JP2005051998A - Stator of capacitor motor and its manufacturing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a stator of a capacitor motor capable of simplifying a construction section of a coil winding machine, and simplifying processing of a connecting wire in combining main winding mandrels with auxiliary winding mandrels, and to provide its manufacturing method. <P>SOLUTION: The construction thereof is such that insulating objects 8A, 8B fitted to the split iron-core elements 7 of a stator iron-core has widely extended parts 8A-1, 8B-1 at a part in the peripheral direction, and the extended parts 8A-1, 8B-1 are provided with a holding mechanism 8A-2 or 8B-2 holding the connecting wire 9A or 9B of the main winding 10 or the auxiliary winding 12. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a stator for a capacitor motor using a divided iron core plate in which a yoke portion and a tooth portion are connected and divided into the same number as the number of slots, and a method for manufacturing the same.

2. Description of the Related Art In recent years, a stator formed by winding a plurality of divided iron core plates and arranging the divided iron core plates in an annular shape and a manufacturing method thereof are known (for example, see Patent Document 1).

  Hereinafter, the configuration and the manufacturing method will be described with reference to FIGS.

As shown in FIGS. 13, 14, and 15, the main winding 101 has the connecting wire 104 </ b> A on the main connecting wire side after the insulator 103 is attached to each of the divided iron cores 102 of several poles held in an annular shape. After winding the insulator 103 on each of the divided iron cores 102, the auxiliary winding 106 is also held in an annular shape. The auxiliary winding wound body 107 is formed by being continuously wound through the connecting wire 104B on the auxiliary connecting wire side, and the main winding wound body 105 and the auxiliary winding wound body 106 are moved in the axial direction. The assembled stator 108 was constructed.
JP 2000-253603 A

  In such a winding method and configuration of the conventional stator 108, the connecting wire 104A, 104B does not have a holding portion in the installed insulator 103, and therefore the connecting wire 104A, 104B is held by the structure of the winding machine. There is a problem that the structure of the winding machine becomes complicated because it is necessary to give the part its function. Further, when the main winding body 105 and the auxiliary winding body 107 are combined and integrated in the axial direction, the processing of holding the crossover wires 104A and 104B, preventing loosening, and managing the length becomes complicated. There was a problem.

  SUMMARY OF THE INVENTION The present invention solves the above-mentioned problem, and it is a capacitor that simplifies the structural part of a winding machine and simplifies the processing of crossovers when combining a main winding body and an auxiliary winding body. An object of the present invention is to provide a stator for an electric motor and a method for manufacturing the same.

  In the stator of the capacitor motor according to the present invention, a predetermined number of divided iron core plates each having a yoke portion having an arc surface on the outer periphery and a tooth portion having a rotor-facing surface on the inner surface side are laminated and fixed. A split iron core body is formed by dividing the same number as the above, and an insulating material is attached to the split iron core body, and then several poles of the main winding are continuously wound in a concentrated manner through a jumper wire. It consists of a main winding body and an auxiliary winding body in which several poles are continuously wound in a concentrated manner on the divided iron core body, with an insulator attached thereto, via a crossover wire, A main winding wound body array group in which the number of poles of the main winding winding body are annularly arranged, and an auxiliary winding winding body array group in which the number of poles of the auxiliary winding winding bodies are annularly arranged In a stator that is combined and fixed and integrated so that the main winding body and the auxiliary winding body are alternately arranged in an annular shape. A part of the insulator to be extended has an extension part greatly extended in the clockwise and counterclockwise directions in the direction of each divided iron core adjacent to each other in the circumferential direction, and the main winding or the auxiliary winding is provided in the extension part. The holding mechanism for holding the connecting wire is provided.

This means simplifies the structural part of the winding machine that winds the main and auxiliary windings directly on the split iron core body, and the jumper wire when combining the main and auxiliary winding bodies. The stator of the capacitor motor that can simplify the process is obtained.

