KR100504854B1 - Noise reducing devise for vacuum-cleaner - Google Patents

Abstract

The present invention relates to a noise reduction device of a vacuum cleaner, comprising: a dust collecting chamber having a dust collecting filter for collecting foreign substances introduced into the body case together with air; and after suctioning the air separated by the dust collecting filter of the dust collecting chamber. A motor chamber having a motor for generating a suction force by discharging is divided and partitioned by partition walls, and a sound absorbing chamber having a predetermined resonance space is provided between the dust collecting chamber and the motor chamber to reduce noise by a change in the cross-sectional area of the flow path. In the vacuum cleaner, the sound absorbing chamber is formed so as to satisfy f = c / 4L when the frequency of the specific noise to be reduced is set to f, the sound velocity is c, and the length of the sound absorbing chamber is L, and the dust collecting chamber is connected to the motor chamber. By reducing the flow noise of the incoming air has the effect of improving the reliability of the vacuum cleaner.

Description

Noise reduction device of vacuum cleaner {NOISE REDUCING DEVISE FOR VACUUM-CLEANER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum cleaner, and more particularly, a vacuum for reducing the noise of air flow between a dust collecting chamber for collecting foreign substances sucked into the vacuum cleaner and a motor chamber for mounting a motor for generating suction force. It relates to a noise reduction device of a cleaner.

In general, the vacuum cleaner generates a suction force to easily clean even the corners and other places that are difficult to clean with a general broom or other cleaning tools in cleaning the house, car or other places, the dust by the suction force Home appliance to remove foreign substances.

Hereinafter, the conventional vacuum cleaner, as shown in FIG. 1 or 2, generates a suction force to suck the foreign matter and then collect the suctioned foreign matter and one of the vacuum cleaner main body 100 Extension hose 200, extension pipe 300, and the suction head 400 is coupled to the side is configured to be sequentially connected.

The cleaner body 100 is configured to apply power to the motor chamber 130 in which the body case 101 generates suction force by the partition wall, the dust collecting chamber 120 for collecting the foreign matter, and the motor chamber 130. Each compartment is divided into a power supply chamber 140.

The dust collecting chamber 120 includes an inlet 121 through which one end of the extension hose 200 is communicatively coupled so that air containing foreign matter is introduced through the extension pipe 300 and the extension hose 200 from the suction head 400, and the inlet port. A dust collecting filter 122 is provided to separate and collect foreign substances introduced through the 121 from the air.

The motor chamber 130 is suturely coupled to the air inlet 111 of the partition 110 to penetrate the partition wall 110 to suck in the air filtered by the foreign matter filter 122 of the dust collecting chamber 120. A motor 131 and a discharge hole 132 formed through one side of the main body casing 101 are provided to discharge the air sucked by the motor 131 to the outside of the cleaner main body 100.

In the figure, reference numeral 123 denotes a front filter, 141 denotes a cord reel, and 142 denotes a power cord.

By such a configuration, when the conventional vacuum cleaner comes into close contact with the bottom surface to be cleaned, the suction cleaner 400 generates the suction force by the motor 131 when the motor 131 of the vacuum cleaner is operated.

The air containing the foreign matter such as dust by the suction force generated by the motor 131 passes through the extension pipe 300 and the extension hose 200 in order from the suction head 400 and the dust collecting chamber 120 through the suction port 121. ) Flows into.

The foreign matter in the air sucked into the dust collecting chamber 120 is collected in the dust collecting filter 122, the filtered air is separated through the dust collecting filter 122, the air inlet 111 of the partition 110 After flowing into the motor 131 through the discharged into the motor chamber 130 is discharged to the air outlet 132 formed through one side of the motor chamber.

However, the air separated into the dust collecting chamber 120 after being introduced into the dust collecting chamber 120 quickly passes through the narrow space of the air inlet 111 formed through the partition wall 110. As it flows into the flow noise that is annoying to the human hearing, that is, the problem that the flow noise of the frequency (Hz) corresponding to the BPF (blade passage frequency) noise occurs.

According to the present invention devised to solve the above problems, an object of the present invention is to provide a noise reduction device for a vacuum cleaner for reducing the air flow noise generated between the dust collection chamber and the motor chamber inside the case of the vacuum cleaner.

