JP2016003829A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To effectively reduce noise caused by swirl air flow formed along a rotating direction of an impeller in a clearance space between a shroud and an opposing face of a bell-mouth opposed to the shroud.SOLUTION: An air conditioner includes: a bell-mouth (2) provided with an air inlet port (2A); and an impeller (6) having a shroud (8) provided with an inflow port (8A) of air guided by the bell-mouth (2). The bell-mouth (2) is opposed to the shroud (8) in an axial direction of the impeller (6), and has an opposing face (30) disposed around the inlet port (2A). The opposing face (30) includes: a first face (31); a second face (32) which is a part corresponding to a region where a structural component (5) adjacent to the bell-mouth (2) is disposed and projects more to a shroud (8) side from the first face (31); and an inclined face (33) disposed between the first face (31) and the second face (32).

Description

  The present invention relates to an air conditioner including a bell mouth and an impeller.

  2. Description of the Related Art Conventionally, an air conditioner including a bell mouth provided with an air inlet and an impeller having a shroud provided with an air inlet guided by the bell mouth is known. When the impeller is rotated by the fan motor, an air flow (main flow) is formed in the casing of the air conditioner. That is, the indoor air sucked into the casing is guided by the bell mouth and flows into the impeller, and the air blown out of the impeller is cooled or exchanged by exchanging heat with the refrigerant when passing through the heat exchanger. Heated. The heat-exchanged air is blown out of the casing and supplied into the room. In addition to such a mainstream, the following swirling airflow is formed in the casing.

  For example, in an indoor unit of a ceiling-embedded air conditioner, the bell mouth has a facing surface that faces the shroud in the axial direction of the impeller. A gap space is formed between the facing surface and the shroud. In this gap space, an air flow (swirl airflow) swirling along the rotation direction is formed as the impeller rotates.

  By the way, the ceiling-embedded indoor unit includes various structural components (for example, electrical component units) inside the casing. In the ceiling-embedded indoor unit, the electrical component unit is usually arranged adjacent to the bell mouth. When the indoor unit is thinned, a step may be formed on the facing surface of the bell mouth by projecting a portion corresponding to the region where the electrical component unit is disposed to the shroud side with respect to the other portion. . Such a level difference disturbs the swirling airflow in the gap space and causes noise.

  Patent Literature 1 discloses an air conditioner in which the position of the upper surface periphery of the outer peripheral portion of the bell mouth is the same as the position of the upper surface of the inner peripheral wall of the drain pan in a state where the bell mouth is attached to the drain pan. Has been. In the air conditioner of this patent document 1, since there is no level | step difference in the connection part of a bell mouth and a drain pan, it is supposed that noise can be reduced.

JP 2013-108684 A

  However, if the gap space between the bell mouth and the shroud is narrowed over the entire circumferential direction in order to eliminate the step as in Patent Document 1, the flow velocity of the air flowing through the gap space increases. Since the noise is approximately proportional to the sixth power of the wind speed, when the flow velocity of the swirling airflow in the gap space is increased as in Patent Document 1, the noise may be increased.

  An object of the present invention is to provide noise caused by the swirling airflow in an air conditioner in which a swirling airflow is formed along the rotation direction of the impeller in a gap space between the shroud and the facing surface of the bell mouth facing the shroud. Is effectively reduced.

  The air conditioner of the present invention has a bell mouth (2) provided with an air inlet (2A) and a shroud (8) provided with an air inlet (8A) guided by the bell mouth (2). ) Having an impeller (6). The bell mouth (2) has a facing surface (30) provided around the suction port (2A) while facing the shroud (8) in the axial direction of the impeller (6). The facing surface (30) is a portion corresponding to a region where the first surface (31) and the structural component (5) adjacent to the bell mouth (2) are disposed, and from the first surface (31). And a second surface (32) protruding toward the shroud (8), and an inclined surface (33) provided between the first surface (31) and the second surface (32).

