JP3977224B2 - Stator for adduction motor and method for manufacturing the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a stator of an internal rotation type electric motor having a structure in which a winding is directly wound around a divided iron core body obtained by dividing a stator iron core into a plurality of parts, and then the divided iron core body is integrated into a ring shape and the stator It relates to a manufacturing method.
[0002]
[Prior art]
Conventionally, in a method for manufacturing a stator of this type of internal motor, a method for manufacturing a stator in which a plurality of divided iron cores are wound and then the divided iron cores are arranged annularly Is widely used (see, for example, Patent Document 1).
[0003]
Hereinafter, the stator of the internal-rotation motor will be described with reference to FIGS. 11 and 12.
[0004]
As shown in FIG. 11, the divided iron cores 201 insulated by the insulating materials 202 and 203 are held in a ring shape for each phase separately, and the A phase winding 204 is continuously passed over the poles. The wire 205 is connected and wound, and as shown in FIG. 12, a plurality of B-phase windings 206 are continuously connected by the connecting wire 207 and wound, and then fixed in a ring shape. It was a manufacturing method of a child.
[0005]
In addition, in this type of stator for an internal rotation type motor and a method for manufacturing the same, a long insulating material is attached to the divided iron core body a in a circumferential direction, and windings are wound for each phase. In addition, an annularly integrated one is also shown (for example, see Patent Document 2).
[0006]
Hereinafter, the stator of the internal motor and the manufacturing method thereof will be described with reference to FIGS.
[0007]
As shown in the figure, the stator iron core 300 is divided into a total of eight parts, including four divided iron cores a301 and four divided iron cores b304. The teeth 301-1 are arranged on the outer periphery of the wire so that the teeth 301-1 are substantially radial, and two A-phase winding wound bodies 307 around which the A-phase winding 306 is wound are separated from each other by 90 degrees in electrical angle. Two of the B-phase winding wound bodies 309 around which the B-phase windings 308 are wound are sandwiched between the divided iron cores b304 divided by the yoke portion 301-2 and alternately arranged in an annular shape and fixed. A child 310 is configured. Then, the insulating material 302 is applied to the divided iron core a301 with the upper surface, the lower surface and both side surfaces of the tooth portion 301-1, the inner peripheral surface of the circumferential protrusion 303 on the inner peripheral side of the tooth portion 301-1, and the yoke portion 301-. The inner peripheral surface of the divided inner core b304 of the inner peripheral surface 2 is mounted so as to extend linearly to about half of the inner peripheral surface, and the number of poles A-phase winding 306 and the number of poles B-phase winding 308 are After each winding is continuously wound in a separate process, and after winding is finished, the insulating material 302 is deformed into a shape along the arc of the inner peripheral surface of the divided iron core body b304, and then the A phase winding is performed. After the wire wound body 307 and the B-phase winding wound body 309 are alternately arranged in an annular shape, the stator 310 is obtained by combining and integrating the divided iron cores b304, and a method for manufacturing the same.
[0008]
[Patent Document 1]
JP 2000-358346 A [Patent Document 2]
Japanese Patent Laid-Open No. 2001-238378
[Problems to be solved by the invention]
In the conventional stator configuration shown in FIGS. 11 and 12, it is difficult to manage the connecting wire 205, and the divided iron cores 201, which are separately wound around several poles, are combined into an annular shape. There was a problem that it took a lot of work to do.
[0010]
Further, in the configuration shown in FIGS. 13 to 15, four divided iron cores a are arranged in an annular shape with the normal dimensions of the stator, and two-pole A-phase winding or two-pole B-phase winding is wound. In the case of direct winding by a wire machine (not shown), when the A phase winding is wound, the insulating material attached to the split iron core a for winding the B phase winding is the winding winding operation of the winding machine. Similarly, when the B-phase winding is wound, there is a problem that the insulating material attached to the divided iron core a for winding the A-phase winding becomes an obstacle to the winding work of the winding machine. .
[0011]
The present invention solves the above-described problem. Four divided iron cores a are arranged in an annular shape with a regular dimension of a stator, and a two-pole A-phase winding or a two-pole B-phase winding is wound. In the case of direct winding by a machine (not shown), when the A-phase winding is wound, the insulating material attached to the split iron core a for winding the B-phase winding is deformed and held, It is an object of the present invention to provide a stator of an adder type electric motor capable of winding operation and capable of assembling a divided iron core with less effort and a method for manufacturing the same.
