KR20070069377A - Drain pan structure of indoor unit for air conditioner - Google Patents

Abstract

A drain pan structure of an indoor unit of an air conditioner is provided to form a pump securing part with impurity blocking bosses at a side of a drain pan for preventing introduction of impurities into a drain pump, thereby preventing damage of the drain pump. A drain pan structure of an indoor unit of an air conditioner includes a pump securing part(250) recessed at a side of a drain pan(200) for generating suction force to secure a drain pump(252) which drains condensed water from the drain pan to the outside of the indoor unit. The pump securing part is formed with a plurality of impurity filtering bosses(260) protruded at a periphery in the radial direction for blocking introduction of impurities into the pump securing part. The impurity filtering bosses are integrated into the drain.

Description

Drain pan structure of indoor unit for air conditioner

1 is an exploded perspective view showing the internal configuration of the indoor unit of the air conditioner according to the prior art.

Figure 2 is a longitudinal sectional view showing the internal configuration and the air flow path of the air conditioner indoor unit according to the prior art.

Figure 3 is a bottom perspective view showing the external appearance of the air conditioner indoor unit employing a preferred embodiment of the present invention mounted on the ceiling.

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

5 is a perspective view showing a state in which a heat exchanger is seated on an upper surface of a drain pan which is one component of an indoor unit of an air conditioner employing a preferred embodiment of the present invention.

Figure 6 is a top perspective view showing the drain pan structure of the indoor unit of the air conditioner according to the present invention.

7 is a longitudinal sectional view showing an air flow path when the air conditioner indoor unit of the present invention operates.

Explanation of symbols on the main parts of the drawings

100. Indoor unit 110. Suction grill

112.Suction Inlet 116.Vane

118. Louver 120. Cabinet

122. Cover 130. Blower

132. Fan motors 134. Crossflow fans

134 '. Rotating shaft 136. Air guide

136 '. Airflow Guide 138. Fan Holder

138 '. Seat 138 ". Shield

140. Front panel 142. Outlet

150. Heat exchanger 200. Drain pan

210. Thermal barrier member 220. Filter

230. Through hole 232. Foreign substance adsorption means

234. Support 240. Stabilizer

250. Pump seat 252. Drain pump

260. Jammed Boss 262. Settling groove

The present invention relates to a drain fan of an indoor unit of an air conditioner, and more particularly, to form a foreign matter catching boss for filtering foreign matter on one side of a drain pan for collecting condensed water drained from a heat exchanger to prevent foreign material from entering the drain pump. It relates to a drain fan structure of an air conditioner indoor unit.

An air conditioner is a device for maintaining indoor air in an optimal state according to purpose. For example, when the room becomes hot, such as in summer, the room is cooled by blowing low temperature wind, and in winter, the room is heated by blowing high temperature warm wind.

Such air conditioners are classified into one type and a separate type. The integrated air conditioner is composed of one unit as a whole, and the separate air conditioner is divided into an indoor unit installed in the space for air conditioning and an outdoor unit installed in the outdoor space. In particular, in consideration of noise and the installation environment of the air conditioner, a separate air conditioner (hereinafter referred to as an “air conditioner”) has been preferred.

1 is an exploded perspective view showing the internal configuration of the air conditioner indoor unit according to the prior art, Figure 2 is a longitudinal cross-sectional view showing the internal configuration and air flow path of the air conditioner indoor unit according to the prior art.

As shown in these figures, the indoor unit 1 of the air conditioner is exposed from the ceiling to form most of the exterior, and the suction grill 10 having the inlet 12 formed so that the indoor air is sucked into the indoor unit 1; The cabinet 20 is inserted into the ceiling to keep the indoor unit 1 spaced apart from the floor, and is provided between the cabinet 20 and the suction grill 10 to form a space rearward. It is configured to include a front panel 30 and the like so that the two parts can be mounted.

The suction grill 10 serves as a passage through which indoor air is sucked into the indoor unit 1, and has a substantially rectangular plate shape, and a plurality of suction ports 12 are formed in the lower portion in a horizontal direction at the bottom of the suction grill 10. . The inlet 12 allows the indoor unit 1 and the room for air conditioning to communicate with each other, thereby guiding indoor air into the indoor unit.

