KR102095693B1 - Dust collector for vacuum cleaner - Google Patents

Abstract

The present invention discloses a fluid suction device for a cleaner. The disclosed fluid intake device for a vacuum cleaner includes a motor case including a fluid guide portion whose size gradually decreases to guide the discharge of air sucked by the impeller unit, and a motor case for transporting air sucked from the outside by the impeller unit. The impeller housing is coupled to the motor case to form a motor suction fluid transfer path in a pair, and the impeller housing is disposed inside to form an auxiliary transfer flow path in pair with the impeller housing, and the impeller is discharged from the motor case and the impeller housing It is characterized by having a convection induction duct through which the air around the impeller housing is introduced and transferred by the change in air pressure. Therefore, the present invention can increase the suction and discharge of air by generating the Coanda effect and Bernoulli effect while discharging the air sucked by the impeller through the motor suction fluid transfer channel.

Description

Cleaner fluid suction device {DUST COLLECTOR FOR VACUUM CLEANER}

The present invention relates to a fluid suction device for a cleaner, and more specifically, it is possible to increase the discharge amount of air by generating a Coanda and Bernoulli effect while transferring air sucked by an impeller through a plurality of fluid transfer channels. , It relates to a fluid suction device for a cleaner to improve the cooling effect of the impeller unit.

In general, a vacuum cleaner is a device that performs cleaning by suctioning foreign matter on a cleaning surface with suction power generated by driving a fan, and a vacuum cleaner body generating suction power and a suction nozzle extending from the vacuum cleaner body to suck foreign matter on the cleaning surface And, it includes a connector for connecting the suction nozzle and the cleaner body.

The vacuum cleaner is made of various types of suction nozzles to increase the efficiency of cleaning according to the place or location to be cleaned.

In recent years, the use of a robot cleaner that automatically cleans dust and the like accumulated on the floor while driving the cleaning area without user intervention is gradually increasing.

The robot cleaner detects the cleaning area and obstacles using the sensor at the command of the control means, runs the cleaning area and cleans automatically, and when the battery power inside the device runs out, It is a device that moves to a charging station provided separately in a predetermined position to charge it, and after charging, returns to the original position where it was cleaned again and performs cleaning.

In addition, the robot cleaner is equipped with a suction device for suctioning foreign objects and a dust collecting device for collecting the sucked foreign matter, and the impeller of the suction device rotates to transport air. And the impeller is rotated by a motor.

However, the conventional suction device as described above, there is a problem in that the discharge amount is significantly reduced due to the generation of vortices or reverse flow when the air by the impeller is sucked and discharged.

Therefore, there is a need to improve this.

On the other hand, Korean Patent Registration No. 10-0405980 (Registration Date: November 04, 2003) discloses a "flow system of a vacuum cleaner equipped with an ejector", and Korean Patent Registration No. 10-0444553 (Registration Date: 2004) On August 5, 2005, a "cyclone dust collector for a vacuum cleaner" is disclosed.

The present invention was created by the necessity as described above, while generating the Coanda and Bernoulli effects while transferring the air sucked by the impeller through a plurality of fluid transfer passages, it is possible to increase the discharge amount of air and cool the impeller unit. It is an object of the present invention to provide a fluid suction device for a cleaner that can improve the effect.

In order to achieve the above object, the fluid suction device for a vacuum cleaner according to an aspect of the present invention includes a motor case including a fluid guide part whose size gradually decreases to guide the discharge of air sucked by the impeller unit, and the An impeller housing coupled with the motor case to form a motor suction fluid transfer path in pair with the motor case for the transfer of air sucked from the outside by the impeller unit, and the air discharged from the motor case and the impeller housing And a convection induction duct covering the impeller housing so that air around the impeller housing is transferred by natural convection due to a pressure change.

In the present invention, the motor case is formed to protrude outwardly and is coupled to the impeller housing, and further comprises a case coupling part for introducing air into the motor intake fluid transfer passage inside for cooling the impeller unit. .

In the present invention, the motor case is characterized in that it further comprises a case outlet for discharging the air flowing in through the case coupling portion.

In the present invention, the impeller housing, the motor case is coupled, the fluid induction portion for guiding the air discharged from the motor suction fluid transfer channel to the outer surface of the fluid guide portion, a fluid intake port is formed to cover the impeller unit It characterized in that it comprises a fluid intake coupled to the fluid induction.

