JP2012077952A - Indoor unit of air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an indoor unit of an air conditioner which can reduce a draft resistance.SOLUTION: A bottom plate 15 includes a decorative sheet 25 which is located under a filter 23 and is arranged nearly horizontally. A suction port 17 is extended along the edge of the decorative sheet 25 at a position out of the center of an inlet port 21. A guide member 33 is provided in a suction passage 31 wherein air sucked from the suction port 17 runs toward the filter 23, so as to guide the air sucked from the suction port 17 to a region on the central side of the inlet port 21 in the filter 23.

Description

  The present invention relates to an indoor unit of an air conditioner.

  Conventionally, an indoor unit of an air conditioner in which a suction port is provided in a bottom plate portion of a casing is known. As this type of indoor unit, for example, a ceiling-mounted indoor unit that is installed on a ceiling in a room can be cited. Examples of the ceiling-mounted indoor unit include a ceiling-embedded indoor unit that is installed by being embedded in the back of the ceiling through an opening provided in the ceiling, and a ceiling-mounted indoor unit that is installed suspended from the ceiling. This ceiling-mounted indoor unit includes a fan, a heat exchanger, a filter, and the like housed in a casing.

  For example, in a ceiling-embedded indoor unit, most of the casing is disposed behind the ceiling, and the bottom plate portion of the casing closes the opening and is exposed to the room. The filter is disposed between the fan and the bottom plate portion. The bottom plate portion has a decorative frame located at the peripheral edge thereof, and a decorative plate (shielding plate) located within the frame of the decorative frame. The shielding plate is disposed directly under the filter so as to cover the filter from below. The bottom plate portion is provided with an air inlet and an outlet formed along the edge of the shielding plate.

  Patent Document 1 discloses a ceiling-embedded indoor unit having a bottom plate portion that is substantially rectangular in bottom view. As shown in FIG. 1 of Patent Document 1, the bottom plate portion of the indoor unit is provided with two suction ports along two opposing edge portions of the shielding plate. The fan is disposed approximately in the center of the casing. A filter having a size capable of covering the entire lower portion of the fan is disposed below the fan, and a shielding plate is disposed below the filter. That is, the suction port is provided outside the shielding plate, and is at a position shifted outward from the center of the air inlet of the fan (rotation center of the impeller).

JP 2005-188768 A

  As in the indoor unit of Patent Document 1, when the suction port of the bottom plate portion is shifted to the outside from the center of the inflow port of the fan, the air flowing into the casing from the suction port follows a curved path. As a result, the airflow resistance tends to increase. When the draft resistance increases, the fan noise may increase.

  Therefore, the present invention has been made in view of such points, and an object of the present invention is to provide an indoor unit of an air conditioner that can reduce ventilation resistance.

  The indoor unit of the air conditioner of the present invention includes a casing (13) having a bottom plate portion (15) provided with an air inlet (17), and the casing (13). A fan (19) having an inlet (21); and a filter (23) disposed between the fan (19) and the bottom plate (15). The bottom plate portion (15) has a decorative plate (25) disposed below the filter (23) and disposed substantially horizontally. The suction port (17) extends along the edge (251) of the decorative plate (25) at a position shifted from the center of the inflow port (21). In the suction flow path (31) in which the air sucked from the suction port (17) flows toward the filter (23), the air sucked from the suction port (17) is passed through the filter (23). A guide member (33) is provided for guiding to a central region of the inflow port (21).

  As described above, in the indoor unit in which the suction port (17) of the bottom plate portion (15) is shifted outward from the center of the inlet (21) of the fan (19), the casing ( 13) The air that has flowed into the air follows the curved path and reaches the inlet (21) of the fan (19). In the process, when the air flowing into the casing (13) from the suction port (17) passes through the filter (23), the air is part of the filter (23), that is, the inlet (21). It becomes easy to concentrate on the area shifted from the center to the outside. When air concentrates on a partial area of the filter (23), the resistance when passing through the filter (23) in that area increases.

  Therefore, in the present configuration, the guide member (33) is provided in the suction flow path (31). The guide member (33) guides the air sucked from the suction port (17) to a region on the center side of the inflow port (21) in the filter (23). Therefore, in this configuration, air reaching the filter (23) can be dispersed on the center side of the inflow port (21) as compared with the case where the guide member (33) is not provided. Concentration in a partial area of (23) can be suppressed. This reduces the resistance when air passes through the filter (23).

  In the indoor unit, for example, the guide member (33) is a plate-like body extending along the extending direction of the suction port (17), and the upper end (332) is more than the lower end (331). It is preferably located on the center side of the inlet (21).

