KR830000162Y1 - External condensation eliminator in air conditioner - Google Patents

Abstract

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Description

External condensation eliminator in air conditioner

1 is a schematic side view of a magnetic field type air conditioner according to the present invention.

2 is a schematic plan view of the air conditioner of the present invention showing the circulation state of the condensate.

3 is a cross sectional view along line III-III of FIG. 2;

The present invention relates to an air conditioner for collecting evaporator condensate, and more particularly to an air conditioner for circulating collected condensate to prevent the occurrence of a low temperature pocket to cause condensation on the outside of the conditioner.

So-called self-contained air conditioners, commonly used in residential or similar applications, include a closed refrigeration circuit containing an evaporator and a condenser.

This type of air conditioner is usually divided into an evaporation part and a condensation part by a partition wall, and the evaporation part communicates with indoor air to be harmonized, and the condensation part communicates with external air such as outdoor air. The refrigerant flows through the refrigeration circuit and absorbs heat from the indoor air at the evaporator to release heat to the outside air at the condenser. Conventional refrigeration circuits are completed by additional attachment of compressors and expansion devices and proper connection between each device.

In the evaporator, air is sent out to the room via an evaporator by an evaporator fan. In an evaporator, the refrigerant changes from liquid to gaseous and absorbs heat from the air during this change. During operation, the evaporator temperature is typically lower than the dew point of the air where heat is absorbed, so that with the cooling of the air some of the moisture contained in the gaseous state condenses and collects on the surface of the evaporator in the liquid phase. . This condensate is shown in a drain pan below the evaporator and is discharged by gravity through the bulkhead that defines the air conditioner.

In the condensation unit, the condensed water is discharged to an external region or evaporated in a condenser for treatment. The condenser receives the compressed hot refrigerant from the compressor and must cool the refrigerant before going to the evaporator. Condenser fans are used to circulate air through the condenser to absorb heat. However, it has been found that when droplets of condensate are sprayed on the condensate, the condensate is evaporated and treated as well as the efficiency of the condenser is improved. The slinger described in U. S. Patent No. 33766751 is a device for spraying condensate onto a condenser.

An oil barrier is a device installed in the condenser fan that creates sufficient eddy currents to draw the condensate into the air stream of the condenser fan which either physically contacts the condensate or blows it onto the condenser surface. A bass pan under the condenser of the air conditioner forms a reservoir for collecting the condensate. A condenser fan shroud is typically attached to the condenser of the conditioner and is used to guide the flow of air to the condenser, while at the same time forming a passage between the air entering and exiting the conditioner. The condenser fan cover is also used to divide the reservoir formed in the base fan into two parts.

Conventionally, if no other measures are taken, cold water discharged directly from the evaporator is collected at a specific part of the reservoir and becomes cold enough to lower the outside temperature of the basal fan to a temperature below the dew point of adjacent air. It happened a lot.

According to the present invention, since the waterproof passage extends through the condenser fan cover so as to communicate with the condensate, a circulation passage of the condensate is formed. The air pressure difference generated by the fan in operation circulates the condensate and mixes it with the relatively cold condensate formed in the evaporator to remove the cold pockets that cause external condensation of the conditioning system.

Another method of preventing the formation of cold pockets of condensate is effective, but too complex and too expensive to produce. Examples include insulating the base pan to prevent moisture or providing a stirring device for circulating the collected condensate.

An object of the present invention is to prevent external condensation in an air conditioner.

Another object of the present invention is to prevent external condensation of the conditioner by circulating the condensate generated on the evaporator into the conditioner to prevent pockets of cold condensate from forming in the evaporator.

Another object of the present invention is to provide an external anti-condensation device which is manufactured inexpensively in an air conditioner, is easy to attach, and convenient to repair.

It is a further object of the present invention to provide an external condensation preventing device for an air conditioner without adding any other parts to the device and without any additional assembly or repair process.

The above objects are achieved in a suitable embodiment of the present invention by forming one waterproof path on each side of the condenser fan opening to contact the reservoir with the reservoir formed by the condenser base pan of the conditioning system.

The condenser fan attached to the condenser fan opening will generate an air pressure differential of sufficient magnitude to circulate the condensate through these channels. Thus, the relatively hot condensate is brought into contact with the cold condensate and the cold pocket of the condensate, which causes external condensation of the conditioner, is removed.

The indoor air conditioner 10 schematically shown in FIG. 1 is divided into an evaporator 12 and a condenser 14 by a partition 26. The conditioner 10 is attached so that in normal use the evaporator 12 communicates with the harmonized indoor air.