  In this configuration, the facing surface (30) of the bell mouth (2) facing the shroud (8) includes an inclined surface (33) provided between the first surface (31) and the second surface (32). ing. Therefore, in this configuration, the swirling airflow swirling along the rotation direction (D) in the gap space (S) between the facing surface (30) and the shroud (8) is the first surface (31) and the second surface. (32) is smoothly guided by the inclined surface (33). For this reason, it can suppress that a whirling air current is disturbed between a 1st surface (31) and a 2nd surface (32), and can suppress that a noise becomes large as a result. Moreover, in this configuration, the flow velocity of the air flowing through the gap space (S) is larger than that in the case where the gap space between the bell mouth and the shroud is narrowed by eliminating the step in the entire circumferential direction as in Patent Document 1. Can be suppressed. From the above, in this configuration, noise caused by the swirling airflow in the gap space (S) can be effectively reduced.

  The said air conditioner WHEREIN: The said inclined surface (33) follows the rotation direction (D) of the said impeller (6) in the clearance gap (S) between the said opposing surface (30) and the said shroud (8). Rotation of the impeller (6) in the gap space (S) and the first inclined surface (33A) for guiding the flowing air (swirl airflow) from the first surface (31) to the second surface (32) It is preferable to include a second inclined surface (33B) for guiding the air (swirl airflow) flowing along the direction (D) from the second surface (32) to the first surface (31).

  In this configuration, the first inclined surface (33A) is provided between the upstream side of the rotation direction (D) in the second surface (32) and the first surface (31), and the rotation direction in the second surface (32). A second inclined surface (33B) is provided between the downstream side of (D) and the first surface (31). Therefore, in this configuration, the swirling airflow flowing from the first surface (31) toward the second surface (32) along the rotation direction (D) in the gap space (S) is caused by the first inclined surface (33A). The whirling airflow that is smoothly guided and flows from the second surface (32) toward the first surface (31) along the rotation direction (D) is smoothly guided by the second inclined surface (33B). Therefore, in this structure, the effect which suppresses noise can be heightened compared with the case where only any one of a 1st inclined surface (33A) and a 2nd inclined surface (33B) is provided.

  In the air conditioner, the bell mouth (2) is attached to the bell mouth main body (20) in which the suction port (2A) is formed and the bell mouth main body (20). ) And the second surface (32) may be provided with a step reducing member (26) for reducing the step.

  In this configuration, since the step reducing member (26) for reducing the step between the first surface (31) and the second surface (32) is provided, the first surface (31), the second surface (32), Disturbance of the swirling airflow flowing along the inclined surface (33) between the two can be reduced. In this configuration, the inclination angle of the inclined surface (33) with respect to the first surface (31) and the second surface (32) is designed to be smaller than that in the case where the step reducing member (26) is not provided. Is also possible. As described above, the inclination angle of the inclined surface (33) is reduced, whereby the degree of change in the direction of the swirling airflow in the gap space (S) can be reduced. Thereby, the disturbance of the swirling airflow can be further reduced.

  In the air conditioner, the structural component (5) is an electrical component unit (5), and the bell mouth (2) is disposed on a side surface (51) of the electrical component unit (5) on the back side of the inclined surface (33). ), And the back surface (34) is provided so as to be inclined with respect to the side surface (51) of the electrical component unit (5). It is preferable that a gap (G) is formed between the side surface (51) of the product unit (5).

  In this configuration, the back surface (34) on the back side of the inclined surface (33) is provided so as to be inclined with respect to the side surface (51) of the electrical component unit (5), whereby the back surface (34) and the electrical component unit (5) are provided. A gap (G) is formed between the side surface (51). Therefore, when the electrical component unit (5) has a component that easily generates heat (for example, an inverter circuit), the heat generated in the electrical component unit is caused by the gap between the back surface (34) and the side surface (51) ( G) is easily dissipated.

  According to the present invention, in an air conditioner in which a swirling airflow is formed along the rotation direction of the impeller in a gap space between the shroud and the facing surface of the bell mouth facing the shroud, noise caused by the swirling airflow is reduced. It can be effectively reduced.

