JP2011193727A - Rotating electric machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a highly reliable rotating electric machine configured so that surface discharge is not generated in the air even when a corona shield layer is eroded due to electric discharge generated in an air gap near an interface between the corona shield layer and an insulating layer formed around a coil conductor. <P>SOLUTION: The rotating electric machine includes the coil conductor 10 stored in an iron-core slot 2 and including an end portion extending toward the outside of the iron-core slot 2, a main insulating-layer-to-ground 4 formed around the coil conductor 10, and the corona shield layer 7 provided on an external periphery of the main insulation-layer-to-ground 4 and extending from the inside of the iron-core slot 2 to the outside to prevent corona discharge in the iron-core slot 10, wherein a pre-impregnated mica tape 22 is wound around the external periphery of the corona shield layer 7 positioned at the outside of the iron-core slot 2 as a protective layer against the surface discharge so that the corona shield layer 7 is not exposed. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to protection against surface discharge of a low-resistance corona shield layer of a stator coil provided at a position corresponding to the outside of a stator core slot in a rotary electric machine, particularly a high-voltage rotary electric machine.

  A stator coil of a high-voltage rotating electrical machine that is used by being housed in a slot of a stator core is formed by winding a mica tape having excellent partial discharge resistance around the outer periphery of the coil conductor to form a ground insulating layer. Further, a low-resistance corona shield layer is provided on the outer peripheral portion of the ground-main insulating layer to provide a low-resistance corona shield layer that prevents discharge between the stator core and a portion outside the slot. A high-resistance corona shield layer that prevents creeping discharge is provided over a portion of the wire, and after the stator coil is housed in the slot of the stator core and connected, the whole is vacuum-impregnated with a resin such as epoxy resin, It is formed by heat treatment.

  When defects such as air gaps exist in the ground-main insulating layer that insulates the high voltage applied to the coil conductor from the iron core, discharge occurs in these defective portions. In particular, if there is a gap at the interface between the low-resistance corona shield layer and the insulating layer, a partial discharge occurs in the gap, and this discharge causes the low-resistance corona shield layer to disappear, resulting in a larger discharge. In particular, the low resistance corona shield layer located outside the slot does not constrain the outer periphery like the stator core in the slot, so the resin near the low resistance corona shield layer is likely to leak, and low resistance due to partial discharge. The corona shield layer is likely to disappear.

For this reason, there is a proposal to prevent the outflow of impregnated resin by providing a resin outflow prevention layer made of an adhesive tape or a heat-shrinkable tape on the low resistance corona shield layer (for example, see Patent Document 1).
There is also a proposal for preventing a resin outflow by providing a film layer on an SiC layer connected to the low resistance corona shield layer (see Patent Document 2).

Japanese Utility Model Publication No.59-117255 JP-A-62-152345

In the stator coil of a rotating electrical machine in which a resin outflow prevention layer is applied on the low resistance corona shield layer as described in Patent Document 1, an adhesive tape or a heat resistant tape that cannot be impregnated with the impregnated resin when heat curing is performed, or By using these films, generation | occurrence | production of the space | gap by the resin leak of an earth-ground insulating layer is reduced. Although the specific material names are not exemplified in the above-mentioned Patent Document 1, the adhesives based on polymer films such as polyester, polyimide, and polyamide are generally used as adhesive tapes and shrink tapes on the market. Tapes and shrink tapes are considered to be applicable.
Moreover, in the said patent document 2, the polyester film is illustrated as a material of the resin outflow prevention layer.
Although the generation of voids is reduced by applying the resin outflow prevention layer, it is difficult to completely eliminate leakage, voids due to poor resin impregnation, and voids due to curing shrinkage of the resin. When the partial discharge generated in these gaps erodes and disappears the low-resistance corona shield layer and reaches the resin outflow prevention layer installed outside, the above-described polymer films such as polyester, polyimide, polyamide, etc. are vulnerable to partial discharge. Therefore, it disappears in a short time, and as a result, a large surface discharge is generated on the coil surface to promote insulation deterioration of the stator coil.
In particular, the air cooler using air as the cooling medium of the generator, when discharge in the air ozone and NO _x is generated, thereby or cause deterioration or corrosion of the metal material of the insulating material. As a result, problems such as dielectric breakdown, breakage of metal parts, and deterioration of lubricating oil occur.

  The present invention prevents a surface discharge from occurring in the air even if a discharge is generated in the gap near the interface between the corona shield layer and the insulating layer formed around the coil conductor and the corona shield layer is eroded. An object of the present invention is to provide a rotating electrical machine with high reliability.

  In the rotating electrical machine according to the present invention, a coil conductor housed in a slot provided in an iron core and having an end extending outside the slot, an insulating layer formed around the coil conductor, and an outer periphery of the slot on the outer periphery of the insulating layer. A corona shield layer that extends from the inside to the outside to prevent corona discharge is provided, and the corona shield layer has a prepreg mica tape as a protective layer against surface discharge on the outer periphery of the corona shield layer located outside the slot. It is wound so as not to be exposed.

  According to this invention, even if a discharge is generated in the gap near the interface between the corona shield layer and the insulating layer formed around the coil conductor and the corona shield layer is eroded, no surface discharge in the air occurs. A highly reliable rotating electrical machine configured as described above can be provided.

It is a perspective view which shows the principal part structure of the stator slot exit vicinity in the stator of the rotary electric machine which concerns on Embodiment 1 by this invention. It is principal part sectional drawing which shows typically the insulation structure of the coil length direction in the stator slot exit vicinity in the stator of the rotary electric machine which concerns on Embodiment 1 by this invention. It is sectional drawing which shows typically the principal part structure of the insulation structure in the stator of the rotary electric machine which concerns on Embodiment 1 by this invention. It is principal part sectional drawing which shows typically the insulation structure of the coil length direction in the stator slot exit vicinity in the stator of the rotary electric machine which concerns on Embodiment 2 by this invention. It is principal part sectional drawing which shows typically the insulation structure of the coil length direction in the stator slot exit vicinity in the stator of the rotary electric machine which concerns on Embodiment 3 by this invention. It is principal part sectional drawing which shows typically the insulation structure of the coil length direction in the stator slot exit vicinity in the stator of the rotary electric machine which concerns on Embodiment 4 by this invention. It is principal part sectional drawing which shows typically the insulation structure of the coil length direction in the stator slot exit vicinity in the stator of the rotary electric machine which concerns on Embodiment 5 by this invention. It is principal part sectional drawing which shows typically the insulation structure of the coil length direction in the stator slot exit vicinity in the stator of the rotary electric machine which concerns on Embodiment 6 by this invention.

