SE511358C2 - Gas or water cooled transformer or reactor wound with high voltage cable - Google Patents

Abstract

Gas or water cooled reactor/transformer, and its method of manufacture, in which at least one winding of high voltage electrical cable, which has an insulating covering of solid insulating material (114) between semiconducting layers (113,115) surrounding a live conductor (112), has at least one additional member (9,11,12,13,14) wound with the cable in the spaces between the turns of the cable.

Description

* 511 ass 10 15 20 25 30 35 to cool the cable windings. It is important to have a short transport path for the heat to the cooling medium and that it is transferred efficiently to the cooling medium. This makes it important that all windings are in direct contact with a sufficient amount of cooling medium of a suitable temperature.

OBJECT OF THE INVENTION: The object of the invention is to provide a transformer of the kind initially indicated, which enables water cooling of a cable-wound power transformer. The invention aims to cool each winding revolution in the windings where the cooling medium is correctly distributed to meet the different cooling needs of the windings.

Furthermore, the invention aims to eliminate previous use of oil cooling in power transformers and thereby achieve internal cooling which means lower weight and higher filling factor which in turn means lower costs.

SUMMARY OF THE INVENTION: The present invention relates to a transformer comprising a cable-wound transformer core, arranged so that the winding is provided with a cooling channel between each winding revolution. The cooling duct is further arranged to transport cooling water to cool all winding turns in the transformer.

The cooling pipes according to the invention consist of electrically insulating material, e.g. crosslinked polyethylene in the form of circular so-called PEX pipes which are alternated with the cables so that the heat is transferred from the cables to the cooling pipes, mainly by heat conduction. By using polymeric pipe materials, problems with induced stresses and eddy currents in the pipes are avoided. In addition, polymer tubes are significantly more flexible than metal tubes. Furthermore, polymeric pipes do not have to have a circular shape but can have a square section or have a shape which means that they occupy the entire space between the four adjacent cables. In order to be able to lead in and out of the cooling pipe / cooling hose in each cable layer, each cable layer is wound and connected in series afterwards. Furthermore, cables and cooling pipes are filled with a thermally separate and spliced space between conductive mass.

In an invention of the present type, the transformer core can be cooled with air from a fan provided in a cooling duct and / or with water circulating cooling blocks.

BRIEF DESCRIPTION OF THE DRAWINGS: The invention will now be described in more detail with reference numerals in connection with the accompanying drawing figures.

Figure 1 shows, partly in section, schematically a three-phase power transformer according to the present invention.

Figure 2 schematically shows a section through an iron core coil comprising four embodiments 2a, 2b, 2c, 2d according to the present invention.

DESCRIPTION OF THE INVENTION: Figure 1 shows a power transformer 1 provided with three winding coils 2,3,4 each comprising a low voltage winding 6 and a high voltage winding 5. The winding coils 2,3,4 are wound around each leg 22,23 , 24 on connected on each side of the coils with one in the iron core Thus, the legs 22,23,24 and the yoke 7,8 form the total iron core of the transformer 1. an iron core whose legs are constituent upper and lower yoke 7.8.

Figure 2 shows a cross-sectional view of a part of a power transformer which is wound with high voltage cables III to be used as a transformer winding according to the present invention. The high voltage cable 111 comprises a number of strands 112 with a circular cross section of, for example, copper (Cu). These strands 112 are arranged in the middle of the high voltage cable III. A first semiconducting layer 113 is arranged around the strands Ü511 358 112 and an insulating layer 114 is arranged around the first semiconducting layer 113, e.g. PEX insulation. There is a conductive layer 115 around the insulating layer 114. The term high-voltage device arranged in a second ha may thus not include the outer cable and metal shield in the present application which normally surround such a cable during power distribution. The high voltage cable 111 is wound around a leg 24 which is connected to the other legs of the transformer by a yoke 7. When winding the high voltage cable, straight cable placement, as T: shown in the embodiment according to Figure 2, a gap 8 is formed by the four adjacent cables - between the cables, which limits its second semiconducting layer a mantle surface, ie. tt with cooling channels for coolant in which channels may be formed on the cylindrical 115 of the 111 111. The gap 8 is to supply liquid phase, preferably water, one of the four ways shown in the figure. The transformer, designated 2a, is 9 of crosslinked polyethylene (so-called which acts as a The first embodiment a the cooling pipe 9 and the cylindrical jacket surface of each cable 111. The second embodiment of the transformer, designated 2b, is d with square cooling tubes 11 via X-tubes) which are surrounded by a spacer 10, which acts as a conductive mass. The spacer 10 completely fills the space 8 between the cooling pipe 11 and the respective cable 111. The square shape of the cooling pipe 11 enables the degree of ductility of the space 8 for cooling purposes. -rf are also made of cross-linked polyethylene (so-called PE n termis 30 a greater use "d The third embodiment of the transformer, designated 2c, is ed concave square cooling pipes 1 a the cables. This form means that 9" _ 35 provided m 2 whose sides have the same shape as the cylindrical * S the remaining space between the cooling pipe 12 and the cable is further minimized in relation to the embodiment according to the second embodiment. The cooling tubes 12 are also in this embodiment made of cross-linked polyethylene (so-called PEX pipes) which also in this embodiment are surrounded by a spacer 10, which acts as a thermally conductive mass, which completely fills the space 8 between the cooling pipe 12 and the respective cable 111.

