KR100269446B1 - Air conditioner for cooling and heating - Google Patents

Abstract

PURPOSE: An air conditioner for cooling and heating is provided to enhance drain efficiency of defrost water and to prevent the frost water from being drained out along a frozen surface. CONSTITUTION: Low-pressure refrigerant flows into a condenser(52) from a compressor when a user powers on an air conditioner. The low-pressure refrigerant is heat-exchanged in the condenser, and the surface of the condenser is frozen by cold external air. The ice on the surface of the condenser is molten when the air conditioner is stopped. Defrost water therefrom drops along the condenser and flows toward a slope on the lower face of the condenser. The defrost water drops directly to a base plate(50) without flowing through the lower face of the condenser. The defrost water flows into a drain hole(62) by flowing through a gap between the base plate and the condenser. The defrost water is drained through the drain hole smoothly without resistance against the condenser.

Description

Drainage structure of air-conditioning combined use air conditioner

The present invention relates to a drainage structure of a combined air conditioning and air conditioner capable of draining defrost water generated in a combined air conditioning and air conditioner.

In general, air conditioners used in homes, such as air conditioners, refrigerators, etc. are operated according to the closed cycle refrigeration cycle, the air conditioner is a window type compressor, condenser, capillary, evaporator installed in a single body, compressor and condenser Installed outdoor unit and indoor unit including an evaporator and a blower is divided into a separate type to reduce the installation space and noise.

In particular, an air-conditioning combined use air conditioner which provides heating by providing a reversing valve in the above-described refrigerant line and reversing the circulation path of the refrigerant discharged from the compressor is used.

As shown in FIG. 3, the window type air conditioner, which is provided with the reversing valve and is used for both heating and cooling, has a base plate 50 and an evaporator 51 and a condenser installed to face the upper surface of the base plate 50. (52), a motor (55) installed between the evaporator (51) and the condenser (52) and driving the blower (53) and the outdoor fan (54), the evaporator (51) and the condenser ( 52 and a compressor 57 connected to the refrigerant pipe 56.

In addition, a reversing valve 58 is provided to connect the suction and discharge pipes 56 'and 56 "of the compressor 57, and the case 59 and the front grill 60 to cover the above components. ) Is provided, and a suction duct 61 is provided to suck the indoor air toward the evaporator 51 side.

In the air-conditioning combined air conditioner as described above, the refrigerant discharged at a high temperature and high pressure from the compressor 57 when the user selects cooling is introduced into the evaporator 51 through the condenser 52, and heat is transferred to the outside of the condenser 52. The heat exchange is performed so as to diverge, and the evaporator 51 is heat exchanged to cool the indoor air.

In addition, when the heating is selected, the refrigerant discharged from the compressor 57 is introduced into the condenser 520 through the evaporator 51. In the evaporator 51, heat is dissipated so as to heat indoor air while dissipating heat. In 52, heat is exchanged to cool the outside air.

That is, the role of the condenser 52 and the evaporator 51 is changed at the time of cooling and heating so that the cooling and heating can be combined.

Here, during the cooling, the condensed water is generated in the evaporator 51 by the temperature difference, and the condensed water improves the heat exchange efficiency by the evaporator 51 in the state stored in the base plate 50.

When heating, the surface of the condenser 52 exposed to cold outside air freezes, so that the surface of the condenser 52 is frozen after the operation is stopped for a predetermined time, and defrost water is stored in the base plate 50 during the thawing.

At this time, the defrost water is discharged to the outside because it is frozen by the cold outside air and the cold air heat exchanged in the condenser 52.

To this end, as shown in FIG. 4, a drain hole 62 formed in the base plate 50 to be located at the bottom of the condenser 52, and a cap for cooling the condensed water to be discharged to the drain hole 62 so as to be discharged. Drainage means consisting of 63) are installed.

That is, when cooling, the drain 63 is blocked by the cap 63 so that the condensed water is not discharged to the outside, and during heating, the cap 63 is removed from the drain 62 so that the defrost water is discharged to the outside.