It is sectional drawing which shows the indoor unit of the air conditioner which concerns on embodiment of this invention. It is the figure which looked at the inside of the indoor unit of the air conditioner which concerns on embodiment from the bottom. It is a perspective view which shows a bell mouth and a shroud, and fractured | ruptured partially in order to explain the flow of air (swirl airflow) formed along the rotation direction of an impeller in the clearance gap between bellmouth and a shroud I am letting. It is a perspective view which shows the bell mouth and electrical component unit in the indoor unit of the air conditioner concerning a reference example. (A) is a top view which shows the bell mouth and electrical component unit in the indoor unit of the air conditioner which concerns on a reference example, (B) is a left view, (C) is the right view. is there. It is a perspective view which shows the bell mouth and electrical component unit in the indoor unit of the air conditioner according to the embodiment. (A) is a top view which shows the bell mouth and electrical component unit in the indoor unit of the air conditioner according to the embodiment, (B) is a left side view, and (C) is a right side view thereof. is there. It is an exploded three-dimensional view showing a bell mouth and an electrical component unit in the indoor unit of the air conditioner according to the embodiment. It is a graph which shows the evaluation result which compared the characteristic of embodiment and the characteristic of a reference example. It is a perspective view which shows the modification 1 of embodiment. It is a side view which shows the modification 1 of embodiment. It is a perspective view which shows the modification 2 of embodiment. It is a side view which shows the modification 2 of embodiment. (A) is a top view which shows the modification 3 of embodiment, (B) is a top view which shows the modification 4 of embodiment, (C) is a plane which shows the modification 5 of embodiment. FIG.

[Air conditioner indoor unit]
Hereinafter, an indoor unit of an air conditioner according to an embodiment of the present invention will be described in detail with reference to the drawings. Below, although the case where the air conditioner of this embodiment is a ceiling embedded type indoor unit embedded in a ceiling is mentioned as an example, it is not restricted to this. The air conditioner of the present invention may be, for example, a ceiling-suspended indoor unit that is suspended from a ceiling, an indoor unit that is installed on a floor, an indoor unit that is installed on a wall, or the like. Moreover, the structure of this invention can also be applied to the outdoor unit of an air conditioner. In the following description, the radial direction is a direction parallel to the radial direction of the impeller 6, and the axial direction is a direction parallel to the direction of the rotation axis A of the impeller 6.

  An indoor unit 1 shown in FIG. 1 includes a casing 15 having a box shape embedded in an opening provided in a ceiling, and a panel 11 (decorative panel 11) attached to a lower portion of the casing 15. In the casing 15, a bell mouth 2, a centrifugal fan 16, a heat exchanger 12, a drain pan 13, and an air filter 14 are provided.

  The panel 11 is slightly larger in plan view than the casing 15 and is exposed indoors in a state of covering an opening provided in the ceiling. The panel 11 has an air inlet 11A provided at the center thereof, and a plurality of air outlets 11C provided around the inlet 11A. In the present embodiment, four outlets 11C are provided, but the number of outlets 11C is not limited to this. The suction port 11A is provided with a rectangular suction grill 11B. The four air outlets 11 </ b> C are provided along the four sides of the panel 11. Each outlet 11C has an elongated shape extending along the corresponding side.

  The centrifugal fan 16 in this embodiment shown in FIGS. 1 and 2 is a turbo fan, and includes an impeller 6 and a fan motor 10 that rotates the impeller 6. The impeller 6 includes a hub 7, a shroud 8, and a plurality of blades 9. The hub 7 is fixed to the shaft 10 </ b> A of the fan motor 10 fixed to the top plate of the casing 15.

  The shroud 8 is disposed closer to the bell mouth 2 than the hub 7. The shroud 8 has an air inlet 8 </ b> A that opens in a circular shape around the rotation axis A of the impeller 6. The outer diameter of the shroud 8 becomes larger toward the hub 7 side in the axial direction of the rotation axis A.

  The plurality of blades 9 are arranged between the hub 7 and the shroud 8 at a predetermined interval along the circumferential direction of the inflow port 8A. One end of each blade 9 in the axial direction (end on the shroud 8 side) is joined to the inner surface of the shroud 8. The other end in the axial direction of each blade 9 (the end on the hub 7 side) is joined to the hub 7.

