KR101543982B1 - Indoor air conditioner - Google Patents

Abstract

The occurrence of the phenomenon that the suction port on the lower surface does not function in some cases due to different environmental conditions is suppressed. The casing 11 has a ceiling surface suction port 21 and a lower surface suction port 22 and the indoor fan 15 generates a flow of air sucked from the suction ports 21 and 22. The indoor heat exchanger 13 is formed in a substantially inverted V-shape by the front heat exchanging portions 13a and 13b and the rear heat exchanging portion 13c, In order to inhibit the flow of the air sucked in from the air blower. Particularly, the indoor fan 15 generates a flow of indoor air sucked from the respective suction ports 21, 22 and flowing into the rear heat exchanging portion 13c. The suction resistance portion 50 is located at the ceiling surface suction port 21 corresponding to the rear heat exchanging portion 13c.

Description

INDOOR AIR CONDITIONER

The present invention relates to an air conditioning indoor unit, and more particularly to a wall-mounted air conditioning indoor unit.

In the air conditioner, there is a separate type comprising an outdoor unit installed outdoors and an indoor unit installed in the room. Particularly, in the indoor unit, there is a wall-mounted type which is attached to a wall surface of the room.

As a wall-hanging type indoor unit, for example, it is known to be disclosed in Patent Document 1 (Japanese Patent Application Laid-Open No. 2001-311530). The indoor unit related to Patent Document 1 has a ceiling front intake port on the ceiling front surface and a lower intake port and an exhaust port on the lower surface. According to this indoor unit, the indoor air is sucked from the both suction ports and heat-exchanged in the heat exchanger, and then taken out to the room through the air outlet.

Japanese Patent Application Laid-Open No. 2001-311530

However, the environmental condition of the place where the indoor unit is installed differs from place to place. Then, as in Patent Document 1, in an indoor unit having a suction port not only on the ceiling surface but also on the ceiling surface, the air is mainly sucked from the suction port on the ceiling surface depending on the environmental conditions at the place where the indoor unit is installed, There is a case in which a phenomenon in which the suction port is hardly sucked is generated. Particularly, the wall-mounted type indoor unit is installed relatively close to the ceiling in the room, and the gap between the ceiling surface of the indoor unit and the ceiling is often narrowed. As a result, the performance of the indoor unit fluctuates as compared with the performance evaluation in a state where the clearance between the ceiling surface and the ceiling of the indoor unit is large.

Here, the object of the present invention is to suppress the occurrence of a phenomenon that the suction port on the lower surface does not function in some cases because the environmental conditions are different.

The air conditioner indoor unit according to the first aspect of the present invention is a wall-mounted air conditioner indoor unit comprising a casing, a fan, a heat exchanger, and a suction resistor. The casing has a top inlet and a bottom inlet. The ceiling front surface suction opening is provided from the front side to the rear side of the ceiling front surface. The suction port is provided on the lower surface. The fan is located inside the casing and generates a flow of air sucked from the top front suction inlet and the bottom suction opening. The heat exchanger is formed inside the casing by combining the front heat exchanger and the rear heat exchanger in a substantially inverted V-shape as viewed from the side. The front heat exchanger covers the front of the fan and the rear heat exchanger covers the back of the fan. The suction resistance portion hinders the flow of air sucked from the top surface suction port. Further, the suction resistance portion increases the suction resistance at the top surface suction port portion corresponding to the rear heat exchanging portion, rather than the suction resistance at the top surface suction port portion corresponding to the front heat exchanging portion. Then, the fan sucked from the top front suction port and the bottom suction port creates a flow of air flowing into the rear heat exchanging portion. The suction resistance portion is located at the ceiling front suction port corresponding to the rear heat exchanging portion.

According to this air conditioning indoor unit, the amount of the room air sucked from the ceiling front suction port is suppressed by the suction resistance portion. Therefore, even when the air conditioning indoor unit is installed under an environmental condition in which the room air sucked from the ceiling front suction port is increased, the increase in the indoor air sucked from the ceiling front suction port is suppressed to some extent by the suction resistance portion. Therefore, it is possible to reduce the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port to the amount of the room air sucked from the suction port, and the phenomenon that the lower suction port does not function in some cases Can be suppressed.

In the air conditioning indoor unit according to the second aspect of the present invention, in the air conditioning indoor unit relating to the first aspect, the suction resistance portion is located at a rear portion of the ceiling front suction opening corresponding to the rear heat exchanging portion.

As a result, the amount of room air sucked from the rear portion of the ceiling front suction port is reduced. Therefore, the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port to the amount of the room air sucked from the suction port can be further reduced.

The air conditioning indoor unit according to the third aspect of the present invention is the air conditioning indoor unit according to the first aspect or the second aspect, wherein the suction resistance part is constituted by a part of the casing.

Thus, the suction resistance portion can be easily configured, and the cost can be reduced as compared with a case where the suction resistance portion is formed of a separate member.

