KR100557547B1 - Structure for rotor of motor using washing machine - Google Patents

Abstract

The present invention relates to a motor for a washing machine, which protrudes and forms a reinforcing rib between a heat dissipation hole and a heat dissipation hole formed at a lower end of a frame of the rotor of the washing machine motor, that is, for cooling the motor. The ribs are protruded in the rotational direction of the rotor, and the lower end of the rotor by the reinforcing ribs has an excellent effect of having rigidity greater than the axial bending load of the rotor and the torsional load of the rotational direction.

Further, as described above, since the lower end of the rotor by the reinforcing rib has rigidity larger than the axial bending load and the torsional load in the rotational direction, the deformation of the rotor due to the bending load and the torsional load can be prevented. There is also an excellent effect.

Washing machine, motor, rotor, reinforcement rib

Description

Structure for rotor of motor using washing machine

1 is a cross-sectional view showing a motor for a general washing machine.

Figure 2 is a cross-sectional view and a plan view showing a rotor structure of a conventional washing machine motor.

Figure 3 is a state diagram showing a deformation state of a conventional frame by the axial bending load and the torsional load of the rotation direction of the rotor.

4 is a cross-sectional view and a plan view showing a rotor structure of a washing machine motor according to the present invention.

Figure 5 is a plan view of the rotor showing the shape of the reinforcing ribs protruding at the bottom of the frame of the rotor structure according to the present invention.

6 is a cross-sectional view of the rotor showing a state of protrusion of the reinforcing rib in the rotor structure according to the present invention.

Figure 7 is another embodiment of the reinforcing rib of the rotor structure according to the present invention.

8 is another embodiment of the reinforcing rib of the rotor structure according to the present invention.

9 is another embodiment of the reinforcing rib of the rotor structure according to the present invention.

10 is a cross-sectional view and a plan view showing another rotor structure of the motor for a washing machine according to the present invention.

Figure 11 is a plan view of the rotor showing the shape of the reinforcing ribs protruding at the bottom of the frame of another rotor structure of the present invention.

12 is a cross-sectional view of the rotor showing a protruding state of the reinforcing rib in another rotor structure of the present invention.

FIG. 13 is yet another embodiment of a reinforcing rib in the rotor structure of FIG. 10. FIG.

14 is another embodiment of the reinforcing rib in the rotor structure of FIG.

15 is yet another embodiment of the reinforcing rib in the rotor structure of FIG.

16 is another embodiment of the reinforcing rib of the rotor structure according to the present invention.

17 is another embodiment of the reinforcing rib of the rotor structure according to the present invention.

Explanation of symbols on the main parts of the drawings

100. Stator 200, 500. Rotor

210, 510. Frames 216, 516. Heat dissipation holes

218, 518. Braid 220, 520. Back York section

250. Permanent magnet 300. Connecting member

400. Drive Shaft

214, 214a, 314a, 314b, 324a, 324b, 334, reinforced rib

514, 614, 614a, 624, 624a, 634, 714, 724. Reinforcement rib

The present invention relates to a motor for a washing machine, and more particularly, to increase the frame rigidity against the axial bending load and torsional load in the rotation direction of the components of the washing machine motor, the reinforcing ribs in the frame of the rotor The lower end, that is, the rotor structure of the motor for a washing machine which is bent in a rotational direction between the heat dissipation hole and the heat dissipation hole is formed.

In general, an outer rotor type non-rectifier motor (hereinafter, referred to as a washing machine motor) used in a washing machine includes a stator 100 having a coil wound around a core formed in a predetermined shape, as shown in FIG. The rotor 200 includes a permanent magnet 250 and installed to be rotatable on the outside of the stator 100, and detects the position of the rotor 200 to sequentially flow current to the stator 100. It is composed of a sensor unit to enable.

In addition, the rotor 200 is connected to the drive shaft 400 for transmitting the power generated in the rotor 200 to another system.

The stator 100 is mounted on an outer tub in which a washing tub is located, and the drive shaft 400 is connected to a washing tub (not shown).

