KR102481303B1 - Window type air-conditioner having condensate dry function - Google Patents

Abstract

The present invention relates to a window type air conditioner including a condensate drying function, and to a window type air conditioner including a case, an evaporator installed indoors within the case, a condenser installed outdoors within the case, an evaporator fan, and a condenser fan. The condensate receiver disposed under the condenser and accommodating the condensate falling from the evaporator; A pump installed in the condensate receiver; a condensate container installed above the condenser and having a first outflow hole formed at the bottom thereof; a hose connecting between the pump and the condensate container; and a condenser bracket installed between the condenser and the condenser container and having a second outlet hole formed at a position communicating with the first outlet hole.
Accordingly, while cooling the condenser while the condensate flows downward through the inside of the upper part of the condenser, it evaporates by itself, so that the condenser can be cooled more easily and the condensate can be treated naturally without a hose exposed to the outside. .

Description

Window type air conditioner with condensate drying function {WINDOW TYPE AIR-CONDITIONER HAVING CONDENSATE DRY FUNCTION}

The present invention relates to a window type air conditioner including a condensate drying function, and more particularly, to a condensate drying unit capable of simultaneously drying the condensate and cooling the condenser by mechanically supplying condensate generated in an evaporator and accommodated in a condensate receiver to a condenser. It relates to a window type air conditioner that includes a function.

The recent window type air conditioner has a structure in which the indoor unit (evaporator) and the outdoor unit (condenser) are integrally built into the case, and a window frame installation frame installed on the window is separately included, so users other than professional engineers can easily install it directly. it is possible

In particular, since the rear surface of the air conditioner facing the outdoors does not protrude through the outer wall, when installed on the double-glazed window frame, there is an advantage in that the outer window can be closed when not in use.

On the other hand, since the window type air conditioner is directly installed on the window frame or window, when a hose for discharging condensate generated from the evaporator to the outside is connected, not only must an additional configuration to prevent interference between the hose and the window, but also the condensate Since the hose protrudes to the outside to be discharged, there was a disadvantage that the appearance was not good.

Korean Patent Publication No. 10-2000-0020818 (2000.04.15)

The present invention has been made to solve the above-mentioned problems of the prior art, and the object of the present invention is to evaporate the condensate by absorbing the condensate that has fallen from the evaporator through a pump and flow it to the surface of the condenser, while simultaneously cooling the condenser to achieve cooling efficiency It is to provide a window type air conditioner that includes a condensate drying function that can further increase the performance.

In order to achieve the above object, a window type air conditioner according to the present invention includes a case, an evaporator installed indoors within the case, a condenser installed outdoors within the case, an evaporator fan, and a condenser fan. in
a condensate tray disposed under the condenser and accommodating the condensed water falling from the evaporator;
A pump installed in the condensate receiver;
Installed on the upper part of the condenser, a temporary accommodation groove for accommodating condensed water, an inlet communicating with the temporary accommodation groove and protruding along the width direction at one side of the condenser in the width direction of the condenser, and a bottom of the temporary accommodation groove. A condensate container including a first outflow hole formed;
a hose connecting between the pump and the inlet of the condensate container; and,
a condenser bracket installed between the condenser and the condenser water container;
Including,
It is characterized in that the piping pipe of the condenser is coupled to the bottom of the temporary receiving groove of the condensate container in a state where it passes through the condenser bracket.

The height of the center of the inlet is characterized in that formed higher than the height of the upper end of the pipe.

When viewed from a plan view, it is characterized in that a step portion is formed along the width direction on the other side of the condensate container facing the inlet.

When viewed from a plan view, a plurality of the first outlet holes are spaced apart from each other along the width direction of the condenser, and are biased toward the outdoor surface of the condenser.

The condensate container has an inlet protruding outward at one side along the width direction of the condenser, a temporary accommodation groove is formed on the inside, and the first outlet hole and the condenser pipe are formed on the bottom surface forming the temporary accommodation groove. It is characterized in that a through hole is formed through which the curved end of the pipe passes.

One side of the temporary accommodation groove where the inlet of the condensate container is formed includes a horizontal guide, a curved guide and a vertical guide so that the condensate discharged through the inlet can naturally flow toward the other side of the floor by a drop in height. Characterized in that the discharge guide is formed.
A discharge guide groove is formed on the upper surface of the horizontal guide part so that the condensed water discharged through the inlet can be stably discharged in a straight direction.

The circumference of the bottom surface of the condensate container is configured to extend downward from the bottom surface, so that the bottom surface is spaced apart from the top surface of the condenser bracket in a state in which the lower circumference of the condensate container is in close contact with the upper surface of the condenser bracket characterized by
Water detachable parts are formed on both sides of the condensate container in the thickness direction, respectively,
It is characterized in that the detachable arm parts are formed on both sides of the condenser bracket in the thickness direction, respectively.