In all the three embodiments described above, cooling medium in the form of cooling water flows inside the respective cooling pipes 9,11,12.

The fourth embodiment of the transformer, designated 2d, is provided with cylindrical PEX pipes 13 as cooling pipes which run in pairs inside a square insulating pipe 14 of crosslinked polyethylene (so-called PEX pipes) 14 of spacer 10 which insulating pipe wherein the PEX pipes 13 are surrounded inside the insulating pipe 14 is also surrounded by spacer 10, which completely fills the space 8 between the cooling pipe 9 and the respective cable 111. The spacer 10 acts both inside and outside the insulation pipe 14 as a thermally conductive mass.

The thermally conductive mass in the form of spacers in all the described embodiments consists of one or two-component hardening silicone rubber filled with thermally conductive fillers such as alumina. In the uncured state, the material is given such rheological properties that it is liquid at high shear rates (pumpable) and pasty at rest. another turn of cable is wound and so on. The winding drum rotates during winding but can also stand still without the spacer 10 floating away. 1511 358 9,11,12 alternatively the insulating pipe 14. In the cured state (similar to the model) it has such a consistency in the mass that the remaining space winding is formed to fill between the cables. Common to all embodiments is that the cooling pipes are always insulated against the cables because in the pipes s conductive and are at ground potential. flowing water as cooling medium, the core is provided with a yoke 7 and the only cooling channel gur 2 is in addition jä 10 According to fi provided with a longitudinal leg a leg 24, the yoke being. 11 .i | hllul 15. ket means that you have a for the windings will require a higher flow equal to cooling pipes. Usually the winding compared to those obtained The cooling demand is different from the 15 different fluid flows in o lies next to the low voltage winding. To be shaped with different diameters, and parallel combinations. in the pipes that are adjacent to high voltage correct flow distribution, the pipes u can alternatively be connected in different series such as polyethylene, polytetrafluoroethylene Polymeric cooling pipes can be made of many materials polypropylene, polybutene, as well as filled and reinforced elastomers. high density polyethylene HDPE as it ad density. Crosslinked polyethylene, silane crosslinking or polyvinylidene fluoride. Among these, thermal conductivity is preferred. Increases with the increase of a peroxide, the ability to withstand pressure at increased radiation crosslinking is increased for the ice for stress corrosion disappears by transverse temperature while falling. Casting in the pipes is necessary because the thermal resistance between the pipe and the cables will otherwise be too high. In order for the trout between the pipe and the winding to fill the space with This may consist of a polymer which has a low viscosity to be filled with a high content of edible filler before it is injected into the space where it is transferred to a non-liquid heat transfer a crosslinkable casting compound. and thus heat can withstand it by chemical reaction over compound. Examples of suitable compounds are acrylic, epoxy, unsaturated polyester, polyurethane and silicone, the latter being preferred due to its non-toxicity. Thermally conductive fillers can e.g. be oxides of aluminum, magnesium, nitrides of boron or aluminum, silicon carbide. A mixture of e.g. alumina and silicone, ie. polydimethylsiloxane with vinyl groups which in the presence of a platinum catalyst reacts iron or zinc, with hydrogen polydimethylsiloxane, is pressed with overpressure into the cavity between the PEX tube and winding, after which curing takes place by adding the hydrogen atoms to the vinyl groups.

