i in the form of a tube, of a transformer bushing around which the capacitor body 1 is centered, as well as that of the transformer conductor consisting of an internal live tube 3 and wound insulating material 4 thereon which has one towards the pipe end conical stepping 5. which then turns into a circular cylindrical part 6.

A transformer breakdown where a capacitor body according to the invention shall include, as usual, one towards the air side acting over-insulating of electrical porcelain. On the oil side has transformer bushings are usually also a sub-insulator of eg electric porcelain. In an embodiment according to the invention there are however, no such insulator of the conventional type.

The capacitor body in the first alternative is impregnated with a suitable casting compound, for example epoxy.

The capacitor body is then wound by, for example, one insulation paper that is impregnable by the current the casting mass. ' The condenser body is designed on the air side as one according to prior art described capacitor body, i.e. with a circular-cylindrical part 7 which merges into an outward straight line truncated cone 8 On the oil side, the condenser body continues with a circular-cylindrical part 9 of the same outer diameter 464 898 10 as the circular-cylindrical part on the air side. The axial the length of the outer contour of the circular-cylindrical part is adapted so that its end coincides with that of the insulation transition from conical to circular-cylindrical part on the trainer. From the end of the capacitor body one starts inwardly straight truncated cone 10 with a conicity which deviates slightly from the previously described method the trainer's conicity. There will then be formed one oil gap between the capacitor body and the conductor's conical part 5. It is important for the DC voltage distribution that the oil gap between the inward line of the capacitor body truncated cone and the conical part of the trainer have largely the same radial cross-section along the outer contour of the entire cone.

The radius difference is therefore greatest at the smallest of the cones basytor.

The first and innermost capacitor coating 11 is electrical connected to the current conducting tube 2 which indicated at the connection point 12. This first evidence has an axial length corresponding to the interior of the capacitor body axial length. It is surrounded by concentric evidence 13 which is rotated in radial direction and tapered relative to the first the bearing in the axial direction. The phasing out takes place by the pads in step with increasing radius are laid in the axial direction so that the outer edges on one side connect to the air side conical contour and with an evenly decreasing step towards the mounting flange of the transformer bushing on the other side.

The outermost of these evidence is connected to earth potential.

The capacitor body is further provided with concentric short pads 14 connecting to the inward straight line the contour of the mutilated woman. The axial length of these short bearings is adapted so that they have a virtually constant area regardless of the radius of their position.

A design of a capacitor body according to the foregoing mentioned second option is shown in Figure 2.

The field-controlling parts of the capacitor body, ie the wound one

Claims (6)

454 shows the insulating material and the coatings are structurally arranged in the same way as in Figure 1. However, in this embodiment the insulating part consists, for example, of oil-impregnated insulating paper. In this alternative, the entire capacitor body is surrounded by oil enclosed in a tight housing 15. In this case, two oil gaps will be formed between the inward cone of the capacitor body and the conical part of the conductor, ie inside and outside the tight housing, respectively. Both of these gaps must now be dimensioned in the same way as the oil gap in Figure 1. The requirements that need to be placed on the material in this casing are that it must have sufficient formability and that its resistivity must be greater than or at least as great as the oil's resistivity. Patent claims A capacitor body (1) for field control of the connection of a transformer bushing to the transformer of a transformer winding - at converter transformers, which capacitor body is arranged as a rotating body with an inner circular-cylindrical opening whose radius corresponds to the first and later conductive has a circular-cylindrical outer part (7) which terminates with a straight outwardly truncated conical part (8), which capacitor body consists of insulating material with concentrically inserted capacitor coating of foil type, characterized in that the capacitor body on the oil side of the bushing has a circular cylinder inner opening and an outer circular-cylindrical part '(9) which is arranged from the end with an inwardly straight truncated cone (10) towards the inner opening. A capacitor body for field control according to claim 1 and wherein around the transformer winding conductor is arranged a 464 898 / g energized pipe (3) with a surrounding insulation (4) with a circular-cylindrical part (6) and with a straight conical taper (5) counter-pipe end , characterized in that the outer axial length of the capacitor body on the oil side is arranged so that its end coincides with the transition between the circular-cylindrical (6) and conical (5) part of the insulation around the energized pipes of the conductor. A capacitor body for field control according to claim 1 and wherein around the conductor of the transformer winding is arranged a live pipe (3) with a surrounding insulation (4) with a circular-cylindrical part (6) and with a straight conical step (5) towards the end of the pipe, k ä Due to the fact that the conicity of the inwardly truncated cone (10) of the condenser body is arranged so that the radial cross-sectional area of the gap formed between it and the conical part of the insulation around the conductor's energized tube is constant along the entire length of the inward cone. A field control capacitor body according to claim 1, which transformer bushing is provided with a mounting flange, characterized in that a first inner capacitor coating (11) has an axial length corresponding to the axial length of the inner circular-cylindrical opening, that concentric capacitors are arranged outside it. 13) rotated in the radial direction and tapered in the axial direction in such a way that the capacitor linings in -tact with increasing radius of the capacitor body from the first coating are laid in the axial direction so that their outer edges' connect to the straight outwardly truncated cone (8) one side and a steadily decreasing step-down from the first coating counted against the mounting flange of the transformer bushing on the other side, and that the capacitor body is also provided with short capacitor coatings arranged so that they increase in step with increasing radius of the capacitor body from the first coating / 3 464 89 axial direction so that des s outer edges connect to the inwardly frustoconical cone (10) of the capacitor body and that their axial length is arranged so that their area is constant. Field control capacitor body according to claims 1 and 2, characterized in that the first inner capacitor coating (11) is electrically connected to the high-voltage conducting tube (2) of the transformer bushing and that the outer capacitor coating at the transformer bushing of the transformer bushing is connected to the ground flange. A capacitor body for field control according to claim 1, characterized in that the capacitor body is arranged enclosed in a tight housing (15) or itself constitutes a tight body (1).