A rib extending in a direction crossing the outflow direction of the hose is disposed inside the condensate container.

It is characterized in that a water level sensor for detecting the level of the condensate is installed in the condensate receiver.

According to the present invention having the configuration as described above, by configuring the condensate container and the condenser bracket to form the first outlet hole and the second outlet hole, respectively, at the top of the condenser, in the process of condensate flowing downward through the inside of the top of the condenser. As it cools the condenser, it evaporates itself.

Therefore, there is an advantage in that the condenser can be cooled more easily and condensed water can be treated naturally without a hose exposed to the outside.

In addition, by forming a condensate outlet in the condenser bracket, condensed water can be discharged outward in the thickness direction of the condenser, so that the cooling efficiency of the condenser can be further improved.

In addition, the condensate container and the condenser bracket constitute a detachable and detachable part and a detachable arm, thereby providing convenience for maintenance work and the condensate container flowing in the longitudinal direction of the condenser bracket or vertically. can prevent doing so.

In addition, by disposing a rib inside the condensate container, when the condensate is shockingly introduced, it may be guided in a direction where the first outlet hole is located without crossing the first outlet hole.

In addition, by forming a discharge guide in the condensate container, the condensate discharged through the inlet provides an effect of imparting kinetic energy so that the condensed water naturally flows from the height drop to the other side of the floor surface.

1 is a front perspective view showing a window type air conditioner according to the present invention.
2 is a rear perspective view showing a window type air conditioner according to the present invention.
3 is a side cross-sectional view showing a window type air conditioner according to the present invention.
4 is an internal perspective view showing the main internal configuration of the window type air conditioner according to the present invention.
5 is a perspective view showing the configuration and coupling structure of the condensate container and the condenser bracket in FIG. 4;
6 is an exploded perspective view of FIG. 5 .
FIG. 7 is a plan view and cross-sectional view of FIG. 5 .
8 is a perspective view illustrating a water level sensor installed in the condensate receiver of FIG. 4 .

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

As shown in Figures 1 to 3, the window type air conditioner 1000 according to the present invention. A case 100, an evaporator 200 installed on the indoor side within the case 100, a condenser 300 installed on the outdoor side within the case 100, a condenser fan 800 and an evaporator fan (900).

In particular, as shown in FIGS. 4 to 7, the window type air conditioner 1000 according to the present invention includes a condensate receiver 120 for accommodating condensate falling from the evaporator 200 at the bottom of the case 100 and , The pump 130 installed in the condensate receiver 120 and. A hose connected between the condensate container 400 installed on the top of the condenser 300 and having a first outlet hole 410 formed at the bottom, and the pump 130 and the inlet 430 of the condensate container 400. 500 and a condenser bracket 600 installed between the condenser 300 and the condensate container 400 and having a second outlet hole 610 formed therein.

According to this configuration, the condensate received in the condensate receiver 120 by the pump 130 flows into the condensate container 400 through the hose 500 and the condenser bracket ( 600), and flows again to the condenser 300 through the second outlet hole 610.

In particular, according to the present invention, the condensate flowing into the condensate container 400 falls down through the first outlet hole 410, and then the second outlet hole 610 of the condenser bracket 600 located below and Through the condensate discharge port 630, the condensed water flows both inside and outside the condenser in the thickness direction, thereby cooling the condenser 300 more effectively.

The first outlet hole 410 and the second outlet hole 610 may be formed in plurality along the longitudinal direction of the condensate container 400 and the condensate bracket 600. Since it can be quickly discharged through the hole 410 and the second outlet hole 610, cooling efficiency for the inside of the condenser 300 can be increased.
As shown in FIG. 7 (a), when viewed from a plan view, a plurality of first outlet holes 410 are spaced apart along the width direction of the condenser 300, and the seal of the condenser 300 It may be arranged biased towards the outer surface.

Of course, the falling condensate evaporates itself while cooling the high-temperature condenser 300 .

Inside the condensate container 400, a rib 420 extending in a direction transverse to the outflow direction of the hose 500 is disposed to prevent the first outlet hole 410 when condensate is shockingly introduced. It can be guided in the direction where the plurality of first outlet holes 410 are located without crossing.

Even if only one rib 420 is formed, a certain degree of effect can be exerted, but a plurality of ribs 420 can be manufactured if conditions for stabilizing the flow of condensate and increasing the speed of discharge are met.

When viewed from a plane, the rib 420 may form a right angle with respect to the flow direction of the condensed water, but may form an acute angle or an obtuse angle so as to have optimal discharge efficiency for guiding to the first outlet hole 410.