A fourth aspect of the air conditioner indoor unit according to the present invention is the air conditioner indoor unit according to the first aspect or the second aspect, wherein the suction resistance part is formed of a member separate from the casing and is mounted on the ceiling front suction port.

Thus, the suction resistance portion can be easily installed.

The air conditioning indoor unit according to the fifth aspect of the present invention is the air conditioning indoor unit according to any one of the first to fourth aspects, wherein the suction resistance portion is provided over the entire length in the longitudinal direction of the ceiling suction inlet.

Thus, the suction resistance portion can cover the ceiling surface suction port over the entire length in the longitudinal direction.

A sixth aspect of the present invention is the air conditioner indoor unit according to any one of the first to fifth aspects, wherein the suction resistance section blocks about 30% or more of the rear portion of the top surface air inlet.

As a result, the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port to the amount of the room air sucked from the suction port is reduced, and the lower suction port can reliably function.

A seventh aspect of the present invention resides in the air conditioning indoor unit according to the sixth aspect, wherein the suction resistance portion blocks about 50% or more of the rear portion of the ceiling suction opening.

This makes it possible to further reduce the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port to the amount of the room air sucked from the suction port.

An eighth aspect of the present invention resides in the air conditioning indoor unit according to any one of the first to seventh aspects, wherein the wind speed of the air sucked from the underwater inlet is about 0.5 m / sec or more.

Here, the suction resistance portion interferes with the room air sucked from at least a part of the ceiling surface suction port corresponding to the rear heat exchanging portion, so that the air velocity of the air sucked from the lower surface suction port becomes about 0.5 m / sec or more. This makes it possible to reliably suppress the degree of deviation of the ratio of the amount of the room air sucked from the ceiling surface suction port and the amount of the room air sucked from the suction port depending on the environmental conditions in which the air conditioning indoor unit is installed.

According to the air conditioning indoor unit related to the first aspect of the present invention, since the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port to the amount of the room air sucked from the suction port can be reduced, Therefore, occurrence of the phenomenon that the suction port does not function can be suppressed.

According to the air conditioning indoor unit according to the second aspect of the present invention, the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port to the amount of the room air sucked from the suction port can be further reduced.

According to the air conditioning indoor unit according to the third aspect of the present invention, the suction resistance portion can be easily configured, and the cost can be reduced as compared with a case where the suction resistance portion is formed of a separate member.

According to the air conditioning indoor unit related to the fourth aspect of the present invention, the suction resistance portion can be simply provided.

According to the air conditioning indoor unit according to the fifth aspect of the present invention, the suction resistance portion can cover the ceiling surface suction port over the entire length in the longitudinal direction.

According to the air conditioning indoor unit according to the sixth aspect of the present invention, the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port to the amount of the room air sucked from the suction port can be reduced, and the lower suction port can reliably function .

According to the air conditioning indoor unit related to the seventh aspect of the present invention, it is possible to further reduce the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port to the amount of the room air sucked from the suction port.

According to the air conditioner indoor unit according to the eighth aspect of the present invention, it is possible to reliably determine the degree of deviation of the ratio of the amount of the room air sucked from the ceiling surface suction port and the amount of the room air sucked from the suction port depending on the environmental condition in which the air- .

1 is an external view of an air conditioning indoor unit according to the present embodiment.
Fig. 2 is a sectional view taken along the line II-II in Fig. 1, showing the air conditioning indoor unit according to the embodiment; Fig.
Fig. 3 is an outline view of the inside of the casing when the supporting member according to the embodiment is fixed in the casing, in which the casing, the floor frame, and the indoor fan are removed from the air conditioning indoor unit.
Figure 4 is an overview of the cleaning unit.
Fig. 5 is an enlarged view of the vicinity of the cleaning unit in Fig. 2; Fig.
Fig. 6 is a view of the filter in Fig. 3 taken off the support member; Fig.
Fig. 7 is an enlarged view of the vicinity of a ceiling face plate related to Fig. 2, and in Fig. 2, a supporting member and a filter are omitted. Fig.
8 is a view of the vicinity of the ceiling surface of the air conditioning indoor unit when the air conditioning indoor unit according to the present embodiment is viewed from above.

Hereinafter, an air conditioning indoor unit related to the present invention will be described in detail with reference to the drawings. The following embodiments are specific examples of the present invention and do not limit the technical scope of the present invention.

(1) Configuration

1 is an external view of an air conditioning indoor unit 100 according to an embodiment of the present invention. The air conditioning indoor unit 100 is attached to a wall surface of a room, and is connected to an outdoor unit (not shown) installed outside the room through a refrigerant pipe (not shown). The air conditioning indoor unit 100 can perform the automatic cleaning operation for automatically cleaning the filter 25 and the brush 33 (Fig. 2) in addition to the cooling operation and the heating operation in the room.

