KR830000118Y1 - Device for reducing condensate noise in air conditioners - Google Patents

Abstract

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Description

Device for reducing condensate noise in air conditioners

1 is a partial schematic plan view of a self-contained indoor air conditioner showing an evaporator and a condenser coil with a fan to operate the air.

2 is a partial front view of the slinger and the condenser fan cover and the condenser fan according to the present invention, in which the passage of the condensate falling from the slinger is indicated by dotted lines.

3 is a plan view of section III-III of FIG. 2;

4 is a view of a conventional apparatus showing a condensate passage from a slinger ring not present in the present invention.

5 is a perspective view of a condenser fan cover showing a curved shield with a spread surface.

The present invention relates to an air conditioner suitable for treating condensate by means of a slinger device. Moreover, this article relates to a device for providing a curved shield with a sparging surface that quietly receives condensate from a slinger.

Conventional air conditioners, particularly self-contained indoor air conditioners for home use, include a refrigeration circuit having an evaporator and a condenser. Such an air conditioner is divided into an evaporation part and a condensation part by a partition wall, and the evaporation part is installed to communicate with the room air supplied to the conditioned air, and the condensation part is installed to communicate with the outside air for heat dissipation. An evaporator coil and an evaporator fan are installed at the evaporation part, and a condenser coil and a condenser fan are installed at the condensation part.

The refrigerant flows through a conventional circuit through an evaporator coil that absorbs heat from the air flowing through the evaporator coil and expands. The evaporator is operated at a lower temperature than the room air flowing over the evaporator coils where cooled air is generated. Condensate forms on the surface of the evaporator coil because the temperature of the evaporator coil is always below the dew point of the air flowing there.

In addition, the refrigerant circuit has a condenser coil, and the refrigerant flows from the compressor into the molten metal coil in the state of the refrigerant gas at a high temperature, and discharges most of its lead to the outside air flowing over the condenser coil, and as a result, the temperature of the refrigerant decreases considerably. And leaves the condenser coil in the liquid state.

The operating efficiency of the condenser coil was further increased by allowing condensate collected from the evaporator coil to be injected into the condenser coil, along with the air flowing over it.

The Slinger loaded in the condenser fan sent condensate from the airflow of the condenser fan, allowing the condensate to be injected into the condenser coil and evaporated therein. Such a slinger device also serves to remove unwanted condensate from the device. The use of Sringer is known and described in US Pat. No. 3,766,751, assigned to this assignor.

It is necessary to reduce the rotational speeds of the condenser and evaporator fans in order to produce a quieter air conditioner. However, reducing the rotational speed of the fan produced undesirable noise as the condensate sprayed by the Slinger hits the interior of the conditioner. The present invention provides a curved shield with an annular spray surface as the condenser fan cover. The sprinkling surface is fixed close to the slinger, thereby reducing the noise of a conventional apparatus caused by condensate collision with adjacent surfaces, i.e., the cover or fan cover surface, by impinging the condensate on the surface at acute angle. Conventional air conditioners have fan covers that condensate hits. However, the conventional fan cover does not have a curved shield with a spray surface and is not designed to reduce the condensate noise by the facility of the shield.

The object of the present invention is to reduce the condensate noise of the slinger of the magnetic air conditioner.

Another object of the present invention is to provide a splash sur-face in the indoor air conditioner to reduce the sound of condensate from the Slinger.

It is yet another object of the present invention to provide a curved shield with a sparging surface as a single part with the condenser fan cover to reduce the condensate noise of the Slinger.

Another object of the present invention is to provide ease, durability, and economics of assembling the device to reduce the noise of Sringer condensate.

The foregoing objects are achieved by the preferred embodiment of the present invention by the installation of a curved shield having a sparging surface closely surrounding the slinger in the air conditioner.

The shield consists of a condenser fan cover and a single part (integrated). The slinger attached to the condenser fan transfers the condensate into the condenser fan air stream through the condensate of the evaporator and sprays a portion of the condensate at an acute angle to the spray surface. The noise produced by the collision between the condensate and the spray surface is relatively small because the angle of impact is acute.

