KR20080004155U - Motor for a vacuum cleaner - Google Patents

Abstract

The present invention has a housing cover, an impeller disposed in an inner space formed by the housing cover, a rotor part, a motor shaft connected to the rotor part to transmit rotational force to the impeller, and a stator core and an outer circumference of the stator core. A cleaner motor having a stator having a stator coil wound up, the cleaner motor comprising: a frame rotatably supporting the other end of the motor shaft and spaced apart from the diffuser; and the frame and the diffuser include a frame fastening portion, and the frame And a cleaner motor having a plurality of core protrusions protruding from the outer circumferential surface of the stator core disposed between the diffuser and the outside.

Description

Cleaner Motor {MOTOR FOR A VACUUM CLEANER}

1 is a schematic partial front sectional view of a cleaner motor according to an embodiment of the present invention.

2 is a schematic exploded front view of a cleaner motor according to an embodiment of the present invention.

3 and 4 is a schematic exploded perspective view of a part of a motor for a cleaner according to an embodiment of the present invention.

5 and 6 are schematic perspective views of a stator core and a modification thereof of the cleaner motor according to an embodiment of the present invention.

Figure 7 is a schematic perspective view showing a modification of the impeller mounting elastic support plate of the cleaner motor according to an embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

10 ... Cleaning motor 100 ... Housing cover

200 ... Impeller 300 ... Diffuser

400 ... Stator 410 ... Stator Core

413 Core Insulator 414 Core Turning

415 Core groove 500 Rotor

510 ... rotor core 520 ... rotor magnet

600 ... frame 610 ... frame fasteners

700 ... Printed Circuit Board

The present invention relates to a motor, and more particularly to a motor provided in a cleaner.

Electric motors are a power source that generates power by electricity, and are indispensable components for various household goods such as mobile phones, washing machines, and vacuum cleaners as well as industrial facilities. In particular, the electric motor provided to the cleaner takes the structure using the suction force generated by operating the impeller with the rotational force by the interaction of the rotor and the stator. In order to increase the suction power of the vacuum cleaner, the pressure difference between the air inlet and the air outlet of the impeller must be maximized and the impeller must be rotated at a high speed, and the rotor and the stator are subjected to considerable loads. The amount of heat deteriorates the operating performance of the motor.

To this end, the motor according to the prior art forms a predetermined window at the lower end of the motor housing and takes a configuration such that air flows between the rotor and the stator and then discharges through the window. However, such a structure is accompanied by a problem that the air passing through the rotor and the stator is difficult to discharge to the outside smoothly from the motor housing and ultimately increase the internal temperature of the motor. In addition, due to the structure in which all the components are inserted and disposed inside the motor housing according to the prior art, the number of components is increased and the assembly speed is reduced due to the narrowing of the work space, thereby reducing productivity, and the motor housing for accommodating all the components. In addition, the material cost required for the manufacture of the material was also accompanied by a problem of increased manufacturing costs.

In addition, the impeller of the motor used in the cleaner according to the prior art is disposed through the motor shaft and fastened with a nut for fixing the impeller to the motor shaft at the upper end of the motor shaft to prevent the impeller separated from the motor shaft, such as The impeller mounting structure according to the prior art has been accompanied with a problem that the mounting structure may be damaged by the rotation of the motor shaft. That is, the impeller according to the prior art rotates together as the motor shaft rotates. The vibration is transmitted from the motor shaft to the impeller by the vibration or external force generated when the motor shaft rotates, and the transmitted vibration is also transmitted to the nut for mounting the impeller. . If such vibration occurs frequently and frequently, the coupling between the nut and the motor shaft mounted on one end of the motor shaft is loosened to install the impeller, and the coupling between the impeller and the motor shaft through the nut is loosened. Smooth and stable rotation of the impeller may be reduced or prevented, and in some cases may cause damage to the device. In addition, such a coupling through the nut may be slow to assemble, thereby causing a decrease in productivity according to the production rate decreases.

Therefore, an object of the present invention is to provide a motor for a cleaner having a structure capable of improving the operating performance through improving heat dissipation and increasing durability and increasing productivity by simplifying the assembly and reducing manufacturing costs.

