KR20050112727A - A noise controller of motor for vacuum cleaner - Google Patents

Abstract

The present invention relates to a device capable of reducing noise of a motor for a vacuum cleaner. A resonance chamber in which an air flow passage corresponding to the inlet is formed in the center and a porous thin fibrous material or porous foam elastic material is inserted into the chamber formed outside of the air flow passage to reduce noise emitted from the air inlet; A suction pipe coupled to the upper side of the seal and having the same inner diameter as the air passage, and having a suction hole formed around the pipe shape of which the upper part is closed, and a pipe-shaped sound absorption pipe coupled to the outside of the suction pipe by a predetermined distance; One side of the internal exhaust hole coupled to the lower part of the resonance chamber to escape the noise from the exhaust port It consists of an inner case formed in, and a lower cover consisting of an outer case formed with an outer exhaust hole through which the noise from the inner exhaust hole escapes, and has excellent sound-absorbing effect as a thermoplastic resin sintered porous sound absorbing material as its material.

Description

Noise reduction device for a vacuum cleaner motor {A noise controller of motor for vacuum cleaner}

The present invention relates to a noise reduction device for a vacuum cleaner motor, and more particularly, to a noise reduction device composed of a thermoplastic resin-sintered porous sound-absorbing material and configured to reduce noise according to the type of noise coming from the motor. It is about.

In order to increase the suction power of the vacuum cleaner used to suck up dust or small garbage, the output of the motor is increasing. However, the noise reduction technology has not been developed significantly, and various noise reduction methods and devices have been developed. It is true, but it is not effective because it is not partial and comprehensive.

In general, the noise of the vacuum cleaner is mainly generated by the motor generating the vacuum, and the centrifugal impeller is rotated at a high speed (typically 30,000 rpm to 40,000 rpm), and the high air pressure flowing through the impeller at the inlet is exhausted. After cooling the motor along the exhaust will be exhausted. At this time, since the impeller makes a high-speed rotational movement, the front part of the impeller, that is, the inlet part, generates vibration and noise together, and noises having a frequency of 4 KHz to 12 KHz are generated, and the airflow noise generated by the suction discharge process goes well with the frequency of the wider band. It is not easy to control the noise of the motor.

As a conventional technology for reducing noise generated in a motor of such a vacuum cleaner, Korean Utility Model Registration No. 86216 uses a dustproof urethane, a noise barrier film (dustproof rubber), and a sound absorbing material (foamed polyurethane, nonwoven fabric, and blower) to reduce noise. In Korea Patent Registration No. 128625, sound is absorbed (foam urethane, non-woven fabric, fan) and the heat from the motor is cooled to slow the flow rate to control the noise.In Korean Patent Registration No. 136758, the noise is detected by the rotation speed of the impeller. There are various conventional techniques, such as sensing and counter-phase to create and offset, but these conventional techniques have a problem in that the noise generated from the motor is complicated but partial and partial noise reduction is not large.

In addition, the noise emitted by the HEPA filter and the non-woven fabric inside the vacuum cleaner is more than 70 ~ 80db and by applying and coating a deodorant or antibacterial agent, a lot of cigarette smell, pet smell, toilet smell, garbage smell, unpleasant smell Although attempting to remove the odor, there is a problem that can not effectively remove harmful odors, such as formaldehyde that occur a lot in the home.

The present invention for achieving the above object of the vacuum cleaner motor to improve the efficiency of noise reduction using a thermoplastic resin sintered porous sound-absorbing material and a structure that can reduce the noise generated in the vacuum cleaner motor To provide a noise reduction device.

In addition, the present invention provides a noise reduction device for a vacuum cleaner motor that does not need a separate deodorant by adding a deodorizing and antibacterial function to the thermoplastic resin sintered porous sound absorbing material itself.