  As shown in FIG. 2, each blade 9 is a backward blade whose blade outlet is inclined to the opposite side to the rotation direction D. Each blade 9 has a pressure surface 91 facing radially outward and a suction surface 92 on the opposite side. Each blade 9 has a front edge 93 which is a portion where the air flow guided by the shroud 8 first contacts, and a rear edge 94 which is the rearmost end of the blade 9 and where the air flow finally contacts.

  The bell mouth 2 is disposed closer to the panel 11 than the shroud 8. The bell mouth 2 has an air inlet 2A that opens in a circular shape around the rotation axis A. The end of the bell mouth 2 is disposed in the air inlet 8 </ b> A of the shroud 8. The suction port 2A of the bell mouth 2 has a curved shape whose outer diameter decreases toward the hub side. Details of the bell mouth 2 will be described later.

  As shown in FIGS. 1 and 2, the heat exchanger 12 is provided so as to surround the impeller 6. The heat exchanger 12 has a flat shape with a small thickness, and is disposed at a position through which air blown out from the centrifugal fan 16 (main flow F0) passes. In the embodiment shown in FIG. 1, the heat exchanger 12 is disposed on the radially outer side of the impeller 6 in a state of standing upward from a dish-shaped drain pan 13 extending along the lower end portion thereof. The heat exchanger 12 is provided so as to be interposed between the impeller 6 and the side wall 15 </ b> A of the casing 15.

  As the heat exchanger 12, for example, a fin-and-tube heat exchanger can be used, but is not limited thereto. The heat exchanger 12 includes a plurality of fins that are spaced apart from each other and a plurality of heat transfer tubes that pass through the fins. In the heat exchanger 12, heat is exchanged between the refrigerant passing through the heat transfer tube and the air around the fins.

  The drain pan 13 stores water droplets generated in the heat exchanger 12. The stored water is discharged through a drainage path (not shown). The air filter 14 has a size that covers the inlet of the bell mouth 2, and is provided between the bell mouth 2 and the suction grill 11B along the suction grill 11B. The air filter 14 captures dust contained in the air sucked into the casing 15 from the suction grill 11B.

  In the indoor unit 1, when the impeller 6 of the centrifugal fan 16 is rotated by the fan motor 10, an air flow F0 (main flow F0) indicated by a two-dot chain line in FIG. That is, the indoor air sucked from the suction grill 11 </ b> B is guided by the bell mouth 2, flows into the impeller 6, and is blown out from the impeller 6. The air blown out from the impeller 6 is cooled or heated by exchanging heat with the refrigerant flowing in the heat transfer tubes when passing through the heat exchanger 12. And the heat-exchanged air is supplied into the room from the outlet 11C.

[Noise suppression structure]
Next, the noise suppression structure in the indoor unit 1 of the air conditioner according to the present embodiment will be described. In the casing 15 of the indoor unit 1, not only the main flow F0 shown in FIG. 1 but also a swirling air flow F1 as shown in FIG. 3 is formed. The shroud 8 has a guide surface 81 that guides the main flow F0 and a back surface 82 on the back side (the lower surface of the shroud 8 in FIG. 3). The bell mouth 2 has a facing surface 30 that faces the back surface 82 of the shroud 8 in the axial direction. The swirling air flow F <b> 1 is an air flow generated in the gap space S between the back surface 82 of the shroud 8 and the facing surface 30 of the bell mouth 2. The air in the clearance space S turns in the rotation direction D as the impeller 6 rotates in the rotation direction D. Thereby, a swirling airflow is formed in the gap space S. The swirling airflow F1 is swirling at a speed approximately the same as the rotational speed of the impeller 6, for example.

  The indoor unit 1 according to the present embodiment can effectively reduce noise caused by the swirling airflow F1. Before describing the noise suppression structure in the present embodiment, an indoor unit of an air conditioner of a reference example will be described for comparison with the present embodiment.