  In this configuration, the air that has flowed into the suction flow path (31) from the suction port (17) is guided along the plate-shaped guide member (33) to the center side of the inflow port (21). Thereby, since the air which reaches | attains a filter (23) can be disperse | distributed by the center side of an inflow port (21), it can suppress that air concentrates on the one part area | region of a filter (23).

  In the indoor unit, the lower end portion (331) of the guide member (33) is preferably located closer to the suction port (17) than the filter (23).

  In this configuration, since the lower end portion (331) of the guide member (33) is disposed closer to the suction port (17), the air flowing into the suction flow path (31) from the suction port (17) It reaches the lower end (331) of the guide member (33) at an early stage of the process of moving from (17) to the filter (23), and thereafter the inlet (in the filter (23) along the guide member (33) ( 21) is guided to the central area. Therefore, in this configuration, the air guiding effect by the guide member (33) can be further enhanced.

  In the indoor unit, it is more preferable that the lower end portion (331) of the guide member (33) is located at substantially the same height as the suction port (17).

  In this configuration, since the lower end portion (331) of the guide member (33) is disposed at substantially the same height as the suction port (17), the air that has flowed into the suction flow path (31) from the suction port (17). Immediately thereafter, reaches the lower end portion (331) of the guide member (33), and thereafter is guided along the guide member (33) to the region on the center side of the inlet (21) in the filter (23). . Therefore, in this configuration, the air guiding effect by the guide member (33) can be further enhanced.

  In the indoor unit, the lower end portion (331) of the guide member (33) is arranged in the width direction of the suction port (17) perpendicular to the extending direction than the center of the suction port (17). It is preferable that it exists in the position close | similar to the said edge part (251) of a board (25).

  As shown in the graph of FIG. 4 to be described later, when the lower end portion (331) of the guide member (33) is disposed closer to the edge portion (251) of the decorative plate (25), the opposite is true. Compared with the case where it is arranged on the side, the effect of reducing the ventilation resistance tends to increase.

  In the indoor unit, an inner wall surface that is located on the outer side in the width direction perpendicular to the extending direction than the guide member (33) and functions as an air guide surface on the outer side in the width direction in the suction channel (31). (29) is preferably provided. In this case, the upper end (332) of the guide member (33) is connected to the upper end of the inner wall surface (29) and the edge of the decorative plate (25). It is preferable that it is located between the virtual plane (S) straddling the part (251) and the filter (23).

  In the indoor unit, in the space between the inner wall surface (29) and the edge portion (251) of the decorative plate (25), air flows into the inner wall surface (29) and the edge portion (251) of the decorative plate (25). To flow to the filter (23) side. That is, air is guided to the filter (23) side from the suction port (17) to the virtual plane (S) by the inner wall surface (29) and the edge (251) of the decorative plate (25). In this configuration, since the upper end portion (332) of the guide member (33) is disposed further on the filter (23) side than the virtual plane (S), the guide member (33) moves closer to the filter (23) side than the virtual plane (S). Then, the air is guided to the filter (23) side by the guide member (33). Therefore, in this configuration, the air can be guided closer to the filter by the guide member.

  In the indoor unit, the lower end (331) of the guide member (33) is located at the same position as the edge of the filter (23) when viewed from the bottom, or more than the edge of the filter (23). The upper end portion (332) of the guide member (33) is at the same position as the edge portion (251) of the decorative plate (25) or the decorative plate (25). ) In the center side of the inlet (21) with respect to the edge (251).

  In this configuration, since the lower end portion (331) and the upper end portion (332) of the guide member (33) are in the positional relationship described above with respect to the filter (23) and the edge portion (251) of the decorative plate (25), Even when the end portion of the filter (23) is directly above the suction port (17), the end portion of the filter (23) is covered by the guide member (33) disposed below the end portion. . Therefore, even if the indoor unit is viewed from below by the user, the user cannot see the filter (23) from the suction port (17), so that the aesthetics can be improved.

  Further, in this configuration, in order to prevent the filter (23) from being seen from the suction port (17), it is not necessary to adopt another means such as reducing the width of the suction port or reducing the filter. If the other means is adopted, there is a problem that the ventilation resistance is increased and the noise of the fan is increased, and if the filter is reduced, the maintenance interval of the filter is shortened. Can be avoided.

  In the indoor unit, the guide member (33) is curved from the lower end (331) toward the upper end (332) so that the surface on the decorative plate (25) side is concave. preferable.

  In this configuration, since the guide member (33) has the curved shape as described above, the air is guided more smoothly along the guide member (33) toward the filter (23).

