KR200143212Y1 - Sound insulation reinforcement structure of vacuum cleaner sound absorption room - Google Patents

Abstract

The present invention relates to a sound insulation structure inside a sound absorbing room of a vacuum cleaner, and more particularly, to a sound insulation reinforcing structure of a vacuum cleaner sound absorbing room to double the existing noise shielding effect by forming a sound insulating reinforcing structure inside the sound absorbing room.

In the construction and effect of the present invention, the sound absorbing material 18 is covered with a cylindrical sound insulation means 31 having a plurality of bent portions 31a, and then assembled to the inner surface portion 9a of the sound absorbing room 9, thereby making the existing noise. It has an excellent effect in further shielding and solving the difficulty of injection molding.

Description

Sound insulation reinforcement structure of vacuum cleaner sound absorption room

1 is a cross-sectional view showing a sound insulation structure of a sound absorbing room according to a conventional technical configuration.

2 is an exploded perspective view showing a sound insulation reinforcement structure according to the present invention

3 is a cross-sectional view showing an embodiment of the sound insulation reinforcement structure according to the present invention

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

* Explanation of symbols for main parts of the drawings

3: electric blower 9: sound-absorbing room

16: cylindrical box 18: sound absorbing material

31: sound insulation means 31a: bent portion

The present invention relates to a sound insulation structure inside a sound absorbing room of a vacuum cleaner, and more particularly, to a sound insulation reinforcing structure of a vacuum cleaner sound absorbing room to double the existing noise shielding effect by forming a sound insulating reinforcing structure inside the sound absorbing room.

In general, since the vacuum cleaner uses an electric blower for powerful suction force, it is convenient to use, but the noise generated is very large, and the interior of the home or office is very noisy during cleaning using a vacuum cleaner. There were a lot of bad things about it.

Therefore, although various means have been used in the art to shield the noise, there have been many difficulties in the technical configuration for the efficient sound insulation effect.

One of the means is shown in FIG. 1, and the structure of a general vacuum cleaner is such that the inside of the main body 1 is separated into a dust collecting chamber 2 and an electric blower storage chamber 4. The dust collecting chamber (2) is provided with a paper stopper (6) for filtering and storing dust contained in the air sucked through the suction pipe (5), which is an air suction passage, and in the electric blower storage chamber (4). The exhaust port part 7 is formed, the sound absorbing room 9 is accommodated, and the dust collecting chamber 2 is provided in the partition wall 8 separating the dust collecting chamber 2 and the electric blower storage chamber 4 from each other. A plurality of intake holes (not shown) are drilled to allow air to flow between the electric blower storage chamber 4 and the electric blower storage chamber 4.

The sound absorbing room 9 is supported and fixed by the front buffer 10, the intermediate buffer 11 and the rear buffer 12 in the electric blower storage chamber 4, the buffer 10 (11) (12) serves to prevent the generation of vibration noise of the sound-absorbing room (9).

The electric blower 3 is accommodated in the sound absorbing room 9, and the front blower 13 and the blower rear buffer 14 are mounted on the front and rear of the electric blower 3, respectively. The blower 3 is supported and fixed inside the sound absorbing room 9. The internal structure of the sound absorbing room 9 will be described in detail in terms of noise shielding.

That is, as shown in FIG. 1, the front surface of the blower front cushioning material 13 assembled to the front of the electric blower 3 constitutes an air layer for absorbing noise between the sound absorbing room 9 and the front wall. In order to make the most effective noise absorbing layer 15, the noise absorbing layer 15 is formed.

In addition, a cylindrical box 16 having a front surface is formed around the electric motor part of the electric blower 3 so as to shield the noise from the electric motor part, to bend and to lengthen the exhaust flow path.

A sound absorbing material 17 for absorbing sound and shielding is attached to the inner surface of the cylindrical box 16, and a sound absorbing material 18 is also attached to the inner surface of the cylindrical wall of the sound absorbing room 9. In addition, around the electric motor part of the electric blower (3) and inside the rear wall of the sound-absorbing room (9), the exhaust passages (19, 20) that pass through the dust without absorbing a certain amount of noise, but pass through the dust, respectively Attached.

With the configuration of the prior art as described above, the function of shielding noise is as follows.

That is, when the electric blower 3 operates, most of the dust and rubbish contained in the air sucked through the suction pipe 5 are filtered out by the paper filter 6 in the dust collecting chamber 21 and clean air. Enters the cylindrical space 22 through the intake groove hole 21 of the dividing wall 8 and enters into the electric blower 3 through the suction port 23 of the sound absorbing room.

Exhaust exhausted through the side of the electric blower (3) passes through the filter (19) wrapped around the electric motor part of the electric blower (3), so that the flow is vacuumed by the cylindrical box (16). It is bent at 90 ° to the front of the cleaner and flows.

The exhaust is bent into a U-shape while exiting the front edge of the cylindrical box 16 and flows between the outer surface of the cylindrical box 16 and the inner surface of the sound absorbing room 9. Exhaust is bent in an S-shape at the rear edge portion of the outer surface of the cylindrical box 16 and passes through the filter 20 attached to the inner surface of the rear wall of the sound absorbing room 9, so that the exhaust hole of the sound absorbing room 9 Exit the sound-absorbing room (9) through 24).