Embodiment 1 FIG.
Embodiment 1 of the present invention will be described based on FIGS. 1 to 3 with respect to a case where insulation is formed by a full impregnation method. FIG. 1 is a perspective view of a principal part showing a configuration in the vicinity of a stator slot outlet in a stator coil of a rotating electrical machine according to a first embodiment. FIG. 2 is a main part sectional view schematically showing an insulating structure in the coil length direction in the vicinity of the slot outlet of the stator coil of the rotating electrical machine according to the first embodiment. FIG. 3 is a cross-sectional view schematically showing a main configuration of the insulating structure in the stator coil of the rotating electrical machine according to the first embodiment. In addition, the same code | symbol is attached | subjected to the same or equivalent part throughout each figure.

  As shown in FIGS. 1 and 2, the stator coil 3 is accommodated in an iron core slot 2 provided in the stator iron core 1, and an end portion thereof extends outside the iron core slot 2. The stator coil 3 includes a coil conductor 10 in which a plurality of wire conductors are bundled, a ground main insulating layer 4 wound around the coil conductor 10, and an iron core slot of the ground main insulating layer 4. The low resistance corona shield layer 7 wound around the outer peripheral portion of the portion housed in 2 and the low resistance corona shield layer 7 overlapped with the low resistance corona shield layer 7 by 10 to 20 mm on the portion protruding from the core slot 2 of the ground main insulating layer 4. It is comprised as the rotary electric machine applied as an air-cooling-type rotary machine with the rated voltage of 11 kV or more.

The low-resistance corona shield layer 7 is provided around the main ground insulating layer 4 as a surface corona shield means for preventing corona discharge on the surface of the stator coil 3.
As a material that can be preferably used as the material for forming the low-resistance corona shield layer 7, for example, a general insulating material excellent in insulation and heat resistance such as woven fabric and nonwoven fabric such as glass, polyester, and polyamide can be used. The material can be mentioned. However, the film is not preferable because it impedes resin impregnation. These materials are coated with or impregnated with conductive or semi-conductive powders such as carbon, graphite, iron powder, iron oxide, etc. A non-woven fabric wound together with can be used as the low resistance corona shield layer 7. Commercially available products include ISOLA's Conductive_Polyester_Tapes (215.51, 215.55), KREMPLE's Flexible_electrically_conductive_materials (06ELR_14AA, 03EFR_13BA).
Alternatively, a paint obtained by diluting a resin containing conductive powder such as carbon or graphite with a solvent may be used.
The volume resistivity of the material constituting such a low resistance corona shield layer 7 is 0.001 to 1000 Ω · cm.

Examples of materials that can be preferably used as a material for forming the high-resistance corona shield layer 9 include impregnating and applying a resin containing silicon carbide (SiC) powder to, for example, glass cloth, polyester or polyamide woven fabric, and non-woven fabric. It is possible to use a high resistance tape obtained by cutting a cured or semi-cured product into a tape shape. Examples of commercially available products include Semi-Conductive_Corona_Protection_Tapes (217.21, 217.22) from ISOLA, AKAIC_4b from KREMMPEL, and the like.
Moreover, you may apply | coat the coating material which diluted the resin containing a silicon carbide (SiC) powder with the solvent.
The volume resistivity of the material forming the high resistance corona shield layer 9 is larger than 0.001 to 1000 Ω · cm which is the volume resistivity of the material constituting the low resistance corona shield layer 7.
The high resistance corona shield layer 9 is coupled with the low resistance corona shield layer 7 to adjust the electric field distribution on the surface of the stator coil 3 and prevent creeping discharge on the surface of the stator coil 3.

Next, the manufacturing process of the stator coil of the rotating electrical machine will be described.
First, after cutting a strand into a predetermined length, the strand is bent for label dislocation, a predetermined number is bundled, heat-molded, and shaped into a predetermined shape to produce a strand bundle.
The stator coil 3 of the rotating machine has a predetermined thickness obtained by winding the mica tape 5 around the coil conductor 10 composed of the above-described wire bundles, and winding it a predetermined number of times. A low resistance corona shield layer 7 is formed on a part outside the core slot 2. A high resistance corona shield layer 9 is formed at a predetermined length on the end of the stator coil 3 so as to overlap with the low resistance corona shield layer 7 by 10 to 20 mm. Further, the conductive silicone rubber layer 20 is made of conductive silicone rubber in the range from the end of the core slot 2 where the low resistance corona shield layer 7 is exposed outside the core slot 2 to the end of the high resistance corona shield 9. It is formed by coating.

  After the stator coil 3 formed in this way is housed in the core slot 2 of the stator core 1 and connected, it is preliminarily heated in a heating furnace to remove moisture adsorbed on the main ground insulating layer 4 and the like. After drying, the entire stator is placed in an impregnation tank, and an insulating layer is formed by a full impregnation method in which a thermosetting resin is impregnated under vacuum and pressure. After the resin is sufficiently impregnated in the insulating layer, the resin is taken out from the impregnation tank and placed in a drying furnace for heating and curing, and the whole is heated and cured.

At this time, the heated impregnating resin tends to flow because the viscosity is lowered, and there is a possibility that a part of the resin impregnated in the insulating layer is exposed. Further, there is a possibility that the gap 12 is formed due to poor impregnation or curing shrinkage when the resin is cured.
If the gap 12 is formed in the stepped portion of the mica tape 5 due to resin leakage or curing shrinkage of the resin, partial discharge occurs due to the electric field during operation. The partial discharge generated in the portion surrounded by the mica tape 5 does not cause any particular inconvenience because the mica is a material having excellent partial discharge resistance.
However, when partial discharge occurs in the gap 12 at the interface between the low resistance corona shield layer 7 and the mica tape 5, carbon, graphite, etc. showing the conductivity of the low resistance corona shield layer 7 are decomposed and disappeared by the discharge, and the low resistance corona An insulating portion that does not exhibit low resistance appears in a part of the shield layer 7. In such a portion, only a discharge directed to the low resistance corona shield layer 7 is generated, and the low resistance corona shield layer 7 is gradually eroded by the discharge, and the disappeared portion expands. As the erosion of the low resistance corona shield layer 7 increases, the partial discharge characteristics deteriorate, the disappearance of the low resistance corona shield layer 7 further expands, and ozone and nitric acid are generated in the air cooler. There is a risk of causing corrosion of the constituent metal material and deterioration of the organic material.

