SE408974B - POWER CONDENSER AND METHOD OF ITS PRODUCTION - Google Patents

Description

Liquid intrusion is prevented. In order to facilitate the penetration of the liquid, it has been proposed to use metal foils and polymer films which are not smooth but are provided with indentations or designed with superficial irregularities. that channels for the liquid are formed within the wraps. In practice, however, reference has been made to inserting the aforementioned porous layers in the form of paper next to the polymer films. The paper layers then act as wicks for sucking the dielectric liquid into the inner parts of the wrapper so that the polymer films there become impregnated. The incorporation of the paper layers means that the drying process becomes very time consuming and takes several days at low pressure and at high temperature. The use of press pan or paper in the insulation around the wraps greatly contributes to making drying time-consuming. The incorporation of paper layers is of course also possible. a disadvantage for the reason that for a given voltage and capacitance it entails a substantial increase in the external dimensions of the capacitor.

According to the present invention, it has been found possible to provide a power capacitor, the windings of which are completely filled with dielectric liquid without the use of paper layers next to the polymer films and whose drying and impregnation of the windings with dielectric liquid can take place in short times and at low temperature. The result according to the invention is achieved by using a special combination of materials for polymer film, dielectric liquid and insulation (outer insulation) for insulating the windings against the capacitor container.

More particularly, the present invention relates to a power capacitor comprising a number of capacitor wraps, each of which consists of layers of metal foil and of layers of polymer film, and which are arranged in a capacitor container and insulated therefrom with an outer insulation and which are impregnated with a dielectric liquid, with which the capacitor container is filled, characterized in that the polymer film consists of a polyolefin film, that the dielectric liquid consists of benzyl neocaprate and that the outer insulation consists of a porous material built up of bonded polyolefin fibers.

Particularly preferred as the polymer film is polypropylene film and as polymer fibers in the porous. the material in the outer insulation polypropylene fibers or polyethylene fibers.

Examples of. other useful polyolefins in the polymer film are polyethylene, copolymer of ethylene and propylene and polymethylpentene and in

The porous material in the outer insulation is normally sheet-shaped and can be a so-called "non-woven fabric". It may be composed of polymeric fibers which are arbitrarily oriented in a plane in the same manner as cellulose fibers in a paper or oriented in certain directions in the plane. The fibers can be bonded to each other, for example by mechanical means by felting together, or by melting or with an adhesive such as a copolymer of butadiene and acrylonitrile or a copolymer of butadiene and styrene. The material in the outer insulation has continuous pores so that it easily lets gases and moisture through when evacuating the contents of the capacitor container and without difficulty allows the passage of the dielectric. the liquid when impregnating lindorrla. The porosity is at 10-60, preferably at 10-30, volume percent. In contrast to cellulose paper, the outer insulation of the present invention has very little tendency to retain water and can be easily freed from water. The advantageous result of the present invention depends in large part on the interaction between the benzyl neocaprate and the polyolefin material in the film and the outer insulation. The benzyl neocaprate effectively penetrates the wraps due partly to the low viscosity and partly to the fact that the polyolefin films do not swell until the liquid has penetrated the rnellzm films. After such an intrusion has taken place, swelling occurs but it no longer prevents the impregnation. No release of constituents from the film or the outer insulation that can adversely affect the liquid.

The above mentioned. favorable penetration of the beneyl neocaprate means that according to the present invention it is possible to use even smooth films of the polyolefin. For the same reason, it is also possible to select films of suitable thickness and thus films that can withstand high stresses. Since the benzyl neocaprate has good glare properties in combination with high strength, the use of this liquid means that it is possible to take advantage of the property of a certain dielectric that it can withstand a higher pile voltage to a certain thickness. The wraps suitably have a filling factor, which amounts to a maximum of 90% and preferably to 80-88% of the theoretically possible to ensure that the penetration of the liquid can be carried out without practical difficulties arising.

It is possible to incorporate additives, such as stabilizers, into the dielectric liquid. Useful stabilizers include epoxy compounds such as diglycidyl ether of bisphenol A, 1-epoxyethyl-β, 4-epoxycyclohexane, styrene oxide, 1,3-bis- (2J-epoxypropoxy) benzene and di-2-ethylheacyl-4,5-epoxy tetrahydrophthalate.

The amount of stabilizer can suitably amount to 0.01-1 percent of the weight of the liquid.

Drying of the capacitor lindorxza and the rest of the capacitor container. content such as impregnation with the benzyl neocaprate takes place preferably at room temperature but can also take place at a slightly lower or slightly higher temperature. However, the temperature should not exceed 70 ° C during drying. The temperature of the liquid and dielectric should not exceed 5006 at the time of impregnation. By being able to work at that. low temperature, any risk of polymer films sticking in the wraps is avoided. together and further any risk that the benzyl neocaprate will cause. a swelling of the polymer films, before the neocaprate has penetrated and impregnated the wraps completely. During the drying and impregnation, as previously mentioned, the outer insulation allows the passage of gases and of the dielectric liquid, respectively, without water being delivered to the liquid.