More specifically, the rear side of the suction grill 10 is equipped with a plurality of filters (F) in the corresponding rear side of the suction port (12). The filter F is mounted under the front panel 30 to filter the indoor air sucked into the indoor unit 1 through the inlet 12 so that foreign matters are loaded in the indoor unit 1 as well as failure of components. Can be prevented.

On the upper side of the front panel 30 on which the filter F is mounted, a vane 32 having a rectangular plate shape is rotatably mounted. The vane 32 is formed to have a size corresponding to the discharge hole 34 bored in a rectangular shape on the top of the front panel 30 and rotates inside the discharge hole 34 so that the vane 32 is external to the indoor unit 1 through the discharge hole 34. The direction of the discharged air is forced.

And, a louver 36 is mounted to the rear of the vane 32. The louver 36 has a plurality of blades 36 'having a triangular shape formed at regular intervals and rotated left and right to force the flow direction of the air discharged to the discharge port 34 to the left and right.

Therefore, the motor 38 for forcing the rotation of the vanes 32 and the louvers 36 is generally mounted on the left end of the louver 36 by generating a rotational power.

On the other hand, the rear side of the front panel 30 is provided with a drain pan (40). The drain pan 40 has an approximately 'A' shaped longitudinal section when viewed from the rear, and the rear surface is recessed. Therefore, the condensed water generated from the heat exchanger 50 to be described below is accommodated therein.

The pump seat 42 is formed at the lower left front of the drain pan 40. The pump seat 42 is a place where a drain pump (not shown) for draining the condensed water collected in the drain pan 40 to the outside of the indoor unit 1 is seated, and drainage by the drain pump (not shown) is smooth. It is formed to be recessed in a downward direction (as seen in FIG. 2) so as to be made.

More specifically, the pump seat 42 is formed to be positioned at a lower position than the lower surface of the drain pan 40, the condensed water dropped to the upper surface of the drain pan 40 is the most in the pump seat 42 It is first collected.

Therefore, the drain pump (not shown) installed to approach the bottom of the pump seat 42 may drain the condensed water collected in the pump seat 42 to the outside of the indoor unit 1.

The upper end of the drain pan 40 is formed with a stabilizer 44 rounded so that the top is convex. The stabilizer 44 is located in the lower left direction of the cross flow fan 60 to be described below as shown in FIG. 2 when the indoor unit 1 is mounted on the ceiling, and the upper end portion is configured to be close to the cross flow fan 60. The interior space of the indoor unit 1 is partitioned from side to side.

Therefore, the air sucked into the indoor unit 1 and passed through the crossflow fan 60 is positioned on the left side (as seen in FIG. 2) with respect to the stabilizer 44, and is guided to the discharge port 34.

The heat exchanger 50 is installed at the rear of the drain pan 40. The heat exchanger 50 exchanges heat by passing indoor air sucked into the indoor unit 1 through the inlet 12, and is mounted obliquely inside the cabinet 20.

The cross flow fan 60 is installed at the rear of the heat exchanger 50. The crossflow fan 60 receives rotational force from the fan motor 62 installed at the left end and rotates the indoor air for air conditioning into the indoor unit 1, and exchanges heat by the heat exchanger 50. At the same time, the discharged air is discharged back into the room.

More specifically, the crossflow fan 60 is coupled to the left and right end of the fan mounting holes 64, the separation is rotatable in a controlled state, the fan motor 62 is a motor mounting port for accommodating the fan motor 62 By being axially coupled to the left end of the fan motor 62 in a state surrounded by the (66) and the fan mounting port 64, the rotational power transmission to the fan motor 62 is possible.

Therefore, when the cross flow fan 60 rotates, the indoor air sucked into the indoor unit through the suction port 12 is heat-exchanged by the heat exchanger 50, and then the flow direction is forced to the discharge port 34, thereby causing the indoor unit ( 1) It can be discharged to the outside.

The controller assembly 70 is provided below the crossflow fan 60. The controller assembly 70 accommodates a PCB (PCB) 72 for controlling the operation of the indoor unit 1, and a control box 74 for accommodating the PCB 72 therein to safely protect the PCB 72 from external shocks. ) And a control cover 76 that shields the control box 74.

