KR100279849B1 - Slot insulator for motor - Google Patents

Abstract

The present invention relates to a slot insulator of a motor, and to improve an insulation structure that is difficult to shorten the conventional winding operation time. The slot insulator 40 for the winding method of the present invention is to individually insulate each pole value 11 of the stator 10 and a portion of the slot 12 adjacent thereto, and is detachable from the stator 10. That is, the slot insulator 40 has the form of the bobbin with respect to the salient pole 11. Accordingly, the winding operation may be performed by winding the winding 30 to the slot insulator 40 outside the stator, and then inserting and fixing the slot insulator 40 on which the winding 30 is wound to the salient pole 11. In this way, the winding work is performed in a free space outside the core of the stator so that the working time can be shortened, the winding number can be increased by winding it neatly, and the efficient winding work can be performed even with a simple dedicated device rather than an expensive automatic winding machine do. Therefore, the present invention increases the productivity of the motor and at the same time is effective in cost reduction, and is advantageous in miniaturization and high performance.

Description

Slot Insulator for Motors {SLOT INSULATOR FOR MOTOR}

The present invention relates to a slot insulator of a motor that can be applied well to the windings of a motor with a concentrated winding, in particular a salient pole stator such as a switched reluctance motor. The present invention relates to a winding method of winding a focus on teeth and a slot insulator of a motor to insulate the teeth and slots of a stator core into which the focus is inserted.

The motor has a winding inserted into at least one of the stator and the rotor as an electric circuit, and the winding zone is wound around each tooth formed in the iron core according to the winding method, and several windings on several teeth There is a distributed winding that distributes 1 to make a phase. For a motor having a double electron concentration zone, it is natural that the winding operation can be made easier by providing a slot insulator that can be inserted around each tooth after the winding operation is performed externally.

In this regard, Figure 1 shows the insulation structure of a conventional variable reluctance motor with a concentrated winding. As shown, the variable reluctance motor is a bipolar pole type in which both the stator 1 and the rotor 2 have the salient poles 3 and 4, and a plurality of windings around each of the salient poles 3 of the stator 1 are provided. Windings 6a, 6a ', 6b, 6b', 6c, and 6c '. Of course, the peripheral surface of the salient pole value 3 and the both side slots 5 which form the salient pole value 3 are insulated by the slot insulator 7. As shown in FIG. On the other hand, the rotor 2 is made of only an iron core which is a magnetic anisotropic soft magnetic material that can be magnetized in a magnetic field without a winding or a permanent magnet. That is, when the windings 6a, 6a ', 6b, 6b', 6c, and 6c 'wound around the poles 3 of the stator 1 are sequentially excited, the poles 3 wound around the excited windings are wound. The rotor (2) by magnetizing and attracting the most adjacent one of the salient pole values (4) of the rotor (2) while having a magnetic pole (N pole or S pole) according to the direction of the current (winding direction) flowing through the rotor 2 Rotates one step (16 ° in the case of drawing).

Specifically, FIG. 1 shows a state in which A-phase windings 6a and 6a 'and C-phase windings 6c and 6c' are simultaneously excited. In this state, if only the phase A windings 6a and 6a 'are excited, the rotor rotates 15 ° counterclockwise. Subsequently, the A phase windings 6a and 6a 'and the B phase windings 6b and 6b' are excited, and the B phase windings 6b and 6b 'are next followed by the B phase windings 6b and 6b'. And the C phase windings 6c and 6c 'and then the C phase windings 6c and 6c' are sequentially excited to rotate the rotor 2 continuously.

As a conventional insulation structure for such a variable reluctance motor, the slot insulator 7 as shown in FIG. 1 has a slot and a peripheral surface of the salient pole 3 except the pole of the salient pole 3. (5) It is formed integrally with the iron core by so-called outsert molding, which is a method of coating a part of the iron core including the inner surface with an insulating resin material.

Winding work for a motor with the slot insulator 7 formed integrally is generally possible by primitive hand work, but is usually done automatically in an automatic winding machine in view of productivity. The automatic winding machine, although not shown in the drawings, usually has a needle leading the enamel coated copper wire introduced from the outside, and forms a complicated structure in which the needle moves around the stator pole 3 to wind the wire. have.

However, the stator iron core of the variable reluctance motor is relatively small, and due to the structure of the salient pole, the slot entrance between adjacent salient pole values is not so large, and is further narrowed by the wing portion of the slot insulator 7 integrally formed therein. Furthermore, the needle of the above-described winding machine cannot be moved quickly. In addition, because the winding work for the salient poles protruding from one stator cannot be done at the same time and each salient pole must be wound sequentially, the total winding time is considerably delayed. This delay in winding time is weighted the larger the number of poles and the smaller the pole value.