1 to 5, the air conditioning indoor unit 100 mainly includes a casing 11, an indoor heat exchanger 13, an indoor fan 15, a floor frame 17, a filter (not shown) 25, a cleaning unit 30, a support member 40, and a suction resistance unit 50. [

In the following description, expressions indicating directions such as "top", "bottom", "left", "right", "front", "rear", etc. are appropriately used. In the state of being installed on the wall surface of the room or the like.

(1-1) Casing

As shown in Fig. 1, the casing 11 has an elongated box shape in the lateral direction (the W direction in Fig. 1). Specifically, as shown in Figs. 1 and 2, the casing 11 is formed with a three-dimensional space by a ceiling face plate 11a, a front plate 11b and a back plate 11c, The indoor fan 15, the bottom frame 17, the cleaning unit 30, the support member 40, and the suction resistance unit 50 are housed in the housing 13. The ceiling face plate 11a mainly constitutes the ceiling face of the casing 11 and the face plate 11b mainly constitutes the front face of the casing 11. [ Further, the front plate 11b is rotatably supported by a part of the ceiling plate 11a at its upper end, and can operate in a hinged manner. The back plate 11c mainly constitutes the back surface of the casing 11. [ The back plate 11c is attached to a mounting plate (not shown) provided on the wall surface of the room by screws or the like, so that the air conditioning indoor unit 100 is installed on the wall surface of the room.

The ceiling face plate 11a of the casing 11 is formed with a ceiling face suction port 21 from the front side to the rear side of the face 11a. The room air in the vicinity of the intake port 21 enters the inside of the casing 11 by driving of the indoor fan 15 so that the front heat exchanging portion 13a of the indoor heat exchanger 13 , 13b (described later) and the rear heat exchanger 13c (described later), respectively. An arrow A shown by a dotted line in Fig. 2 represents, for example, a flow of room air conveyed to the indoor fan 15 through the ceiling inlet 21 and the front heat exchanger 13b.

The bottom surface of the casing 11 is mainly constituted by a bottom portion 17a (described later) of the bottom frame 17, and a bottom suction port 22 and a blowout port 23 are formed on the bottom surface have. The suction port 22 is provided on the wall side of the outlet port 23 and is connected to the inside of the casing 11 by the suction flow path 16. The indoor air in the vicinity of the suction port 22 enters the inside of the casing 11 by driving the indoor fan 15 and flows through the suction flow path 16 to the rear side of the indoor heat exchanger 13 And transferred to the heat exchanging portion 13c (described later). An arrow B shown by a dotted line in Fig. 2 indicates, for example, the flow of room air conveyed from the lower intake port 22 to the rear heat exchanging portion 13c. The air outlet 23 is provided on the front side of the air conditioning indoor unit 100 rather than the lower air inlet 22 and is connected to the inside of the casing 11 by the blowout flow passage 18. In the air outlet 23, the indoor air sucked from the respective suction ports 21, 22 and heat-exchanged in the indoor heat exchanger 13 is taken out to the room through the takeout flow path 18. The arrow C in the dotted line in Fig. 2 shows the flow of the air that is conveyed from the take-out passage 18 to the room through the take-out port 23.

The suction passage 16 is formed along the flow passage forming portion 17b (to be described later) of the bottom frame 17 from the lower surface suction port 22. [ The takeout flow passage 18 is formed along the flow passage forming portion 17b of the bottom frame 17 from the air outlet 23. That is, it can be said that the suction passage 16 and the blow-out passage 18 are located adjacent to each other with the passage forming portion 17b of the bottom frame 17 interposed therebetween.

A horizontal flap 23a is attached to the casing 11 so as to be rotatable in the vicinity of the air outlet 23. The horizontal flap 23a can be driven by a flap motor (not shown) and opens and closes the air outlet 23 according to the operating state of the air conditioning indoor unit 100. [ Further, the horizontal flap 23a plays a role of changing the take-out direction of the room air so that the room air taken out from the dispensing opening 23 is guided in a desired direction by the user.

(1-2) Indoor heat exchanger

The indoor heat exchanger (13) is composed of a plurality of fins and a plurality of heat transfer tubes. The indoor heat exchanger (13) is attached to a part of the bottom frame (17) inside the casing (11). The indoor heat exchanger (13) functions as an evaporator or a condenser depending on the operating state of the air conditioning indoor unit (100), thereby allowing heat exchange between the refrigerant and the air passing through the heat exchanger (13).

Particularly, as shown in Fig. 2, the indoor heat exchanger 13 according to the present embodiment has a substantially inverted V-shaped shape with both ends bent downward as seen from the side, Is located. In the present embodiment, among the indoor heat exchangers 13 having such a shape, the heat exchanging section covering the front of the indoor fan 15 is referred to as " front heat exchanging sections 13a and 13b & The indoor heat exchanger 13 according to the present embodiment is provided with the front heat exchanging portions 13a and 13b and the rear heat exchanging portion 13c, And the heat exchanging portion 13c has a substantially inverted V-shape connected to the apex 13d.