On the other hand, the cabinet 20 will be embedded therein a plurality of the above-described components. In addition, a drain hose 22 is installed on the inner left side wall of the cabinet 20. The drain hose 22 has one end connected to the recessed rear surface of the drain pan 40 and the other end connected to the outside of the indoor unit 1 to collect condensed water collected in the drain pan 40. ) Can drain outside.

In addition, an air guide 80 having a longitudinal section of a 'b' shape is attached to the inner wall surface of the cabinet 20 when viewed from the right side of FIG. 1. The air guide 80 guides the air sucked into the inlet 12 by the action of the crossflow fan 60 to flow to the outlet 34, and allows the air to flow smoothly without interference. Is formed round.

'모양(도 2에서 볼 때)의 종단면을 가지는 기류안내돌기(82)가 돌출 형성된다.The air guide 80 is installed over the ceiling and the left side wall inside the cabinet 20. And, the bottom of the bottom of the air guide 80 is approximately '

An airflow guide protrusion 82 having a longitudinal section (as seen in FIG. 2) is formed to protrude.

The airflow guide protrusion 82 guides the flow direction such that the air sucked into the inlet 12 passes through the crossflow fan 60 after passing through the heat exchanger 50, and a lower end of the airflow guide protrusion 60 passes through the crossflow fan 60. It is configured to be located below the upper end of the).

Therefore, the air heat-exchanged via the heat exchanger 50 can flow to the crossflow fan 60 due to the interference of the airflow guide protrusion 82 as shown by the arrow of FIG.

However, the above conventional technologies have the following problems.

That is, one side of the drain pan 40 is formed with a pump seat 42 in which the drain pump (not shown) is seated, as described above, and the condensed water collected in the drain pan 40 is pumped. The water is first collected in the seating portion 42.

Therefore, when a large volume of foreign matters are collected in the drain pan 40, such foreign matters also flow into the pump seat 42 and flow into the drain pump.

In addition, the drain pan 40 is not provided with any configuration that can block the inflow of foreign matter into the drain pump (not shown), it is preferable because the foreign matter is introduced into the drain pump eventually causes damage to the drain pump I can't.

In addition, when the drain pump is damaged, a repair cost is additionally generated, which causes the customer to cause a decrease in product satisfaction.

Therefore, an object of the present invention is to solve the problems in the prior art as described above, by forming a foreign matter catching boss for filtering foreign matter on one side of the drain pan to collect the condensed water drained from the heat exchanger to introduce foreign substances into the drain pump. A drain pan structure of an air conditioner indoor unit is to be prevented.

The drain fan structure of the indoor unit of the air conditioner according to the present invention for achieving the above object, the drain is installed on the lower side of the heat exchanger for heat-exchanging the indoor air introduced into the indoor unit to collect the condensed water drained from the heat exchanger In the fan, one side of the drain pan, the pump seat portion recessed and formed so as to seat the drain pump for generating a suction force to drain the condensed water collected in the drain pan to the outside of the indoor unit, and protruded around the pump seat portion It is characterized in that it is provided with a plurality of foreign matter catching boss to block the inflow of foreign matter to the pump seat.

The plurality of foreign matter catching boss is characterized in that it is formed radially.

The foreign matter catching boss is formed integrally with the drain pan.

The plurality of foreign matter catching boss is characterized in that spaced apart at equal intervals.

One side of the drain pan is characterized in that the sedimentation groove is provided so that the foreign matter contained in the collected condensate is precipitated.

The condensed water collected in the drain pan is introduced into the foreign matter catching boss after passing through the settling groove.

One side of the drain pan is characterized in that the foreign matter adsorption means for adsorbing foreign matter contained in the air.

One surface of the drain pan is characterized in that the heat blocking member for blocking heat exchange of the collected condensate and air.

According to the indoor unit of the separate type air conditioner according to the present invention, there is an advantage that the productivity is improved and the air conditioning performance is maximized.

Hereinafter, with reference to the accompanying drawings, a configuration of an indoor unit of an air conditioner employing a preferred embodiment of the present invention will be described in detail.

Figure 3 is a bottom perspective view showing the external appearance of the air conditioner indoor unit employing a preferred embodiment of the present invention mounted on the ceiling.

As shown in the figure, the indoor unit 100 of the air conditioner is installed in a room where air conditioning is required to match indoor air, and has an approximately rectangular parallelepiped shape, and is mounted to expose the bottom surface from the indoor ceiling. .