  In the indoor unit, an inner wall surface that is located on the outer side in the width direction perpendicular to the extending direction than the guide member (33) and functions as an air guide surface on the outer side in the width direction in the suction channel (31). (29) is preferably provided. In this case, in the cross section perpendicular to the extending direction, the guide member (33) includes a lower end portion of the inner wall surface (29) and the decorative plate (25). On the straight line connecting the first point (Pm) on the straight line connecting the edge (251) and the upper end of the inner wall surface (29) and the edge (251) of the decorative board (25). The distance (Lm ′) from the first point (Pm) to the edge (251) of the decorative board (25) through the second point (Pn), and the inner wall (29) Ratio (Lm) to the distance (Lm) from the lower end to the edge (251) of the decorative panel (25) ′ / Lm) is the distance (Ln ′) from the second point (Pn) to the edge (251) of the decorative plate (25) and the upper end of the inner wall (29). The ratio (Ln ′ / Ln) to the distance (Ln) to the edge (251) of the plate (25) is preferably substantially the same.

  In this configuration, since the guide member (33) is disposed so as to pass through the first point (Pm) and the second point (Pn) which are in the positional relationship as described above, the ventilation resistance is further reduced. be able to.

  In the indoor unit, the distance (Lm ′) from the first point (Pm) to the edge (251) of the decorative plate (25) and the lower end of the inner wall surface (29) The ratio (Lm ′ / Lm) to the distance (Lm) to the edge (251) of the decorative board (25) is more preferably in the range of 0.2 to 0.4.

  As shown also in the graph of FIG. 4 described later, when the ratio (Lm ′ / Lm) is in the range of 0.2 to 0.4, a remarkable effect of reducing the ventilation resistance is obtained.

  As described above, according to the present invention, since the guide member that guides the air sucked from the suction port to the region on the center side of the inflow port in the filter, the ventilation resistance can be reduced.

(A) is a perspective view which shows the ceiling embedded type indoor unit concerning one Embodiment of this invention, (B) is the bottom view. It is sectional drawing which shows the said ceiling embedded type indoor unit. (A) And (B) is sectional drawing which expanded the suction inlet vicinity of the said ceiling embedded type indoor unit shown in FIG. 2, and demonstrates the shape and arrangement | positioning of the guide member provided in the said ceiling embedded type indoor unit. FIG. It is a graph which shows the relationship between the arrangement | positioning position of the said guide member, and resistance. (A) is sectional drawing which expanded the suction inlet vicinity of the said ceiling embedded type indoor unit, (B) and (C) are sectional drawings which respectively show the modification of the shape of the suction inlet vicinity. (A) is sectional drawing which shows the flow of the air which flowed in from the said suction inlet of the said ceiling embedded type indoor unit, (B) is the flow of the air which flowed in from the suction inlet of the conventional ceiling embedded type indoor unit. It is sectional drawing shown. (A) is sectional drawing which shows the pressure distribution in the casing of the said ceiling embedded indoor unit, (B) is sectional drawing which shows the pressure distribution in the casing of the conventional ceiling embedded indoor unit. (A) is sectional drawing which shows the other example of arrangement | positioning of the said guide member. (B) is an enlarged cross-sectional view of the vicinity of a suction port of a conventional ceiling-embedded indoor unit, and (C) is an enlarged cross-sectional view of the vicinity of a suction port of a ceiling-embedded indoor unit of a reference example.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. As shown in FIGS. 1 (A), (B) and FIG. 2, an indoor unit 11 of an air conditioner according to the present embodiment is installed by being embedded in the back of the ceiling through an opening provided in an indoor ceiling T. It is an embedded indoor unit. The indoor unit 11 includes a casing 13, a fan 19, a filter 23, a heat exchanger 41, and a drain pan 45 disposed in the casing 13.

  The casing 13 includes a top plate portion 51, a front plate portion 52 and a rear plate portion (not shown) facing the direction D1, a side plate portion 53 and a side plate portion 54 facing the direction D2, and a bottom plate portion 15. Yes. As shown in FIG. 1B, the casing 13 has a substantially rectangular parallelepiped shape whose longitudinal direction D1 (hereinafter referred to as the longitudinal direction D1) is longer than the width direction D2 perpendicular thereto. The top plate portion 51, the front plate portion 52, the rear plate portion, and the pair of side plate portions 53 and 54 are arranged on the back of the ceiling, and the bottom plate portion 15 closes the opening of the ceiling T and is exposed indoors. .

  The bottom plate portion 15 includes a decorative frame 27 and a decorative plate 25 positioned within the frame of the decorative frame 27. The decorative frame 27 includes a peripheral edge portion 271 and a pair of partitioning portions 272. The peripheral edge portion 271 constitutes the peripheral edge of the bottom plate portion 15 and has a substantially rectangular outer shape. The peripheral edge portion 271 has two edge portions extending substantially parallel to the longitudinal direction D1 and two edge portions extending substantially parallel to the width direction D2.

