JP3576106B2 - Capacitor motor stator and method of manufacturing the same - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a stator for a condenser motor using a split 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 of manufacturing the same.
[0002]
[Prior art]
2. Description of the Related Art In recent years, a stator in which a winding is applied to a plurality of divided iron core plates and the divided iron core plates are arranged in a ring shape, and a method of manufacturing the stator have been widely used.
[0003]
Conventionally, as an example of a method for manufacturing this type of stator, one described in Japanese Patent Application Laid-Open No. 9-46979 has been known. Hereinafter, the manufacturing method will be described with reference to FIGS.
[0004]
As shown in FIGS. 16 and 17, the coil 101 is wound, and the coil bobbin 103 provided with the relay pin 102 serving as the winding start portion and the winding end portion of the winding 101 is inserted into each tooth portion 104, and then the yoke is formed. 105 to produce a stator.
[0005]
Also, as shown in FIGS. 18 and 19, after the divided tooth portions 201 are insulated by end insulators 202 and 203, a relay pin 205 serving as a winding start portion and a winding end portion of the winding 204 is provided. After winding the winding 204, the stator is manufactured by being combined into a ring.
[0006]
[Problems to be solved by the invention]
In such a conventional stator and its manufacturing method, in the former, a relay pin 102 serving as a winding start portion and a winding end portion of the winding 101 is provided for each coil bobbin 103 provided in the tooth portion 104, and in the latter, Is provided with the relay pins 205 serving as a winding start part and a winding end part of the winding 204 for each divided tooth part 201, so that the number of the relay pins 102 and 205 in the former and the latter increases, and the tooth part 104 Alternatively, there has been a problem that a crossover process for connecting the tooth portions 201 is complicated, and the number of processing operations is increased.
[0007]
Further, after the main winding and the auxiliary winding, each of which has the main winding and the auxiliary winding wound continuously in a series of several poles, are arranged in a ring shape, the main winding and the auxiliary winding are moved in the axial direction, and the main winding and the auxiliary winding are moved. When the wire winding body and the auxiliary winding winding body are integrated so as to be alternately arranged in a ring shape, there is a problem that a crossover may hinder the assembling work.
[0008]
The present invention solves the above-mentioned problems, and minimizes the number of winding start portions and winding end portions of a winding, thereby reducing the number of man-hours for lead wire processing, and a method of manufacturing the same. The purpose is to provide.
[0009]
Another object of the present invention is to facilitate the work of combining the main winding and the auxiliary winding with each other.
[0010]
[Means for Solving the Problems]
In the manufacturing method of the capacitor motor stator according to the present invention, the yoke portion having the arc surface on the outer circumference and the tooth portion having the rotor facing surface formed on the inner surface side are connected and divided into the same number as the number of slots. A punching step of punching an iron core plate, a laminating step of forming a fixed divided iron core body by laminating a predetermined number of the divided iron core plates, and winding the main winding by concentrated winding via an insulator on the divided iron core body. A main winding winding step of continuously winding a number of poles of the main winding winding body continuously through a mounting transition wire, and winding an auxiliary winding by concentrated winding through an insulator on the divided iron core body; The auxiliary winding is connected to the main crossover side provided with the crossover of the main winding winding body via the auxiliary crossover side crossover arranged on the opposite side in the axial direction with the divided iron core body interposed therebetween. An auxiliary winding winding step of continuously winding several windings of the winding body in series, and the number of main winding winding bodies and the number of auxiliary winding winding bodies After arranging in an annular shape, the auxiliary winding wrapping arranged in the same manner as the main winding wrapping arranged in the annular shape is opposed to the opposite side of the main crossover side and the opposite side of the auxiliary crossover side. The main winding and the auxiliary winding are integrated so that they are alternately arranged in a ring shape.