The noise reduction device of the vacuum cleaner motor of the present invention for solving the above problems is coupled to the outside of the motor consisting of an inlet, an impeller, an exhaust port to reduce the noise, is coupled to the upper portion of the motor Reducing the noise from the inlet, the air passage corresponding to the inlet is formed in the center, the resonance chamber is inserted into the porous fine fiber material or porous foam elastic material inside the chamber formed outside the air passage, The technical feature is that it consists of a pipe-shaped sound absorbing tube having an inner diameter slightly larger than that of the air passage above the resonance chamber.

In addition, the noise reduction device of the vacuum cleaner motor of the present invention is coupled to the outside of the motor consisting of the suction port, the impeller, the exhaust port to reduce the noise, coupled to the upper portion of the motor to reduce the noise coming out of the suction port The air passage having the same inner diameter as the suction port is formed in the center portion, and the resonance chamber is filled with a porous thin fibrous material or a porous foam elastic material inside the chamber formed outside the air passage, and is coupled to an upper portion of the resonance chamber. It is characterized in that the technical configuration of the suction pipe having the same inner diameter as the air passage, the suction hole is formed around the closed pipe shape.

In addition, the noise reduction device of the vacuum cleaner motor of the present invention is coupled to the outside of the motor consisting of the suction port, the impeller, the exhaust port to reduce the noise, coupled to the upper portion of the motor to reduce the noise coming out of the suction port An air passage corresponding to the inlet is formed at a central portion thereof, and is coupled to a resonance chamber filled with a porous thin fibrous material or a porous foamed elastic material in an inside of a chamber formed outside the air passage, and coupled to an upper side of the resonance chamber. The technical features of the present invention include a suction pipe having a suction hole formed around a pipe shape having an upper diameter closed thereon, and a pipe-shaped sound absorption pipe coupled to the outside of the suction pipe by a predetermined distance.

In addition, the noise reduction device of the vacuum cleaner motor of the present invention is coupled to the outside of the motor consisting of a suction port, an impeller, an exhaust port to reduce the noise, the noise exit from the exhaust port of the lower motor, the exhaust port It consists of an inner case formed on one side of the internal exhaust hole through which the noise from the outside is discharged, and an outer case formed by an external exhaust hole through which the noise from the internal exhaust hole escapes. It is characterized by a technical feature that consists of a lower cover that is increasingly wider.

In addition, the material of the noise reduction device of the vacuum cleaner motor of the present invention is preferably made of a thermoplastic resin sintered porous sound absorbing material made by sintering thermoplastic resin, activated carbon, photocatalyst, silver nano powder, zeolite during sintering of the thermoplastic resin sintered porous sound absorbing material. It is preferable to have a sintering, antibacterial and sterilizing function by mixing and sintering.

In addition, the incidence hole is preferably formed around the inner surface of the chamber of the resonance chamber.

In general, the noise of the vacuum cleaner mainly appears in the motor 10 for generating a vacuum, the conventional vacuum motor 10 is a high speed rotation of the centrifugal impeller 14, that is, the front of the impeller 14, that is, the suction port 12 Air is introduced through the air inlet 12, and a high air pressure flowed through the inlet 12 is cooled through the exhaust port 19 after cooling the motor 10 along the exhaust path, and noise and vibration are generated in the process. do.

In other words, vibration and noise are generated at the inlet 12 by a high-speed rotational movement of the impeller 14 operated to suck air, and noise and air sucked in the air having a frequency of 4 KHz to 12 KHz are generally along the exhaust path. Compressed airflow exiting the exhaust port 19 is mixed with the noise is a noise having a complex and wide band frequency.

In more detail, in the inlet 12, the vibration of the high speed rotary motion of the impeller 14 and the intake airflow noise due to the inhalation are mixed so that noise having a frequency of 4 KHz to 12 KHz is radiated toward the inlet 12, and the motor Since the impeller 14 part of (10) performs a high-speed rotational motion of 30,000 rpm to 40,000 rpm with respect to the rotating shaft 18, friction and vibration noise are generated mainly on the M1 and M2 parts of the impeller case 16, The friction vibration noise is radiated through the suction channel as the impeller case 16 serves as a ringing plate. In addition, the noise generated by the impeller 14 comes out of the exhaust port 19 together with the compressed air along the exhaust flow path inside the motor 10. The air exiting the exhaust flow path forms the turbulence in the exhaust port 19 to impeller In combination with the noise from (14), it becomes a complicated airflow noise.