[0012]
[Means for Solving the Problems]
In the stator of the internal motor according to the present invention, there are four divided iron cores a in which the stator core composed of four slots and four teeth is laminated integrally with the teeth and the yoke. The divided iron core body b, in which the yoke portions sandwiched between the divided iron core bodies a are stacked, is divided and divided into a total of four pieces, and the four divided iron core bodies a are used as stators. Hold the ring with regular dimensions in an annular shape, wind the work of winding the 2-pole A-phase winding and the 2-pole B-phase winding directly from the outer periphery of the motor stator by concentrated winding after insulation treatment In the insulation process, one slot insulating film Y per slot is mounted so that the end thereof is in the vicinity of the center of the slot outer periphery opening, and the teeth of the divided iron core a around which the winding is wound are attached. A slot far from the tooth portion of the split iron core a that winds the winding while deforming the end face of the near slot insulating film Y in the outer diameter direction The end face of the edge film Y is deformed and held so as not to be an obstacle to the winding work and wound, and after all the winding is completed, the divided iron core b is moved from the outer diameter direction toward the inner diameter direction. When moving, a stator manufacturing method for an adder type electric motor in which the stator is assembled while holding and moving and pressing the end surfaces of the slot insulating film Y to overlap is used.
[0013]
According to the present invention, the four tooth portions are fixed in an annular shape with the regular dimensions of the stator, the end face of the slot insulating film Y close to the tooth portions of the split iron core body a is deformed in the outer diameter direction, and the winding Since the end surface of the slot insulating film Y far from the tooth portion of the divided iron core a to be wound is deformed and held so as not to hinder the winding operation, the winding is wound, so that the assembly of the divided iron core can be performed with less effort. Is possible. Then, after all the windings are completed, when the divided iron core body b is moved from the outer diameter direction toward the inner diameter direction, the stator is held while moving and pressing the end surfaces of the slot insulating films so as to overlap each other. In addition, the insulating treatment uses one slot per slot, a total of four slot insulating films Y, and other insulating materials X, etc., and the circumferential end surfaces of the slot insulating films Y are at least 1 each other. The cutting length with an overlap part of 5 mm or more is set, and the axial length of the outer peripheral part of the slot center part and the inner peripheral part of the slot center part including the overlap part is set to the thickness of the stator core plus 3 mm or more. In order to secure the insulation distance between the winding and the stator iron core without inserting an insulating wedge, without attaching an insulating wedge or the like between the winding and the stator iron core, Line and the stator insulation distance can be made to secure a predetermined value or more of the inner rotor type motor between the stator iron core and it is possible to provide a manufacturing method thereof.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
According to the first aspect of the present invention, there are four divided iron cores a in which a stator iron core composed of four slots and four tooth portions is laminated integrally with the tooth portions and the yoke portions. And the divided iron core body b in which the yoke portions sandwiched between the divided iron core bodies a are separated and divided into a total of eight pieces, and the four divided iron core bodies a are normally used as stators. In the winding work of winding the 2-pole A-phase winding and the 2-pole B-phase winding directly from the outer peripheral side of the motor stator by concentrated winding after insulation treatment In the insulation process, one slot insulating film Y per slot is mounted so that the end thereof is in the vicinity of the center of the slot outer peripheral opening, and close to the tooth portion of the divided iron core a around which the winding is wound. The end surface of the slot insulation film Y is deformed in the outer diameter direction, and the slot insulation film far from the tooth portion of the divided iron core a around which the winding is wound. The end face of the mud Y is deformed and held so as not to interfere with the winding work, and the winding is wound. After all the windings are completed, the divided iron core b is moved from the outer diameter direction toward the inner diameter direction. In this case, the stator insulation is assembled while holding, moving and pressing the end surfaces of the slot insulating film Y so as to overlap each other, and it is possible to assemble the divided iron core with less effort. Have
[0015]
In the invention according to claim 2 of the present invention, there are four divided iron cores a in which a stator iron core composed of four slots and four tooth portions is laminated integrally with a tooth portion and a yoke portion. And the divided iron core body b in which the yoke portions sandwiched between the divided iron core bodies a are separated and divided into a total of four pieces, and only the four divided iron core bodies a are motor stators. The crossover wires are continuously arranged so that two-pole A-phase windings and two-pole B-phase windings are alternately arranged in a concentrated winding after insulation treatment. In the stator of the direct winding system, the insulating treatment uses one slot per slot, a total of four slot insulating films Y and other insulating materials X, and the like. The circumferential end faces have a cut length having an overlap portion of at least 1.5 mm and include the overlap portion. The axial length of the outer peripheral portion of the slot central portion and the inner peripheral portion of the slot central portion is set to a stack thickness of the stator core plus 3 mm or more, and the winding and the stator core can be connected without inserting an insulating wedge. The insulation distance is secured, and the insulation distance between the winding and the stator core can be secured without attaching an insulation wedge or the like.
