KR101199739B1 - Airflow noise reduction structure of vacuum cleaner - Google Patents

Abstract

The present invention relates to a flow noise reduction structure of a vacuum cleaner. According to an embodiment of the present invention, there is provided a structure for reducing noise in a vacuum cleaner, the body including a suction motor; A motor housing accommodating the suction motor and having a discharge hole through which air passing through the suction motor is discharged; A motor chamber accommodating the motor housing and having a chamber discharge hole through which air discharged from the discharge hole is discharged; An exhaust passage through which air discharged from the motor chamber flows; And a flow guide part for guiding the flow of air discharged from the chamber discharge hole, wherein a flow direction of air discharged from the chamber discharge hole is formed in a direction opposite to the air flow passing through the exhaust flow path, and discharges the chamber. Air discharged from the ball is characterized in that the flow direction is changed by the flow guide portion flows to the exhaust flow path.

Vacuum cleaner, flow noise reduction structure

Description

Airflow noise reduction structure of vacuum cleaner

The present invention relates to a flow noise reduction structure of a vacuum cleaner.

In general, a vacuum cleaner is a device that sucks air containing a foreign material by using a suction force generated by a suction motor mounted inside the main body, and then filters the foreign material inside the main body.

Meanwhile, the air sucked into the vacuum cleaner body is separated from the dust separation unit by cyclone flow, and the separated foreign matter is moved to the dust container, and the air from which the dust is separated is passed through a predetermined exhaust flow path through the suction motor. It is common to discharge to the outside.

There was a problem that noise is generated due to the friction of the air in the process of the dust separated air is discharged to the outside through the exhaust passage.

It is an object of an embodiment of the present invention to provide a flow noise reduction structure of a vacuum cleaner which improves the structure of the exhaust passage of the vacuum cleaner and reduces the noise generated in the exhaust passage.

According to an aspect of the present invention, there is provided a flow noise reducing structure of a vacuum cleaner, including: a main body including a suction motor, an exhaust unit for discharging air backward, and a base forming a bottom surface; A motor housing accommodating the suction motor and having a discharge hole through which air passing through the suction motor is discharged; A motor chamber accommodating the motor housing and having a chamber discharge hole through which air discharged from the discharge hole is discharged; A front flow path in which air discharged from the motor chamber is introduced and positioned in front of the exhaust flow path; And an exhaust flow path formed by the air discharged from the motor chamber and formed between the motor chamber and the base, wherein the motor chamber guides the flow of air discharged from the chamber discharge hole and extends forward. A flow guide part is formed to form part of the front flow path, and air of the motor housing is discharged into the space between the motor housing and the motor chamber, and the air in the space is discharged forward from the chamber discharge hole toward the front flow path. The air discharged to the front flow passage is changed in the flow direction by the flow guide part and flows backward along the exhaust flow passage.

According to the embodiment of the present invention by the means as described above, the noise generated in the process of using the vacuum cleaner is reduced, there is an advantage that can reduce the discomfort that can be given to people around due to such noise.

In addition, there is an advantage that can reduce the noise that can be generated in the vacuum cleaner by a simple method of changing the flow path structure without adding a separate component or device.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. It is to be understood, however, that the spirit of the invention is not limited to the embodiments shown and that those skilled in the art, upon reading and understanding the spirit of the invention, may easily suggest other embodiments within the scope of the same concept.

1 is a perspective view of a vacuum cleaner according to a first embodiment of the present invention.

Referring to FIG. 1, the vacuum cleaner 1 according to the present embodiment includes a main body 10 forming an exterior of the vacuum cleaner 1, and a main body 10 coupled to the main body 10. The dust container 20 in which the dust separated from the sucked air is stored is included.

In detail, the main body 10 includes a base 11 forming a bottom surface of the vacuum cleaner 1, a body part 12 coupled to an upper side of the base 11, and a rotation with the body part 12. Cover 13 is coupled to the possible, the body handle 14 for the user to grip and the moving wheel 15 is provided on the main body 10 to facilitate the movement of the vacuum cleaner (1).

The base 11 may be provided with a support 62 (see FIG. 4) for supporting the motor chamber 60 to be described later. In addition, an insertion rib 111 (refer to FIG. 5) may be formed in the base 11 to be inserted into a lower extension portion 64b to be described later.

The main body 10 is formed with an air inlet 16 to which a suction nozzle (not shown) is connected. Although not shown in the figure, an extension tube and a connection hose are provided between the suction nozzle and the air inlet 16.

The air sucked from the suction nozzle passes through the extension pipe and the connection hose and flows into the main body 10 through the air inlet 16.

