KR20080050155A - Noise reduction structure of refrigerator machine room - Google Patents

Abstract

A noise reduction structure of a machine room in a refrigerator is provided to absorb noise generated from a compressor, a cooling fan, and a cooling fan driving motor via discharge space parts effectively by forming sound absorbing materials. A noise reduction structure of a machine room in a refrigerator comprises a suction space part(770), discharge space parts(780), a partition, a curved surface(R), and sound absorbing materials(800). The suction space part has a suction hole(500) at one side and a condenser(300). The discharge space parts include a discharge hole(600) at one side and a compressor(200). The partition has a cooling fan(400) between the suction space part and the discharge space part. The suction space part and the discharge space part include a bottom frame, a front plate(750), a rear machine room cover(720), a cover plate, and two side plates(710). The curved surface is formed at an edge portion of the front to be opposed to the discharge hole. The sound absorbing materials are formed at the side plates, the machine room cover, and the cover plate to be opposed to the cooling fan from the discharge space part of the machine room. The sound absorbing materials, whose surface is not protruded to a peripheral plate, are fitted into grooves formed on the side plates, the machine room cover, and the cover plate.

Description

Noise reduction structure of refrigerator machine room {NOISE REDUCTION STRUCTURE OF REFRIGERATOR MACHINE ROOM}

1A is a plan view illustrating a machine room structure of a general refrigerator.

1B is a schematic plan view of the machine room of FIG. 2A.

FIG. 1C is a schematic plan view showing a noise generation state in the machine room of FIG. 2A.

2 is a plan view showing the machine room structure of the refrigerator according to the present invention.

3 is a rear view showing the machine room structure of the refrigerator according to the present invention.

4 is a perspective view illustrating the structure of a bell mouse in FIG. 2.

※ Explanation of Major Components

200 ... compressor

300 ... condenser

400 ... cooling fan

500 ... inlet

600 ... outlet

710 ... shroud

720 ... machine room cover

730 ... cover plate

800 .., Sound absorbing material

900 ... Bell Mouse

1000 ... machine room

The present invention relates to a noise reduction structure of a refrigerator machine room, and more particularly, to a noise reduction structure of a refrigerator machine room for reducing high frequency noise generated in a refrigerator machine room.

As shown in FIGS. 1A and 1B, a machine room 121 is formed at a bottom rear portion of a main body of a general refrigerator, and the machine room 121 is configured to compress a high temperature and high pressure refrigerant that generates cold air. 103 and a condenser 111 for liquefying a refrigerant are mounted.

In addition to the compressor 103 and the condenser 111, a cooling fan 123 and a cooling fan 123 for dissipating heat generated from the compressor 103 and the condenser 111 to the outside in the machine room 121 of the refrigerator. A motor 125 for driving the engine 125 is installed at a position adjacent to the compressor 103, and all of these devices are attached to the bottom frame 127 by fastening means such as bolts 129 and the like. The machine room 121 is also surrounded by the bottom frame 127, the cabinet 131 of the refrigerator, the front plate 133 and the machine room cover 135, the bottom, side and back, and the upper surface is a separate cover plate (not shown) Sealed).

Thus, as shown schematically in FIG. 1C, the conventional refrigerator machine room 121 has a high frequency noise generated from the compressor 103, the cooling fan 123, and the cooling fan drive motor 125. Large release through the machine room cover 135 and cover plate.

In addition, in a general refrigerator machine room, the cooling fan 123 is blown through an air distribution hole such as an inlet and an outlet formed in the cover of the machine room 135, thereby causing a high frequency noise generation.

The high frequency noise corresponds to the noise having a high frequency characteristic of 2.5 to 3.15 kHz.

The present invention has been made to solve the above problems, an object of the present invention is to provide a noise reduction structure of the refrigerator machine room for reducing the high frequency external noise generated by the compressor, the cooling fan and the cooling fan drive motor in the machine room of the refrigerator. To provide.

In order to achieve the above object, the noise reduction structure of the refrigerator machine room according to the present invention,

A suction space portion accommodating the condenser and having a suction port formed at one side thereof; A discharge space portion accommodating the compressor and having a discharge port formed on one side, a partition provided with a cooling fan between the suction space portion and the discharge space portion, a bottom frame forming an outer portion of the suction space portion and the discharge space portion, a front plate, and a rear machine room cover. And a cover plate and both side plates, a curved surface formed at a front edge portion facing the discharge port, and a sound absorbing material disposed on the side plate facing the cooling fan in the discharge space portion of the refrigerator machine room, the machine room cover and the cover plate. It is characterized by.

Here, the sound absorbing material is fitted into the groove formed in the side plate, the machine room cover and the cover plate, respectively, it is preferable that the surface of the sound absorbing material does not protrude with respect to the peripheral plate.

In addition, it is preferable that a bell mouse having a larger cross section toward the compressor is provided around the cooling fan.

In addition, the bell mouse preferably has an inclination angle in the range of 50 ~ 70 ° relative to the rotation surface of the cooling fan.

Hereinafter, with reference to the accompanying Figures 2 to 4 will be described in detail a preferred embodiment of the present invention. In this case, the parts except for the machine room are not different from other general refrigerators, so a separate description of the parts will be omitted.

As illustrated, the machine room 1000 of the refrigerator includes a compressor 200 for compressing a high temperature and high pressure refrigerant, a condenser 300 for cooling and liquefying the refrigerant supplied from the compressor 200, and the condenser 300. And a cooling fan 400 disposed between the compressor 200.

The housing structure surrounding various devices in the machine room 1000 has a structure in which the front plate 750 is covered in front of the bottom frame 740 forming the bottom surface and the machine room cover 720 is covered in the rear. . In addition, a cover plate 730 is disposed above the bottom frame 740. In addition, side plates 710 are disposed on both sides of the cooling fan 400.

