KR100487380B1 - structure for draining condensing water in the air conditioner - Google Patents

Abstract

The present invention relates to an air conditioner, and more particularly, to a condensate drainage structure of a combined air conditioner.

To this end, the present invention is installed in the case in which the air intake passage and the discharge passage is intersected therein, the suction passage and the discharge passage is installed in the intersection, the first passage portion and suction in communication with the discharge passage therein A total heat exchanger each having a second flow path communicating with the passage, a compressor, an expansion device, and four sides provided in the case, first and second heat exchangers respectively provided in the suction passage and the discharge passage, and the suction passage And a first and second blower fan installed in the discharge passage, respectively, wherein the bottom surface of the case corresponds to the lower portion of the first and second heat exchangers and has a predetermined width and is directed toward one side. Each of the condensate receiving grooves is formed to be inclined to be lowered, and is connected to one side of the condensate receiving groove, and the outdoor side is indoors over the entire case bottom surface. A condensate drainage path having a lower inclination than the side and having a predetermined width is formed, and a condensate drainage hole is formed in a portion formed at the lowest end of the outdoor side of the condensate drainage path in a vertical downward direction to the bottom surface. Of the condensate drainage structure.

Description

Structure for draining condensing water in the air conditioner

The present invention relates to an air conditioner, and more particularly, to a condensate drainage structure of a combined air conditioner.

Hereinafter, a conventional heating and cooling system of an air conditioner will be described with reference to FIG. 1.

Referring to FIG. 1, the air-conditioning / heating system for a ventilation system includes a compressor 11 for compressing a refrigerant, a four-sided valve 12 installed at a discharge side refrigerant pipe of the compressor to switch a flow direction of the refrigerant according to an operation mode, and The first and second heat exchangers 13 and 14 for condensing or evaporating the refrigerant introduced by switching sides, and a refrigerant pipe between the first and second heat exchangers, An expansion device (15) for expanding the refrigerant discharged from any one of them, an electrothermal exchanger (20) installed between the first and second heat exchangers, and a first and second blower fan (16) installed near the electrothermal exchanger (16). And 17).

The first flow path part 21 and the second flow path part 22 are formed in the electrothermal heat exchanger 20 so as to indirectly exchange heat while passing indoor air and outdoor air. Here, the first channel portion 21 and the second channel portion 22 are formed independently so as not to communicate with each other.

The pre-heat exchanger 20 is formed by alternately layering the first flow path portion 21 and the second flow path portion 22 as a plurality of winding bent plate as shown in FIG. In this case, the first flow path part 21 and the second flow path part 22 are formed substantially perpendicularly.

Here, the plate is formed of a material having excellent thermal conductivity, such as aluminum, so that the indoor and outdoor air passing through the heat exchanger is mutually heat exchanged.

The heat exchanger is not limited to the above-described structure, and it is understood that the structure for forming the first and second flow paths inside the heat exchanger may also be variously modified.

On the other hand, the first blower fan 17 is installed on the indoor air suction side or the discharge side based on the total heat exchanger 20, and the second blower fan 18 is the outdoor air suction side on the basis of the total heat exchanger 20. Or on the discharge side.

Therefore, the indoor air sucked by the first blower fan 17 passes through the first flow path part 21 and the first heat exchanger 13 of the total heat exchanger 20 sequentially, and then is discharged to the outside. At the same time, the outdoor air sucked by the second blower fan 17 passes through the second flow path part 22 and the second heat exchanger 14 of the total heat exchanger 20 in sequence and then discharges it into the indoor space. do.

In this process, the indoor air and outdoor air pass through the heat exchanger 20 to indirectly perform heat exchange, and the thermal energy of the indoor air is recovered by a predetermined amount by the outdoor air. That is, the air passing through the total heat exchanger is introduced into the second heat exchanger 14 in a state where the temperature is lower when cooling and the temperature is higher when heating.

Referring to the operation of the combined ventilation and heating system configured as follows.

The combined ventilation air conditioning system is operated in a heating / cooling mode or a ventilation only mode under the control of a controller. The operation mode will be described below.

First, when the air conditioner is cooled, the refrigerant compressed by the compressor 11 sequentially moves the four sides 12, the first heat exchanger 13, the expansion device 15, and the second heat exchanger 14. Flow. At this time, the first heat exchanger 13 functions as a condenser and the second heat exchanger 14 functions as an evaporator.