With reference to the accompanying drawings, the present invention which is a device for reducing the noise generated by the operation of the impeller of the motor as described above will be described in detail. 1 is a perspective view according to a preferred embodiment of the present invention, Figure 2 is an exploded view according to a preferred embodiment of the present invention, Figure 3 is a cross-sectional view according to a preferred embodiment of the present invention, Figure 4 is a first of the present invention 5 is a perspective view according to a second embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along the AA portion of FIG. 3.

Noise reduction device (N) of the vacuum cleaner motor according to the present invention, as shown in Figure 1 is coupled to the upper portion of the resonance chamber 20 and the resonance chamber 20 coupled to the upper portion of the motor 10 It is composed of a sound absorbing tube 30 or a suction tube 40 and a lower cover 50 coupled to the lower portion of the resonance chamber 20.

The resonance chamber 20 is coupled to the upper portion of the motor 10 to reduce the noise coming from the inlet 12 of the motor 10, the air passage formed to the same diameter as the inlet of the inlet 12 ( 22 is formed in the center, and consists of a chamber 24 having an inner space portion outside the air flow passage 22. Therefore, the resonance chamber 20 has an air flow path 22 formed at the center thereof, and its cross section has a rectangular shape.

In addition, the chamber 24 is filled with a porous thin fibrous material such as a sponge or a porous flexible foamed elastic material.

Existing resonance method is a method to reduce the noise by creating a separate resonance chamber for each frequency, because the noise generated in the inlet 12 has a wide frequency, so that several resonance chambers are required to reduce the noise. The resonance chamber 20 according to the present invention inserts a porous thin fibrous material or a porous flexible foamed elastic material into the chamber 24 of the resonance chamber 20 so as to simplify the structure and achieve the same effect. It is possible to effectively reduce the noise of a wide band without making a resonance chamber for each frequency and is configured to reduce the noise exiting the air flow path (22).

As described above, the sound absorbing reliability is further improved by inserting the porous thin fibrous material or the porous flexible foamed elastic material which is excellent in reducing the noise of the low frequency portion into the chamber 24 of the resonance chamber 20.

In addition, the incident hole 28 in which the noise suctioned from the suction port 12 enters the resonance chamber 20 without affecting the air flow flowing through the air passage 22 is a chamber of the resonance chamber 20. (24) It is provided around the inner surface.

Since the impeller 14 of the vacuum cleaner motor 10 performs a high-speed rotational motion of 30,000 rpm to 40,000 rpm with respect to the rotating shaft 18, as shown in FIG. 3, the M1 and M2 portions of the impeller case 16 are located. The friction and vibration noise is mainly generated. This part is composed of a structure in which the bottom surface of the chamber 24 of the resonance chamber 20 can be tightly coupled with the impeller case 16. It will absorb well. Here, the range of vibration shown in M1 is usually about 20 mm to 30 mm, and varies slightly depending on the type of the motor 10 and the structure of the impeller 14. The vibration absorbing structure prevents the appearance of secondary noise vibrations from the impeller case 16 to the resonance chamber 20 and increases the effect of the resonance chamber 20.

As shown in FIG. 2, the cover 60 is made of dustproof urethane or dustproof rubber which is closely coupled to the upper surface of the impeller case 16 to reduce vibration noise of the impeller 14 as described above. desirable.

According to the first embodiment of the present invention, as shown in FIG. 4, the pipe-shaped sound absorbing tube 30 having excellent noise absorption is coupled to the upper portion of the resonance chamber 20. The inner diameter of the sound absorbing tube 30 has a larger inner diameter than the air passage 22 of the resonance chamber 20 so as not to disturb the flow of air.