[0016]
Further, the wall surface of the slot of the stator iron core is mainly insulated by the slot insulating film Y, and the upper and lower surfaces of the stator iron core are mainly insulated by another insulating material. X also has the function of preventing the slot insulating film Y from falling off.
[0017]
Embodiments of the present invention will be described below with reference to the drawings.
[0018]
【Example】
Example 1
As shown in FIGS. 1 to 10, a stator iron core 1 having four slots 15 is divided into four divided iron cores a4 and a yoke portion 3 in which a tooth portion 2 and a yoke portion 3-1 are integrated. The divided iron core body a2 is divided into eight parts with the four divided iron core bodies b5, and the tooth portions 3-1 are radially arranged on the outer periphery of the rotor hole 6, and the positions thereof are regular inside and outside. An insulating material X32-1, which is held at the same size and spacing and is arranged to be the same as when the stator 14 is completed, is resin-molded to insulate the upper surface and the temporary surface of the divided iron core body a2, and the divided iron core body After the insulation treatment by the insulating material 32 made of the slot insulating film Y32-2 that insulates the side surface of the slot 15 of a2 and the inner peripheral side surface of the divided iron core body b5, the tooth portion of the divided iron core body a2 around which the winding is wound The end face of the slot insulating film Y32-2 on the side close to the outer peripheral shape is deformed in the outer diameter direction, and the divided iron core a The two-phase A-phase winding 7 or B-phase winding 9 with respect to the divided iron core a2 in a state where the slot insulating film Y32-2 on the side far from the center is deformed and held so as not to hinder the winding operation. Is wound directly. Then, after the winding is completed, when the divided iron core b5 is moved from the outer diameter direction toward the inner diameter direction, the end face of the slot insulating film Y32-2 is held so as to overlap and fixed while moving and pressing. A manufacturing method for assembling the child 14 is used.
[0019]
In the above configuration, the four divided iron cores a2 can be wound around the A winding 2 and the B phase winding 5 while being held in an annular shape with the regular dimensions of the stator 14, and the slot insulating film Y32- Since the split iron core body b is assembled so that the ends of 2 overlap, there is no need to combine two A-phase winding bodies 10 and B-phase winding bodies 11 respectively, and an insulating wedge is used as the A-phase winding. Since it is not necessary to secure an insulation distance by inserting between the winding 2 and the B-phase winding 5 and the stator iron core, the stator 14 can be assembled with less effort.
[0020]
Further, in the same configuration, each of the four slots 15 of the stator core 1 is provided with one slot insulating film Y32-2 and other insulating material X32-1, and this slot insulating film Y32-2. The circumferential end surfaces of the slot 15 have an overlapping portion at least 1.5 mm or more at the outer peripheral portion of the central portion of the slot 15, and at the same time, the axial direction of the overlapping portion of the slot insulating film Y32-2 and the inner peripheral portion of the central portion of the slot 15 The length is set to a cutting length that is longer than the stack thickness of the stator core 1 plus 3 mm or more, that is, 1.5 mm or more from the load side end surface of the stator core 1 and 1.5 mm or more from the non-load side end surface.
[0021]
In the above configuration, the insulation distance between the two-pole A-phase winding 2 and B-phase winding 5 and the stator core 1 is reliably secured to 1.5 mm or more at the outer peripheral portion and inner peripheral portion of the central portion of the slot 15. Will be. The other portions are secured by an insulating material X32-1 at an insulation distance of a predetermined value or more.
[0022]
As shown in the drawing, the slot insulating film Y32-2 mounted along the wall surface of the slot 15 of the divided iron core body a4 includes a part of the insulating material X32-1 that insulates the upper surface of the divided iron core body a4. It is configured to be held by a part of the insulating material X32-1 that insulates the lower surface.
[0023]
In the above configuration, the slot insulating film Y32-2 is prevented from falling off from the slot wall surface of the stator core 1.
[0024]
In the embodiment, the axial length in the vicinity of the outer peripheral portion and the inner peripheral portion of the central portion of the slot 15 of the slot insulating film Y32-2 is set to the axial length of the stator core 1 plus 3 mm (1.5 mm on one side). In addition, the overlap size of the outer peripheral portion of the slot 15 of the slot insulating film Y32-2 is 1.5 mm or more, but this value should be changed according to the rated voltage of the motor, etc. It is to be decided.
[0025]
【The invention's effect】
As is apparent from the above embodiments, the present invention can provide a method for manufacturing a stator of an adder type electric motor that is effective in assembling the stator with less effort.
[0026]
In addition, it is possible to provide a stator for an internal rotation type motor having a configuration capable of ensuring an insulation distance between the stator winding and the stator iron core without mounting an insulating wedge or the like.