[0011]
According to the present invention, the number of winding start portions and winding end portions can be minimized to reduce the number of man-hours for lead wire processing, and the main winding winding body and the auxiliary winding winding can be reduced. It is possible to provide a method of manufacturing a capacitor motor stator that can prevent each crossover from hindering the assembling operation when the body is moved in the axial direction and combined.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
The invention according to claim 1 of the present invention relates to a split iron in which a yoke portion having an arcuate surface on the outer periphery and a tooth portion having a rotor facing surface on the inner surface side are connected and divided into the same number as the number of slots. A punching step of punching a core plate, a lamination step of laminating a predetermined number of the divided iron core plates to form a divided iron core body fixed, and winding the main winding by concentrated winding on the divided iron core body via an insulator. A main winding winding step of continuously winding several poles of the main winding winding body continuously via a connecting wire, and winding an auxiliary winding by concentrated winding on the divided iron core via an insulator. The main winding wire side of the main winding wire body, on which the crossover wire is provided, is connected to the auxiliary winding wire side of the auxiliary crossover wire side disposed on the opposite side in the axial direction with the divided iron core body interposed therebetween. An auxiliary winding winding step of continuously winding several windings of the winding body continuously; and arranging the main winding winding body of the number of poles and the auxiliary winding winding body of the number of poles in a ring each. After Similarly to the main winding winding arranged in a ring, the auxiliary winding winding arranged in a ring is moved in the axial direction with the opposite side of the main crossover side and the opposite side of the auxiliary crossing side facing each other. And an assembling step in which the main winding and the auxiliary winding are integrated so that they are alternately arranged in a ring shape. The number of poles of the wound winding body can be continuously manufactured through the crossover wires, and the beginning and end of winding of the main winding and auxiliary winding are minimized, and the work of stator lead wire processing It is possible to reduce man-hours and to prevent each crossover from hindering the assembling work when the main winding and the auxiliary winding are moved in the axial direction and combined. Have.
[0013]
Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
[0014]
(Embodiment 1)
As shown in FIGS. 1 to 9, a yoke portion 3 having an arcuate surface on the outer periphery, a tapered convex portion 1 provided on one of the connecting surfaces, and a tapered concave portion 2 provided on the other, and an inner peripheral surface. And a toothed portion 5 having a rotor facing surface 4 formed thereon, and a punching step 8 for punching a split iron core plate 7 divided into the same number as the number of slots 6, and a split iron core plate 7 punched in the punching step 8. A laminating step 10 for laminating a predetermined number of sheets and forming a divided iron core body 9 fixed by welding or the like, and a winding machine (not shown) via the insulator 11 on the divided iron core bodies 9 laminated in the laminating step 10. ), The main winding 12 is wound in a concentrated winding, the main winding winding body 14 is continuously wound in series with several poles via the connecting wire 13, and the main winding winding start portion 12a and the main winding are wound at the ends. The main winding winding step 15 for forming the wire winding end portion 12b, and separately from the main winding winding step 15, the divided iron core body 9 is supplemented by concentrated winding via the insulator 11. The side on which the winding 16 is wound and on which the main winding winding 14 is provided is connected to the auxiliary winding winding 17 via a connecting wire 13 disposed on the opposite side in the axial direction with respect to the stator core. An auxiliary winding winding step 18 in which several windings are continuously wound in series and an auxiliary winding winding start part 16a and an auxiliary winding winding end part 16b are formed at the ends, a main winding winding step 15 and an auxiliary winding The side of the main winding winding body 14 wound in the winding winding step 18 and arranged in an annular shape, on which the connecting wires 13 are not provided, and the side of the auxiliary winding winding body 17 arranged in an annular shape, on which the connecting wires 13 are not provided. Are assembled in the axial direction so as to face each other, and the stator 20 is manufactured as a product by the assembling step 19 in which the main winding windings 14 and the auxiliary winding windings 17 are alternately arranged in an annular shape. .
[0015]
As shown in FIG. 9, a main crossover side 21 having a crossover 13 (not shown) of the main winding body 14 and an auxiliary crossover side 22 having a crossover of the auxiliary winding body 17 are provided. Are arranged on opposite sides of the stator 20 in the axial direction.
[0016]
When the main winding 14 and the auxiliary winding 17 are successively wound in series by several poles, the main winding 14 and the auxiliary winding 17 are arranged in a ring shape. The stator 20 is wound while maintaining an interval substantially equal to the interval between adjacent poles when the stator 20 is formed, and the crossover wire 13 between the poles of the main winding winding body 14 and the auxiliary winding winding body 17 is formed. The length is substantially equal to the interval between adjacent poles after the stator 20 is formed.
[0017]
In the main winding winding step 15 and the auxiliary winding winding step 18, the divided iron cores 9 are arranged substantially linearly, and the main winding 12 and the auxiliary winding 16 are wound directly. This is a method of manufacturing the main winding winding body 14 and the auxiliary winding winding body 17.
