KR20070010752A - Air conditioner - Google Patents

Abstract

An air conditioner is provided to prevent leakage of condensate to the outer side of the air conditioner by preventing reverse flow of the condensate. An air conditioner includes a heat exchanger, a drain pan, a drain pump, a drain tube, a condensate circulating section, and a reverse flow preventing unit(300). A refrigerant is circulated in the heat exchanger. The drain pan is provided on the lower side of the heat exchanger. The condensate generated by the heat exchange is collected in the drain pan. The drain pump discharges the condensate collected in the drain pan outside. The drain tube is engaged with one end of the drain pump to guide the movement of the condensate. The condensate circulating section is engaged with one end of the drain tube and functions as a passage for the condensate discharged outside. The reverse flow preventing unit is provided in the interior of the condensate circulating section to prevent reverse flow of the condensate.

Description

Air Conditioner {Air conditioner}

1 is a schematic perspective view showing an indoor unit provided in a general air conditioner according to the prior art.

Figure 2 is a schematic partial cutaway view showing an indoor unit provided in a conventional air conditioner according to the prior art.

Figure 3 is a perspective view showing a state in which the front grill of the indoor unit employing an embodiment of the preferred air conditioner according to the present invention is rotated.

Figure 4 is an exploded perspective view showing the internal configuration of an indoor unit employing an embodiment of a preferred air conditioner according to the present invention.

5 is a partially enlarged view showing a fastening part that is a main part configuration of an indoor unit in which an embodiment of a preferred air conditioner according to the present invention is employed.

Figure 6 is an enlarged view showing the backflow prevention means that is the main configuration of the indoor unit employing an embodiment of a preferred air conditioner according to the present invention.

Explanation of symbols on the main parts of the drawings

100. Indoor unit 110. Front panel

112. Discharge port 114. Discharge vane

116. Discharge louver 118. Step motor

120. Front Grill 122. Air Suction Hole

124. Locking Holes 126. Locking Device

128. Display unit 130. Air filter

140. Cabinet 150. Heat exchanger

160. Crossflow fans 162,164. Fan Mount

170. Fan motor 172. Motor mounting part

200.Drain pump 220.Drain tube

240. Fastener 240 '. Fastener

242. Hose connection part 244. Tube connection part

244 '. Tube Jam Jaw 244 ". Flow Bump

246. Fastening plate 246 '. Screwman

248. Condensate Water 260. Drain Pan

300. Backflow prevention measures 320. Orifice

340. Poppet 342. Head section

344. Piston section

The present invention relates to an air conditioner in which backflow of condensate generated by a temperature difference of a heat exchanger is prevented.

As the income level of air conditioners increases recently, demand for air conditioners increases, and demand for air conditioners increases to create a more comfortable and comfortable environment even in hot weather.

In general, the air conditioner is a device for maintaining the indoor air in the most optimal state according to the purpose, by cooling the room by the repeated action of taking in the hot air in the room and heat-exchanging it with a low temperature refrigerant and then discharging it into the room. Appliances for heating a room by means of a negative or negative action.

A series of cycles of such an air conditioner show that a low temperature is formed by evaporation of a compressor providing a high temperature and high pressure gas refrigerant, a condenser providing a high temperature and high pressure liquid refrigerant, and an expansion valve providing a low temperature and low pressure liquid refrigerant. Which consists of an evaporator.

In addition, recently, in addition to cooling and heating, various functions such as an air purifying function of sucking and filtering contaminated air in the room and re-purifying clean air into the room, and a dehumidifying function of making humid air into wet and dry air and re-injecting it into the room Features are being added.

On the other hand, as is well known, the air conditioner is divided into a separate type air conditioner is installed separately from the outdoor unit and the indoor unit, and an integrated air conditioner is installed integrally with the outdoor unit and the indoor unit.

Recently, a multi-type air conditioner has been released that can be effectively applied to install two or more air conditioners in a home or to install an air conditioner in each office in a building having multiple offices. The multi-type air conditioner is installed to achieve the same effect as installing a plurality of separate air conditioners by connecting a plurality of indoor units to a single outdoor unit.

Hereinafter, an indoor unit of a multi-type air conditioner in which demand is recently increasing will be described with reference to the drawings.

1 is a schematic perspective view of an indoor unit provided in a conventional air conditioner according to the prior art, and FIG. 2 is a partial cutaway view of the indoor unit provided in the general air conditioner according to the prior art.