In order to achieve the above object, the present invention is a dust collecting chamber having a dust collecting filter for collecting the foreign matter introduced with the air inside the main body case, and the suction force is discharged by sucking and discharged the air separated by the dust collecting filter of the dust collecting chamber In a vacuum cleaner having a sound absorbing chamber having a predetermined resonance space for dividing a motor chamber having a motor for generating a partition by partition walls and reducing noise due to a change in the cross-sectional area of the flow path between the dust chamber and the motor chamber. The sound absorbing room is a noise reduction device of a vacuum cleaner, characterized in that the frequency of the specific noise to be reduced, f, sound speed c, the length of the sound absorbing room is L, satisfies f = c / 4L to provide.

Hereinafter, the configuration and operation of the noise reduction device of the vacuum cleaner according to the present invention will be described in detail.

3 to 7 show a noise reduction device of the vacuum cleaner according to an embodiment of the present invention, Figure 3 is a side cross-sectional view of the vacuum cleaner body having a noise reduction device, Figure 4 is a vacuum having a noise reduction device Fig. 5 is an enlarged cross-sectional view of a sound absorbing chamber of the vacuum cleaner of the present invention, and Fig. 6 is a diagram showing the relationship between the transmission loss with respect to the length and area ratio of the sound absorbing chamber of the vacuum cleaner motor of the present invention. 7 is a view showing the relationship between the frequency according to the length of the sound absorbing chamber of the vacuum cleaner motor of the present invention and the resulting noise.

As shown in the drawing, the cleaner body 1 includes a dust collecting chamber 10 in which the body case 2 collects foreign substances, a motor chamber 20 generating suction force, and applying power to the motor chamber. And a sound absorbing chamber 30 positioned between the power supply chamber 40 and the dust collecting chamber 10 and the motor chamber 20 to reduce noise due to air flow by varying the cross-sectional area of the flow path. Partition is partitioned.

The dust collecting chamber 10 has an inlet 11 through which one end of an extension hose is communicatively coupled so that air containing foreign matter is introduced through an extension tube (not shown) and an extension hose (not shown) from the suction head (not shown), and the suction port is provided. The dust collecting filter 12 for collecting the foreign matter introduced through the (11) to separate the air is provided.

The sound absorbing chamber 30 has a predetermined volume of resonance space 31 between the dust collecting chamber 10 and the motor chamber 20 by the front partition 4 and the rear partition 5 inside the cleaner body case 2. It is partitioned to have.

The front partition 4 has the dust collecting chamber 10 and the rear partition 5 has the ventilation holes 6 and 7 communicating with the motor chamber 20, respectively. It is formed to have an area ratio.

In addition, it is preferable that the partition is divided into a plurality of the interior of the resonance space 31, and the inner partition wall is formed with a vent so that each of the divided resonance spaces communicate with each other.

The motor chamber 20 includes a motor 21 which is tightly fixed to the air outlet 7 of the rear partition 5 and a main body casing 2 for discharging the air discharged from the motor 21 to the outside of the cleaner body. A discharge hole 22 formed through one side of the motor chamber 20 is provided.

In the figure, reference numeral 13 denotes a front filter, 41 a cord reel, and 42 a power cord.

By such a configuration, when the noise reduction device of the vacuum cleaner according to the embodiment of the present invention applies power from the power supply chamber 40 to operate the motor 21 of the motor chamber 20, the motor 21 The suction force is generated, and the air containing foreign matter such as dust passes through the extension pipe and the extension hose from the suction head in turn, and is sucked into the dust collecting chamber 10 through the suction port 11.

The foreign matter in the air sucked into the dust collecting chamber 10 is collected and separated from the air inside the dust collecting filter 12, and the air separated from the dust collecting filter 12 opens the vent 6 of the front partition 4. It is introduced into the sound absorbing chamber 30 through.

The air introduced into the suction chamber 30 passes through the resonance space 31 having a predetermined volume so that the passage section inside the suction chamber 30 is expanded, and then through the vent hole 7 of the rear partition 5. After being sucked by the motor 21 of the 20, the air is discharged into the motor chamber 20, and the air discharged into the motor chamber 20 is discharged to the outside of the main body case 2 through the outlet 22.

At this time, the transmission loss (TL: Transmission Loss) of the sound absorption room 30 is obtained by the following equation,

here,

m = A ₂ / A ₁ (area ratio), A ₁ = vent area

A ₂ = sound absorbing area, k = 2πf / c: positive constant

L = sound absorbing chamber length [mm], c = sound speed (340m / sec)

f = frequency of sound wave to remove.

