KR200431843Y1 - shading pole induction motor - Google Patents

Abstract

The present invention relates to a shading pole induction motor, and the rotor is relatively expensive when the assembly of the gear part is generated by providing a coupling separation structure that can be rotated by simply rotating the shaft housing and the bushing cap of the gear box housing the rotor bushing. The bushing can be easily extracted and recycled, and the bushing cap can be easily assembled by hand without using a press, thereby minimizing assembly defects.

According to the present invention, a shading coil is provided on the yoke of the stator on which the driving coil is wound, and a rotor having a rotor shaft is installed between the yokes of the stator, and a rotor shaft protruding to the lower portion of the rotor is wrapped around the lower portion of the stator. The shading pole induction motor is equipped with a rotor housing which is formed to support the upper part of the stator and rotates in engagement with a pinion assembled to the rotor shaft of the rotor to obtain a predetermined reduction ratio and torque. In one embodiment, one end of the rotor shaft of the rotor is supported by a spherical rotor bushing seated in a bushing seating groove of a celebratory housing penetrating the gearbox, and prevents the rotor bushing from the celebratory housing so that the rotor bushing can be removed. Bushing cap is combined, but simply by rotating the bushing cap to the It is characterized in that the coupling separation structure is provided.

Shading Pole Induction Motor, Bushing, Bushing Cap, Detachable

Description

Shading pole induction motor

1 is a schematic diagram of a conventional shading pole induction motor,

2 is a cross-sectional view showing the motor of FIG.

Figure 3 is a detailed cross-sectional view showing an excerpt of the gearbox in Figure 1,

Figure 4 is an exploded perspective view showing a shading pole induction motor according to the present invention,

5 is an assembly cross-sectional view of FIG.

Figure 6a and 6b is a view showing an excerpt of the gear housing part of the gearbox in FIG.

<Description of the symbols for the main parts of the drawings>

11: stator 11a: york

12: drive coil 12a: shading coil

13: rotor 13a: rotor shaft

14: motor unit 15: rotor housing

16: Geartrain 17: Gearbox

17b: bushing mounting hole 18: gear part

170: congratulation housing 171: insertion groove

172: locking jaw 173: cap seating groove

210: bushing cap 211: insertion protrusion

212: Gripping Hole

The present invention relates to a geared motor, and more particularly, a poor assembly of the gear unit by providing a coupling separation structure that can be separated by simply rotating the shaft housing and the bushing cap of the gear box housing the rotor shaft support for the rotor shaft. The present invention relates to a shading pole induction motor that can be easily extracted and recycled when generated.

In general, among induction motors, induction motors are classified as a rotor type and the rotor is caused by the interaction between a rotating magnetic field generated by alternating current flowing through a drive coil of an MXP rotor and an induced current generated in the rotor. Is the motor to be rotated. Usually, two or more phases of AC are required to rotate the rotor of an AC motor. However, since only a single phase alternating current is supplied to a general household power source, a condenser is used to generate and drive a separate power source having a different phase.

Thus, unlike a general AC motor that uses a capacitor to make a separate power source having a different phase, as shown in FIG. 1, the yoke 11a of the stator 11 is separated from the driving coil 12 by one. The shading pole induction motor is a motor which winds the shading coil 12a (short circuit coil) of ˜2 rotations and thereby generates a rotating magnetic field.

These shading pole induction motors are simple in structure and inexpensive, but have limitations of several tens of watts (W) and low output efficiency, so they are used in small fans or devices that do not require exact rotational characteristics (rotational fluctuations, torque fluctuations). have.

In order to be able to use even when a larger torque is required for the shading pole induction motor as described above, a gear part is mounted. Such a conventional shading pole induction motor has a driving coil 12 as shown in FIG. The motor part 14 provided with the shading coil 12a in the yoke 11a of the wound stator 11, and the rotor 13 which has the rotor shaft 14a between the yoke 11a of the stator 11 is provided. And a rotor housing 15 formed below the stator 11 to support the rotor shaft 13a protruding to the lower portion of the rotor 13 while surrounding the lower portion of the rotor 13 and the stator 11. In the upper part of the gear unit 16 is provided in the gearbox 17, the gear train 16 is provided in the gearbox 17 so as to be engaged with the pinion 16a assembled to the rotor shaft 13a of the rotor 13 to obtain a predetermined reduction ratio and torque. It is configured to include).

The rotor housing 16 and the gearbox 17 are mounted to the stator 11 by a plurality of bolts (not shown) fastened through the stator 11.