  In the method of manufacturing a stator for a capacitor motor according to the present invention, the yoke portion having the arc surface on the outer periphery and the tooth portion having the rotor facing surface on the inner surface side are integrated and divided into the same number as the number of slots. A predetermined number of the divided iron core plates are laminated and fixed to form a divided iron core body, and an insulating material is attached to the divided iron core body, and then several poles of the main winding are continuously connected via a jumper wire in a concentrated winding. Main winding wound body that is directly wound, and auxiliary winding that is continuously wound directly by winding several poles via a jumper wire with an insulator attached to the divided iron core body A main winding wound body array group in which the number of poles of the main winding winding are arranged in a ring and an auxiliary arrangement in which the poles of the auxiliary winding winding are arranged in a ring A method of manufacturing a stator in which a winding winding body array group is combined and fixed and integrated so that the main winding winding body and the auxiliary winding winding body are alternately arranged in an annular shape A portion of the insulator attached to the divided iron core body has an extended portion that is greatly extended in the clockwise and counterclockwise directions in the directions of the divided iron core bodies adjacent to each other in the circumferential direction. This is a method of manufacturing a stator of a capacitor motor in which a winding is wound while holding a crossover of a main winding or an auxiliary winding in a holding mechanism provided at an output portion.

  This simplifies the structural part of the winding machine that winds the main winding and auxiliary winding directly on the split iron core body, and the crossover wire is combined when the main winding winding body and auxiliary winding winding body are combined. A method of manufacturing a stator of a capacitor motor that can simplify processing is obtained.

  According to the present invention, a predetermined number of divided iron core plates each having a yoke portion having an arc surface on the outer periphery and a tooth portion having a rotor-facing surface on the inner surface side are stacked and fixed, and divided into the same number as the number of slots. A main coil winding in which a split iron core body is formed, an insulator is mounted on the split iron core body, and a number of main windings are continuously wound by direct winding through a jumper wire in a concentrated winding And an auxiliary winding wound body in which a number of poles are continuously wound in a concentrated manner through a jumper wire after an insulator is mounted on the divided iron core body, and the number of poles A main winding wound body arrangement group in which main winding winding bodies are arranged in an annular shape, and an auxiliary winding winding body arrangement group in which the number of pole auxiliary winding winding bodies are arranged in an annular form, In the stator formed by combining and fixing the winding winding body and the auxiliary winding winding body so as to be alternately arranged in an annular shape, a part of the insulator to be attached to the divided iron core body in the circumferential direction. There is an extended part that extends greatly in the clockwise and counterclockwise directions in the direction of each adjacent divided iron core, and a holding mechanism that holds the crossover of the main winding or the auxiliary winding is provided in this extended part Therefore, it is not necessary to provide a mechanism for holding the crossover in the structural part of the winding machine that winds the main winding and the auxiliary winding on the divided iron core body, and the structure can be simplified. This makes it possible to rationalize the cost of the winding machine, and when combining the main winding body and the auxiliary winding body, the holding mechanism of the stator is changed from the holding mechanism provided with the jumper to the winding machine. Therefore, it is possible to provide a stator for a capacitor motor and a method for manufacturing the same, which can simplify the processing of the crossover wires.

  In addition, when combining the main winding body group and the auxiliary winding body group, some of the insulators attached to the divided iron core bodies are clockwise in the direction of the divided iron core bodies adjacent to each other in the circumferential direction. In addition, it is possible to provide a structure in which the extension part greatly extended in the counterclockwise direction does not become an obstacle to the combination work.

  Also, the extension part of the insulator to be attached to the split iron core body for winding the main winding is provided only on the auxiliary crossover side, and the extension part of the insulator to be attached to the split iron core body for winding the auxiliary winding By providing only on the main crossover side, it is possible to provide a structure in which the extended portion does not become an obstacle to the combination work and a method for manufacturing the structure.

