JP2008043080A - Stator of rotating electric machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain the stator of a rotating electric machine that has a simple configuration and can reduce occurrence loss and temperature rise reliably. <P>SOLUTION: There are provided: a stator core 1 in which a magnetic plate is laminated axially and a plurality of open slots are provided inside, a stator coil 2 wound in the slot of the stator core 1, a clamper 4 made of a magnetic body for pressing the stator core 1 in the direction of lamination to clamp the stator core 1, a shield core 5 provided to the clamper 4 opposite to the side of the stator core, a shield retainer 6 for pressing and clamping the shield core 5, and a groove section 9 for eddy current suppression in which at least one portion is extended in a radial direction on the axial outer surface of the shield retainer 6. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a stator of a rotating electric machine, and more particularly to a cooling configuration thereof.

The stator of the rotating electrical machine in the prior art has a basic configuration similar to the configuration shown in FIGS. 1 and 2 showing Embodiment 1 according to the present invention.
1 and 2, a stator core 1 having a plurality of open slots obtained by laminating electromagnetic steel sheets in the axial direction, a stator coil 2 wound around a slot of the stator core 1, and an outboard shaft of the stator core 1. The finger plate 3 installed on the end surface in the direction, the clamper 4 made of magnetic metal installed on the end surface in the axial direction of the outer side of the finger plate 3 and tightening the stator core 1 via the finger plate 3, the end surface in the direction of the outer side of the clamper 4 Shield core 5 having a structure in which electromagnetic steel plates are laminated, shield retainer 6 for fixing shield core 5, and stator core 1, finger plate 3, clamper 4, shield core 5 and shield retainer 6 on the outer diameter side. Core bolt 7 to be fixed, stator core 1 as well as finger plate 3, clamper 4, shield core 5 and shield presser 6 on the inner diameter side. Through bolt is provided which is fixed. However, the eddy current suppressing groove 9 extending in the radial direction is not provided on the outer surface in the axial direction which is the machine outer side of the shield presser 6.

During operation of the rotating electrical machine, magnetic flux enters the shield presser from the rotor end (not shown) or the stator coil end 2a.
In the shield presser 6, an eddy current flows in the peripheral portion, and loss occurs. Since the magnetic flux density from the rotor end and the stator coil end 2a is higher on the inner diameter side 6a than on the outer diameter side 6b, the loss increases toward the inner diameter side 6a. The vicinity of the through bolt 8 is the maximum loss portion B.
As described above, in the prior art, a loss occurs in the peripheral edge portion of the shield retainer 6 due to the leakage magnetic flux from the rotor end portion or the stator coil end portion 2a, and the temperature rise becomes a problem.

During operation of the rotating electrical machine, the pressure of the space on the inner diameter side of the stator core becomes larger than the pressure of the space on the outer diameter side of the stator core due to rotation of the rotor (not shown).
As a conventional technique, utilizing such a phenomenon, a cooling groove is provided on the end surface on the shield core side of the conductive shield member disposed between the shield core and the clamper to cool from the inner diameter side to the outer diameter side. There is also a stator of a rotating electrical machine in which wind is flowing and the conductive shield member and the shield core are cooled (see, for example, Patent Document 1), and loss caused by leakage magnetic flux from the rotor end and stator coil end Avoiding temperature rise due to generation is a problem.

JP 2003-250234 A

  The present invention has been made to solve the above-described problems, and an object of the present invention is to obtain a stator for a rotating electrical machine that has a simple configuration and can reliably reduce generation loss and temperature rise.

  In the stator of the rotating electrical machine according to the present invention, a stator core in which magnetic plates are laminated in the axial direction, a stator coil wound around the stator core, and a magnetic body that presses the stator core in the axial direction. A clamp core formed on the anti-stator core side of the clamper, and a shield presser that presses the shield core toward the clamper side, and extends radially on the outer surface in the axial direction of the shield presser. An existing groove is provided.

  According to the present invention, it is possible to obtain a stator of a rotating electrical machine that has a simple configuration and can reliably reduce generation loss and temperature rise.

Embodiment 1 FIG.
A first embodiment of the present invention will be described with reference to FIGS. 1 is a longitudinal sectional view showing a configuration of a stator of a rotating electrical machine according to Embodiment 1. FIG. FIG. 2 is an end view of the shield presser according to the first embodiment as viewed from the direction II on the outside of the machine.