The sound absorbing pipe 30 solves the problem that noise generated in the impeller 14 is radiated along the air flow passage 22, and the air flow passage 22 does not affect the flow because the high speed air is sucked in. It does not consist of structures.

The noise to be reduced depends on the height of the sound absorbing pipe 30, which is shown in Table 1.

[Table 1] Noise Reduction

Nil 6 cm 7 cm 10 cm 15 cm 20 cm 30 cm 60 cm Air intake side Sound absorption tube Noise module Length 70cm 70db 74db 72db 70db 68db 65db 63db 61db 60db

The second embodiment according to the present invention is a structure capable of reducing the noise of the impeller 14, as shown in Figure 5, the same inner diameter of the air passage 22 on the upper portion of the resonance chamber 20 Has a suction pipe 40 formed around the pipe shape of the closed top is configured to be coupled.

The most effective way to control the noise from the inlet 12 of the motor 10 is to block the noise source, the suction pipe 40 is configured to effectively block the high speed and noise source.

The suction pipe 40 has a pipe shape, the upper part is closed, and a plurality of suction holes 42 are provided to facilitate the suction of air. The suction pipe 40 configured as described above can achieve a noise reduction effect by blocking the direct radiation of the noise by blocking the noise source.

The suction hole 42 has a structure that is less influenced by the air intake for smooth suction, the size is preferably configured so as not to interfere with the flow rate while minimizing the amount of noise coming out of the suction hole 42, the suction hole It is preferable to comprise so that the total number of 42 may be 2 to 3 times or more of the suction area of the air flow passage 22.

And, the noise reduction value for each height of the suction pipe 40 is shown in Table 2.

[Table 2] Noise Reduction

Nil 5 cm 7 cm 10 cm 15 cm Air Intake Side Intake Tube Noise Module Length 70cm 70db 74db 72db 70db 69db 68db

In order to reduce the noise of the upper part of the motor 10 may be configured as in the first embodiment or the second embodiment, the sound absorbing tube 30 and the suction tube (30) in the resonance chamber 20 coupled to the upper portion of the impeller 14 It is also possible to configure 40 at the same time.

When the sound absorbing pipe 30 and the suction pipe 40 are provided at the same time, the sound absorbing pipe 30 serves to absorb the noise emitted from the suction hole 42 of the suction pipe 40 and to help smooth suction. In order to enhance the effect, the height of the sound absorbing pipe 30 is preferably 10 mm or more larger than the height of the suction pipe 40.

The noise generated by the impeller 14 of the motor 10 is discharged to the exhaust port 19 together with the compressed air along the exhaust flow path inside the motor 10, and the air exiting the exhaust flow path is discharged from the exhaust port 19. While forming turbulence, the noise from the impeller 14 is changed into complicated airflow noise. Such airflow noise is not easy to reduce the noise because the amount of air exiting the exhaust port 19 and the flow rate is fast.

The lower cover 50 coupled to the outside of the exhaust port 19 of the motor 10 according to the present invention in order to reduce the noise of the exhaust port 19 as described above, is coupled to the lower portion of the resonance chamber 20 An inner case 52 having an inner exhaust hole 54 through which the noise from the exhaust port 19 escapes is formed, and an outer exhaust hole 58 through which the noise from the exhaust hole of the inner case 52 escapes. The outer case 56 is configured to convert the turbulent air from the exhaust port 19 into a deflectable air flow to increase the area in contact with the inner and outer cases 52 and 56 to absorb noise energy.

In more detail, the turbulent air exiting the exhaust port 19 is divided into two parts into a deflectable airflow along the inner wall surface of the inner case 52 and exits into the inner exhaust hole 54 to form the inner wall of the outer case 56. The noise energy is reduced by the collision.

Subsequently, the silencer exiting the inner exhaust hole 54 is divided into two again and passes between the walls of the inner and outer cases 52 and 56 to the outer exhaust hole 58 of the outer case 56, but still has a high flow rate. It can be said to have. In order to effectively control the rapid airflow noise, the interval between the inner and outer cases 52 and 56 is narrowed in the inner exhaust hole 54 and wider toward the outer exhaust hole 58 to reduce the flow rate of the air to escape, thereby reducing the flow rate of the inner and outer cases. It is preferable to extend the contact time with the 52 and 56 so as to sufficiently absorb noise on the wall surfaces of the inner and outer cases 52 and 56.