  In the indoor unit of the air conditioner according to the reference example shown in FIGS. 4 and 5, the bell mouth 102 has a facing surface 130 that faces the shroud in the axial direction of the impeller. The facing surface 130 is provided around the suction port 102 </ b> A of the bell mouth 102. In the reference example, the electrical component unit 5 is disposed adjacent to the bell mouth 102. The electrical component unit 5 extends in one direction D1 orthogonal to the rotational axis A of the impeller 6 on the radially outer side of the suction port 102A.

  In the thinned indoor unit, there is not much room in the space in the casing. For this reason, a part of the bell mouth 102 is closer to the shroud side than the other part by the volume corresponding to a part of the electrical component unit 102. It protrudes. Accordingly, the facing surface 130 includes a first surface 131 corresponding to a region where the electrical component unit 5 is not disposed, a second surface 132 corresponding to a region where the electrical component unit 5 is disposed, the first surface 131 and the first surface 131. And a step surface 133 that connects the step with the second surface 132. The step surface 133 is a plane orthogonal to the first surface 131 and the second surface 132.

  In the reference example, since such a step surface 133 is formed, the swirling airflow F1 flowing in the rotation direction of the impeller in the gap space is formed on the step surface 133 when moving from the first surface 131 to the second surface 132. Since the collision occurs, the stepped surface 133 is disturbed, and when moving from the second surface 132 to the first surface 131, the stepped surface 133 is disturbed. Such disturbance of the swirling airflow F1 causes noise.

  In the embodiment shown in FIGS. 6 and 7, the electrical component unit 5 is disposed adjacent to the bell mouth 2 as in the reference example. As shown in FIGS. 2, 6, and 7, the electrical component unit 5 extends in one direction D1 orthogonal to the rotational axis A of the impeller 6 on the radially outer side of the suction port 2A. For this reason, a part of the bell mouth 2 protrudes to the shroud 8 side than the other part.

  Therefore, the opposing surface 30 includes a first surface 31 corresponding to a region where the electrical component unit 5 is not disposed and a second surface 32 corresponding to a region where the electrical component unit 5 is disposed. In the present embodiment, the second surface 32 is a plane orthogonal to the axial direction, but is not limited thereto. In addition, although the electrical component unit 5 has a rectangular parallelepiped shape, for example, it is not restricted to this. The electrical component unit 5 includes, for example, a box-shaped case and a plurality of electrical components disposed in the case.

  In the present embodiment, the facing surface 30 further includes an inclined surface 33 provided between the first surface 31 and the second surface 32. The inclined surface 33 is a surface that is inclined with respect to the first surface 31 and the second surface 32. The inclined surface 33 smoothly connects the first surface 31 and the second surface 32 as compared to the step surface 133 of the reference example. In the present embodiment, the edge 331 on the first surface 31 side in the inclined surface 33 is in contact with or close to the first surface 31, and the edge 332 on the second surface 32 side in the inclined surface 33 is the second surface 332. It is in contact with or close to the surface 32. A slight gap may be formed between the inclined surface 33 and the first surface 31, and a slight gap may be formed between the inclined surface 33 and the second surface 32.

  In the present embodiment, the swirling airflow F <b> 1 flowing in the rotation direction D of the impeller 6 in the gap space S is smoothly guided on the inclined surface 33 between the first surface 31 and the second surface 32. For this reason, it can suppress that the swirl | vortex airflow F1 is disturbed like a reference example between the 1st surface 31 and the 2nd surface 32, As a result, it can suppress that a noise becomes large.

  In the present embodiment, the inclined surface 33 includes the first inclined surface 33A that guides the swirling airflow F1 from the first surface 31 to the second surface 32 in the gap space S, and the swirling airflow F1 in the gap space S as the second surface. 32 and a second inclined surface 33 </ b> B guiding from the first surface 31 to the first surface 31. In the present embodiment, a first inclined surface 33A that connects the upstream side of the second surface 32 in the rotational direction D and the first surface 31 is provided, and the downstream side of the second surface 32 in the rotational direction D and the first surface 31 are provided. The 2nd inclined surface 33B which connects is provided. Therefore, in this embodiment, as shown in FIGS. 14A and 14B, which will be described later, as compared with Modifications 3 and 4 in which only one of the first inclined surface 33A and the second inclined surface 33B is provided. Thus, the effect of suppressing noise can be enhanced.