The present invention for achieving the above object, a housing cover, an impeller disposed in an inner space formed by the housing cover, a rotor portion, a motor shaft connected to the rotor portion and transmitting a rotational force to the impeller, and a stator core And a stator having a stator coil wound around an outer circumference of the stator core, the cleaner motor comprising: a frame rotatably supporting the other end of the motor shaft and spaced apart from the diffuser; and the frame and the diffuser are frames It may be provided with a fastening unit, and disposed between the frame and the diffuser may be provided with a cleaner motor having a plurality of core projections protruding on the outer peripheral surface of the stator core exposed to the outside.

In addition, the cross-section of the core groove may form an arc on a plane perpendicular to the motor shaft, an impeller mounting O-ring groove formed on the outer peripheral surface of the motor shaft between the housing cover and the impeller, and the impeller mounting O-ring groove It may be provided with an impeller mounting part provided with an impeller mounting O-ring inserted in and arranged. The impeller mounting portion may be disposed on an outer circumference of the motor shaft between the impeller mounting elastic support plate and the impeller mounting elastic support plate disposed parallel to each other between the impeller mounting o-ring and the impeller, and the impeller mounting elastic support plate. An impeller mounting elastic member may be further provided, and the impeller mounting elastic support plate may further include a plurality of support plate flow holes for facilitating the flow of air.

Hereinafter, a cleaner motor according to the present invention will be described with reference to the drawings. 1 is a schematic partial front cross-sectional view of a cleaner motor according to an embodiment of the present invention, and FIG. 2 is a schematic exploded view of the cleaner motor according to an embodiment of the present invention, and FIGS. 3 and FIG. 4 is a schematic partial exploded perspective view of an impeller, a diffuser and a printed circuit board of a cleaner motor according to an embodiment of the present invention. Cleaner motor 10 according to an embodiment of the present invention is provided with a housing cover 100, diffuser 300, motor shaft 110, impeller 200, rotor portion 500, stator 400 The impeller 200 is provided in an inner space formed by the housing cover 100.

The housing cover 100 forms an inner space for accommodating other components. At the upper end of the housing cover 100, air passing through a filter unit (not shown) from an inlet of a cleaner (not shown) is impeller 200. A cover inlet 101 is provided to allow the inlet into. The cover inlet 101 is in fluid communication with the impeller inlet 201 of the impeller 200 disposed in the inner space, and the motor shaft 110 is disposed through the cover inlet 101. In some cases, the cover inlet 101 may be configured to further include a cover mold 102 (see FIG. 2) formed of a synthetic resin or the like to prevent damage due to contact with other components or injury to an operator during work. It may be.

 The motor shaft 110 is disposed through the housing cover 100. The impeller 200 is fixedly disposed at the upper end of the motor shaft 110, and the rotor part 500 is fixedly disposed at the lower end of the motor shaft 110.

The impeller 200 rotates at a high speed with the motor shaft 110 rotating by the rotational force due to the interaction between the stator 400 and the rotor part 500, which are described below, so that the impeller inlet 201 of the impeller 200 A pressure difference occurs between the impeller outlets 202, and thus air is introduced through the impeller inlet 201 by the negative pressure generated in the impeller inlet 201, and the introduced air flows into the impeller 200. After the flow through the impeller discharge port 202 is discharged.

The diffuser 300 is disposed below the impeller 200 as an inner space of the housing cover 100, and an outer end of the diffuser 300 is engaged with the housing cover 100. That is, the outer lower end of the housing cover 100 takes a structure that is bent toward the inner center, and the outer lower end of the curved housing cover 100 takes a structure that surrounds the outer circumference of the diffuser 300 and takes a structure that engages each other. . Here, the housing cover 100 has a structure that is fitted to the diffuser 300, but this is only an example of the present invention is not limited to the configuration of the present invention. That is, various modifications are possible according to design specifications, such as taking a structure connected to each other through a separate fastening structure such as a bolt nut. The diffuser 300 is provided with a guide vane 301, which guides the flow of the air discharged from the impeller 200 and transmits the guide vane 301 to the rotor part 500 and the stator 400 which are disposed under the guide vane 301. . A diffuser shaft through hole 306 (see FIG. 4) is provided at the center of the diffuser 300, and a motor shaft bearing 120 is disposed on one surface of the diffuser 300 facing the rotor unit 500, which is a lower surface of the diffuser 300. The shaft 120 is rotatably mounted to the diffuser 300.