In addition, in order to increase the effect of noise reduction, the size of the internal exhaust hole 54 of the inner case 52 is configured to be 1 to 1.5 times larger than the exhaust port 19 of the motor 10, and the external exhaust of the outer case 56 is provided. It is preferable to configure the size of the ball 58 to be larger than the internal exhaust hole (54).

Noise reduction device according to the present invention is configured to meet the causes of each noise, the structure is simple, but the noise reduction effect is large. Therefore, the noise reduction device according to the present invention can obtain a sufficient noise reduction effect even if used for each of the inlet, the impeller, and the exhaust port of the motor.

In order to maximize the noise and vibration reduction effect, the structure that is effective for noise and vibration reduction and the sound absorption and vibration absorption ability of the material constituting the structure are important. If the device according to the present invention is made of a thermoplastic resin-sintered porous sound absorbing material, the effect will be more excellent.

In general, among the properties of an object for sound, the practical importance is sound absorption and sound insulation. Sound insulation refers to the property that the noise that reaches the object does not penetrate and reflects. In general, the higher the particle size of the material constituting the material, the better the effect. Sound absorption means that the noise reaching the object is weakened and reflected. In general, porous materials are said to have abundant properties. The porous material has many pores on the surface, and the incident sound wave is absorbed into the material through the pores.

When sound waves are incident on the porous material, some are reflected, some are absorbed by vibrating air particles in the surface or pores of the material, and others are transmitted. At this time, the sound absorption is caused because part of the incident energy is converted into thermal energy by the viscosity of the air particles in the pores or by friction with the pore wall surface. Therefore, the particle size and porosity of porous materials are very important for sound absorption.

Thermoplastic Sintered Porous Sound Absorbing Material is Polyethylene (PE), Polypropylene (PP: Polypropylene), Polyester (Polyester), Polyvinylidene Fluoride (PVDF: Polyvinylidene fluoride) Fluoropolymer (PTFE: Polytetrafluoroethylene), Ultra High Molecular Weight Polyethylene It is made by sintering thermoplastic resins such as Ultra-High Molecular Weight Polyethylene (UHMW-PE) and Polyether sulfone (PES). It effectively absorbs noise as micropores and voids inside.

In addition, when sintering the thermoplastic resin-sintered porous sound-absorbing material, if activated carbon, photocatalyst, silver nanopowder, zeolite, etc. are mixed, the material itself has deodorization, antibacterial, and sterilization function, so there is no need for a separate deodorant and antibacterial agent used in a vacuum cleaner When the noise reduction device according to the present invention is manufactured using a thermoplastic resin sintered porous sound absorbing material containing functionalities, the air containing the various odors is continuously removed while passing through the noise reduction device. outstanding.

As described above, the noise reduction device of the vacuum cleaning motor according to the present invention includes a resonance chamber, a sound absorbing tube, and a suction tube, which are coupled to an upper portion of the motor so as to reduce noise generated in the motor as much as possible. It is configured to reduce the noise, and the material is a thermoplastic resin sintered porous sound-absorbing material having good air-absorption with abundant pores, and has a high noise reduction effect.

In addition, when sintering a thermoplastic resin-sintered porous sound-absorbing material, mixed sintering of activated carbon, a photocatalyst, silver nanopowder, and zeolite, which is a functional material, adds functionality to the material, thereby eliminating the need for a separate deodorant and antibacterial agent.

The present invention is not limited to the above embodiments, and various changes can be made by any person having ordinary knowledge in the field of the present invention without departing from the gist of the present invention as claimed in the following claims. It will be said that there is a technical spirit of the present invention to the extent.

1 is a perspective view according to a preferred embodiment of the present invention

2 is an exploded view according to a preferred embodiment of the present invention

3 is a cross-sectional view according to a preferred embodiment of the present invention.