Exhaust exhausted from the sound absorbing room 9 is again bent 90 ° outward from the center line of the vacuum cleaner by the sound absorbing room accommodating part 25 so that the outer surface of the sound absorbing room 9 and the sound absorbing room accommodating part 25 are separated. The filter (26) bent to the front of the vacuum cleaner while flowing between the inner surfaces and finally attached to the inner surface of the exhaust port (7) formed at the front bottom surface of the sound-absorbing and accommodating portion 25, that is, the lower surface of the main body (26). ) And is discharged to the outside of the vacuum cleaner through the exhaust port (7).

Problems caused by the above-described prior art configuration and operation are as follows. That is, the material of the sound-absorbing room (9) is plastic, so that the injection molding of the sound-absorbing room (9) by a mold (mold), so that the thickness is beyond a certain limit (4 mm in the art) When the injection molded product is poorly formed, it is difficult to obtain the structure of the sound absorbing room 9 that is desired by those skilled in the art. Therefore, in order to increase the sound insulation effect, the thickness of the sound absorbing room 9 should be increased, but the problem cannot be increased infinitely for the reasons described above.

The sound insulation reinforcing structure according to the present invention has been devised to solve the above problems, and its purpose is to provide a sound insulation reinforcing structure of the vacuum cleaner sound absorption room to double the existing noise shielding effect by forming the sound insulation reinforcing structure inside the sound absorbing room. Is in.

Therefore, in order to achieve the above object, the present invention is a sound absorbing structure inside a vacuum cleaner sound absorbing room in which a cylindrical sound absorbing material is in close contact with an inner surface of a sound absorbing room of a vacuum cleaner. By providing a sound insulation reinforcement structure of the sound-absorbing room, characterized in that assembled.

Hereinafter, with reference to the accompanying drawings, the configuration and operation of the sound insulation reinforcement structure according to the present invention in detail as follows.

That is, as shown in FIG. 2, the sound insulation reinforcing structure 30 according to the present invention has a constant thickness on the sound absorbing material 18 attached to the inside of the sound absorbing room 9 shown in FIG. It is constructed by overlaying the generally cylindrical sound insulation means 31.

As shown in the drawing, the sound insulation means 31 has a structure in which a plurality of bent portions 31a bent at a predetermined angle on a cylindrical steel pipe surface are formed in an annular shape. 31), which is made of stainless steel or general steel having a high specific gravity.

FIG. 3 shows an embodiment in which the sound insulation reinforcing structure 30 according to the present invention is applied inside the sound absorbing room 9 shown in FIG. 1, and the thickness 32 of the sound absorbing room 9 is not increased. In the non-state state, it is assembled to the rear inner wall surface of the sound absorbing room 9.

FIG. 3 shows a flow direction 33 of the exhaust air flowing through the intake port 23 of the sound absorbing chamber 9 in the exhaust hole 24. The side opening 34 of the electric blower 3 is shown in FIG. Exhaust air exiting through the c) is bent into a U-shape while exiting the front edge of the cylindrical box 16 to form an outer surface portion 16a of the cylindrical box 16 and an inner surface portion 9a of the sound absorbing room 9. Between the sound absorbing material 18 in the sound insulation means 31 inside. At this time, the noise is almost absorbed and reflected by the sound absorbing material 18 and the sound insulating means 31, which is a component of the invention, the effect of the noise to the inner surface portion 9a of the sound absorbing room 9 is Significantly reduced.

On the other hand, FIG. 4 shows that the noise generated through the side opening 34 of the electric blower 3 is closer to the electric blower 3 due to the noise reflection phenomenon inside the bent portion 31a of the sound insulation means 31. It shows the flow direction 33 'of the return noise.

That is, as shown, the sound insulation means 31 is made of a material such as stainless steel having a large specific gravity, the bent portion formed on the surface of the sound insulation means 31 when the noise exhaustion hits the sound insulation means 31 (31a) It reflects and returns along the flow direction 33 'shown on the inner side.

Therefore, according to the sound insulation reinforcing structure 30 according to the present invention, in order to increase the sound insulation effect, by increasing the thickness 32 of the sound-absorbing room (9), to solve the problem of having to take injection molding defects fundamentally By forming a plurality of the bent portions 31a on the surface of the sound insulation means 31, there is an echo effect that reflects the noise in addition to doubling the existing sound insulation effect, which is excellent in shielding the noise of the electric blower. have.

In addition, since the sound insulation means 31 is made of a material such as stainless steel, an additional effect of acting as a reinforcing structure of the sound absorbing room 9 is also obtained.

Claims (2)

A vacuum cleaner in which a cylindrical sound absorbing material is in close contact with the inner surface portion 9a of the sound absorbing room 9 of the vacuum cleaner has a sound insulating structure in which the sound absorbing material 18 is covered with the sound insulating material 31. Sound absorbing structure of the sound absorbing room, characterized in that assembled on the inner surface (9a) of the sound absorbing room (9). The sound insulation reinforcing structure of a sound absorbing room according to claim 1, wherein said sound insulating means (31) is cylindrical and is formed in a plurality of bent portions (31a) bent at a predetermined angle on the surface thereof.