KR840002206B1 - Drain system of air conditioning - Google Patents

Abstract

The air conditioner comprises a body with air channels and an evaporator in the first air channel for cooling the air passing through. A drain tray is disposed below the evaporator for receiving dew drops formed on the evaporator and falling from it and for containing the drain. A second drain tray below the first receives dew drops formed on the first drain tray and falling from it the drain overlowing the first tray. The second air channel is defined between the drain trays.

Description

Drain Dish Structure of Air Conditioner

1 is a side cross-sectional view showing an example of the drain dish structure of a conventional air conditioner,

2 is a partial front view showing an embodiment of the drain dish structure of the air conditioner according to the present invention;

3 is a partial side cross-sectional view showing an embodiment of the drain dish structure of FIG.

Figure 4 is a side cross-sectional view showing another embodiment of the drain dish structure of the air conditioner according to the present invention,

5 is a partial perspective view of FIG. 4,

6 is a side cross-sectional view showing another embodiment of the drain dish structure of the air conditioner according to the present invention;

7 is a partial perspective view of FIG. 6,

8 is a side cross-sectional view showing another embodiment of the drain dish structure of the air conditioner according to the present invention;

9 is a partial perspective view of FIG. 8,

10 is a side view showing another embodiment of the drain dish structure of the air conditioner according to the present invention;

11 is a cross-sectional view along the line A-A showing the back of FIG.

12 is a partial perspective view of FIG. 10;

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drain pan structure of an air conditioner, and in particular, a drain pan is formed into a double structure having a space therebetween, and the drain is formed into an air passage through which air that does not pass through the evaporator passes through the drain. It relates to a drain pan structure of an air conditioner which is heated above a temperature.

In an air conditioner, a drain pan is provided in order to receive the drain falling from the evaporator and to store it. However, since the temperature of the drain is low, there is a problem that dew forms on the outer surface of the drain plate and the outer circumferential surface of the drain discharge hose. On the other hand, the drain pan 1 and the drain discharge hose 2 were conventionally covered with the heat insulating material 3 as shown in FIG. That is, (4) is an evaporator mounted near the air outlet (5), the air sucked in the inlet (7) by the operation of the blower (6), the drain below the drain to store the drain once The pan 1 is provided, and the drain pan 1 is connected with a drain discharge hose 2 for guiding the drain in the drain plate 1 to the outside of the air conditioner. The drain plate 1 and the drain discharge hose 2 were covered with the heat insulating material 3 to prevent dew from forming around them.

However, since the carbon material 3 is bulky, it hinders the miniaturization of the air conditioner. Also, in the drain discharge hose 2, the diameter of the hose is increased due to the heat insulator 3, and therefore, for outdoor discharge. The holes formed in the walls tend to grow naturally, and the installation work becomes complicated.

In addition, coating the heat insulating material 3 on the drain pan 1 and the drain discharge hose 2 is cumbersome in manufacturing and has a defect in terms of cost.

The present invention was devised to solve these problems effectively, and an object of the present invention is to heat the drain falling from the evaporator above the dew point temperature to discharge it to the outside, thereby miniaturizing the air conditioner without using an integral insulation material. It is to provide a drain dish structure of an air conditioner capable of achieving sufficient energy savings.

In order to achieve the above object, the present invention is to provide a drain passage of the upper and lower stages in the lower edge of the evaporator to form an air passage for passing the indoor air that does not pass through the evaporator and the heat exchanger does not pass through the evaporator. By focusing on the heating of the drain by the indoor air is to complete this.

Embodiments of the present invention will be described below with reference to the accompanying drawings.

