KR100442284B1 - outer rotor type induction motor - Google Patents

Abstract

The present invention relates to an outer rotor type induction motor that can apply one rotor housing to all of motors of different capacities.

To this end, the outer rotor type induction motor of one embodiment of the present invention is fixed to the frame and stator iron cores 30a and 30b in which a plurality of stator slots are formed in parallel with the axial direction, and a coil 40 wound around the stator slot. And a rotor having a stator iron core and a predetermined gap outside the stator iron core, the driving shaft being coupled through the center thereof, and at least two support ends 113a and 113b having different heights along an inner circumferential surface thereof. The housing 110 and the rotor conductors 200a and 200b press-fitted into the inner circumferential surface of the rotor housing to a support end capable of maintaining the same height as the height of the stator iron core among the support ends.

Description

Outer rotor type induction motor

The present invention relates to an induction motor, and more particularly, to an outer rotor type induction motor having a rotor outside the stator.

In general, an electric motor is a machine that obtains rotational power by converting electrical energy into mechanical energy, and is roughly classified into an AC motor and a DC motor, and among them, an induction motor is a kind of AC motor.

Such an induction motor is an electromagnetic induction of the primary winding connected to the power source, and current is induced in the secondary winding, and the rotational torque is obtained by the interaction between the current induced in the secondary winding and the rotor field. According to the position, it is further classified into an inner rotor type induction motor and an outer rotor type induction motor. The inner rotor type induction motor is generally a kind of induction motor widely applied to a washing machine and the like, and has a rotor provided inside the stator.

However, the inner rotor type induction motor has a disadvantage in that the torque produced in the same volume is limited because the radius of the rotor is limited as the rotor rotates through the inside of the stator. In addition, a disadvantage has been raised that the usability of the internal space is deteriorated. Therefore, recently, an induction motor capable of increasing the torque at the same volume by using a rotor on the outside of the stator and using the internal space of the stator for other purposes has been proposed. Presented. Such an induction motor is called an outer rotor type induction motor.

Hereinafter, the general structure of the outer rotor type induction motor will be described briefly.

1 is a cross-sectional view schematically illustrating a structure of a general outer rotor type induction motor, wherein the outer rotor type induction motor has a rotor housing 10 of a magnetic material coupled to a driving shaft 50 through a center thereof, and the rotor A rotor conductor 20 provided on an inner circumferential surface of the housing and forming a closed circuit; a stator iron core 30 in which a plurality of steel sheets are stacked to maintain a predetermined gap with the rotor conductor inside the rotor housing; It is provided on the stator iron core and is composed of a coil 40 is applied to the AC power to form a rotating magnetic field.

The rotor housing 10 has a cylindrical shape with an open top surface, and an insertion hole 11 through which a drive shaft penetrates is formed at a center of a bottom surface thereof, and a support end 13 for supporting a rotor conductor press-fitted to a predetermined height side is provided. It is formed along the inner circumferential surface. In addition, a plurality of blades 17 are further provided on the bottom of the rotor housing 10 to simultaneously cool the coils, and at the same time, induce forced circulation of air.

The rotor conductor 20 is pressed into the support end 13 along the inner circumferential surface of the rotor housing 10, and current is induced from the coil 40 to generate rotational torque. To this end, the rotor conductor 20 is made of a plurality of steel sheets are stacked, such as stator iron core (30).

The stator core 30 forms a concentric circle with the rotor housing 10 and forms a passage for the magnetic flux generated by the rotor field. To this end, the stator iron core 30 is configured by stacking a plurality of electrical steel sheets having a central center so that the drive shaft 50 penetrates. At this time, each of the electrical steel sheet has a plurality of stator slots 31 are formed radially on the outer circumferential side, a fastening screw insertion hole 33 for fixing the stator iron core on the inner circumferential side. Therefore, the stator iron core 30 is configured by stacking the stator slot 31 and the fastening screw insertion hole 33 so as to be continuous along the axial direction.