Embodiments of the present invention described below are intended for use in magnetically controlled air conditioners, but the present invention can also be used in a slinger device, or in other devices for pumping fluid into the air by a slinger, such as a raid or evaporator. Used.

Referring to the drawings, FIG. 1 is a partial schematic plan view of a magnetic indoor air conditioner 2 showing several element parts. The air conditioner 2 is provided with an evaporator 9 having an evaporator coil 8 and an evaporator fan 12, a condenser coil 10, a condenser fan 14, and an electric motor 16 by a partition wall 6. Genie is divided into a condensation unit (11). In the condensation unit, an air hole (30) for introducing external air, a condensate cover (18), and a discharge port (32) are provided.

An indoor air conditioner is usually installed in communication with the indoor air to be matched with the evaporator and with the condenser in communication with the outside air.

In a typical refrigeration cycle, the refrigerant is circulated through the condenser coil 10, the evaporator coil 8, a compressor (not shown) and an expansion regulator. The refrigerant expands in the evaporator coil and absorbs heat from the indoor air flowing through the outer surface of the coil to lower the room temperature. The evaporator coil temperature is usually lower than the dew point temperature of the solid air that is sucked by the evaporator fan 12 and flows through the outer surface of the coil. Therefore, a condenser generated from moisture contained in the air is formed on the evaporator coil 8 and collected in a base pan.

The action of the condenser coil 10 is to cool the hot compressed refrigerant sent from the compressor. In order to perform such cooling, the outside air is introduced into the condenser 11 through the air hole 30 by the condenser fan 14 driven by the motor 16. And the outside air is guided by the condenser fan cover 18 to surround the outer surface of the condenser coil 10 and is discharged through the discharge surface (32).

A cylindrical band is formed on the condenser fan 14 and attached to the tip of the fan blade to install a slinger 20 configured in the form of a solid ring. The shaft 24 is the rotation axis of the fan 14 and the slinger 20.

The condensed water generated from the evaporator coil 8 is collected into the base fan 26 extending from the evaporator 9 to the condenser 11. The condensed water enters the condensation unit from the evaporation unit by the waterproof path in the partition wall 6. The slinger 20, which is in contact with the condensate collected in the base fan 26, is rotated by the operation of the motor 16 through the shaft 24 on the condenser fan 14. Some of the condensate is sprinkled into the air stream by the action of the Slinger and is sprayed directly onto the condenser coil 10 to help remove heat from the refrigerant. Some other condensate is sprayed in the form of droplets in a direction perpendicular to the radius extending from the ring ring 20 to the edge of the ring ring. These droplets hit the inner surface of the air conditioner and are collected again in the base fan 26.

The condenser fan cover 18, made of a plastic material covering the condenser fan 14, acts as an airflow shielding wall and defines the cross-section between the air discharged from the condenser through the air holes 32. . A curved shield 27 having a spray surface 28 consists of a condenser fan cover 18 and a single portion, and the spray surface 28 is configured to be fixed close to the slinger 20.

4 shows the direction of scattering of condensate droplets when condensate is sprayed from the slinger 20 without the spray surface (former field). The direction of the water droplets is perpendicular to the two areas of the air conditioner, the inner wall of the air conditioner, in which significant noise occurs when the droplets collide.

2 depicts the impingement angle and direction of condensate droplets changed by the use of sparging surface 28. In the case of the present invention, since the water droplets collide at an acute angle with respect to the spraying surface, the direct impact and noise on the spraying surface are reduced.

It is clear from the above description of the preferred embodiment that the present invention provides ease, efficiency and economy in fabricating a device for reducing condensate noise.

Claims (1)

A condenser 11 having an evaporator 9 and a condenser fan 14, in which condensate is formed, a driving device 16 for driving the fan, and a fluid transfer device for transferring condensate from the evaporator to the condenser. And, in the air conditioning device consisting of a slinger 20, etc. in communication with the condensate in the condensate in order to reduce the noise of the condensate, the condensate sprayed by the slinger 20 is installed so as to impinge at acute angle to the spray surface Air conditioning apparatus, characterized in that it has a curved shielding portion (27) having a spraying surface (28) fixed adjacent one of the slinger.