As shown in these figures, looking at the indoor unit of the multi-type air conditioner, the front surface of the indoor unit 10 is formed by the front panel 20, the front grill 30, and the discharge port 40. The front panel 20 is formed in a substantially rectangular plate shape, the front panel 20 is formed with a front grill 30 to prevent the intake of foreign matter when the air in the space for air conditioning is sucked.

In addition, the front grill 30 serves as a passage through which air for air conditioning is sucked into the interior of the indoor unit 10, and a plurality of air suction holes 32 long in the longitudinal direction are cut off. It is formed. The air suction hole 32 guides the air of the space for air conditioning to the interior of the indoor unit 10 by allowing the indoor unit 10 to communicate with the space for air conditioning.

One side of the front grill is formed with a discharge port 40, the harmonized air is discharged to the outside of the indoor unit. The discharge port 40 is formed long in the longitudinal direction of the indoor unit 10, the discharge port 40 is provided with a discharge vane 42 for controlling the direction of the discharged air to discharge the air in the direction desired by the user do.

The cabinet 50 is provided above the front panel 20. The cabinet 50 is shaped into a rectangular box shape having an open lower surface, and a plurality of parts are embedded therein. Although not shown in the cabinet 50, a refrigerant, which is a working fluid, is flowed therein, and a heat exchanger is provided in which heat exchange occurs with air in a space for air conditioning that is sucked through the refrigerant and the front grill 30. .

Although not shown, a drain pan is provided below the heat exchanger. The drain pan is formed by recessing a central portion downward to collect condensate generated while the refrigerant flowing in the heat exchanger and the air sucked through the front grill heat exchange. In addition, the drain pan is formed to have a length corresponding to the length of the heat exchanger so that condensate generated in the heat exchanger does not leak to the outside.

One side of the drain pan is provided with a drain pump 60 for discharging the condensed water collected in the drain pan to the outside of the indoor unit (10). The outlet of the drain pump 60 is provided so that the drain discharge pipe 62 for discharging the condensed water to the outside. The drain discharge pipe 62 is formed upwardly with a predetermined height and then formed through one side surface of the cabinet 50.

When the drain discharge pipe 62 is formed to penetrate one side of the cabinet 50, a drain discharge port 64 is provided at an end portion of the drain discharge pipe 62 protruding to the outside of the cabinet 50. That is, the drain discharge port 64 is formed to communicate with the end of the drain discharge pipe 62. One end of the drain discharge pipe 64 is provided to be fixed to the outer surface of the cabinet 50, and the other end is fastened to the drain hose 66 for guiding condensate to be discharged to the outside.

The drain hose 66 is molded upwards to a predetermined height by a height at which the pump of the drain pump 60 pumps water, and then is formed to have a predetermined downward gradient in a direction in which condensate is drained.

However, the air conditioner according to the prior art as described above has the following problems.

In the conventional configuration as described above, when the air conditioner is operating, the operation of the drain pump 60 is stopped if the power is suddenly cut off due to external factors. As such, when the operation of the drain pump 60 is stopped, the condensed water discharged by the drain pump 60 is connected to the drain discharge port 64 to flow backward along the inside of the drain hose 66 formed upward.

As such, the condensed water flowing back has a problem of being introduced into the air conditioner through the drain pump 60.

Due to condensed water introduced into the air conditioner, the inside of the air conditioner may be placed in a high temperature and high humidity environment, thereby allowing bacteria to grow inside the air conditioner.

In addition, when bacteria are propagated inside the air conditioner, there is a problem in that harmful effects on the health of the user by the propagated bacteria.

In addition, there is a problem that can not be solved by electrical control due to the power is cut off.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to provide an air conditioner having a backflow preventing means in the air conditioner to prevent backflow of condensate.

An air conditioner according to the present invention for achieving the above object is a heat exchanger for flowing a refrigerant as a working fluid therein, a drain pan provided below the heat exchanger to collect condensed water generated by heat exchange, and A drain pump for discharging the condensate collected by the drain pan to the outside, a drain tube having one end coupled to the drain pump to guide the movement of the condensate, and one end of the drain tube being a passage for the condensate discharged to the outside It is configured to include a condensate flow unit and a reverse flow prevention means provided in the condensate flow unit to prevent the back flow of condensate.