  Further, only the connecting wire of the main winding is held or accommodated in the extending portion of the insulator provided on the main connecting wire side, and the auxiliary winding is provided in the extending portion of the insulator provided on the auxiliary connecting wire side. Since only the crossover wire is held or stored, the crossover wires of the main winding and the auxiliary winding come into contact with each other, and it is possible to prevent electrical problems and the like.

  In addition, when there are a plurality of connecting wires of the main winding or the auxiliary winding, each connecting wire is electrically separated and held or stored, thereby preventing problems caused by damage to the winding film. be able to.

  According to a first aspect of the present invention, a predetermined number of divided iron core plates each having a yoke portion having an arc surface on the outer periphery and a tooth portion having a rotor facing surface on the inner surface side are laminated and fixed. A divided iron core body is formed by dividing the same number as the number, and an insulating material is mounted on the divided iron core body, and then several poles of the main winding are continuously wound directly on the jumper wire via concentrated wires. Main winding windings and an auxiliary winding winding body in which an insulating material is mounted on the divided iron core body, and a number of poles are continuously wound in a concentrated manner via a jumper wire. A main winding body arrangement group in which the number of poles of the main winding body are arranged in an annular shape, and an auxiliary winding body arrangement in which the number of the poles of the auxiliary winding bodies are arranged in an annular shape In a stator formed by combining and fixing a group so that the main winding body and the auxiliary winding body are alternately arranged in an annular manner, an insulator to be attached to the divided iron core body A part has an extended part which is greatly extended in the clockwise and counterclockwise directions in the direction of each divided iron core adjacent to each other in the circumferential direction, and a connecting wire of the main winding or the auxiliary winding is provided in the extended part. It is configured to have a holding mechanism to hold, simplifying the structural part of the winding machine that directly winds the main winding and auxiliary winding on the split iron core body, and the main winding winding body and auxiliary It has the effect that simplification of the processing of the crossover can be achieved when the winding winding body is combined.

  In addition, a yoke portion having a circular arc surface on the outer periphery and a tooth portion having a rotor facing surface on the inner surface side are integrated, and a predetermined number of divided iron core plates divided into the same number of slots are laminated and fixed. Forming a split iron core body, mounting an insulator on the split iron core body, and then winding the main winding continuously in a concentrated manner with a number of poles through a crossover; And an auxiliary winding wound body in which a number of poles are continuously wound in a concentrated manner through a jumper wire after an insulating material is mounted on the divided iron core body, and the number of poles of the main winding A main winding wound body array group in which wire winding bodies are arranged in an annular form, and an auxiliary winding winding body array group in which the number of pole auxiliary winding winding bodies are arranged in an annular form, In the stator in which the winding body and the auxiliary winding body are combined and fixed and integrated so that they are alternately arranged in an annular shape, a part of the inner diameter side rising portion of the insulator attached to the divided iron core body is An extending portion of the insulator of the main winding body adjacent to each other, having an extending portion that extends greatly in both the clockwise and counterclockwise directions in the direction of each divided iron core adjacent to each other in the circumferential direction Is mounted so as to be positioned on the outer diameter side of the inner diameter side rising portion of the insulator of the adjacent auxiliary winding body, and the extension portion of the insulator of the adjacent auxiliary winding body is It is configured to be mounted so as to be positioned on the outer diameter side of the inner diameter side rising portion of the insulator of the adjacent main winding body, and the circumferential extension of the insulator of the main winding body And the circumferentially extending portion of the insulator of the auxiliary winding winding body has an effect of preventing an obstacle to work when the main winding winding group and the auxiliary winding winding group are combined. .

  In addition, the extension part of the insulator to be attached to the split iron core body for winding the main winding is provided only on the side opposite to the load side of the split iron core body or on the main crossover side of the load side. The extending portion of the insulator to be attached to the split iron core is configured to be provided only on the auxiliary crossover side opposite to the main crossover side on the load side or the anti-load side of the split iron core, The extending portion of the winding body and the connecting wire on the main connecting wire side, and the extending portion of the auxiliary winding device and the connecting wire on the auxiliary connecting wire side have an effect that the combined work does not become an obstacle.