2 shows a case in which the front heat exchanging parts 13a and 13b have a bent shape in front of the indoor fan 15 as an example. That is, the front heat exchanging parts 13a and 13b are located in the upper part and lower part (that is, the front heat exchanging part 13a) and the upper part (that is, the front heat exchanging part 13b) Respectively. However, the front heat exchanging parts 13a and 13b may be positioned so as to cover the front of the indoor fan 15, and it is not necessary to be constituted by dividing them in the vertical direction as shown in Fig.

(1-3) Indoor fan

The indoor fan 15 is located inside the casing 11 and is a substantially cylindrical crossflow fan which is elongated in the W direction shown in Fig. The indoor fan 15 is sucked from each of the ceiling front suction port 21 and the bottom suction port 22 by driving and connected to the indoor heat exchanger 13 (specifically, the front heat exchangers 13a and 13b and the rear heat exchanger 13 (Indicated by the arrows A, B, and C in the dotted line in Fig. 2) to flow into the room from the outlet 23 through the heat exchanger 13 Reference).

The indoor fan 15 has its drive shaft connected to the output shaft of an indoor fan motor (not shown). When the indoor fan motor is driven, the output of the motor is transmitted to the drive shaft of the indoor fan 15 through the output shaft, so that the indoor fan 15 can be driven.

(1-4) Floor frame

The bottom frame 17 is composed of a bottom portion 17a and a flow path forming portion 17b.

The bottom portion 17a is an element constituting at least a part of the lower surface of the casing 11 and is exposed to the outside of the air conditioning indoor unit 100 in the bottom frame 17. [ Therefore, the user can see the bottom portion 17a from the bottom of the air conditioning indoor unit 100. [

The flow path forming portion 17b is an element located in the inside of the casing 11 among the bottom frames 17. [ The flow path forming portion 17b extends upward from one end of the bottom portion 17a and has a curved shape in accordance with the shape of the indoor fan 15. [

(1-5) Filter

The filter 25 is disposed mainly on the upstream side of the indoor heat exchanger 13 between the ceiling plate 11a of the casing 11 and the indoor heat exchanger 13, (Not shown). The filter 25 covers the front heat exchanging portions 13a and 13b and the rear heat exchanging portion 13c. The filter 25 has a shape in which the rear end portion 25b of the filter 25 in the front-rear direction is positioned below the apex 13d of the indoor heat exchanger 13. More specifically, the filter 25 according to the present embodiment has a substantially central portion extending along the ceiling face plate 11a of the casing 11 and a front end portion 25a in the front- And the rear end portion 25b of the indoor heat exchanger 13 is lowered below the apex 13d of the indoor heat exchanger 13 so as to cover the upper portion of the indoor heat exchanger 13.

In the present embodiment, the rear end 25b of the filter 25 reaches a position substantially covering the rear heat exchanging portion 13c, and the front end 25a of the filter 25 is connected to the front heat exchange Covering the entire portion 13b and partially covering the upper portion of the front heat exchanging portion 13a. Thus, the portion of the filter 25 corresponding to the rear heat exchanging portion 13c can remove dust from the indoor air sucked from the suction port 22 mainly. The portion of the filter 25 corresponding to the front heat exchanging portions 13a and 13b can remove dust mainly from the room air sucked from the ceiling front suction port 21. [ That is, the filter 25 can be said to prevent the surface of the indoor heat exchanger 13 from being contaminated by the dust in the room air.

Such a filter 25 is, for example, a plain weave made of resin or a twill net, formed into a ring shape (that is, on an endless belt) and spans a support frame (not shown). As shown in Fig. 3, two filters 25 provided on the support frame are provided so as to extend from the front of the air conditioning indoor unit 100 to the right side and the left side. These filters 25 are not provided with reinforcing rims or ribs that can be seen from the general filter, so that the filter 25 can not maintain its own stable shape. Therefore, the filter 25 is placed over the support frame, so that the shape of the annular shape is maintained.

(1-6) Cleaning unit

5, the cleaning unit 30 is located in the vicinity of the filter 25 in the casing 11, more specifically in the vicinity of the folded portion of the lower portion of the filter 25. As shown in Fig. The cleaning unit 30 performs not only the cleaning of the filter 25 but also the cleaning of the brush 33 (described later) for directly cleaning the filter 25. As shown in Figs. 2 to 6, A filter driving portion 32, a brush 33, a brush driving portion 34, a brush cleaning portion 35, a dust receiving portion 37, and a pressing roller 38. [

As shown in Fig. 4, the cleaning unit frame 31 has an elongated shape along the longitudinal direction (the W direction in Fig. 1) of the air conditioning indoor unit 100, and a brush 33 is detached Respectively. 5, an opening portion 31a is formed on the upper surface of the cleaning unit frame 31. The cleaning unit frame 31 is formed so that the lower portion of the lower portion of the filter 25 . A part of the brush 33 is exposed through the opening 31a of the frame 31 to the filter 25 through the opening 31a while being exposed to the space above the cleaning unit frame 31 So that they can be in direct contact with each other.