[0018]
Also, in the assembling step 19, when the main winding windings 14 and the auxiliary winding windings 17 are alternately arranged in an annular shape, the projections 1 of the main winding windings 14 are adjacent to the auxiliary winding windings. The outer diameter of the stator is smaller than the regular size so that the concave portion 2 of the winding body 17 faces the concave portion 2 of the main winding winding body 14 and the convex portion 1 of the adjacent auxiliary winding winding body 17 faces the concave portion 2 of the main winding winding body 14. After arranging them in a slightly large annular shape and tentatively arranging them so that the main winding windings 14 and the auxiliary windings 17 are alternately arranged, the outer diameter of the stator is adjusted to a regular size. This is a manufacturing method in which the projections 1 and the recesses 2 are fitted and integrated by being reduced.
[0019]
In addition, the main windings 14 and the auxiliary windings 17 are both processed so that the lead wire processing is concentrated on the main crossover side 21 or the auxiliary windings 22 are concentrated on the auxiliary crossover side 22. The winding start portion 12a and the main winding end portion 12b, and the auxiliary winding start portion 16a and the auxiliary winding end portion 16b are provided on the same side.
[0020]
As described above, according to the capacitor motor stator and the method of manufacturing the same according to the first embodiment of the present invention, main winding 12 is wound around divided iron core body 9 by concentrated winding, and main winding 12 is A series of several windings of the winding body 14 are continuously wound, the auxiliary winding 16 is wound around the divided iron core body 9 by concentrated winding, and the auxiliary winding winding body 17 is wound several times through the crossover wire 13. Since the stator 20 is manufactured by successively winding the stator and manufacturing the stator 20 by alternately arranging the main windings 14 and the auxiliary windings 17 in an annular shape, the winding of the main winding 12 and the auxiliary winding 16 is performed. The number of windings at the beginning and end of the winding is minimized, and the number of man-hours for processing the lead wire of the stator 20 can be reduced.
[0021]
The main crossover side 21 having the crossover 13 (not shown) of the main winding wrapping body 14 and the auxiliary crossover side 22 having the crossover of the auxiliary winding wrapping body 17 are arranged in the axial direction of the stator 20. When the main winding winding body 14 and the auxiliary winding winding body 17 are combined in the axial direction and are alternately arranged in a ring shape and integrated with each other, the main winding winding body 14 The crossover wire 13 and the crossover wire 13 of the auxiliary winding winding body 17 are located opposite to each other with the divided iron core body interposed therebetween, so that it is possible to prevent an obstacle to an assembly operation.
[0022]
In addition, when the direct winding is performed, the winding is performed while maintaining the interval substantially equal to the interval between the adjacent poles when the stator 20 is formed, so that the length of the connecting wire 13 between the poles is not adjusted. The winding winding body 14 and the auxiliary winding winding body 17 can be integrated.
[0023]
In addition, since the divided iron cores 9 are arranged in a substantially straight line and the main winding 12 and the auxiliary winding 16 are directly wound, a sufficient rotation space for the nozzle or fryer of the winding machine can be secured. Thus, the efficiency of the winding operation can be improved.
[0024]
In addition, since the length of the crossover wire 13 between the poles is made substantially equal to the interval between the adjacent poles after the stator 20 is formed, when winding the windings, the number of main windings of the number of poles on which each winding is wound is made. The jig space for holding the wire winding body 14 and the auxiliary winding winding body 17 can be reduced, and the size of the winding winding device can be reduced.
[0025]
Further, the convex portion 1 and the concave portion 2 provided on the connecting surface of the yoke portion 3 of the main winding winding body 14 and the auxiliary winding winding body 17 are connected to each other so that the outer diameter of the stator 20 is slightly smaller than the regular size. After arranging the protrusions 1 and the recesses 2 so as to reduce the outer diameter of the stator 20 to the regular size, the stator 20 is fitted and integrated. Part deformation can be prevented.
[0026]
In addition, the main winding start portion 12a and the main winding end portion 12b, and the auxiliary winding start portion 16a and the auxiliary winding end portion 16b are concentrated on the main crossover side 21 or the auxiliary crossover side 22. Since it is provided, the lead wire processing work, the work of assembling the terminal block, and the work of electrical connection can be easily performed in a short time, and the structure of the terminal block can be simplified and downsized.
