CS229792B1 - Laminated high voltage wind insulant - Google Patents

Description

The invention relates to a winding, strip of mica-type insulating material intended to insulate individual rectangular cross-section conductors used to form windings of high-voltage electrical, most rotating, machines. The purpose of the solution is to obtain a suitable insulator, which allows to improve the quality of the insulated conductors and windings, and in connection with this application of more demanding and more productive processing processes, which will significantly improve the production and maintenance of the respective electrical machines.

High-voltage windings of electrical machines are formed from rectangular conductors, the so-called profile conductors, whose coils may have a final shape before being inserted into the grooves. Insulation of these conductors can be accomplished in several ways. If a bare conductor is used with insulating inserts between adjacent winding surfaces, for example with polyamide-based inserts, operational safety due to the low electrical strength of such insulation between. the threads are small, for this solution is suitable only for small machines and low voltage. The advantage of the lacquered profile conductors is the low insulation gain, i. low insulation thickness. However, the production of a flawless insulating varnish film on rectangular cross-section wires is very clouded, for this reason, due to the degree and the possibility of errors, their use is largely limited to low voltages. Only in some varnished or unpainted conductors of this type, additional fencing, wrapping with cotton, polyster, glass, respectively. Another distance, or a combination thereof, also provides a certain distance after winding the conductors, which allows their use even for voltages above 1 kV. Conductors wrapped with insulating tapes, single-layer or multi-layer are suitable for demanding processing and operating requirements, and various combinations of insulating components are known, for example a wire with a strip of 2229 792 is also fiber-stripped, lacquered and the like.

The requirements for the properties of the insulated conductors, for the composition and construction of their insulation, are equally determined by the method of manufacture when applying them to the windings, in particular by the need and method of forming them, as well as the operating conditions in which the windings and conductors are to operate. The sphere of temperature range of insulated conductors is given by the temperature resistance of the insulating components used. By selecting these components, varnish, fibers, foils, insulated conductors of temperature classes E, B, P, H, C can be obtained as required. In addition to the material side, the voltage capability is mainly a function of the structural form of the insulating components used.

For operating voltages above 6 kV, the most suitable solution is isolation with studded tapes, as these limit the main electric pole. For insulating individual rectangular cross-sectional conductors such conducting tapes are formed of a mica layer which is bonded to the carrier material by means of an adhesive based on, for example, rubbers, thermoplastics, or epoxies or other resins. With the use of prior art tapes of this kind in the manufacture of insulated rectangular conductors for winding of electrical machines, there are however, to a large extent, serious drawbacks which are manifested here, inter alia, in particular in the chipping of the leaves, respectively. of mica particles, in the separation of the layers of carrier material and mica, in gluing the tape to the conductor surface already in the winding process, before the final coil shaping.

Cleavage of the mica results in a reduction in the electrical strength of the insulation. The cause of this drawback can be found in the unsatisfactory properties of the binder of the layers as an integrating insulating component. In view of its low penetration capability, the binder is not able to bind the mica into the compacted layer by winding the tape of the layered particle structure. The same results are also obtained when bituminous, for example epoxy binders of higher consistency are used. If, on the other hand, binders of lower consistency are used, these penetrate into the mica structure, which results in the absence of balanced and sufficient adhesive forces in the intermediate layer between the carrier and mica, which then leads to stratification of the tape. By increasing the binder content in the tape, it is possible to achieve the desired cohesiveness of the layers as well as compactness of the tear layer, but in the process of processing insulated conductors it occurs by multiplication.

- 3 229 792 elevated temperature to the outflow of a portion of the binder, which then causes the tape to adhere to the conductor, which has the negative consequence of further damaging the insulation of the individual conductors during the formation of the windings, the coils.

According to the invention, the disadvantages of the prior art are eliminated by a solution according to which the insulator is formed from a sheet of opaque paper which is adhesive-bonded to the support of a heat-resistant material by means of specific surfaces with a two-component adhesive-impregnating binder. This binder contains, in proportion to the total weight of the laminate insulator, in an amount of at most 20% by weight of an adhesive composition of the reactktoplas having a pour point of 35-600C and its tack to carriers is greater than the cohesive value of the interparticle applied. A further proportion of the two-component binder is an impregnating composition which is of a thermosetting or heat-resistant thermoplastic material of liquid or semi-solid consistency having a melt point of not more than 30 ° C and which material is integrated in the amount of 10 weight percent relative to the weight of the paper. A suitable embodiment is a solution wherein the insulator is formed from a sheet of carbon paper associated with the carrier by means of a two-component binder in which the proportions of the adhesive composition and the impregnating composition share are in 15:85 to 85:15 parts by weight ratios. Another alternative to the preferred embodiment of the solution is the case where the two-composite binder of the lined layers is a binder whose adhesive composition is a thermosetting epoxy resin based on glycidyl ethers with an epoxy equivalent of 200-600, and the impregnating binder is a low molecular weight polymer. polysiloxanes or epoxides.

The solution according to the invention provides a technically and economically effective high voltage sheet insulator of the type of foil or tape of a winding laminate suitable for insulating individual conductors of rectangular cross-section in the winding of high voltage electrical machines. The paper layer and the carrier material layer are joined by a two-component binder, the adhesive function of which ensures the necessary cohesiveness between the mica layer and the carrier, but the simultaneous action of the impregnant components results in the required compactness and integrity. layers of mica paper under the operating conditions of the insulator application.