The washing machine motor configured as described above causes the rotor 200 to rotate by the interaction force between the current flowing through the coil and the permanent magnet 250 when a current flows through the coil of the stator 100. The rotational force of the 200 is transmitted to the washing tank through the drive shaft 400 so that the washing tank is repeatedly rotated from side to side when washing, or rotates in one direction together with the outer tank during dehydration according to the rotation of the drive shaft 400.

Meanwhile, when the structure (patent registration number: 314009) of the rotor 200 installed on the outer circumferential surface of the stator 100 coiled among the components of the washing machine motor is schematically illustrated, as shown in FIG. A frame 210 having a large outer shape of the rotor 200 and bending the predetermined height of the inner edge portion to form the back yoke portion 220; A permanent magnet 250 mounted to the back yoke portion 220 of the frame 210; A connection member (300) fixed to the inner center of the frame (210) and connected to the drive shaft (400) on the frame (210) through engagement with the drive shaft (400); Fastening means for fastening the frame 210 and the connection member 300; The connecting member 300 and the drive shaft 400 inserted through the frame 210 is composed of a fixing means to be fixed to the frame 210.

At this time, a plurality of reinforcing ribs 214 are radially projected on the frame 210 while having a radial length centering on the shaft insertion hole 212 in the center of the inner bottom surface (base plate portion) of the frame 210. The radiating hole 216 penetrates the reinforcing rib 214 while having a radial length, and is bent and extended to have a predetermined inclination angle in the radiating hole 216. Braids 218 are formed to guide the turbulent flow into the heat dissipation hole 216, respectively.

Looking at the coupling state of the rotor 200 of the motor for a washing machine configured as described above, the shape of the frame 210 is formed by pressing, and the back yoke portion bent to the inner edge of the frame 210. After placing the permanent magnet 250 pieces, the permanent magnet 250 is fixed to the back yoke part 220 by fixing the permanent magnet 250.

Then, a screw hole 312, which is a coupling means of the connection member 300, is matched with an inner bottom surface of the frame 210, that is, a fastening means insertion hole 211a of the base plate portion 211, and then a bolt (fastening means) The coupling member 300 is coupled to the frame 210 by fastening the 350.

In addition, the shaft serration portion 410 of the drive shaft 400 is joined to the serration hole 310 of the connection member 300, and then the nut 420 is fixed to the screw portion 421 of the drive shaft 400. By fastening the drive shaft 400, the frame 210 and the connecting member 300 are fixed to each other to form the rotor 200 of FIG. 2.

However, in the structure of the conventional rotor 200, bending and torsional loads applied to the rotor 200, that is, the frame 210 by the axial bending vibration and the torsional vibration in the rotational direction of the rotor 200, In the case of the reinforcing rib 214 formed on the inner bottom surface of the rotor 200 to reduce, as shown in Figure 2, the radial heat radiation hole having a radial length on the inner bottom surface of the frame 210, Since it extends only in the radial direction of the shaft 400 so as to pass through the space between the heat dissipation means consisting of 216 and the braid 218, the clearance between the heat dissipation means 216, 218 and the reinforcing rib 214. There is a problem in that the use of the installation space of the reinforcing rib 214 is not efficient, such as a lot of space, in particular, when the rotor 200 is rotated, the protruding reinforcing rib 214 in any direction the rotor ( 200) can not generate wind within Since only the stirring action, there is a big problem, such as the cooling effect of the rotor 200, that is, the motor is greatly reduced.

In addition, when the axial bending load and the torsional load in the rotational direction act on the rotor 200 in which the reinforcing rib 214 protrudes as described above, the axis of the inner bottom surface of the frame 210 with respect to the axial bending load is applied. The rotor 200, that is, the frame 210, is supported by the reinforcing ribs 214 radially protruded while having a radial length about the insertion hole 212 to reduce the axial bending load. Even if the rotational force of the rotor 200 is greater with respect to the torsional load in the rotational direction, the reaction force acting in the direction opposite to the rotational direction of the rotor 200, that is, the rotating rotor 200 may be stopped. Since the force is also increased, the radially enlarged reinforcing rib 214 does not support the lower end of the rotor 200 due to the torsional load, and as shown in (a) of FIG. 3, the lower end of the rotor 200 and Before rotor 200 There were a large problem such that the said bent by the torsional load.