  Each partition 272 spans the two edges extending in the width direction D2 and extends substantially parallel to the longitudinal direction D1. One partition portion 272 is disposed with a predetermined gap between one partition portion 272 extending in the width direction D2. The other partition portion 272 is disposed with a predetermined gap between the other partition portion 272 and the other edge portion extending in the width direction D2. These gaps function as air outlets 18 and 18. Each air outlet 18 has an elongated rectangular shape extending along the partition portion 272. Each air outlet 18 is provided with a flap 43 for changing the wind direction.

  The decorative board 25 is instructed in a state of being stretched over the two edge portions of the peripheral edge portion 271 extending in the width direction D2, and is disposed substantially horizontally. The decorative plate 25 is substantially rectangular in the longitudinal direction D1 longer than the width direction D2, and is disposed between the pair of partition portions 272. The decorative plate 25 is disposed below the filter so as to cover most of the filter 23 from below. The edge portions 251 and 251 located on both sides of the decorative plate 25 in the width direction D2 have arc-shaped cross-sections such that the end sides of the flat plate are folded upward and inward.

  The pair of partitioning portions 272 are disposed with a predetermined gap from the adjacent edge portions 251. These gaps function as air inlets 17 and 17. Each suction port 17 has an elongated rectangular shape extending along the partition portion 272. Each suction port 17 is provided at a position shifted from the center (a straight line C described later) of the inlet 21 of the fan 19. Each suction port 17 is located between the edge portion 251 of the decorative plate 25 and the partition portion 272 of the decorative frame 27.

  In the present embodiment, the region functioning as an inlet into which air is sucked into the casing 13 is only the pair of suction ports 17 and 17 described above, and the decorative plate 25 itself is provided with a through-hole for air suction and the like. Not limited to this. In the indoor unit 11, the main inlet for air intake is an inlet provided at a position shifted from the center (straight line C) of the inlet 21 of the fan 19 (for example, the pair of inlets 17 of the present embodiment, 17), for example, a through-hole or a slit may be provided in a part of the decorative plate 25 as an auxiliary air inlet.

  For example, a centrifugal blower or the like can be used as the fan 19. Although the fan 19 of this embodiment is a turbo fan, other centrifugal blowers, such as a sirocco fan, may be used, and other blowers other than a centrifugal blower may be used. The fan 19 includes an impeller, a motor 19d connected to the impeller via a rotation shaft 19e, and a bell mouth 19c disposed below the impeller.

  The impeller includes a hub 19a, a shroud 19f, and a plurality of blades 19b. The motor 19 d is fixed to the approximate center of the top plate portion 51. The rotating shaft 19e extends downward from the motor 19d. A hub 19a is fixed to the lower end of the rotating shaft 19e. The impeller rotates about a straight line C passing through the center of the rotation shaft 19e by driving the motor 19d.

  The bell mouth 19c is disposed below the shroud 19f. The bell mouth 19c has an air inlet 21 penetrating in the vertical direction D3. The inflow port 21 has a circular opening in a bottom view. The center of the inlet 21 is substantially located on a straight line C passing through the center of the rotation shaft 19e.

  The heat exchanger 41 has a flat shape with a small thickness. The heat exchanger 41 is disposed so as to surround the periphery of the impeller while standing upward from a dish-shaped drain pan 45 extending along the lower end thereof. The drain pan 45 stores water droplets generated in the heat exchanger 41. The stored water is discharged through a drainage path (not shown).

  The filter 23 is disposed between the fan 19 and the bottom plate portion 15. As shown in FIG. 2, the filter 23 has a flat shape, and slightly intersects the horizontal direction so as to intersect the air flow direction on the path from each suction port 17 to the inlet 21 of the fan 19. It is arranged in a substantially V shape with an inclined posture. In addition, the filter 23 is not limited to a substantially V-shaped form as shown in FIG. 2, and may be disposed, for example, in a posture extending substantially parallel to the horizontal direction.

  When the fan 19 is driven, indoor air is sucked into the casing 13 through each suction port 17. A guide member 33 is provided in the suction flow path 31 in which air sucked from the suction port 17 flows toward the filter 23.

  The guide member 33 guides a part of the air sucked from the suction port 17 to the straight line C side in the suction flow path 31. Thereby, compared with the case where the guide member 33 is not provided, the ratio of the air which passes the site | part of the center side (straight line C side) of the inflow port 21 in the filter 23 increases.

  The guide member 33 is a plate-like body extending along the extending direction of the suction port 17 (longitudinal direction D1 in the present embodiment). The guide member 33 is supported by the bottom plate portion 15 such as the decorative plate 25 and the decorative frame 27, for example.