The backflow prevention means includes an orifice fixedly formed in the condensate flow unit to guide the flow of condensate, and a poppet formed to penetrate the inner circumferential surface of the orifice to control the flow direction of the condensate.

The poppet is formed so that one surface is formed with one surface of the orifice to control the flow of condensate, and is formed on one surface of the head to control the movement of the head while reciprocating through the interior of the orifice. Characterized in that it comprises a piston.

The outer diameter of the head portion is characterized in that the molded smaller than the inner diameter of the condensate flow.

The poppet is further characterized in that the locking projection for regulating the reciprocating range of the piston portion.

The locking projection is characterized in that formed in a pair on one side of the piston.

The locking projection may be formed to protrude further outward than a radius of the inner circumferential surface of the orifice.

According to the air conditioner according to the present invention having such a configuration, the condensate can be prevented from flowing back into the air conditioner to protect the user, and the maintenance cost and the service cost can be reduced by preventing the damage of parts. There is an advantage.

Hereinafter, the air conditioner configured as described above will be described in more detail.

3 is a perspective view showing a state in which the front grill of the indoor unit employing the preferred embodiment of the air conditioner according to the present invention is rotated, and FIG. 4 is a view of the indoor unit employing the preferred embodiment of the air conditioner according to the present invention. An exploded perspective view showing the internal configuration is shown.

FIG. 5 is a partially enlarged view showing a condensed water flow unit, which is a main component of an indoor unit in which an embodiment of a preferred air conditioner according to the present invention is employed, and FIG. 6 is an indoor unit employing an embodiment of a preferred air conditioner according to the present invention. An enlarged view showing the backflow prevention means which is a main component of the is shown.

Looking at the ceiling indoor unit employing a preferred embodiment of the separate type air conditioner according to the present invention with reference to these drawings, the ceiling indoor unit (100, hereinafter referred to as 'indoor'), the front panel 110 and the discharge port 112, The front surface is constituted by the discharge vane 114, the front grill 120, and the like.

The front panel 110 is formed in a substantially rectangular plate shape, the discharge hole 112 is discharged to the outside of the indoor unit 100, the air harmonized in the interior of the indoor unit 100 to the front side. Discharge vanes 114 are rotatably provided in the discharge ports 112 to control the direction of the discharged air. One side of the discharge vane 114 is provided with a display unit 128 in which operation information of the indoor unit 100 or information for air conditioning is displayed.

A plurality of discharge louvers 116 are provided at the rear side of the discharge vane 114. A plurality of discharge louvers 116 are formed on one axis, and when the shafts reciprocate, the plurality of discharge louvers 116 rotate in the left and right directions. The shaft for rotating the discharge louver 116 is fastened to the step motor 118 provided on one side of the discharge louver 116.

Therefore, the air direction of the air discharged through the discharge port 112 is controlled by the rotation of the discharge louver 116, and the wind direction is controlled again by the rotation of the discharge vane 114. By controlling the wind direction discharged in this way, it is possible to discharge the air in the direction desired by the user.

A central portion of the front panel 110 is formed to be a passage through which air in the space for air conditioning is sucked into the indoor unit 100. An air filter 130 for filtering the air sucked is provided at the center portion of the front panel 110 that is punched out. The air filter 130 filters the fine foreign matter contained in the air sucked into the indoor unit 100.

The air filter 130 is formed to be selectively detachable from the front panel 110, if the cleaning of the air filter 130 is required due to the filtered foreign matter, the air filter 130 can be replaced or washed So that it is formed.

The front grill 120 is provided on the front surface (as seen in FIG. 4) of the air filter 130. The front grill 120 is formed in a substantially rectangular plate shape, a plurality of air suction holes 122 are formed long in the longitudinal direction. The air suction hole 122 is cut in the longitudinal direction is formed so that the interior of the indoor unit 100 is in communication with the room for air conditioning. The air suction hole 122 is formed long in the longitudinal direction is formed a plurality over the front of the front grill (120).

Locking holes 124 through the locking device 126 for fastening and releasing to the front panel 110 when the user rotates the front grill 120 as necessary, the front side both ends of the front grill 120 Perforation is formed.