At the same time, as the first blower fan 16 is rotated, indoor air flows into the first heat exchanger 13 through the first flow path part 21 of the total heat exchanger 20, and the second blower fan ( As the 17 is rotated, outdoor air flows into the second heat exchanger 14 through the total heat exchanger 20.

At this time, the indoor air and the outdoor air is indirectly heat exchanged while passing through the heat exchanger (20), by which the indoor air recovers the heat energy of the outdoor air.

Therefore, the outdoor air passing through the second flow path part 22 of the total heat exchanger flows into the second heat exchanger 14 in a state where the temperature is considerably lower than before entering the total heat exchanger 20. This low temperature outdoor air is cooled once more while passing through the second heat exchanger 14 to become cooler cold air. The cold air is discharged into the indoor space to cool the indoor space to a constant temperature.

In addition, the indoor air passing through the first flow path part 21 of the total heat exchanger 20 flows into the first heat exchanger 13, and the warmer heat exchanged in the first heat exchanger 13 is the compressor 11. After cooling the compressor while passing through it is discharged to the outside.

As such, the dual purpose air conditioner simultaneously cools the outdoor space and cools the indoor space during the cooling operation, thereby simultaneously cooling and cooling the indoor space. Therefore, even when the air conditioner is operated for a long time to cool the indoor space, the indoor air is kept clean and the humidity is kept constant.

Secondly, when the air conditioner is heated, the flow of the indoor air and the outdoor air is the same as in the above-described cooling operation and will be omitted below.

However, the refrigerant of the air conditioner flows in the opposite direction as when the cooling operation is performed. That is, the refrigerant compressed by the compressor 11 performs a refrigerant cycle in which the second heat exchanger 14, the expansion device 15, and the first heat exchanger 13 sequentially flow. At this time, the first heat exchanger 13 functions as an evaporator, and the second heat exchanger 14 functions as a condenser.

Third, when the air conditioning system is operated in a ventilation only mode, the first and second blower fans 16 and 17 are operated and the compressor 11 and the first and second heat exchangers 13 and 14 are stopped. .

Therefore, the outdoor air is sucked into the indoor space after passing through the heat exchanger 20, and the indoor air is discharged to the outside after passing through the heat exchanger 20. In this case, the indoor heat exchanger indirectly heat exchanges the indoor and outdoor air, thereby recovering a predetermined amount of heat energy of the air discharged to the outside. Therefore, the temperature difference of the indoor space is changed relatively even after the ventilation only operation.

However, in the heat exchanger acting as an evaporator, moisture in the air condenses, and the condensate thus generated flows down the lower part of the heat exchanger, so that a structure capable of treating the condensate is required.

In order to solve the above problems, an object of the present invention is to provide a drainage structure for discharging the condensate generated in the heat exchanger.

In order to achieve the above object, the present invention is installed in the case where the air intake passage and the discharge passage is intersected therein, and the suction passage and the discharge passage is installed in the intersection, the first communication with the discharge passage therein A heat exchanger having a flow path portion and a second flow passage portion communicating with the suction passage, respectively, a compressor, an expansion device, and four sides provided in the case, and first and second heat exchangers respectively provided in the suction passage and the discharge passage; In the ventilation and air conditioner comprising a first and a second blower fan respectively installed in the suction passage and the discharge passage, the bottom surface of the case corresponds to the lower portion of the first and second heat exchangers and at the same time a predetermined width It has a slope that is lowered to one side and each condensate receiving groove is formed, is connected to one side of the condensate receiving groove and throughout the case bottom The outdoor side has a lower slope than the indoor side and a condensate drainage path having a predetermined width is formed, and the condensate drainage hole is formed in a portion formed at the lowest end of the one end of the outdoor side of the condensate drainage path in a vertical downward direction to the bottom surface. Provide a condensate drainage structure for a combined air conditioner.

Hereinafter, with reference to the accompanying Figures 2 and 3 with respect to the combined ventilation air conditioner according to the present invention.

Referring to FIG. 2, the dual purpose air conditioner includes a case 30 forming an external appearance and a dual air conditioning / heating system installed inside the case 30.

A duct 31 is installed in the case 30 to cross the suction passage 33 and the discharge passage 32. In addition, the air suction parts 32a and 33a and the discharge parts 32b and 33b are disposed on one indoor side surface and one outdoor side surface of the case 30 so as to correspond to end portions of the suction passage 33 and the discharge passage 32. Are each formed.