  In FIG. 1, a stator core 1 having a plurality of open slots obtained by laminating electromagnetic steel sheets in the axial direction, a stator coil 2 wound around the slots of the stator core 1, and an outboard axial end surface of the stator core 1. The installed finger plate 3, the clamper 4 made of a magnetic metal that is installed on the end surface in the axial direction of the outer side of the finger plate 3 and clamps the stator core 1 via the finger plate 3, and is installed on the end surface in the axial direction of the outer side of the clamper 4. A shield core 5 having a structure in which electromagnetic steel plates are laminated, a shield retainer 6 that presses the shield core 5 in the laminating direction and fastens and fixes the shield core 5, a stator core 1 on the outer diameter side, a finger plate 3, a clamper 4, and a shield core 5 and the core bolt 7 that penetrates and fixes the shield presser 6, the stator core 1 on the inner diameter side, the finger plate 3, the clamper 4, the seal Core 5 and through bolt 8 of the shield pressing 6 through and fixed is provided. The shield retainer 6 is provided with an eddy current suppressing groove 9 on the outer surface in the axial direction which is the outside of the machine.

  In FIG. 2, the shield presser 6 is formed with a through hole 7 a through which the core bolt 7 is inserted and a through hole 8 a through which the through bolt 8 is inserted. A plurality of eddy current suppression grooves 9 extending in the radial direction and formed at predetermined intervals in the circumferential direction are provided on the outer surface in the axial direction, which is the machine outer side of the shield presser 6.

Next, the operation will be described.
In FIG. 1 and FIG. 2, when the magnetic flux that has entered from the rotor end or the stator coil end 2a attempts to enter the shield presser 6, an eddy current that cancels this flows mainly to the peripheral edge of the shield presser 6, A loss occurs in the shield presser 6. An arrow A in FIG. 2 indicates an eddy current flow path.

By providing the eddy current suppressing groove 9 on the outer surface of the shield retainer 6 as shown in FIG. 2, the resistance to the flow of eddy current in the shield retainer 6 can be increased. The loss caused by the shield retainer 6 has a resistance limit characteristic and is inversely proportional to the resistance to the eddy current flow in the shield retainer 6. Therefore, the loss generated by the shield retainer 6 can be reduced.
On the other hand, by providing the eddy current suppressing groove 9, the cooling area can be increased, and the shield retainer 6 can be effectively cooled by the cooling air flowing from the inner diameter side 6 a to the outer diameter side 6 b of the outer surface of the shield retainer 6.

  During operation of the rotating electrical machine, the pressure in the space near the inner diameter side 1a of the stator core 1 is higher than the space near the outer diameter side 1b due to the rotation of the rotor. 6 flows from the inner diameter side 6a of the outer surface of the machine 6 to the outer diameter side 6b through the eddy current suppression groove 9 to cool the outer surface of the shield presser 6 including the maximum loss portion B, that is, the axial outer surface.

  In the first embodiment, the shield presser 6 can be reliably cooled by effectively utilizing the cooling area increased by the formation of the eddy current suppressing groove 9 as described above.

(1A) According to Embodiment 1 of the present invention, a stator core 1 having a plurality of magnetic slots stacked in the axial direction and having a plurality of open slots therein, and a fixed coil wound in the slots of the stator core 1 A core coil 2, a clamper 4 made of a magnetic material that presses the stator core 1 in the stacking direction and fastens the stator core 1, and a shield core 5 disposed on the side opposite to the stator core of the clamper 4; Since the shield presser 6 that presses the shield core 5 and fastens the shield core is provided, and the eddy current suppression groove 9 that extends at least partially in the radial direction is provided on the outer surface of the shield presser 6 in the axial direction. The shield retainer 6 is effectively cooled by the eddy current suppressing groove 9 provided at least partially extending in the radial direction on the outer surface in the axial direction of the shaft 6. It can be obtained stator of a rotary electric machine which can reliably reduce loss and temperature rise.

Embodiment 2. FIG.
A second embodiment of the present invention will be described with reference to FIG. FIG. 3 is an end view of the shield presser according to the second embodiment as viewed from the outside in the axial direction on the outside of the machine.
In the second embodiment, the configuration other than the specific configuration described here has the same configuration as the configuration in the first embodiment described above, and performs the same function. In the drawings, the same reference numerals indicate the same or corresponding parts.

