KR200241490Y1 - Condensate receiver structure of indoor air conditioner - Google Patents

Abstract

The condensate receiving structure of the indoor unit of the separate type air conditioner according to the present invention has a condensate receiving part disposed under the evaporator, and an inlet refrigerant pipe and an outlet refrigerant pipe connected to the heat transfer pipe of the evaporator are provided with a heat insulator installed on the rear side of the case. In the indoor unit of the split type air conditioner which is to come out from the top, characterized in that the guide member is coupled to the lower side of the upper end of the heat insulator so that the condensed water generated in the upper portion of the heat insulator is guided to the condensation part receiver. In this way, the condensate generated on the upper side of the insulator flows into the condensate tray and flows out, so that it does not accumulate on the inner floor of the indoor unit and does not affect the electrical components fixed to the floor. No leakage

Description

Condensate collection structure of the indoor unit of a separate air conditioner.

The present invention relates to a condensate receiving structure of an indoor unit of a separate air conditioner.

1 is a cross-sectional view showing the motor side in the indoor unit of a conventional split air conditioner. As shown, the front panel 12 is coupled to the front side of the case 10, the inside of the front panel 12 is an evaporator that generates heat by heat exchange with the indoor air while the refrigerant flowing therein evaporates ( 14 is coupled, and between the evaporator 14 and the case 10 is coupled a motor 16 for driving a blower to suck air into the evaporator 14.

The motor 16 is accommodated in the support 18 formed integrally with the case 10, and is fixed by a fastening member (not shown) enclosed by a cover 20 coupled to the other side of the support 18. have.

The motor 16 is to rotate the blower (not shown) coupled to the ground long in the penetrating direction (ie, the longitudinal direction of the indoor unit).

The condensate receiver 22 is provided below the evaporator 14 so as to receive condensate generated by the water in the air being cooled by the evaporator 14 to cool down.

An insulating body 28 is coupled between the support part 18 and the inner wall of the case 10 so as to suppress heat transfer between the inlet refrigerant pipe 24 and the outlet refrigerant pipe 26 connected to the evaporator 14. have.

The inlet refrigerant pipe 24 and the outlet refrigerant pipe 26 come from the upper portion of the heat insulator 28 to be connected to the middle portion of the heat exchanger 14.

In the indoor unit of the conventional split type air conditioner configured as described above, the indoor air passing through the evaporator 14 is exchanged with the refrigerant flowing inside the evaporator 14 to be changed to cold.

At this time, the moisture contained in the indoor air is crushed by the evaporator 14 is cooled and flows into the water or frost is attached to the evaporator (14). The frost on the evaporator 14 is melted by the defrosting operation. The condensate thus produced flows down the evaporator and is collected in the condensate receiver 22.

The condensed water collected in the condensate receiver 22 is discharged to the outside of the indoor unit through an outlet (not shown).

However, in the indoor unit of the split type air conditioner configured as described above, moisture in the air that does not condense while passing through the evaporator 14 is attached to the inlet refrigerant pipe 24 and the outlet refrigerant pipe 26 coming out of the upper portion of the insulator 28. It will be condensed and fall off.

As such, some of the condensed water falling from the inlet refrigerant pipe 24 and the outlet refrigerant pipe 26 flows into the condensate receiver 22 along the outer surface of the cover 20, but the rest of the condensate water is supported by the support part 18. Along the inner rear side of the case 10 is accumulated on the inner bottom of the indoor unit, affects the electrical components fixed to the bottom, there was a problem that the condensate leakage from the coupling portion of the case to the outside.

Therefore, the present invention is devised to solve the above problems, an object of the present invention is to prevent the condensate falling from the upper side of the indoor unit does not accumulate on the floor and prevent the leakage of condensate in the case of the indoor unit of the air conditioner To provide a condensate receiver structure.

1 is a cross-sectional view across the combined motor side of the indoor unit of the conventional split air conditioner,

Figure 2 is a perspective view showing an indoor unit of a separate air conditioner to which the present invention is applied;

3 is a cross-sectional view of an embodiment of the present invention according to arrow A-A in FIG.

4 is an elevation view showing the guide member of FIG.