The printed circuit board 700 is disposed to face the impeller 200 with the diffuser 300 therebetween. On the printed circuit board 700 is provided a circuit wiring (not shown) for electrical communication between the electrical element (not shown) such as a control unit for controlling the electrical signal applied to the stator coil of the cleaner motor 10 and the electrical element. do. As in the case of the diffuser 300, a printed circuit board shaft through hole 701 is provided at the center of the printed circuit board 700 to allow the motor shaft 110 to pass therethrough, thereby providing a diffuser shaft through hole of the diffuser 300. Allow the motor shaft 110 through 306 to be disposed through the printed circuit board 700.

In addition, the printed circuit board 700 is disposed below the diffuser 300, and components for coupling them may be further provided. That is, as shown in Figure 4, the lower surface of the diffuser 300 is provided with a printed circuit board mounting protrusion 302, the printed circuit board 700 is provided with a printed circuit board mounting hole 703, diffuser 300 The printed circuit board mounting protrusion 302 of the printed circuit board mounting protrusion 703 may be formed through the mounting arrangement between the two, the printed circuit board mounting protrusion 302 and the printed circuit board mounting hole 703 of the Coupling may limit the rotation of the printed circuit board 700 in the axial direction. In addition, in some cases, the printed circuit board mounting protrusion 302 has a wedge shape so that the combination of the printed circuit board mounting protrusion 302 and the printed circuit board mounting opening 706 is forcibly fitted in the axial direction. You can also restrict movement.

The rotor part 500 includes a rotor core 510 and a rotor magnet 520, and the rotor core 510 includes a rotor core mounting part 511 and a rotor core center part 512. The rotor core mounting portion 511 and the rotor core central portion 512 are disposed in parallel with each other through the motor shaft 110, and the rotor magnet 520 is disposed on the outer circumference of the rotor core central portion 512. Two rotor core mounting portions 511 are disposed in parallel to each other, the rotor core center portion 512 has a region in which the axial length of the motor shaft 110 is changed in the radial direction grooves formed, the rotor core mounting portion 511 is By providing the protrusion protruding in the axial direction of the motor shaft 110, it is possible to more easily mount the rotor core central portion 512. The rotor core mounting portion 511 and the rotor core central portion 512 may be made of different materials, and in some cases, the rotor core mounting portion and the rotor core central portion may have a structure in which they are integrally formed. Various modifications are possible, such as a configuration in which only the rotor core center is independently provided without the rotor core mounting portion. In addition, the rotor magnet 520 is disposed on the outer circumference of the rotor core center 512, the number and arrangement position of the rotor magnet 520 can be variously modified.

The stator 400 is disposed on the outer circumference of the rotor unit 500, and the stator 400 includes a stator core 410 and a stator coil (not shown), which includes an electrical element such as a control unit on a printed circuit board. It takes a structure that is wound around the stator core 410 while making electrical communication. That is, the stator core 410 may have a structure including a plurality of iron pieces. An inner space for accommodating the rotor part 500 is provided at the center of the stator core 410 including the plurality of iron pieces, and the inner space is provided. A plurality of teeth 412 (refer to FIG. 5) formed toward the inner center toward the rotor part 500 disposed in the center is provided. The plurality of teeth are disposed inside the stator core 410 at positions equally divided from the center of the motor shaft 110. The core insulator 413 formed of an insulating material such as an insulating synthetic resin is arranged to have a structure surrounding the teeth 412 such that the stator coil is wound around the outer circumferential surface of the core insulator 413. The 413 may be arranged to surround the teeth 412 of the stator core 410 by taking a configuration in which the pair face each other at the top and the bottom. Accordingly, the stator coils may be wound around the outer circumferential surface of the core insulator 413 so that the stator coils may be wound around the stator core 410 with the rotor part 500 as the center.

The frame 600 is spaced apart from the stator 400 and the rotor part 500 so as to correspond to the diffuser 300. The frame 600 rotatably supports the other end of the motor shaft 110. A frame bearing mounting end 601 is provided at an inner center of the frame 600, and the motor shaft bearing 130 has a frame bearing mounting end ( By being supported by the 601, the motor shaft 110 may be stably supported by the frame 600 to be rotatable.