However, as shown in FIG. 2, a conductive silicone rubber layer 20 is formed on the low resistance corona shield layer 7 located outside the stator core slot by applying conductive silicone rubber, so that the low resistance corona shield layer 7 is formed. if so as not to be exposed, it is possible to suppress the generation of the occurrence of surface discharge and ozone and nO _x.
That is, when the conductive silicone rubber layer 20 is formed on the outer periphery of the low resistance corona shield layer 7 by applying the conductive silicone rubber, it is cured after approximately 12 to 24 hours at room temperature. Since the conductive silicone rubber layer 20 is formed by applying conductive silicone rubber at most about 200 mm, impregnation is impeded because the main insulating layer can be easily penetrated and impregnated from other parts when impregnated with resin. It will not be.
Even if the partial discharge occurs in the gaps 12 caused by resin leakage and resin cure shrinkage and the low-resistance corona shield layer 7 disappears locally, the conductive silicone rubber having excellent partial discharge resistance is provided thereon. not to the surface in the air because of the layer 20, thus the occurrence of ozone and NO _x is prevented.

When a part of the low resistance corona shield layer 7 disappears and reaches the conductive silicone rubber layer 20, the conductive silicone rubber layer 20 and the low resistance corona shield layer 7 have the same potential as shown in FIG. Since the discharge path SP is formed between the conductive silicone rubber layer 20 and the insulation at the disappearance portion of the resistance corona shield layer 7, the discharge toward the end of the low resistance corona shield layer 7 becomes weak, so that the discharge is reduced. Further disappearance expansion of the resistance corona shield layer 7 is suppressed.
Compared to the material constituting the low-resistance corona shield layer 7 silicone rubber parts silicone rubber for strong and long lifetime to discharge without surface discharge in the air not occur because not lost, suppress the generation of ozone and NO _x it can. In addition, since the rate at which the discharge erodes the low resistance corona shield layer 7 is slowed, expansion of the disappearing portion of the low resistance corona shield layer 7 is also suppressed.

Silicone rubber is more resistant to partial discharge than common organic materials such as epoxy varnish (corona resistance life: epoxy varnish 65.5h, silicone rubber 35,600h: Shin-Etsu Chemical Co., Ltd. catalog description) It takes a long time for the silicone rubber to disappear and discharge in the atmosphere, and generation of ozone and nitric acid can be prevented over a long period of time.
Examples of the conductive silicone rubber include KE3491 and KE3492 which are RTV rubber products manufactured by Shin-Etsu Chemical Co., Ltd., and 1038 and 1075 manufactured by Chomerics.

As described above, according to the first embodiment, since the conductive silicone rubber layer 20 is a material having excellent partial discharge resistance, it does not lead to surface discharge in the air and obtains good insulation characteristics over a long period of time. it can be the generation of ozone and NO _x can be suppressed.

(1A) According to the first embodiment of the present invention, the coil conductor is formed of an insulation-coated wire bundle that is housed in the iron core slot 2 provided in the stator iron core 1 and whose end extends to the outside of the iron core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A low-resistance corona comprising a low-resistance corona shield layer that extends from the end face of the stator core 1 by 25 mm or more and prevents a corona discharge in the core slot 2 and is located outside the slot. A stator coil is formed by forming a silicon protective layer formed of a conductive silicone rubber layer 20 or the like as a protective layer against surface discharge on the outer periphery of the corona shield layer composed of the shield layer 7. A rated voltage of 11 kV, comprising an all-impregnated stator coil manufactured by vacuum-impregnating a thermosetting resin after accommodating and connecting the stator coil in an iron core slot 2 provided in the stator core 1 Since the rotating electric machine is applied as the above-described air-cooling type rotating machine, the gap near the interface between the corona shield layer composed of the low-resistance corona shield layer 7 and the ground main insulating layer 4 formed around the coil conductor 10 Therefore, it is possible to provide a highly reliable rotating electrical machine configured so that surface discharge does not occur in the air even when a corona shield layer composed of the low-resistance corona shield layer 7 is eroded due to the occurrence of discharge at 12. .

(1B) According to the first embodiment of the present invention, the coil conductor is formed of an insulation-coated wire bundle that is housed in the iron core slot 2 provided in the stator iron core 1 and whose end extends to the outside of the iron core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A first corona shield layer comprising a low resistance corona shield layer 7 extending from the end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2, and comprising the low resistance corona shield layer 7. A part of 10 to 20 mm is overlapped on the outer end of the first corona shield layer and is formed of a higher resistance member than the first corona shield layer member made of the low resistance corona shield layer 7. A second corona shield layer composed of a high resistance corona shield layer 9 for preventing the creeping discharge, and against the surface discharge on the outer periphery of the first corona shield layer composed of the low resistance corona shield layer 7 located outside the slot. A silicon protective layer formed of a conductive silicone rubber layer 20 or the like is formed as a protective layer to constitute a stator coil, and after the stator coil is housed and connected in an iron core slot 2 provided in the stator iron core 1, Since the rotary electric machine is applied as an air-cooled rotary machine having a rated voltage of 11 kV or more, which is provided with an all-impregnated stator coil manufactured by vacuum impregnation of a thermosetting resin, the low resistance corona shield layer 7 A discharge is generated in the gap 12 near the interface between the first corona shield layer and the ground main insulating layer 4 formed around the coil conductor 10, and the low resistance roller Be eroded first corona shield layer made of the shielding layer 7, it is possible to surface discharges in air to provide a structure and reliable rotary electric machine so as not to generate.

(1C) According to the first embodiment of the present invention, the coil conductor is formed of an insulation-coated wire bundle that is housed in the core slot 2 provided in the stator core 1 and whose end extends to the outside of the core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A first corona shield layer comprising a low resistance corona shield layer 7 extending from the end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2, and comprising the low resistance corona shield layer 7. A part of 10 to 20 mm is overlapped on the outer end of the first corona shield layer and is formed of a higher resistance member than the first corona shield layer member made of the low resistance corona shield layer 7. A second corona shield layer composed of a high resistance corona shield layer 9 for preventing the creeping discharge, and against the surface discharge on the outer periphery of the first corona shield layer composed of the low resistance corona shield layer 7 located outside the slot. As a protective layer, a stator rubber coil is formed by forming a silicone rubber protective layer formed of a conductive silicone rubber layer 20 that is electrically coupled to the second corona shield layer composed of the high-resistance corona shield layer 9 and can be energized. A rated voltage of 11 kV, comprising an all-impregnated stator coil manufactured by vacuum-impregnating a thermosetting resin after accommodating and connecting the stator coil in an iron core slot 2 provided in the stator core 1 Since the rotating electric machine is applied as the above air cooling type rotating machine, the first corona shield layer and the coil made of the low resistance corona shield layer 7 are used. Even if the first corona shield layer made of the low resistance corona shield layer 7 is eroded by a discharge occurring in the gap 12 near the interface with the ground-main insulating layer 4 formed around the body 10, the low resistance It is possible to provide a highly reliable rotating electrical machine configured to maintain the function as the first corona shield layer including the corona shield layer 7 and prevent the occurrence of surface discharge in the air.