The filter driving unit 32 is for rotating the filter 25 and comprises a roller 32a and a roller motor (not shown). On the circumferential surface of the roller 32a, a so-called punched fabric base fabric is attached. The fabric bubbles on the circumferential surface of the roller 32a enter the mesh of the filter 25 and slide is hard to occur between the roller 32a and the filter 25. [ The output shaft of the roller motor is connected to the rotation shaft of the roller 32a. When the motor for the roller is driven, the roller 32a rotates and the filter 25 can rotate.

4, the brush 33 has an elongated shape along the longitudinal direction of the air conditioning indoor unit 100 like the cleaning unit frame 31, and a cross section orthogonal to the longitudinal direction of the brush 31 has a substantially circular shape . The brush (33) directly contacts the filter (25) to remove dust from the filter (25). 5, the brush 33 is composed of a core material 33a and a plurality of wire rods 33b provided on the circumferential surface of the core material 33a. The wire rods 33b, And has a length that can be contacted with the filter 25. The brush 33 is rotatably provided with respect to the cleaning unit frame 31.

The brush driving part 34 is for rotating the brush 33 and is constituted by, for example, a stepping motor. That is, the output shaft of the brush drive section 34, which is a motor, is connected to the rotation shaft of the brush 33, and the brush 33 can be rotated by driving the stepping motor. For example, when the brush 33 rotates, the movement of the filter 25 is stopped. On the contrary, when the filter 25 is moving, the brush 33 stops rotating. That is, the filter driving unit 32 and the brush driving unit 34 can move the filter 25 or the brush 33 relatively.

The brush cleaning unit 35 is attached to the cleaning unit frame 31 as shown in Fig. 5, the brush cleaning unit 35 is disposed along the rotation axis direction of the brush 33 and protrudes from the rear surface of the cleaning unit frame 31 toward the brush 33, (That is, in the direction of the arrow in the brush 33 portion of Fig. 5). Accordingly, when the brush 33 rotates in the direction of the arrow in Fig. 5, the brush cleaning portion 35 can drop dust between the wire rods 33b of the brush 33. Fig.

2 and 5, the dust receiving portion 37 is disposed below the brush 33 and the brush cleaning portion 35 in a state where the dust receiving portion 37 is attached to the cleaning unit frame 31. As shown in Fig. In the dust receiving portion 37, dust separated from the brush 33 can be collected by the brush cleaning portion 35. [ Since the dust receiving portion 37 is detachably attached to the cleaning unit frame 31, the user can take out the dust receiving portion 37 from the cleaning unit frame 31 and the casing 11 So that the dust accumulated in the dust receiving portion 37 can be easily treated.

The compression roller 38 is a cylindrical bar member and is rotatably supported by a frame 31 for the cleaning unit. Here, as shown in Fig. 5, the compression roller 38 is positioned in contact with the brush 33 in the vicinity of the brush cleaning portion 35. [ Accordingly, when the brush 33 rotates in the direction of the arrow in Fig. 5, the brush 33 follows the rotation of the brush 33 and rotates in the direction opposite to the direction of rotation of the brush 33. [ The dust gathered in the dust receiving portion 37 is compressed by the pressing roller 38, so that a relatively large amount of dust is contained in the dust receiving portion 37. Further, by the rotation of the compression roller 38, the dust having a comparatively high viscosity is reliably conveyed to the dust receptacle 37.

(1-7) supporting member

As shown in Fig. 2, the support member 40 is located above the front heat exchanging portions 13a and 13b and the rear heat exchanging portion 13c and, as shown in Figs. 3 and 6, (32) and a brush driving part (34) which are a part of the brush driving part (30). When the filter 25 is mounted on the air conditioning indoor unit 100, the filter 25 is inserted into the casing 11 from the front side of the casing 11 along the support member 40, The filter 25 is moved toward the back side of the casing 11 and supports the filter 25. The support member 40 has a rear end portion 40b which is a rear end portion in the front and rear direction and a vertex 13d of the indoor heat exchanger 13, And has a shape that is located at the rear and also at the bottom.

More specifically, the support member 40 has a substantially central portion extending along the ceiling face plate 11a of the casing 11 and also has a front end portion 40a and a rear end portion 40b Is located below the apex 13d of the indoor heat exchanger 13 so as to cover the upper portion of the indoor heat exchanger 13. In other words, paying attention only to the front end 40a and the rear end 40b, the support member 40 has a so-called inverted U shape.