In FIG. 2 and FIG. 3, (5) is an air outlet and the evaporator 4 is attached in the vicinity, and the blower 6 is provided above the evaporator 4. In FIG. Near the bottom of the evaporator 4, a first drain plate 8 is provided to receive the drain falling from the evaporator 4. The first drain pan 8 is provided with a hole 9 for appropriately draining the accumulated drain downward, and a second drain pan 10 is provided below the first drain pan 8 to provide a hole. The drain falling from (9) is received and flows to the drain discharge hose (2). The space 11 formed by the upper surface of the second drain plate 10 and the lower surface of the first drain plate 8 allows drainage of the indoor air sucked through the blower 6 without passing through the evaporator 4. An air passage 11a is formed to allow the heat to be released to the outside while heating. The drain discharge hose 2 is arranged to discharge the drain accumulated in the second drain dish 10 to the outside of the air conditioner and to the outside.

12 is a drain guide panel for guiding the drain generated inside the front panel to the second drain plate 10, 13 is a wind direction variable element, and 14 is a wind direction adjusting grill. , (15) is a double auxiliary pipe.

Hereinafter, the operation of the present invention will be described.

When the blower 6 is operated, most of the air sucked from the room is cooled while passing through the evaporator 4 and is discharged from the air outlet 5 through the wind direction adjusting grill 14. A portion of this air, that is, air that does not pass through the evaporator 4, is discharged to the room through the air passage 11a formed by the lower surface of the first drain plate 8 and the upper surface of the second drain plate 10. . In this state, the drain falling from the evaporator 4 is collected in the first drain dish 8 and then flows out through the hole 9 and is collected in the second drain dish 8 and then flows out through the hole 9. The second drain pan 10 is once stored, and then flows into the drain discharge hose 2 and is discharged to the outside. Also, as shown in FIG. 4, the dew condensed on the frame supporting the evaporator 4 is separated along the guide around the outlet 5 in the direction of the dotted line arrow, leading to the second drain plate 10. do. At this time, since the uncooled air flows through the air passage 11a, the lower side of the first drain plate 8 and the upper surface of the second drain plate 10 are heated above the dew point temperature due to the air. Due to the temperature difference between the upper and lower sides, dew forms on the lower surface of the first drain plate 8 and falls, but the dew is heated and received on the second drain dish 10. In addition, the drain accumulated on the first drain pan 8 falls from the hole 9 but is also collected on the second drain pan 10 while being heated. In addition, since the drain on the second drain pan 10 is also heated, and the temperature difference between the upper and lower surfaces of the second drain pan 10 is reduced, dew is prevented from occurring on the lower surface of the second drain pan 10. Moreover, since the drain which flows into the drain discharge hose 2 from the 2nd drain pan 10 is heated and it becomes more than dew point temperature, dew does not form on the outer peripheral surface of the drain discharge hose 2. In addition, while the drain flowing into the second drain plate 10 along the guide panel 12 is heated in the same manner, the drain is discharged to the outside through the drain discharge hose 2. Therefore, the outer surface insulation of the flow path which receives and discharges a drain becomes unnecessary completely. As a result, the drain discharge hose 2 may use a small diameter, and accordingly, a hole to be drilled in the wall in order to discharge into the jade or the occupied area of the drain discharge hose 2 on the back of the air conditioner. The size of the air conditioner can be reduced, the space occupied by the drain plate can be saved, and the air conditioner can be miniaturized, thinned, and the installation work can be promoted. In addition, since the cooling loss discharged as the conventional cooling water is lost, it is a substantial energy saving measure.

Incidentally, the present invention is not limited to the above embodiment, but also includes the one shown in FIG. In this case, except that the first drain plate 8 is formed with a slit-shaped hole 9 having a passage amount appropriate to the drain amount flowing out of the evaporator 4 as shown in detail in FIG. Same as the above embodiment. By forming the holes 9 in this way, the drain overflowing the first drain pan 8 can be treated and the heating effect of the drain falling from the first drain pan 8 to the second drain pan 10 can be improved. have. In addition, the size of the outlet 16 of the air passage 11a is set in consideration of the flow rate of air so that the drain can be heated above the dew point temperature.

In addition, in the present invention, either the first drain plate 8 or the second drain plate 10 may be combined with the main body of the air conditioner. In addition, all of them may be incorporated into the main body by assembling separate parts. On the contrary, an integrated configuration by vacuum molding or the like is also possible.