In the present invention, the fluid induction part, the motor case is coupled, the fluid induction rim member and a fluid induction rim member formed with a fluid induction bend to guide the air conveyed from the motor suction fluid transport passage toward the fluid guide part It is characterized in that it comprises a duct coupling rim member formed in a ring shape to be spaced apart and coupled to the convection induction duct.

In the present invention, the convection induction duct is characterized in that one side is opened to form a convection suction port, and a convection guide bend to guide air convected to the other side toward the fluid guide portion.

As described above, the fluid suction device for a vacuum cleaner according to an aspect of the present invention generates a Coanda effect and a Bernoulli effect while discharging air sucked by an impeller through a motor suction fluid transfer channel, unlike the conventional invention. It has the effect of increasing intake and discharge.

In addition, the fluid suction device for a cleaner according to the present invention has an effect of improving the cooling effect by passing the air sucked by the impeller to the core portion of the impeller unit.

1 is an exploded perspective view showing a fluid suction device for a cleaner according to an embodiment of the present invention.
2 is a perspective view showing a fluid suction device for a cleaner according to an embodiment of the present invention.
3 is a cross-sectional view taken along line AA in FIG. 2.
4 is an enlarged view of a main part showing a motor case and a fluid guide part according to an embodiment of the present invention.
5 is a front view of FIG. 4.
6 is a schematic view showing a fluid flow of a fluid suction device for a cleaner according to an embodiment of the present invention.
7 is a view showing a fluid transfer simulation of the fluid suction device for a cleaner according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the fluid suction device for a cleaner according to the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of components shown in the drawings may be exaggerated for clarity and convenience.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or practice. Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is an exploded perspective view showing a fluid suction device for a cleaner according to an embodiment of the present invention, FIG. 2 is a perspective view showing a fluid suction device for a cleaner according to an embodiment of the present invention, and FIG. 3 is FIG. 2 It is a cross section of AA line.

In addition, FIG. 4 is an enlarged view of a main portion showing a motor case and a fluid guide part according to an embodiment of the present invention, and FIG. 5 is a front view of FIG. 4.

In addition, FIG. 6 is a schematic view showing a fluid flow of a fluid intake device for a cleaner according to an embodiment of the present invention, and FIG. 7 is a fluid transport simulation of a fluid intake device for a cleaner according to an embodiment of the present invention.

1 to 7, the fluid suction device 100 for a vacuum cleaner according to an embodiment of the present invention is installed in a cleaner body to communicate with a suction nozzle (not shown) of a vacuum cleaner, and sucks foreign matter. In order to inhale the outside air.

To this end, the fluid suction device 100 for a vacuum cleaner according to the present embodiment comprises a motor case 120 to which the impeller unit 110 is coupled, and a motor case 120 to form a motor suction fluid transfer channel 101 The impeller housing 130 is formed, and the convection induction duct 140 is formed in pair with the impeller housing 130 to form the auxiliary transport flow path 103. In addition, the fluid suction device 100 for the cleaner further includes a motor fixture 150 provided between the motor case 120 and the impeller housing 130 to stably fix the impeller unit 110.

The fluid suction device 100 for a cleaner according to the present embodiment generates a Coanda effect on the outer surface of the motor case 120 by the motor case 120 and the impeller housing 130, and the convection induction duct 140 This causes the Bernoulli effect. Through this, the Coanda effect and the Bernoulli effect are simultaneously generated in the fluid discharged between the motor case 120 and the convection induction duct 140, and thus the fluid transfer amount of the fluid suction device 100 for a cleaner is generated. Can be increased.

The motor case 120 is coupled to the impeller housing 130 and is disposed in the central portion of the convection induction duct 140, and an impeller unit for forcibly sucking air outside the impeller housing 130 into the motor suction fluid transfer channel 101 110 is combined.

The motor case 120 is formed by bending the fluid guide unit 121 to guide the flow of air sucked by the impeller unit 110 and discharged through the motor suction fluid transport passage 101. The diameter of the fluid guide portion 121 is gradually reduced, and a cylindrical case outlet 123 is formed at the inner end.

In addition, the motor case 120 is coupled to be spaced apart from the inner surface of the impeller housing 130, the case coupling portion 125 is formed to protrude outward to form the motor suction fluid transfer passage 101. The motor case 120 according to the present invention may be formed in a cylindrical shape.

Case coupling portion 125 is supported on both sides and the outer surface is coupled to the impeller housing 130, the air flowing along the motor suction fluid transfer passage 101 flows into the interior of the motor case 120, the impeller unit 110 ) To improve the cooling effect.