Embodiment 2. FIG.
Embodiment 2 of the present invention will be described with reference to FIG. 4 in the case where insulation is formed by a full impregnation method. FIG. 4 is a cross-sectional view schematically showing a main configuration of the stator coil of the rotating electrical machine according to the second embodiment.
In the second embodiment, the configuration other than the specific configuration described here has the same configuration contents as the configuration in the first embodiment described above, and exhibits the same operation. In the drawings, the same reference numerals indicate the same or corresponding parts.

The volume resistivity of the conductive silicone rubber constituting the conductive silicone rubber layer 20 shown in the first embodiment is the same as that of the material constituting the low resistance corona shield layer 7 in this second embodiment. 0.001 to 1000 Ω · cm.
When the volume resistivity of the conductive silicone rubber constituting the conductive silicone rubber layer 20 is 0.001 to 1000 Ω · cm, the conductive silicone rubber itself can play the same role as the low resistance corona shield layer 7 at the end. That is, the high resistance corona shield layer 9 is connected to the low resistance corona shield layer 7 for the purpose of suppressing the creeping discharge on the surface, but the high resistance corona shield layer 9 passes through the low resistance corona shield layer 7. Therefore, it is necessary to pass current through the stator core 1 as shown by the current path CP. By setting the volume resistivity of the conductive silicone rubber layer 20 to 0.001 to 1000 Ω · cm, which is the same volume resistivity as that of the material constituting the low resistance corona shield layer 7, the low resistance corona shield layer 7 is formed by partial discharge. Since the current from the high resistance corona shield layer 9 can flow to the stator core 1 via the conductive silicone rubber layer 20 even if it disappears and the current path CP is cut off, the function of the high resistance corona shield layer 9 can be achieved. Even if the low resistance corona shield layer 7 disappears even if a partial discharge occurs in the gap 12 that is not damaged and is caused by resin leakage or resin curing shrinkage, the conductive silicone rubber layer 20 is present on the air, so that air It does not become in the surface and thus the generation of ozone and NO _x is prevented. Since silicone rubber is excellent in partial discharge resistance, the occurrence of surface discharge can be suppressed over a long period of time.

(2A) According to the second embodiment of the present invention, the coil conductor is composed of a bundle of insulated wires that are housed in the core slot 2 provided in the stator core 1 and whose end portions extend to the outside of the core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A first corona shield layer comprising a low resistance corona shield layer 7 extending from the end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2, and comprising the low resistance corona shield layer 7. A part of 10 to 20 mm is overlapped on the outer end of the first corona shield layer and is formed of a higher resistance member than the first corona shield layer member made of the low resistance corona shield layer 7. A second corona shield layer comprising a high resistance corona shield layer 9 for preventing creeping discharge, and the high resistance as a protective layer against surface discharge on the outer periphery of the first corona shield layer located outside the core slot 2 A silicone rubber protective layer having a volume resistivity of 0.001 to 1000 Ω · cm formed of a conductive silicone rubber layer 20 that is electrically coupled to the second corona shield layer 9 made of the corona shield layer 9 and can be energized. An all-impregnation type stator coil that is formed by forming a stator coil, housing the stator coil in an iron core slot 2 provided in the stator core 1 and connecting the stator coil, and then vacuum impregnating the thermosetting resin. The first corona composed of the low-resistance corona shield layer 7 is used as a rotating electric machine that is applied as an air-cooled rotating machine with a rated voltage of 11 kV or more. Even if a discharge is generated in the gap 12 near the interface between the shield layer and the ground main insulating layer 4 formed around the coil conductor 10 and the first corona shield layer composed of the low resistance corona shield layer 7 is eroded. In addition, it is possible to provide a highly reliable rotating electrical machine configured to reliably maintain the function as the first corona shield layer including the low-resistance corona shield layer 7 and prevent surface discharge in the air from occurring. .

Embodiment 3 FIG.
Embodiment 3 according to the present invention will be described with reference to FIG. FIG. 5 is a cross-sectional view schematically showing a main configuration of the stator coil of the rotating electrical machine according to the third embodiment.
In the third embodiment, the configuration other than the specific configuration described here has the same configuration contents as the configuration in the first embodiment or the second embodiment described above, and exhibits the same operation. It is. In the drawings, the same reference numerals indicate the same or corresponding parts.

If the insulating silicone rubber layer 21 is formed on the outer periphery of the low-resistance corona shield layer 7 located outside the stator core slot 2 as shown in FIG. the production of and NO _x can be suppressed.
That is, when the insulating silicone rubber layer 21 is formed on the outer periphery of the low resistance corona shield layer 7 by applying the insulating silicone rubber, it is cured after approximately 12 to 24 hours at room temperature. Since the insulating silicone rubber layer 21 is formed by applying the insulating silicone rubber at most about 200 mm, the main insulating layer 4 can be easily penetrated and impregnated from other portions when impregnated with the resin. It won't interfere.
Even if a partial discharge occurs in the gap 12 formed due to resin leakage or curing shrinkage of the resin and the low resistance corona shield layer 7 disappears, there is an insulating silicone rubber layer 21 on top of it so should not, therefore generation of ozone and NO _x is prevented. Since the insulating silicone rubber forming the insulating silicone rubber layer 21 is particularly excellent in partial discharge resistance, the occurrence of surface discharge can be suppressed over a long period of time.

The RTV rubber having a volume resistivity of 1 TΩ · m (10 ¹⁴ Ω · cm) or more is preferably applied as the insulating silicone rubber for forming the insulating silicone rubber layer 21. There are KE42 and KE348, which are RTV rubber products of Chemical Industries, Ltd.

  As described above, according to the third embodiment, since the insulating silicone rubber layer 21 is a material excellent in partial discharge resistance, it does not lead to surface discharge in the air, and good insulation is obtained over a long period of time. The generation of ozone and nitric acid can also be suppressed.