The evaporator 12 has an evaporator 16 for absorbing heat from the air and an evaporator fan 18 for sucking the indoor air from the evaporator 16 and for delivering the harmonized air to the room (air). Inlet and outlet are not shown).

The condensation unit 14 of the air conditioner 10 is attached in contact with the outside air. The condenser 20, the condenser fan 22, and the motor 24 for operating the condenser fan 22 and the evaporator fan 18 are attached to the condenser 14.

The condenser fan 22 sucks outside air into the condenser 14 and discharges the air from the condenser 20 to the outside to absorb heat from the refrigerant on the surface of the condenser 20. The condenser fan cover 32 (FIG. 2) forms an air passage leading into the condenser 14 and attaches to the condenser 14 for guiding air from the condenser fan 22 via the condenser 20. (The discharge port and the discharge area of the condenser 14 are not shown).

In this embodiment, a normal refrigerant circuit is used to condition indoor air. In addition to the evaporator 16 and the condenser 20, a compressor and expansion device (not shown) are connected to form a refrigeration circuit. The liquid refrigerant expands in the evaporator 16 to become a gas, absorbs heat from the air, and lowers the temperature of the evaporator 16 to a temperature below the dew point of the air passing through the evaporator 16. When the temperature of the evaporator 16 becomes below the dew point of the adjacent air, water vapor contained in the air becomes water droplets and adheres to the surface of the evaporator 16. This water is collected and falls to the drain pan 36 below the evaporator 16. Cold condensate collected in the drain pan 36 flows downward through the drain pan outlet 38 and passes through the opening 40 of the partition 26 and is formed by the base pan 28 and the partition 26. Enter the reservoir 30. The base fan 28 has flanges on four sides, which together with the partition 26 form the wall of the reservoir 30.

The refrigerant is usually transferred from the evaporator 16 to the condenser 20 via a compressor (not shown) as in the case of the refrigeration cycle. The heat of the relatively hot refrigerant is absorbed by the air in contact with the surface of the condenser 20, and the refrigerant circulated through the condenser 20 is cooled.

In the condenser 14 of the air conditioner 10, a condenser fan cover 32 is attached such that the condenser fan 22 is generally received in the condenser fan 32 opening 42 of the cover and the condenser fan cover 32 is provided. ) Is discharged from the air conditioner 10 through an outlet (not shown) and the condenser fan 22 through the condenser 20 and into the condenser 14 (not shown) through the delivery area. It forms a passage for air.

A slinger 44 is attached to the condenser fan 22. The slinger 46 is a cylindrical band body whose opening 30 is in contact with the condensate in the reservoir 24. When the condenser fan 22 is rotated by the shaft connected to the motor 22, the slinger 44 discharges the condensate water into the air stream so that the condenser fan 22 is sprayed on the condenser 20. The condensate immediately evaporates and removes unnecessary condensate from the air conditioner 10 while improving the heat transfer efficiency of the condenser 20. The condenser fan cover 32, which divides the reservoir 30 into two parts, has one waterproof path 34 on each side of the condenser fan opening 42 (FIGS. 2 and 3).

The waterproof passage 34 is located adjacent to the base fan 28 and circulates the condensed water between both sides of the condenser fan cover 32.

Rotation of the condenser fan 22 causes a difference in air pressure sufficient to force circulation of condensed water from the evaporator in the reservoir 30. The circulation of condensate flowing from the evaporator and purified in the reservoir 30 is mixed with the condensate present in the air conditioner 10 for a period of time, and as a result, a lower temperature entering from the evaporator 16 through the opening 40 is obtained. It will heat the condensate. The total condensate temperature is outside the conditioner 10 adjacent to the opening 40 where the condensate contacts the base plate 28, which causes external condensation to form on the outer surface of the base pan 28 by this mixing. There was a lot of condensation. The condenser fan cover 32 is a single molded product that is inserted into the conditioning device 10 and assembled.

In order to form the waterproof passage 34 according to the present invention, the single molded article may be modified such that a plurality of openings are formed in a part of the condenser fan opening 42. Thus, no other assembly is needed to form the waterproof passage 34.

By the embodiment of the above description, the object of the present invention for removing external condensation of the conditioner 10 is very easily achieved.

Claims (1)

An air conditioner formed by an evaporator having an evaporator in which condensed water is formed and a condenser having a condenser and a condenser fan made of a rotating body by a partition wall and a motor for rotating the fan, forming a reservoir in the condenser 20. The base pan 28 and the drain pan out let 38 to transfer the condensate from the evaporator 12 to the reservoir 30 are divided into two parts and communicated with the reservoir. External condensation removal device of the air conditioner, characterized in that consisting of a condenser fan cover (32) having a waterproof passage (34).