The cabinet 140 is provided above the front panel 110. The cabinet 140 is inserted into the ceiling and is molded into a rectangular box shape having an open front. The cabinet 140 includes a plurality of components to be described later, for example, a heat exchanger 150, a cross flow fan 160, a fan motor 170, a drain pump 200, a drain fan 260, and the like. .

On the other hand, the upper side of the front panel 110 is formed in the shape of a tube having a predetermined diameter, the heat exchanger 150 is formed as these tubes are bent a number of times. The heat exchanger 150 is formed to communicate with a plurality of pipes so that a refrigerant, which is a working fluid, flows therein.

The heat exchanger 150 may exchange heat with the refrigerant flowing in the inside of the tube while passing the indoor air sucked into the inside of the indoor unit 100 between the tubes having a predetermined diameter bent a plurality of times. The heat exchanger 150 is provided to be inclined so that one side is inclined downward.

As such, one side of the heat exchanger 150 is inclined downward so as to be inclined downward, and a difference in temperature when the air sucked into the interior of the indoor unit 100 from the surface of the heat exchanger 150 and the refrigerant, which is a working fluid, exchanges heat. Condensate is generated. This is to allow the condensed water to flow along the surface of the heat exchanger 150 to the drain pan 260 which will be described later.

The air heat exchanged through the heat exchanger 150 is discharged to the outside of the indoor unit 100 through the discharge port 112 to match the air of the space for air conditioning.

The cross flow fan 160 is provided above the heat exchanger 150. The crossflow fan 160 is a fan assembled by connecting a plurality of fans long and has a feature of circulating air through a wide surface. The cross-flow fan 160 is rotated by receiving the rotational power from the fan motor 170 provided at one end so that the air of the space for air conditioning is sucked into the indoor unit (100).

The fan motor 170 is mounted by the motor mounting unit 172 provided on one side, and is axially coupled with the crossflow fan 160. The crossflow fan 160 is mounted to the fan mounting parts 162 and 164 provided at both end portions thereof, and is installed to be rotatable in a restricted state. That is, the cross-flow fan 160 is fastened to prevent separation from the fan mounting parts 162 and 164 provided at both ends, and the motor mounting part 172 provided at one side of the fan mounting part 164 of the fan mounting parts 162 and 164. ) Is coupled to the fan motor 170 is coupled to receive the rotational power.

On the other hand, one side of the cross flow fan 160 is provided with a drain pump (200). The drain pump 200 is provided to discharge the condensed water generated on the surface of the heat exchanger 150 to the outside of the indoor unit 100.

The heat exchanger 150 generates a temperature difference while the air sucked into the indoor unit 100 and the refrigerant flowing in the heat exchanger 150 exchange heat. As such, condensed water is generated on the surface of the heat exchanger 150 due to the temperature difference generated by heat exchange on the surface of the heat exchanger 150.

The condensed water generated in this way is collected in the drain pan 260 provided below the heat exchanger 150. The drain pan 260 is recessed to form a central portion downward to collect condensate falling along the surface of the heat exchanger 150. The drain pan 260 is formed to a length corresponding to the length of the heat exchanger 150, one end portion is bent backward to extend.

The condensed water collected in the drain pan 260 is discharged to the outside of the indoor unit 100 by the drain pump 200. In order to discharge the condensed water to the outside of the indoor unit 100 by the drain pump 200, one side of the cabinet 140 is fastened to the condensate oil eastern 240 to be described below. In addition, one side surface of the cabinet 140, that is, one side surface on which the drain pump 200 is provided, is formed with a fastening hole 240 ′ coupled to the condensate flow unit 240.

In addition, a drain tube 220 is fastened to the drain pump 200. One end of the drain tube 220 is fastened in communication with the drain pump 200, and the other end is fastened in communication with the tube fastening part 244. The drain tube 220 is formed of a flexible material and is formed to have a predetermined elasticity, and guides the condensed water to a desired space (outside the room).

The condensate flow unit 240 is a passage through which the condensed water collected by the drain pan 260 moves to a desired space (outside the interior). The condensate flow unit 240 is formed so as to communicate with the inside, one end of the tube fastening portion 244 is fastened to the drain tube 220 is formed, the other end of the tube fastening portion 244 is the condensate flow portion Fastening plate 246 is provided so that 240 is fixed to the cabinet 140.

In addition, a hose fastening part 242 to which a drain hose (not shown) to be described later is fastened to the other side of the fastening plate 246. The hose fastening part 242 is fastened to the drain hose to guide the condensate to flow out of the cabinet 140.

