CH683049A5 - Surface shaped insulating electrical machinery or apparatus, in particular slot insulation. - Google Patents

Description

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description

TECHNICAL AREA

The invention is based on a sheet-like insulating material body according to the preamble of claim 1. Such insulating material bodies are preferably used as slot insulation for rotating electrical machines of high and medium voltage technology, but can also be used for other purposes in electrical machines and apparatus.

STATE OF THE ART

With the preamble, the invention relates to a state of the art of sheet-like insulating material bodies, as is described, for example, in US Pat. No. 3,974,314. The known insulating body can be designed as a groove insulation with a U-shaped or L-shaped profile and has multilayer insulation sheets made of aromatic polyamide (aramid) and polyheterocycles. If such insulations are inserted into a groove of a rotating electrical machine, damage may occur on the outside due to the deformation of the radius if the wall thickness of the groove insulation is determined by the required electrical properties. This can lead to failure of the slot insulation.

PRESENTATION OF THE INVENTION

The invention, as defined in claim 1, is based on the object of creating a sheet-like insulating material body, in particular in the form of slot insulation, which can be installed in an electrical machine or an electrical apparatus without damage even in the case of severe deformations in the region of the at least one radius .

The insulating body according to the invention is distinguished by the fact that it has high mechanical strength at selectively defined points and can be subjected to almost any deformation at other points without damage. When designed as groove insulation, the insulating body according to the invention can therefore be easily adapted to any groove shape with almost any small radius of curvature when installed in an electrical machine. At the same time, it is ensured that undesired foreign bodies which impair the insulating ability of the slot insulation cannot penetrate between the individual layers of the slot insulation, as can be the case, for example, in the case of multi-layer slot insulation with unglued legs. Waviness of the leg insulation sheets, which can occur with multi-layer groove insulation with unglued legs, is largely eliminated.

WAY OF CARRYING OUT THE INVENTION

The invention is explained below with reference to the drawing. Here shows:

1 is a plan view of a cross-section of a groove through a sheet-like insulating body designed as groove insulation according to the invention,

Fig. 2 is a plan view of an insulating material layer used in the production of the slot insulation according to Fig. 1 and coated with adhesive, and

Fig. 3 is a plan view of a section made transversely to a groove through part of another insulating material body according to the invention, also designed as groove insulation.

In FIG. 1, 1 denotes a slot insulation with a U-shaped profile used, for example, in the rotor of a high-voltage generator. This groove insulation essentially consists of two layers 2, 3 of flexible insulating material, typically 0.5 mm thick, arranged in layers. A high-temperature-resistant and in particular fibers and / or flakes containing aromatic polymer, for example based on polyamide, is preferably used as the material of the insulating material. A typical material is a paper sold under the registered trademark Nomex® by Dupont.

A section 4 connecting the two legs of the U is designed to be comparatively rigid and serves as a mechanically highly resilient part which rests on the base of the rotor groove (not shown). The rigidity and high mechanical strength of section 4 is achieved in that the two layers of insulating material 2, 3 are connected in the area of section 4 by means of an adhesive layer 5 located between them. The adhesive layer 5 is preferably formed from a thermoset or dried polymer, for example based on epoxy or polyester. In order to reinforce the section 4 which supports the conductor of the rotor on the groove base, a laminated glass fiber plate can additionally be provided, if desired.

The legs of the U each contain a substantially vertically extending section 6 and 7 and a radius 8 and 9 formed between the sections 4 and 6 or 4 and 7 in the insulating layers 2, 3. Between the superimposed parts of the insulating layers 2 , 3 are provided in the region of the sections 6, 7 plastically or elastically deformable adhesive layers 10, 11. Such adhesive layers, like the comparatively rigid adhesive layer 5, are typically approximately 50 μm thick and can be produced from a thermosetting or dried, polymeric, preferably heat-resistant, adhesive, for example based on polyacrylate. A typical material for the adhesive layers 10 and 11 is, for example, a rubber-like deformable, acrylate-containing adhesive. The adhesive layer 11 extends into the area of the radius 9, but can also stop in front of the area of the radius 8 like the adhesive layer 10. The same applies to the adhesive layer 10, which can extend into the area of the radius 8.