And, the louver is installed in the discharge portion 33b of the one side of the indoor side to be rotatable. The louver constantly adjusts the discharge angle of the air discharged to the indoor space through the suction passage 33 in the air conditioning mode or the ventilation only mode of the air conditioner.

The heat exchanger 40 is installed at a portion where the discharge passage 32 and the suction passage 33 of the duct 31 cross each other. The first heat exchanger part 41 communicating with the discharge passage 32 and the second flow passage portion 42 communicating with the suction passage 33 are formed in the heat exchanger 40. The first flow path part 41 and the second flow path part 42 are formed independently so as not to communicate with each other.

The total heat exchanger 40 is formed by alternately layering the first flow path part 41 and the second flow path part 42 as a plurality of windingly curved plates are stacked as shown in FIG. 3. The first and second flow path parts 41 and 42 are formed substantially vertically.

Here, the plate is preferably formed of a material having excellent thermal conductivity such as aluminum so that indoor air and outdoor air heat exchange indirectly.

Meanwhile, a compressor 51, four sides, first and second heat exchangers 52 and 53, and an expansion device (not shown) are installed in the case 30, which will be described below.

A compressor 51 for compressing a refrigerant is installed in the case 30, and four sides (not shown) are installed in the discharge side refrigerant pipe of the compressor 51. The four sides performs a function of switching the flow direction of the refrigerant in accordance with the cooling and heating mode operation.

At this time, the compressor 51 is preferably installed on the air discharge side of the discharge passage (32). This is to improve the operating performance of the compressor 51 by allowing the compressor 51 to cool before the indoor air is discharged to the outside.

The first heat exchanger 52 is installed at the air discharge side of the discharge passage 32 based on the total heat exchanger 40, and the second heat exchanger 53 has the suction passage 33 based on the total heat exchanger 40. Is installed on the air discharge side.

An expansion device (not shown) is installed in the refrigerant pipe between the first and second heat exchangers 52 and 53. The expansion device expands the refrigerant discharged from any one of the first and second heat exchangers 52 and 53 according to the air conditioning operation of the air conditioner.

In addition, a first blowing fan 54 is installed in the discharge passage 32, and a second blowing fan 55 is installed in the suction passage 33. In this case, the first blowing fan 54 is installed on the suction side or the discharge side of the indoor air of the first flow path part 41, and the second blowing fan 55 is the suction side or the discharge side of the second flow path part 42. Is installed on.

Accordingly, the first blower fan 54 discharges the heat-exchanged indoor air to the outside while passing through the first flow path part 41 and the first heat exchanger 52 of the total heat exchanger 40, and the second blower fan. The fan 55 discharges the heat-exchanged outdoor air into the indoor space while passing through the second flow path part 42 and the second heat exchanger 53 of the total heat exchanger 40.

An auxiliary suction part 34 is formed between the total heat exchanger 40 and the second heat exchanger 53 at the bottom of the case 30, and selectively opens and closes the auxiliary suction part and the discharge passage near the auxiliary suction part. Opening and closing device 34a is installed. The opening and closing device is composed of an opening and closing plate and a motor device.

The opening and closing device 34a closes the auxiliary suction part 34 in the ventilation / heating / heating mode or the ventilation only operation, and opens the auxiliary suction part 34_ and closes the suction passage 33 in the air-conditioning only mode. Let's do it.

As such an air conditioner is operated in a ventilation / cooling / heating mode or an air conditioning mode, moisture in the air condenses on the surface of the heat exchanger serving as an evaporator.

In order to process the condensate generated in this way, a condensate receiving groove 35 is formed on the bottom surface of the case 30 so as to correspond to the lower portions of the first and second heat exchangers 52 and 53, respectively, It is connected to the condensate receiving groove 35 and a condensate drainage passage 36 having a predetermined slope in the indoor and outward directions is formed.

The condensate drainage path 36 is preferably formed such that the outdoor side has a lower slope D1 <D2 than the indoor side, so that the condensate drained from the condensate receiving groove 35 smoothly flows to the outdoor.

The condensate drain 36 may be installed on one side or both sides of the bottom surface.

In addition, the condensate receiving groove 35 is formed to have a low inclination (D3 <D4) of the condensate drainage path side, it is preferable to allow the condensate to be discharged smoothly in the case (30).

In such a condensate drainage structure, a condensate drainage hole 36a is formed at one end of the outdoor side of the condensate drainage passage 36. The drain hose 37 is connected to the condensate drain hole 36a. In addition, the drain hose 37 may be connected to a condensate collector (not shown).

The operation of the dual purpose air conditioner having such a structure will be described.