Cleaner motor 10 according to the present invention is provided with a frame fastening portion 610, the frame fastening portion 610 is connected to the frame 600 and the diffuser 300 but is disposed through the stator core 410 Take the structure That is, as shown in FIGS. 1, 2, and 3, the frame fastening part 610 is composed of a plurality of bolts, the diffuser 300, the printed circuit board 700, the stator core 410, and the frame 600. The diffuser fastening through hole 305, the printed circuit board fastening through hole 702, the core fastening through hole 411 and the frame fastening receiving groove (not shown), respectively, one end of the frame fastening portion 610 is a screw A frame fastening rib is formed which is processed and the other end allows contact support with one surface of the diffuser 300. The diffuser fastening through hole 305, printed circuit board fastening through hole 702, core fastening through hole 411, and frame fastening receiving groove are centered on the motor shaft 110 when viewed in a plane perpendicular to the motor shaft 110. It is equally divided into concentrically from and arranged in the same number as the number of the frame fastening portion 610 composed of a plurality of bolts. The frame fastening part 610 is inserted into the diffuser fastening through hole 305 of the diffuser 300 to connect each diffuser fastening through hole 305, printed circuit board fastening through hole 702, and core fastening through hole 411. After penetrating, one end may be screwed into the frame coupling receiving groove to assemble each component integrally. Through such a structure, the diffuser 300 and the frame 600 are spaced at a predetermined distance to take a structure that is supported by each other. Is allowed.

A frame outer opening 621 (see FIG. 3) is formed on the outer surface of the frame 600, and is discharged from the diffuser 300 to flow between the rotor portion and the stator to cool the heat generated by the rotation of the rotor portion. The heat exchanged with the air may be discharged to the outside of the cleaner motor 10 through the frame outer opening 621 and discharged from the cleaner (not shown) through the air discharge port (not shown) of the cleaner (not shown). .

In addition, the stator core 410 is stably supported between the housing cover 100 and the frame 600 due to the structure of the frame fastening part 610 disposed through the stator core 410. Here, the frame fastening part 610 is composed of a bolt-type component, but this is only an embodiment of the present invention is not limited to the present invention. That is, the frame fastening portion according to an embodiment of the present invention may have a configuration in which one end is formed in a wedge type and a wedge receiving groove is provided in the frame to accommodate the wedge type end, and is fused and mounted by heat or ultrasonic wave. Various configurations can be taken according to design specifications, such as configurations.

Meanwhile, the stator core 410 of the cleaner motor 10 according to an embodiment of the present invention includes a plurality of core protrusions 413 and core grooves 414, and the plurality of core protrusions 413 are stator cores. Protrudingly formed on the outer circumferential surface of the 410, the core groove 414 is disposed between the core projection 413, a plurality of core grooves 414 are also provided. The rotor part 500 is disposed inside the stator core 410 to rotate at high speed. Heat generated in the rotor part 500 which rotates at high speed is transmitted through air flowing through the stator core 410 and the rotor part 500. And cooled through the outer circumferential surface of the stator core 410. That is, part of the heat generated by the rotation of the rotor part 500 flows between the stator core 410 and the rotor part 500 to transfer heat between the inner circumferential surface of the stator core 410 and the outer circumferential surface of the rotor part 510. After it is discharged through the air discharged through the frame outer opening 621, the other part is discharged through the radiant heat emission and / or heat convection through the outer peripheral surface of the stator core 410, the outer peripheral surface of the stator core 410 The surface area of the outer circumferential surface of the stator core 410 is increased by the formed plurality of core protrusions 413 and the core groove 414 disposed between the core protrusions 413, so that heat dissipation through the outer circumferential surface of the stator core 410 is more enhanced. Can be promoted. The stator core 410 may be composed of a plurality of iron pieces. In this case, the core protrusions 413 and the core grooves 414 are formed in the longitudinal direction of the motor shaft 110 by combining the iron pieces having the same size. The length can be formed.