  In the guide member 33, the upper end portion 332 is located closer to the center side (the straight line C side) of the inflow port 21 than the lower end portion 331. The lower end 331 of the guide member 33 is located at substantially the same height as the suction port 17.

  Each guide member 33 is curved from the lower end portion 331 toward the upper end portion 332 so that the surface on the decorative plate 25 side is concave. Each partition portion 272 of the decorative frame 27 has an inner wall surface 29 that functions as an air guide surface on the decorative plate 25 side in the suction flow path 31. Each inner wall surface 29 is a concave surface that is curved. Each guide member 33 has a shape along the curved shape of the corresponding inner wall surface 29.

  Each guide member 33 is positioned as follows, for example. 3A and 3B are enlarged cross-sectional views of the vicinity of the suction port 17 of the indoor unit 11 shown in FIG. 2, and the shape and arrangement of the guide member 33 provided in the indoor unit 11 will be described. FIG. In this arrangement example, as shown in FIGS. 3A and 3B, the guide member 33 passes through the first point Pm and the second point Pn in the cross section perpendicular to the longitudinal direction D1. Are arranged as follows. More preferably, as shown in FIG. 3B, the guide member 33 has an arc shape that is curved so that a perpendicular line Lp drawn downward from the first point Pm in the vertical direction is a tangent line at the first point Pm. Formed.

  The first point Pm is a point on a straight line connecting the lower end portion of the inner wall surface 29 and the edge portion 251 of the decorative plate 25. The second point Pn is a point on a straight line connecting the upper end portion of the inner wall surface 29 and the edge portion 251 of the decorative plate 25. Here, the edge portion 251 of the decorative board 25 in the present embodiment has an arc-shaped cross section in which the edge of the flat plate is folded upward and inward as described above, so the first point Pm and The second point Pn can be positioned as follows, for example.

  When determining the first point Pm, the outer end portion (end portion in the width direction D2) 251a of the edge portion 251 is used as a reference. Moreover, as a lower end part of the inner wall surface 29, a part where the straight line M extending in the horizontal direction from the outer end part 251a intersects the inner wall surface 29 is defined as a lower end part 29a.

  When the second point Pn is determined, the upper end 251b which is the uppermost part of the edge 251 is used as a reference. Further, as the upper end portion of the inner wall surface 29, the end point of the curved shape of the inner wall surface 29 is defined as the upper end portion 29b. In the case of this embodiment, the end point of the curved shape, as shown in FIG. 3A, is the upper end portion of the inner wall surface 29 that is curved and smoothly changes the surface inclination (surface direction), This is a boundary portion with the side surface of the drain pan 45. The second point Pn is a point on the straight line N connecting the upper end portion 29b and the upper end portion 251b of the edge portion 251.

  The first point Pm and the second point Pn are positioned so that the ratio (Lm ′ / Lm) shown in FIG. 3A is substantially the same as the ratio (Ln ′ / Ln). preferable. The ratio (Lm ′ / Lm) is a ratio between the distance Lm ′ from the first point Pm to the edge 251 of the decorative board 25 and the distance Lm from the lower end of the inner wall surface 29 to the edge 251 of the decorative board 25. It is. The ratio (Ln ′ / Ln) is determined by the distance Ln ′ from the second point Pn to the edge 251 of the decorative board 25 and the distance Ln from the upper end of the inner wall surface 29 to the edge 251 of the decorative board 25. Ratio.

  Further, the lower end portion 331 of the guide member 33 is preferably located closer to the edge portion 251 of the decorative board 25 than the center of the suction port 17 in the width direction (width direction D2) of the suction port 17. Specifically, as shown in the graph of FIG. 4, the ratio (Lm ′ / Lm) is preferably less than 0.5, and the ratio (Lm ′ / Lm) is 0.2 to 0.4. More preferably, it is in the range. When the ratio (Lm ′ / Lm) is in the range of 0.2 to 0.4, the ventilation resistance is reduced by 20% or more. In the graph of FIG. 4, the resistance ratio on the vertical axis indicates the ventilation resistance of the indoor unit 11 of the present embodiment when the ventilation resistance when the guide member 33 is not provided is “1.0”. ing.

  In the form shown in FIG. 3B, the lower end 331 of the guide member 33 is at the first point Pm and the upper end 332 is at the second point Pn, but is not limited thereto. For example, as shown in FIG. 5A, the upper end portion 332 of the guide member 33 may extend further to the filter 23 side than the second point Pn. Although not shown, the lower end 331 of the guide member 33 may extend further below the first point Pn. In the form shown in FIG. 5A, the upper end 332 of the guide member 33 is located between the filter 23 and the virtual plane S straddling the upper end of the inner wall surface 29 and the edge 251 of the decorative plate 25. Yes. The virtual plane S here is defined as follows in the case of the form shown in FIGS. 5B and 5C, for example.