(3A) According to the third embodiment of the present invention, the coil conductor is formed of an insulation-coated wire bundle that is housed in the iron core slot 2 provided in the stator iron core 1 and whose end extends to the outside of the iron core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A corona shield layer comprising a low resistance corona shield layer 7 extending from the end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2 and located outside the slot. insulating silicone rubber composed of insulating silicone rubber with ^{1TΩ · m (10 14 Ω ·} cm) of about or more of the volume resistivity of the protective layer to the surface discharge on the outer periphery of the layer 21 is formed to form a stator coil, and the stator coil is housed in an iron core slot 2 provided in the stator core 1 and connected, and then is made by vacuum impregnation with a thermosetting resin. Since the rotating electrical machine is applied as an air-cooling type rotating machine having a rated voltage of 11 kV or more, which includes a child coil, the grounding main body formed around the corona shield layer composed of the low-resistance corona shield layer 7 and the coil conductor 10 Even if a discharge is generated in the gap 12 near the interface with the insulating layer 4 and the corona shield layer made of the low resistance corona shield layer 7 is eroded, the insulating silicone rubber protective layer 21 causes surface discharge in the air. It is possible to provide a highly reliable rotating electrical machine configured so as not to occur.

(3B) According to the third embodiment of the present invention, the coil conductor is formed of an insulation-coated wire bundle which is housed in the core slot 2 provided in the stator core 1 and whose end extends to the outside of the core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A first corona shield layer comprising a low resistance corona shield layer 7 extending from the end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2, and comprising the low resistance corona shield layer 7. A part of 10 to 20 mm is overlapped on the outer end of the first corona shield layer and is formed of a higher resistance member than the first corona shield layer member made of the low resistance corona shield layer 7. Creeping discharge a second corona shield layer made of high-resistance corona shielding layer 9 to prevent the, 1TΩ · m (10 as a protective layer against the outer circumference surface discharge of the first corona shield layer located outside of the slot ^The stator coil is formed by forming an insulating silicone rubber layer 21 made of an insulating silicone rubber having a volume resistivity of about ¹⁴ Ω · cm) or more, and is formed in the core slot 2 provided in the stator core 1. A rotating electrical machine applied as an air-cooling type rotating machine with a rated voltage of 11 kV or more, equipped with a stator coil of an all-impregnation method manufactured by vacuum impregnating a thermosetting resin after housing and connecting the stator coil. Therefore, the first corona shield layer composed of the low-resistance corona shield layer 7 and the gap 12 near the interface between the main ground insulating layer 4 formed around the coil conductor 10 are released. Even if the first corona shield layer composed of the low-resistance corona shield layer 7 is eroded, the insulating silicone rubber protective layer 21 prevents the surface discharge in the air from occurring. A high rotating electrical machine can be provided.

Embodiment 4 FIG.
Embodiment 4 according to the present invention will be described with reference to FIG. FIG. 6 is a cross-sectional view schematically showing a main configuration of the stator coil of the rotating electrical machine according to the fourth embodiment.
In the fourth embodiment, the configuration other than the specific configuration described here has the same configuration contents as the configuration in any of the first to third embodiments described above, and is similar. It has an effect. In the drawings, the same reference numerals indicate the same or corresponding parts.

If the prepreg mica tape 22 is wound around a portion of the low resistance corona shield layer 7 located outside the stator core slot 2 that is not overlapped (exposed) with the high resistance corona shield layer 9 as shown in FIG. it is possible to suppress the generation of generating ozone and NO _x of the surface discharge.
That is, when the prepreg mica tape 22 is wound around the outer periphery of the low resistance corona shield layer 7, partial discharge occurs in the gap 12 formed due to resin leakage or resin curing shrinkage below the low resistance corona shield layer 7. even if the resistance corona shielding layer 7 is lost, not the surface discharge in the air because there is a layer of the prepreg mica tape 22 on its outer periphery, thus the generation of ozone and NO _x is prevented. Since mica is excellent in partial discharge resistance, the occurrence of surface discharge can be suppressed over a long period of time.

  As the prepreg mica tape 22, a mica tape impregnated with a resin and applied to a semi-cured state is cut into a tape shape.

  As described above, according to the fourth embodiment, since the prepreg mica tape 22 is a material having excellent partial discharge resistance, it does not lead to surface discharge in the air, and good insulation characteristics can be obtained over a long period of time. Moreover, generation | occurrence | production of ozone and nitric acid can also be suppressed.

(4A) According to the fourth embodiment of the present invention, the coil conductor is formed of an insulation-coated wire bundle that is housed in the iron core slot 2 provided in the stator iron core 1 and whose end extends to the outside of the iron core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. And a corona shield layer comprising a low resistance corona shield layer 7 extending from an end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2, and the low resistance located outside the slot. A stator coil is formed by winding a prepreg mica tape 22 as a protective layer against surface discharge around the outer periphery of the corona shield layer composed of the corona shield layer 7. It is used as an air-cooled rotating machine with a rated voltage of 11 kV or more, equipped with an all-impregnated stator coil manufactured by housing the stator coil in the core slot 2 and connecting it, and then vacuum-impregnating the thermosetting resin. Therefore, a discharge is generated in the gap 12 near the interface between the corona shield layer formed of the low-resistance corona shield layer 7 and the ground main insulating layer 4 formed around the coil conductor 10, and the low Even when the corona shield layer made of the resistance corona shield layer 7 is eroded, the prepreg mica tape 22 wound around the outer periphery of the corona shield layer made of the low resistance corona shield layer 7 does not cause surface discharge in the air. A highly reliable rotating electrical machine configured as described above can be provided.

(4B) According to the fourth embodiment of the present invention, the coil conductor is formed of an insulation-coated wire bundle that is housed in the core slot 2 provided in the stator core 1 and whose end extends to the outside of the core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A first corona shield layer comprising a low resistance corona shield layer 7 extending from the end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2, and comprising the low resistance corona shield layer 7. A part of 10 to 20 mm is overlapped on the outer end of the first corona shield layer and is formed of a higher resistance member than the first corona shield layer member made of the low resistance corona shield layer 7. A second corona shield layer composed of a high resistance corona shield layer 9 for preventing creeping discharge, and surface discharge on the outer periphery of the first corona shield layer composed of the low resistance corona shield layer 7 located outside the slot. A prepreg mica tape 22 is wound as a protective layer to form a stator coil, and the stator coil is housed and connected in an iron core slot 2 provided in the stator iron core 1 and then vacuum-impregnated with a thermosetting resin. Since the rotating electrical machine is provided as an air-cooling type rotating machine having a rated voltage of 11 kV or more and has a fully impregnated stator coil to be manufactured, the first corona shield layer and coil comprising the low-resistance corona shield layer 7 are used. A discharge is generated in the gap 12 near the interface with the ground-main insulating layer 4 formed around the conductor 10, and the first consisting of the low-resistance corona shield layer 7. Even when the corona shield layer is eroded, the prepreg mica tape 22 wound around the outer periphery of the first corona shield layer made of the low-resistance corona shield layer 7 is configured not to generate surface discharge in the air. A highly reliable rotating electrical machine can be provided.