Therefore, in the slot insulation structure formed integrally with the iron core for the motor, it takes a long time for the winding operation for the salient pole, which is a major factor causing the problem of deterioration of the productivity of the motor. In addition, the number of windings that can be wound around one pole pole is difficult because the winding poles protruding from the iron core for the motor are not uniformly wound in a multilayer, and the limitation of design freedom considering the use and performance of the motor, and the winding It is difficult to miniaturize due to the limited number of times.

In addition, the above-described automatic winding machine is very complicated and expensive in the facilities that need to be equipped to produce a motor, so the cost of purchasing, installing and operating it is excessive, and it is pointed out that a problem that greatly increases the cost of the motor. will be.

It is an object of the present invention to provide a slot insulator for a motor that can shorten the time required for winding during its production process in order to increase the productivity of the motor.

Another object of the present invention is to provide a slot insulator of a motor capable of increasing the number of turns in a limited size to enable miniaturization.

Another object of the present invention is to provide a winding method of a motor and a slot insulator for winding the motor in a winding machine which is much simpler and cheaper than a conventional automatic winding machine which is expensive in order to reduce a cost increase factor.

1 is a plan view showing an insulating structure of a conventional variable reluctance motor.

Figure 2 is a plan view showing the insulating structure of a variable reluctance motor to which the present invention is applied.

FIG. 3 is a perspective view of a part of the stator of the variable reluctance motor shown in FIG. 2 and a slot insulator separated therefrom; FIG.

Figure 4 is a side cross-sectional view showing a state in which the slot insulator according to the invention is inserted and fixed around the stator pole teeth.

Figure 5 is a cross-sectional view showing a state in which the slot insulator according to the present invention is inserted and fixed around the stator pole teeth.

6 is a cross-sectional view showing another embodiment in which the slot insulator according to the present invention is inserted and fixed around the stator salient pole.

Explanation of symbols on the main parts of the drawings

10: stator 11: salient extreme

12: slot 30: winding

40: slot insulator 41: coil bobbin body

42 hollow part 43 winding front support part

44: winding back support 45: iron core support

46: uneven portion

A slot insulator according to the present invention for achieving the above objects, in the slot insulator for the winding of the motor having a plurality of slots formed at regular intervals and an iron core having a plurality of teeth formed between the slots, A coil bobbin body having a hollow portion into which each tooth can be inserted, which insulates the peripheral surface of each tooth, for winding the winding zone; A portion of the peripheral surface of each tooth that meets the inner side of the slot that meets the side portion located in the slot, and closes the rear portion of the coil bobbin body so as to insulate the rear portion of the coil bobbin body and the upper and lower sides of the coil bobbin body and the upper and lower sides of the coil bobbin body. An iron core support extending from the edge in a horizontal plane to accommodate the thickness of the iron core, To construct a structure comprising in combination with a value for the holding means to be able to be fixed does not escape nature.

That is, the present invention improves the insulation structure in the form of assembling the coil core in the form of a coil bobbin in the structure that was conventionally insulated by the method of external molding, so that the winding work in the iron core can be performed from the outside, the winding work time It is possible to shorten to increase the productivity, as well as miniaturization and cost reduction, the preferred embodiment will be described in detail with reference to the accompanying drawings as follows.

Figure 2 shows a variable reluctance motor with improved insulation in accordance with the present invention. In the figure, reference numeral 10 denotes a stator, 20 a rotor, and 30 a winding. Here, the stator 10 has protrusions 11 and slots 12 alternately formed at regular intervals. Each salient pole 11 of the stator 10 and a portion of the slot 12 adjacent thereto are individually insulated by a slot insulator 40 having an improved construction in accordance with the present invention.

The slot insulator 40 is a molded product of an insulating synthetic resin produced by a separate injection mold, and as shown in FIG. 3, the coil bobbin body 41 having the hollow part 42, and the coil bobbin body 41. Winding front support portion 43 formed at the leading edge of the), winding rear support portion 44 extending in a curved shape on both sides of the coil bobbin body 41, upper and lower surfaces of the coil bobbin body 41 and the winding rear support portion 44 Consists of the iron core support portion 45 extending in the horizontal plane at the upper and lower edges of the).

The hollow part 42 of the coil bobbin body 41 of the slot insulator 40 has a form in which the pole teeth 11 formed on the iron core of the stator 10 can be fitted. Here, the slot insulator 40 has a jaw 14 on both the left and right sides of the pole electrode 11 and the pole electrode 13 instead of having a separate shape as a means for being fixed in the state where the pole electrode 11 is inserted. As shown in Fig. 4, the jaw 14 formed in the protrusion 11 is fixed so that it can be fixed by exiting the front side opening of the hollow part 42 and covering the left and right edges (not shown) of the opening. It is.