In addition, according to another embodiment of the present invention, in order to further improve the heating effect of the drain, fins protruding into the air passage 11a may be provided on the lower surface of the first drain plate 8. That is, as shown in FIGS. 6 and 7, the fins 17 are provided at the lower portions of the first drain plates 8 at equal intervals or only in part thereof, so that the drains are formed along the fins 17. 10) and air is heated on the pin (17). As a result, the temperature of the drain that is completely heated on the pin 17, which is the drain flowing down from the first drain dish 8 to the second drain dish 10, is collected on the second drain dish 10. It becomes possible to heat enough above temperature. In addition, the pins 19 may be lengthened so that the first drain plates 8 and the second drain plates 10 are connected to the pins 17 as shown in FIGS. 8 and 9. In this case, the strength between the first drain plate 8 and the second drain plate 10 can be improved beyond the effect of the above embodiment. Further, according to the present invention, either the first drain plate 9 or the second drain plate 10 may be integrally formed with the thick plate of the air conditioner main body. For example, as shown in FIGS. 10, 11, and 12, the first drain pan 8 is provided with a plurality of reinforcing ribs 19 on the inner side of the rear plate 18 of the air conditioner body. By shaping the rear part of the body into a human body, the entirety of the first drain pan 8 can be integrally formed with the thick plate 18 so that the strength of the first drain pan 8 supporting the evaporator 4 can be improved. The second drain plate 10 is fixedly mounted to the rear plate 18 with screws 20 and is connected to the lower part of the first drain plate by screwing or pinching.

The cavity portion between each rib 10 is a flow path for passing air that has not passed through the evaporator 4 to the air passage 11a formed of the first and second drain plates 8 and 10. ). In addition, the side plate 21 at the rear plate 18 functions as a drain inlet plate as well as a partition plate between the bearing chamber and the cooling chamber, so that dew attached to the inner surface of the side plate 21 is first drained. We relax with dish (8). Alternatively, the second drain plate 10 may be integrally formed with the thick plate 18 instead of forming the first drain plate 8 with the thick plate 18. The strength at the fixed portion with the thick plate 18 can be improved.

As apparent from the above description, the present invention has the following effects.

(1) Since the drain plate is not required to be insulated, the air conditioner can be miniaturized, and the structure is simple, so that the production is easy.

(2) Since the insulation of the drain discharge hose is not required, the air conditioner can be thinned. In addition, at the time of installation, since the hole for the drain discharge hose of the wall is at least minimized, coordination of the installation operation of the air conditioner and aesthetic improvement after installation are achieved.

(3) Since low-temperature energy is recovered from the discharged drain, it can contribute to energy saving.

(4) The air that drains from the first drain dish to the second drain dish can be effectively heated by forming a slit-shaped hole having a water wave amount corresponding to the drain amount falling from the evaporator to the first drain dish. And the drain discharged can be completely heated above the dew point temperature.

(5) The heating effect of the drain can be further improved by providing fins protruding into the air passage on the lower surface of the first drain pan.

(6) By connecting the first and second drain plates with a pin, the heating effect of the drain and the strength can be improved.

(7) Either the first drain dish or the crab 2-drain dish is integrally formed with the rear plate of the air conditioner body so that its strength can withstand the weight of the evaporator.

(8) Since the structure of the drain plate and the drain discharge hose can be configured without using a heat insulator, there is an excellent effect of improving the manufacturability and reducing the cost.

Claims (1)

In the air conditioner in which the indoor air introduced from the inlet 7 through the blower 6 passes through the evaporator 4 mounted near the azeotropic outlet 5, and heat exchanges, the evaporator at the lower edge of the evaporator 4. The 1st drain pan 8 for receiving the drain falling from (4) is provided, The 2nd drain pan 10 is provided in the lower space of this 1st drain dish 8 at predetermined intervals, and the 1st A drain pan structure of an air conditioner, characterized in that the space between the drain pan (8) and the second drain pan (10) is an air passage (11a) for introducing air that has not passed through the evaporator (4).

Images