2 is a perspective view showing a motor chamber installed on the base of the vacuum cleaner according to the first embodiment of the present invention, Figure 3 is a bottom perspective view of the motor chamber according to the first embodiment of the present invention, Figure 4 5 is a longitudinal cross-sectional view of the vacuum cleaner according to the first embodiment of the present invention, and FIG. 5 is an enlarged cross-sectional view of the chamber discharge hole formed in the motor chamber according to the first embodiment of the present invention.

2 to 5, inside the main body 10, a flow path forming unit 17 for guiding air introduced through the air inlet unit 16 and the flow path forming unit 17. The dust separation unit 30 allows the dust in the guided air to be separated by the cyclone flow, and the foreign matter in the air is filtered before the air discharged from the dust separation unit 30 enters the suction motor 50. A filter unit 40 and a suction motor 50 are provided to provide suction force for suctioning air into the main body 10.

The suction motor 50 is provided with a motor housing 51 for receiving the suction motor 50.

The motor housing 51 surrounds the suction motor 50 and serves to reduce noise generated by the suction motor 50. The motor housing 51 has a discharge hole 511 through which the air passing through the suction motor 50 is discharged. In addition, the bottom of the motor housing 51 is formed with a hole 512 through which the lower end of the suction motor 50 can be exposed to the outside of the motor housing 51.

A fixing portion 52 for fixing the suction motor 50 protrudes from the lower end of the suction motor 50. The fixing part 52 may pass through the hole 512.

The motor cover 53 covering the suction motor 50 is provided at an upper portion of the suction motor 50. The motor cover 53 may be coupled to an upper end of the motor housing 51. In addition, an inflow hole 531 through which the air filtered by the filter unit 40 is introduced is formed in the motor cover 53.

The main body 10 is provided with a motor chamber 60 in which the motor housing 51 is accommodated. The motor chamber 60 includes a front part 60a facing the front of the vacuum cleaner 1 and a bottom part 60b forming a bottom surface of the motor chamber 60.

The motor housing 51 or the motor cover 53 may be coupled to the front part 60a.

The bottom portion 60b has a fixing hole 60c through which the fixing portion 52 can be inserted. The fixing hole 60c is formed in a shape corresponding to the outer circumferential surface of the fixing part 52, and serves to fix the position of the suction motor 50.

A front edge portion 60d is formed between the front portion 60a and the bottom portion 60b. For example, in the present embodiment, the front edge portion 60d is formed in a round shape, but the shape of the front edge portion 60d is not limited thereto.

In the motor chamber 60, a chamber discharge hole 61 may be formed to allow air passing through the suction motor 50 to be discharged from the motor chamber 60. The chamber discharge hole 61 may be formed in the front portion 60a or the front edge portion 60d. The flow direction of air discharged from the chamber discharge hole 61 is formed in a direction opposite to the air flow passing through the exhaust flow path 63.

The support part 62 may protrude from the base 11. The support portion 62 may be coupled to the bottom portion 60b. The motor chamber 60 is spaced apart from the base 11 by the support 62. In the space between the bottom portion 60b and the base 11, an exhaust flow path 63 through which air discharged from the chamber discharge hole 61 flows is formed.

In the rear portion of the exhaust passage 63, an exhaust portion 69 is formed so that air passing through the exhaust passage 63 is discharged toward the exhaust filter 80. The exhaust part 69 may be disposed at a position higher than the exhaust flow path 63, and at least a portion of the motor chamber 60 may be opened.

Therefore, the air passing through the exhaust passage 63 may be discharged through the exhaust unit 69 after moving upward. The air discharged from the exhaust unit 69 may move backward to pass through the exhaust filter 80.

The motor chamber 60 is provided with a flow guide 64 for guiding the flow of air discharged from the chamber discharge hole 61. The flow guide portion 64 may be formed to extend forward from the front surface portion (60a).

The flow guide portion 64 is provided with an inclined portion 64a for guiding the air discharged from the chamber discharge hole 61 and a downward extension portion 64b that can be coupled to the base 11. . The flow guide part 64 may be arranged to connect between the motor chamber 60 and the base 11.

The inclined portion 64a extends inclined forward from the motor chamber 60. The downward extension portion 64b extends downward from the inclined portion 64a and is coupled to the base 11.

By such a configuration, the inclined portion 64a allows the air discharged from the chamber discharge hole 61 to allow the air discharged from the chamber discharge hole 61 to flow through the exhaust flow passage 63. Guide downwards.

The lower extension portion 64b may be formed by bending at a predetermined angle from the inclined portion 64a. The lower extension 64b may be recessed and formed to allow the insertion rib 111 to be inserted therein. However, the coupling method of the lower extension 64b and the base 11 is not limited thereto. The downward extension portion 64b is tightly coupled to the base 11 without a gap, thereby preventing air from leaking from the noise flow guide portion 64 into the space outside the exhaust passage 63.

