KR19990009858A - Condensate drainage structure of air conditioner - Google Patents

Abstract

The present invention discloses an improved condensate drainage structure of an air conditioner.

Conventionally, only the drain pan is provided in the lower part of the evaporator to collect and discharge condensate. Thus, a water bridge phenomenon occurs due to condensate concentration at the lower end of the evaporator, thereby lowering cooling performance.

In the present invention, at least one drain guide is installed to be inclined in the horizontal direction to traverse the heating fins in a predetermined position of the vertical direction of the evaporator and to collect the condensed water generated in the evaporator located on the upper side and guide the condensed water to the outer side of the side plate; Water drain phenomenon due to concentration of condensate at the bottom of the evaporator is provided with a drain pan installed at the bottom of the evaporator to collect condensate generated by the evaporator and a drain hose connected to the drain pan to discharge the collected condensate to the outside. The cooling performance was prevented from being prevented from occurring.

Description

Condensate drainage structure of air conditioner

The present invention relates to an air conditioner, and more particularly, to a structure for draining condensate generated on the surface of an evaporator when a refrigerant evaporates.

The air conditioner used to cool the room using a cooling cycle is well known, and the refrigerant gas compressed in the compressor is liquefied by heat exchange with ambient air in a condenser, and then an expansion valve. It is an air conditioner that cools the room by vaporization heat of refrigerant absorbed by vaporizing liquid refrigerant changed to low temperature through valve) by heat exchange with ambient air in the evaporator.

Accordingly, when the air conditioner is driven, a large amount of condensed water is generated by instantaneous condensation of water in the air due to a sudden drop in temperature while the air is cooled. Such condensate will flow out of the air conditioner as well as the inside of it and contaminate the room, so it must be properly collected and drained.

For this purpose, as shown in FIG. 1, a condensate (W) generated from the evaporator (E) is installed by installing a drain pan (D) at the bottom of the evaporator (E). ), And collect the condensate (W) in the drain pan (D) by flowing down the heating fins (傳熱 fin: F), and then through the drain hose (H) connected to the drain pan (D) To discharge. The remaining symbol T is a tube through which the refrigerant flows.

However, since the conventional condensate drainage structure simply installs only the drain pan D in the lower part of the evaporator E to drain by natural falling of the condensate W, condensate W is concentrated at the lower end of the evaporator E. There was a problem in that the water bridge phenomenon occurs to reduce the cooling performance of the evaporator (E). That is, all of the condensate (W) generated on the surface of the evaporator (E) flows down to the lower end side of the evaporator (E) by riding the side plate (S) and the heat transfer fins (F), and toward the lower end of the condensate (W) As the amount increases, the water bridge phenomenon due to the surface tension of the condensate water W is severely generated between the heat transfer fins F, as shown in FIG. 2, and thus the amount of air flow into the evaporator E is reduced. The heat exchange amount is reduced. This problem is more serious the larger the evaporator (E). Therefore, the conventional drainage structure was not able to reliably drain the condensate (W), and as a result, it was not possible to guarantee the cooling performance and reliability of the air conditioner such as causing a decrease in the thermal efficiency of the evaporator (E).

SUMMARY OF THE INVENTION An object of the present invention is to provide a condensate drainage structure of an air conditioner capable of reliably draining condensate by effectively preventing the water bridge phenomenon at the bottom of the evaporator caused by the concentration of condensate generated on the surface of the evaporator in view of the above-described conventional problems. It is.

In order to achieve the above object, the condensate drainage structure of the air conditioner according to the present invention is connected to the compressor and the condenser, respectively, and has a zigzag-shaped tube in which the refrigerant flows therein, and is arranged orthogonal to the tube to promote heat exchange of the refrigerant. An evaporator of an air conditioner having a plurality of plate-shaped heat transfer fins and side plates coupled to the tubes so as to be positioned on both outer sides of the heat transfer fins, the horizontal direction of traversing the heat transfer fins at a predetermined position in the vertical direction of the evaporator. At least one drain guide is installed inclined to collect the condensate generated by the evaporator located at the upper side to guide the outer side of one side plate, and the condensate is installed at the bottom of the evaporator to collect the condensed water generated in the evaporator To drain the drain pan and the collected condensate connected to the drain pan Key is characterized in that it is constituted by a drain hose.

According to one preferred feature of this invention, a plurality of flow paths for guiding the drainage of the condensed water collected on the upper surface of the drain guide are formed in the longitudinal direction thereof.

Accordingly, the present invention effectively prevents condensate concentration at the lower end of the evaporator, so that the water bridge phenomenon of the condensate does not occur as in the prior art, and thus has a great effect on improving cooling performance and reliability of the air conditioner.

1 is a front view of an evaporator showing a conventional condensate drainage structure,

2 is an enlarged front view of an extract of an evaporator which schematically shows a conventional problem;

3 is a front view of the evaporator showing the condensate drainage structure according to the present invention,

4 is a perspective view showing an extract of the drain guide of the present invention;

Figure 5 is an enlarged view of the main portion of the evaporator showing the effect of the present invention.

<Description of the code | symbol about the principal part of drawing>

E: evaporator D: drain pan

F: Heat fin (of evaporator)

S: side plate

G: Drain guide

C: Flow path (drain) N: Flange (drain)

Such specific features and other advantages of the present invention will become more apparent from the following description of the preferred embodiments with reference to the accompanying drawings.

3 to 5, the evaporator E is a tube zigzag-shaped tube T which vaporizes the liquid refrigerant introduced from the condenser (not shown) by heat exchange with air and sends it to a compressor (not shown). A plurality of heat transfer fins (F) for facilitating heat exchange of the refrigerant to each other are arranged at regular intervals along their longitudinal direction so as to be orthogonal to the tube (T), and the side plates for protecting them on both sides of the heat transfer fins (F) ( S) is composed of each combined.

