KR20150118858A - Vacuum cleaner - Google Patents

Abstract

Disclosed is a vacuum cleaner having an improved structure for mass-production and cost reduction to be possible. In a vacuum cleaner which comprises a suction unit placed in the main frame, the suction unit comprises: a motor; an impeller connected to the motor by a rotating shaft to take in air by rotation; and, a diffuser for guiding the air discharged from the impeller. The impeller comprises: a body having a hub formed in the center; and, multiple blades placed on the body to have a leading edge extended from the hub toward the outside of the hub. At least a part of the leading edge comprises a curve.

Description

Vacuum cleaner {VACUUM CLEANER}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a vacuum cleaner, and more particularly, to a vacuum cleaner having an improved structure capable of mass production and cost reduction.

BACKGROUND ART [0002] Generally, a vacuum cleaner has been developed and used as various kinds of vacuum cleaners as an electrical product that sucks and collects dirt from a surface to be cleaned by using a suction force.

The vacuum cleaner includes a main body and a dust separating device provided inside the main body for separating dust and air, a dust collecting device for collecting dust separated by the dust separating device, and a vacuum suction Unit. ≪ / RTI >

Therefore, when the vacuum suction unit operates, air containing dust flows into the interior of the body, and is separated into dust and air by the dust separating device. The air separated from the dust can be discharged to the outside of the main body through the vacuum suction unit.

The vacuum suction unit may include a motor and an impeller connected to the motor.

In recent years, attention has been paid to injection molding as a manufacturing method of an impeller in terms of mass production and cost reduction.

One aspect of the present invention provides a vacuum cleaner having an improved structure capable of injection molding of an impeller.

Another aspect of the present invention provides a vacuum cleaner having an improved structure for preventing an undercut shape that may occur during an injection molding process of an impeller.

The suction unit includes a motor, a motor connected to the motor by a rotating shaft, an impeller for sucking air by rotation, and a motor for driving the motor, The impeller includes a body having a hub formed at a central portion thereof, and a plurality of teeth having a leading edge extending from the hub toward the outer direction of the hub, And a blade, wherein at least a portion of the leading edge comprises a curve.

The leading edge may include a convex curve toward the rotational direction of the impeller.

The leading edge may include a convex circular arc shape toward the rotational direction of the impeller.

The leading edge may be connected to a fixing part fixed to the body so as to be adjacent to the hub and an edge part formed at one end of the leading edge so as to face the outer direction of the hub.

Wherein the leading edge includes a first region connected to the fixing portion and a second region connected to the edge portion, the first region including at least one of a straight line and a curve, and the second region including a curve can do.

The first region and the second region may include curves having different curvatures.

In the vacuum cleaner according to the present invention, the suction unit includes a motor, a motor connected to the motor by a rotary shaft, and an impeller for sucking air by rotation, and an air blower Wherein the impeller includes a body having a hub formed at a central portion thereof and a plurality of blades provided on the body and having a leading edge adjacent to the hub, All or a part of the leading edge is curved so as to prevent the undercut from occurring in the leading edge during the injection process.

The leading edge may have a convex curve toward the rotational direction of the impeller.

Wherein the leading edge connects a fixing part fixed to the body so as to be adjacent to the hub and an edge part formed at one end of the leading edge so as to face the outer direction of the hub, and a part of the leading edge including the edge part Curve.

By forming at least a portion of the leading edge with a curved line, an undercut shape that may occur in the leading edge during the injection molding process of the impeller can be prevented.

It is possible to expect mass production and cost reduction of the impeller by injection molding the impeller.

1 is a view illustrating a state in which a vacuum cleaner according to an embodiment of the present invention is coupled to a stick body;
2 is a view illustrating a state in which a vacuum cleaner according to an embodiment of the present invention is separated from a stick body
3 is a cross-sectional view illustrating a vacuum cleaner according to an embodiment of the present invention.
4 is an exploded perspective view showing a suction unit of a vacuum cleaner according to an embodiment of the present invention.
Fig. 5 is an enlarged perspective view of the impeller included in the suction unit of Fig.
6 is a perspective view illustrating an impeller of a vacuum cleaner according to an embodiment of the present invention.
7 is a perspective view illustrating an impeller of a vacuum cleaner according to another embodiment of the present invention.
8 is a perspective view illustrating a process of molding an impeller of a vacuum cleaner according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms "front", "rear", "upper", "lower", "upper" and "lower" used in the following description are defined with reference to the drawings. The position is not limited.