As shown in Figs. 3 and 6, the support member 40 is provided with a left part (not shown) positioned with the partition part 41 extending in the front- 42 and a right side portion 43. As shown in Fig. 3, the filter 25 spanning the support frame is mounted on the upper surface of each of the portions 42, 43. The filter 25 is first inserted into the casing 11 from the front side of the casing 11 in the state of Fig. 6 and the rear end 25b of the filter 25 is inserted into the casing 11, Along the upper surface of the left portion 42 and the right portion 43 of the support member 40 until reaching the vicinity of the rear end 40b of the support member 40. [ Thus, the filter 25 is mounted on the upper surface of the support member 40 as shown in Fig. 6, the left and right end portions 42a, 42b, 43a, 43b of the left portion 42 and the right portion 43, respectively, as viewed from the front surface of the support member 40, There is provided a slide mechanism for sliding the filter 25 in addition to the cross section of the filter 25. Specifically, the slide mechanism is formed by a groove or a plurality of projections. That is, the slide mechanism in the left and right end portions 42a, 42b, 43a, and 43b of the left portion 42 and the right portion 43 is a structure for moving the filter 25 on the support member 40 And is advantageous in the case where the filter 25 is moved not only when the filter 25 is mounted on the casing 11 but also when the filter 25 is cleaned.

(1-8) Suction resistance portion

2, 7, and 8, the suction resistance portion 50 serves to prevent the flow of the air sucked from the top surface suction port 21, And is located in the vicinity of the ceiling front suction port 21. 7 is an enlarged cross-sectional view of the inside of the casing 11 in the vicinity of the ceiling plate 11a in FIG. 2. In FIG. 2, the supporting member 40 and the filter 25 are omitted. 8 is a view near the ceiling plate 11a when the air conditioning indoor unit 100 is viewed from above.

More specifically, the suction resistance portion 50 according to the present embodiment is constituted by a member separate from the ceiling plate 11a, the front plate 11b, and the back plate 11c constituting the casing 11 And is attached to the rear portion 21a of the top surface suction port 21 corresponding to the rear heat exchanging portion 13c. In other words, the suction resistance portion 50 can be regarded as a separate member located on the rear side of the ceiling suction port 21 and above the indoor fan 15. In other words, the suction resistance portion 50 is located on the rear side of the vertex 13d of the indoor heat exchanger 13 in the front-rear direction of the air conditioning indoor unit 100 along with the upward direction of the rear heat exchanger 13c Among them, the suction opening 21 is not located near the center of the ceiling suction opening 21 but may be a separate member located on the side of the back plate 11c. The rear portion 21a of the ceiling front suction port 21 refers to a portion between the apex 13d of the indoor heat exchanger 13 and the back plate 11d of the casing 11. 8, the rear heat exchanger 13c is located inside the casing 11 corresponding to the rear portion 21a, and on the contrary, from the vertex 13d of the indoor heat exchanger 13, The front heat exchanging portions 13a and 13b are located inside the casing 11 corresponding to the front portion 21b between the front plate 11b and the front plate 11b.

In addition, the material of the suction resistance portion 50 can be made of, for example, resin in the same manner as the material of the casing 11. [ Alternatively, the suction resistance portion 50 may be made of metal or the like.

8, the suction resistance portion 50 is provided along the entire length in the longitudinal direction of the ceiling face suction port 21 (that is, the direction of W in Fig. 8) in the lateral direction. As shown in Fig. 8, And has an approximately rectangular shape elongated in the lateral direction as viewed from the upper surface of the indoor unit 100. [

2, 7, and 8 according to the present embodiment, the suction resistance portion 50 is in contact with the back plate 11c of the casing 11 without any clearance, and the suction resistance portion 50 of the casing 11 (That is, on the side of the front plate 11b of the casing 11). 8 shows a case in which the suction resistance portion 50 is in contact with both the left end portion 11d and the right end portion 11e of the casing 11. In Fig.

As described above, since the suction resistance portion 50 covers the rear portion 21a of the top surface suction port 21, the amount of the room air sucked from the rear portion 21a of the top surface suction port 21 is reduced, The indoor air sucked into the inside of the casing 11 from the ceiling surface of the ceiling surface 11 of the main body 11 is mainly supplied to the portion of the ceiling front suction port 21 which is not clogged (specifically, the front portion 21b or the rear portion 21a A portion thereof). Therefore, even if the air conditioning indoor unit 100 according to the present embodiment is installed under an environmental condition in which the indoor air sucked from the ceiling front suction port 21 is increased if the suction resistance portion 50 is not provided, The increase in the indoor air sucked from the suction port 21 is suppressed to some extent by the suction resistance section 50. [

The " environmental condition " is a condition indicating the environment in which the air conditioner indoor unit 100 is installed. The environmental conditions include, for example, a relatively small distance between the ceiling of the room in the installation place of the air conditioning indoor unit 100 and the ceiling surface of the indoor unit 100, and the like.