  First, in the form shown in FIG. 5B, the inner wall surface 29 is arranged on the first inner wall surface 291 that is an air guide surface provided on each partition portion 272 of the decorative frame 27 and the upper portion of the partition portion 272. And a second inner wall surface 292 that is an air guide surface formed by a part of the lower surface of the member (drain pan 45 in the present embodiment). The second inner wall surface 292 is connected to the upper end of the first inner wall surface 291, and forms a guide surface that is continuous with the first inner wall surface 291. 5B, the upper end portion 29b of the inner wall surface 29 is an end portion on the lower surface of the drain pan 45 (an end portion on the filter 23 side). Note that the first inner wall surface 291 of the partition portion 272 may be a combination of a plane extending in the vertical direction and a plane extending obliquely upward, as shown in FIG.

  Similarly, in the form shown in FIG. 5C, the inner wall surface 29 is arranged on the first inner wall surface 291 that is an air guide surface provided on each partition part 272 of the decorative frame 27 and on the upper part of the partition part 272. And a second inner wall surface 292 that is an air guide surface formed by a part of the lower surface of the member (the drain pan 45 in the present embodiment). Similarly, in the case of the configuration shown in FIG. 5B, the upper end portion 29 b of the inner wall surface 29 becomes an end portion (end portion on the filter 23 side) of the lower surface of the drain pan 45.

  FIG. 6A and FIG. 6B are diagrams showing the flow of air with streamlines by numerical analysis. FIG. 6A is a cross-sectional view showing the flow of air flowing in from the suction port 17 of the indoor unit 11, and FIG. 6B flows in from the suction port 17 of the indoor unit in which the guide member 33 is not provided. It is sectional drawing which shows the flow of air. In FIGS. 6A and 6B, the area where the air flow rate is high has a high degree of streamline density, and the area where the air flow rate is low has a low streamline density. Except for the presence or absence of the guide member 33, the configuration of the indoor unit of FIG. 6A and the other part of the indoor unit of FIG. Moreover, in the indoor unit of FIG. 6 (A) and the indoor unit of FIG. 6 (B), the total amount of the air which flows in from the suction inlet 17 was set to the same value.

  As shown in FIGS. 6 (A) and 6 (B), by providing a guide member 33 in the suction flow path 31, the air sucked from the suction port 17 is moved to the straight line C side (inlet 21 on the filter 23). It can be seen that the ratio of the air flowing to this area is increased by being guided to the area on the center side of the area. Further, as can be seen by comparing the arrow H1 in FIG. 6A and the arrow H2 in FIG. 6B, by providing the guide member 33, the air flows in a wider range of the filter 23, The filter 23 can be used more effectively. Further, as shown in FIG. 6B, when the guide member 33 is not provided, it can be seen that the vortex F is generated in the vicinity of the inner wall surface 29 and the suction flow path cannot be used effectively. .

  FIG. 7A and FIG. 7B are diagrams showing the pressure distribution by isobars by numerical analysis. 7A is a cross-sectional view showing the pressure distribution in the casing 13 of the indoor unit 11, and FIG. 7B is a cross-sectional view showing the pressure distribution in the casing of the indoor unit in which the guide member 33 is not provided. It is. In FIG. 7 (A) and FIG. 7 (B), one scale of the isobar shows a pressure of 5 Pa. Except for the presence or absence of the guide member 33, the configuration of the indoor unit of FIG. 6A and the other part of the indoor unit of FIG.

  In the indoor unit 11 of FIG. 7A, the pressure difference between the position A and the position B was 35 Pa. On the other hand, in the indoor unit of FIG. 7B, the pressure difference between position A and position B was 48 Pa. When the guide member 33 is provided in this way, the pressure difference between the inside of the casing 13 and the outside becomes small, and it can be seen that the resistance when air is sucked into the casing 13 from the suction port 17 becomes small.

  FIG. 8A is a cross-sectional view showing another arrangement example of the guide member. FIG. 8B is an enlarged cross-sectional view of the vicinity of the suction port of the conventional ceiling-embedded indoor unit, and FIG. 8C is an enlarged cross-sectional view of the vicinity of the suction port of the ceiling-embedded indoor unit of the reference example. .