  Further, only the connecting wire of the main winding is held or accommodated in the extending portion of the insulator provided on the main connecting wire side, and the auxiliary winding is provided in the extending portion of the insulator provided on the auxiliary connecting wire side. Only the crossover wire is held or housed, and the crossover wire of the main winding and the crossover wire of the auxiliary winding are not in contact with each other and have an effect of preventing the occurrence of an electrical failure.

In addition, when there are a plurality of connecting wires of the main winding or the auxiliary winding, each connecting wire is electrically separated and held or stored, and the plurality of connecting wires are not in contact with each other. Spatally separated and held, it has the function of preventing the occurrence of problems due to damage to the winding film.

  In addition, a yoke portion having a circular arc surface on the outer periphery and a tooth portion having a rotor facing surface on the inner surface side are integrated, and a predetermined number of divided iron core plates divided into the same number of slots are laminated and fixed. Forming a split iron core body, mounting an insulator on the split iron core body, and then winding the main winding continuously in a concentrated manner with a number of poles through a crossover; And an auxiliary winding wound body in which a number of poles are continuously wound in a concentrated manner through a jumper wire after an insulating material is mounted on the divided iron core body, and the number of poles of the main winding A main winding wound body array group in which wire winding bodies are arranged in an annular form, and an auxiliary winding winding body array group in which the number of pole auxiliary winding winding bodies are arranged in an annular form, In the method of manufacturing a stator in which the winding body and the auxiliary winding body are alternately fixed and integrated so that the winding bodies are alternately arranged in an annular shape, a part of the insulator attached to the divided iron core body is circumferential. It has an extended part that extends greatly in the clockwise and counterclockwise directions in the direction of each adjacent iron core, and the crossover of the main winding or auxiliary winding is held in the holding mechanism provided in this extended part The manufacturing method of winding winding while simplifying the structural part of the winding machine that directly winds the main winding and auxiliary winding on the split iron core body, It is possible to simplify the crossover process when the auxiliary winding body is combined.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS.

(Embodiment 1)
As shown in FIGS. 1 to 10, a predetermined number of divided iron core plates 5 each having a yoke portion 2 having an arc surface 1 formed on the outer periphery and a tooth portion 4 having a rotor facing surface 3 on the inner periphery are laminated. The divided iron core body 7 is divided into the same number as the number of slots 6, and an insulator 8A is attached to the divided iron core body 7, and concentrated winding is performed via the connecting wire 9A by a winding machine (not shown). Separately from the main winding wound body 11 formed by directly winding the main winding 10 by several poles, the insulator 8B is attached to the divided iron core body 7 separately from the main winding wound body 11. A number of poles are continuously connected via a connecting wire 9B arranged on the opposite side in the axial direction across the divided iron core body 7 from the side where the main winding body 11 is provided by concentrated winding by a winding machine. The auxiliary winding 12 is composed of an auxiliary winding 12 formed by winding the auxiliary winding 12 directly, and the main winding 11 and the auxiliary winding 13 are arranged in an annular shape. Body The row group 11G and the auxiliary winding wound body array group 13G include a side where the connecting wire 9A of the main winding wound body 11 is not provided and a side where the connecting wire 9B of the auxiliary winding wound body 13 arranged in an annular shape is not provided. Are combined in the axial direction, and the main winding body 11 and the auxiliary winding body 13 are alternately arranged in an annular shape and fixed together to form a stator 14. It will be.

Further, as shown in FIG. 11, the main connecting wire side 15 having the connecting wire 9 </ b> A (not shown) of the main winding body 11 and the auxiliary connecting wire side having the connecting wire 9 </ b> B of the auxiliary winding device 13. 16 is arranged on the opposite side of the stator 14 in the axial direction.