This, the case coupling portion 125 is formed to protrude inclined in the longitudinal direction of the motor case 120, the inclined support surface (125a) is formed inclined on both sides is fixed to the impeller housing 130 stably in contact.

Meanwhile, the case outlet 123 discharges air flowing into the motor case 120 through the case coupling portion 125 to the outside of the motor case 120. Since the air discharged through the case outlet 123 joins the flow of air discharged from the motor suction fluid transfer passage 101 and the auxiliary transfer passage 103, the air discharged from the cleaner fluid suction device 100 It can increase flow rates and emissions.

The impeller housing 130 is coupled to the motor case 120 and the motor fixture 150, and is paired with the motor case 120 to transport air sucked from the outside by the impeller unit 110 to transport the motor suction fluid The flow path 101 is formed.

The impeller housing 130 includes a fluid induction unit 131 to which the case coupling unit 125 of the motor case 120 is coupled, and a fluid induction unit 131 through the motor fixture 150 to cover the impeller unit 110. It includes a fluid intake 133 is coupled.

The fluid induction part 131 is a motor case 120 is coupled to the inside, the outer surface is coupled to the inner surface of the convection induction duct 140, the motor suction the fluid flow discharged from the fluid transfer passage 101 motor case 120 ) Is guided to the outer surface of the fluid guide portion 121.

To this end, the fluid guide portion 131 is fixed to the case coupling portion 125, and the fluid induction rim member (131a) for guiding the flow of air conveyed from the motor suction fluid transfer path 101 toward the fluid guide portion 121 , A duct coupling rim member (131b) for fixing the impeller housing 130 to the convection induction duct (140).

The fluid induction rim member 131a is centered on a fluid induction bend 131a 'for guiding the flow of air conveyed from the motor suction fluid transport passage 101 to the outer surface of the fluid guide part 121 to improve the Coanda effect. It is formed to bend in the direction. In addition, the fluid induction rim member 131a is formed with a plurality of coupling grooves 131c in which the case coupling portion 125 is inserted and fixed along the circumferential direction.

The duct coupling rim member 131b is formed in a cylindrical shape, and is integrally coupled to the outer surface of the fluid induction rim member 131a through the separation rib 131b '.

The fluid intake 133 is formed with a fluid intake 133a and is coupled to the motor fixture 150 to cover the impeller unit 110 to form a motor suction fluid transfer passage 101. The fluid suction part 133 is gradually expanded toward the motor fixture 150 from the fluid suction port 133a.

The impeller unit 110 is seated inside the motor case 120, the motor member 111 fixed by the motor fixture 150, and the motor member 111 through a rotating shaft to be disposed inside the fluid intake 133a ) It is provided with an impeller member 113 rotatably coupled to.

The motor fixture 150 is coupled between the fluid induction part 131 and the fluid intake part 133 to fix the motor member 111, and is applied to the fluid forcibly sucked into the fluid intake part 133 by the impeller member 113. Swirl flow is generated to increase the flow rate of the fluid. To this end, a swirl flow blade 151 is protruded from one side of the motor fixture 150 on the outer surface.

The convection induction duct 140 is paired with the impeller housing 130 so that the impeller housing 130 is disposed therein to form the auxiliary transport flow path 103. One side of the convection induction duct 140 is completely opened to form a convection inlet 141, and external air flows in due to a pressure difference caused by the fluid discharged from the motor suction fluid transfer passage 101. .

Convection induction duct 140 according to this embodiment may be connected to the dust collecting assembly of the cleaner.

In addition, the convection induction duct 140 is a convection guide bending portion 143 for guiding the air that is naturally convected along the auxiliary transfer passage 103 to the fluid guide portion 121 of the motor case 120 to be bent in the center direction Is formed.

At this time, since the flow velocity of the fluid discharged through the motor suction fluid transfer flow path 101 is discharged at a faster speed than the flow velocity of the fluid discharged from the auxiliary transfer flow path 103, the Bernoulli effect is generated to the auxiliary transfer flow path 103 The flow rate and flow rate of the fluid being transported can be further increased. Here, the width of the motor suction fluid transfer path 101 is formed smaller than the width of the auxiliary transfer flow path 103.

In addition, the convection induction duct 140 is formed with a cylindrical integrated discharge port 145 at the end of the convection guide bent portion 143. The integrated discharge port 145 discharges the fluid that is transferred through the case discharge port 123, the motor suction fluid transfer channel 101, and the auxiliary transfer channel 103 at the same time.

In the present embodiment, the fluid suction device 100 is described as an example applied to a cleaner, but it may also be used in a hair dryer, an air cleaner, and the like.