The transmission loss is a, the area ratio (m) is the vent area (A ₁₎ is larger the larger that is, the size of the sound-absorbing room area (A ₂₎ is limited in the interior of the body case 2 as shown in Figure 6 The smaller the amplitude α of the transmission loss is, the smaller the area ratio m is, on the contrary, the smaller the area ratio m is, i.e., the larger the vent area A ₁ is, the larger the amplitude α of the transmission loss is.

Further, when the suction chamber length L is longer, the period β of the transmission loss becomes smaller and the area where the maximum transmission loss occurs is narrowed. On the contrary, when the length L of the sound absorption chamber is reduced, the period of transmission loss ( β) becomes large, and the area where the maximum transfer loss occurs is widened. Therefore, the frequency at which the transmission loss TL is maximized is f = c / 4L.

As shown in FIG. 7, waveform a shows sound pressure (dB) according to the frequency of noise generated in a vacuum cleaner motor having no sound absorbing chamber 30, and waveforms b and c indicate the sound absorbing chamber 30. Sound pressure (dB) according to the frequency of the noise when the sound absorbing room length (L) is 100mm and 20mm, respectively.

Waveform a shows the maximum sound pressure (dB) in the 5000 Hz and 10000 Hz region of the blade pass frequency (BPF) of the vacuum cleaner motor 21, and waveform c shows the minimum sound pressure (dB) in the 5000 Hz and 10000 Hz region. Can be.

Therefore, it can be seen that the sound absorbing chamber 30 has a noise reduction effect when the sound absorbing chamber length L is 20 mm at the same area ratio m than when the sound absorbing chamber 30 is 100 mm.

Therefore, the area ratio m of the sound absorbing chamber and the sound absorbing chamber length L are varied so that the transmission loss TL is maximized and the rotational speed RPM of the impeller (not shown) of the vacuum cleaner motor 21. BPF (Blade Passing Frequency) is matched to each other (Matching) to cancel to reduce the noise of a specific area.

As described above, according to the present invention, a sound absorbing chamber is formed between the dust collecting chamber and the motor chamber inside the cleaner case to reduce the flow noise in a specific frequency region which is a problem among the noise generated by the vacuum cleaner. .

1 is a perspective view of a conventional vacuum cleaner,

2 is a plan sectional view of a conventional vacuum cleaner,

3 is a side cross-sectional view of the vacuum cleaner of the present invention;

4 is a cross-sectional plan view of the vacuum cleaner of the present invention;

5 is an enlarged sectional view of a suction chamber of the vacuum cleaner of the present invention;

6 is a diagram showing a relationship between a transmission loss with respect to a length and an area ratio of a sound absorbing chamber of a vacuum cleaner motor of the present invention;

7 is a view showing the relationship between the number of revolutions and the generated noise according to the length of the sound absorbing chamber of the vacuum cleaner motor of the present invention.

* Description of the main parts of the drawings *

2: body case 4: front bulkhead

5: rear bulkhead 6, 7: ventilator

10: dust collecting chamber 20: motor chamber

21: motor 30: sound absorption room

31: resonance space

Claims (3)

Dust chamber having a dust collecting filter for collecting the foreign matter introduced with the air in the main body case, and a motor chamber having a motor for generating a suction force by suctioning and discharging the air separated by the dust collecting filter of the dust collecting chamber In the vacuum cleaner which is divided and partitioned by the partition wall and provided with a sound absorbing chamber having a predetermined resonance space in order to reduce noise by changing the flow path cross-sectional area between the dust collecting chamber and the motor chamber, The length of the sound absorbing chamber is expressed by the following equation: Noise reduction device for a vacuum cleaner, characterized in that formed to a length that satisfies L = c / 4f (L: the length of the sound absorption chamber, f: frequency of the specific noise to be removed, c: sound speed). The method of claim 1, The sound absorbing room is divided into a plurality of resonance space by the partition inside the vacuum cleaner, characterized in that the noise reduction device. The method according to claim 1 or 2, The sound absorbing chamber is formed through the front, rear, or inner partition to form the resonance space, and the noise reduction device for a vacuum cleaner, characterized in that the ventilation area having a cross-sectional area and a predetermined area ratio of each resonance space is provided.