Further, in the case of the reinforcing rib 214 extended radially as described above, the shape of the reinforcing rib 214 is formed in a straight triangular cross section, even if the axial bending load acts on the rotor 200 as described above, the reinforcing rib Since the length of the straight line 214 is too long, the impact force generated during the low speed rotation of the rotor 200 (the state in which the washing tub is initially rotated), that is, the bending load acting in the axial direction, cannot be tolerated. There was also a big problem that the lower end of the rotor 200 is also bent while being bent toward the axis radius, such as).

 The present invention has been made in order to solve the above problems, the protrusion of the reinforcing rib between the heat dissipation hole and the heat dissipation hole formed in the lower end of the frame of the rotor of the washing machine motor, that is, the motor for cooling the motor, The reinforcing ribs are bent in the rotational direction of the rotor to protrude, and the lower end of the rotor by the reinforcing ribs has a rigidity greater than the axial bending load of the rotor and the torsional load in the rotational direction. .

In addition, the lower end of the rotor by the reinforcing rib as described above has a rigidity greater than the axial bending load and the torsional load of the rotation direction, so that the deformation of the rotor by the bending load and the torsional load is prevented. There is another purpose.

The object of the present invention, bar can be solved by the rotor structure of the washing machine motor formed between the heat dissipation hole formed in the lower end of the frame and the heat dissipation hole for cooling the motor is bent in the rotational direction of the rotor. It will be described in detail with reference to the accompanying drawings.

Figure 4 is a cross-sectional view and a plan view showing a rotor structure of the washing machine motor according to the present invention, Figure 5 is a plan view of the rotor showing the shape of the reinforcing ribs protruding at the bottom of the frame of the rotor structure according to the invention, 6 is a cross-sectional view of the rotor showing the protruding state of the reinforcing rib according to the present invention.

The rotor structure of the motor for a washing machine according to the present invention includes a motor for a washing machine comprising a stator (100) wound with a coil and a rotor (200) installed on an outer circumferential surface of the stator (100);

A frame 210 forming an outer shape of the rotor 200;

A permanent magnet 250 fixed to the inner edge of the frame 210;

A connection member (300) fixed to the inner center of the frame (210) and connected to the drive shaft (400) on the frame (210) through engagement with the drive shaft (400);

Including a reinforcing rib 214a which is bent in a predetermined direction at the bottom of the frame 210 to increase the rigidity of the frame 210 against the axial bending load and the torsional load in the rotational direction of the rotor 200. Consists of.

Hereinafter, the rotor structure of the washing machine motor of the present invention will be described in detail.

Rotor structure of the washing machine motor of the present invention, the lower end of the frame 210 of the rotor 200 of the components of the washing machine motor has a rigidity greater than the axial bending load and torsional load in the rotational direction of the bending load and In order to prevent the deformation of the rotor 200 due to the torsional load, the heat radiation hole 216 formed in the lower end of the frame 210, that is, the lower end of the frame 210 for cooling the motor, and heat radiation The reinforcing ribs 214a are formed to protrude between the holes 216, and the curved ribs protrude in the rotational direction of the rotor 200. The present invention will be described in detail. The same reference numerals will be applied to the same configurations as those of the present invention and the conventional art described above.

The rotor 200 structure of the washing machine motor according to the present invention, as shown in Figure 4, the frame 210 forming the outer shape of the rotor 200; A permanent magnet 250 fixed to the inner edge of the frame 210; A connection member (300) fixed to the inner center of the frame (210) and connected to the drive shaft (400) on the frame (210) through engagement with the drive shaft (400); Including a reinforcing rib 214a which is bent in a predetermined direction at the bottom of the frame 210 to increase the rigidity of the frame 210 against the axial bending load and the torsional load in the rotational direction of the rotor 200. Consists of.

Particularly, in the detailed description of the present invention, the structure of the rotor 200 according to the present invention, that is, the heat dissipation hole 216 penetrated for cooling the motor in the inner bottom surface of the frame 210 and the blades on one side of the heat dissipation hole 216 218 is bent and reinforced between the heat dissipation hole 216 and the heat dissipation hole 216 to increase the rigidity of the frame 210 against the axial bending load of the rotor 200 and the torsional load of the rotation direction. The rib 214a will be described in detail with the basic structure of the rotor 200 protruding in a predetermined direction.