The operation of the fluid suction device for a cleaner according to an embodiment of the present invention configured as described above will be described.

When the impeller member 113 rotates as the motor member 111 operates, the external air of the fluid suction device 100 for the cleaner is forcibly sucked through the fluid suction port 133a of the fluid suction part 133. And the fluid forcibly sucked through the fluid intake 133a is transferred through the motor suction fluid transfer passage 101 and is discharged between the fluid guide part 121 and the fluid induction bend 131a ', and the fluid guide by the Coanda effect It is conveyed along the surface of the part 121.

In addition, some of the fluid sucked into the impeller housing 130 is transferred to the inside of the motor case 120 by the case coupling portion 125 and then cools the motor member 111 and is then discharged to the case outlet 123 .

In particular, a pressure difference occurs inside and outside the auxiliary transfer flow path 103 due to the flow velocity of the fluid transferred along the surface of the fluid guide portion 121 of the motor case 120. That is, the Bernoulli effect appears, and air outside the convection induction duct 140 is naturally convected to the inside of the convection induction duct 140 and is transported through the auxiliary transport flow path 103. Through this, the air discharge amount of the fluid suction device 100 for a cleaner is further increased.

The fluid suction device 100 for a vacuum cleaner according to the present invention has a pressure difference in the convection induction duct 140 as air forcibly sucked by the impeller member 113 is transferred and discharged through the motor suction fluid transport passage 101. Will occur. Due to this, the Coanda effect and the Bernoulli effect may be generated, thereby increasing air intake and discharge of the motor case 120 and the convection induction duct 140.

In addition, the fluid suction device 100 for a vacuum cleaner according to the present invention is guided to the inside of the motor case 120 through the case coupling portion 125 through the air sucked into the impeller housing 130 by the impeller member 113 , It is possible to improve the cooling effect of the motor member 111.

The present invention has been described with reference to the embodiment shown in the drawings, but this is merely exemplary, and those skilled in the art to which the art belongs can various modifications and equivalent other embodiments from this. Will understand.

Therefore, the true technical protection scope of the present invention should be defined by the claims.

100: cleaner fluid suction device 101: motor suction fluid transfer path
103: auxiliary transfer passage 110: impeller unit
111: motor member 113: impeller member
120: motor case 121: fluid guide portion
123: case outlet 125: case coupling
130: impeller housing 131: fluid induction
131a: fluid induction rim member 131b: duct coupling rim member
133: fluid suction unit 140: convection induction duct
141: convection inlet 143: convection guide bend
145: integrated outlet 150: motor fixture

Claims (6)

A motor case including a fluid guide portion whose size gradually decreases to guide the discharge of air sucked by the impeller unit;
An impeller housing coupled with the motor case to form a motor suction fluid transport path by pairing with the motor case for transport of air sucked from the outside by the impeller unit; And
The impeller housing is disposed inside the pair with the impeller housing to form an auxiliary transport flow path, and convection through which air around the impeller housing is introduced and transferred by the pressure change of air discharged from the motor case and the impeller housing Induction ducts;
A fluid suction device for a vacuum cleaner comprising a.
According to claim 1,
The motor case is formed to protrude outwardly and is coupled to the impeller housing, and further comprising: a case coupling part that introduces air into the motor suction fluid transfer passage for cooling of the impeller unit. Fluid suction device.
According to claim 2,
The motor case, a fluid intake device for a cleaner, characterized in that it further comprises; a case outlet for discharging the air flowing into the interior through the case coupling portion.
According to claim 1,
The impeller housing, the motor case is coupled, a fluid guide portion for guiding the air discharged from the motor suction fluid transfer passage to the outer surface of the fluid guide portion; And
A fluid suction part formed with a fluid suction port and coupled to the fluid guide part to cover the impeller unit;
A fluid suction device for a vacuum cleaner comprising a.
The method of claim 4,
The fluid induction part, the fluid induction rim member to which the motor case is coupled, a fluid induction bend is formed to guide the air conveyed from the motor suction fluid transport passage toward the fluid guide part; And
A duct coupling rim member formed in a ring shape to be spaced apart from the fluid induction rim member and coupled to the convection induction duct;
A fluid suction device for a vacuum cleaner comprising a.
According to claim 1,
The convection induction duct, a fluid suction device for a vacuum cleaner, characterized in that one side is open to form a convection suction port, and a convection guide bend for guiding air that is naturally convected to the other side toward the fluid guide portion.

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