On the other hand, the core groove formed on the outer circumferential surface of the stator core may have a shape that can further improve the flow of air and improve the heat transfer performance by increasing the contact ratio with the flowing air. That is, most of the air discharged from the diffuser 300 is discharged through the gap between the center rotor part and the stator and then discharged through the frame outer opening 621, and the discharged air is discharged from the diffuser 300. By maintaining a significant portion of the kinetic energy, some of the exhausted air may flow at high speeds along the outer circumferential surface of the stator core. The stator core according to the present invention may have a core groove 414a having an arcuate cross section as shown in FIG. 5, and the core groove 414a formed between the plurality of core protrusions 413a may be provided. It is formed to have an arc-shaped cross section when viewed on a plane perpendicular to the motor shaft 110, so that the air discharged through the frame outer opening 621 is a predetermined length along the longitudinal direction of the motor shaft 110. The contact surface between the air guided along the core groove 414a and the core groove 414a may be maximized by being stably guided along the core groove 414a formed to have the shape. Air flow through the core groove length direction is inhibited due to the vortex of air occurring at the corners of the core groove of the rectangular cross section, which prevents the air from flowing along the entire length of the core groove and the air from the core groove of the stator core. The heat release to the high-speed flow air through the entire core groove of the outer circumferential surface of the stator core 410 may be inhibited. The core groove 414a having an arc-shaped cross section is smooth with the high-speed flow air. By preventing or reducing the occurrence of turbulence through the contact, heat release to the high velocity flow air through the entire length of the core groove 414a may be securely ensured.

On the other hand, the cleaner motor 10 according to an embodiment of the present invention may further take a configuration having an impeller mounting portion (800). As shown in Figure 1, the impeller mounting portion 800 is disposed inside the housing cover 100, the impeller mounting portion 800 has an impeller mounting O-ring groove 111 and impeller mounting O-ring 830, the impeller mounting The O-ring groove 111 is formed on the outer peripheral surface of the upper end of the motor shaft 110 between the housing cover 100 and the impeller 200, the impeller mounting O-ring 810 is inserted into the impeller mounting O-ring groove 111. 1, 2 and 6, the impeller mounting O-ring 810 has been shown to have a configuration to facilitate the insertion mounting in the impeller mounting O-ring groove 111 by having an O-ring through-hole on the outside, The present invention is not limited thereto. That is, the impeller-mounted O-ring may be variously modified, such as having a configuration in which the impeller-mounted O-ring is press-fitted to the impeller-mounted O-ring groove. However, by adopting such a configuration, it is not only easy to mount the impeller 200 to the motor shaft 110, but also the impeller mounting O-ring inserted into the impeller mounting O-ring groove 111 even when the impeller rotates. Deviation from the motor shaft 110 due to the rotation of the can be prevented.

On the other hand, the cleaner motor according to an embodiment of the present invention may further include a configuration for absorbing the vibration that can occur according to the rotation of the impeller. That is, the impeller mounting portion 800 further includes an impeller mounting elastic support plate 820, 840 and an impeller mounting elastic member 830. Opposite and arranged in parallel, the impeller mounting elastic members 830 are disposed on the outer circumference of the motor shaft 110 so that the motor shaft 100 penetrates between the impeller mounting elastic support plates 820 and 840. One surface of the impeller mounting elastic support plates 820 and 840 is in contact with the impeller mounting o-ring 810 and the other surface is in contact with the impeller 200, and the vibration and external force applied to the impeller mounting elastic support plates 820 and 840 are It may be attenuated or absorbed by the coil spring type impeller mounting elastic member 830 disposed between the impeller mounting elastic support plates 820 and 840. Accordingly, the impeller mounting O-ring groove 111 of the motor shaft 110 is damaged by the impeller mounting O-ring 810 that restricts the impeller 200 from moving in the axial direction of the motor shaft 110 due to vibration caused by the rotation of the impeller 200. Undesired separation from the ()) is prevented, enabling a more stable integrated rotation of the motor shaft 110 and the impeller 200.

In addition, the impeller mounting elastic support plate may further include a configuration for preventing the inflow of air through the impeller inlet (201, see FIG. 1) is inhibited. That is, as shown in FIG. 7, the impeller mounting elastic support plate 820a disposed with the impeller mounting elastic member interposed therebetween is a support plate through hole 821a which allows a penetration arrangement of the motor shaft 110 (see FIG. 1) in the center thereof. Is provided, and a plurality of support plate flow holes 823a are disposed on the outer circumference of the support plate through hole 821a, and the support plate flow holes 823a are formed through the impeller mounting elastic support plate, thereby providing air through the impeller mounting elastic support plate 820a. By allowing the flow of the more smoothly, the flow of air flowing into the impeller 200 through the impeller mounting portion 800 can be made smoothly.

The above embodiments are examples for describing the present invention, but the present invention is not limited thereto. That is, although the impeller mounting portion of the present invention is shown as having a coil spring type impeller mounting elastic member, it may take a configuration having a leaf spring type elastic member, the fastening of the frame fastening portion for connecting the diffuser and the frame is A plurality of core protrusions and a core formed therebetween on the outer circumferential surface of the stator core are disposed so that the outer circumferential surface is exposed between the frame and the diffuser spaced apart through the frame fastening portion, such as may be made through a wedge-shaped frame fastening wedge end or fusion structure. Various modifications are possible in the range which has a structure provided with a groove.

Cleaner motor according to the present invention having the configuration as described above has the following effects.

First, the cleaner motor according to the present invention improves the operating performance of the cleaner motor by increasing the heat dissipation area of the stator core through the structure of the plurality of core protrusions and core grooves formed on the outer circumferential surface of the stator core to increase the cooling effect. You can.

Second, the cleaner motor according to the present invention, by having a core groove having an arc cross section on a plane perpendicular to the motor shaft to guide the air discharged at high speed between the rotor portion and the stator to smooth heat for the entire length of the core groove It may also be accompanied by an effect of improving operating performance due to the structure which achieves the emission to further increase the cooling effect.

Third, in the cleaner motor according to the present invention, the impeller is separated from the motor shaft through the axial direction through a simple operation by placing the impeller mounting O-ring in the impeller mounting O-ring groove formed in the motor shaft when the impeller and the motor shaft is mounted Prevention and permitting mounting through simple operation may entail increased productivity at increased production speeds.

Fourth, the cleaner motor according to the present invention, by taking a configuration further comprising an impeller mounting elastic plate / impeller mounting elastic member between the impeller mounting O-ring and the impeller, the impeller by the vibration or external force that can occur during rotation of the impeller By preventing the impeller mounting O-ring mounted on the shaft from being undesirably separated from the impeller mounting O-ring groove, a stable rotation of the impeller may be achieved.

Fifth, the cleaner motor according to the present invention, by providing a support plate flow port in the impeller mounting elastic support plate disposed between the impeller mounting O-ring and the impeller mounting O-ring groove, it may smoothly allow the flow of air flowing into the impeller.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be defined by the technical spirit of the utility model registration claims attached.

Claims (5)

A housing cover, an impeller disposed in an inner space formed by the housing cover, a rotor part, a motor shaft connected to the rotor part to transmit rotational force to the impeller, and a stator coil wound around the stator core and the stator core In the motor for a cleaner having a stator having a, A frame disposed rotatably supporting the other end of the motor shaft and spaced apart from the diffuser, and the frame and the diffuser have a frame fastening portion, And a plurality of core protrusions protruding from an outer circumferential surface of the stator core disposed between the frame and the diffuser and exposed to the outside. The method of claim 1, The cross section of the core groove is a cleaner motor, characterized in that to form an arc on a plane perpendicular to the motor shaft. The method of claim 1, And an impeller mounting portion having an impeller mounting o-ring groove formed on the outer circumferential surface of the upper end of the motor shaft between the housing cover and the impeller, and an impeller mounting o-ring inserted into the impeller mounting o-ring groove. The method of claim 3, wherein The impeller mounting portion: An impeller mounting elastic support plate disposed in parallel with each other between the impeller mounting o-ring and the impeller; The impeller mounting elastic member is further provided between the said impeller mounting elastic support plate, and the said motor shaft penetrates and is arrange | positioned on the outer periphery of the said motor shaft. The method of claim 4, wherein The impeller mounting elastic support plate is a cleaner motor, characterized in that further provided with a plurality of support plate flow port for smooth air flow.

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