The indoor unit 100 includes a suction grill 110 having a suction port 112 formed therein so that indoor air can be sucked into the indoor unit 100, and is provided outside the suction grill 110 and inserted into the ceiling. The cover 120 is formed on the cabinet 120 in which a plurality of components are built, and formed on left and right sides of the cabinet 120 to shield a space formed by the suction grill 110 and the cabinet 120 by forming a space downward. ), And a front panel 140 provided between the cabinet 120 and the suction grill 110 to guide air flow into / out of the indoor unit 100.

The suction grill 110 serves as a passage through which indoor air is sucked into the indoor unit 100. The suction grill 110 has a rectangular plate shape and a plurality of suction ports 112 are formed on the front surface of the suction grill 110. The inlet 112 may guide the indoor air to the inside of the indoor unit 100 by allowing the indoor unit 100 and the room for air conditioning to communicate with each other.

The suction grill 110 has a substantially rectangular plate shape and serves as a passage to allow indoor air to be sucked into the indoor unit 100. Therefore, a plurality of suction ports 112 are generally formed in the upper portion of the center of the suction grill 110 so that the inside of the indoor unit 100 communicates with the room for air conditioning.

Discharge openings 142 are formed before and after the lower surface of the suction grill 110, respectively. The discharge port 142 is formed to be elongated in the horizontal direction before and after the lower surface of the front panel 140, and serves to guide the discharge to the interior after heat exchange in the indoor unit (100).

Therefore, the indoor unit 100 separates the air heat exchanged through the discharge port 142 back and forth after discharging the indoor air through the suction port 112 formed in the center portion.

In addition, a rectangular plate-shaped vane 116 is rotatably mounted inside the discharge port 142. The vane 116 serves to force the discharge direction by interfering when the heat exchanged air inside the indoor unit 100 is discharged into the room through the discharge port 142.

Therefore, when the vane 116 is reciprocated in the vertical direction, the air discharged to the discharge port 142 is forced to flow to the corner of the room, the vane 116 is suction grill 110 The discharge port 142 is shielded when placed on the same plane as the lower surface of the ().

Hereinafter, the internal structure of the indoor unit 100 will be described with reference to FIG. 4.

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

As shown in the figure, the rear side of the vane 116 is provided with a louver 118 for forcibly flowing the air discharged to the discharge port 142 in the left and right directions. The louver 118 is formed so that a plurality of triangular blades 118 'are spaced apart at regular intervals in the left and right directions, and the blade 118' is configured to reciprocate in the left and right directions, so that the discharged air flows This is forced.

Accordingly, a motor (not shown) is provided at the left end of the louver 118 to generate power by applying power, and the vane 116 and the louver 118 are generated from the motor (not shown). ), The vanes 116 and the louvers 118 can be repeatedly rotated.

A blower 130 is provided behind the vanes 116 and the louvers 118. The blower 130 is for forcing the suction and blowing of the indoor air is provided with a pair in the same shape, it is installed symmetrically to each other inside the indoor unit (100).

The blower 130 is a fan motor 132 for generating a rotational power when the power is applied, and a cross-flow fan 134 for rotating and coupled to one side of the fan motor 132 to generate wind power when rotating; The crossflow fan 134 is accommodated in a spaced apart state therein, the air guide 136 for guiding the flow direction of the wind generated from the crossflow fan 134 and the air guide 136 is coupled to the crossflow fan It is configured to include a fan holder 138 to prevent the 134 from being separated from the air guide 136.

The cross-flow fan 134 has a long cylindrical shape in the left and right directions, a plurality of blades are formed on the outer peripheral surface at equal intervals. The crossflow fan 134 is rotatable by a rotation shaft 134 'protruding from the center of the left and right surfaces.

The crossflow fan 134 receives the rotational power from the above-described fan motor 132 and rotates at a high speed so that indoor air for air conditioning is sucked into the indoor unit 100, and at the same time, a heat exchanger to be described below. The air heat-exchanged by the 150 is discharged to the room again through the discharge port 142.

Air guides 136 are provided on the right side and the upper side of the crossflow fan 134. That is, the air guide 136 has an approximately 'A' shaped longitudinal section when viewed from the front, and is attached to the inner wall surface of the cabinet 120.