  As shown in FIG. 8A, in this embodiment, the lower end portion 331 of the guide member 33 is located at substantially the same position as the edge portion 23a of the filter 23 when viewed from the bottom. Further, the upper end portion 332 of the guide member 33 is substantially at the same position as the edge portion 251 of the decorative plate 25 when viewed from the bottom. On the other hand, in the conventional indoor unit shown in FIG. 8B, the guide member is not provided, so that the filter 23 is viewed from below through the suction port 17. Further, if the filter 23 is made small as shown in FIG. 8C so that the filter 23 cannot be seen through the suction port 17, the ventilation resistance becomes large and the maintenance interval of the filter becomes short.

  As described above, in the embodiment, the guide member 33 provided in the suction channel 31 guides the air sucked from the suction port 17 to the region on the center side of the inlet 21 in the filter 23. Therefore, in this configuration, air reaching the filter 23 can be dispersed on the center side of the inflow port 21 as compared with the case where the guide member 33 is not provided. It is possible to suppress concentrating on. Thereby, the resistance when air passes through the filter 23 is reduced.

  In the embodiment, the air that has flowed into the suction flow path 31 from the suction port 17 is guided to the center side of the inflow port 21 along the plate-shaped guide member 33. Thereby, since the air reaching the filter 23 can be dispersed on the center side of the inflow port 21, it is possible to suppress the air from being concentrated on a partial region of the filter 23.

  Moreover, in the said embodiment, since the lower end part 331 of the guide member 33 is arrange | positioned at the substantially same height as the suction inlet 17, the air which flowed in in the suction flow path 31 from the suction inlet 17 immediately follows the guide member. After reaching the lower end 331 of 33, it is guided along the guide member 33 to the area on the center side of the inlet 21 in the filter 23. Therefore, in this configuration, the air guiding effect by the guide member 33 can be further enhanced.

  Moreover, in the said embodiment, since the lower end part 331 of the guide member 33 is arrange | positioned near the edge part 251 of the decorative board 25, the reduction effect of ventilation resistance increases more compared with the case where it arrange | positions on the opposite side. There is a tendency.

  In the embodiment, the lower end 331 of the guide member 33 is located at the same position as the edge of the filter 23 when viewed from the bottom, and the upper end 332 of the guide member 33 is viewed from the bottom when viewed from the bottom. Since it is in the same position as the edge part 251 of 25, the edge part of the filter 23 is covered with the guide member 33 arrange | positioned under it. Therefore, even if the indoor unit 11 is viewed by the user from below, the user cannot see the filter 23 from the suction port 17, so that the aesthetics can be improved.

  In the embodiment, when the guide member 33 has a curved shape, the air is smoothly guided toward the filter 23 along the guide member 33.

  Moreover, when the guide member 33 is disposed so as to pass through the first point Pm and the second point Pn as described above, the ventilation resistance can be further reduced. In particular, when the ratio (Lm ′ / Lm) is in the range of 0.2 to 0.4, a remarkable effect of reducing the ventilation resistance can be obtained.

(Other embodiments)
Note that the present invention is not limited to the above-described embodiment, and various modifications and improvements can be made without departing from the spirit of the present invention. For example, in the above-described embodiment, a ceiling-embedded indoor unit has been described as an example of an indoor unit of an air conditioner. However, the present invention is not limited to this. The present invention also applies to other indoor units (for example, a ceiling-mounted indoor unit) in which a bottom plate portion is provided with an air inlet, and the inlet is provided at a position shifted from the center of the inflow port of the fan. Can be applied.

  In the above embodiment, the case where the decorative frame and the decorative plate constituting the bottom plate are separate from each other has been described as an example, but the decorative frame and the decorative plate may be an integral member.

  In the said embodiment, although the guide member 33 is extended in D1 direction at the same length as the suction inlet 17, it is not limited to this. For example, the guide member may have a shape installed only in the vicinity of the fan.

  In the embodiment, the case where the guide member has a curved shape has been described as an example, but the present invention is not limited to this. For example, the guide member may be a flat plate inclined toward the center of the inflow port of the fan with respect to the vertical direction, or may have a shape combining a curved portion and a flat plate portion.

  In the above embodiment, the case where the lower end portion 331 of the guide member 33 is located at substantially the same height as the suction port 17 has been described as an example. May be located. However, the lower end 331 of the guide member 33 is preferably located at a position closer to the suction port 17 than the filter 23.

  In the above embodiment, the case where the guide member 33 is positioned as shown in FIGS. 3A and 3B has been described as an example, but the present invention is not limited to this. In the present invention, the ratio (Lm ′ / Lm) is not necessarily the same as the ratio (Ln ′ / Ln).

  In the embodiment, the case where one guide member 33 is provided in each suction flow path 31 is described as an example, but two or more guide members 33 may be provided in parallel in each suction flow path 31.