  The main winding 10 is directly wound via an insulator 8A attached to several divided iron cores 7 arranged in a ring or a straight line, and the insulator 8A The auxiliary crossover side 16 has extended portions 8A-1 extending greatly in the clockwise and counterclockwise directions in the respective divided iron cores 7 adjacent to each other in the circumferential direction of the stator 14, and the extended portions 8A -1 is used to hold the connecting wire 9B of the auxiliary winding 12, and similarly, the auxiliary winding 12 has several divided iron cores 7 arranged in an annular or linear manner. The insulator 8B is wound around the insulator 8B in the direction of the divided iron cores 7 adjacent to each other in the circumferential direction of the stator 14 on the main crossover side 15. Each extending in the counterclockwise direction and the extending portion 8B-1, and provided in the extending portion 8B-1. The crossover wire 9A of the main winding 10 is held by the holding mechanism 8B-2, and the crossover wire 9A of the main winding 10 and the crossover wire 9B of the auxiliary winding 12 are both mechanically fixed by an insulating structural part. Composed.

  Further, the extending portion 8A-1 of the insulator 8A to be mounted on the split iron core body 7 for winding the main winding 10 is provided only on the auxiliary crossover side 16, and the split iron core body 7 for winding the auxiliary winding 12 is provided. The extending portion 8B-1 of the insulator 8B to be attached to is constructed by being provided only on the main crossover side 15.

  Further, only the connecting wire 9A of the main winding 10 is held or accommodated in the extending portion 8B-1 of the insulating material 8B provided on the main connecting wire side 15, and the insulating material 8A provided on the auxiliary connecting wire side 16 is held. Only the connecting wire 9B of the auxiliary winding 12 is held or accommodated in the extending portion 8A-1, and the connecting wire 9A of the main winding 10 and the connecting wire 9B of the auxiliary winding 12 are electrically separated. Composed.

  Also, as shown in FIG. 12, when there are a plurality of connecting wires 9A, 9B of the main winding 10 or the auxiliary winding 12, a plurality of connecting wires 9A-1, 9A-2 and 9B-1, 9B-2 Each of them is electrically separated and held or stored, and the crossover wires 9A and 9B are all arranged spatially separated.

  Thus, according to the stator of the capacitor motor of the first embodiment of the present invention, the jumper wire 9A of the main winding 10 is provided in the extending portion 8B-1 of the insulator 8B of the auxiliary winding winding body 13. The crossover wire 9B of the auxiliary winding 12 is held by the holding mechanism 8B-2, and is mechanically held by the holding mechanism 8A-2 provided in the extending portion 8A-1 of the insulator 8A of the main winding body 11. Therefore, it is not necessary to provide a structure portion for holding the crossover wires 9A and 9B on the side of the winding machine that winds the main winding 10 and the auxiliary winding 12 directly. When the winding body 11 and the auxiliary winding body 13 are combined, it is possible to reduce the load on the connecting wires 9A and 9B.

    Moreover, it is a part of insulator 8A, 8B with which the division | segmentation iron core body 7 was mounted | worn, and the extension part 8A extended greatly clockwise and counterclockwise in the direction of each division | segmentation iron core body 7 mutually adjacent in the circumferential direction -1,8B-1 will provide a structure that does not hinder the combination work.

  Further, the extension 8A-1 of the insulator 8A of the main winding body 11 is provided only on the auxiliary connecting wire side 16, and the extension 8B-1 of the insulator 8B of the auxiliary winding body 13 is Since it is provided only on the main crossover wire side 15 on the opposite side of the auxiliary crossover wire side 16 across the divided iron core body 7, when combining the main winding body group 11G and the auxiliary winding body group 13G The extension portion 8A-1 and the crossover wire 9A, and the extension portion 8B-1 and the crossover wire 9B provide a structure that does not hinder the combination work.