The impeller 210 according to the present invention includes a canister type in which a main body and a suction nozzle are separated from each other and connected to a predetermined pipe, an up-right type in which a main body and a suction nozzle are provided as one, The present invention is applicable to various types of vacuum cleaners. Hereinafter, a handy vacuum cleaner will be described as an embodiment.

FIG. 1 is a view illustrating a state where a vacuum cleaner according to an embodiment of the present invention is coupled to a stick body. FIG. 2 is a view illustrating a state in which a vacuum cleaner according to an embodiment of the present invention is separated from a stick body. to be. 3 is a cross-sectional view illustrating a vacuum cleaner according to an embodiment of the present invention.

1 to 3, the vacuum cleaner 1 may include a main body 52, a suction unit 200, and a dust collecting apparatus 100.

The main body 52 may be provided with a grill-shaped first exhaust part 56, a handle 62, and a power button 65, which are provided with a plurality of exhaust holes. A suction unit 200 for generating a suction force and a battery (not shown) may be mounted on the upper side of the main body 52. A second exhaust part 58 in the form of a grill in which a plurality of exhaust holes are formed at a position opposite to the first exhaust part 56 may be formed on the back surface of the main body 52. [ A second connection terminal 60 may be provided on the upper portion of the second exhaust portion 58 on the rear surface of the main body 52. At the lower end of the main body 52, a roller 114 may be rotatably installed. A cyclone mounting space (not shown) through which the cyclone type dust collecting apparatus 100 is mounted may be formed in the lower portion of the main body 52.

The dust collecting apparatus 100 is not limited to the cyclone type, but it is assumed that the vacuum cleaner 1 includes a cyclone type dust collecting apparatus 100 for convenience of explanation.

The body 52 may include an inlet 63, a roller 114, an inlet gasket (not shown), an outlet gasket (not shown), and a rib 69. The suction port 63 can be tightly coupled to the opening 4 of the stick body 14 and the cyclone inlet 110. The inlet gasket may be installed on the circumferential surface of the suction port 63 so as to prevent air from leaking at the joint portion between the suction port 63 and the cyclone inlet 110. The outlet gasket can be installed around the inlet 251 of the suction unit 200 formed on the upper portion of the cyclone mounting space to increase the adhesion force so as to prevent air from leaking from the coupling portion between the filter unit 70 and the main body 52 .

The roller 114 may be installed at a lower portion of the suction port 63. When the vacuum cleaner 1 is detached from the stick main body 14, the roller 114 rotates in contact with the surface to be cleaned, thereby facilitating the back and forth movement of the vacuum cleaner 1, Can be reduced.

The rib 69 protrudes from the suction port 63 and is inserted into the opening 4 of the stick body 14 when the vacuum cleaner 1 is mounted in the mounting space 3 and is inserted into the suction port 63 and the opening 4, Thereby preventing air from leaking. In addition, when the vacuum cleaner 1 is tilted to bring the suction port 63 into contact with the bottom surface, the space between the bottom surface and the suction port 63 is reduced so that the suction force of the suction unit 200 can be sufficiently transmitted to the bottom So that the dust suction performance of the surface to be cleaned can be improved.

The dust collecting apparatus 100 may include a dust container 102, a cover member 104, a filter unit 70, and a cyclone container 107. The dust container 102 is made of a transparent material, and the filter unit 70 can be detachably mounted on one side.

The cover member 104 is made of a transparent material and can be integrally formed with the dust container 102. The cover member 104 may form the appearance of the vacuum cleaner 1 when mounted on the cyclone mounting space (not shown) of the vacuum cleaner 1.

The cyclone container 107 is installed inside the dust container 102 to partition the inner space of the dust container 102 into the centrifugal chamber S1 and the dust receiving chamber S2. A central pipe 108 is provided at the center of the cyclone cylinder 107 and a spiral flow guide for guiding the rotation of the air introduced through the cyclone inlet 110 is provided between the cyclone cylinder 107 and the central pipe 108. [ A member 106 may be provided.