Here, how the suction resistance portion 50 blocks the rear portion 21a of the top surface suction port 21 will be described. The suction resistance portion 50 according to the present embodiment is capable of absorbing the air sucked from the lower surface suction port 22 at an air velocity of about 0.5 m / sec or more So that the ceiling surface suction port 21 is closed. Specifically, assuming that the area of the rear portion 21a of the top surface suction port 21 is 100%, the suction resistance portion 50 blocks about 30% or more of the rear portion 21a. Further, it is preferable that the suction resistance portion 50 covers about 50% or more of the rear portion 21a. 2, 7 and 8 relating to the present embodiment show, for example, a case where the suction resistance portion 50 blocks about 60% of the rear portion 21a.

This ensures that the ratio of the amount of the room air sucked from the ceiling front suction port 21 to the amount of the room air sucked from the suction port 22 is scattered depending on the environmental conditions in which the air conditioning indoor unit 100 is installed can do. Therefore, it is possible to reduce the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port 21 to the amount of the room air sucked from the suction port 22, and the environmental condition in which the air conditioning indoor unit 100 is installed is different Therefore, the occurrence of the phenomenon that the suction port 22 does not function in some cases can be suppressed.

Concrete numerical values of how the suction resistance portion 50 blocks the rear portion 21a of the top surface suction port 21 are the same as the conditions for setting the air volume of the indoor fan 15 to the minimum air volume, Or more than about 50% or more of the air suctioned from the lower inlet port 22, the condition that the air velocity of the air sucked from the lower inlet port 22 is about 0.5 m / sec or more, Based on the above calculation, simulation, and experiment, it is determined appropriately.

(1-9) Other configuration

In addition to the above, the air conditioning indoor unit 100 is provided with an indoor control unit (not shown) for controlling various devices constituting the indoor unit 100. The indoor control unit is a microcomputer composed of a CPU and a memory, and is housed in a front portion of the casing 11. [ For example, the indoor control unit is connected to the flap motor and the indoor fan motor. By performing drive control of these motors, it is possible to control opening and closing of the horizontal flap 23a and angle control, air volume control of the indoor fan 15 .

(2) Features

(2-1)

The air conditioning indoor unit 100 according to the present embodiment is provided with a ceiling front suction port 21 and a lower suction port 22. The ceiling front suction port 21 corresponding to the rear heat exchange portion 13c is connected to the suction- (50). Accordingly, the amount of the room air sucked from the ceiling front suction port 21 is suppressed by the suction resistance portion 50. [ Therefore, even if the air conditioning indoor unit 100 according to the present embodiment is installed under an environmental condition in which the indoor air sucked from the ceiling front suction port 21 is increased if the suction resistance portion 50 is not provided, The increase in the room air sucked from the suction port 21 is suppressed to some extent by the suction resistance section 50. [ Therefore, the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port 21 to the amount of the room air sucked from the suction port 22 can be reduced, and the environmental conditions are different. Therefore, 22 is not functioning can be suppressed.

The degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port 21 to the amount of the room air sucked from the suction port 22 is reduced so that the amount of the indoor air flowing into the indoor heat exchanger 13, The deviation due to environmental conditions is also reduced. That is, the amount of the room air flowing into the indoor heat exchanger 13 is not limited to what kind of environmental condition the air conditioning indoor unit 100 is installed, and can be almost constant. Therefore, it is also possible to prevent the performance of the air conditioning indoor unit 100 from varying depending on the installation place.

(2-2)

Particularly, the suction resistance portion 50 is located at the rear portion 21a of the top surface suction port 21 corresponding to the rear heat exchanging portion 13c. As a result, the amount of room air sucked from the rear portion 21a of the ceiling front suction port 21 is reduced. Therefore, the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port 21 to the amount of the room air sucked from the suction port 22 can be further reduced.

(2-3)

The suction resistance portion 50 is simply constituted by a separate member from the casing 11 and the rear portion 21a of the ceiling suction port 21 of the casing 11 is surely blocked.

(2-4)

In addition, the suction resistance portion 50 is provided over the entire length in the longitudinal direction of the top surface suction port 21. Thus, the suction resistance portion 50 can block the top surface suction port 21 over the entire length in the longitudinal direction.

(2-5)

The suction resistance portion 50 prevents the amount of room air sucked from the top surface suction port 21 and the amount of indoor air sucked from the suction port 22 from the top surface suction port 21 by blocking about 30% or more of the rear portion 21a of the top surface suction port 21 The degree of variation in the ratio of the amount of indoor air sucked can be reduced, and the lower surface suction port 22 can reliably function.

(2-6)

Particularly, the suction resistance portion 50 prevents the amount of room air sucked from the top surface suction port 21 and the amount of indoor air sucked from the suction port 22 from the suction port 22 by blocking about 50% or more of the rear portion 21a of the top surface suction port 21 The degree of variation in the ratio of the amount of indoor air sucked can be further reduced.