The air conditioner is operated in a ventilation / heating / heating mode, a ventilation-only mode, or a heating / heating-only mode.

When the air conditioner is operated in the ventilation / cooling and heating mode, one of the first and second heat exchangers 52 and 53 functions as an evaporator and the other functions as a condenser. In addition, the opening and closing device 34a closes the auxiliary suction part 34.

At this time, the indoor air is sucked into the discharge passage 32, passes through the total heat exchanger 40, the first heat exchanger 52 and is discharged to the outside. At the same time, the outdoor air is sucked into the suction passage 33 and passed through the total heat exchanger 40 and the second heat exchanger 53 and then discharged into the room.

When the air conditioner is operated in the ventilation only mode, the compressor 51 and the first and second heat exchangers 52 and 53 are stopped, and the opening and closing device 34a closes the auxiliary suction part 34.

In this case, the indoor air and outdoor air are the same as in the operation of the ventilation and cooling mode described above will be omitted.

Next, any one of the first and second heat exchangers 52 and 53, in which the air conditioner is operated in a cooling / heating mode, functions as an evaporator and the other function as a condenser. In addition, the opening and closing device 34a opens the auxiliary suction part 34 and closes the suction passage 33. The first and second blowing fans 54 and 55 are both operated.

At this time, the indoor air is sucked into the space between the second heat exchanger 53 and the total heat exchanger 40 of the suction passage 33 through the auxiliary suction unit 34, and then in the second heat exchanger 53 After heat exchange, it is discharged back to the indoor space.

When such an air conditioner is operated in a ventilation / cooling / heating mode or an exclusive mode for cooling / heating, moisture in the air condenses in the heat exchanger serving as the evaporator. The condensate thus generated flows down the surface of the heat exchanger and falls to the condensate receiving groove 35.

The condensate flows into the condensate drainage path 36 along the condensate receiving groove 35 having a predetermined width and slope, and then flows to the outdoor side by the inclination of the condensate receiving groove 35. Subsequently, the condensed water reached to the outdoor side of the condensate receiving groove 35 is introduced into the condensate drain hose 37 through a drain hole 36a formed vertically downward on the bottom surface. Accordingly, it is possible to treat the condensate generated in the air conditioner.

As described above, the condensate drainage structure of the air conditioner according to the present invention has an effect that can smoothly discharge the condensate by forming a predetermined width and inclination in the condensate drainage.

In addition, by forming a predetermined width and inclination in the condensate receiving groove to facilitate the discharge of the condensate, it is possible to prevent the condensate is accumulated in the air conditioner.

1 is a perspective view showing a heating and cooling system of a conventional air-conditioning combined air conditioner.

Figure 2 is a perspective view showing a dual-use air conditioner in the present invention.

3 is a perspective view showing the condensate drainage structure of FIG.

Explanation of symbols on the main parts of the drawings

30: case 31: duct

32: discharge passage 32a: suction part

32b: discharge part 33: suction passage

33a: suction part 33b: discharge part

34: auxiliary suction part 35: condensate receiving groove

36: condensate drainage passage 36a: drainage hole

37: drain hose 40: heat exchanger

41: first euro part 42: second euro part

51 compressor 52: first heat exchanger

53: second heat exchanger 54: first blower fan

55: second blowing fan

Claims (5)

 A case having an air suction passage and an discharge passage intersecting therein, and a first passage portion installed at a portion where the suction passage and the discharge passage cross each other, and having a first passage portion communicating with the discharge passage and a second communication portion with the suction passage; A total heat exchanger having a flow path portion formed therein, a compressor, an expansion device and four sides installed in the case, first and second heat exchangers respectively provided in the suction passage and the discharge passage, and installed in the suction passage and the discharge passage, respectively. In the combined use air conditioner comprising a first and a second blowing fan, The bottom surface of the case corresponds to the lower portion of the first and second heat exchangers and has a predetermined width and has an inclination lowering to one side, and condensate receiving grooves are formed, respectively, and are connected to one side of the condensate receiving groove. The condensate drainage path having a lower slope than the indoor side is formed in a predetermined width over the entire floor surface, and a condensate drainage hole is formed in a portion vertically downwardly formed on the bottom of the outdoor end of the condensate drainage path. Condensate drainage structure of the dual-purpose air conditioner, characterized in that. delete The method of claim 1, The condensate drainage structure of the combined air conditioning unit, characterized in that installed on one side or both sides of the bottom surface. delete delete