At this time, in the case of the frame 210 forming the outer shape of the rotor 200, the conventional rotor registered by the present applicant on October 25, 2001 (patent registration number: 314009) Since it is formed in the same shape as the frame 210 forming the outer shape of the conventional structure according to the same shape as the conventional description will be omitted.

In addition, the frame 210 according to the present invention is made of a magnetic material to which a magnet can be attached. Among the magnetic material of the frame 210, an iron plate (hereinafter, an iron plate) is the most preferable material. By using the press molding operation to be molded in the shape as shown in Figures 4 and 10.

The reinforcing rib 214a rotates the rotor 200 to reduce the axial bending load and the torsional load of the rotor 200 as shown in FIG. It is bent in the clockwise direction to protrude, or conversely, as shown in FIG. 5B, it is bent in the counterclockwise direction opposite to the rotation of the rotor 200 to protrude.

Particularly, in the case of the reinforcing ribs 214a protruding as shown in FIGS. 4 and 5, as shown in FIG. 6A, the protruding ribs 214a protrude only inside the lower end of the frame 210 or in FIG. As shown in b), it may be formed to protrude only outside the bottom of the frame 210.

In addition, as another embodiment of the reinforcing rib 214a, as shown in Figure 7, the reinforcing rib 314a protruding in the clockwise direction and the reinforcing rib 314b protruding in the counterclockwise direction, respectively It is formed alternately.

In addition, as another embodiment of the reinforcing rib 214a, as shown in FIG. 8, the reinforcing ribs that are bent in the counterclockwise direction and protrude in the counterclockwise direction per 2-3 reinforcing ribs 324a which are bent in the clockwise direction ( 324b) alternately formed one by one.

In addition, as another embodiment of the reinforcing rib 214a, as shown in Figure 9, the rigidity of the frame 210 against the axial bending load and the torsional load in the rotation direction of the rotor 200 To further increase, one side of the reinforcing rib 334 extends to the inner edge of the frame 210 at the bottom of the permanent magnet 250.

Another rotor 500 structure of the washing machine motor according to the present invention, as shown in Figure 10, the frame 510 forming the outer shape of the rotor 500; A permanent magnet 250 fixed to the inner edge of the frame 510; A connection member 300 fixed to an inner center of the frame 510 and configured to be connected to the drive shaft 400 on the frame 510 through engagement with the drive shaft 400; A reinforcing rib 514 inclined in a predetermined direction at the bottom of the frame 510 to increase the rigidity of the frame 510 against the axial bending load and the torsional load in the rotation direction of the rotor 500. Consists of.

At this time, the reinforcing rib 514 as shown in (a) of Figure 11, in order to reduce the axial bending load and the torsional load in the rotation direction of the rotor 500, It is formed to be inclined in the clockwise direction in the rotational direction, or conversely, as shown in FIG. 11B, is inclined in the counterclockwise direction in the counterclockwise direction of the rotor 500.

Particularly, in the case of the reinforcing rib 514 protruding as shown in FIGS. 10 and 11, as shown in FIG. 12A, the protruding ribs 514 protrude only inside the lower end of the frame 510 or as shown in FIG. As shown in b), the frame 510 may protrude only outside the bottom.

In addition, as another embodiment of the reinforcing rib 514, as shown in Figure 13, the reinforcing rib 614 inclined in the clockwise direction and the reinforcing rib 614a inclined in the counterclockwise direction, respectively It is formed alternately.

In addition, as another embodiment of the reinforcing rib 514, as shown in Figure 14, the reinforcing rib protruded inclined in the counterclockwise direction per 2-3 reinforcing ribs 624 protruding inclined clockwise ( 624a) alternately formed one by one.

In addition, as another embodiment of the reinforcing rib 514, as shown in Figure 15, the rigidity of the frame 510 against the axial bending load and the torsional load in the rotation direction of the rotor 500 further To further increase, one side of the reinforcing rib 634 extends to the inner edge of the frame 510 at the bottom of the permanent magnet 250.