At this time, the stator iron core 30 is fixed to the frame 1 through a separate fastening screw 35. The frame 1 is provided at the upper portion of the rotor housing 10, and a bearing mounting portion for supporting the bearing 55 provided at the outer circumference of the drive shaft 50 is formed at the center thereof.

The coil 40 is not wound through the opening of the stator slot 31 in a pre-wound form, but is wound directly onto the stator slot through a winding machine, and the shape thereof is a distribution range.

Referring to the operation of the induction motor configured as described above, the alternating current is applied to the coil 40 generates a magnetic field to rotate the magnetic flux through the stator core 30, such a rotating magnetic flux through the air gap By linking with the rotor conductor 20, current is induced in the rotor conductor. At this time, the current induced in the rotor conductor 20 generates a torque according to Fleming's left hand law together with the magnetic flux.

On the other hand, in the outer rotor type induction motor as described above, the capacity of the electric motor depends on the stack height of the stator iron core 30 and the height of the rotor conductor 20. At this time, the stator iron core 30 and the rotor conductor 20 may be smoothly performed when the motor is installed in parallel with each other having the same height. Therefore, in order to change the capacity of the motor, the height of the rotor conductor 20 must be varied while the stack height of the stator iron core 30 must be changed.

However, when the height of the rotor conductor 20 is different, the rotor housing 10 must be newly manufactured. Because the rotor conductor 20 is a member that rotates at high speed, the rotor conductor 20 is not supported by the rotor housing 10 through screw fastening, but is pressed into and fixed to the support end 13 of the rotor housing. to be. By the way, a considerable additional cost was required to newly manufacture the rotor housing 10 to match the height of the rotor conductor 20. That is, since the rotor housing 10 is a member connecting the drive shaft 50 and the rotor conductor 20, the rotor housing 10 is manufactured by pressing a metal having high strength of the iron system, and the rotor housing is newly manufactured. In order to do this, a new press mold must be made. This is a considerable cost, which was a significant limitation in varying the capacity of the outer rotor type induction motor.

The present invention has been made to solve the above problems, an object of the present invention is to provide an outer rotor type induction motor that can be applied to all of the rotor housing of the different capacity.

1 is a cross-sectional view schematically showing the structure of a general outer rotor type induction motor

Figure 2 is a perspective view showing a rotor housing of the induction motor according to the first embodiment of the present invention

3 is a perspective view showing a state in which the rotor conductor is pressed into the rotor housing of the induction motor according to FIG.

4A and 4B are cross-sectional views illustrating a state in which the outer rotor type induction motor according to the first embodiment of the present invention is applied to different capacities.

5A and 5B are cross-sectional views illustrating a state in which the outer rotor type induction motor according to the second embodiment of the present invention is applied to different capacities.

6A and 6B are cross-sectional views illustrating a state in which an outer rotor type induction motor according to a third embodiment of the present invention is applied to different capacities.

Explanation of symbols on the main parts of the drawings

30a, 30b: stator iron core 40: coil

110: rotor housing 111: drive shaft insertion hole

113a, 113b: Supporting end 115: Ventilation opening

117: blade 200a, 200b: rotor conductor

300: spacer 400: screw

In order to achieve the above object, the outer rotor type induction motor of one embodiment of the present invention is fixed to the frame and a plurality of stator slots are formed in parallel with the axial direction, the stator slot, the coil wound on the stator slots, A rotor housing provided outside the stator core to maintain a predetermined gap with the stator core, and a drive shaft coupled through the center thereof, the rotor housing having at least two support ends having different heights along an inner circumferential surface thereof, and stator iron cores among the support ends; And a rotor conductor press-fitted into the inner circumferential surface of the rotor housing to a support end capable of maintaining the same height as that of the rotor.

Accordingly, the outer rotor type induction motor of one embodiment of the present invention is pressurized to an appropriate support end of the rotor housing so that the rotor conductor corresponds to the height of the stator core, thereby increasing the capacity of the motor without separately manufacturing the rotor housing. Can be varied.