Both ends of the rotor shaft 13a of the rotor 13 are rotatably supported by the axial housing 17a of the gearbox 17 constituting the gear unit 18 and the axial housing 15a of the rotor housing 15. The spherical rotor bushings 20 are seated in the bushings 15a and 17a of the rotor housing 15 and the gearbox 17, and the rotor bushings 21 are mounted in the bushing seating holes 17b therein. It is constrained by the bushing cap 21 to be rotated at an angle.

In the conventional shading pole induction motor configured as described above, the gear box 17 is seated on the press die, and the rotor bushing 20 is seated on the axial housing 17a of the gear box 17, and then the punch of the press is used. The bushing cap 21 is assembled by pressure. Thus, the method of press-assembling the bushing cap 21 by using the punch of the press on the gear housing 17a of the gearbox 17 has no problem for the skilled worker, but for the inexperienced worker, the gearbox 17 Due to the difference in position (point) of mounting the bushing cap 21 on the celebration housing 17a, there was a problem in that deformation or breakage of the celebration housing 17a is likely to occur.

In particular, a ring-shaped locking jaw 17c is formed on the entire inner surface of the gearbox 17 of the gearbox 17, and the bushing cap 21 is also a ring-shaped plate and the rotor bushing 20 in the gearbox 17a of the gearbox 17. ) And the assembly of the bushing cap 21, the entire gear box had to be disposed of, and in order to recycle the rotor bushing 20, the shaft bushing 17 of the gear box 17 had to be split and the rotor bushing 20 There was a problem that can be taken out.

The present invention has been researched and developed in order to solve the conventional problems as described above, the object of the gearbox by providing a coupling separation structure that can be separated by simply rotating the rotating housing and the bushing cap of the gear box housing the rotor bushing In case of poor assembly, the rotor bushing, which is relatively expensive, can be easily extracted and recycled, and the bushing cap motor can be easily assembled by hand without using a press, and the shading pole motor can be minimized. To provide.

The present invention for achieving the above object is provided with a shading coil in the yoke of the stator, the drive coil is wound and a rotor having a rotor shaft between the yoke of the stator is installed, while wrapping the lower portion of the rotor in the lower portion of the stator The rotor housing is formed to support the rotor shaft protruding to the lower part of the rotor, and the gear train is provided in the gearbox so that the upper part of the stator is engaged with the pinion assembled to the rotor shaft of the rotor to obtain a predetermined reduction ratio and torque. In the shading pole induction motor comprising a portion, one end of the rotor shaft of the rotor is supported by a spherical rotor bushing seated in a bushing seating groove of the shaft housing penetrating the gearbox, and the shaft housing can be pulled out. In the bushing cap to prevent the departure of the rotor bushing is coupled to the celebration housing It is characterized in that the coupling separation structure that can be separated by simply rotating the bushing cap.

The coupling separation structure is sufficient if the structure that can be repeatedly coupled to the bushing cap and the separation in the celebratory housing, for example, the celebrity housing is provided with a cap seating groove having an insertion groove and a locking jaw at the inner inlet, The bushing cap is provided with a gripping hole which can be rotated by gripping the bushing cap while an insertion protrusion is formed to be inserted into the insertion groove of the cap seating groove on an outer circumferential surface thereof.

Hereinafter, a preferred embodiment of the shading pole induction motor according to the present invention will be described in detail with reference to the accompanying drawings. In the shading pole induction motor of the present invention, the same reference numerals are used for the same components as the conventional motors attached to FIGS. 1 to 3.

Figure 4 is an exploded perspective view showing a shading pole induction motor according to the present invention, Figure 5 is an assembled cross-sectional view of Figure 4, Figure 6a and Figure 6b is a view showing an excerpt of the gearbox of the gear box in Figure 4 shown.

As shown in the figure, the shading pole induction motor of the present invention is provided with a shading coil 12a on the yoke 11a of the stator 11 on which the driving coil 12 is wound, and the yoke 11a of the stator 11. The motor part 14 provided with the rotor 13 which has the rotor shaft 13a between them, and the rotor shaft which protruded to the lower part of the rotor 13 while wrapping the lower part of the rotor 13 in the lower part of the said stator 11 The rotor housing 15 formed to support the 13a is mounted, and the upper portion of the stator 11 is engaged with the pinion 16a assembled to the rotor shaft 13a of the rotor 13 to obtain a predetermined reduction ratio and torque. The gear train 16 is configured to include a gear unit 18 provided in the gear box 17 to be able to.

The rotor housing 15 and the gearbox 17 are mounted to the stator 11 by a plurality of bolts 19 fastened through the stator 11.