[0027]
In the first embodiment, a method of manufacturing by a punching step 8 of punching the split iron core plate 7 and a stacking step 10 of stacking the split iron core plates 7 and fixing them by welding or the like to form the split iron core body 9 are described. As described above, the present invention also includes a case where a divided iron core body is manufactured by sequentially laminating through a joint while punching a divided iron core plate with a press machine.
[0028]
(Embodiment 2)
As shown in FIGS. 10 and 11, the divided iron core plates 9 </ b> A are arranged in a substantially circular shape, the main winding 12 is wound by concentrated winding, and the main winding winding body 14 </ b> B Continuously wound in series.
[0029]
In addition, the auxiliary winding 16 is wound around the divided iron core plates 9A arranged in a substantially circular shape by concentrated winding, and the auxiliary winding winding body 17B is wound straight and continuously several poles via the crossover wire 13.
[0030]
Then, a stator (not shown) is formed by alternately arranging the main winding wraps 14B and the auxiliary winding wraps 17B in an annular shape.
[0031]
As described above, according to the method for manufacturing the capacitor motor stator of the second embodiment of the present invention, the divided iron cores 9A are arranged in a substantially circular shape, and the main winding 12 and the auxiliary winding 16 are directly wound. Therefore, the main winding wrapping 14B and the auxiliary winding wrapping 17B are the same as the arrangement when they are integrated with the stator. There is no need to rearrange from a linear shape to a circular shape as in the case of arrangement in a shape, and it is also unnecessary to change the holding structure of the crossover wires 13 between the poles.
[0032]
(Embodiment 3)
As shown in FIGS. 1 to 3 and FIGS. 12 to 15, a yoke having an arcuate surface on the outer periphery, a tapered convex portion 1 provided on one of the connecting surfaces, and a tapered concave portion 2 provided on the other. A punching step of connecting the portion 3 and a tooth portion 5 having a rotor facing surface 4 formed on an inner peripheral surface thereof, and punching a divided iron core plate 7 divided into the same number as the number of the slots 6; A laminating step of laminating a predetermined number of iron core plates 7 to form a divided iron core body 9B fixed by welding or the like, and a winding machine (FIG. (Not shown), the main winding 12 is wound in a concentrated winding, and the main winding winding body 14C is wound directly by several poles. Auxiliary winding winding step of winding the auxiliary winding 16 in a concentrated manner around the core body 9B via the insulator 11 and directly winding a few poles of the auxiliary winding winding body 17C The main winding winding body 14C wound in the main winding winding step and the auxiliary winding winding step and arranged in an annular shape and the auxiliary winding winding body 17 arranged in an annular shape are opposed to each other and axially combined. As a result, the stator 20A is manufactured as a product by the assembling process in which the main winding winding body 14C and the auxiliary winding winding body 17C are alternately arranged in a ring shape. At this time, in the assembling step, the main winding winding 14C and the auxiliary winding windings 17C each having a few poles are arranged in a ring shape and slightly larger than a regular size. The body 14C and the auxiliary winding winding body 17C are opposed to each other, and are combined by moving in the axial direction so as to be alternately positioned while the outer diameter of the stator is slightly larger than the regular dimension, and temporarily arranged in a ring. Thereafter, the stator 20A is formed by reducing and integrating the outer diameter of the stator to a regular size.
[0033]
In addition, the main winding wrap 14C and the auxiliary winding wrap 17C are arranged one by one so that the main winding wrap 14C having a few poles and the auxiliary winding wrap 17C having a few poles are alternately positioned. The stator 20 </ b> A is formed by arranging one or a plurality of rings in an annular shape slightly larger than the regular outer diameter of the stator, and then reducing and integrating the regular dimensions.
[0034]
As described above, according to the capacitor motor stator of the third embodiment of the present invention, the main winding wrapping 14C and the auxiliary winding wrapping 17C that are arranged in a substantially circular shape are smaller than the regular stator outer diameter. In order to reduce the size of the main winding winding body 14C and the auxiliary winding winding body 17C to reduce the driving force and to reduce the main winding in order to reduce the size of the main winding winding body 14C and the auxiliary winding winding body 17C in order to reduce the size of the main winding body. Deformation of the combined portion of the body 14C and the auxiliary winding body 17C can be prevented.