The vacuum cleaner 1 may be detachably coupled to the stick body 14.

The stick main body 14 can be divided into a grip portion 16 at an upper portion and a center portion 11 having a tab shape having a mounting space 3 at a lower portion thereof. The grip portion 16 is a portion that is engaged with the upper end of the central portion 11 and is a portion gripped by the user to push or pull the nozzle assembly 2. The mounting space 3 formed in the central portion 11 is a space in which the vacuum cleaner 1 can be attached to or detached from the stick main body 14.

In FIG. 1, the side of the stick body 14 facing the stick body 14 is the front side of the stick body 14, and the side facing toward the B side is the back side of the stick body 14. A body exhaust unit 20 including a plurality of exhaust holes may be formed in the front surface of the stick body 14 and a body transparent unit 18 formed of a transparent panel may be formed under the body exhaust unit 20. [

The nozzle assembly 2 is rotatably connected to the lower end of the stick main body 14 and is rotatably connected to the neck 6 of the nozzle assembly 2 and the opening 4 of the stick main body 14 Can be communicated. External air and dust or the like introduced through the nozzle assembly 2 can be introduced into the vacuum cleaner 1 through the neck portion 6 and the opening 4 of the stick body 14. [ The nozzle assembly 2 has a bottom suction port 2a for sucking air on the surface to be cleaned, and a cylindrical brush (not shown) for scraping dust on the surface to be cleaned can be rotatably installed inside.

The first connection terminal 12 may be provided in the mounting space 3 of the stick main body 14 and the second connection terminal 60 may be provided on the back surface of the vacuum cleaner 1. [ The first connecting terminal 12 and the second connecting terminal 60 are brought into contact with each other when the vacuum cleaner 1 is mounted in the mounting space 3. This causes the stick main body 14 and the vacuum cleaner 1 to contact each other And can be electrically connected.

Details of the suction unit 200 will be described later.

Hereinafter, the operation of the vacuum cleaner 1 will be described.

The power supply button 65 provided on the main body 52 can be used to turn on / off the power of the suction unit 200 installed in the main body 52. [ The suction port 63 and the roller 114 of the vacuum cleaner 1 are brought into contact with the surface to be cleaned and the outside air and dust can be sucked while the vacuum cleaner 1 is moved. When the vacuum cleaner 1 is operated, external air can be introduced into the dust collecting apparatus 100 through the suction port 63 and the cyclone inlet 110. Since the cyclone inlet 110 is located at the bottom, air passing through the inlet 63 can be directly introduced into the cyclone inlet 110 in contact with the cyclone inlet 110. The dust contained in the air is separated from the air by the centrifugal force and is separated from the air by the centrifugal force, Can be stored in the dust container 102. The dust-separated air passes straight through the filter unit 70 mounted on the upper portion of the cyclone container 107 without any change in the traveling direction. At this time, the fine dust remaining in the air is removed by the grill portion 71 and the filter member (not shown), and the first exhaust portion 56 of the vacuum cleaner 1 and the second exhaust portion 56 of the vacuum cleaner 1 And can be discharged to the exhaust part 58.

When the vacuum cleaner 1 is mounted on the stick main body 14 (hereinafter referred to as a "stick type vacuum cleaner"), the user presses a power switch (not shown) provided on the stick main body 14, The stick body 14 can be tilted with respect to the nozzle assembly 2 by grasping the grip portion 16 of the stick body 14 by hand. The user can properly clean the stick type body 14 while tilting the stick type body 14 in accordance with his or her body conditions while moving the stick type type cleaner back and forth. External air including dust can be introduced into the dust collecting apparatus 100 through the nozzle assembly 2, the neck portion 6 and the opening 4 of the stick body 14. The external air introduced into the dust collecting apparatus 100 is rotated in the centrifugal separation chamber S1, and the dust contained in the external air can be separated and stored in the dust container 102 by the centrifugal force. The dust-separated air passes through the filter unit 70 and fine dust is removed by the grill part 71 and the filter member (not shown), and the air is sucked through the suction unit 200 to the first ship of the vacuum cleaner 1 And may be discharged to the base 56 and the second exhaust 58. The air discharged to the second exhaust part 58 can be discharged to the front part of the stick body 14 through the body exhaust part 20. [

FIG. 4 is an exploded perspective view illustrating a suction unit of a vacuum cleaner according to an embodiment of the present invention, and FIG. 5 is an enlarged perspective view of an impeller included in the suction unit of FIG.