  In FIG. 3, the shield retainer 6 is formed with a through hole 7 a through which the core bolt 7 is inserted and a through hole 8 a through which the through bolt 8 is inserted. Radial eddy current suppression grooves 10 are provided on the outer surface in the axial direction, which is the outer surface of the shield presser 6. The eddy current suppression grooves 10 are formed radially about the central portion C on the outer surface in the axial direction of the shield presser 6 and are arranged so as to be substantially perpendicular to the flow path B of the eddy current flowing through the shield presser 6. .

  In the second embodiment, the eddy current suppressing groove 10 is arranged substantially perpendicular to the flow of eddy current, so that the resistance to the eddy current flowing inside the shield presser 6 is more effective than that of the first embodiment. Therefore, the loss can be further reduced as compared with the first embodiment.

(2A) According to the second embodiment of the present invention, the eddy current suppressing groove portion 10 is replaced with the eddy current suppressing groove portion 9 (see FIG. 2) instead of the eddy current suppressing groove portion 9 (see FIG. 2). The shield retainer 6 is radially extended from the axial outer surface, which is the outer surface of the shield retainer 6, with the central portion C in the axial outer surface, which is the outer surface of the shield retainer 6, as the center. By effectively increasing the resistance to the eddy current flowing inside the shield presser 6 by the eddy current suppressing groove portion 10 extending radially on the outer surface in the axial direction, it has a simple structure, and the generated loss and It is possible to obtain a stator of a rotating electrical machine that can reliably reduce temperature rise and that can more effectively suppress eddy currents.

Embodiment 3 FIG.
A third embodiment of the present invention will be described with reference to FIGS. FIG. 4 is a longitudinal sectional view showing the configuration of the stator of the rotating electric machine according to the third embodiment, and FIG. 5 is an end view of the shield presser according to the third embodiment when viewed from the V direction outside the machine in FIG.
In the third embodiment, the configuration other than the specific configuration described here has the same configuration as the configuration in the first embodiment or the second embodiment described above, and performs the same function. is there. In the drawings, the same reference numerals indicate the same or corresponding parts.

  In FIG. 4, a stator core 1 having a plurality of open slots obtained by laminating electromagnetic steel sheets in the axial direction, a stator coil 2 wound around the slots of the stator core 1, and an outboard axial end surface of the stator core 1. The installed finger plate 3, the clamper 4 made of a magnetic metal that is installed on the end surface in the axial direction of the outer side of the finger plate 3 and clamps the stator core 1 via the finger plate 3, and is installed on the end surface in the axial direction of the outer side of the clamper 4. A shield core 5 having a structure in which electromagnetic steel plates are laminated, a shield retainer 6 that presses the shield core 5 in the laminating direction and fastens and fixes the shield core 5, a stator core 1 on the outer diameter side, a finger plate 3, a clamper 4, and a shield core 5 and the core bolt 7 that penetrates and fixes the shield presser 6, the stator core 1 on the inner diameter side, the finger plate 3, the clamper 4, the seal Core 5 and through bolt 8 of the shield pressing 6 through and fixed is provided. The shield retainer 6 is provided with an eddy current suppressing groove 11 on the inner surface in the axial direction, which is the surface inside the machine.

  In FIG. 5, the shield presser 6 is formed with a through hole 7 a through which the core bolt 7 is inserted and a through hole 8 a through which the through bolt 8 is inserted. An eddy current suppressing groove 11 is provided on the inner surface in the axial direction, which is the inner surface of the shield presser 6. The eddy current suppression groove 11 is formed by a radial groove 11a and circumferential grooves 11b and 11b. The end portions 11c and 11c of the circumferential groove portions 11b and 11b open to the circumferential side surface 6c of the shield retainer 6, respectively. The radial groove portion 11 a and the circumferential groove portions 11 b and 11 b of the eddy current suppressing groove portion 11 communicate with each other at the central portion C on the inner surface in the axial direction of the shield retainer 6.

  As shown in FIG. 4, a ventilation space portion 13 is provided between the clamper 4 and the shield core 5, and a ventilation hole portion 14 is provided in the clamper 4. The eddy current suppressing groove portion 11 passes through the circumferential groove portions 11b and 11b and the radial groove portion 11a from the end portions 11c and 11c of the circumferential groove portions 11b and 11b through the axial inner surface central portion C of the shield presser 6 and the ventilation space. A ventilation path VP is formed through the part 13 and the ventilation hole part 14.