The invention is not limited to the examples shown, but a number of modifications are conceivable within the scope of the invention.

The cable placement thus does not have to be straight but can be diagonal, whereby the space between the adjacent windings has a different appearance, whereby the cooling pipes are adapted to this shape of space.

Claims (15)

f. | ..> innåi fi ._... ï.nd | xm | .l..l-mmi uiínliil »min ... m mlnnmn mmm." (nu. illiful 'f ä fi ml: mä 511358 10 15 20 25 30 35 SE 9700339-6 8 PATENT REQUIREMENTS Water-cooled power transformer (1) comprising a transformer core (22, 23, 24) wound with, preferably cylindrical, conductor, characterized in that the conductor is designed as a high-voltage cable (111) comprising a number of strands (112) in the middle of the high-voltage cable (111) and that a first semiconducting layer (113) is arranged around the strands, an insulating layer (114) being arranged around the first semiconducting layer and that a second semiconducting layer (115) is arranged around the insulating layer (114), wherein at least one cooling pipe (9, 11, 12, 14) is placed in a space (8) formed by the winding process between each cable (111), the space (8) remaining between the cooling pipes (9, 11, 12, 14) and the cables being filled with a thermally conductive mass (10). Transformer according to Claim 1, characterized in that a cooling pipe (9) with a circular cross-section is placed in the space (8). Transformer according to Claim 1, characterized in that a cooling pipe (11) with a square cross-section is placed in the space (8). Transformer according to Claim 1, characterized in that a square cooling pipe (12) with concave sides is placed in the space (8). Transformer according to Claim 1, characterized in that the cooling pipe (13) is enclosed by an insulating pipe (14) filled with filler (10). Transformer according to one of Claims 1 to 5, characterized in that the thermally conductive mass (10) is low-viscosity at high shear rates and pasty at rest. 10 15 20 25 30 35 511 358 SE 9700339-6 9 Transformer according to Claim 6, characterized in that the thermally conductive mass (10) consists of a one- or two-component hardening silicone rubber provided with a heat-conducting filler. Transformer according to one of the preceding claims, characterized in that the filler consists of either alumina, boron nitride or silicon carbide. Transformer according to one of the preceding claims, characterized in that the cooling tube (13) is made of dielectric material such as polyethylene, polypropylene, polybutene, polyvinylidene fluoride, polytetrafluoroethylene or filled and reinforced elastomers. Any one of the preceding claims, characterized in that the transformer Transformer according to is designed as a power transformer whose winding consists of a high-voltage cable (111). The high voltage cable (III) Transformer according to claim 10, characterized in that it has a diameter in the range 20 - 200 mm and a line area in the range 80 - 3000 mm Transformer according to one of the preceding claims, characterized in that the cooling pipe (13) is made of high-density polyethylene (HDPE). Transformer according to one of the preceding claims, characterized in that the cooling pipe (13) is made of cross-linked polyethylene (PEX). A method of manufacturing a water-cooled transformer, of the type indicated according to any one of claims 1-13, characterized in that, a) a first layer with the cable is wound, (10) the winding turns formed the grooves, b) a thermally conductive mass is sprayed in the between 511 358 SE 9700339-6 10 c) a cooling pipe (9, 11, 12) or an insulating pipe (14) is wound in the groove formed between the winding turns, d) additional thermally conductive mass (10) is sprayed on the cooling pipe (9, 11, 12) or the insulation pipe (14), É 5 e) a further layer of cable is wound,; wherein steps b) to e) are repeated until the entire coil is finished. Ä Process for producing a water-cooled transformer 10 of the type specified in any one of claims 1-13, characterized in that, a) a first layer of cable is wound, b) a cooling tube (9, 11, 12 ) alternatively an insulating tube (14) (H11: mmm (vw h »i) which is extruded or cast with a thermally conductive mass (10) is wound on the cable, c) the thermally conductive mass (10) is formed into abutment» -fi imww against the cables when a second layer of cable is wound one on one second turn, É whereby steps b) and c) are repeated until the whole coil is completed. H H .E * ä få lä ï fl: HH