KR20040085965A - The condenser's cooling system of an air-conditioner - Google Patents

Abstract

PURPOSE: A condenser cooling structure of a window-type air conditioner is provided to effectively cool a condenser by approaching sufficiently condensate dispersed by an axial fan to the condenser and equally scattering the condensate to left and right sides of the condenser. CONSTITUTION: A condenser cooling structure of a window-type air conditioner is composed of an evaporator(42) installed in a cabinet(60) to heat-exchange the room air with refrigerant; a condensate tray unit(54) for collecting condensate generated from the evaporator; an axial fan(48) of which an end is sunk in the condensate collected in the condensate tray unit; a condenser(44) for heat-exchanging the outdoor air flowing by the axial fan with the refrigerant; and a condensate guide unit(70) interposed between the axial fan and the condenser to guide the condensate scattered by the rotation of the axial fan to the condenser without dropping the condensate.

Description

The condenser's cooling system of an air-conditioner}

The present invention relates to a condenser cooling structure of a window type air conditioner that cools the condenser by utilizing the condensed water generated in the evaporator of the window type air conditioner. In particular, the condensate scattered by the axial fan is guided to the condenser along the upper surface of the cabinet. It relates to a condenser cooling structure of a window type air conditioner which is cooled by being lowered.

1 is a perspective view showing the configuration of a general window type air conditioner, Figure 2 is a side view showing a condenser cooling structure of the window type air conditioner according to the prior art, Figure 3 is a condenser of the window type air conditioner according to the prior art It is a front view showing a cooling structure.

As shown in FIGS. 1 to 3, the window type air conditioner according to the related art includes a cabinet 2 having an inlet port 2a and an outlet port (not shown) through which outdoor air is sucked / discharged, and a bottom of the cabinet 2. A base panel 3 coupled to the front panel, a front panel 4 coupled to the front surface of the cabinet 2, and having a suction port 4a and a discharge port 4b for suctioning and discharging indoor air, and the front panel 4. E) an evaporator (6) installed inside to exchange heat between the indoor air and the refrigerant, an indoor blower (7) installed at the rear of the evaporator (6) to blow the indoor air, and the indoor blower (7). An air guide 8 installed to surround the air guide 8 to form an intake / exhaust flow path of the indoor air, a shroud 10 spaced apart from the rear of the air guide 8 to guide the flow of outdoor air, and the shra It is installed to be wrapped in the wood (10) and the outdoor side blowing fan (11) for blowing outdoor air, Air condenser 12 installed at the rear of the outdoor blower fan 11 to exchange heat between the outdoor air and the coolant, and between the air guide 8 and the shroud 10 and the indoor blower fan 7. And a biaxial motor 14 connected to an outdoor blower fan 11 for rotating the indoor blower fan 7 and an outdoor blower fan 11, and installed on one side of the biaxial motor 14. 6) and an expansion valve (not shown) and a compressor (16) installed to connect between the condenser (12).

In addition, the lower surface of the cabinet 2 on which the condenser 12 is mounted is provided with condensate receiving means 20 for collecting the condensed water C formed in the evaporator 6.

Here, the axial flow fan 11, as shown in Figure 2, the end portion is disposed with a predetermined gap with the bottom surface of the condensate receiving means 20, the condensate collected in the condensate receiving means 20 during the operation of the air conditioner It is installed to be contained in (C).

Looking at the operation of the prior art configured as described above with reference to Figures 2 and 3 as follows.

When the air conditioner is operated, the refrigerant is circulated along the compressor 16, the evaporator 6, and the condenser 12 while the two shaft motor 14 and the compressor 16 are operated, and the turbo connected to the two shaft motor 14 is provided. As the fan 7 and the axial fan 11 are rotated, the indoor and outdoor air are sucked and discharged into the cabinet 2, respectively.

That is, the indoor air sucked by the turbofan 7 passes through the evaporator 6 and cools and is discharged to the indoor side. During heat exchange, the condensed water C formed on the surface of the evaporator 6 flows down to receive the condensed water. Will be gathered at (20).

On the other hand, the outdoor air sucked by the axial fan 11 passes through the condenser 12, the air condensing the refrigerant while passing through the condenser 12 is discharged to the outdoor.

At this time, the surface temperature of the condenser 12 is increased as the refrigerant circulated in the condenser 12 is heat-exchanged with the air, so that the condenser 12 actively performs heat exchange through smooth heat transfer with external air. In order to lower the surface temperature of the condenser (12).

In order to lower the surface temperature of the condenser 12, the condensed water C collected in the condensate receiving means 20 is utilized. For this purpose, the end of the axial fan 11 is contained in the condensed water C. When the axial fan 11 is rotated, the condensate C is scattered to the upper surface of the outdoor cabinet 2 by the rotational force of the axial fan 11.