Specifically, the condensate container 400 has an inlet 430 protruding outward on one side along the width direction of the condenser 300, and a temporary receiving groove 401 in which the rib is formed is formed inside.

That is, the inlet 430 is combined with the hose 500 to serve to introduce condensed water, and the temporary receiving groove 401 is a space provided to temporarily accommodate condensed water.

A through hole 411 through which the first outflow hole 410 and the curved end of the piping pipe 390 of the condenser 300 pass is formed on the bottom surface where the temporary receiving groove 401 is formed.
In this case, the height of the center of the inlet 430 is formed higher than the height of the upper end of the piping pipe 390.

In particular, on one side of the temporary accommodation groove 401 where the inlet 430 of the condensate container 400 is formed, the condensate discharged through the inlet 430 can naturally flow from the height drop to the other side of the bottom surface. A guide 440 is formed.

When viewed from a front cross-sectional view, the discharge guide 440 is preferably formed as a curved surface curved from top to bottom.
That is, as shown in FIG. 7(b), the discharge guide 440 may include a horizontal guide part 445, a curved guide part 446, and a vertical guide part 447.

In addition, on the upper surface of the horizontal guide part 445 constituting the discharge guide 440, the discharge guide groove ( 441) is formed.

In addition, the bottom surface of the condensate container 400 is located on the upper side spaced apart from the upper surface of the condenser bracket 600, and the circumferential lower end of the condensate container is supported on the upper surface of the condenser bracket 600 in a surface-contact state.

In addition, on both sides of the condensate container 400 in the thickness direction, detachable and detachable parts 450a and 450b are formed that are detachably coupled to the condenser bracket.

The detachable and detachable parts 450a and 450b facilitate the mutual detachable coupling between the condensate container 400 and the condenser bracket 600 to provide convenience for easier maintenance such as internal cleaning, as well as the inlet 430 It is possible to prevent the condensate container 400 from flowing in the longitudinal direction of the condenser bracket 600 or flowing vertically due to the hydraulic pressure of the condensed water introduced through the condenser bracket 600 .
When viewed from a plan view, a step portion 480 is formed on the other side of the condensate container 400 facing the inlet 430 along the width direction.

Meanwhile, the condenser bracket 600 is installed between the condenser 300 and the condensate container 400, and a second outlet hole 610 is formed at a position communicating with the first outlet hole 410.

The second outlet hole 610 discharges the condensed water into the inner space of the condenser 300 to increase the cooling effect of the condenser 300 and the evaporation efficiency of the condensed water.

Specifically, the condensate generated by the evaporator 200 is moved to the condensate container 400 at the top of the condenser 300 by the pump 130, and the condensate in the condensate container 400 passes through the first outflow hole 410. It flows into the condenser bracket 600, and at this time, the condensed water moves to the aluminum plate (cooling fin) of the condenser 300 through the second outflow holes 610 located on the plane of the condenser bracket 600. At this time, the cold condensed water spreads evenly on the heated aluminum plate surface, and naturally evaporates and cools, improving the heat dissipation efficiency.

Among the condensed water spread evenly on the plane of the aluminum plate, the condensed water that has not evaporated naturally moves downward through the slotting part of the aluminum plate in sequence, cooling the aluminum plate in the same way and naturally evaporating the condensed water.

The condenser bracket 600 includes a bottom member 601 installed on the top of the condenser 300, a first side member 602 bent from one side in the width direction of the bottom member 601 and erected upward, It consists of a second side member 603 bent from the other side in the width direction of the bottom member 601 and standing upright.

When viewed from the side, the condenser bracket 600 has a channel-type structure with an open top.

A pipe hole 620 through which the second outlet hole 610 and the piping pipe 390 of the condenser 300 pass is formed in the bottom member 601 .

Since the condenser bracket 600 has a structure in which the piping pipe 390 of the condenser 300 passes through the piping hole 620, it is stably fixed to the top of the condenser 300 without using a separate fastening configuration. can be maintained as

In particular, a condensate outlet 630 for discharging condensate to the outside in the thickness direction of the condenser 300 is formed on the bent surface where the bottom member 601 and the first side member 602 are connected, and the second side member ( 603), an open space 640 is formed by breaking a part in the longitudinal direction so that a fastening action between the male attachable and detachable part and the arm attachable and detachable part to be described later can be easily performed.

That is, the condenser bracket 600 forms a condensate outlet 630 so that the condensed water can be discharged to the outer surface in addition to the second outlet hole 610, so that both the inside and outside of the condenser 300 can be discharged. Since the condensed water can be discharged, the cooling efficiency of the condenser 300 can be further improved.