That is, the condensate flow unit 240 is formed on one side of the tube fastening portion 244, the other side is formed of the hose fastening portion 242. A fastening plate 246 is formed between the tube fastening part 244 and the hose fastening part 242 so that the fastening plate 246 is screwed to the cabinet 140 so that the condensed water flow part 240 is in the cabinet. It is fixed to 140.

The condensate flow unit 240 is formed with a hose fastening portion 242 is formed in a cylindrical shape having a predetermined diameter. The inside of the hose fastening portion 242 is molded to have a predetermined length in the form of a tube vacant so that condensed water flows. Although not shown, the drain hose is fastened to the outer circumferential surface of the hose fastening part 242.

On the other side of the end of the hose fastening portion 242, that is, the drain hose is fastened to the fastening plate 246 is integrally molded with the hose fastening portion 242. The fastening plate 246 is formed in a substantially square plate shape, and a condensation hole 248 is formed in the center so as to communicate with the hose fastening portion 242 and the tube fastening portion 244.

That is, the hose fastening part 242 is protruded to have a predetermined length laterally at a substantially central portion of the fastening plate 246, one end of the hose fastening part 242 is fastened with a drain hose (not shown) The other end is formed to communicate with the condensation water hole 248 of the fastening plate 246.

In addition, a threaded hole 246 ′ is formed in each corner of each of the fastening plates 246, and is formed such that one side surface of the fastening plate 246 and the cabinet 140 is screwed.

In other words, the other side of the fastening plate 246, the tube fastening portion 244 which is fastened to the drain tube 220 is protruded laterally on the other surface of the surface on which the hose fastening portion 242 is formed. The tube fastening part 244 is formed to have a smaller diameter than the hose fastening part 242, and is formed to communicate with the inner circumferential surface of the condensation hole 248 formed in the center of the fastening plate 246.

The tube catching jaw 244 'protrudes from the center portion of the tube fastening portion 244 in the vertical direction in the direction in which the tube fastening portion 244 is formed along the outer circumferential surface thereof. The tube catching jaw 244 ′ prevents the drain tube 220 from being fastened when the drain tube 220 is fastened in the longitudinal direction along the outer circumferential surface of the tube fastening portion 244. This makes it possible to know the fastening degree of the drain tube 220, thereby reducing unnecessary time in the assembly process and regulating the flow of the drain tube 220.

In addition, a flow preventing jaw 244 "is further formed in the tube fastening portion 244. The flow preventing jaw 244" is bent upwards on the outer circumferential surface of the tube fastening portion 244, and then a predetermined angle goes toward the rear. It is formed to be downwardly gradient to, and the protrusion length bent upward is formed smaller than the tube catching jaw. The flow preventing jaw 244 "is fastened along the flow blocking jaw formed to be gradient when the drain tube 220 is fastened in the longitudinal direction along the outer circumferential surface of the tube fastening portion 244. The drain tube formed of a flexible material By extending the 220 by a protruding length, the drain tube 220 has elasticity in the direction of the inner circumferential surface to prevent flow.

Accordingly, the condensed water flow part 240 is formed with a hose fastening part 242 on one side of the condensing water hole 248 of the fastening plate 246 and a tube fastening part 244 on the other side thereof. The hose fastening part 242, the tube fastening part 244, and the condensate hole 248 are all formed in communication so that the condensed water is discharged from the inside of the indoor unit 100 to the outside.

On the other hand, the inside of the tube fastening portion 244 is provided with a backflow prevention means (300). The backflow prevention means 300 is an orifice 320 fixedly formed inside the tube fastening part 244 and a poppet formed to penetrate the inside of the orifice 320 to control the flow direction of condensate (Poppet, 340). It is composed of

The orifice 320 is fixedly formed on the inner circumferential surface of the tube fastening portion 244 while having a predetermined thickness. The poppet 340 is fastened while penetrating the central portion of the orifice 320. The poppet 340 includes a head part 342 for directly controlling the flow direction of the condensate and a piston part 344 reciprocating through the inner circumferential surface of the orifice 320.

The left side (seen in FIG. 6) of the orifice 320 is shaped to mate with the right side (seen in FIG. 6) of the head portion 342. That is, when the piston portion 344 moves to the right side (as seen in FIG. 6), the right side surface of the head portion 342 and the left side surface of the orifice 320 are molded to be closely formed. .