Next, the outer rotor-type induction motor according to another aspect of the present invention is fixed to the frame and a plurality of stator slots are formed in parallel with the axial direction, the stator iron core, the coil wound on the stator slots, outside the stator iron core A rotor housing provided to maintain the stator core and a predetermined gap, the drive shaft being coupled through a center thereof, and a support end having a predetermined height formed along an inner circumferential surface thereof, a rotor conductor press-fitted into the inner circumferential surface of the rotor housing; It includes a depth adjusting means provided between the rotor conductor and the support end to adjust the indentation depth of the rotor conductor so that the rotor conductor can maintain the same height as the stator iron core.

Accordingly, the outer rotor type induction motor according to another aspect of the present invention includes a separate depth adjusting means between the support end and the rotor housing even if the support end of the rotor housing has a single height, thereby providing the rotor conductor. The height corresponding to the stator iron core can be maintained, and thus the capacity of the motor can be changed without separately manufacturing the rotor housing.

Hereinafter, with reference to the accompanying drawings, the outer rotor-type induction motor according to a preferred embodiment of the present invention will be described in more detail.

First, Figure 2 is a perspective view showing a rotor housing of the induction motor according to the first embodiment of the present invention, Figure 3 shows a state in which the rotor conductor is pressed into the rotor housing of the induction motor according to FIG. 4A and 4B are cross-sectional views illustrating a state in which the outer rotor type induction motor according to the first embodiment of the present invention is applied to different capacities.

The outer rotor type induction motor according to the present invention is fixed to the frame and a plurality of stator slots are formed in parallel with the axial direction, the stator iron core, the coil wound on the stator slot, and the stator iron core concentric with the stator on the outside The rotor housing is provided to maintain a predetermined gap with the iron core, and the drive shaft is coupled through the center thereof, and the rotor conductor is pressed into the rotor housing and forms a closed circuit. This configuration is the same as that shown in Figure 1, except for the structure of the rotor housing and the rotor conductor is the same as described above, the detailed description thereof will be omitted.

As shown in FIG. 2, the rotor housing 110 of the outer rotor type induction motor according to the first embodiment of the present invention has an insertion hole 111 through which a drive shaft penetrates a center of a bottom surface thereof in a cylindrical shape with an open top surface. It is formed, the support end 113 for supporting the rotor conductor indented to the predetermined height side is formed along the inner peripheral surface. At this time, the height of the support end 113 determines the indentation depth of the rotor conductor. In addition, a plurality of blades 117 are further provided on the bottom of the rotor housing 110 to simultaneously form a plurality of vents 115 to facilitate cooling of the coil.

In this case, the support end 113 is not formed with a single height along the inner circumferential surface of the rotor housing 110, but is formed stepped along the inner circumferential surface of the rotor housing such that at least two height differences occur. This is to correspond to the height of the rotor conductor press-fitted to the support end 113.

For example, in FIG. 2, the support end 113 includes a first support end 113a having a predetermined height from a bottom of the rotor housing, and a second support end 113b having a height higher than that of the first support end. Is shown. In this case, a plurality of the second support ends 113b are spaced apart by a predetermined angle along the inner circumferential surface of the rotor housing 110. For example, four second support ends spaced at an angle of 90 ° are illustrated. have. At this time, the height of the first support end 113a and the second support end 113b depends on the height of the rotor conductor selected according to the capacity of the motor, which means that it depends on the height of the stator core.

Therefore, the rotor conductor is press-fitted to the support end that can maintain the same height as the height of the stator iron core of the support end 113, the support end is the first support end 113a and the second support end there is a height difference The rotor conductor may include two kinds of rotor conductors having different heights, which may be selectively pressed into the first support end or the second support end.

At this time, when the rotor conductor is press-fitted to any support end 113, another support end having a higher height than the support end should be press-in through the outer circumferential surface of the rotor conductor. Otherwise, it would be impossible for the rotor conductor to be pressed into the desired support end.