Figure 5 is a cross-sectional view according to another embodiment of the present invention shown along the arrow A-A line in FIG.

<Description of the symbols for the main parts of the drawings>

30: case 32: front panel

38: evaporator 40: motor

42: condensate receiving 44: insulator

46: inlet refrigerant pipe 48: outlet refrigerant pipe

50: support 52: cover

56: heat transfer pipe 58: fixture

60: bend portion 64, 72: guide member

66: plate portion 68: rib portion

70: groove 74: locking groove

76: slope 78: frangipani

Condensed water receiving structure of the indoor unit of the separate type air conditioner according to the present invention made to achieve the above object is a condensate receiving part is disposed in the lower part of the evaporator, the inlet refrigerant pipe and the outlet refrigerant pipe connected to the heat pipe of the evaporator of the case In the indoor unit of the separate type air conditioner, which is to come out from the inside of the insulator installed on the rear side, the guide member is provided under the upper end of the insulator so that the condensate generated in the upper portion of the insulator is guided to the condensation part receiver. It is characterized by being coupled.

A rib is formed upward in the guide member, and an end portion of the rib is caught by the heat transfer tube of the evaporator, and the guide member is fixed.

A locking portion is formed at an upper end of the support part, and a locking groove is formed at a lower end of the guide member, and the locking groove may be locked to the locking part to fix the guide member.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view showing the indoor unit of the separate air conditioner to which the present invention is applied. As shown, the front panel 32 is coupled to the front side of the case 30 to form the exterior of the indoor unit, and a blower not shown along the longitudinal direction is coupled to the inside of the indoor unit, and the right side of the blower The motor mentioned later which drives this blower is combined.

The front side of the front panel 32 is formed with an intake opening 34 through which the indoor air is sucked, and the bottom surface of the front panel 32 has an evaporator through which the indoor air sucked through the suction opening 34 is described later. While changing to cold, the discharge port 36 for discharging back to the room is formed.

As shown in FIG. 3, an inside of the front panel 32 is coupled to an evaporator 38 which generates heat by heat exchange with indoor air while the refrigerant flowing therein is evaporated. The evaporator 38 and the case are coupled to each other. Between the 30 is coupled a motor 40 for driving a blower to suck air into the evaporator 38.

The condensate receiver 42 is provided below the evaporator 38 so as to receive condensate generated by the water in the air being cooled by the evaporator 38 and cooled.

An insulator 44 is coupled upwardly between the motor 40 and an inner wall of the case 30, and an inlet connected to the evaporator 38 in the insulator 44. The refrigerant pipe 46 and the outlet refrigerant pipe 48 pass through.

The case 30 has a support part 50 for receiving and fixing the motor 40 to the upper side and is integrally coupled to the case 30, and covers 52 to cover and fix the motor 40 accommodated in the support part 50. ) Is coupled to the support 50. The cover 52 and the support part 50 are coupled to each other by a fastening member (not shown) and coupled to the side of the case 30.

The front panel 32 is detachably coupled to the case 30.

The evaporator 38 has a plurality of fins 54 in a bent shape consisting of an oblique upper portion and a lower portion vertically arranged at predetermined intervals in a direction penetrating the ground. The heat transfer pipe 56 penetrates and forms the refrigerant pipe path.

At this time, the oblique upper portion of the fin of the evaporator 38 is longer than the vertical lower portion. This is because the inlet port of the front panel 32 is formed to be biased on the upper side, it is a configuration for increasing the heat transfer area closer to the inlet port.

The inlet refrigerant pipe 46 and the outlet refrigerant pipe 48 come from the top of the heat insulator 44 and are connected to the heat transfer pipe in the middle of the evaporator 38.

A drain port (not shown) is formed in the condensate receiver 42, and a drain pipe is connected to the drain port, and condensate is discharged to the outside through the drain pipe.

The heat insulator 44 is made of a known heat insulator, and a fastener 58 is coupled to an upper portion thereof to fix the inlet refrigerant pipe 46 and the outlet refrigerant pipe 48. The fastener 58 is a known bundle band or the like.