Embodiment 5 FIG.
Embodiment 5 according to the present invention will be described with reference to FIG. FIG. 7 is a cross-sectional view schematically showing a main configuration of the stator coil of the rotating electrical machine according to the fifth embodiment.
In the fifth embodiment, the configuration other than the specific configuration described here has the same configuration contents as the configuration in any of the first to fourth embodiments described above, and is similar. It has an effect. In the drawings, the same reference numerals indicate the same or corresponding parts.

As shown in FIG. 7, when a prepreg high resistance tape 23 having voltage nonlinear resistance characteristics is wound around the outer periphery of the low resistance corona shield layer 7 located outside the stator core slot 2, the occurrence of surface discharge and ozone the production of and NO _x can be suppressed.
That is, when the prepreg high resistance tape 23 having this voltage nonlinear resistance characteristic is wound around the outer periphery of the low resistance corona shield layer 7, voids formed due to resin leakage or resin curing shrinkage below the low resistance corona shield layer 7. Even if a partial discharge occurs at 12 and the low-resistance corona shield layer 7 disappears locally, there is a layer of the prepreg high-resistance tape 23 on the outer periphery, so that it does not become the surface in the air, so ozone or NO _x Is also prevented. The prepreg high resistance tape 23 having the voltage non-linear resistance characteristic reduces the electric field at the discharge tip due to the voltage non-linearity, and thus greatly reduces the erosion rate due to the discharge of the prepreg high resistance tape 23 as compared with a general polymer material. Therefore, the life is long, and as a result, the occurrence of surface discharge can be suppressed over a long period of time.

The prepreg high resistance tape 23 having voltage non-linear resistance characteristics is a prepreg high resistance tape material for forming the high resistance corona shield layer 9 (for example, Semi-Conductive_Corona_Protection_Tapes (217.21, 217.22) from ISOLA, AKASIC_4b from KREMPLEL, etc.) ) Can be applied as is. Normally, the prepreg high-resistance tape 23 having this voltage nonlinear resistance characteristic is placed 10 to 20 mm overlapped with the low-resistance corona shield layer 7. In this fifth embodiment, the stator core exceeds the overlap of 10 to 20 mm. It is installed on the entire outer periphery of the low resistance corona shield layer 7 up to one end.
Since the same tape material as the original high-resistance corona shield layer 9 can be used as the prepreg high-resistance tape 23, it is continuously formed by slightly widening the range in which the high-resistance corona shield layer 9 is installed. The required effect can be obtained with a slight process increase.

  A high-resistance paint can also be used as the high-resistance corona shield layer 9. In this case, the prepreg high resistance tape 23 is used as the low resistance corona shield layer 7 and the high resistance paint is used as the high resistance corona shield layer 9. Also in this case, the same effect as when a prepreg high resistance tape is used as the high resistance corona shield layer 9 can be obtained.

  As described above, according to the fifth embodiment, the prepreg high resistance tape 23 having the voltage nonlinear resistance characteristic reduces the electric field at the discharge tip due to the voltage nonlinearity, and therefore the erosion speed of the prepreg high resistance tape 23 is generally reduced. Compared with the above polymer material, the lifetime is significantly reduced, so that the lifetime is increased, and as a result, the occurrence of surface discharge can be suppressed over a long period of time.

(5A) According to the fifth embodiment of the present invention, the coil conductor is formed of an insulation-coated wire bundle that is housed in the core slot 2 provided in the stator core 1 and whose end extends to the outside of the core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. And a corona shield layer comprising a low resistance corona shield layer 7 extending from an end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2, and the low resistance located outside the slot. A prepreg high-resistance tape 23 for electric field relaxation having voltage nonlinear resistance characteristics is wound around the outer periphery of the corona shield layer made of the corona shield layer 7 as the protective layer against surface discharge. The stator coil is configured by forming a stator coil, and the stator coil is housed in the core slot 2 provided in the stator core 1 and connected and then vacuum impregnated with a thermosetting resin. And a corona shield layer formed of the low-resistance corona shield layer 7 and a ground insulating layer formed around the coil conductor 10. Even if a discharge is generated in the gap 12 near the interface with 4 and the corona shield layer composed of the low resistance corona shield layer 7 is eroded to reach the discharge, the electric field at the tip of the discharge is reduced due to the voltage nonlinearity. The voltage wound around the outer periphery of the corona shield layer comprising the low resistance corona shield layer 7 so as not to cause surface discharge in the air in order to reduce the erosion rate due to the discharge. The electric field relaxation for the prepreg high resistance tape 23 having a linear resistance characteristic, can be surface discharge in air to provide a structure and reliable rotary electric machine so as not to generate.

(5B) According to the fifth embodiment of the present invention, the coil conductor is formed of an insulated sheathed wire bundle that is housed in the core slot 2 provided in the stator core 1 and whose end extends to the outside of the core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A first corona shield layer comprising a low resistance corona shield layer 7 extending from the end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2, and comprising the low resistance corona shield layer 7. Voltage non-prevention that prevents a creeping discharge formed with a high resistance member than the first corona shield layer member made of the low resistance corona shield layer 7 provided at the outer end of the first corona shield layer. A second corona shield layer composed of a high resistance corona shield layer 9 formed of a prepreg high resistance tape for electric field relaxation having a shape resistance characteristic, and comprising the low resistance corona shield layer 7 located outside the slot. A prepreg high-resistance tape 23 for electric field relaxation having voltage nonlinear resistance characteristics as the protective layer against surface discharge on the outer periphery of the first corona shield layer is formed of a high-resistance corona shield layer 9 formed of the prepreg high-resistance tape. A stator coil is formed by winding continuously around the corona shield layer of No. 2, and the stator coil is housed and connected in an iron core slot 2 provided in the stator iron core 1 and then vacuum-impregnated with a thermosetting resin. Rotating power applied as an air-cooled rotating machine with a rated voltage of 11 kV or more, equipped with a fully impregnated stator coil Therefore, a discharge is generated in the gap 12 near the interface between the first corona shield layer made of the low-resistance corona shield layer 7 and the ground main insulating layer 4 formed around the coil conductor 10, and the low-resistance corona Even if the first corona shield layer composed of the shield layer 7 is eroded and the discharge reaches, the electric field at the tip of the discharge is reduced due to the voltage non-linearity and the erosion rate due to the discharge is reduced. It consists of the high resistance corona shield layer 9 formed of the prepreg high resistance tape for electric field relaxation having the voltage nonlinear resistance characteristic on the outer periphery of the first corona shield layer consisting of the low resistance corona shield layer 7 to prevent The prepreg high resistance tape 23 for electric field relaxation having a voltage nonlinear resistance characteristic continuously wound around the second corona shield layer is used to release the surface in air. It is possible to provide a highly reliable rotating electrical machine configured so as not to generate electricity.