  Further, the connecting wire 9A of the main winding 10 is held only by the extending portion 8B-1 of the insulator 8B of the auxiliary winding wound body 13, and the connecting wire 9B of the auxiliary winding 12 is held by the main winding wound body 11. Since this is held only by the extending portion 8A-1, the connecting wire 9A of the main winding 10 and the connecting wire 9B of the auxiliary winding 12 do not contact each other, and it is possible to prevent the occurrence of electrical problems. it can.

  Further, when there are a plurality of connecting wires 9A or connecting wires 9B on the auxiliary connecting wire side or the main connecting wire side, such as when having a winding for speed adjustment, a plurality of connecting wires (9A-1, 9A-2 and 9B Since -1 and 9B-2) are spatially separated from each other without being in contact with each other, it is possible to prevent the occurrence of problems due to damage to the winding film.

The perspective view of the division | segmentation iron core body which mounted | wore the insulator of the capacitor | condenser motor stator of Embodiment 1 of this invention. Circuit diagram of stator winding of capacitor motor Perspective view of split iron core plate of stator of same capacitor motor Perspective view of split iron core of stator of same capacitor motor Front view showing a split state of the stator iron core of the capacitor motor Front view of the stator of the capacitor motor Enlarged perspective view showing the main winding body of the stator of the capacitor motor Enlarged perspective view showing auxiliary winding body of stator of same capacitor motor Front view of the main winding wound body group of the stator of the same capacitor motor Front view of auxiliary winding wound body group of stator of same capacitor motor Sectional view from the side of the stator of the capacitor motor Perspective view of main winding winding body (or auxiliary winding winding body) having a plurality of jumpers of stator of same capacitor motor Front view of the main winding body of the stator of a conventional capacitor motor Front view of auxiliary winding body of stator of same capacitor motor Front view of the stator of the capacitor motor

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Arc surface 2 Relay part 3 Rotor opposing surface 4 Tooth part 5 Divided iron core board 6 Slot 7 Divided iron core body 8A, 8B Insulator 8A-1, 8B-1 Extension part 8A-2, 8B-2 Holding Mechanism 9A, 9B Junction wire 9A-1, 9A-2, 9B-1, 9B-2 Junction wire 10 Main winding 11 Main winding winding body 11G Main winding winding group 12 Auxiliary winding 13 Auxiliary winding Winding body 13G Auxiliary winding winding body group 14 Stator 15 Main crossover wire side 16 Auxiliary crossover wire side

Claims (9)