And, as another embodiment of the reinforcing rib 514 according to Figures 4 and 10, as shown in Figure 16, the frame for the axial bending load and the torsional load in the rotational direction of the rotor 500 In order to increase the rigidity, the reinforcing rib 714 is formed to protrude in a rhombus shape, and protrudes to the inner side of the bottom of the frame 510 as shown in FIG. 16A, or as shown in FIG. 16B. The frame 510 is configured to protrude outward from the bottom.

In addition, as another embodiment of the reinforcing rib 514 according to Figures 4 and 10, as shown in Figure 17, the frame for the axial bending load and the torsional load in the rotational direction of the rotor 500 In order to increase the stiffness, the reinforcing rib 724 is formed to protrude in an “S” shape, and protrudes into the bottom of the frame 510 as shown in FIG. 17A, or FIG. 17B. As shown in FIG. 2, the frame 510 protrudes outward from the bottom.

The reinforcing rib 214a for the axial bending load and the torsional load in the rotational direction of the rotor 200 through the rotor 200 structure of the washing machine motor configured as described above, that is, radially on the inner bottom surface of the frame 210. Referring to the operation state of the reinforcing rib 214a protruded in the clockwise direction which is the rotation direction of the rotor 200 between the formed heat dissipation hole 216 and the heat dissipation hole 216 are as follows.

First, when a current is applied to the coil constituting the stator (not shown), the rotor 200 is rotated by the interaction of the current flowing in the coil and the permanent magnet 250, the of the rotor 200 The rotational force is transmitted to the washing tank through the drive shaft 400 so that the washing tank repeatedly rotates from side to side when washing, or rotates in one direction during dehydration, according to the rotation of the drive shaft 400. In this case, in the case of the rotor 200, In the process of rotating by interaction with the current applied to the winding coil of the stator, bending and torsional loads due to bending and torsional vibrations act on the axial direction and the rotational direction of the rotor 200.

As such, the lower end of the rotor 200 is retracted inwardly or vice versa due to the axial bending load of the rotor 200, and the rotor 200 The lower end of the rotor 200 is twisted based on the center of the drive shaft 400 by the torsional load according to the rotation direction of the), as described above, the axial bending load and rotation of the rotor 200 When a torsional load in the direction acts on the frame 210 of the rotor 200, the rotor 200 is disposed between the heat dissipation hole 216 and the heat dissipation hole 216 radially formed on the inner bottom surface of the frame 210. A plurality of reinforcing ribs 214a protruding in a clockwise direction, which is a rotational direction of, support the lower end of the frame 210 so as to have a rigidity greater than an axial bending load and a rotational direction torsional load. The deformation of the electrons 200 is prevented It becomes.

In more detail, when the reinforcing rib 214a is bent and the axial bending load and the torsional load in the rotational direction act on the rotor 200 as described above, the conventional reinforcing rib for the axial bending load is applied. As in 214, the frame 210 is supported by a plurality of reinforcing ribs 214a protruding in the clockwise direction, which is the rotational direction of the rotor 200, to attenuate the axial bending load. The lower end of the rotor 200 is supported by the reinforcing rib 214a to prevent deformation of the rotor 200.

In addition, as described in the related art for the torsional load in the rotational direction, the larger the rotational force of the rotor 200, the greater the reaction force acting in the direction opposite to the rotational direction of the rotor 200, that is, the rotational rotation Since the force to stop the electrons 200 also increases, a plurality of reinforcing ribs 214a protruding in the clockwise direction, which is a rotational direction of the rotor 200, as described above, are opposite to the rotating rotor 200. The lower force of the rotor 200 is prevented from being bent through the torsional load by subtracting the force acting from the direction, and the reinforcement ribs protruded in the clockwise direction in the rotational direction of the rotor 200 as described above. 214a) supports the lower end of the frame 210 so as to have a rigidity greater than the axial bending load and the rotational torsional load, thereby deforming the rotor 200, that is, the axial bending load and the torsional load in the rotational direction. The deformation of the rotor 200 is prevented by the.