(2-7)

In the present embodiment, the indoor air sucked from the rear portion 21a of the top surface suction port 21 is sucked into the suction port 22 so that the air velocity of the indoor air sucked from the lower surface suction port 22 becomes about 0.5 m / The resistance portion 50 interferes. The degree of deviation of the ratio of the amount of the room air sucked from the top surface suction port 21 and the amount of the room air sucked from the suction port 22 depending on the environmental conditions in which the air conditioning indoor unit 100 is installed .

(3) Modifications

Although the embodiment of the present invention has been described above with reference to the drawings, the specific configuration is not limited to the above embodiment but can be changed without departing from the gist of the invention.

(3-1) Modification Example A

In the above-described embodiment, the suction resistance portion 50 is formed of a member separate from the casing 11. [ However, the suction resistance portion 50 may be constituted by a part of the casing 11. Fig. In this case, the suction resistance portion 50 is configured by, for example, extending the ceiling face plate 11a of the casing 11 such that the ceiling face suction opening 21 is made small.

Thus, the suction resistance portion 50 can be easily formed, and the cost can be reduced as compared with the case where the suction resistance portion 50 is formed as a separate member.

(3-2) Variation B

2, 7, and 8 of the above embodiment, the case where the suction resistance portion 50 is in contact with the back plate 11c of the casing 11 without any clearance and extends toward the front side of the casing 11 Respectively. However, the suction resistance portion 50 may cover at least a part of the back portion 21a of the top surface suction port 21 while being separated from the back surface plate 11c.

8 of the above embodiment shows a case where the suction resistance portion 50 is in contact with both the left end portion 11d and the right end portion 11e of the casing 11. [ However, the suction resistance portion 50 may not be in contact with the left end portion 11d and / or the right end portion 11e of the casing 11, but may be separated from each other.

(3-3) Variation C

The suction resistance portion according to the present invention is provided to prevent the flow of the room air sucked from the rear portion 21a of the ceiling surface suction port 21 as described above. Therefore, the suction resistance portion may be provided so as to cover at least a part of the rear portion 21a at a position away from the ceiling face plate 11a of the casing 11 downward.

≪ Industrial Availability >

As described above, according to the present invention, it is possible to reduce the degree of deviation of the ratio of the amount of the room air sucked from the ceiling front suction port to the amount of the room air sucked from the suction port, and therefore, It is possible to suppress the occurrence of a phenomenon in which it is not possible to perform the function. Therefore, the air conditioning indoor unit related to the present invention is useful as a wall-mounted indoor unit installed under various environmental conditions.

100: air conditioning indoor unit 11: casing
11a: ceiling face plate 11b: front plate
11c: back plate 13: indoor heat exchanger
13a, 13b: front heat exchanger 13c: rear heat exchanger
15: indoor fan 17: floor frame
21: Front surface suction inlet 21a: Rear portion of the front surface suction inlet
22a: a front portion of the ceiling front suction port 22: a lower suction port
23: air outlet 25: filter
30: cleaning unit 32: filter driving unit
34: brush driving unit 40: supporting member
50: Suction resistance part

Claims (8)

As wall-type air conditioner indoor unit,
A casing 11 having a ceiling front suction port 21 provided from the front side to the rear side of the ceiling front surface and a bottom suction port 22 provided on the bottom surface,
A fan (15) located inside the casing and generating a flow of air sucked from the ceiling suction port and the lower suction port,
In the casing, a heat exchanger (13) in which front heat exchanging parts (13a, 13b) covering the front of the fan and a rear heat exchanging part (13c) covering the back of the fan are combined in an inverted V- Wow,
(21) corresponding to the rear heat exchanging part (21), and the suction heat exchanger (21) is provided to prevent the flow of air sucked from the ceiling suction port (21) And a suction resistance portion (50) for increasing the suction resistance in the suction port portion,
The fan generates a flow of air sucked from the top surface suction port and the bottom surface suction port and flowing into the rear heat exchanging part (13c)
The suction resistance portion 50 is located at the ceiling surface suction port 21 corresponding to the rear heat exchanging portion 13c,
Wherein the suction resistance portion (50) is constituted by a part of the casing (11). The method according to claim 1,
Wherein the suction resistance portion is located at a rear portion of the ceiling suction inlet and corresponds to the rear heat exchange portion. The method according to claim 1 or 2,
Wherein the suction resistance portion (50) is provided over an entire length in a longitudinal direction of the ceiling surface suction port (21). The method according to claim 1 or 2,
Wherein the suction resistance portion (50) covers at least 30% of the rear portion (21a) of the ceiling suction port (21). The method of claim 4,
Wherein the suction resistance portion (50) covers at least 50% of the rear portion (21a) of the ceiling suction port (21). The method according to claim 1 or 2,
The air speed of the air sucked from the suction port 22 is 0.5 m / sec or more. delete delete

Images