The iron part having a circular arc surface on the outer periphery and the tooth part having the rotor facing surface on the inner surface side are integrated, and a predetermined number of divided iron core plates divided into the same number as the number of slots are laminated and fixed. Forming a core body, and attaching an insulator to the divided iron core body, and then winding the main winding continuously in a number of poles through a crossover wire in a concentrated winding, It consists of an auxiliary winding wound body in which several poles are continuously wound by direct winding via a jumper wire with an insulating material attached to a split iron core body, A main winding winding arrangement group in which main bodies are arranged annularly and an auxiliary winding winding arrangement group in which the number of pole auxiliary winding windings are arranged in an annular form In the stator formed by combining and fixing so that the body and the auxiliary winding wound body are alternately arranged in an annular shape, a part of the insulator attached to the divided iron core body is adjacent to each other in the circumferential direction. Fixing a condenser motor that has an extension part that extends greatly in the clockwise and counterclockwise directions in the direction of the iron core, and that is provided with a holding mechanism that holds the crossover of the main winding or auxiliary winding. Child. The iron part having a circular arc surface on the outer periphery and the tooth part having the rotor facing surface on the inner surface side are integrated, and a predetermined number of divided iron core plates divided into the same number as the number of slots are laminated and fixed. Forming a core body, and attaching an insulator to the divided iron core body, and then winding the main winding continuously in a number of poles through a crossover wire in a concentrated winding, It consists of an auxiliary winding wound body in which several poles are continuously wound by direct winding via a jumper wire with an insulating material attached to a split iron core body, A main winding winding arrangement group in which main bodies are arranged annularly and an auxiliary winding winding arrangement group in which the number of pole auxiliary winding windings are arranged in an annular form The stator and the auxiliary winding wound body are combined and fixed and integrated so that they are alternately arranged in an annular shape, and a part of the inner diameter side rising portion of the insulator attached to the divided iron core body is Direction In the direction of each divided iron core adjacent to each other, there is an extension part greatly extended in both the clockwise and counterclockwise directions, and the extension part of the insulator of the adjacent main winding body is adjacent The auxiliary winding winding body is mounted so as to be positioned on the outer diameter side of the inner diameter side rising portion of the insulator, and the extension portions of the insulators of the adjacent auxiliary winding winding bodies are adjacent to each other. A stator of a capacitor motor configured to be mounted so as to be positioned on an outer diameter side of an inner diameter side rising portion of an insulator of a main winding body. The extension part of the insulator to be attached to the split iron core body for winding the main winding is provided only on the anti-load side of the split iron core body or on the main crossover side of the load side. The extension part of the insulator attached to the core body is provided only on the auxiliary crossover side opposite to the main crossover line side on the load side or the anti-load side of the divided iron core body. The stator of the capacitor motor described. Only the connecting wire of the main winding is held or stored in the extending portion of the insulator provided on the main connecting wire side, and the connecting portion of the auxiliary winding is connected to the extending portion of the insulator provided on the auxiliary connecting wire side. The capacitor motor stator according to claim 1, wherein only the wire is held or housed. 5. The capacitor motor stator according to claim 3, wherein when there are a plurality of connecting wires of the main winding or the auxiliary winding, each connecting wire is electrically separated and held or stored. The iron part having a circular arc surface on the outer periphery and the tooth part having the rotor facing surface on the inner surface side are integrated, and a predetermined number of divided iron core plates divided into the same number as the number of slots are laminated and fixed. Forming a core body, and attaching an insulator to the divided iron core body, and then winding the main winding continuously in a number of poles through a crossover wire in a concentrated winding, It consists of an auxiliary winding wound body in which several poles are continuously wound by direct winding via a jumper wire with an insulating material attached to a split iron core body, A main winding winding arrangement group in which main bodies are arranged annularly and an auxiliary winding winding arrangement group in which the number of pole auxiliary winding windings are arranged in ring form In the stator manufacturing method in which the body and the auxiliary winding wound body are alternately fixed and integrated so that they are alternately arranged in a ring, a part of the insulator attached to the divided iron core body is adjacent in the circumferential direction. Each of the divided iron cores has an extending part that is greatly extended in the clockwise and counterclockwise directions, and the holding mechanism provided in the extending part holds the connecting wire of the main winding or the auxiliary winding. A method of manufacturing a stator of a capacitor motor to be wound by winding. The extension part of the insulator to be attached to the split iron core body for winding the main winding is provided only on the anti-load side of the split iron core body or on the main crossover side of the load side. 7. The capacitor motor according to claim 6, wherein the extending portion of the insulator attached to the core is provided only on the auxiliary crossover side opposite to the main crossover side on the load side or the non-load side of the divided iron core. Method of manufacturing the stator. Only the connecting wire of the main winding is held or stored in the extending portion of the insulator provided on the main connecting wire side, and the connecting portion of the auxiliary winding is connected to the extending portion of the insulator provided on the auxiliary connecting wire side. The method of manufacturing a stator for a capacitor motor according to claim 6, wherein only the wire is held or stored. 9. The method of manufacturing a stator for a capacitor motor according to claim 7, wherein when there are a plurality of connecting wires of the main winding or auxiliary winding, each connecting wire is electrically separated and held or stored. .

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