In addition, around the cooling fan 400 between the condenser 300 and the compressor 200, a partition 760 having a vent hole (not shown) is opened at the center thereof, and the cooling fan 400 faces the condenser 300. Air is sucked from and blown toward the compressor 200. Accordingly, the space inside the machine room 1000 is divided into a suction space 770 provided with the condenser 300 and a discharge space 780 provided with the compressor 200 with the partition 760 interposed therebetween.

Here, a suction port 500 through which air from the outside is sucked by the cooling fan 400 is formed at one side of the machine room cover 720 of the suction space 770, and the machine room cover (of the discharge space 780) is formed. At one side 720, a discharge port 600 for discharging the circulating air of the cooling fan 400 passing through the compressor 200 to the outside is formed through.

In addition, a curved surface (R) is formed at the front edge portion facing the discharge port 600 to guide the noise generated from the condenser 300 to the discharge port 600 as smoothly as possible to reduce noise by one step.

On the other hand, the upper part of the condenser 300, the defrost water receiving container 350 for receiving and storing the defrost water from the defrost pipe is installed.

According to this structure, the outside air flows into the suction space 770 through the suction port 500 formed in the machine room cover 720 of the suction space 770. Then, the introduced air is added to the condenser 300 to cool the condenser to reach the cooling fan 400.

Next, the inlet air is introduced into the discharge space 780 through the vent hole 760a of the partition 760 by the cooling fan 400 to cool the compressor 200. Thereafter, the air passing through the compressor 200 is discharged through the discharge port 600 while being guided to the curved surface R of the front plate 750.

In this case, in the machine room at the compressor 200 side, the sound absorbing material 800 is disposed in at least a portion of the side plate 710, the machine room cover 720, and the cover plate 730 facing the cooling fan 400.

The sound absorbing material 800 may be used a general product on the market, there is no particular limitation on the material. In particular, since the noise generated in the machine room has high frequency characteristics, it is preferable to adopt a porous sound absorbing material. That is, it is preferable to use materials, such as a sponge and a textile.

Accordingly, the noise passing through the cooling fan 400 is mostly absorbed by the inner surface of the discharge space 780.

Furthermore, grooves 790 into which the sound absorbing material 800 is fitted are formed in the plates 710, 720, and 730, so that the surface of the sound absorbing material 800 has a peripheral plate (eg, a curved plate R). A natural connection surface can be formed without protruding from)).

On the other hand, a bell mouth 900 having a larger cross section toward the compressor 200 is provided around the cooling fan 400. That is, the bell mouse 900 is formed in a trumpet shape. Accordingly, since the noise generated by the cooling fan 400 is naturally guided along the inclined surface of the bell mouse 900, wind noise caused by the rupture of sound waves is eliminated.

At this time, the inclination angle of the bell mouth 900 with respect to the installation surface of the cooling fan 400 is preferably in the range of 50 ~ 70 ㅀ. This is because the noise generated by the cooling fan 400 occupies about 80% of the circumferential portion of the center, and the discharge direction is also around 60 mW. That is, when the inclination angle of the bell mouse 900 is smaller than 50 ㅀ, the sound wave may hit the bell mouse and a rupture sound may be generated.

The bell mouse 900 may be separately installed in the partition 760 or may be previously manufactured integrally.

As a result, the noise around the cooling fan 400, which occupies most of the wind noise, naturally moves toward the discharge port 600 through the bell mouth 900, and thus the overall noise is greatly reduced.

Through actual experiments, it can be seen that the noise reduction effect of about 3dB is obtained in the high frequency band when comparing the noise of the machine room with respect to the conventional machine room shown in FIG. 1B and the machine room structure of the present invention shown in FIG.

According to the present invention having the above-described configuration, the sound absorbing material is disposed in the side plate, the machine room cover and the cover plate facing the cooling fan in the compressor-side machine room, so that the noise generated by the compressor, the cooling fan and the cooling fan drive motor is discharged. There is an advantage that the noise is effectively reduced in the space portion is greatly reduced.

In addition, according to the present invention, since the surface of the sound absorbing material does not protrude with respect to the plate arranged around the periphery of the sound absorbing material, the expansion of the noise by the protruding portion can be prevented.

In addition, according to the present invention, a bell mouse having a large cross section toward the compressor is installed around the cooling fan to guide the sound waves smoothly, thereby preventing the bursting wind noise.

Claims (5)

A suction space portion for accommodating the condenser and having a suction port at one side thereof, A discharge space part accommodating the compressor and having a discharge port formed at one side thereof; A partition provided with a cooling fan between the suction space portion and the discharge space portion, A bottom frame, a front plate, a rear machine room cover, a cover plate, and both side plates forming an outline of the suction space and the discharge space; A curved surface formed at the front edge portion facing the discharge port, and Noise reduction structure of the refrigerator machine room comprising a sound absorbing material disposed in the side plate, the machine room cover and the cover plate facing the cooling fan in the discharge space portion of the refrigerator machine room. The method of claim 1, The sound absorbing material is installed in each of the grooves formed in the side plate, the machine room cover and the cover plate, the noise reduction structure of the refrigerator machine room, characterized in that the surface of the sound absorbing material does not protrude relative to the peripheral plate. The method of claim 2, The sound absorbing material is a noise reduction structure of the refrigerator machine room, characterized in that made of a porous material. The method according to any one of claims 1 to 3, Noise reduction structure of the refrigerator machine room, characterized in that the bell mouse is installed around the cooling fan of the partition having a larger cross section toward the compressor. The method of claim 4, wherein The bell mouse has a noise reduction structure of the refrigerator machine room, characterized in that the inclination angle of the range of 50 ~ 70 ° relative to the rotation surface of the cooling fan.

Images