Of course, the cap 63 is coupled and separated by the user by hand.

However, as described above, if the drain hole is formed in the base plate so as to be located at the bottom of the condenser, the gap between the base plate and the condenser is constant as the defrost water is dropped from the condenser, so that it is not only swelling but also freezes in this part. A freeze prevents defrost water from draining smoothly into the drain.

In addition, when the defrosting water is not drained by the drain hole, there is a problem that the ice is frozen between the end portion of the base plate and the condenser, and the defrost water flows out through the freezing surface.

Accordingly, an object of the present invention is to solve the above problems, and to improve the discharge efficiency of the defrost water and drainage structure of the combined air-conditioning and air conditioner that can prevent the defrost water is discharged to the outside along the ice surface In providing.

In order to achieve the above object, the present invention is located in the bottom surface of the condenser and in the drainage structure of the air-conditioning combined air conditioner including a drain hole formed in the base plate, the condenser at a predetermined angle so that the defrost water is concentrated to the drain hole It features a tilted installation.

1 is a perspective view showing a drainage structure of a combined air conditioning and air conditioner according to the present invention,

2 is a side cross-sectional view of FIG. 1,

3 is an exploded perspective view showing a general air-conditioning combined air conditioner.

4 is a cross-sectional view showing a drain hole installation state of the condenser and the base plate in FIG.

* Explanation of symbols for main parts of the drawings

50: base plate 52: condenser

62: drain hole

1 and 2 are a perspective view and a cross-sectional view showing a drainage structure of a combined air-conditioning and air conditioner according to the present invention, and are provided such that a distance between the condenser 52 and the base plate 50 forms a constant angle θ.

That is, when the defrost water flows down during condensation, defrost water is concentrated in the drain hole 62 along the bottom slope of the condenser 52 and the defrost water may flow along the base plate 50 along the interval. This will improve the discharge efficiency of the defrost water.

When explaining the operation and effect of the present invention as described above, a low-pressure refrigerant flows into the condenser 52 from the compressor 57 when the user heats the air conditioner.

When the low-pressure refrigerant flows into the condenser 52, heat exchange is performed in the condenser 52. When the heat exchange is performed, freezing occurs on the surface of the condenser 52 by cold external air, which is a heating operation for a predetermined time. It is melted in the stopped state.

The defrost water in which ice frozen on the surface of the condenser 52 is melted flows down the condenser 52, and the defrost water flows in an inclined direction at the bottom of the condenser 52.

Defrost water flowing down the bottom of the condenser 52 is discharged to the outside by dropping at the drain hole 62 position, defrost water directly falling to the base plate 50 without flowing through the bottom of the condenser 52 is Flowing through the gap between the base plate 50 and the condenser 52 flows into the drain hole (62).

That is, the defrost water flows down the bottom of the condenser 52 inclined toward the drain hole 62 so that the defrost water flows down from the conventional condenser 52 and flows into the drain hole 62. By removing the resistance by the defrost water is discharged to the drain hole 62 more smoothly.

In addition, the defrost water is concentrated to the drain hole 62 position by the inclined angle of the condenser 52, the discharge efficiency is improved compared to the conventional defrost water flows to the entire base plate 50.

As described above, if the defrost water flows down to the drain hole 62 easily by the inclined condenser 52, it is possible to prevent the defrost water from being frozen in the state of the prior art.

When the defrost water is prevented from being frozen, ice formed between the base plate 50 and the condenser 52 is not generated, and defrost water can be prevented from flowing to the outside on the ice surface.

As described above, the present invention has an advantage of improving the discharge efficiency of the defrost water by installing the condenser inclined at an angle with respect to the base plate and preventing the defrost water outflow due to freezing.

Claims (1)

In the drainage structure of the air-conditioning combined air conditioner including a drain hole formed in the base plate and located on the bottom of the condenser, the air conditioner for cooling and cooling is characterized in that the condenser is installed at an angle so as to concentrate the defrost water into the drain hole. Drainage structure of the conditioner.

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