The inlet refrigerant pipe 46 and the outlet refrigerant pipe 48 are raised upward along the inside of the heat insulator 44, and then bent horizontally out of the upper end of the heat insulator 44 and then in the evaporator 38. It extends obliquely downward along the upper side and then communicates with the heat transfer tube in the middle of the evaporator 38.

The support part 50 encloses the right semicircular part of the motor 40, and the upper end part is formed with the bent part 60 bent to the said insulator side. The cover 52 encloses the left semicircle of the motor 40, and the guide protrusion 62 is obliquely formed at the middle part of the cover 52 to guide the condensate falling from the upper side of the evaporator 38 to the condensate receiver 42. It is.

Then, the lower end of the upper end of the heat insulator 44 so that the condensed water generated in the inlet refrigerant pipe 46 and the outlet refrigerant pipe 48 at the upper portion of the heat insulator 44 is guided to the condensation part receiver 42. Guide member 64 is coupled to.

4 is an elevation view showing the guide member 64 separately. 3 and 4, the guide member 64 extends from the upper position of the cover 52 to the upper right side to cover the upper side of the bent portion 60, and then the And a plate portion 66 connected to the lower end of the upper portion, and the rib portion 68 is formed on the upper side of the plate portion 66 so that the end portion of the rib portion 68 is caught by the heat pipe 56 of the evaporator 38. The guide member 64 is fixed. An opening groove 70 is formed in the upper portion of the rib 68 that is caught by the heat pipe 56.

In the indoor unit of the separate type air conditioner according to the embodiment of the present invention configured as described above, when the motor 40 is driven by operating an operation unit (not shown), the blower connected to the motor 40 rotates, and the suction port 34 is rotated. Through the indoor air is introduced into the indoor unit.

The indoor air passing through the suction port 34 passes through the evaporator 38 and exchanges heat with the refrigerant flowing in the evaporator 38 to be changed to cold. At this time, the moisture contained in the indoor air is crushed by the evaporator 38 and cooled to flow into the water or frost is attached to the evaporator 38. The frost on the evaporator 38 is melted by the defrosting operation. The condensate thus produced flows down the evaporator and collects in the condensate receiver 42.

On the other hand, the moisture in the air that does not condense while passing through the evaporator 38 is condensed and dropped to the inlet refrigerant pipe 46 and the outlet refrigerant pipe 48 coming from the upper portion of the heat insulator 44, The condensate flows down the plate portion of the guide member 64 and the cover 52 and is collected in the condensate receiver 42.

The condensed water collected in the condensate receiver 42 is discharged to the outside of the indoor unit through a drain not shown.

5 is a cross-sectional view showing a condensate receiving structure of an indoor unit of a separate air conditioner according to another embodiment of the present invention.

As shown, in this embodiment, the locking groove 74 is provided in the lower portion of the guide member 72, the locking groove 74 is caught by the bent portion 60, the guide member 72 is fixed It is. An inclined surface 76 is formed at the upper end of the guide member 72 so that condensed water can easily flow down. The flange 78 protruding upward is formed on the heat insulation side of the guide member 72 so that the condensate does not fall to the heat insulation side.

The configuration of the guide member is simple because it does not need a separate rib is mounted directly.

According to the condensed water receiving structure of the indoor unit of the separate air conditioner according to the present invention, all the condensed water falling from the inlet and outlet refrigerant pipe passing through the upper side of the evaporator flows into the inside of the condensed water receiver and flows out along the drainage outlet. Does not accumulate on the interior floor of the indoor unit, condensate does not affect the electrical components fixed to the floor, and condensate does not leak out from the joint of the case.

Claims (1)

In the indoor unit of the separate type air conditioner, the condensate receiver is disposed in the lower part of the evaporator, and the inlet refrigerant pipe and the outlet refrigerant pipe connected to the heat transfer pipe of the evaporator are discharged upward from the inside of the insulator installed on the rear side of the case. Under the upper end of the heat insulator, a guide member for receiving the condensate generated in the upper portion of the heat insulator to guide the condensation part receiving, The guide member has a rib extending upward, the end of the rib condensed water receiving structure of the indoor unit of the separate type air conditioner, characterized in that the groove formed in the opening groove that is caught on the heat pipe.