  The outline of the noise suppression structure in the present embodiment is as described above. Hereinafter, the noise suppression structure in the present embodiment will be described more specifically. The noise suppression structure in the present invention is not limited to the following specific examples.

  As shown in FIGS. 3 and 6, the bell mouth 2 includes a duct portion 24 and a peripheral portion 25 provided around the duct portion 24. The duct portion 24 is a portion that forms the suction port 2A, and has a substantially cylindrical shape. The duct portion 24 has an inner diameter that decreases toward the hub 7 side. Further, the hub-side tip portion 24E (the upper end portion of the duct portion 24 in FIG. 3) of the duct portion 24 may have a constant inner diameter in the axial direction or may increase in diameter toward the hub 7 side. Good.

  The front end 24E of the duct portion 24 overlaps the front end 8E on the panel 11 side of the shroud 8 (the lower end of the shroud 8 in FIG. 3). That is, the front end portion 24E of the duct portion 24 is disposed inside the front end portion 8E of the shroud 8, and faces the front end portion 8E of the shroud 8 in the radial direction. The duct portion 24 is a part of the bell mouth 2 that is located radially inward from the inner peripheral surface of the tip portion 8E of the shroud 8. The tip 8E of the shroud 8 forms an inlet 8A of the shroud 8.

  The peripheral portion 25 is a part of the bell mouth 2 that is located radially outside the inner peripheral surface of the tip portion 8E of the shroud 8. The peripheral portion 25 is connected to the upstream side of the duct portion 24 (the upstream side in the flow direction of the main flow F0 in the duct portion 24). The radially inner portion of the peripheral portion 25 (the portion on the duct portion 24 side in the peripheral portion 25) has an inner diameter that decreases toward the duct portion 24 so as to be smoothly connected to the duct portion 24. In the present embodiment, the radially outer portion of the peripheral portion 25 has a flat plate shape, but is not limited thereto, and may be, for example, a curved shape.

  FIG. 8 is an exploded view showing the bell mouth 2 and the electrical component unit 5 in the present embodiment. As shown in FIG. 8, in this embodiment, the bell mouth 2 consists of a plurality of members. Specifically, the bell mouth 2 includes a bell mouth main body 20 and a slope portion 23. The bell mouth main body 20 and the slope portion 23 are formed as separate bodies and are joined to each other.

  The bell mouth body 20 includes a first portion 21 and a second portion 22. The slope portion 23 includes a first slope portion 23A and a second slope portion 23B. The first portion 21 and the second portion 22 are formed as separate bodies, and the first slope portion 23A and the second slope portion 23B are formed as separate bodies. However, the bell mouth 2 may be one in which the bell mouth main body 20 and the slope portion 23 are integrally formed as shown in Modification 2 (see FIG. 12) described later.

  The first portion 21 of the bell mouth main body 20 has a first surface 31 of the facing surface 30, and the second portion 22 has a second surface 32 of the facing surface 30. The first portion 21 is provided with a duct portion 24. The peripheral portion 25 is provided in the first portion 21 and the second portion 22. In the present embodiment, the second portion 22 is flat so as to match the surface shape of the electrical component unit 5, but is not limited thereto.

  The slope portion 23 has an inclined surface 33. Specifically, the first slope portion 23A has a first inclined surface 33A, and the second slope portion 23B has a second inclined surface 33B. In the present embodiment shown in FIGS. 6 and 8, the slope portion 23 has a surface 35 (the lower surface 35 of the slope portion 23 in FIG. 8) that faces the surface of the first portion 21. The surface 35 of the slope portion 23 has a shape along the surface of the first portion 21. Further, the slope portion 23 includes an end surface of the second portion 22 (in FIG. 8, a side end surface of the second portion 22 on the suction port 2A side) and a side surface 51 of the electrical component unit 5 (on the suction port 2A side of the electrical component unit 5). And a surface 36 facing the side surface 51). The slope portion 23 is joined to the bell mouth body 20 by means such as adhesion or fusion.