[0035]
In addition, the main winding wrap 14C and the auxiliary winding wrap 17C are arranged one by one so that the main winding wrap 14C having a few poles and the auxiliary winding wrap 17C having a few poles are alternately positioned. After arranging each ring or a plurality of rings in an annular shape slightly larger than the regular outer diameter of the stator, and reducing the size to the regular size and integrating them, the main winding body 14C and the auxiliary It is possible to prevent deformation of the combined portion of the wound winding body 17C, and it is possible to manufacture the stator 20A having the present structure with a minimum of simple facilities.
[0036]
【The invention's effect】
As is clear from the above embodiments, according to the present invention, the yoke portion having the circular arc surface on the outer periphery and the tooth portion having the rotor facing surface on the inner surface side are connected, and the number of slots is equal to the number of slots. A punching step of punching a divided iron core plate divided into a plurality of pieces, a lamination step of laminating a predetermined number of the divided iron core plates to form a fixed divided iron core body, and a concentrated winding through an insulator on the divided iron core body. A main winding winding step of winding several windings of a main winding body continuously in series through a crossover, and assisting with a concentrated winding through an insulator on the divided iron core. The winding is wound, and the main crossover side on which the crossover of the main winding is provided is connected to the auxiliary crossover side provided on the opposite side in the axial direction with the split iron core body interposed therebetween. An auxiliary winding winding step of continuously winding several poles of the auxiliary winding body in series, and the main winding winding body of several poles and the auxiliary winding winding body of several poles To After arranging in an annular shape, the auxiliary winding wrapping arranged in the same manner as the main winding wrapping arranged in the annular shape is opposed to the opposite side of the main crossover side and the opposite side of the auxiliary crossover side. The main winding and the auxiliary winding are manufactured by an assembly process in which the main winding and the auxiliary winding are integrated so that the main winding and the auxiliary winding are alternately arranged in an annular shape. The number of winding start and end parts can be minimized to reduce the number of man-hours required when processing the lead wire of the stator. It is possible to provide a method for manufacturing a stator for a condenser motor, which can prevent each crossover from hindering the assembling operation when being moved and combined.
[0037]
Further, when the main winding winding and the auxiliary winding winding are successively wound several poles continuously, the main winding winding and the auxiliary winding winding are arranged in a ring, and the stator is formed. The main winding and the auxiliary winding are wound without adjusting the length of the crossover between the poles, because the winding is maintained at a distance substantially equal to the distance between adjacent poles when formed. Can be integrated.
[0038]
In addition, since the divided iron cores are arranged on a substantially straight line, the main winding and the auxiliary winding are wound in series, and the main winding and the auxiliary winding are manufactured. A sufficient rotation space for the nozzle or fryer can be secured, and the efficiency of winding work can be increased.
[0039]
In addition, the length of the crossover between the poles of the main winding and the auxiliary winding is approximately equal to the interval between the adjacent poles after the stator is formed. In order to reduce the space required for the jigs to hold the main winding of several poles around which the main winding is wound and the auxiliary winding of several poles around which the auxiliary winding is wound, a winding winding device is provided. The size can be reduced.
[0040]
In addition, a tapered convex portion is provided on one of the connection surfaces of the yoke portion, and a main winding winding body and an auxiliary winding winding body having a tapered concave portion provided on the other side are sequentially connected to the convex portion and the concave portion. After the provisional arrangement in an annular shape, the protrusions are fitted and integrated into the recesses so that the outer diameter of the stator is reduced to the regular size, and manufactured. The required driving cost can be reduced and the combination can be prevented from being deformed.
[0041]
In addition, the lead wire processing of the main winding wire and the auxiliary winding wire is concentrated on the main crossover side or the auxiliary crossover side. Connection can be easily performed in a short time, and the structure of the terminal block can be simplified and downsized.
[0042]
In addition, since the divided iron cores are arranged in a substantially circular shape and the main winding and the auxiliary winding are wound in series to manufacture the main winding and the auxiliary winding, the main winding and the auxiliary winding are manufactured. The windings and the auxiliary windings are equivalent to the arrangement after integration, and there is no need to rearrange the main windings and the auxiliary windings from a straight line to a circular shape. The effect of eliminating the need to change the structure for holding the crossover between the poles is obtained.
[0043]
In addition, an arcuate surface is provided on the outer periphery, and the same number of divided iron cores as the number of slots in which the rotor-facing surface is formed on the inner surface, and a main winding wound around the divided iron core, and via a crossover wire A main winding winding body wound in series with several poles continuously, and an auxiliary winding wound around the divided iron core body with several poles continuously wound in series via a crossover wire The main winding side provided with the crossover of the main winding body and the auxiliary crossover side provided with the crossover of the auxiliary winding are opposite sides in the axial direction of the stator. Since it is a capacitor motor stator in which the main winding and the auxiliary winding are alternately arranged in a ring so as to be arranged at the beginning of winding of the main winding and the auxiliary winding, The quantity at the end of the winding is minimized.