The front flow path 66 is formed in front of the motor chamber 60. The front flow path 66 may be defined as a space surrounded by the flow guide portion 64, the motor chamber 60, and the base 11. The front flow passage 66 is located in front of the exhaust flow passage 63.

The front flow path 66 is formed in the opposite direction of the exhaust part 69 with respect to the chamber discharge hole 61. That is, based on FIG. 4, the front flow path 66 is formed at the left side of the chamber discharge hole 61, and the exhaust part 69 is formed at the right side of the chamber discharge hole 61.

The air discharged to the front flow path 66 is switched by the flow path guide part 64. The air flowing along the front flow passage 66 moves backward and passes the exhaust flow passage 63. In addition, the air passing through the exhaust flow path 63 flows into the exhaust filter 80 through the exhaust part 69, and foreign substances are filtered and discharged to the outside of the cleaner.

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

When the vacuum cleaner 1 is operated, air is sucked through the air inlet 16 by the suction force generated by the suction motor 50.

The air sucked through the air inlet 16 is introduced into the dust separation unit 30 through the flow path forming unit 17. In the dust separation unit 30, dust is separated from air by a cyclone phenomenon.

The dust separated from the dust separation unit 30 is accumulated in the dust container 20, and the dust separated air is filtered again through the filter unit 40.

Air passing through the filter unit 40 is introduced into the suction motor 50 through the inlet hole 531. In addition, the air introduced by the suction motor 50 is discharged to the outside of the motor housing 51 through the discharge hole 511. That is, the air is discharged into the space between the motor housing 51 and the motor chamber 60.

The air discharged to the outside of the motor housing 51 (the space between the motor housing 51 and the motor chamber 60) is external to the motor chamber 60 through the chamber discharge hole 61. Is discharged to the front flow passage 66. For example, air is discharged to the charge chamber through the chamber discharge hole 61 with reference to FIG. 4.

Air flows through the front flow passage 66 and is guided by the inclined portion 64a. The inclined portion 64a extends to form an inclined angle with respect to the base 11, and the inclined portion 64a is spaced apart from the chamber discharge hole 61 by a predetermined interval. Therefore, the air discharged through the chamber discharge hole 61 may maintain the direction when discharged from the chamber discharge hole 61.

The front passage 66 prevents the passage of the air discharged from the chamber discharge hole 61 from sharply bending. In addition, the air flow rate is reduced in the process of flowing the front flow path (66).

The air guided by the inclined portion 64a flows to the bottom surface of the front flow path 66. Air flowing to the bottom surface of the front flow passage 66 is switched to the exhaust flow passage 63 side and flows to the exhaust flow passage 63 side.

According to the proposed embodiment, since the direction of the air discharged from the motor chamber 60 is not rapidly changed toward the exhaust flow path, the noise is reduced.

In addition, the velocity of the air discharged from the motor chamber 60 by the front flow path 66 is reduced, thereby reducing the friction noise of the air in the exhaust flow path.

Hereinafter, a second embodiment of the present invention will be described.

6 is a bottom perspective view of the motor chamber according to the second embodiment.

This embodiment is the same as in the first embodiment in other parts, except that there is a difference in the formation position of the chamber discharge hole and the flow of air flowing into the exhaust flow path. Therefore, hereinafter, only characteristic parts of the present embodiment will be described, and the same contents as the first embodiment will be used herein.

Referring to FIG. 6, the motor chamber 90 of the vacuum cleaner 1 according to the present embodiment has first and second chamber discharge holes 91a and 91b through which air sucked from the suction motor 50 is discharged. Is formed. The first and second chamber discharge holes 91a and 91b may be formed in the bottom surface 92 of the motor chamber 90 or the side end 93 of the bottom surface 92.

Although the first and second chamber discharge holes 91a and 91b are formed in the side end portion 93 of the bottom portion 92 in the present embodiment, the chamber discharge hole is one side of the motor chamber 90. And it may be formed in plurality on the other side.

The first and second chamber discharge holes 91a and 91b may be formed at positions symmetric with each other. FIG. 6 shows that the first and second chamber outlet holes 91a and 91b are formed at positions symmetric with respect to an imaginary line passing through the center of the bottom portion 92 of the motor chamber 90. The air introduced by the suction motor 50 is discharged to the outside of the motor housing 51 through the discharge hole. That is, the air is discharged into the space between the motor housing 51 and the motor chamber 90. The air discharged into the space between the motor housing 51 and the motor chamber 90 is discharged to the outside of the motor chamber 90 through the chamber discharge holes 91a and 91b.