A coating 12 is applied to the exposed surface of the insulating material layer 3 facing the conductor of the rotor (not shown). This

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The purpose of the covering is to protect the fibers and / or flakes of the insulating layers 2 and 3 underneath from abrasion and to create a surface that is as smooth and fiber-free as possible. If a similar covering is also applied to the exposed surface of the insulating layer 2, the slot insulation 1 is additionally protected against moisture and dirt. The covering 12 can preferably be produced from a composite material, such as a fleece based on polyester or polyamide, which is impregnated with polyester or epoxy resin. Such a covering is characterized by scratch resistance, tracking resistance and moisture resistance.

The groove insulation 1 can be pressed from a prefabricated prepreg, but can also be produced in a conventional manner by successively overlapping and pressing the different layers.

2, the prepreg can be produced as follows: First, the layer 2 is provided with a layer 13 of a polymer based on polyester or epoxy and with layers 14 and 15 based on an acrylate adhesive. The layers 14 and 15 can be applied as typically 50 µm thick coverings by dry removal from a carrier film. It should be noted here that the coated surfaces correspond to the dried or hardened adhesive layers 5, 10 and 11. Layer 3 is then layered over layer 2. If desired, the exposed surface of layer 3 can be coated in accordance with layer 2 and covered with a further layer of insulating material. The uppermost layer of the stack can then also be provided with a composite material providing the covering 12 on the basis of a resin-impregnated polyester fleece. Such a prepreg can be cut to the desired dimensions of the groove insulation 1 and pressed in a mold at elevated temperatures while the resins or adhesives used are hardened.

It is also possible to apply only the layer 13 to the layer 2 and, after the layer 3 has been placed in a mold at elevated temperature, initially only to produce the adhesive layer 5. The adhesive layers 10 and 11 and the composite material can then be applied and the groove insulation 1 can be finally finished by hot pressing.

After pressing, the groove insulation 1 has the shape shown in broken lines in FIG. 1. When inserting into the rotor groove, not shown, sections 6 and 7 stand up on the groove flanks. Here, the groove insulation 1 in the area of the radii 8 and 9 cannot be damaged, since the insulating layers 2 and 3 can still move relative to one another even with very small radii of curvature. Only in the area of section 4 are the insulating layers 2 and 3 practically rigidly coupled to one another. The adhesive layer 5 provided there has an elongation at break of at most a few percent. This, however, ensures a tight fit of the groove insulation 1 on the groove bottom. In contrast, the adhesive layers 10 and 11 have elongations at break of approximately 100%, which is also after the hardening of the

Groove insulation allows even strong bending stresses without damaging the insulating layers 2 and 3. Additional radii, such as those marked by angled portions 16, can be formed in a simple manner into the sections 6, 7 of the slot insulation 1 which are only slightly loaded mechanically. Particularly good subsequent deformability of the groove insulation 1 in the area of a radius, e.g. 8, is achieved in that the insulating layers 2 and 3 are free of an adhesive layer, e.g. 10, are. The in the subsequent section, e.g. 6, provided adhesive layer 10, then prevents undesirable foreign bodies from entering between the insulating layers 2 and 3, as in the case of insulating layers 2 and 3 which are open at the top.

The groove insulation 17, which is preferably shown in FIG. 3 and preferably has a U-shaped profile, contains two layers 18, 19 of a flexible and mechanically highly resilient insulating material, typically 0.5 mm thick. A suitable material is, for example, the paper already described for insulating layer 2 and 3 of slot insulation 1 and sold under the trademark Nomex® by Dupont. A further layer 20 of an insulating material is provided between the two layers of insulating material 18, 19. This insulating material is of higher dielectric quality but less mechanically stressable than the insulating material of layers 18 and 19 and can be, for example, a film sold by the Dupont company under the trademark Kapton®.

In the area of the groove base, the three layers of insulating material 18, 19 and 20 are rigidly connected to one another by means of adhesive layers 21, 22 based on a thermoset or dried polymer. The insulation can therefore be subjected to high mechanical loads in the area of the groove base.