The air guide 136 guides the flow direction of air passing through the indoor unit 100. That is, the air guide 136 is sucked into the indoor unit 100 by the cross flow fan 134 and guides the air passing through the cross flow fan 134 upward to flow to the discharge port 142. You will be guided.

Therefore, the front surface of the bent portion of the air guide 136 is preferably formed to be round so that the air sucked into the indoor unit 100 can flow smoothly without interference.

In addition, an airflow guide protrusion 136 ′ is formed on the front center of the air guide 136. The airflow guide protrusion 136 ′ guides the air introduced into the indoor unit 100 to flow into the crossflow fan 134. The lower side of the airflow guide protrusion 136 ′ is formed to be inclined backward and the upper side is rounded.

Therefore, the air introduced into the indoor unit 100 by the suction force of the crossflow fan 134 is interfered with and guided by the airflow guide protrusion 136 ′ and guided in a diagonal direction, that is, the center direction of the crossflow fan 134. .

The fan holder 138 is provided at left and right ends of the air guide 136. The fan holder 138 is such that the cross flow fan 134 and the fan motor 132 are mounted to the air guide 136, and the cross flow fan 134 is rotated while being spaced apart from the front surface of the air guide 136. And a shielding portion 138 " coupled to a tip of the seating portion 138 'to prevent the fan motor 132 from being separated.

The seating portion 138 ′ has a rear end coupled to the front left and right sides of the air guide 136 and the front end is recessed to correspond to the left end shape of the fan motor 132. Therefore, the fan motor 132 is accommodated on the opposite surface of the seating portion (138 ').

The facing surface of the seating portion 138 'is recessed outwardly so that the rotation shaft 134' is inserted. Accordingly, the fan motor 132 and the rotating shaft 134 'accommodated in the fan holder 138 of the seating portion 138' may be coupled to each other.

A shield 138 "is coupled to the front of the seat 138 '. The second half of the shield 138" is recessed into a shape corresponding to the first half of the fan motor 132. Therefore, when the fan motor 132 is accommodated in a space formed by combining the seating portion 138 ′ and the shielding portion 138 ″, the fan motor 132 is not separated from the fan holder 138.

'모양의 종단면을 가지며 좌우로 길게 형성된다.The heat exchanger 150 is installed between the pair of blowers 130. The heat exchanger 150 is to heat exchange the air moved backward through the through hole 230 to be described below, when viewed from the right '

It has a longitudinal cross section and is formed long to the left and right.

On the other hand, the front of the heat exchanger 150, the drain pan 200 constituting the main portion of the present invention is installed. The drain pan 200 is for collecting the condensate generated on the outer surface of the heat exchanger 150 when the heat exchanger 150 heat-exchanges the indoor air, and the rear surface is recessed forward.

In addition, a heat shield member 210 is coupled to a front surface of the drain pan 200. The heat blocking member 210 is to prevent dew from forming on the outer surface of the drain pan 200 by cold air of condensate stored in the rear of the drain pan 200, and is formed of polyethylene foam having excellent heat blocking effect. The front surface of the drain pan 200 is formed to cover the entire surface.

The filter 220 is mounted to the perforated center portion of the drain pan 200. The filter 220 may primarily filter indoor air sucked into the indoor unit 100 through the suction port 112 to prevent foreign matter loading as well as failure of components inside the indoor unit 100.

Hereinafter, the structure of the drain pan 200 will be described in more detail with reference to the accompanying drawings.

FIG. 5 is a perspective view showing a state in which a heat exchanger is seated on an upper surface of a drain pan, which is one component of an indoor unit of an air conditioner employing a preferred embodiment of the present invention, and FIG. 6 is a drain pan of an indoor unit of an air conditioner according to the present invention. A top perspective view of the structure is shown.

As shown in these figures, the drain pan 200 has a through-hole 230 in the central portion when viewed from above, has a substantially rectangular outline, and the top surface is recessed downward. Therefore, the condensed water dropped from the heat exchanger 150 can be collected on the upper surface of the drain pan 200.

In addition, a drain hose (not shown) is coupled to one side of the drain pan 200 in communication. Therefore, the condensed water collected on the upper surface of the drain pan 200 may be drained to the outside of the indoor unit 100 along the drain hose (not shown).