The condensed water C scattered on the upper surface of the cabinet 2 by the axial flow fan 8 is moved toward the condenser 12 due to the blowing air generated while the axial flow fan 11 is rotated, and eventually caused by its own weight. The condenser 12 is lowered.

That is, since the temperature of the condensate C is lower than that of outdoor air, the condenser 12 may be kept at a low temperature, thereby improving heat exchange efficiency of the condenser 12.

However, the condenser cooling structure of the conventional air conditioner is lowered by its own weight before being moved to the condenser 12 through the upper surface of the cabinet 2 when the amount of condensed water C scattered by the axial fan 11 increases. The condensate (C) is not sufficiently utilized to cool the condenser 12, the condensate (C) is biased to the left and right one side of the upper surface of the cabinet (2) in the direction in which the axial fan 11 is rotated Since it moves to the condenser 12 and descends, it is difficult to cool both sides of the condenser 12 evenly.

The present invention has been made to solve the above-mentioned problems of the prior art, in the condenser cooling structure of the window type air conditioner to cool the condenser by utilizing the condensate generated in the evaporator, the condensate that is scattered by the axial flow fan is fully condenser The purpose is to ensure that the condensate is efficiently cooled by being evenly sprayed evenly in the left and right directions of the condenser.

1 is a perspective view showing the configuration of a typical window type air conditioner,

Figure 2 is a side view showing a condenser cooling structure of the window type air conditioner according to the prior art,

3 is a front view showing a condenser cooling structure of a window type air conditioner according to the prior art,

4 is a perspective view showing an embodiment of a condenser cooling structure of an air conditioner according to the present invention;

5 is a side view showing an embodiment of the present invention shown in FIG. 4;

6 is a front view showing an embodiment of the present invention shown in FIG.

<Explanation of symbols on main parts of the drawings>

42: evaporator 44: condenser

48: axial fan 52: bulkhead

56: double shaft motor 54: condensate receiving means

58: turbo fan 60: cabinet

70: condensate guide means 74: guide panel

78: guide rib C: condensate

The condenser cooling structure of the window type air conditioner according to the present invention for solving the above problems is an evaporator installed inside the cabinet to exchange heat between the indoor air and the refrigerant, and condensate receiving means for collecting the condensate formed in the evaporator; An axial fan installed so that its end portion is contained in the condensate accumulated by the condensate receiving means, a condenser for exchanging heat from the outdoor air flowed by the axial fan, and a refrigerant provided between the axial fan and the condenser, And condensate guide means for guiding the condensate so that the condensed water scattered by the condensate does not fall while moving to the condenser.

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

Figure 4 is a perspective view showing an embodiment of the condenser cooling structure of the window type air conditioner according to the present invention, Figure 5 is a side view showing an embodiment of the present invention shown in Figure 4, Figure 6 is a view shown in Figure 4 An embodiment of the invention is shown in front view.

4 to 6, the condenser cooling structure of the window type air conditioner according to the embodiment includes a cabinet 60 having partition walls 52 partitioning the interior into an indoor side and an outdoor side, and the cabinet 60. And an evaporator 42 installed at an indoor side of the evaporator to exchange heat between the indoor air and the refrigerant, condensate receiving means 54 formed at an outdoor bottom surface of the cabinet 60 so that the condensed water formed in the evaporator is accumulated, and an end portion thereof. It is installed to be contained in the condensate (C) accumulated in the condensate receiving means 54 and the axial flow fan 48 connected to the biaxial motor 56 installed in the partition 52, and flows by the axial flow fan 48 Condenser 44 for exchanging outdoor air with a refrigerant, and the condensate (C) installed on the upper surface of the cabinet (60) between the axial fan (48) and the condenser and scattered by the rotation of the axial fan (48). Does not fall while moving to the condenser 44 To be composed of condensed water guiding means 70 for guiding the condensed water (C).

Here, the other end of the two-axis motor 56 formed in the partition 52 is installed in the indoor side of the cabinet 60, the turbo fan 58, which is an indoor fan that sucks air into the interior of the cabinet 60 is connected. And disposed behind the evaporator 42.

On the other hand, the condensate guide means 70 is a guide panel 74 is installed on both sides of the upper portion of the cabinet 60 so that the condensate (C) does not fall to the lower side, the guide panel 74 and the cabinet 60 A guide rib 78 formed between the guide ribs 78 to divide a plurality of flow paths through which the condensed water C moves, and downwardly bent at the end of the condenser side of the guide panel 74 so that the condensed water is formed on the condenser 44. It is composed of a drop guide portion 76 to guide the fall.