  The inclined surface 33 of the slope portion 23 includes at least one of a flat surface, a convex curved surface, and a concave curved surface such that the first surface 31 and the second surface 32 are smoothly connected. The inclined surface 33 includes at least one of a straight line and a curve in a cross section when the slope portion 23 is cut along a plane parallel to the axial direction. Examples of the curve include an arc and a spline curve.

  FIG. 9 is a graph showing evaluation results comparing the characteristics of the present embodiment shown in FIGS. 6 and 7 and the characteristics of the reference example shown in FIGS. 4 and 5. As shown in FIG. 9, in the test conditions in which the air volume by the centrifugal fan 16 of the present embodiment and the air volume of the centrifugal fan of the reference example are the same value, the blowing sound is reduced in this embodiment compared to the reference example. I understand that.

[Summary of Embodiment]
As described above, in the embodiment, the facing surface 30 of the bell mouth 2 facing the shroud 8 includes the inclined surface 33 provided between the first surface 31 and the second surface 32. Therefore, the swirling airflow F1 flowing along the rotation direction D in the gap space S between the facing surface 30 and the shroud 8 is smoothly smoothed by the inclined surface 33 that smoothly connects the first surface 31 and the second surface 32. Be guided to. Thus, since the inclined surface 33 can reduce the influence of the step between the first surface 31 and the second surface 32, the swirling air flow F1 is disturbed between the first surface 31 and the second surface 32. Can be suppressed. As a result, increase in noise can be suppressed. Moreover, in the present embodiment, the flow velocity of the air flowing through the gap space S becomes larger than in the case where the gap space between the bell mouth and the shroud is narrowed by eliminating the step in the entire circumferential direction as in Patent Document 1. Can be suppressed. From the above, it is possible to effectively reduce noise caused by the swirling airflow formed along the circumferential direction in the gap space S.

  In the present embodiment, the inclined surface 33 guides the air flowing along the rotational direction D of the impeller 6 from the first surface 31 to the second surface 32 in the gap space S between the facing surface 30 and the shroud 8. The first inclined surface 33 </ b> A and the second inclined surface 33 </ b> B for guiding the air flowing along the rotation direction D of the impeller 6 in the gap space S from the second surface 32 to the first surface 31 are included. In the gap space S between the facing surface 30 and the shroud 8, the first inclined surface 33A guides the air flowing along the rotational direction D of the impeller 6 from the first surface 31 to the second surface 32, and the second inclined surface The surface 33 </ b> B guides the air flowing along the rotation direction D of the impeller 6 from the second surface 32 to the first surface 31. That is, in the present embodiment, the first inclined surface 33A that connects the upstream side in the rotational direction D on the second surface 32 and the first surface 31 is provided, and the downstream side in the rotational direction D on the second surface 32 and the first surface 31. The 2nd inclined surface 33B which connects is provided. Therefore, in this embodiment, as shown in FIGS. 12A and 12B, which will be described later, as compared with Modifications 3 and 4 in which only one of the first inclined surface 33A and the second inclined surface 33B is provided. Thus, the effect of suppressing noise can be enhanced.

[Modification]
FIG. 10 is a perspective view showing a first modification of the embodiment, and FIG. 11 is a side view thereof. 10 and 11, the bell mouth 2 is different from the above-described embodiment in that the bell mouth 2 includes a step reducing member 26 that reduces the step between the first surface 31 and the second surface 32. Yes.

  The step reducing member 26 is attached to a part of the surface of the bell mouth main body 20 on the shroud 8 side. Specifically, the step reducing member 26 is provided around the suction port 2 </ b> A along the surface on the shroud 8 side in the first portion 21 of the bell mouth main body 20. The step reducing member 26 is not provided on the surface of the second portion 22 of the bell mouth main body 20 on the shroud 8 side. The step reducing member 26 is a plate-like member that is molded separately from the bell mouth main body 20. In Modification 1, the surface on the shroud 8 side of the step reducing member 26 (the upper surface of the step reducing member 26 in FIGS. 10 and 11) constitutes the first surface 31 of the facing surface 30.