4 and 5, the suction unit 200 includes an impeller 210, a return channel 220 provided below the impeller 210, a motor 230, a motor 230, and an impeller 210 A fan cover 250 covering the impeller 210 and the return channel 220 and a motor bracket 260 to which the motor 230 is mounted.

The motor 230 may include a stator (not shown) mounted to the motor bracket 260 and a rotor 232 disposed to be surrounded by a stator (not shown).

The rotary shaft 240 is inserted into the rotor 232 and can rotate according to the rotation of the rotor 232. [

The rotating shaft 240 is disposed to pass through the return channel 220, and the upper end of the rotating shaft 240 can be coupled to the impeller 210. Accordingly, when the rotor 232 rotates, the rotating shaft 240 and the impeller 210 can be rotated.

An air intake port 251 through which air is sucked may be provided at an upper portion of the fan cover 250. The fan cover 250 may wrap around the impeller 210 and the return channel 220.

The motor bracket 260 may be coupled to the lower portion of the fan cover 250. Specifically, a step 252 is formed on the lower edge of the fan cover 250, and an upper edge of the motor bracket 260 can be coupled to the step 252.

The lower edge of the fan cover 250 may be arranged to surround the upper edge of the motor bracket 260.

The impeller 210 may include a body 211 and a plurality of blades 213 provided on the body 211.

A hub 212 may be formed at the center of the body 211. The degree of protrusion of the upwardly facing body 211 can be gradually reduced toward the radial direction of the body 211 from the center of the body 211. [ That is, the height of the hub 212 is the highest, and the height of the body 211 decreases as the distance from the hub 212 increases. This is to prevent the air introduced through the inlet 251 from breaking in a horizontal direction in a vertical direction, thereby reducing the flow loss.

The plurality of blades 213 may be arranged on the body 211 in the up-and-down direction. That is, the plurality of blades 213 can be disposed on the body 211 so as to extend in the radial direction of the body 211 from the outer surface of the hub 212.

The plurality of blades 213 may be disposed on the body 211 so as to be inclined.

The plurality of blades 213 may be disposed on the body 211 in a twisted state.

The plurality of blades 213 may be disposed on the body 211 so as to be spaced apart from each other.

The inlet 219a of the impeller 210 is provided at the upstream side in the direction A in which the air introduced through the inlet 251 passes through the impeller 210 and the outlet 219b of the impeller 210 is provided at the downstream side .

The plurality of blades 213 may be spaced apart from each other to form a flow path 219. The inlet 219a of the impeller 210 may be provided at the starting point of the flow path 219 and the outlet 219b of the impeller 210 may be provided at the end point of the flow path 219. [

The flow path 219 becomes minimum at the inlet 219a of the impeller 210 and can be maximized at the outlet 219b of the impeller 210. [ That is, the flow path 219 can be wider as it goes toward the radial direction of the body 211.

As the flow path 219 is narrowed, the air velocity of the flowing air increases, and as the flow path 219 is wider, the amount of air flowing can be increased. Accordingly, at the inlet 219a of the impeller 210, the air introduced through the inlet 251 is rapidly moved, and at the outlet 219b of the impeller 210, a large amount of air flows downwardly, that is, 220).

The inlet 219a of the impeller 210 may be positioned further downstream in the direction A in which the air introduced through the inlet 251 than the upper end 211a of the body 211 passes through the impeller 210 . That is, the upper end 211a of the body 211 may be formed higher than the inlet 219a of the impeller 210. The upper end 211a of the body 211 may be used in the same sense as the upper end of the hub 212. [ In addition, the upper end 211a of the body 211 may be formed with an inclined surface. This is to guide the air that has passed through the intake port 251 to flow into the inlet 219a of the impeller 210 while drawing a curve.

The plurality of blades 213 may include a coupling portion 213a that is fixed on the body 211. [ The engaging portion 213a may be fixed on the body 211 in a vertically long direction.

The plurality of blades 213 may further include a leading edge 214 connected to an upper end of the coupling portion 213a and an ending edge 218 connected to a lower end of the coupling portion 213a.