[0044]
Further, since the winding start portion and the winding end portion of the main winding and the auxiliary winding are provided concentrated on the main crossover side or the auxiliary crossover side, the terminal block structure can be simplified and downsized. .
[0045]
In addition, several main winding windings and several auxiliary winding windings are provided independently, and the main windings and the auxiliary windings are alternately formed in a ring shape, and Tentatively arranged slightly larger than the outer diameter of the stator, and then reduced to a regular size and integrated, making it easier to combine the main winding and the auxiliary winding. And the deformation of the combination part can be prevented.
[0046]
Further, the main winding winding and the auxiliary winding winding may be arranged one by one or a plurality of times such that the main winding winding of several poles and the auxiliary winding winding of several poles are alternately positioned. Each of them is arranged in a ring shape slightly larger than the regular stator outer diameter, then reduced to the regular dimensions and integrated into a manufacturing process. Can be prevented from being deformed, and can be manufactured with low cost and simple equipment.
[Brief description of the drawings]
FIG. 1 is a circuit diagram of a winding of a capacitor motor stator according to a first embodiment of the present invention; FIG. 2 is a front view of a split iron core plate of the capacitor motor stator; FIG. FIG. 4 is a partially cutaway front view of the condenser motor stator. FIG. 5A is a front view showing a winding state of a main winding of the condenser motor stator. FIG. FIG. 6 is a front view showing a winding state of auxiliary windings of the stator. FIG. 6 is a schematic view showing a temporary arrangement state of the capacitor motor stator. FIG. 7 is a schematic view showing a fitting integration state of the capacitor motor stator. FIG. 8 is a block diagram showing a manufacturing process of the capacitor motor stator. FIG. 9 is a side view of the capacitor motor stator. FIG. 10 is a diagram showing main windings of the capacitor motor stator according to the third embodiment of the present invention. Front view showing winding state [Fig. 11] FIG. 12 is a front view showing a winding state of an auxiliary winding of a stator of the motor of the present invention. FIG. 12 is a schematic view showing a temporary arrangement of main windings of a stator of a capacitor motor according to a third embodiment of the present invention. FIG. 14 is a schematic view showing a temporary arrangement state of an auxiliary winding winding body of the capacitor motor stator. FIG. 14 is a schematic view showing a temporary arrangement state of the capacitor motor stator. FIG. 15 is fitting of the capacitor motor stator. FIG. 16 is a schematic view showing an integrated state. FIG. 16 is a perspective view of a coil bobbin on which a conventional stator winding is wound. FIG. 17 is a front view of the same stator. FIG. 18 is a tooth section of another conventional stator. FIG. 19 is a perspective view showing a state in which a winding is wound on the stator. FIG. 19 is a plan view of the stator.
Reference Signs List 1 convex part 2 concave part 3 yoke part 4 rotor facing surface 5 tooth part 6 slot 7 divided iron core plate 8 punching process 9 divided iron core body 9A divided iron core body 9B divided iron core body 10 laminating step 11 insulator 12 main Winding 12a Main winding winding start portion 12b Main winding winding end portion 13 Crossover 14 Main winding winding body 14B Main winding winding body 14C Main winding winding body 15 Main winding winding process 16 Auxiliary winding Wire 16a Auxiliary winding start 16b Auxiliary winding end 17 Auxiliary winding 17B Auxiliary winding 17C Auxiliary winding 18 Auxiliary winding step 19 Assembly step 20 Stator 20A Stator 21 Main crossover side 22 Auxiliary crossover side

Claims (8)

A punching step of connecting 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, and punching a divided iron core plate divided into the same number as the number of slots; A laminating step of forming a divided iron core body in which a predetermined number of plates are laminated and fixed, and winding the main winding by a concentrated winding around the divided iron core body through an insulator and a main winding through a crossover wire. A main winding winding step of successively winding several poles in series, and an auxiliary winding wound around the divided iron core body by concentrated winding via an insulator, and a crossover wire of the main winding body With the main crossover side provided, the auxiliary winding winding body is wound in series with several poles continuously via the crossover on the auxiliary crossover side arranged on the opposite side in the axial direction with the divided iron core body interposed. the method of manufacturing a motor stator with the auxiliary winding winding step of instrumentation, the main winding and auxiliary winding series-wound wound around several divided iron core poles of the main winding wound wearing of The main winding by performing several divided iron core poles of the auxiliary winding wound wearing each annularly arranged and to maintain an approximately equal interval as the spacing between