The condensate outlet 630 preferably extends long from the bent surface in the direction toward the inside of the bottom member 601 and the first side member 602, and the condensate outlet extending to the first side member 602 ( 630), it is preferable to form the length of the space of the condensed water outlet 630 extending to the floor member 601 longer.

In addition, the first side member 602 and the second side member 603 are formed with respective detachable arm portions 650a and 650b that are detachably coupled to the condensate container 400 in a complementary manner.

On the other hand, the condenser fan 800 and the evaporator fan 900 have a cylindrical exterior that extends vertically in structure, and outdoor air flows through the second suction part 160 together with the operation of the condenser fan 800. The condenser 300 is cooled while the condenser 300 is discharged through the second discharge unit 170, and the air in the room moves through the first suction unit 140 to the first discharge unit 150 along with the operation of the evaporator fan 900. As it comes out, the inside of the case 100 is cooled.

As shown in FIG. 8 , a pump 130 generating mechanical pressure to move the condensed water to the top of the condenser 300 is installed in the condensate receiver 120 .

In addition, a water level sensor 700 for detecting the level of condensate is installed in the condensate receiver 120.

That is, when the water level sensor 700 reaches a certain level so that the condensate collected in the condensate receiver 120 does not overflow to the outside, the pump 130 is driven to move the condensate to the upper part of the condenser 300, and then the condensed water is transferred to the condenser. It flows down along the longitudinal direction of the condenser 300 to cool the condenser 300, and serves to sense the level of condensed water so that evaporation can be made.

In addition, since the condenser fan 800 is located in the area of the condensate receiver 120, indirect cooling of the condenser fan 800 by the condensate received in the condensate receiver 120 is possible.

As shown in FIG. 3 , in this case, a guide passage 110 for guiding the condensed water falling from the evaporator 200 to the condensate receiver 120 where the condenser fan 800 is disposed may be installed.

The embodiments of the present invention are merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible within the scope of the claims below.

100... case
120... condensate tray
130... pump
200... evaporator
300... condenser
400... condensate container
401... temporary housing unit
410... first outflow hole
420... rib
430... inlet
440... discharge guide
500... hose
600... condenser bracket
610... second outflow hole
700... water level sensor
800... condenser fan
900... evaporator fan
1000... window air conditioner

Claims (8)

In a window type air conditioner including a case, an evaporator installed indoors within the case, a condenser installed outdoors within the case, an evaporator fan, and a condenser fan,
a condensate tray disposed under the condenser and accommodating the condensed water falling from the evaporator;
A pump installed in the condensate receiver;
Installed on the upper part of the condenser, a temporary accommodation groove for accommodating condensed water, an inlet communicating with the temporary accommodation groove and protruding along the width direction at one side of the condenser in the width direction of the condenser, and a bottom of the temporary accommodation groove. A condensate container including a first outflow hole formed;
a hose connecting between the pump and the inlet of the condensate container; and,
a condenser bracket installed between the condenser and the condenser water container;
Including,
A window type air conditioner, characterized in that coupled to the bottom of the temporary receiving groove of the condensate container in a state where the piping pipe of the condenser passes through the condenser bracket. According to claim 1,
A window type air conditioner, characterized in that the height of the center of the inlet is formed higher than the height of the upper end of the pipe. According to claim 1,
When viewed from a plan view, a window type air conditioner characterized in that a step portion is formed along the width direction on the other side of the condensate container facing the inlet. According to claim 1,
When viewed from a plan view, a plurality of first outlet holes are spaced apart from each other along the width direction of the condenser, and the window type air conditioner is biased toward the outdoor surface of the condenser. According to claim 1,
One side of the temporary accommodation groove where the inlet of the condensate container is formed includes a horizontal guide, a curved guide and a vertical guide so that the condensate discharged through the inlet can naturally flow toward the other side of the floor by a drop in height. Window type air conditioner, characterized in that the discharge guide is formed. According to claim 5,
A window type air conditioner, characterized in that a discharge guide groove is formed on the upper surface of the horizontal guide part so that the condensed water discharged through the inlet can be stably discharged in a straight direction. According to claim 1,
The circumference of the bottom surface of the condensate container is configured to extend downward from the bottom surface, so that the bottom surface is spaced apart from the top surface of the condenser bracket in a state in which the lower circumference of the condensate container is in close contact with the upper surface of the condenser bracket A window type air conditioner characterized in that. According to claim 7,
Water detachable parts are formed on both sides of the condensate container in the thickness direction, respectively,
The window type air conditioner, characterized in that the detachable arm parts are formed on both sides of the condenser bracket in the thickness direction, respectively.

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