During operation of the rotary electric machine, the space in the vicinity of the inner diameter side 1a of the stator core 1 is higher than the space in the vicinity of the outer diameter side 1b due to the rotation of the rotor. From the axial inner surface of the shield presser 6 through the ventilation path VP formed so as to pass through the ventilation space portion 13 and the ventilation hole portion 14 from the eddy current suppressing groove portion 11 provided on the inner surface of the stator. Cooling air flows into the space near the radial side 1b.
From the end portions 11c, 11c of the circumferential groove portions 11b, 11b provided on the inner surface in the axial direction of the shield retainer 6 so as to open to the circumferential side surface 6c of the shield retainer 6 through the radial groove portion 11a, the ventilation space 13 and the ventilation holes The inner surface in the axial direction of the shield presser 6 is cooled by the cooling air flowing through the ventilation path VP formed in the space near the outer diameter side 1b of the stator core 1 via the portion 14.

  In the third embodiment, the shield retainer 6 is formed by the cooling air flowing through the ventilation path VP formed from the inner surface in the axial direction of the shield retainer 6 to the space near the outer diameter side 1b of the stator core 1 according to the first embodiment. And it can cool more efficiently than Embodiment 2.

(3A) According to the third embodiment of the present invention, a stator core 1 having magnetic plates stacked in the axial direction and having a plurality of open slots therein, and a fixed wound around the slots of the stator core 1 The stator coil 2, the clamper 4 made of a magnetic body that presses the stator core 1 in the laminating direction of the magnetic plates and fastens the stator core 1, and the shield core disposed on the anti-stator core side of the clamper 4 5 and a shield presser 6 that presses the shield core 5 in the laminating direction and fastens the shield core, and at least a portion of the shield presser 6 extends radially in the axial inner surface of the shield presser 11. And the ventilation path VP communicating with the space in the vicinity of the outer diameter side 1b of the stator core 1 from the axial inner surface of the shield presser 6 is formed. A rotating electrical machine that can be reliably reduced and that can effectively cool the shield retainer 6 by the ventilation path VP communicating from the inner surface in the axial direction of the shield retainer 6 to the space near the outer diameter side 1b of the stator core 1. A stator can be obtained.

Embodiment 4 FIG.
A fourth embodiment of the present invention will be described with reference to FIGS. FIG. 6 is a longitudinal sectional view showing the configuration of the stator of the rotating electrical machine in the fourth embodiment. FIG. 7 is an end view of the shield presser according to the fourth embodiment as viewed from the VII direction on the outside of the machine in FIG.
In the fourth embodiment, the configuration other than the specific configuration described here has the same configuration as that in any of the first to third embodiments described above, and has the same function. It is something to do. In the drawings, the same reference numerals indicate the same or corresponding parts.

  In FIG. 6, a stator core 1 having a plurality of open slots obtained by laminating electromagnetic steel sheets in the axial direction, a stator coil 2 wound around the slots of the stator core 1, and an outboard axial end surface of the stator core 1. The installed finger plate 3, the clamper 4 made of a magnetic metal that is installed on the end surface in the axial direction of the outer side of the finger plate 3 and clamps the stator core 1 via the finger plate 3, and is installed on the end surface in the axial direction of the outer side of the clamper 4. A shield core 5 having a structure in which electromagnetic steel plates are laminated, a shield retainer 6 that presses the shield core 5 in the laminating direction and fastens and fixes the shield core 5, a stator core 1 on the outer diameter side, a finger plate 3, a clamper 4, and a shield core 5 and the core bolt 7 that penetrates and fixes the shield presser 6, the stator core 1 on the inner diameter side, the finger plate 3, the clamper 4, the seal Core 5 and through bolt 8 of the shield pressing 6 through and fixed is provided. The shield retainer 6 is provided with an eddy current suppressing groove 15 on the inner surface in the axial direction which is the inner surface of the machine.

  In FIG. 7, the shield presser 6 is formed with a through hole 7 a through which the core bolt 7 is inserted and a through hole 8 a through which the through bolt 8 is inserted. An eddy current suppressing groove 15 is provided on the inner surface in the axial direction, which is the inner surface of the shield presser 6. The eddy current suppressing groove 15 includes a radial groove portion 15a extending radially from the central portion C on the inner surface in the axial direction that is the inner surface of the shield presser 6 and an axial direction that is the inner surface of the shield presser 6. Formed by branch groove portions 15b, 15b extending from the central portion C on the inner surface toward the vicinity of the inner diameter portion 6a of the shield retainer 6 that is near the maximum loss portion B of the shield retainer 6. ing.