The invention will be explained in more detail by describing an exemplary embodiment with reference to the accompanying drawing, in which Fig. 1 shows a cellulose-free capacitor according to the present invention in a section perpendicular to the longitudinal direction of the coils config 2 a section of a metal foil and polymer film. bound contains several rounds of.

In the capacitor according to Fig. 1, the wraps are designated 10. Each turn in the wraps consists in accordance with Fig. 2 of two aluminum foils 11 and 12, respectively, and of four polypropylene films 13, 14, 15 and 16. Each aluminum foil has a thickness of 5-10 .mu.m and each polypropylene film a thickness of 10-20 .mu.m. From Fig. 2 it can be seen that the foil 11 is retracted from one edge 17 of the strip and the foil 12 from the other edge 18 of the strip. The finished capacitor wind thereby obtains free edges in a conventional manner. the ends to prevent overlap between the electrodes. Estimates between the electrodes. at the beginning and end of the strip, it is conveniently prevented by inserting separate polymer films or by cutting one of the foils slightly offset relative to the other. folien.

Between adjacent capacitor wraps, spacers 20 of two layers of a 25 .mu.m thick polypropylene film are arranged. Only two. such. spacers are shown in Fig. 1.

Half of the capacitor elements are interconnected in parallel to one group 21 and the remaining capacitor elements are connected in parallel to another group 22.

These two groups are connected in series with each other. They are insulated from each other with a spacer 23 of four. layer of a 25 .mu.m thick polypropylene film. Within each group, it's on. one side projecting the foil of each wrap via a fuse 24 connected to a busbar 25 and 26, respectively. Below each busbar a strip 27 and 28 of polypropylene film, respectively, is arranged. The busbar 25 is connected to the top 30 of the bushing 29 Correspondingly, the busbar 26 is connected to the top of another bushing (not shown) of the same type. On. the back of the wraps is the foil projecting on the back of each wrapper connected to one for the groups. common assembly rail not shown. The package of wraps is on all sides, that is. also on. the front shown and the back not shown, surrounded

Claims (4)

7712934-9 of an outer insulation 52 which insulates the package from the capacitor container 51. The outer insulation consists of ten layers of a 68 μm thick sheet-shaped, porous material of polypropylene fibers, where the fibers are held together without binder, (e.g. wibrii E 1488 from The Kendall cempany, usa). When drying the wraps and the other contents of the capacitor, the opening 55 is connected to a vacuum pump with a pressure at the pump of, for example, 8 Pa. The drying time can be. for example 12 hours. The capacitor can then be kept at room temperature. After the drying process is completed, benzyl neocaprate containing 0.5% by weight of stabilizer in the form of 1-epoxyethyl-5γ-epoxycyclohexaz is fed through the opening 55, for a period of 5 hours, while the dried condenser is still kept under said vacuum. The connection with the liquid supply is maintained for a further 15 hours. The capacitor is thus completely filled and its windings are completely impregnated with the benzyl neocaprate. When filling the benzyl xeocaprate, the capacitor as well as the neocaprate can advantageously be kept at room temperature. After closing: in the opening 55, the condenser is heat-treated for at least 8 hours at a temperature of 9000 to ensure that any gaseous substances present in the condenser are completely dissolved in the liquid. PATENTIQAV A power capacitor comprising a plurality of capacitor windings, each of which consists of layers of metal foil and of layers of polymer film, and which are arranged in a capacitor container and insulated therefrom with an outer insulation and which are impregnated with a dielectric liquid, with which capacitor container is filled, characterized in that the polymer film consists of a polyolefix film, that the dielectric liquid consists of benzyl neocaprate and that the outer insulation consists of a porous material built up of bonded polyolefix fibers. 2. A power capacitor according to claim 1, characterized in that the polyolefin film consists of polypropylene film and the polyolefin fibers of polypropylene or polyethylene fibers. 5. A method of manufacturing a power capacitor according to claim 1, characterized in that capacitor wraps are made by winding metal foil and polyolefin film, that the capacitor wraps are surrounded by an outer insulation consisting of a porous material of polyolefin fibers and placed in a condenser. 3. L gv12saA¿s torbe container, to condenserlindonxa. dried during evacuation of the condenser container at a temperature not exceeding 70 ° C, preferably at room temperature, and that the condenser coils. is impregnated with and the condenser container is filled with benzyl neocaprate at a temperature of the polymer film and the benzyl neocaprate of at most 50%, preferably at room temperature. 4. A method according to claim 3, characterized in that the condenser after the filling of the benzyl neocaprate and closure of the condenser is subjected to a heat treatment to ensure that all any gaseous substances present are completely dissolved in the benzyl neocaprate. MENTIONED PUBLICATIONS: