KR102141392B1 - Motor Assembly - Google Patents

Abstract

The motor assembly of the present invention has a balancing compensator provided to be able to be cut to compensate for rotation balancing, and is provided as a blower fan coupled to the rotor shaft and rotated with the rotor, and a blower fan housing fixedly disposed on the rear surface of the blower fan, It is configured to include a blower fan housing forming a cutting space adjacent to the balancing compensation unit for cutting of the balancing. Through this configuration, it is possible to easily compensate for rotational balancing of the blower fan and the rotor.

Description

Motor assembly

The present invention relates to a motor assembly with improved structure for rotation balancing.

In general, a vacuum cleaner is a household appliance that filters out foreign substances inside the body after inhaling air containing foreign substances such as dust by using a vacuum pressure generated by a motor mounted inside the cleaner body.

The motor generates suction power by lowering the internal pressure by discharging the air inside the vacuum cleaner to the outside. The suction force generated in this way allows foreign matter such as dust on the cleaning surface to be sucked together with external air through the suction means to be removed by a dust collecting device.

A motor is a machine that obtains rotational force from electric energy, and includes a stator and a rotor. The rotor is configured to interact electromagnetically with the stator, and rotates by a force acting between the magnetic field and the current flowing through the coil.

As the blowing fan rotates with the rotational force generated by the rotor, suction force is generated. In this process, if eccentricity occurs due to rotational balancing between the rotor and the blower fan, noise and suction power deterioration occur.

One aspect of the present invention provides a motor assembly with an improved structure to compensate for rotational balance.

The motor assembly according to the spirit of the present invention includes a stator; A rotor having a rotor shaft and rotatably provided by electromagnetic interaction with the stator; A blower fan having a balancing compensator provided to be able to be cut to correct rotation balancing, and coupled to the rotor shaft to be rotated together with the rotor; And a blower fan housing fixedly disposed on a rear surface of the blower fan, and a blower fan housing forming a cutting space adjacent to the balancing correction unit for cutting of the balancing.

The cutting space may be arranged to be open with respect to the radial direction of the blowing fan.

The blowing fan housing includes a housing body provided on one side of the blowing fan; It may be characterized in that it comprises; a cutting insert is formed in an annular shape on the outer periphery of the housing body to form the cutting space, and is formed stepwise in the outer direction with respect to the adjacent housing body.

The blower fan housing may further include a coupling ring coupled to the cutting insert so as to reduce flow resistance at the cutting insert.

The blower fan housing may be disposed between the blower fan and the rotor, and provided to cool the heat generated by the blower fan and the rotor.

The blowing fan includes a fan body having a rotating body shape around a fan rotating shaft; Further comprising; a plurality of wings provided in the first area of the fan body, the balancing correction portion, characterized in that disposed in the second area spaced apart in the axial direction from the first area of the fan body Can.

The first region may be provided on the front surface of the fan body, and the second region may be provided on the rear surface of the fan body.

The blowing fan may be configured to discharge air introduced in the axial direction of the fan rotation axis in a radial direction.

The rotor is provided on the rotor shaft, a rotor magnet that electromagnetically interacts with the stator; It may be characterized in that it comprises a; provided adjacent to the rotor magnet is provided with a rotor balancing correction that is provided so as to be able to cut to correct the rotational balancing of the rotor.

The balancing compensation portion and the rotor balancing compensation portion may be provided to be cut in the centrifugal direction with respect to the rotor shaft.

The rotor balancing compensator may include: a first rotor balancing compensator provided to be cuttable in the centrifugal direction from the upper portion of the rotor magnet; It may be characterized in that it comprises; a second rotor balancing compensation portion provided to be cuttable in a direction parallel to the rotor axial direction from the lower portion of the rotor magnet.

The blowing fan housing includes: a housing body having a support surface facing the second region; It may be characterized in that it comprises a; a cutting insert to form a cutting space adjacent to the support surface and provided to expose the balancing compensation portion of the second region.

The cutting insert may be formed to be concave in the centrifugal direction from the housing body.

Further comprising; a diffuser unit coupled to the rear surface of the blowing fan housing, the diffuser unit, an annular diffuser unit body disposed along the periphery of the blowing fan housing; It may be characterized in that it comprises a; a plurality of ribs disposed on the extension line of the air flow path blowing from the blower fan in the diffuser unit body.

The diffuser unit body may include a space coupling portion extending from the diffuser unit body and projecting toward an annular center so as to correspond to the cutting insert.

The diffuser unit body, when the cutting insertion portion and the space coupling portion is coupled to the diffuser unit so that the diffuser unit is in close contact with the rear surface of the blower fan housing, a protruding extension formed in the centrifugal direction from the annular diffuser unit body; further It may be characterized by including.

The blower fan housing may include an aluminum material, and the diffuser unit may include a plastic material.

The motor assembly of the present invention can reduce the occurrence of eccentricity by correcting the rotational balance, thereby reducing noise generation and improving suction power by the blowing fan.

1 is a view showing a cleaner according to a first embodiment of the present invention.
Figure 2 is a cross-sectional view of a part of the vacuum cleaner according to the first embodiment of the present invention.
3 is a perspective view of a motor assembly according to a first embodiment of the present invention.
4 is a cross-sectional view of a motor assembly according to a first embodiment of the present invention.
Figure 5 is an exploded perspective view of the motor assembly according to the first embodiment of the present invention.
Figure 6 is an exploded perspective view of the blowing fan, the blowing fan housing, the rotor according to the first embodiment of the present invention.
7, 8 is a cross-sectional view of a partial configuration according to the first embodiment of the present invention.
9 is an enlarged view of A of FIG. 7.
10 is a perspective view according to a second embodiment of the present invention.
11 is an exploded perspective view of a partial configuration according to a second embodiment of the present invention.
12 is a bottom perspective view of a blower fan housing according to a second embodiment of the present invention.
13 is a rear view of the combined blowing fan housing and the blowing fan according to the second embodiment of the present invention.
14 is a perspective view of a diffuser unit according to a second embodiment of the present invention.
15 is a bottom perspective view of a combined diffuser unit and a blower fan housing according to a second embodiment of the present invention.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a cleaner according to a first embodiment of the present invention, and FIG. 2 is a cross-sectional view of a part of the cleaner according to the first embodiment of the present invention.

The cleaner 1 of the embodiment of the present invention includes a stick body 10, a suction part 20, and a cleaning basic body 30.

The stick body 10 is a portion that is coupled to the upper end of the cleaning basic body 30 and may be provided to allow the user to operate the cleaner 1 by gripping. The control unit 12 is provided on the stick body 10 and is provided to allow the user to control the cleaner 1.

The suction part 20 is provided under the cleaning basic body 30 and is arranged to contact the surface to be cleaned. The suction unit 20 is provided to contact the surface to be cleaned, and to introduce dust or dirt from the surface to be cleaned into the cleaning base body 30 with suction force generated from the motor assembly 100.

The cleaning basic body 30 includes a motor assembly 100 provided therein and a dust container 40. The motor assembly 100 generates power so as to generate suction force inside the cleaning base body 30, and the dust container 40 is disposed upstream of the air flow than the motor assembly 100 and flows in from the suction part 20 It is provided to filter and collect dust and dirt in the air.

3 is a perspective view of the motor assembly according to the first embodiment of the present invention, FIG. 4 is a cross-sectional view of the motor assembly according to the first embodiment of the present invention, and FIG. 5 is an exploded view of the motor assembly according to the first embodiment of the present invention. It is a perspective view.

The motor assembly 100 is provided inside the cleaning base body 30 and is provided to generate suction power.

The motor assembly 100 includes a housing 102, a motor 170 installed inside the housing 102 to generate suction force, and a seating housing 142 provided to fix the motor 170 within the housing 102 ) And a blower fan 130 installed on the rotor shaft 172a of the motor 170 and provided to rotate.

The housing 102 includes a first housing 110 and a second housing 120 provided to be coupled to the first housing 110. The housing 102 may be provided to have a substantially cylindrical shape, but is not limited thereto, and various shapes may be provided. The first housing 110 and the second housing 120 may be provided detachably in the axial direction of the rotor shaft 172a. The first housing 110 is provided with an air intake 111 so that air introduced by the motor 170 flows into the housing 102, and the second housing 120 is air introduced into the housing 102. Air outlet 121 is provided so that it can be discharged. Since the second housing 120 is coupled to the first housing 110 on the rear surface of the first housing 110, an air intake 111 is provided in front of the housing 102, and an air outlet 121 is provided in the rear. Can be prepared. However, the arrangement of the air intake 111 and the air outlet 121 is not limited.

The first housing 110 and the second housing 120 are combined to form an air passage 113 leading from the air intake 111 to the air outlet 121, and therein a motor 170 or a blower fan 130 ) To form the inner space 127 where the lamps are arranged.

The air flow path 113 may include a module flow path 113a and a module external flow path 113b. Air is sucked from the motor assembly 100 by the blowing fan 130, and the sucked air flows through the air passage 113. The air introduced into the interior of the housing 102 is a module flow path 113a introduced into the motor module 140 by the flow guide section 194 of the insulator 190, and the exterior and housing of the motor module 140 ( 102), the module external flow passage 113b passing between the inner sides may flow. The suction air passing through the module flow path 113a can cool the heat generated from inside the motor module 140. The suction air passing through the module flow path 113a and the suction air passing through the module external flow path 113b can cool the heat generated from the circuit board 196 while passing through the circuit board 196.

The first housing 110 may include a shroud 112.

The shroud 112 is provided to correspond to the blower fan 130 or the diffuser unit 122 to be described later, and guides air introduced into the housing 102 by the motor 170. The shroud 112 is a space formed by the shroud 112 with respect to the axial direction of the rotor shaft 172a so that a flow path is formed wide along the traveling direction of the intake air by the motor 170 from the air intake 111 It can be provided to widen. The shroud 112 allows air introduced through the air intake 111 to be guided to the interior of the housing 102, and may be provided in a shape corresponding to the upper portion of the blowing fan 130.

A blowing fan 130 may be provided inside the air intake 111 of the first housing 110. The blowing fan 130 will be described later.

The second housing 120 may include a diffuser unit 122. The diffuser unit 122 is provided to increase the flow velocity of air flowing by the blowing fan 130. It is provided to be disposed on the outer side along the radial direction of the blowing fan 130. The diffuser unit 122 may be provided to include a plastic material.

The diffuser unit 122 may be provided in a radial direction with respect to the blowing fan 130. In detail, it may be formed in a direction extending with respect to the plurality of wings 132 of the blowing fan 130. Diffuser unit 122 may be formed of a plurality of ribs (123, 124), a plurality of ribs (123, 124) is formed so that the spacing between the gaps along the extending direction with respect to the plurality of wings (132) Can. A plurality of ribs (123, 124) is formed to increase the flow rate of the air while guiding the air flowing by the blowing fan 130. In detail, the diffuser unit 122 and the shroud 112 formed in the first housing 110 form the diffuser flow path 125 to guide the air flowing by the blower fan 130 while the air flow velocity It is formed to increase.

The plurality of ribs 123 and 124 may include a first rib 123 and a second rib 124. The first rib 123 is provided on the same plane as the downstream end of the air flow by the blowing fan 130, and the second rib 124 has air guided by the first rib 123 to the housing 102 ) Is formed to have a certain inclination in the direction of the rotor shaft 172a so as to flow along the up and down direction, which is the direction of the rotor shaft 172a.

A motor module 140 may be provided inside the housing 102. The motor module 140 is provided so that the motor 170 is fixed inside the housing 102 as one module.

The motor module 140 may include a motor 170 and a seating housing 142.

The seating housing 142 may include a front seating housing 150 and a rear seating housing 160 provided to be coupled to the front seating housing 150 with the motor 170 interposed therebetween.

The front seat housing 150 is provided to be fixed to the housing 102. In detail, a hole-shaped seating hole 126 in which the front seating housing 150 is provided is formed at the center of the second housing 120, and the front seating housing 150 may be coupled to the seating hole 126. have. It may be fitted and the method of coupling is not limited.

The front seating housing 150 may include a front seating housing body 151 and a front seating portion 154. The front seat housing body 151 may be formed in a substantially disc shape. And, as described above, it may include a body coupling portion 152 corresponding to the shape of the seating hole 126 to be coupled to the seating hole 126 of the hole shape of the second housing 120.

The front seating portion 154 is provided so that the motor 170 is seated on the rear surface of the front seating housing body 151. The front seating portion 154 is provided to seat and fix the stator 180 so that the center of the rotor 172 that is rotatably provided is disposed the same as the rotation center of the blowing fan 130.

The shape of the front seating portion 154 is not limited, and in an embodiment of the present invention, it is provided to protrude from the front seating housing body 151 so that the front seating housing body 151 and the motor 170 are spaced at regular intervals to be seated. It is formed to be.

The arrangement of the front seating portion 154 is not limited, but in the embodiment of the present invention, since the stator 180 is formed to be long in the first direction w1, the front seating portion 154 is provided at each end of the stator 180. Four can be arranged to correspond.

The rear seating housing 160 is provided to be coupled with the front seating housing 150, and the motor 170 is disposed between the front seating housing 150 and the front seating housing 150.

The rear seating housing 160 may include a rear seating housing body 161 and a rear seating unit 164. The rear seating housing body 161 may be formed to be elongated along the longitudinal direction of the stator 180 to correspond to the shape of the stator 180.

Arrangement of the rear seating portion 164 is not limited, but in the embodiment of the present invention, since the stator 180 is formed to be long in the longitudinal direction, four rear seating portions 164 correspond to each end of the stator 180. Can be deployed.

The front seating housing 150 and the rear seating housing 160 have screw holes 151b and 161b, respectively, for coupling, and are provided to be coupled by screws 148.

The front seat housing 150 may be referred to as a blowing fan housing 150 from the perspective of a blowing fan.

6 is an exploded perspective view of a blower fan, a blower fan housing, and a rotor according to the first embodiment of the present invention, FIGS. 7 and 8 are cross-sectional views of some configurations according to the first embodiment of the present invention, and FIG. 9 is A of FIG. 7 It is an enlarged view.

The blowing fan 130 is provided to be rotatable and is provided to generate suction power.

The blowing fan 130 includes a fan body 132 having a rotating body shape around a fan rotating shaft 132a and a plurality of wings 135. The fan rotation shaft 132a is provided to match the rotor shaft 172a of the rotor 172. In this embodiment, the blowing fan 130 is provided to bend the air flowing in the axial direction by bending in the radial direction with respect to the axial direction. To this end, the fan body 132 of the blowing fan 130 is formed such that the radius of the fan rotating shaft 132a increases in an upstream to downstream direction with respect to the air traveling direction. That is, it is provided to guide the air flowing in the direction of the fan rotating shaft 132a in the radial direction of the fan rotating shaft 132a according to the rotation of the blowing fan 130.

The fan body 132 may be provided with a plurality of wings 135 to generate a flow of air. The fan body 132 has a fan front 134 on which a plurality of wings 135 are arranged to generate air flow, and a fan rear 136 provided on the rear surface of the fan to correspond to the front surface of the blowing fan housing 150. ). The fan front 134 and the fan rear 136 may be referred to as a first region 134 and a second region 136, respectively. The second region 136 is provided to be spaced apart in the axial direction of the first region 134 and the fan rotation shaft 132a.

The blowing fan 130 may include a balancing compensation unit 137.

The balancing compensation unit 137 is provided on the blowing fan 130, and is provided to be cuttable to correct rotational balancing of the blowing fan 130. That is, it is provided to be cuttable in the second region 136 of the blowing fan 130. The balancing unit 137 may be integrally formed with the blowing fan 130. The balancing unit 137 may be provided in an annular shape in the second region 136 of the blowing fan 130. The balancing correction unit 137 may be a separate configuration from the fan body 132, and in an embodiment of the present invention, is integral with the fan body 132 and is formed as a part of the fan body 132.

The balancing unit 137 may be formed of the same material as the blowing fan 130, but is not limited thereto and may be formed of a separate material. If the rotational balancing does not match with the blowing fan 130 rotating about the fan rotating shaft 132a, problems such as weak suction power or noise may occur. To this end, the blowing fan 130 is provided with a balancing compensation 137 to be cuttable, so that it is possible to correct rotational balancing by cutting at least a portion.

The balancing compensation unit 137 may be provided to be exposed to a radial direction centered on the fan rotation axis 132a when the blowing fan 130 rotates. Through this, a cutting mechanism (not shown) for cutting the balancing compensator 137 flows in the direction of the fan rotation shaft 132a during the balancing operation, cutting at least a portion of the balancing compensator 137, and rotating the blowing fan 130 The balancing will be corrected.

The blowing fan housing 150 is disposed on the rear surface of the blowing fan 130 and is provided to be fixed to the housing.

The front surface of the blowing fan housing 150 is provided to correspond to the rear surface of the blowing fan 130, and is provided to form a small gap to reduce the flow resistance in relation to the blowing fan 130. The rear side of the blower fan housing 150 is provided so that one side of the stator 180 can be seated.

A blowing fan 130 may be disposed in front of the blowing fan housing 150, a rotor 172 and a stator 180 may be disposed in the rear, and a bearing 173a may be disposed in the hollow portion 151a. The blower fan housing 150 may be provided to include an aluminum material so as to cool the heat generated from the adjacent components.

The blower fan housing 150 may include a housing body 151 and a cutting insert 157.

The housing body 151 may be provided on one side of the blowing fan 130. The housing body 151 has the same configuration as the front seating housing body 151, and has only different names for convenience of explanation. The housing body 151 is provided to correspond to the shape of the blowing fan 130, and is provided to have a substantially disc shape. A hollow portion 151a is formed in the center of the housing body 151 so that the rotor shaft passes, and a bearing may be disposed in the hollow portion 151a for smooth rotation of the rotor shaft. Through this configuration, the blowing fan 130 disposed on one side of the housing body 151 and the motor disposed on the other side may be rotatably coupled.

The cutting insert 157 may be provided on the housing body 151.

The cutting insert 157 may be provided to correspond to the second region 136 in the housing body 151. The cutting insert 157 may form a cutting space 158. The cutting space 158 is provided so that the cutting mechanism is not interfered by the blowing fan housing 150 when a cutting mechanism (not shown) is used to cut the balancing compensation portion 137 of the blowing fan 130. To this end, the cutting space 158 is arranged to be open to the radial direction around the fan rotation axis 132a of the blowing fan 130.

The cutting insert 157 is formed in an annular shape on the outer periphery of the housing body 151 to form a cutting space 158, and may be formed to be stepped in the outer direction with respect to the adjacent housing body 151.

The housing body 151 may include a support surface 151b facing the second region 136 of the blowing fan 130 on its front surface. The support surface 151b is provided to correspond to the blowing fan 130 on the front surface of the housing body 151. The support surface 151b is provided to correspond to the shape of the rear surface of the blowing fan 130 so that rotation of the blowing fan 130 does not interfere. The cutting insert 157 is formed to be stepped with the support surface 151b, and is provided to be disposed in the radial direction of the support surface 151b.

Since the cutting insert 157 is formed to be stepped with the support surface 151b of the housing body 151 to form the cutting space 158, the flow path resistance in the cutting space 158 when the suction force is generated by the blowing fan 130 Can occur.

To prevent this, the blowing fan housing 150 may include a coupling ring 159 disposed along the cutting insert 157. The coupling ring 159 may be provided in an annular shape in correspondence with the annular cutting insert 157, and disposed along the cutting insert 157 to fill the cutting space 158. In FIG. 7, the coupling ring 159 is separated, and in FIG. 8, the coupling ring 159 is disposed in the cutting space 158.

During the cutting operation to correct the rotational balancing of the blower fan 130, the coupling ring 159 is released to form a cutting space 158 so that the cutting mechanism can be introduced, and when the cutting operation is completed, the cutting space 158 ) By filling the coupling ring 159 to reduce the flow resistance.

The motor 170 may include a rotor 172 and a stator 180.

The rotor 172 is rotatably provided at the center of the stator 180.

The stator 180 is provided to electromagnetically interact with the rotor 172.

The stator 180 may include a stator body 182, an insulator 190, and a coil 195.

The rotor 172 may be disposed in the rotor accommodating portion 186 of the stator 180. The rotor 172 may be provided to electromagnetically interact with the stator 180 in the rotor accommodating portion 186.

The rotor 172 may include a rotor shaft 172b and a rotor magnet 173.

The rotor shaft 172b is rotatably provided around the rotor shaft 172a. The blower fan 130 is coupled to one end of the rotor shaft 172b to be provided to rotate together with the rotor 172. The rotor shaft 172b may be provided in the shape of a rod. The rotor shaft 172b may rotate while forming an air gap 185b between the expansion core portion 185a of the stator 180.

The rotor magnet 173 is provided so that the rotor shaft 172b passes. That is, it is provided to be disposed along the periphery of the rotor shaft 172b. The shape and arrangement method of the rotor magnet 173 is not limited, but in the embodiment of the present invention, the rotor magnet 173 is provided in an annular shape, and is provided so that the rotor shaft 172b passes through the center of the annular shape.

The rotor 172 may include a rotor balancing compensation unit 175.

The rotor balancing compensation unit 175 is provided to be able to cut to correct the rotational balancing of the rotor 172

The rotor balancing compensation unit 175 is provided to be adjacent to the rotor magnet 173. In detail, the rotor balancing compensation unit 175 may be disposed adjacent to the rotor magnet 173 in the direction of the rotor shaft 172a. A pair of rotor balancing compensation units 175 may be provided, and may be disposed on one side and the other side in the direction of the rotor shaft 172a of the rotor magnet 173. The rotor balancing compensation unit 175 may include a balancer. That is, a pair of balancers are provided on one side and the other side of the rotor magnet 173, and may be provided to compensate for eccentricity due to the rotation of the rotor 172.

The rotor balancing compensation unit 175 is provided so that the rotor shaft 172b passes. That is, it may be provided to be disposed along the periphery of the rotor shaft 172b. The shape and arrangement method of the rotor balancing compensator 175 are not limited, but in the embodiment of the present invention, the rotor balancing compensator 175 is provided in an annular shape so that the rotor shaft 172b passes through the center of the annulus. .

The rotor balancing compensation portion 175 is disposed on one side of the rotor magnet 173 along the direction of the rotor shaft 172a and the rotor magnet 173 along the direction of the rotor shaft 172a. It may include a second rotor balancing compensation unit (175b) disposed on the other side of.

The balancing compensator 137 and the rotor balancing compensator 175 may be provided to be cut in the centrifugal direction with respect to the rotor shaft. In detail, the blower fan housing 150 is constrained so as not to operate, and both ends of the rotor shaft 172a are constrained in the axial direction, and then the rotor shaft 172a is rotated to rotate the blowing fan 130 and the rotor 172. You will measure balancing. In this process, at least a part of the balancing compensator 137 or the rotor balancing compensator 175 is inserted by using a cutting mechanism (not shown) in the centrifugal direction based on the direction of the rotor shaft 172a to correct the rotational balancing. It will cut.

The rotor balancing compensation portion 175 may be provided to be cuttable in the centrifugal direction based on the rotor axis direction together with the balancing compensation portion 137, and the first rotor balancing compensation portion 175a may be centrifuged based on the rotor axis direction. Cutting in the direction and the second rotor balancing compensation portion (175b) may be provided to be capable of cutting in a direction parallel to the rotor axis direction.

The rotor 172 may be provided with a plurality of bearings (173a, 173b). The arrangement of the plurality of bearings 173a and 173b is not limited, and in the embodiment of the present invention, one bearing 173a is provided between the hollow portion 151a of the blowing fan housing 150 and the rotor shaft 172a. , One bearing 173b is provided between the rear seating housing 160 and the rotor shaft 172b.

The following describes the motor assembly according to the second embodiment.

This embodiment differs from the configuration of the motor assembly 100, the blower fan housing 250, and the diffuser unit 222 in the first embodiment.

FIG. 10 is a perspective view according to a second embodiment of the present invention, FIG. 11 is an exploded perspective view of a partial configuration according to a second embodiment of the present invention, and FIG. 12 is a lower perspective view of the blower fan housing according to the second embodiment of the present invention , Figure 13 is a rear view of the combined blower fan housing and the blower fan according to the second embodiment of the present invention, Figure 14 is a perspective view of a diffuser unit according to a second embodiment of the present invention, Figure 15 is a second embodiment of the present invention It is a bottom perspective view of the combined diffuser unit and the blower fan housing according to the embodiment.

The blowing fan housing 250 is disposed on the rear surface of the blowing fan 230 and is provided to be fixed to the housing 102.

The front surface of the blowing fan housing 250 is provided to correspond to the back surface of the blowing fan 230, and is provided to form a small gap to reduce the flow resistance in relation to the blowing fan 230. At the rear of the blower fan housing 250, one side of the stator 180 is provided to be seated.

A blowing fan 230 may be disposed in front of the blowing fan housing 250, a rotor 172 and a stator 180 may be disposed in the rear, and a bearing 273a may be disposed in the hollow portion 251a. The blower fan housing 250 may be provided to include an aluminum material so as to cool the heat generated from the adjacent components.

The blowing fan housing 250 may include a housing body 251 and a cutting insert 257.

The housing body 251 may be provided on one side of the blowing fan 230. The housing body 251 has the same configuration as the front seating housing bodies 251 and 251. The housing body 251 is provided to correspond to the shape of the blowing fan 230, and is provided to have a substantially disc shape. A hollow portion 251a is formed in the center of the housing body 251 so that the rotor shaft passes, and a bearing may be disposed in the hollow portion 251a for smooth rotation of the rotor shaft. Through this configuration, the blower fan 230 disposed on one side of the housing body 251 and the motor disposed on the other side may be rotatably coupled.

The cutting insert 257 may be provided on the housing body 251.

The housing body 251 may include a support surface 251b facing the second region 236. The support surface 251b is provided to form a small gap with the second region 236 of the blowing fan 230.

The cutting insert 257 may form a cutting space 258 adjacent to the support surface 251b and provided to expose the balancing compensation portion 237 of the second region 236. In detail, the cutting insert 257 is formed at least partially concave in the disc-shaped housing body 251 in the centrifugal direction, so that the back surface of the blowing fan 230 is not supported by the supporting surface 251b, but the blowing fan housing ( 250).

The number of cutting inserts 257 is not limited, and in the embodiment of the present invention, a pair of cutting inserts 257 are provided in opposite directions.

As the back surface of the blowing fan 230 is provided to be exposed to the back surface of the blowing fan housing 250, the cutting mechanism may prevent the adjacent components from affecting the cutting of the balancing compensation portion 237.

The cutting insert 257 may include a first cutting insert surface 257a in the radial direction and a second cutting insert surface 257b in the circumferential direction.

The first cutting insert surface 257a forms a depth in the centrifugal direction of the cutting space 258, and the second cutting insert surface 257b is provided to form a circumferential width of the cutting space 258. The second cutting insert surface 257b may be formed to extend along the circumferential direction with respect to the rotor axis direction.

The diffuser unit 222 is provided to increase the flow velocity of air flowing by the blowing fan 230. It is provided to be disposed on the outer side along the radial direction of the blowing fan 230.

The diffuser unit 222 may include a diffuser unit body 222a and a plurality of ribs 222b.

The diffuser unit 222 may be provided in a radial direction with respect to the blowing fan 230. In detail, it may be formed in a direction extending with respect to the plurality of wings 235 of the blowing fan 230. The diffuser unit body 222a may be formed in an annular shape along the periphery of the blowing fan housing 250.

A plurality of ribs (222b) is provided on the diffuser unit body (222a), it may be formed so that the spacing between the plurality of wings 235 extending along the direction extending. A plurality of ribs (222b) is formed to increase the flow rate of the air while guiding the air flowing by the blowing fan 230.

The diffuser unit 222 may include a space coupling unit 223.

The space coupling portion 223 is provided to extend from the diffuser unit body 222a to protrude toward the center of the annulus so as to correspond to the cutting insert 257. When the diffuser unit 222 is coupled to the rear surface of the blower fan housing 250, the space coupling unit 223 is provided so as to correspond to the cutting insert 257 so that both components form concentric and can be combined. In the embodiment of the present invention, the cutting insertion portion 257 is disposed in the opposite direction of the pair, and the spatial coupling portion 223 may also be formed to face the pair corresponding to this.

The spatial coupling portion 223 may include a first spatial engagement surface 223a corresponding to the first cutting insertion surface 257a and a second spatial engagement surface 223b corresponding to the second cutting insertion surface 257b. Can. Blowing fan housing 250 and diffuser unit (1) so that the first cutting inserting surface 257a corresponds to the first spatial engaging surface 223a and the second cutting inserting surface 257b corresponds to the second spatial engaging surface 223b, respectively. 222) By combining, both configurations are concentric, and may be provided to be firmly coupled.

The diffuser unit 222 may include a coupling contact portion 224. The engaging contact portion 224 is formed to protrude along the inner circumferential surface of the diffuser unit body 222a, and the diffuser unit 222 is provided to be seated on the blowing fan housing 250.

In detail, the housing body 251 of the blowing fan housing 250 may be provided with a coupling seat 258 that is concavely formed along its outer circumferential surface. Coupling seating portion 258 may be formed along at least a portion of the outer circumferential surface of the housing body 251, the circumference of the first cutting inserting surface 257a and the second cutting inserting surface 257b of the cutting insert 257 It can be formed accordingly. The engagement contact 224 of the diffuser unit 222 is seated on the coupling seat 258 of the blowing fan 230 unit, so that the diffuser unit 222 can be seated on the blowing fan 230 unit.

The diffuser unit 222 may include a position adjustment unit 225.

The position adjustment unit 225 is provided to protrude in the centrifugal direction from the annular diffuser unit body 222a. At least one position adjusting unit 225 may be provided, and in the exemplary embodiment of the present invention, four are provided, each spaced apart in the circumferential direction. The position adjustment unit 225 is provided so that the blowing fan 230 unit and the diffuser unit 222 have concentricity when combined.

Correspondingly, the blowing fan 230 unit is provided with a position adjusting seat 259 on which the position adjusting unit 225 is seated, so that the diffuser unit 222 can be coupled to the blowing fan 230 unit. The depth of the position adjustment seating portion 259 is provided to be deeper than the thickness of the position adjustment portion 225, and may be provided so that the blowing fan housing 250 and the diffuser unit 222 can be bonded by injecting an adhesive into the corresponding space. .

In the above, specific examples have been illustrated and described. However, the present invention is not limited to the above-described embodiments, and those skilled in the art to which the invention pertains may perform various modifications without departing from the gist of the technical spirit of the invention described in the claims below. .

1: Cleaner 100: Motor assembly
130: blowing fan 132: fan body
134: first area 135: a plurality of wings
136: Area 2 137: Balancing Security Administration
170: motor 172: rotor
172a: rotor shaft 180: stator
150: blowing fan housing 151: housing body
157: cutting insert 158: cutting space
159: coupling ring 175: rotor balancing
175a: 1st rotor balancing government
175b: 2nd rotor balancing government

Claims (17)

Stator;
A rotor having a rotor shaft and rotatably provided by electromagnetic interaction with the stator;
A blower fan having a balancing compensator provided to be able to be cut to correct rotation balancing, and coupled to the rotor shaft to be rotated together with the rotor;
Includes a blower fan housing fixedly disposed on the rear surface of the blower fan to form a cutting space adjacent to the balancing member for cutting of the balancing member.
The blower fan housing,
A housing body provided on one side of the blowing fan; And
And a cutting insert formed in an annular shape on the outer periphery of the housing body to form the cutting space, and formed to be stepped in the outer direction with respect to the adjacent housing body. According to claim 1,
The cutting space,
The motor assembly, characterized in that arranged to be open with respect to the radial direction of the blowing fan. delete According to claim 1,
The blower fan housing,
And a coupling ring coupled to the cutting insert to reduce the flow resistance at the cutting insert. According to claim 1,
The blower fan housing,
And a motor assembly disposed between the blower fan and the rotor to cool the heat generated by the blower fan and the rotor. According to claim 1,
The blowing fan,
A fan body having a rotating body shape around a fan rotating shaft;
Further comprising; a plurality of wings provided in the first region of the fan body,
The balancing government,
And a second region spaced apart from the first region of the fan body in the axial direction of the fan rotation axis. The method of claim 6,
The first region,
It is provided on the front of the fan body,
The second region,
The motor assembly, characterized in that provided on the rear of the fan body. The method of claim 6,
The blowing fan,
And a motor assembly configured to discharge air introduced in the axial direction of the fan rotation shaft in a radial direction. According to claim 1,
The rotor,
A rotor magnet provided on the rotor shaft and in electromagnetic interaction with the stator;
And a rotor balancing correction unit provided adjacent to the rotor magnet and provided to be cuttable to correct rotational balancing of the rotor. The method of claim 9,
The balancing unit and the rotor balancing unit,
The motor assembly, characterized in that provided to be cut in the centrifugal direction with respect to the rotor shaft. The method of claim 9,
The rotor balancing government,
A first rotor balancing compensator provided to be cuttable in the centrifugal direction from the upper portion of the rotor magnet;
And a second rotor balancing compensator provided to be cuttable in a direction parallel to the rotor shaft direction at a lower portion of the rotor magnet. Stator;
A rotor having a rotor shaft and rotatably provided by electromagnetic interaction with the stator;
A fan body having a rotating body shape around a fan rotating shaft, a plurality of blades provided in a first region of the fan body, and a balancing correction portion provided to be able to be cut to correct rotation balancing, and coupled to the rotor shaft A blowing fan provided to rotate together with the rotor;
Includes; a blower fan housing fixedly disposed on the rear surface of the blower fan to form a cutting space adjacent to the balancing compensator for cutting of the rotating balance;
The balancing government,
In the first region of the fan body is spaced apart in the axial direction of the fan rotation axis,
The blower fan housing,
A housing body having a support surface facing the second region; And
Includes a cutting insert that is adjacent to the support surface and forms a cutting space provided to expose the balancing compensation portion of the second region.
The first region is provided on the front surface of the fan body, and the second region is provided on the rear surface of the fan body. The method of claim 12,
The cutting insert,
A motor assembly characterized in that it is formed concave in the centrifugal direction from the housing body. The method of claim 12,
Further comprising; a diffuser unit coupled to the back of the blowing fan housing,
The diffuser unit,
An annular diffuser unit body disposed along the periphery of the blower fan housing;
And a plurality of ribs disposed on an extension line of the air flow path blowing from the blower fan in the diffuser unit body. The method of claim 14,
The diffuser unit body,
And a space coupling portion extending from the diffuser unit body so as to correspond to the cutting insert and protruding toward the center of the annulus. The method of claim 15,
The diffuser unit body,
When engaging the cutting insert and the space coupling unit, the diffuser unit is formed to protrude in the centrifugal direction from the annular diffuser unit body so that the diffuser unit is in close contact with the back surface of the blower fan housing. Motor assembly. The method of claim 14,
The blower fan housing,
Aluminum material,
The diffuser unit,
A motor assembly comprising a plastic material.

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