In the area of the legs of the groove insulation, the insulating layers 18, 19 and 20 are held together by means of elastically or plastically deformable adhesive layers 23, 24. The adhesive layers 23, 24 can have the same dimensions and the same material structure as the adhesive layers 10, 11 of the groove insulation 1. As shown in FIG. 3, they can extend from the legs of the U-profile over a radius into the groove base extend.

Compared to the slot insulation 1, the slot insulation 17 additionally has the following advantages. It is of particularly high dielectric quality and, despite the use of a material that is comparatively sensitive to mechanical stress, is extremely robust. The outer insulating material layers 18 and 19, which can be subjected to high mechanical stress, protect the mechanically less robust, but dielectric high-quality insulating material layer 20 against impermissibly high forces. For the most part, the forces are absorbed by the outer layers 18 and 19 and their transmission is considerably reduced by the flexible adhesive layers 23 and 24. Undesired crack damage in the layer 20, which is relatively susceptible to mechanical forces, is largely avoided in this way.

Corresponding to the groove insulation 1, the exposed surfaces can also be covered with a groove, for example on the basis of a damp 5

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repellent and creep-resistant composite material.

Depending on the requirements for insulation capacity and thickness of the insulating material layers used, the slot insulation 1 or 17 can of course also be constructed from more than 2 or 3 insulating material layers.

Claims (11)

Claims 1. Flat insulating material body for electrical machines or apparatus, in particular groove insulation (1), containing at least two layers (2, 3, 18, 19, 20) arranged in layers, at least one flexible insulating material, at least one formed by parts of the insulating material layers one above the other, mechanically resilient first section (4), at least one second section (6, 7) formed by superimposed parts of the insulating material layers, and at least one radius (8) arranged between the first (4) and the second section (6, 7) and molded into the insulating material layers , 9, 25), characterized in that the parts of the insulating material layers forming the at least one first section (4) are almost rigid and the parts of the insulating material layers forming the at least one second section (6, 7) by means of at least one plastically or elastically deformable adhesive layer ( 10, 11, 23, 24) are interconnected, and that the at least two isoli first layers (2, 3, 18, 19, 20) in the region of the at least one radius (8, 9, 25) are arranged so as to be displaceable relative to one another. 2. Insulating body according to claim 1, characterized in that at least three insulating layers (18, 19, 20) are arranged in layers one above the other, of which a second insulating layer (20) located between two outer first insulating layers (18, 19) from one opposite the material of the two outer layers of insulating material is made of dielectric material which is of higher dielectric value but is less mechanically strong and is at least partially provided with the elastically or plastically deformable adhesive layer (23, 24) on both sides at least in the region of the second section. 3. Insulating body according to one of claims 1 or 2, characterized in that the at least one adhesive layer (10, 11, 23, 24) extends into the region of the at least one radius (8, 9, 25). 4. Insulating body according to one of claims 1 or 2, characterized in that the region of the at least one radius (8, 9) is free of the at least one adhesive layer (10, 11). 5. Insulating body according to one of claims 1-4, characterized in that the at least one adhesive layer (10, 11, 23, 24) contains hardened or dried adhesive. 6. Insulating body according to claim 5, characterized in that the at least two insulating layers (2, 3, 18, 19, 20) and the at least one adhesive layer (10, 11, 23, 24) each contain a high temperature-resistant polymer. 7. Insulating body according to claim 6, characterized in that the at least two insulating layers (2, 3, 18, 19, 20) contain an aromatic polyamide and the at least one adhesive layer (10, 11, 23, 24) is a polymer based on acrylate having. 8. Insulating body according to one of claims 1-7, characterized in that at least one (3) of the at least two insulating layers (2, 3) contains fibers and / or flakes, which by at least one on the exposed surface of the at least one insulating layer (3 ) applied covering (12) is at least partially covered. 9. Insulating body according to claim 8, characterized in that the at least one covering (12) is formed from an abrasion-resistant composite material. 10. Insulating body according to claim 9, characterized in that the composite material is based on a resin-impregnated polyester or polyamide fleece. 11. Insulating body according to one of claims 1-10, characterized in that a further radius is formed in the at least one second section (6, 7). 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th