In addition, the drain pan 200 also serves to guide the air filtered by the filter 220 to flow upward after passing through the inlet 112. That is, air existing under the drain pan 200 is guided upward along the through hole 230.

The foreign material adsorption means 232 is mounted in the through hole 230. The foreign material adsorption means 232 is to filter the air primarily filtered by the filter 220 secondly, it is preferable to apply a plasma filter that generates a plasma to charge and adsorb foreign substances contained in the air.

In addition, the support 234 is formed in the through hole 230 so that the foreign matter adsorption means 232 may be mounted. The support part 234 supports the load by bringing both ends of the lower surface of the foreign substance adsorption means 232 into contact with the upper surface thereof, and is coupled by a fastening member such as a screw to restrict the separation of the foreign substance adsorption means 232.

The stabilizer 240 protrudes in the left and right directions before and after the upper surface of the drain pan 200. The stabilizer 240 has a pointed streamlined vertical section at an upper portion thereof and is formed to correspond to the length of the crossflow fan 134 to guide the discharge direction of air passing through the crossflow fan 134.

That is, the stabilizer 240 is formed so that the upper end portion is close to the outer circumferential surface of the cross flow fan 134 to divide the space below the cross flow fan 134 to the left and right. Therefore, the air passing through the crossflow fan 134 is guided by the stabilizer 240 to be discharged to the discharge port 142.

The pump seating part 250 is provided on the upper left side of the drain pan 200. The pump seating part 250 generates suction and causes the drain pump 252 to drain the condensed water collected in the drain pan 200 to the outside of the indoor unit 100, and is recessed downward.

In more detail, the pump seating part 250 is recessed to be positioned at a lower position than the bottom surface of the drain pan 200, and the condensed water dropped to the top surface of the drain pan 200 is disposed at the pump seating part 250. The first is collected.

Accordingly, the drain pump 252 installed to approach the bottom of the pump seat 250 may suck the condensed water collected in the pump seat 250. In addition, the drain pump 252 is preferably connected to communicate with the above-described drain hose (not shown) to drain the condensed water sucked out to the indoor unit (100).

On the other hand, in the periphery of the pump seating portion 250, a plurality of cylindrical foreign matter catching boss 260 is formed to protrude radially. The foreign matter catching boss 260 is a configuration for filtering foreign matter contained in the condensed water flowing into the pump seating part 250 after being collected on the upper surface of the drain pan 200, and is formed to be closely spaced at equal intervals.

Therefore, even when foreign matter (for example, hair) is included when the condensed water accumulated on the drain pan 200 moves to the pump seating part 250, the foreign matter is caught by the foreign matter catching boss 260 and the pump seating part ( 250 is prevented from flowing into the drain pump 252 by blocking the inflow into the interior.

The foreign matter catching boss 260 is integrally formed with the drain pan 200. This is because it is difficult to separately form and bond to the drain pan 200 when viewed in the shape of the foreign matter catching boss 260, and more precisely, to secure the strength of the foreign matter catching boss 260.

Therefore, the condensed water in the pump seating part 250 is drained into the indoor unit 100 by the suction force of the drain pump 252 and the condensed water that falls on the upper surface of the drain pan 200 flows to the pump seating part 250. In the process, even if the stopped foreign matter caught by the foreign matter catching boss 260 interferes with the condensate, the foreign matter catching boss 260 can firmly support the foreign matter without bending or breaking.

The left side spaced apart from the foreign matter catching boss 260 is provided with a precipitation groove 262 formed in an arc shape. The settling groove 262 is to allow the fine foreign matter contained in the condensed water collected on the upper surface of the drain pan, the condensed water is removed through the settling groove 262, the fine foreign matter is removed, the foreign matter jamming boss 260 Large foreign bodies such as hair are filtered out.

Hereinafter, the operation of the separate type air conditioner indoor unit 100 according to the present invention having the configuration as described above will be described as an example of the cooling mode.

FIG. 7 is a longitudinal sectional view showing an air flow path when the air conditioner indoor unit according to the present invention operates.

First, when the air conditioner is driven by applying power, the fan motor 132 generates rotational power, and the crossflow fan 134 interlocked with the fan motor 132 rapidly rotates to generate suction force, thereby providing indoor air. Is sucked into the indoor unit 100 through the inlet 112.