Specifically, FIG. 3 illustrates a state in which the rotor conductor having the highest height among the rotor conductors is pressed into the rotor housing. Accordingly, the rotor conductor 200 should be press-fitted to the first support end of the rotor housing 110. For this purpose, a plurality of press-fit grooves in which the second support end may be press-fitted on the outer circumferential surface of the rotor conductor 210 is formed. If the press groove 210 is not formed, the rotor conductor 200 is press-fitted only to the second support end, and it is impossible to press-fit below it.

At this time, the press-in groove 210 should be formed at the same position as the position where the second support end is formed in the rotor housing 110, and thus are formed one at four points dividing the rotor housing by 90 °. .

The rotor housing configured as described above is commonly applied to different capacities as shown in FIGS. 4A and 4B.

First, the outer rotor type induction motor shown in FIG. 4A has a high capacity, and a high capacity stator core 30a is fixed to the frame and positioned at an appropriate height inside the rotor housing 110. At this time, the rotor conductor 200a is a high capacity having the same height as the stacking height of the stator iron core 30a, and is press-fitted to the first support end 113a of the rotor housing so as to be parallel to the stator iron core. do. At this time, the second support end 113b of the rotor housing is pressed into the press-in groove 210 formed on the outer circumferential surface of the rotor conductor.

Next, the outer rotor type induction motor shown in FIG. 4B is of a small capacity, and a small capacity stator core 30b is fixed to the frame and positioned at an appropriate height inside the rotor housing 110. At this time, the rotor conductor 200b is of a small capacity having the same height as the stacking height of the stator iron core 30b, and is pressed into the second support end 113b of the rotor housing so as to be parallel to the stator iron core. do.

As described above, the rotor housing 110 is applied to both of the two different capacities in the same one member. On the other hand, the rotor housing 110 is not limited thereto. That is, by adjusting the number of support ends in which the height difference exists, the rotor conductors having different heights may be press-fitted, and thus, the outer rotor type induction motor of various capacities may be configured with one rotor housing.

5A and 5B are cross-sectional views illustrating a state in which the outer rotor type induction motor according to the second embodiment of the present invention is applied to different capacities.

5A and 5B, the outer rotor type induction motor according to the second embodiment of the present invention is fixed to a frame and stator iron cores 30a and 30b in which a plurality of stator slots are formed parallel to the axial direction, A coil wound around the stator slot, the rotor housing 120 having a concentric circle with the stator iron core, and having a stator iron core and a predetermined gap therebetween, and having a driving shaft coupled thereto through the center thereof; Rotor conductors 200a and 200b press-fitted into a closed circuit and depth adjusting means 300 for adjusting the press-in depth of the rotor conductor so that the rotor conductor can maintain the same height as the stator core.

The rotor housing 120 has a cylindrical shape with an open top surface, and an insertion hole 121 through which a drive shaft penetrates is formed at a center of the bottom surface, and a plurality of ventilation holes 125 for smoothing cooling of the coil around the insertion hole. Is formed, and a plurality of blades 127 are provided to induce forced circulation of air. A support end 123 having a predetermined height is formed along the inner circumferential surface of the rotor housing 120. The support end 123 determines the indentation depth of the rotor conductors 200a and 200b, and determines the indentation depth of the rotor conductor for high capacity, that is, the rotor conductor 200a having the highest height. Therefore, when the rotor conductor 200b for low capacity is pressed into the rotor housing 120, a separate member supporting the rotor conductor in order to position the rotor conductor in parallel with the stator core 30b. Is required. This is the depth adjusting means 300.

As the depth adjusting means 300, in the second embodiment of the present invention, a spacer is provided between the rotor conductor 200b and the support end 123 to fill a space therebetween. When the low capacity rotor conductor 200b is press-fitted, the spacer 300 is press-fitted into the upper part of the support end 123 in advance, and as a result, the rotor conductor is press-fitted to the upper part of the spacer and the stator iron core 30b and Thus, the height of the spacer 300 is determined by the height of the low capacitance rotor conductor 200b.