  And as shown in FIG. 6, the ventilation space part 13 and the clamper 4 of the branching groove part 15b in the eddy current suppression groove part 15b from the edge part 15c of the 15b, 15c via the branching groove part 15b, 15b and the radial direction groove part 15a. A ventilation path VP is provided between the ventilation hole portions 14 to ventilate the shield retainer 6 from the inner diameter side 6 a to the outer diameter side 1 b of the stator core 1.

  During the operation of the rotating electrical machine, the space on the inner diameter side 1a of the stator core 1 is higher than the space on the outer diameter side 1b due to the rotation of the rotor. 6a from the end portions 15c, 15c of the branch groove portions 15b, 15b in the eddy current suppressing groove portion 15 provided in the maximum loss portion B near the peripheral surface of the peripheral surface in 6a through the branch groove portions 15b, 15b and the radial groove portion 15a. The cooling air flows through the ventilation path VP formed between the ventilation holes 13 of the clamper 4 and the clamper 4.

  The end portions 15c and 15c of the branch groove portions 15b and 15b in the eddy current suppressing groove 15 are adjacent to the peripheral surface of the inner diameter portion 6a in the shield retainer 6, and in the vicinity of the peripheral surface of the inner diameter portion 6a in the shield retainer 6, that is, the shield retainer. 6 by the cooling air flowing through the ventilation path VP that passes through the vicinity of the maximum loss portion B in FIG. 6 and reaches the ventilation space portion 13 and the ventilation hole portion 14 via the branch groove portions 15b and 15b of the eddy current suppression groove 15 and the radial groove portion 15a. Then, the air is passed near the maximum loss portion of the shield retainer 6 in the vicinity of the inner diameter portion 6 a of the shield retainer 6, and the vicinity of the maximum loss portion B of the shield retainer 6 is cooled.

  In the fourth embodiment, the vicinity of the maximum loss portion B of the shield presser 6, that is, the vicinity of the maximum temperature portion, can be reliably cooled by the cooling air flowing through the ventilation path VP, and the shield presser 6 can be cooled from the first embodiment to the first embodiment. Cools more efficiently than 3.

(4A) According to the fourth embodiment of the present invention, in the configuration according to the item (3A) of the third embodiment, instead of the eddy current suppressing groove 11 (see FIG. 5), the axial direction of the shield retainer 6 The eddy current suppression groove 15 provided on the inner surface forms the ventilation path VP for ventilating from the inner diameter side 6a of the shield retainer 6 to the outer diameter side 1b of the stator core 1, and thus has a simple configuration. At the same time, the generated loss and the temperature rise can be reliably reduced, and the shield retainer 6 is cooled by the ventilation path VP for ventilating the space from the inner diameter side 6a of the shield retainer 6 to the space near the outer diameter side 1b of the stator core 1. Thus, a stator of a rotating electric machine that can efficiently perform the above can be obtained.

Embodiment 5. FIG.
A fifth embodiment of the present invention will be described with reference to FIGS. FIG. 8 is a longitudinal sectional view showing the configuration of the stator of the rotating electrical machine in the fifth embodiment. FIG. 9 is an end view of the shield presser according to the fifth embodiment when viewed from the IX direction on the outside of the machine in FIG.
In the fifth embodiment, the configuration other than the specific configuration described here has the same configuration as the configuration in any of the first to fourth embodiments described above, and has the same function. It is something to do. In the drawings, the same reference numerals indicate the same or corresponding parts.

  In FIG. 8, a stator core 1 having a plurality of open slots obtained by laminating electromagnetic steel sheets in the axial direction, a stator coil 2 wound around the slots of the stator core 1, and an outboard axial end surface of the stator core 1. The installed finger plate 3, the clamper 4 made of a magnetic metal that is installed on the end surface in the axial direction of the outer side of the finger plate 3 and clamps the stator core 1 via the finger plate 3, and is installed on the end surface in the axial direction of the outer side of the clamper 4. A shield core 5 having a structure in which electromagnetic steel plates are laminated, a shield retainer 6 that presses the shield core 5 in the laminating direction and fastens and fixes the shield core 5, a stator core 1 on the outer diameter side, a finger plate 3, a clamper 4, and a shield core 5 and the core bolt 7 that penetrates and fixes the shield presser 6, the stator core 1 on the inner diameter side, the finger plate 3, the clamper 4, the seal Core 5 and through bolt 8 of the shield pressing 6 through and fixed is provided. The through bolt 8 is inserted into a through hole 8 a provided in the shield core 5 and the shield presser 6. The inner peripheral surface of the through hole 8 a provided in the shield core 5 and the shield retainer 6 has a gap between the outer peripheral surface of the through bolt 8. The shield retainer 6 is provided with a slit 17 formed from the inner peripheral surface of the inner diameter portion 6 a of the shield retainer 6 to the through hole 8 a of the through bolt 8.