4 is a perspective view according to a first embodiment of the present invention;

5 is a perspective view according to a second embodiment of the present invention;

6 is a cross-sectional view taken along the line A-A of FIG.

<Description of Symbols for Main Parts of Drawings>

10: motor 20: resonance chamber

30: sound absorption pipe 40: suction pipe

50: lower cover

Claims (9)

In the device that is coupled to the outside of the motor consisting of the suction port, the impeller, the exhaust port to reduce the noise, It is coupled to the upper portion of the motor to reduce the noise from the inlet, the air passage corresponding to the inlet is formed in the center, the porous thin fiber or porous foam in the interior of the chamber formed outside of the air passage A resonance chamber into which an elastic material is inserted; And a pipe-shaped sound absorbing tube having an inner diameter slightly larger than that of the air flow passage on the resonance chamber. In the device that is coupled to the outside of the motor consisting of the suction port, the impeller, the exhaust port to reduce the noise, It is coupled to the upper portion of the motor to reduce the noise from the inlet, the air passage of the same inner diameter as the inlet is formed in the center, the porous thin fibrous material or porous inside the chamber formed outside of the air passage A resonance chamber filled with a foamed elastic material; And a suction pipe coupled to an upper portion of the resonance chamber, the suction tube having the same inner diameter as the air flow passage, and having a suction hole formed around a closed pipe shape. In the device that is coupled to the outside of the motor consisting of the suction port, the impeller, the exhaust port to reduce the noise, It is coupled to the upper portion of the motor to reduce the noise from the inlet, the air passage corresponding to the inlet is formed in the center, the porous thin fiber or porous foam in the interior of the chamber formed outside of the air passage A resonance chamber filled with an elastic material; A suction pipe coupled to an upper side of the resonance chamber, the suction tube having the same inner diameter as the air passage, and having a suction hole formed around a pipe shape of which an upper portion is closed; And Noise reduction device for a vacuum cleaner motor comprising a; pipe-shaped sound-absorbing tube coupled to the outside of the suction pipe by a predetermined distance apart. In the device that is coupled to the outside of the motor consisting of the suction port, the impeller, the exhaust port to reduce the noise, In order to reduce the noise coming from the exhaust port of the lower part of the motor, the internal exhaust hole through which the noise from the exhaust port escapes is composed of an inner case formed on one side, the outer case formed with an external exhaust hole facing the inner exhaust hole, the inner and outer case Noise reduction device of the vacuum cleaner motor, characterized in that consisting of; the lower cover is configured as the interval between the inner exhaust hole and the outer exhaust hole wider. The method according to any one of claims 1 to 3, The inner case is coupled to the lower portion of the resonance chamber and the inner exhaust hole through which the noise from the exhaust port escapes, and the outer case formed with the outer exhaust hole through which the noise from the internal exhaust hole escapes. Noise reduction device of the vacuum cleaner motor, characterized in that it comprises a; the lower cover is configured as the interval from the inner exhaust hole to the outer exhaust hole wider. The method according to any one of claims 1 to 5, The material of the device is a noise reduction device for a vacuum cleaner motor, characterized in that the thermoplastic resin sintered porous sound absorbing material made by sintering thermoplastic resin. The method according to any one of claims 1 to 3 and 5, Noise reduction device for a vacuum cleaner motor, characterized in that the entrance hole is formed around the inner surface of the chamber of the resonance chamber. The method according to any one of claims 1 to 3 and 5, Noise reduction device of the vacuum cleaner motor, characterized in that the lower portion of the resonance chamber is provided with a cover made of anti-vibration urethane or anti-vibration rubber to hold the vibration of the impeller. The method of claim 6, Noise reduction device for a vacuum cleaner motor, characterized in that the sintering of the thermoplastic resin sintered porous sound-absorbing material has a deodorizing, antibacterial, and sterilizing function by mixing and sintering activated carbon, photocatalyst, silver nano powder and zeolite.