The air sucked into the indoor unit 100 is filtered by the filter 220, and after being purified, the air flows upward to come into contact with the heat exchanger 150.

In more detail, the air filtered by the filter 220 is divided into left and right inside the indoor unit 100 and is heat-exchanged by passing through the heat exchanger 150.

Thereafter, the air cooled by heat exchange by the heat exchanger 150 is guided toward the center of the crossflow fan 134 by being interfered by the airflow guide protrusion 136 ', and the airflow guide protrusion 136'. Air guided by the flow direction is forced by the cross flow fan 134 is moved to the left and right inside the indoor unit (100).

At this time, the air passed through the above process is guided by the rounded bottom surface of the air guide 136 to change the flow direction downward, further along the spaced space between the stabilizer 240 and the air guide 136 It moves and is discharged to the indoor space through the discharge port 142.

In addition, the air discharged to the indoor space through the discharge port 142 is interfered by the vane 116 and the louver 118 to harmonize a large area of the indoor space.

Hereinafter, the operation of the drain pan 200 will be described with reference to FIG. 6, and condensate is generated on the outer surface of the heat exchanger 150 by heat exchange of indoor air. The condensate flows down the outer surface of the heat exchanger 150 at an angle and is collected on the upper surface of the drain pan 200.

At the same time, power is applied to the drain pump 252 so that the drain pump 252 generates suction power, and the condensate collected on the upper surface of the drain pan 200 by the suction power passes through the settling groove 262. Fine foreign matter is precipitated, the fine foreign matter is precipitated and the first purified condensed water flows to the pump seat 250.

At this time, even if a light foreign material such as hair is included on the upper surface of the drain pan 200, such foreign matter is interrupted by the foreign matter catching boss 260, the flow is stopped and prevents the flow to the pump seat 250. do. Therefore, the inflow of foreign matter is blocked into the drain pump 252.

Thereafter, the condensed water filtered by the foreign matter catching boss 260 is sucked upward by the drain pump 252 and then drained to the outside of the indoor unit 100 via the drain hose (not shown).

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.

That is, in the embodiment of the present invention, but the foreign matter catching boss is formed on the upper edge portion of the drain pan, it can be formed in various positions according to the mounting position of the drain pump.

The drain pan structure of the indoor unit of the air conditioner according to the present invention as described above further comprises a foreign matter catching boss for filtering foreign matter to one side of the drain pan for collecting condensed water drained from the heat exchanger.

Therefore, there is an advantage that the inflow of foreign matter into the drain pump is prevented.

In addition, since the inflow of foreign matter into the drain pump is blocked, there is an advantage that the damage of the drain pump is prevented in advance.

In addition, the above advantages are expected to improve the customer satisfaction.

Claims (8)

In the drain pan for collecting the condensed water drained from the heat exchanger to heat exchange the air introduced into the indoor unit, On one side of the drain pan, A pump seat formed indented so that a drain pump for draining the collected condensed water to the outside of the indoor unit is seated; The drain fan structure of the indoor unit of the air conditioner characterized in that the protruding molded around the pump seating portion is provided with a plurality of foreign matter catching boss to block the foreign material inflow into the pump seating portion. The drain fan structure of the indoor unit of claim 1, wherein the plurality of foreign matter jamming bosses are formed radially. The drain pan structure of the indoor unit of claim 2, wherein the foreign matter catching boss is integrally formed with the drain pan. The drain fan structure of the indoor unit of claim 3, wherein the plurality of foreign matter jamming bosses are formed at equal intervals. The drain pan structure of an indoor unit of claim 1, wherein a settling groove is provided at one side of the drain pan to allow foreign matter contained in the collected condensate to settle. The drain pan structure of the indoor unit of claim 5, wherein the condensed water collected in the drain pan flows into the foreign matter catching boss after passing through the settling groove. The drain pan structure of the indoor unit of claim 1, wherein the one side of the drain pan is provided with foreign matter adsorption means for adsorbing foreign matter contained in the air. The drain pan structure of the indoor unit of claim 1, wherein a heat shield member for blocking heat exchange between the collected condensed water and air is provided at one surface of the drain pan (200).

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