  In FIG. 9, the shield retainer 6 has a through hole that has a through hole 7 a through which the core bolt 7 is inserted and an inner peripheral surface that forms a gap between the outer surface of the through bolt 8 and through which the through bolt 8 is inserted. 8a is formed. The shield retainer 6 is provided with a slit 17 formed from the inner peripheral surface of the inner diameter portion 6 a of the shield retainer 6 to the through hole 8 a of the through bolt 8.

As shown in FIG. 8, a ventilation space portion 13 is provided between the clamper 4 and the shield core 5, and a ventilation hole portion 14 is provided in the clamper 4. The shield core 5 is provided with a duct 18 extending in the radial direction.
A ventilation path VP communicating from the slit 17 to the ventilation space 13 and the ventilation hole 14 via the through hole 8a of the through bolt 8 and the duct 18 is formed.
Further, a ventilation path CP is formed which communicates from the inner diameter side 5 a of the shield core 5 to the ventilation space portion 13 and the ventilation hole portion 14 via the duct 18.

  In the shield presser 6, the flow path A of the eddy current flowing through the shield presser 6 becomes longer and the resistance against the flow of the eddy current increases as shown in FIG. 9 due to the slit 17, so that the inner diameter portion 6 a serving as the maximum loss portion B is increased. Loss is reduced.

During operation of the rotating electrical machine, the pressure on the inner diameter side 1a of the stator core 1 is higher than that on the outer diameter side 1b due to the rotation of the rotor. It flows through the ventilation path VP between the slit 17 and the ventilation hole portion 14 of the clamper 4 via the through hole 8a, the duct 18 and the ventilation space portion 13. The maximum loss B of the shield presser 6 and the shield core 5 can be cooled by the cooling air flowing through the ventilation path VP.
Similarly, since there is a pressure difference between the inner diameter side 5 a of the shield core 5 in which the duct 18 is formed and the ventilation hole portion 14 of the clamper 4, the inner diameter side 5 a of the shield core 5 passes through the ventilation space portion 13. The ventilation path CP is formed between the duct 18 and the ventilation hole 14 of the clamper 4 so that the cooling air flows. The shield core 5 can be reliably cooled by the cooling air flowing through the ventilation path CP.

  In the fifth embodiment, the slit 17 extending from the circumferential surface on the inner diameter side 6a of the shield retainer 6 to the through hole 8a of the through bolt 8 is provided to reduce the loss in the shield retainer 6, and the slit 17 to the through bolt 8 By forming the ventilation path VP communicating with the outer diameter side 1b of the stator core 1 through the through hole 8a, the shield presser 6 and the shield core 5 can be efficiently cooled, and the duct 18 provided in the shield core 5 is provided. Thus, the shield core 5 can be reliably cooled from the inner diameter side 5a of the shield core 5 by the ventilation path CP, so that the loss can be effectively reduced and the cooling can be efficiently performed as compared with the first to fourth embodiments.