Looking in more detail, the left side of the head portion 342 is formed into a flat disc shape, extending in the right direction along the circumference of the left side. It is formed to be inclined toward the inner circumferential surface while being formed extending in the right direction. In other words, the cross-sectional area of the head portion 342 is formed to be narrower from the left side to the right side.

The head portion 342 is formed into an arc shape with a predetermined curvature by the cross-sectional area that narrows toward the right side. This curvature is equally applied to the left side of the orifice 320 so that the left side of the orifice 320, that is, the portion closer to the right side of the head 342, has a narrower cross-sectional area of the inner circumferential surface toward the right side. Molded to lose weight.

In addition, the cross-sectional area of the head portion 342 is formed to be narrower than the cross-sectional area of the condensate flow unit 240. This is to allow the condensed water to flow into the space between the outer circumferential surface of the head portion 342 and the inner circumferential surface of the condensate flow unit 240.

In addition, the piston portion 344 is integrally formed from the right side surface of the head portion 342. The piston portion 344 is formed in a cylindrical shape which is inclined substantially vertically, and the diameter of the piston portion 344 is formed smaller than the shortest diameter of the orifice 320 to penetrate the central portion of the orifice 320.

The piston portion 344 is formed to have a predetermined length in the longitudinal direction, and the right end portion of the piston portion 344 has a locking projection 346 for regulating the movement in the left direction of the piston portion 344 in the piston portion. It protrudes outward from the outer peripheral surface of 344.

The locking protrusions 346 are provided in pairs on the upper side and the lower side (as shown in FIG. 6), and the locking protrusions 346 provided on the upper side are formed to have a predetermined thickness in a substantially “┓” shape. The locking projection 346 provided at the lower side is formed to have a predetermined thickness in a substantially “┛” shape.

When the front end surfaces of the locking protrusions 346 are in contact with the right side surface of the orifice 320 and the poppet 340 is moved to the left side, the front ends of the locking protrusions 346 are moved by a predetermined length. In contact with the right side of the 320 is no longer regulated to move the piston portion 344 to the left.

Accordingly, the locking protrusion 346 is preferably formed to protrude more than the radius of the inner circumferential surface of the orifice 320.

Hereinafter, the operation of the air conditioner provided with the backflow prevention means according to the present invention having the configuration as described above.

First, when external power is applied, the fan motor 170 provided on one side of the crossflow fan 160 and axially coupled with the crossflow fan 160 generates rotational power. The rotational power of the fan motor 170 is transmitted to the crossflow fan 160 is fastened by the shaft coupling. The cross flow fan 160 receives the rotational power of the fan motor 170 is rotated, the air of the space for air conditioning is sucked into the indoor unit 100 by the rotation of the cross flow fan 160.

Air in the space for air conditioning sucked by the rotation of the crossflow fan 160 is sucked into the indoor unit 100 while passing through the air suction hole 122 formed in the front grill 120. The air sucked through the air suction hole 122 is removed a relatively large foreign matter, and is filtered to fine foreign matter while passing through the air filter 130.

The air filtered to fine foreign matters exchanges heat with the refrigerant flowing in the heat exchanger 150 while passing through the heat exchanger 150. The air heat-exchanged while passing through the heat exchanger 150 is moved toward the discharge port 112 by the rotation of the cross flow fan 160. The air moved to the discharge port 112 is discharged again into the space for air conditioning while the direction is controlled by the discharge vane 114 and the discharge louver 116. This process is repeated, creating a space for air conditioning in a comfortable environment.

On the other hand, when the air in the space for air conditioning is heat-exchanged with the refrigerant which is the working fluid while passing through the heat exchanger 150, condensed water is generated on the surface of the heat exchanger 150 by the temperature difference. The condensed water flows along the surface of the heat exchanger 150 that is inclined and is collected in the drain pan 260.

In addition, when external power is applied, the drain pump 200 also operates. When the drain pump 200 is operated, the condensed water collected in the drain pan 260 moves through the inside of the drain tube 220 formed to communicate with the drain pump 200. The condensate is discharged to the outside of the indoor unit 100 while passing through the drain hose (not shown) via the condensate flow unit 240.