The winding front support part 43 and the winding rear support part 44 of the slot insulator 40 support the front part 31 and the rear part 32 of the winding 30 wound around the coil bobbin body 41, respectively. The winding front support part 43 serves to prevent the winding 30 from falling forward from the coil bobbin body 41, and the winding rear support part 44 is wound on the opposite side of the winding front support part 43. At the same time supporting the rear side of the 32 is in close contact with the part of the inner surface 15 of the slot 12 in the state coupled to the stator iron core serves to insulate the portion.

On the other hand, the iron core support 45 of the slot insulator 40 accommodates the thickness of the iron core in the stator 10 to maintain a stable insulation and coupling state.

As described above, the present invention separately manufactures the slot insulator 40 having an improved insulation structure as a coil bobbin and separates the slot insulator 40 from the salient pole 11 of the stator 10. The winding work for the windings 30 is performed by winding the coil bobbin body 41 of the slot insulator 40 in an enamel coated copper wire outside the core of the stator 10, fixed to a dedicated winding machine that is not in use. 30 is a process of inserting the wound slot insulator 40 wound around each pole 11 of the stator 10, so that the winding can be finished simply and quickly.

In particular, the winding of the winding to the slot insulator 40, unlike the automatic winding machine of the conventional structure is possible, it is possible to a simple dedicated winding machine that can be rotated by holding the slot insulator 40, although not shown, in this case several The winding work for the slot insulator 40 can be performed simultaneously, and the two or more slot insulators 40 wound in series can be wound continuously without interrupting the winding, thereby reducing the number of wiring work thereafter. will be.

5 shows another embodiment of the slot insulator 40 according to the present invention as a fixing means for the salient pole 11 formed on the stator 10 iron core. That is, the concave-convex portion 46 corresponding to the inner surface of the hollow portion 42 of the coil bobbin body 41 and the circumferential surface of the salient pole 11 which comes into contact with the coil bobbin body 41 are formed. Of course, in this embodiment, it is not necessary to form the jaw 14 on both sides of the tooth 13 of the salient pole 11 shown in FIG. Therefore, the gap between the winding front support part 43 and the winding rear support part 44 of the slot insulator 40, that is, the effective length of the coil bobbin body 41 can be secured a little longer, which is advantageous to increase the number of turns. .

As described above, according to the present invention, by using a separate bobbin-type prefabricated improved slot insulator, the winding work can be performed outside the stator core free of space, and the winding work time can be further shortened. Therefore, the present invention is effective to increase the productivity of the motor by reducing the winding time.

In addition, according to the present invention, the winding work in a free space can be wound in a multi-layered winding on the slot insulator to increase the number of windings in the same size, which is based on the same torque performance, It means that the volume can be reduced by that much. Therefore, the present invention is effective in miniaturizing the motor and increasing the performance of high torque with a motor of the same size.

On the other hand, the present invention enables the winding operation as a simple dedicated winding machine that can be easily grabbed and turned rather than the conventional groin automatic winding machine in the winding operation. Therefore, it is not necessary to purchase expensive winding equipment for the production of the motor, thereby reducing the production cost and simultaneously increasing the productivity by winding a plurality of salient poles on a simple dedicated machine simultaneously.

As such, the present invention has the effect of increasing the productivity of the motor and at the same time reducing the production cost, thereby distributing the motor in large quantities at low cost, and increasing the design freedom of the motor for miniaturization and performance. It makes motor production possible.

The present invention is not limited to the variable reluctance motor as described above and illustrated in the drawings, or is intended only for the focus of the stator, but more variations and modifications are possible within the scope of the claims set out below. to be.

Claims (3)

A slot insulator for winding a motor having a plurality of slots formed at regular intervals and an iron core having a plurality of teeth formed therebetween, A coil front body having a hollow portion into which each tooth of the iron core can be inserted, the coil bobbin body for winding the winding zone by insulating the peripheral surface of each tooth, and the winding front surface formed at the tip of the coil bobbin body so as not to deviate from the front portion of the wound winding zone. Winding rear support extending to the rear end of the coil bobbin body and the upper and lower sides of the coil bobbin body so as to insulate the rear part of the coil bobbin body in close contact with the supporting part and the inner part of the slot which meets the side part located in the slot of each tooth. The motor of the motor characterized in that it comprises a fixing means for extending in the horizontal plane at the upper and lower edges of the support portion to accommodate the iron core thickness to accommodate the iron core thickness, and to be fixed so as not to be separated from nature by combining with each tooth of the iron core. Slot insulator. 2. The slot insulator of a motor according to claim 1, wherein said fixing means is provided with a jaw formed to be caught by the opening of the hollow portion of the tooth end portion of the iron core fitted to the hollow portion of the coil bobbin body. 2. The slot insulator of the motor according to claim 1, wherein the fixing means is provided with an uneven portion formed to correspond to an inner surface of the hollow portion of the coil bobbin body and a circumferential surface of the teeth of the iron core which is fitted and contacted with the hollow portion of the coil bobbin body.