[0027]
Further, it is possible to provide a stator for an adder type electric motor capable of preventing the slot insulating film Y from falling off.
[Brief description of the drawings]
FIG. 1 is a front view showing a stator iron core of an adder type electric motor according to a first embodiment of the present invention. FIG. 2 is a perspective view showing four divided iron cores a of the stator iron core of the adder type electric motor. FIG. 3 is a perspective view showing details of a split iron core a of the same internal motor. FIG. 4 is a detailed perspective view showing four split iron cores b of a stator iron core of the same internal motor. FIG. 5 is a perspective view showing details of a split iron core b of the same internal motor. FIG. 6 is a diagram showing the arrangement of four split iron cores a of the stator iron core of the same internal motor in regular dimensions. FIG. 7 is a front view showing a state in which the end portion of the slot insulating paper Y attached to the split iron core body a of the same internal motor is deformed to wind the winding. FIG. 8 is a perspective view showing a state where the slot insulating paper Y of the internal motor is molded into a mounting shape. FIG. 9 is a front view showing a state where the slot insulating paper of the internal motor is developed. FIG. 11 is a partial cross-sectional view of the stator of the same internal motor. FIG. 11 is a front view showing the stator of the conventional internal motor. FIG. 12 is a winding on the split iron core a of the internal motor. FIG. 13 is a partial cross-sectional view of a stator of another conventional adder-type electric motor. FIG. 14 shows a state in which windings are wound around the split iron core body a of the adder-type electric motor. FIG. 15 is a front view showing a state in which an insulating material is molded after winding a winding around a split iron core body a of the same internal motor.
DESCRIPTION OF SYMBOLS 1 Stator iron core 2 Tooth part 3-1, 3-2 yoke part 4 Split iron core a
5 split iron core b
6 Rotor hole 7 A phase winding 9 B phase winding 10 A phase winding winding body 11 B phase winding winding body 14 Stator 32 Insulating material 32-1 Insulating material X
32-2 Slot insulation film Y

Claims (3)

A stator iron core composed of four slots and four tooth portions is sandwiched between four divided iron core bodies a in which the tooth portions and the yoke portions are integrally laminated, and the divided iron core body a. The divided iron core body b in which the yoke portions are laminated is divided and divided into a total of four pieces, and only the four divided iron core bodies a are held in an annular shape with the regular dimensions of the stator, and after insulation treatment In the winding work in which the two-pole A-phase winding is wound directly from the outer peripheral side of the motor stator and the two-pole B-phase winding is wound directly from the outer periphery of the motor stator, the insulation treatment is performed one piece per slot. The slot insulating film Y is mounted so that the end thereof is in the vicinity of the center of the slot outer peripheral opening, and the end of the slot insulating film Y close to the tooth portion of the divided iron core a around which the winding is wound is formed on the outer diameter. The end portion of the slot insulating film Y that is deformed in the direction and is far from the tooth portion of the divided iron core a that winds the winding is an obstacle to the winding work. When the divided iron core b is moved from the outer diameter direction toward the inner diameter direction after all the winding winding is completed, the end of the slot insulating film Y is deformed and held so as not to be deformed. A method for manufacturing a stator of an adder type electric motor having a structure in which the stator is assembled while being moved, pressed and held so as to overlap each other. A stator iron core composed of four slots and four tooth portions is sandwiched between four divided iron core bodies a in which the tooth portions and the yoke portions are integrally laminated, and the divided iron core body a. The divided iron core body b in which the yoke portions are laminated is divided and divided into a total of eight pieces, and only the four divided iron core bodies a are held while being annularly fixed with the regular dimensions of the stator. In the stator of the system in which the winding is continuously wound with the connecting wires continuously arranged so that the two-pole A-phase windings and the two-pole B-phase windings are alternately arranged in the concentrated winding after the insulation treatment, The insulating treatment uses one slot per slot, a total of four slot insulating films Y and other insulating materials X, and the circumferential ends of the slot insulating films Y are at least 1.5 mm or more from each other. The cut length has an overlapping part and the width of the outer peripheral part at the center of the slot including the overlapping part And the axial length of the predetermined width portion of the inner peripheral portion of the central portion of the slot is set to the stack thickness of the stator core plus 3 mm or more, and winding is performed without inserting an insulating wedge or the like on both the inner diameter side and the outer diameter side of the slot. A stator of an adder type electric motor having a configuration in which an insulation distance between a wire and a stator iron core is secured. The stator of an internal motor according to claim 2, wherein the slot insulating film Y is prevented from falling off by other insulating material X or the like.

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