The air discharged through the first and second chamber discharge holes 91a and 91b is guided by the first and second flow guide ribs 94a and 94b. The first and second flow guide ribs 94a and 94b protrude from the bottom surface 92. The guide ribs 94a and 94b are formed between the chamber discharge holes 91a and 91b.
The air discharged by the first chamber discharge hole 91a flows forward through the first guide flow path 95a by the first flow guide rib 94a and into the second chamber discharge hole 91b. The discharged air flows forward through the second guide flow path 95b by the second flow guide rib 94b.

In the present embodiment, the first and second chamber discharge holes 91a and 91b have been described as an example, but a plurality of chamber discharge holes may be formed. In addition, in the present embodiment, the first and second flow guide ribs 94a and 94b have been described as an example, but a plurality of flow guide ribs may be formed, and a plurality of air flows passing through the plurality of flow guide ribs. Is laminated in the exhaust flow path 98.

Air flowing through the first and second guide flow paths 95a and 95b flows toward the flow guide portion 96 of the motor chamber 90. The air is changed in flow direction at the edge portion 96a of the motor chamber 90 and merged in the front flow path 97.

The plurality of air flows passing through the plurality of flow guide ribs are laminated in the exhaust flow path 98 and discharged to the outside through the exhaust part 99 formed at the rear of the main body 12. That is, the air discharged through the first and second chamber discharge holes 91a and 91b is guided along the first surfaces (outer surfaces) of the first and second flow guide ribs 94a and 94b. The air combined in the front flow path 97 is guided along the second surfaces (outer surfaces) of the first and second flow guide ribs 94a and 94b.

According to the proposed embodiment, the noise in the exhaust passage is reduced even when the space between the motor chamber and the base is narrow.

In addition, the air discharged from the chamber discharge hole flows to the front flow passage through the first and second guide flow passage before the flow to the exhaust flow passage to reduce the flow rate of air, thereby reducing the friction noise of the air have.

1 is a perspective view of a vacuum cleaner according to a first embodiment of the present invention.

Figure 2 is a perspective view showing a state in which the motor chamber is installed on the base of the vacuum cleaner according to the first embodiment of the present invention.

3 is a bottom perspective view of the motor chamber according to the first embodiment of the present invention.

4 is a longitudinal sectional view of the vacuum cleaner according to the first embodiment of the present invention.

5 is an enlarged cross-sectional view of the chamber discharge hole formed in the motor chamber according to the first embodiment of the present invention.

6 is a bottom perspective view of the motor chamber according to the second embodiment;

Claims (9)

A main body including a suction motor, an exhaust unit through which air is discharged backwards, and a base defining a bottom surface thereof; A motor housing accommodating the suction motor and having a discharge hole through which air passing through the suction motor is discharged; A motor chamber accommodating the motor housing and having a chamber discharge hole through which air discharged from the discharge hole is discharged; A front flow path in which air discharged from the motor chamber is introduced and positioned in front of the exhaust flow path; And Air discharged from the motor chamber is flown, and includes an exhaust flow path formed between the motor chamber and the base, The motor chamber guides the flow of air discharged from the chamber discharge hole, and includes a flow guide part extending forward to form a part of the front flow path. The air of the motor housing is discharged to the space between the motor housing and the motor chamber, the air of the space is discharged forward toward the front flow path from the chamber discharge hole, the air discharged to the front flow path is the flow guide Flow direction reduction structure of the vacuum cleaner, characterized in that the flow direction is changed by the portion flows backward along the exhaust passage. The method of claim 1, The base is a noise reduction structure of the vacuum cleaner to form a portion of the front flow path. delete The method of claim 1, The flow guide portion, An inclined portion extending inclined toward the front; And It includes a downward extension extending downward from the inclined portion, The downward extension is a noise reduction structure of the vacuum cleaner coupled to the base. delete delete A main body including a suction motor, an exhaust unit through which air is discharged backwards, and a base defining a bottom surface thereof; A motor housing accommodating the suction motor and having a discharge hole through which air passing through the suction motor is discharged; And A motor chamber accommodating the motor housing and having a plurality of chamber discharge holes through which air discharged from the discharge hole is discharged; A plurality of guide ribs are formed between the plurality of chamber discharge holes of the motor chamber to guide the air discharged from the plurality of chamber discharge holes to the front, Air of the motor housing is discharged into the space between the motor housing and the motor chamber, the air of the space is discharged through the plurality of discharge holes, Air discharged through the plurality of discharge holes flows forward along the first surface of each of the plurality of guide ribs, The air discharged from the plurality of chamber discharge holes and flowed forward flows backward along the exhaust flow path formed between the plurality of guide ribs after being combined in the front flow passage, And the air combined in the front flow passage flows backward along the second surface of each of the plurality of guide ribs. delete delete

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