The rotor housing configured as described above is commonly applied to different capacities as shown in FIGS. 5A and 5B. That is, as shown in Figure 5a, in order to configure a high capacity outer rotor-type induction motor, a high capacity stator core 30a is fixed to the frame and positioned at a predetermined height inside the rotor housing 120, A high capacity rotor conductor 200a is pressed into the support end 123 along the inner circumferential surface of the rotor housing. In this case, the height of the stator iron core 30a and the height of the rotor conductor 200a are the same, and as the bottom surface of the stator iron core is positioned to the support end 123 of the rotor housing, the stator iron core and the rotor conductor Are located parallel to each other.

Next, as shown in FIG. 5B, in order to configure a small capacity outer rotor type induction motor, a small capacity stator core 30b is fixed to a frame and positioned at a predetermined height inside the rotor housing 120. A small capacity rotor conductor 200b is press-fitted along the inner circumferential surface of the rotor housing. At this time, the spacer 300 having a predetermined height is pressed into the support end 123 along the inner circumferential surface of the rotor housing 120, and the rotor conductor 200b is pressed into the spacer. In this case, the heights of the stator iron core 30b and the rotor conductor 200b are the same, and as the bottom surface of the stator iron core is positioned to the upper end of the spacer 300, the stator iron core and the rotor conductor are positioned parallel to each other. do.

As described above, the rotor housing 120 is applied to both of the two states with different capacities as one member together with the spacer 300. On the other hand, the rotor housing may be applied to the outer rotor-type induction motor of a different capacity according to the height of the spacer.

6A and 6B are cross-sectional views illustrating a state in which an outer rotor type induction motor according to a third embodiment of the present invention is applied to different capacities.

As shown in Figure 6a and 6b, the outer rotor type induction motor according to the third embodiment of the present invention is fixed to the frame and the stator iron core (30a, 30b) in which a plurality of stator slots are formed in parallel with the axial direction, A coil 40 wound around the stator slot, the rotor housing 130 having a concentric circle with the stator iron core and provided to maintain a predetermined gap with the stator iron core and having a drive shaft coupled through the center thereof; Rotor conductors 200a and 200b press-fitted into the rotor housing and forming a closed circuit, and depth adjusting means 400 for adjusting the press-in depth of the rotor conductor so that the rotor conductor can maintain the same height as the stator core. It is composed.

The rotor housing 130 has an insertion hole 131 through which a drive shaft penetrates is formed in the center of the bottom surface, and a plurality of ventilation holes 135 for cooling the coil are formed around the insertion hole, and a plurality of inducing forced circulation of air is provided. Blade 137 is provided. A support end 133 having a predetermined height is formed along the inner circumferential surface of the rotor housing 130. The support end 133 determines the indentation depth of the rotor conductor, and determines the indentation depth of the rotor conductor 200a for high capacity, that is, the rotor conductor having the highest height. Thus, when the rotor conductor 200b for low capacity is pressed into the rotor housing 130, a separate depth for supporting the rotor conductor so that the rotor conductor is located parallel to the stator core 30b. Adjusting means 400 is required.

With the depth adjusting means 400, in the third embodiment of the present invention, a screw penetrates into the space between the rotor conductor 200b and the support end 133 through the side of the rotor housing. That is, the screw 400 is inserted into the through the side of the rotor housing 130 to contact the bottom surface of the rotor conductor 200b, thereby supporting the rotor conductor. To this end, a plurality of screw fastening holes 139 are formed on the side of the rotor housing 130 through which the screw 400 can be fastened. At this time, the press-in depth of the rotor conductor 200b depends on the height of the screw fastening hole 139. Therefore, the screw fastening hole 139 should be formed between the upper end of the rotor housing 130 and the support end 133, more preferably, a plurality of different heights are formed. 6A and 6B, for example, two kinds of screw fastening holes 139 having different heights are formed. In this case, the rotor housing 130 may accommodate three rotor conductors of different heights.