adjacent poles when forming the stator winding A winding body and an auxiliary winding winding body are formed, and each of the auxiliary winding winding bodies having a number of poles arranged in an annular shape in the same manner as the main winding winding body having a number of poles arranged in an annular shape. The opposite side of the wire side and the opposite side of the auxiliary crossover side are opposed to each other and axially moved and combined, and the poles of the main winding and the auxiliary winding are alternately arranged in a ring shape. method for manufacturing a capacitor motor stator, characterized in that to produce more as assemblers to integrate as. 2. The capacitor motor stator according to claim 1, wherein the length of the crossover between the poles of the main winding winding and the auxiliary winding is approximately equal to the interval between adjacent poles after the stator is formed. Manufacturing method. When the main winding winding body and the auxiliary winding winding body each having a tapered convex portion provided on one of the connection surfaces of the yoke portion and a tapered concave portion on the other are arranged in a ring shape, the outside of the stator Combine in the axial direction while keeping the diameter dimension slightly larger than the regular dimension, connect the convex part and the concave part, temporarily arrange them in a ring, and then reduce the outer diameter of the stator to the regular dimension. 2. The method for manufacturing a stator for a capacitor motor according to claim 1, wherein the stator is fitted and integrated into a recess. The winding start part and winding end part of the main winding and auxiliary winding are all provided on the main crossover side or all auxiliary crossover sides, and the lead wire processing of the main winding winding body and the auxiliary winding winding body is mainly performed. 2. The method for manufacturing a stator for a capacitor motor according to claim 1, wherein the process is performed on the crossover side or the auxiliary crossover side. 2. The capacitor motor fixed according to claim 1, wherein the divided iron cores are arranged in a substantially circular shape, and the main winding and the auxiliary winding are wound in series to manufacture the main winding and the auxiliary winding. Child manufacturing method. A division in which a yoke portion having an arc surface on the outer periphery and a tooth portion having a rotor facing surface formed on the inner surface side are connected, and a predetermined number of divided iron core plates that are divided into the same number as the number of slots are punched and laminated and fixed. An iron core body, a main winding winding body in which the main winding is wound around the divided iron core body with a concentrated winding via an insulator, and several poles are continuously wound in a straight series through a crossover, In an electric motor stator having an auxiliary winding wound around the divided iron core body with concentrated winding via an insulator and concentratedly wound continuously with several poles continuously via a crossover . The main winding and the auxiliary winding are wound by arranging the divided cores of several poles for winding the main winding and the divided cores of several poles for winding the auxiliary winding, respectively, in a ring shape. In this way, a main winding and an auxiliary winding are formed, and a main crossover side provided with a crossover of the main winding and an auxiliary crossover provided with a crossover of the auxiliary winding. ~ side It said main winding wire wound Sokarada and the auxiliary winding wire wound Sokarada and capacitor motor stator formed by annularly arranged alternately so as to be disposed opposite side of the scissors axis divided iron core. 7. The capacitor motor stator according to claim 6, wherein the winding start portion and the winding end portion of the main winding and the auxiliary winding are all provided on the main crossover side or all the auxiliary crossover sides. A punching step of connecting 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 and punching a divided iron core plate divided into the same number as the number of slots; A lamination step of forming a divided iron core body in which a predetermined number of core plates are laminated and fixed, and a number of poles of a main winding wound body in which main windings are wound around the divided iron core body by concentrated winding via an insulator. After arranging a plurality of auxiliary winding winding bodies in which auxiliary windings are wound by concentrated winding on the divided iron core body via an insulator through an insulator, each of the main winding windings is arranged in an annular shape. The main winding winding and the auxiliary winding winding are opposed to the auxiliary winding winding arranged in a ring like the body, and the outer diameter of the stator is slightly larger than the regular size. Are moved in the axial direction so that they are alternately positioned, and they are temporarily arranged in a ring, and then the stator outer diameter is reduced to the regular size and integrated. Method for manufacturing a capacitor motor stator manufactured by the method.

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