A leading edge 214 may form an inlet 219a of the impeller 210.

In addition, the leading edge 214 may be adjacent to the upper end 211a of the body 211, i.e., the hub 212. [

In addition, the leading edge 214 may extend from the hub 212 toward the outward direction of the hub 212.

An ending edge 218 may form the outlet 219b of the impeller 210. [

The ending edge 218 may be located at the edge of the body 211.

The leading edge 214 may include a fixing portion 214a and a corner portion 214b.

The fixing portion 214a is formed at one end of the leading edge 214 adjacent to the hub 212 and the corner portion 214b is formed at the other end of the leading edge 214 facing the outward direction of the hub 212 .

The fixing portion 214a is connected to the upper end of the engaging portion 213a and the corner portion 214b may be spaced apart from the fixing portion 214a so as to face the outer direction of the hub 212. [

That is, the leading edge 214 has a fixing portion 214a fixed to the body 211 so as to be adjacent to the hub 212, and a corner formed at one end of the leading edge 214 so as to face the outer direction of the hub 212 And a part 214b.

The plurality of blades 213 may further include a side surface portion 217.

The side surface portion 217 can connect the corner portion 214b of the leading edge 214 and the outer end portion 218a of the ending edge 218 corresponding to the corner portion 214b.

At least a portion of the leading edge 214 may comprise a curve.

A detailed description of the shape of the leading edge 214 will be described later.

The return channel 220 may act as a diffuser and guide the air discharged after being sucked by the impeller 210 downward.

The return channel 220 may include a body portion 221 and a plurality of vanes 222 disposed on the sides of the body portion 221.

The air discharged from the impeller 210 can be guided downward by the plurality of vanes 222.

The fan cover 250 may be coupled to the upper portion of the return channel 220. The motor bracket 260 may wrap around the bottom and sides of the return channel 220. The return channel 220 can be coupled or fixed to the motor bracket 260 to maintain the fixed state of the return channel 220 since the impeller 210 rotates and the return channel 220 is fixed.

A first receiving groove 223 in which the lower portion of the impeller 210 is received may be provided on the upper surface of the return channel 220. The first receiving groove 223 may be provided with a second receiving groove (not shown) in which a supporting member 224 for rotatably supporting the impeller 210 is received.

The upper and lower edges of the return channel 220 are subjected to a curved surface treatment to prevent a sudden change in the air flow direction.

FIG. 6 is a perspective view illustrating an impeller of a vacuum cleaner according to an embodiment of the present invention, and FIG. 7 is a perspective view illustrating an impeller of a vacuum cleaner according to another embodiment of the present invention.

As shown in Figures 6 and 7, at least a portion of the leading edge 214 may comprise a curve. That is, all or a part of the leading edge 214 may be a curved line.

The leading edge 214 may include a convex curve toward the rotational direction Q of the impeller 210. [

In addition, the leading edge 214 may include a convex circular arc shape toward the rotational direction Q of the impeller 210.

The leading edge 214 may include a first region 215 coupled to the securement portion 214a and a second region 216 coupled to the edge portion 214b. That is, the second region 216 may be located outside the hub 212 relative to the first region 215.

The first region 215 may include at least one of a straight line and a curved line.

The second region 216 may comprise a curve.

The second region 216 may include a curve to prevent undercuts from occurring in the leading edge 214 during the injection process of the impeller 210. In particular, since the undercut is likely to occur at the corner 214b of the leading edge 214, the second region 216 including the corner 214b may be curved.

The first region 215 and the second region 216 may include curves having different curvatures. That is, when the first area 215 and the second area 216 are all curved, the curvatures of the curves forming the first area 215 and the second area 216 may be different from each other.

However, the first region 215 and the second region 216 may include curves having the same curvature.

8 is a perspective view illustrating a process of molding an impeller of a vacuum cleaner according to an embodiment of the present invention.

As shown in Fig. 8, the impeller 210 can be manufactured by injection molding. When the impeller 210 is manufactured by injection molding, the body 211 of the impeller 210 and the plurality of blades 213 may be integrally formed.

The upper mold (not shown), the lower mold (not shown) and the plurality of slide cores 300 may be coupled to each other to form a molding space (not shown). The impeller 210 can be injected by injecting resin into the molding space.