The adhesive function in the binder can be provided by both a thermoplastic and a thermosetting polymer composite component. % of the total weight of the insulator, preferably 2-15% by weight, and is preferably of epoxy resin material. The impregnating function of the binder can be accomplished by compositional proportions of polymers of lower molecular weight, liquid to semi-solid consistency, with polysiloxanes being the most suitable for higher temperature utilization. The composition providing the impregnation function is 2-20% by weight of the total weight of the layered insulating tape.

The insulating tapes according to the invention are particularly suitable for winding high-voltage electrical machines with an operating voltage of 6-20 kV, arranged in temperature classes B to H, especially in applications where the final spatial forming of the windings takes place only after pressing the groove part of the winding insulation.

The layer of etude paper on the insulating tape is usually 0.03 to 0.06 mm, the types of this material being selectable without any limitation. The heat-resistant carrier layer is preferably of a non-porous material of foils, fabrics, fibers and the like of an organic, inorganic or mixed type, usually a thickness of 0.02 to 0.05 mm. The amount of the two-component epoxy-epoxy, polysiloxane-polysiloxane, loxane-type epoxy or other type binder does not exceed 25 percent by weight in the insulator. The epoxy-based binders can also contain a lower proportion of hardeners, which at the elevated temperature have a predominantly linear character of the polymerization.

The insulating tapes according to the invention are characterized in particular by the cohesiveness of the layers, the compactness of the etched paper and the ability to follow the shape of the wrapped conductor without adhering the tape to the conductor when processed into a coil. With tape insulators according to the invention, the breakthrough voltage and reliability between the tight insulated winding areas increases by about 20-25 percent.

- 5 229 792

The possibility of utilizing the solution according to the invention is given immediately in the sector of the production of wound cast steel electrical insulating materials. Applicability is in the field of direct production, relevant insulated conductors as well as given electrical machines of high voltage types, in their repair and maintenance.

Example 1

Tissue paper produced by a thermochemical method of natural muscovite type mica, characterized by a basis weight of 80 g / m @ 2, was associated with a 0.025 mm thick polyethylene terephthalate foil by means of a two-component binder whose adhesive compositional constituent 1/8 and the impregnating composition fraction consisted of polymeric polymethylsiloxane -3 2 -1 liquid with a viscosity of 5.10 ms. In the binder, whose weight fraction in relation to the weight of the whole layered insulator represented 20 percent, compositionally stuck to the adhesive and impregnating parts were 1: 1st A 0.08 mm thick insulator was cut into strips which wound a rectangular cross-section of 2 x 8 mm of pressed media with the yard layers with half overlapping adjacent layers during wrapping. The average value of the breakdown voltage measured according to ČSN 34 5640 on an insulated conductor was 8.2 kV.

Example 2

Polyethylene terephthalate thermoplastic sheet, axially oriented, 0.03 mm thick, combined by a dry lamination process with a 70 g / m 2 layer of mica paper, applying an adhesive-impregnating, two-component binder »In this binder, the adhesive composite dian was Resins of the commercial designation CHS Epoxy 15 and CHS.Epoxy 1/16, an epoxy equivalent of 520 and a softening point of 45 ° C. A 30 percent acetone solution based on CHS Epoxy 15 and CHS Epoxy 1003, having an epoxy equivalent of 205 and a softening point of 18 ° C, was applied to the foil material by the mica paper as impregnating binder. The solvent was evaporated from the insulator by passing through a drying channel. The epoxy components contained 0.5% by weight of BF-γ-lamin as hardener. The ratio of adhesive com

The proportion of the binder to the impregnating agent was 2: 1 parts by weight in the binder and the proportion of this binder in relation to the weight of the insulator as a whole was 15% by weight.

A rectangular 2.24 conductor wire was wrapped with a 16 mm strip insulator. 8 mm, with two layers with 50 percent overlap. The average breakdown napMtie wire was 10.2 kV, while the exposure to thermal stress for 45 minutes at 160 DEG C. After _a subsequent bending of the insulated wire in high - the radius of 40 mm, the measured value of the breakdown voltage was 7.0 kV.

Claims (3)

OBJECT OF THE INVENTION 229 792 1. A winding high-voltage laminate insulator for insulating individual conductors of a rectangular cross-section of a high-voltage electrical machine winding, characterized in that the insulating material is formed from a sheet of carbon paper, which is adhesive bonded to the heat carrier material by adhesive surfaces. - an impregnating binder containing, in proportion to the total weight of the laminated insulator, a maximum of 20% by weight of an adhesive composition composition of the thermosetting plastics having a softening point of 35-6 ° C and having a tack to carriers greater than the bonding value of the particles and wherein the other binder portion is an impregnating composition which is of a thermosetting or heat resistant thermoplastic material of liquid or semi-solid consistency, a softening point of not more than 30 ° C, which material is in the applied layer The paper is integrated in at least 10 percent by weight relative to the weight of the paper. 2. A winding high-voltage laminate insulator according to claim 1, wherein the insulator is formed from a layer of carbon paper associated with the carrier with a two-component binder in which the proportions of the adhesive composition and the impregnating composition are relative to each other. parts. 3. A winding high-voltage insulator according to claim 1 or 2, characterized in that the two-component binder of the insulated insulating layers is a binder whose adhesive composition is a thermosetting epoxy resin based on glycidyl ethers with an epoxy equivalent of 200-600 and the impregnating composition. of liquid to semi-solid consistency based on polysiloxanes or epoxides.