(5C) According to the fifth embodiment of the present invention, the coil conductor is formed of an insulation-coated wire bundle that is housed in the iron core slot 2 provided in the stator iron core 1 and whose end extends to the outside of the iron core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A first corona shield layer comprising a low resistance corona shield layer 7 extending from the end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2, and comprising the low resistance corona shield layer 7. A part of 10 to 20 mm is overlapped on the outer end of the first corona shield layer, and the first corona shield layer 7 is composed of a higher resistance member than the first corona shield layer member. A first corona comprising a second corona shield layer comprising a high resistance corona shield layer 9 formed of a high resistance paint for preventing creeping discharge and comprising the low resistance corona shield layer 7 located outside the slot. A stator coil is formed by winding a prepreg high-resistance tape 23 for electric field relaxation having voltage nonlinear resistance characteristics as the protective layer against surface discharge on the outer periphery of the shield layer, and a stator coil is formed in the core slot 2 provided in the stator core 1. A rotating electrical machine applied as an air-cooling type rotating machine with a rated voltage of 11 kV or more, equipped with a stator coil of an all-impregnation method manufactured by vacuum impregnating a thermosetting resin after housing and connecting the stator coil. Therefore, in the vicinity of the interface between the first corona shield layer composed of the low resistance corona shield layer 7 and the ground-main insulating layer 4 formed around the coil conductor 10. Even if a discharge occurs in the gap 12 and the first corona shield layer composed of the low resistance corona shield layer 7 is eroded and reaches the discharge, the electric field at the discharge tip is reduced due to the voltage non-linearity and the erosion due to the discharge. A prepreg height for electric field relaxation having a voltage non-linear resistance characteristic wound around the outer periphery of the first corona shield layer made of the low resistance corona shield layer 7 to prevent the surface discharge in the air so as to reduce the speed. With the resistance tape 23, it is possible to provide a highly reliable rotating electrical machine configured so that surface discharge in the air does not occur.

Embodiment 6 FIG.
Embodiment 6 according to the present invention will be described with reference to FIG. FIG. 8 is a cross-sectional view schematically showing a configuration of main parts in the stator coil of the rotating electrical machine according to the sixth embodiment.
In the sixth embodiment, the configuration other than the specific configuration described here has the same configuration contents as the configuration in any of the first to fifth embodiments described above, and is similar. It has an effect. In the drawings, the same reference numerals indicate the same or corresponding parts.

As shown in FIG. 8, a high-resistance paint having a voltage nonlinear resistance characteristic in a portion of the low-resistance corona shield layer 7 located outside the stator core slot 2 that does not overlap (expose) the high-resistance corona shield layer 9. if the coating 24, it is possible to suppress the generation of the occurrence of surface discharge and ozone and NO _x.
That is, when the high-resistance paint 24 having the voltage nonlinear resistance characteristic is applied to the outer periphery of the low-resistance corona shield layer 7, the gap 12 formed due to resin leakage or resin curing shrinkage is formed below the low-resistance corona shield layer 7. even partial discharge occurs to the low-resistance corona shielding layer 7 is lost, not the surface in the air, thus generating the ozone and NO _x is prevented because of the layer of high-resistance coating 24 on its outer periphery . The high-resistance paint 24 having voltage non-linear resistance characteristics reduces the electric field at the discharge tip due to the voltage non-linearity, and therefore has a long life because the erosion rate of the high-resistance paint 24 is greatly reduced as compared with general polymer materials. As a result, generation of surface discharge can be suppressed over a long period of time.

As the high resistance paint 24 having voltage nonlinear resistance characteristics, the high resistance paint for forming the high resistance corona shield layer 9 can be applied as it is. That is, silicon carbide (SiC) powder and resin are dissolved in a solvent and stirred to form a mixture, which is applied 10 to 20 mm on the ground main insulating layer 4 and the low-resistance corona shield layer 7. Is installed in all the low-resistance corona shield layers 7 beyond the overlapping portion of 10 to 20 mm to the end of the stator core 1.
Since the same high resistance paint as that used to form the original high resistance corona shield layer 9 can be used, the high resistance corona shield layer 9 can be continuously formed by slightly widening the range in which the high resistance corona shield layer 9 is installed. Necessary effects can be obtained by increasing the number of processes.

  As described above, according to the sixth embodiment, the high-resistance paint 24 having the voltage nonlinear resistance characteristic reduces the electric field at the discharge tip due to the voltage nonlinearity. Compared with molecular materials, the lifetime is significantly reduced, resulting in a long life. As a result, the occurrence of surface discharge can be suppressed over a long period of time.

  A prepreg high resistance tape can also be used as the high resistance corona shield layer 9. In this case, a high resistance paint is used as the low resistance corona shield layer 7 and a prepreg high resistance tape is used as the high resistance corona shield layer 9. Also in this case, the same effect as when a high resistance paint is used as the high resistance corona shield layer 9 can be obtained.