The rotor housing configured as described above is commonly applied to different capacities as shown in FIGS. 6A and 6B. That is, as shown in Figure 6a, in order to configure a high capacity outer rotor-type induction motor, a high capacity stator core 30a is fixed to the frame and positioned at a predetermined height inside the rotor housing 130, A high capacity rotor conductor 200a is press-fitted to the support end 133 along the inner circumferential surface of the rotor housing 130. In this case, the height of the stator iron core 30a and the height of the rotor conductor 200a are the same, and as the bottom surface of the stator iron core is positioned up to the support end 133 of the rotor housing, the stator iron core and the rotor conductor Are located parallel to each other.

Next, as shown in Figure 6b, in order to configure a small capacity outer rotor-type induction motor, a small capacity stator core (30b) is fixed to the frame and located at a predetermined height inside the rotor housing 130, A small capacity rotor conductor 200b is press-fitted along the inner circumferential surface of the rotor housing. At this time, the screw 400 penetrates into the rotor housing through the screw fastening hole 139 of the rotor housing, and the rotor conductor 200b is press-fitted to the screw. In this case, the heights of the stator iron core 30b and the rotor conductor 200b are the same, and as the bottom surface of the stator iron core is positioned up to the screw 400, the stator iron core and the rotor conductor are positioned parallel to each other.

As described above, the rotor housing 130 is applied to both of the two states with different capacities as one member together with the screw 400. On the other hand, the rotor housing may be applied to the outer rotor type induction motor of a more various capacity according to the height of the screw fastening hole.

So far, the present invention has been described with reference to preferred embodiments thereof, and one of ordinary skill in the art to which the present invention pertains may implement the modified embodiment within the essential technical scope of the present invention. Here, the essential technical scope of the present invention is shown in the claims, and the modified forms within the equivalent range will be construed as being included in the present invention.

As the outer rotor type induction motor according to the present invention can accommodate all of the rotor conductors having various heights in one rotor housing, it is applicable to various electric motors having different capacities. Therefore, the cost of having to separately manufacture the rotor housing according to the capacity of the motor provides an effect that can be significantly reduced.

Claims (6)

A stator iron core fixed to the frame and having a plurality of stator slots formed parallel to the axial direction; A coil wound around the stator slot; A rotor housing provided at an outer side of the stator iron core to maintain a predetermined gap with the stator iron core, and having a driving shaft coupled through the center thereof, and having at least two support ends having different heights along an inner circumferential surface thereof; An outer rotor type induction motor including a rotor conductor press-fitted into the inner circumferential surface of the rotor housing to a support end capable of maintaining the same height as the height of the stator iron core among the support ends. The method of claim 1, When the rotor conductor is press-fitted to an arbitrary support end, a plurality of indentation grooves are further formed on the outer circumferential surface of the rotor conductor so that a support end having a height higher than the support end is press-fitted to the rotor conductor. Outer rotor type induction motor. A stator iron core fixed to the frame and having a plurality of stator slots formed parallel to the axial direction; A coil wound around the stator slot; A rotor housing provided outside the stator core to maintain a predetermined gap with the stator core, and a driving shaft coupled through the center thereof, and a support end having a predetermined height along an inner circumferential surface thereof; A rotor conductor pressed into an inner circumferential surface of the rotor housing; And an outer rotor type induction motor provided between the rotor conductor and the support end to adjust the indentation depth of the rotor conductor so that the rotor conductor can maintain the same height as the stator iron core. The method of claim 3, wherein The depth adjusting means is an outer rotor type induction motor, characterized in that the annular spacer (spacer) is provided between the rotor conductor and the support end to fill the space therebetween. The method of claim 3, wherein The depth adjusting means is a screw that penetrates into the space between the rotor conductor and the support end from the outer circumferential surface of the rotor housing through a fastening hole formed in the rotor housing and is in contact with the bottom surface of the rotor conductor. Type induction motor. The method of claim 5, wherein The rotor housing has an outer rotor type induction motor, characterized in that a plurality of screw fastening holes having different heights are formed along a side thereof so as to correspond to the indentation depth of the rotor conductor.