The plurality of blades 213 formed on the body 211 may be formed by a plurality of slide cores 300. The plurality of slide cores 300 are combined with the upper and lower molds to form a molding space, and then rotate about the center of rotation C to be separated from the upper mold and the lower mold.

An undercut may be generated in the leading edge 214 in a process in which the plurality of slide cores 300 are rotated about the rotation center C and separated from the upper and lower molds. That is, at least a part of the leading edge 214 is formed so that the plurality of slide cores 300 are aligned with the rotation center C when the leading edge 214 connecting the fixing portion 214a and the corner portion 214b is formed by only a straight line. So that an undercut may occur in the second region 216 of the leading edge 214. [0031] As shown in FIG. Thus, when at least a portion of the leading edge 214 includes a curve, at least a portion of the leading edge 214 can be prevented from being located on the rotational orbits of the plurality of slide cores 300, It is possible to reduce the frequency of occurrence of undercuts in the substrate.

The foregoing has shown and described specific embodiments. However, it should be understood that the present invention is not limited to the above-described embodiment, and various changes and modifications may be made without departing from the technical idea of the present invention described in the following claims .

1: Vacuum cleaner 2: Nozzle assembly
3: mounting space 4: opening
6: neck part 11: center part
12: first connection terminal 14:
16: Handle portion 18: Body transparent portion
20: main body exhaust part 52: main body
56: first exhaust part 58: second exhaust part
60: second connection terminal 62: handle
63: Suction port 65: Power button
69: rib 70: filter unit
71: grill part 100: dust collecting device
102: dust box 104: cover member
106: Helical flow guide member 107: Cyclone tub
110: Cyclone inlet 114: Roller
200: suction unit 210: impeller
211: Body 211a:
212: hub 213: blade
214: leading edge 214a:
214b: corner portion 215: first region
216: second area 217: side surface
218: Ending edge 218a: Outer end
219a: entrance 219b: exit
220: return channel 221: body part
222: Vane 223: First receiving groove
224: support member 230: motor
232: Rotor 240:
250: fan cover 251: intake port
252: step 260: motor bracket
2a: bottom suction port 219:
S1: centrifugal chamber S2: dust receiving chamber
108: center pipe 213a:
300: slide core

Claims (9)

A vacuum cleaner comprising a suction unit provided inside a main body,
The suction unit includes:
motor;
An impeller connected to the motor by a rotary shaft and sucking air by rotation; And
And a diffuser for guiding air discharged from the impeller,
The impeller
A body having a hub formed in a central portion thereof; And
And a plurality of blades provided on the body and having a leading edge extending from the hub toward an outer direction of the hub,
Wherein at least a portion of the leading edge comprises a curve. The method according to claim 1,
Wherein the leading edge includes a convex curve toward the rotating direction of the impeller. The method according to claim 1,
Wherein the leading edge includes a convex circular arc shape toward the rotational direction of the impeller. The method according to claim 1,
Wherein the leading edge connects the fixing part fixed to the body so as to be adjacent to the hub and the corner part formed at one end of the leading edge toward the outside direction of the hub. 5. The method of claim 4,
The leading edge,
A first region connected to the fixing portion; And
And a second region connected to the corner portion,
Wherein the first area includes at least one of a straight line and a curved line, and the second area includes a curved line. 6. The method of claim 5,
Wherein the first region and the second region include curves having different curvatures. A vacuum cleaner comprising a suction unit provided inside a main body,
The suction unit includes:
motor;
An impeller connected to the motor by a rotary shaft and sucking air by rotation; And
And a diffuser for guiding air discharged from the impeller,
The impeller
A body having a hub formed in a central portion thereof; And
A plurality of blades provided on the body and having a leading edge adjacent to the hub,
Wherein all or a part of the leading edge is curved so as to prevent an undercut from being generated in the leading edge during an injection process of the impeller. 8. The method of claim 7,
Wherein the leading edge is convex curved toward the rotating direction of the impeller. 8. The method of claim 7,
Wherein the leading edge connects a fixing part fixed to the body so as to be adjacent to the hub and an edge part formed at one end of the leading edge so as to face the outer direction of the hub,
And a part of the leading edge including the corner portion is formed of a curved line.

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