(6A) According to the sixth embodiment of the present invention, the coil conductor is composed of a bundle of insulated wires that are housed in the iron core slot 2 provided in the stator iron core 1 and whose end portions extend outside the iron core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A corona shield layer comprising a low-resistance corona shield layer 7 extending from the end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2 and located outside the slot A stator coil is formed by applying a high-resistance electric field relaxation coating 24 having a voltage non-linear resistance characteristic as a protective layer against surface discharge to the outer periphery of the stator core, and an iron core provided in the stator core 1 Rotation applied as an air-cooled rotating machine with a rated voltage of 11 kV or more, equipped with a stator coil of all impregnation method that is manufactured by housing and connecting the stator coil in lot 2 and then vacuum impregnating thermosetting resin. Since it is an electric machine, a discharge is generated in the gap 12 near the interface between the corona shield layer formed of the low resistance corona shield layer 7 and the ground main insulating layer 4 formed around the coil conductor 10, and the low resistance corona shield layer is formed. Even if the corona shield layer composed of 7 is eroded and the discharge reaches, the electric field at the tip of the discharge is reduced due to the voltage non-linearity and the erosion rate due to the discharge is reduced, so that surface discharge in the air is not caused. In the air, a high resistance paint 24 for electric field relaxation having a voltage nonlinear resistance characteristic applied to the outer periphery of the corona shield layer composed of the low resistance corona shield layer 7. It is possible to provide a surface discharge is not configured to generate reliable rotary electric machine.

(6B) According to the sixth embodiment of the present invention, the coil conductor is formed of an insulated sheathed wire bundle that is housed in the core slot 2 provided in the stator core 1 and whose end extends to the outside of the core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A first corona shield layer consisting of a low resistance corona shield layer 7 extending from the end face of the stator core 1 by 25 mm or more to prevent corona discharge inside the core slot 2, from the low resistance corona shield layer 7. The first corona shield layer is formed of a part having a thickness of 10 to 20 mm overlapped with the outer end of the first corona shield layer, and the first corona shield layer 7 is made of a high resistance member. A second corona shield layer comprising a high-resistance corona shield layer 9 formed by applying a high-resistance coating 24 for electric field relaxation having a voltage nonlinear resistance characteristic for preventing creeping discharge, and is provided outside the core slot 2. High-resistance paint for electric field relaxation having voltage nonlinear resistance characteristics provided integrally with the second corona shield layer comprising the high-resistance corona shield layer 9 as a protective layer against surface discharge on the outer periphery of the first corona shield layer located 24 is applied to form a stator coil, and the stator coil is housed in an iron core slot 2 provided in the stator core 1 and connected, and then the thermosetting resin is vacuum-impregnated and manufactured. Since the rotating electrical machine is used as an air-cooled rotating machine with a rated voltage of 11 kV or more, which has a child coil, the first resistance consisting of the low-resistance corona shield layer 7 is used. Discharge occurs in the gap 12 near the interface between the Rona shield layer and the ground main insulating layer 4 formed around the coil conductor 10, and the first corona shield layer composed of the low resistance corona shield layer 7 is eroded and discharge occurs. Even if it reaches, the electric field at the tip of the discharge is reduced due to the voltage non-linearity, and the erosion rate due to the discharge is reduced. A highly reliable rotating electrical machine configured to prevent surface discharge in the air from occurring can be provided by the high-resistance coating 24 for electric field relaxation having voltage nonlinear resistance characteristics applied to the outer periphery of the corona shield layer. .

(6C) According to the sixth embodiment of the present invention, the coil conductor is composed of an insulated sheathed wire bundle that is housed in the core slot 2 provided in the stator core 1 and whose end extends to the outside of the core slot 2. 10. The ground main insulating layer 4 formed by winding the mica tape 5 many times around the coil conductor 10, and provided on the outer periphery of the ground main insulating layer 4 so as to extend from the inside of the core slot 2 to the outside. A first corona shield layer comprising a low resistance corona shield layer 7 extending from the end face of the stator core 1 by 25 mm or more to prevent corona discharge in the core slot 2, and comprising the low resistance corona shield layer 7. A prep of a member having a higher resistance than the member of the first corona shield layer formed of the low resistance corona shield layer 7 is provided by overlapping a part of 10 to 20 mm on the outer end of the first corona shield layer. A second corona shield layer comprising a high-resistance corona shield layer 9 for preventing creeping discharge formed of a high-resistance tape, and protecting against surface discharge on the outer periphery of the first corona shield layer located outside the slot A stator coil is formed by applying a high-resistance coating 24 for electric field relaxation having voltage nonlinear resistance characteristics as a layer, and the stator coil is housed and connected in an iron core slot 2 provided in the stator core 1, and then thermosetting. Since the rotary electric machine is applied as an air-cooling type rotating machine having a rated voltage of 11 kV or more, which is provided with an all-impregnation type stator coil manufactured by vacuum impregnation with a conductive resin, the first layer comprising the low resistance corona shield layer 7 is used. A discharge is generated in the gap 12 near the interface between the corona shield layer 1 and the ground main insulating layer 4 formed around the coil conductor 10, and the low resistance corona shield layer 7 Even if the first corona shield layer is eroded and the discharge reaches, the electric field at the tip of the discharge is reduced due to the voltage non-linearity and the erosion rate due to the discharge is reduced. The electric field relaxation high resistance paint 24 having voltage nonlinear resistance characteristics applied to the outer periphery of the first corona shield layer made of the low resistance corona shield layer 7 is configured to prevent surface discharge in the air from occurring. A highly reliable rotating electrical machine can be provided.

  DESCRIPTION OF SYMBOLS 1 Stator iron core, 2 Iron core slot, 3 Stator coil, 4 Main ground insulating layer, 5 Mica tape, 7 Low resistance corona shield layer, 9 High resistance corona shield layer, 10 Coil conductor (element wire bundle), 12 Air gap, 20 Conductive silicone rubber layer, 21 insulating silicone rubber layer, 22 prepreg mica tape, 23 voltage nonlinear prepreg high resistance tape, 24 voltage nonlinear high resistance paint.

Claims (2)

  A coil conductor housed in a slot provided in the iron core and having an end extending outside the slot, an insulating layer formed around the coil conductor, and extending from the inside of the slot to the outside on the outer periphery of the insulating layer A corona shield layer provided to prevent corona discharge is provided, and a prepreg mica tape is wound around the outer periphery of the corona shield layer located outside the slot as a protective layer against surface discharge so that the corona shield layer is not exposed. Rotating electric machine.   A coil conductor housed in a slot provided in the iron core and having an end extending outside the slot, an insulating layer formed around the coil conductor, and extending from the inside of the slot to the outside on the outer periphery of the insulating layer A first corona shield layer provided to prevent corona discharge, and a higher resistance than a member of the first corona shield layer provided partially overlapping the outer end of the first corona shield layer to prevent creeping discharge The first corona shield layer is formed of a prepreg mica tape as a protective layer against surface discharge on the outer periphery of the first corona shield layer located outside the slot. A rotating electric machine characterized by being wound so as not to be exposed.

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