DESCRIPTION OF SYMBOLS 11 Indoor unit 13 Casing 15 Bottom plate part 17 Inlet 18 Outlet 19 Fan 21 Fan air inflow port 23 Filter 25 Decorative plate 251 Decorative plate edge 27 Decorative frame 271 Decorative frame peripheral portion 272 Decorative frame partition 29 Wall surface 31 Suction flow path 33 Guide member 331 Lower end portion 332 of guide member Upper end portion C of guide member Rotation center of impeller (center of inlet)
Lm ′ Distance from the first point to the edge of the decorative plate Lm Distance from the lower end of the inner wall surface to the edge of the decorative plate Ln ′ Distance from the second point to the edge of the decorative plate Ln Upper end of the inner wall surface Distance Pm from edge to edge of decorative plate First point Pn Second point S Virtual plane

Claims (10)

A casing (13) having a bottom plate (15) provided with an air inlet (17);
A fan (19) disposed in the casing (13) and having an air inlet (21) at the bottom;
An air conditioner indoor unit comprising a filter (23) disposed between the fan (19) and the bottom plate (15),
The bottom plate portion (15) has a decorative plate (25) located below the filter (23) and disposed substantially horizontally.
The inlet (17) extends along the edge (251) of the decorative plate (25) at a position deviated from the center of the inlet (21),
In the suction flow path (31) in which the air sucked from the suction port (17) flows toward the filter (23), the air sucked from the suction port (17) is passed through the filter (23). The indoor unit of an air conditioner provided with a guide member (33) for guiding to a region on the center side of the inflow port (21).   The guide member (33) is a plate-like body extending along the extending direction of the suction port (17), and the upper end (332) is closer to the center of the inflow port (21) than the lower end (331). The indoor unit of the air conditioner according to claim 1, which is located at   The indoor unit of an air conditioner according to claim 2, wherein the lower end portion (331) of the guide member (33) is located closer to the suction port (17) than the filter (23).   The indoor unit of an air conditioner according to claim 3, wherein the lower end (331) of the guide member (33) is located at substantially the same height as the suction port (17).   The lower end portion (331) of the guide member (33) has a width direction of the suction port (17) perpendicular to the extending direction of the decorative plate (25) rather than the center of the suction port (17). The indoor unit of the air conditioner according to any one of claims 2 to 4, wherein the indoor unit is at a position close to the edge (251). An inner wall surface (29) is provided outside the guide member (33) in the width direction perpendicular to the extending direction and functions as an air guide surface outside the width direction in the suction flow path (31). And
The upper end portion (332) of the guide member (33) includes a virtual plane (S) straddling the upper end portion of the inner wall surface (29) and the edge portion (251) of the decorative plate (25), and the filter. The indoor unit of an air conditioner according to any one of claims 2 to 5, which is located between (23) and (23). The lower end (331) of the guide member (33) is located at the same position as the edge of the filter (23) or outside the edge of the filter (23) when viewed from the bottom. ,
The upper end portion (332) of the guide member (33) is the same position as the edge portion (251) of the decorative plate (25) or the edge portion (25) of the decorative plate (25) when viewed from the bottom. The indoor unit of the air conditioner according to any one of claims 2 to 6, wherein the indoor unit is located at a position closer to the center of the inlet (21) than 251).   The said guide member (33) is curving toward the said upper end part (332) from the said lower end part (331) so that the surface at the side of the said decorative board (25) may become concave. The indoor unit of the air conditioner of any one of Claims. An inner wall surface (29) is provided outside the guide member (33) in the width direction perpendicular to the extending direction and functions as an air guide surface outside the width direction in the suction flow path (31). And
In the cross section perpendicular to the extending direction, the guide member (33) is a first straight line connecting the lower end portion of the inner wall surface (29) and the edge portion (251) of the decorative plate (25). Passing through the point (Pm) and a second point (Pn) on a straight line connecting the upper end of the inner wall surface (29) and the edge (251) of the decorative plate (25),
The distance (Lm ′) from the first point (Pm) to the edge (251) of the decorative plate (25) and the lower end of the inner wall surface (29) to the decorative plate (25) The ratio (Lm ′ / Lm) to the distance (Lm) to the edge (251) is the distance (Ln ′) from the second point (Pn) to the edge (251) of the decorative board (25). ) And the distance (Ln '/ Ln) from the upper end of the inner wall surface (29) to the edge (251) of the decorative plate (25). The indoor unit of the air conditioner described in 8. The distance (Lm ′) from the first point (Pm) to the edge (251) of the decorative plate (25) and the lower end of the inner wall surface (29) to the decorative plate (25) The air conditioner indoor unit according to claim 9, wherein a ratio (Lm '/ Lm) to a distance (Lm) to the edge (251) is in a range of 0.2 to 0.4.