Since the condensate (C) scattered while the axial fan (48) rotates is biased on one side of the left and right sides according to the rotational direction of the axial fan (48), the guide rib (78) is provided at the inlet portion through which the condensate (C) flows. The spacing is densely formed at one side where the condensate C is biased, and the outlet part through which the condensate C flows out is equally distributed between both sides, and the condensate C biased at one side of the inlet part is guide ribs 78. It is formed to be evenly guided to both sides while moving to the exit along).

Looking at the operation of the present invention configured as described above are as follows.

When the air conditioner is operated, the refrigerant is circulated along the compressor (not shown), the evaporator 42 and the condenser 44 while the two-axis motor 56 and the compressor (not shown) are operated. As the connected turbo fan 58 and the axial fan 48 are rotated, the indoor and outdoor air are sucked and discharged into the cabinet 60, respectively.

That is, the indoor air sucked by the turbo fan 58 is cooled by passing through the evaporator 42 and then discharged to the indoor side. During heat exchange, the condensed water C formed on the surface of the evaporator 52 flows down to receive the condensed water. Are gathered at (54).

On the other hand, the outdoor air sucked to the outdoor side of the cabinet 60 while the axial fan 48 rotates passes through the condenser 44, and the air that condenses the refrigerant while passing through the condenser 44 is discharged to the outside. .

At this time, as the refrigerant circulated in the condenser 44 heat exchanges with air, the surface temperature of the condenser 44 is increased.

On the other hand, the end portion of the axial flow fan 48 is installed to be spaced apart from the bottom of the condensate receiving means 54 by a predetermined distance, as shown in Figure 5, when the axial flow fan 48 rotates the condensate receiving means 54 ) Condensed water (C) is splashed in the direction of rotation of the axial fan 48 is scattered to the upper surface of the cabinet (60).

A portion of the condensed water C scattered on the upper surface of the cabinet 60 by the axial fan 48 is formed on the upper surface of the cabinet 60 due to the blowing air generated while the axial fan 48 rotates. It is moved toward the condenser 44.

When the condensed water C moving along the cabinet 60 falls down due to its own weight, the condensed water C is accumulated in the guide panel 74 connected to both upper sides of the cabinet 60, and then guides to the guide panel 74. Condensate (C) is also stored in the air flows toward the condenser 44 by the blowing of the axial fan (48).

In this way, when the condensate (C) scattered upward by the axial flow fan 48 does not fall during the movement to the condenser 44 reaches the upper side of the condenser 44 by the guide of the guide panel 74 By falling as a ratio most of the condensate C can be used to cool the condenser 44.

In addition, as shown in FIG. 6, when the axial flow fan 48 is rotated in the clockwise direction, the condensate C is biased and accumulated at the left side of the guide panel 74. Since the guide ribs 78 formed on the upper side of the c) are densely formed on the left side, the amount of condensed water C flowing into each flow path partitioned by the guide ribs 78 is almost the same, and the guide ribs 78 are Since the intervals are equally arranged at the outlet portion from which the condensate C flows out, the condensate C flowing out of the upper portion of the condenser 44 is evenly distributed in the left and right directions of the condenser 44.

That is, since the condensate (C) falls evenly to the left and right sides of the condenser 44 by the guide of the guide ribs 78 so that the condenser 44 is evenly cooled to increase the heat exchange efficiency of the condenser 44. Will be.

Condenser cooling structure of the air conditioner according to the present invention configured as described above is provided with a condensate guide means in the upper portion between the axial flow fan and the condenser installed on the outdoor side of the cabinet during the movement of the condensate splashed due to the rotation of the axial flow fan Heat to the condenser by allowing the condenser to reach the condenser along the guide means without falling, and the condensed water scattered on one side of the condenser to fall evenly in the left and right directions of the condenser, thereby cooling the condenser more effectively and evenly. There is an effect that can increase the efficiency.

Claims (4)

An evaporator installed inside the cabinet to exchange heat between the indoor air and the refrigerant; Condensate receiving means for collecting condensate formed in the evaporator; An axial fan installed so that an end portion is contained in the condensate accumulated in the condensate receiving means; A condenser for exchanging heat from the outdoor air flowing by the axial fan with a refrigerant; The condenser cooling structure of the window type air conditioner is provided between the axial flow fan and the condenser and guides the condensate so that the condensate splashed by the rotation of the axial flow fan does not fall while moving to the condenser. . The method of claim 1, The condensate guide means is a condenser cooling structure of the window type air conditioner, characterized in that the guide panel is installed in the upper portion of the cabinet is formed with a flow path of condensate. The method of claim 2, The condensate guide means is formed on the upper side of the guide panel condenser cooling structure of the window air conditioner, characterized in that it further comprises a guide rib for partitioning the flow path into a plurality. The method of claim 3, wherein The guide rib of the window type air conditioner is formed so that one side is densely formed at the inlet of the guide means and evenly distributed toward the outlet to guide the condensed water biased to the left and right sides evenly to the left and right sides of the condenser. Condenser cooling structure.