The rotor structure of the motor for a washing machine configured as described above is a clockwise direction in which the rotor 200 rotates between the heat dissipation hole 216 and the heat dissipation hole 216 formed at the lower end of the frame 210 for cooling the motor. Since the curved reinforcement ribs 214a are formed, the lower end of the rotor 200 by the reinforcement ribs 214a has a rigidity greater than the axial bending load and the torsional load in the rotational direction. It is an excellent invention that the deformation of the rotor 200 is prevented by.

Rotor structure of the washing machine motor of the present invention, the reinforcing rib protrudes between the heat dissipation hole and the heat dissipation hole formed in the lower end of the frame, that is, the lower end of the frame of the rotor of the washing machine motor, the reinforcement The ribs are protruded in the rotational direction of the rotor, and the lower end of the rotor by the reinforcing ribs has an excellent effect of having rigidity greater than the axial bending load of the rotor and the torsional load of the rotational direction.                     

Further, as described above, since the lower end of the rotor by the reinforcing rib has rigidity larger than the axial bending load and the torsional load in the rotational direction, the deformation of the rotor due to the bending load and the torsional load can be prevented. There is also an excellent effect.

Claims (15)

In the washing machine motor consisting of a stator winding the coil and a rotor installed on the outer peripheral surface of the stator; A frame forming the outer shape of the rotor; A permanent magnet fixed to the inner edge of the frame; A connection member fixed to an inner center of the frame and configured to connect the drive shaft to the frame through engagement with the drive shaft; Rotor structure of a motor for a washing machine comprising a; reinforcing rib formed by bending in a predetermined direction at the bottom of the frame to increase the frame rigidity against the axial bending load of the rotor and the torsional load of the rotation direction . In the washing machine motor consisting of a stator winding the coil and a rotor installed on the outer peripheral surface of the stator; A frame forming the outer shape of the rotor; A permanent magnet fixed to the inner edge of the frame; A connection member fixed to an inner center of the frame and configured to connect the drive shaft to the frame through engagement with the drive shaft; Rotor structure of a motor for a washing machine comprising a; reinforcing rib protruded in a predetermined direction at the bottom of the frame to increase the frame rigidity against the axial bending load of the rotor and the torsional load of the rotation direction . The rotor structure of claim 1, wherein the reinforcing rib is formed to be curved in a clockwise direction. The rotor structure of claim 1, wherein the reinforcing rib is formed to be bent in a counterclockwise direction. 3. The rotor structure of claim 2, wherein the reinforcing rib is formed to be inclined in a clockwise direction to protrude. The rotor structure of claim 2, wherein the reinforcing rib is formed to be inclined counterclockwise to protrude. The rotor structure according to claim 3 or 4, wherein the reinforcing ribs that are bent in the clockwise direction and the reinforcing ribs that are bent in the counterclockwise direction are alternately formed. The rotor structure according to claim 3 or 4, wherein one or more reinforcing ribs bent in a counterclockwise direction are formed alternately per 2-3 reinforcing ribs protruding in a clockwise direction. 7. The rotor structure according to claim 5 or 6, wherein the reinforcing ribs inclined in the clockwise direction and the reinforcing ribs inclined in the counterclockwise direction are alternately formed. 7. The rotor structure according to claim 5 or 6, wherein one or more reinforcing ribs which are bent in a counterclockwise direction and protruded in a counterclockwise direction are alternately formed. The rotor structure according to claim 1 or 2, wherein the reinforcing rib protrudes into the lower end of the frame. The rotor structure according to claim 1 or 2, wherein the reinforcing rib protrudes outward from the lower end of the frame. The rotor structure of claim 1 or 2, wherein one side of the reinforcing rib extends to the frame inner edge of the lower end of the permanent magnet to protrude. According to claim 1 or 2, wherein the reinforcing ribs in the form of a rhombus to increase the frame stiffness against the axial bending load and the torsional load in the rotation direction of the rotor is characterized in that protruding to the inside or outside the bottom of the frame Rotor structure of motor for washing machine. 3. The method according to claim 1 or 2, wherein the reinforcing ribs protrude in or out of the bottom of the frame in the form of an "S" to increase the frame stiffness against the axial bending load and the torsional load in the rotational direction. Rotor structure of the washing machine motor, characterized in that formed.

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