On the surface of the evaporator (E), that is, the surface of the tube (T) and the heat transfer fins (F), since a large amount of condensed water (W) is generated by moisture in the air cooled when the air conditioner is driven, appropriate drainage measures are required.

To this end, in the present invention, a drain pan (D) for collecting condensed water (W) generated from the evaporator (E) is installed at the bottom of the evaporator (E), and the condensate (W) collected on the bottom surface of the drain pan (D). The drain hose (H) for discharging to the outside is connected. In addition, according to a characteristic of the present invention, a predetermined position in the vertical direction of the evaporator E, for example, in the middle part thereof, separately collects only the condensed water W generated in the upper part of the evaporator E, so that the outer surface of the side plate S is separated. Drain guide (G) leading to the horizontal is installed in the horizontal direction so as to cross each heating fin (F) and the side plate (S). Accordingly, each of the heat transfer fins F and the side plate S are separated into two parts so as to be respectively positioned above and below the drain guide G.

Meanwhile, the drain guide G of the present invention collects a part of the condensate W and guides the drain pan D through the side plate S. Preferably, the collected condensate W is easy. It is properly inclined so as to be drained to guide the condensed water (W) collected only on the outer surface of any one side plate (S). However, the evaporator E is coupled to the heat fins (F) and the side plate (S) to the plurality of U-shaped pipes (P) of the tube (T) arranged side by side, adjacent to each pipe (P) The tip is configured by interconnecting the return band (B), it is preferable that the production drain guide (G) is configured to be inclined downward toward the return band (B).

The drain guide G of the present invention has a plate shape in which a plurality of flow paths C for guiding the flow of the condensate water W are formed in the longitudinal direction on the upper surface of the body M for easy drainage of the collected condensate water W. It is comprised, The flange (N) (N) which extends upwards is formed in the both ends of the width direction, respectively, for preventing the overflow of the condensate (W). Accordingly, the drain guide (G) is preferably composed of corrugated (coruugate) type plate, as shown in the width, it will be preferable that the width is larger than the width of the heat transfer fin (F).

The condensate drainage structure of the air conditioner of the present invention configured as described above has condensate (W) generated from the upper portion of the drain guide (G) of the condensate (W) generated on the surface of the evaporator (E). Flows down the first and collected in the drain guide (G) and then collected by the side pan (S) to the drain pan (D), the condensate (W) generated from the lower portion of the heat transfer fin (F) ), It flows down and is collected directly in the drain pan (D).

On the other hand, the condensate (W) collected in the drain guide (G) flows down to the side plate (S) by the inclination thereof, in which the condensate (W) is guided to the flow path (C) of the drain guide (G) very smoothly Guided to the outer side of the side plate (S).

As a result, the condensed water W generated at the upper portion of the drain guide G is blocked and does not flow down to the lower portion of the drain guide G. Therefore, concentration of the condensed water W at the lower end of the evaporator E is effectively prevented. Therefore, the water bridge phenomenon caused by the concentration of the condensed water (W) between the heat transfer fins (F) as in the prior art is not generated, it is possible to heat exchange with a sufficient amount of air.

On the other hand, the present invention has been described as having only one drain guide G, but this is merely for the purpose of illustration, the present invention is not limited to this, a plurality of drain guide (G) according to the size of the evaporator (E) ) May be arranged at regular intervals.

As described above, according to the present invention, since the condensed water generated on the surface of the evaporator when the air conditioner is driven is collected in at least two places, the water bridge phenomenon generated at the lower end of the evaporator according to the concentration of the condensate as in the prior art is effectively prevented. As a result, uniform heat exchange with a sufficient amount of air is performed on the whole of the evaporator, and of course, it is possible to reliably drain the generated condensate. Therefore, the present invention has an excellent effect of greatly improving the cooling performance and reliability of the air conditioner.

Claims (5)

Zigzag-shaped tubes connected to the compressor and the condenser, respectively, in which refrigerant flows, and a plurality of plate-shaped heat transfer fins arranged to be orthogonal to the tubes and positioned on both outer sides of the heat transfer fins to promote heat exchange of the refrigerant. In the evaporator of the air conditioner having a side plate coupled to the tube, The one side plate by collecting the condensed water (W) generated by the evaporator (E) located in the horizontal direction inclined in the horizontal direction to traverse the heat transfer fins (F) at a predetermined position in the vertical direction of the evaporator (E) At least one drain guide G leading to an outer surface of S; A drain pan (D) installed below the evaporator (E) to collect condensed water (W) generated from the evaporator (E), Condensate drainage structure of the air conditioner, characterized in that it comprises a drain hose (H) connected to the drain pan (D) to discharge the collected condensate (W) to the outside. The method of claim 1, Condensate drainage structure of the air conditioner, characterized in that a plurality of flow paths (C) for guiding the drainage of the condensate (W) collected on the upper surface of the drain guide (G) is formed in the longitudinal direction. The method of claim 2, Condensate drainage structure of the air conditioner, characterized in that the drain guide (G) is composed of a corrugated plate. The method according to claim 2 or 3, Condensate drainage structure of the air conditioner, characterized in that the flange (N) is formed to prevent the overflow of the condensate (W) collected at both ends of the width direction of the drain guide (G). The method of claim 1, The heat transfer fin (F) and at least one side plate (S) is condensed water drainage structure of the air conditioner, characterized in that a plurality of separation is configured so as to be located respectively on the upper and lower sides around the drain guide (G).