Both ends of the rotor shaft 13 of the rotor 13 are rotatably supported by the axial housing 170 of the gearbox 17 constituting the gear unit 18 and the axial housing 15a of the rotor housing 15. The spherical rotor bushings 20 are seated in the bushings 15a and 170 of the rotor housing 15 and the gearbox 17, and the rotor bushings 21 are spherical. The rotor bushing 20 of the shape is constrained by the bushing cap 210 to be rotated at an angle.

The rotor bushing 20 of the gearbox 17 and the bushing cap 210 of the gearbox 17 are prevented from being damaged when assembled to the rotor housing 15 and the gearbox 170 of the gearbox 17. It is provided with a coupling separation structure that can be separated by simply rotating. The coupling separating structure is provided with a cap seating groove 173 having an insertion groove 171 and a locking jaw 172 at an inner surface inlet of the celebrator housing 170, and an insertion groove at an outer circumferential surface of the bushing cap 210. The insertion protrusion 211 to be inserted into the 171 is formed, and the bushing cap 210 is provided as a gripping hole 212 capable of gripping and rotating the jig pin (not shown).

Operation of the shading pole induction motor of the present invention configured as described above is the same as described above in the prior art, the detailed description thereof will be omitted. Here, the rotor bushing 20 is seated in the bushing seating hole 17b of the celebratory housing 170 formed on the lower surface of the gearbox 17, and then the jig pin is inserted into the gripping hole 212 of the bushing cap 210. Gripping the bushing cap 210 to rotate the insertion protrusion 211 of the bushing cap 210 to be seated in the cap seating groove 173 through the insertion groove 171 of the inner inlet of the celebratory housing 170. The insertion protrusion 211 of the bushing cap 210 is stopped by being caught by the locking jaw 172 of the inner surface inlet of the celebratory housing 170. Thereafter, the assembly is completed by removing the jig pin from the gripping hole 212 of the bushing cap 210.

On the contrary, the process of disassembling the rotor bushing 20 can be simply and easily disassembled by the reverse order listed above.

Therefore, after the rotor bushing 20 is seated in the bushing seating hole 17b of the gearbox 17 side shaft housing 170, the conventional press assembly for pressing and assembling the bushing cap 210 by the punch of the press. It is possible to prevent damage of the celebratory housing generated by the method at the source, even if the assembly of the rotor bushing 20 and the bushing cap 210 in the celebrity housing 170 of the gearbox 17 is simple and easy. By disassembling to remove the relatively expensive rotor bushing 20 is to be recycled.

Lastly, the rotor bushing and the bushing cap are simply described as a coupling separation structure that can be easily combined and detached to the gear housing. However, the rotor housing and the rotor housing 15 surrounding the rotor shaft in the lower part of the rotor may be provided as it is. Can be.

As described in detail above, the shading pole induction motor of the present invention, as well as the housing of the gear box for accommodating the rotor bushing, as well as providing a coupling separation structure in the bushing cap to facilitate the separation of the gear portion has been generated. When the relatively expensive rotor bushings can be easily extracted and recycled, the bushing cap can be easily assembled by hand without a press, and this is a useful design that can minimize assembly defects.

Claims (3)

A shading coil is provided on the yoke of the stator on which the driving coil is wound, and a rotor having a rotor shaft is installed between the yokes of the stator. The lower portion of the stator surrounds the lower portion of the rotor and supports the rotor shaft protruding to the lower portion of the rotor. In the shading pole induction motor including a gear housing is provided in the gear box so that the rotor housing is mounted and the upper portion of the stator is engaged with the pinion assembled to the rotor shaft of the rotor to obtain a predetermined reduction ratio and torque, One end of the rotor shaft of the rotor is supported by a spherical rotor bushing seated in the bushing seating groove of the gearbox penetrating the gearbox, and a bushing cap for preventing the rotor bushing from the gearbox to be pulled out. Shade pole induction motor is coupled, characterized in that the coupling separation structure is provided that can be separated by simply rotating the bushing cap in the celebration housing. The method of claim 1, Shading pole induction motor, characterized in that the coupling separation structure is also provided in the axial housing of the rotor housing surrounding the rotor shaft of the lower rotor. The method according to claim 1 or 2, The coupling separation structure is provided with a cap seating groove having an insertion groove and a locking jaw at the inner inlet of the celebration housing, and the bushing cap is rotated by holding the bushing cap while an insertion protrusion is inserted into the outer peripheral surface of the bushing cap. Shading pole induction motor, characterized in that provided with a gripping hole that can be made.

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