The condensed water passing through the condensate flow unit 240 passes through the tube fastening part 244, at which time it passes through a backflow prevention means provided in the tube fastening part 244. The backflow preventing means moves the piston part 344 along the flow direction of the condensate by the flow of condensate.

When the piston part 344 moves in the flow direction of the condensate, the head part 342 is spaced apart from the front end surface of the orifice 320. When the head part 342 is spaced apart from the front end surface of the orifice 320, condensed water flows at an interval between the inner circumferential surface of the orifice 320 and the outer circumferential surface of the piston part 344. The condensed water that flows flows along the front end surface from the rear end surface of the head portion 342 having a predetermined curvature and formed into an arc shape.

The condensed water flowing through the backflow prevention means 300 passes through the condensed water hole 248 via the tube fastening portion 244. The condensed water that has passed through the condensed water hole 248 is discharged to the desired place through the drain hose (not shown) via the hose fastening part 242. The drain hose (not shown) is fastened upwardly after being fastened with the hose fastening part 242 and is formed to extend.

Therefore, when the power applied by external influence such as short circuit and short circuit due to power failure or over current is cut off, the operation of the drain pump 200 is stopped, and when the operation of the drain pump 200 is stopped, it is bent upwards. Condensed water that flows inside the drain hose (not shown) that extends to flow backward.

 At this time, the backflow prevention means 300 provided inside the tube fastening part 244 is operated to prevent the backflow of condensate. Looking at the operation of the backflow prevention means 300, the condensate flowing back from the drain hose (not shown) is introduced into the tube fastening portion 244 through the condensate hole 248 through the hose fastening portion 242 do.

The condensed water flowing into the tube fastening part 244 pushes the front end face of the head part 342 to the right by the flow of the flow. When the condensed water pushes the head 342 to the right, the piston 344 moves to the right. The head part 342 is seated on the front surface of the orifice 320 by the movement of the piston part 344 and is in close contact.

As such, when the head part 342 is seated on the front surface of the orifice 320 and comes into close contact, the condensate may no longer flow. As the head portion 342 is seated on the orifice 320, the condensate can no longer flow, thereby preventing backflow of the condensate.

The scope of the present invention is not limited to the above-exemplified embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

According to the air conditioner according to the present invention having the configuration as described above, the back flow of the condensate is prevented when the external power source is cut off. When the backflow of the condensate is prevented, the backflow of the condensate has an effect of not leaking to the appearance of the air conditioner.

In addition, there is an effect that can prevent the growth of bacteria in the interior of the air conditioner that may occur due to the backflow of condensate.

Since it is possible to prevent the growth of bacteria in the interior of the air conditioner in advance, there is an effect that can protect the user by blocking the health harm caused by bacteria.

In addition, there is an effect that can resolve the emotional complaints caused by bacteria.

As the backflow of the condensate is prevented, it is possible to prevent component damage inside the air conditioner due to the backflow of the condensate, thereby reducing the maintenance and service costs of the product.

Claims (7)

A heat exchanger through which a refrigerant, which is a working fluid, flows; A drain pan provided below the heat exchanger to collect condensate generated by heat exchange; A drain pump for discharging condensate collected in the drain pan to the outside; One end is fastened to the drain pump and the drain tube for guiding the movement of condensate, One end of the drain tube is fastened and a condensate flow portion that is a passage of condensate discharged to the outside; The air conditioner is provided in the condensate flow unit, characterized in that it comprises a backflow preventing means for preventing the backflow of condensate. The method of claim 1, wherein the backflow prevention means, An orifice fixedly formed in the condensate flow unit and guiding the flow of condensate; And a poppet which is formed to penetrate the inner circumferential surface of the orifice and controls the flow direction of the condensate. The method of claim 2, wherein the poppet, A head part formed to conform to one surface of the orifice to control the flow of condensate; And a piston part formed on one surface of the head part to control the movement of the head part while reciprocating through the inside of the orifice. The air conditioner according to claim 3, wherein an outer diameter of the head is smaller than an inner diameter of the condensate flow. The air conditioner according to claim 3, wherein the poppet further includes a locking protrusion for restricting a reciprocating range of the piston. The air conditioner according to claim 5, wherein the locking projection is formed in a pair on one side of the piston part. The air conditioner according to claim 4, wherein the locking projection is formed to protrude outwardly from the radius of the inner circumferential surface of the orifice.

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