(5A) According to Embodiment 5 of the present invention, a stator core 1 having a plurality of magnetic slots stacked in the axial direction and having a plurality of open slots therein, and a fixed coil wound in the slots of the stator core 1 The stator coil 2, the clamper 4 made of a magnetic body that presses the stator core 1 in the laminating direction of the magnetic plates and fastens the stator core 1, and the shield core disposed on the anti-stator core side of the clamper 4 5, a shield presser 6 that presses the shield core 5 in the laminating direction and fastens the shield core 5, and a through bolt 8 that is inserted into a through hole 8 a provided in the shield core 5 and the shield presser 6. A slit 17 formed from the peripheral surface of the inner diameter side 6a of the shield retainer 6 to the through hole 8a of the through bolt 8 is provided. A ventilation path VP that communicates with the space near the outer diameter side 1b of the stator core 1 through the duct 18 provided in the shield core 5 through the through hole 8a is formed, and the inner diameter side 5a of the shield core 5 is formed. Since the ventilation path CP communicating with the ventilation space portion 13 and the ventilation hole portion 14 via the duct 18 is formed, the structure has a simple structure, and the generated loss and the temperature rise can be surely reduced, and the shield presser 6 Of the stator core 1 through a slit 17 extending from the inner peripheral surface of the through bolt 8 to the through hole 8a of the through bolt 8 and a duct 18 provided in the shield core 5 through the through hole 8a of the through bolt 8. The ventilation path VP communicates with the outer diameter side 1b and the ventilation path CP communicates with the ventilation space portion 13 and the ventilation hole portion 14 via the duct 18 from the inner diameter side 5a of the shield core 5. It can be obtained stator of a rotary electric machine capable of performing cooling of the shield retainer 6 and the shield core 5 effectively.

It is a longitudinal cross-sectional view which shows the structure of the stator of the rotary electric machine in Embodiment 1 by this invention. FIG. 2 is an end view of the shield presser according to the first embodiment of the present invention as viewed from the direction II on the outside of the machine in FIG. 1. It is the end elevation which looked at the shield presser in Embodiment 2 by this invention from the axial direction outer side of the machine outside. It is a longitudinal cross-sectional view which shows the structure of the stator of the rotary electric machine in Embodiment 3 by this invention. It is the end elevation which looked at the shield presser in Embodiment 3 by this invention from the V direction of the machine outer side in FIG. It is a longitudinal cross-sectional view which shows the structure of the stator of the rotary electric machine in Embodiment 4 by this invention. FIG. 7 is an end view of a shield presser according to a fourth embodiment of the present invention as viewed from the VII direction on the outside of the machine in FIG. 6. It is a longitudinal cross-sectional view which shows the structure of the stator of the rotary electric machine in Embodiment 5 by this invention. FIG. 9 is an end view of a shield presser according to a fifth embodiment of the present invention as viewed from the IX direction on the outside of the machine in FIG. 8.

Explanation of symbols

1 Stator Core, 2 Stator Coil, 3 Finger Plate, 4 Clamper, 5 Shield Core, 6 Shield Presser, 7 Core Bolt, 8 Through Bolt, 9, 10, 11 Eddy Current Suppression Groove, 13 Ventilation Space, 14 Air hole part, 15 Eddy current suppression groove part, 17 slit, 18 duct.

Claims (5)

  A stator core in which magnetic plates are laminated in the axial direction, a stator coil wound around the stator core, a clamper made of a magnetic body that presses the stator core in the axial direction, and an anti-stator of the clamper A shield core disposed on the core side and a shield presser that presses the shield core toward the clamper side, and a groove portion that extends in the radial direction is provided on an axially outer surface of the shield presser. Stator for rotating electric machine.   The stator of a rotating electrical machine according to claim 1, wherein the groove portion extends radially centering on a central portion of the shield presser.   A stator core in which magnetic plates are laminated in the axial direction, a stator coil wound around the stator core, a clamper made of a magnetic body that presses the stator core in the axial direction, and an anti-stator of the clamper A shield core disposed on the core side; and a shield presser that presses the shield core toward the clamper side, a groove portion extending in a radial direction is provided on an inner surface in the axial direction of the shield presser, and the groove portion is provided on the clamper. A stator of a rotating electrical machine, wherein a ventilation path communicating with the outer diameter side of the stator core is formed.   Ventilation from the inner diameter side of the shield presser through the groove portion to the outer diameter side of the stator core through the ventilation space portion provided on the outer diameter side of the shield core and the ventilation hole portion provided in the clamper. The stator for a rotating electrical machine according to claim 3, wherein a ventilation path is formed. A stator core in which magnetic plates are laminated in the axial direction, a stator coil wound around the stator core, a clamper made of a magnetic body that presses the stator core in the axial direction, and an anti-stator of the clamper A shield core disposed on the core side; a shield presser that presses the shield core toward the clamper; and a bolt that is inserted into a through hole provided in the shield core and the shield presser, the shield presser A slit formed from a peripheral surface on the inner diameter side to the through hole of the bolt is provided, and a duct formed to extend in the radial direction is provided in the shield core, from the slit through the through hole of the bolt. A stator for a rotating electrical machine, wherein an air passage that communicates with the outer diameter side of the stator core through the duct is formed.

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