  In the first modification, the step reducing member 26 that reduces the step between the first surface 31 and the second surface 32 is provided, and therefore, along the inclined surface 33 between the first surface 31 and the second surface 32. The turbulence of the swirling airflow F1 flowing through can be reduced. Moreover, in the modification 1, the inclination | tilt angle of the inclined surface 33 with respect to the 1st surface 31 and the 2nd surface 32 is the case where the level | step difference reduction member 26 is not provided (for example, FIG.6 and FIG.7 (A)-(C)). Compared to the embodiment shown in FIG. Thus, the inclination angle of the inclined surface 33 is reduced, so that the degree of change in the direction of the swirling airflow F1 in the gap space S can be reduced. Thereby, the disturbance of the swirl airflow F1 can be further reduced.

  In the specific examples shown in FIGS. 10 and 11, the thickness of the step reducing member 26 is set to ½ of the step (height difference) between the first surface 31 and the second surface 32, but is not limited thereto. Absent. However, in the first modification, if the thickness of the step reducing member 26 is increased too much, the entire gap space S becomes narrow, and the flow velocity of the air flowing through the gap space S increases. Therefore, in the first modification, the thickness of the step reduction member 26 is preferably 2/3 or less of the step between the first surface 31 and the second surface 32, and the step between the first surface 31 and the second surface 32. Is less than or equal to ½, and more preferably less than or equal to １ ／ of the step between the first surface 31 and the second surface 32.

  FIG. 12 is a perspective view showing a second modification of the present embodiment, and FIG. 13 is a side view thereof. In Modification 2 shown in FIGS. 12 and 13, a gap G is formed between the bell mouth 2 and the side surface 51 of the electrical component unit 5.

  Specifically, in the second modification, the bell mouth 2 has a back surface 34 facing the side surface 51 of the electrical component unit 5 on the back side of the inclined surface 33. By providing the back surface 34 so as to be inclined with respect to the side surface 51 of the electrical component unit 5, a gap G is formed between the back surface 34 and the side surface 51 of the electrical component unit 5.

  In the second modification, when the electrical component unit 5 has a component that easily generates heat, such as an inverter circuit, for example, the gap G between the back surface 34 of the bell mouth 2 and the side surface 51 of the electrical component unit 5. Functions as a space for dissipating heat generated in the electric component unit.

  In the second modification, the bell mouth 2 is formed by integrally forming the bell mouth main body 20 and the slope portion 23, but is not limited thereto. For example, as shown in FIG. 8, the bell mouth main body 20 and the slope portion 23 are formed as separate bodies, and the back surface 34 is provided so as to be inclined with respect to the side surface 51 of the electrical component unit 5. A gap G may be formed between the back surface 34 and the side surface 51 of the electrical component unit 5.

  FIG. 14A is a plan view showing a third modification of the embodiment, FIG. 14B is a plan view showing a fourth modification of the embodiment, and FIG. 14C is a plan view of the embodiment. It is a top view which shows the modification 5. FIG. 14A, the inclined surface 33 has a first inclined surface 33A for guiding the swirling air flow F1 from the first surface 31 to the second surface 32 in the gap space S, while FIG. The second inclined surface 33B as shown in A) is not provided. 14 (B), the inclined surface 33 has a second inclined surface 33B that guides the swirling airflow F1 from the second surface 32 to the first surface 31 in the gap space S, while FIG. The first inclined surface 33A as shown in A) is not provided.

  14C, the inclined surface 33 includes the first inclined surface 33A that guides the swirling airflow F1 from the first surface 31 to the second surface 32 in the gap space S, and the swirling airflow in the gap space S. A second inclined surface 33B for guiding F1 from the second surface 32 to the first surface 31; In the embodiment shown in FIG. 7A described above, the first inclined surface 33 </ b> A and the second inclined surface 33 </ b> B are provided beside one side surface 51 of the electrical component unit 5, and are adjacent along the side surface 51. It is arranged side by side to fit. On the other hand, in the modified example 5 shown in FIG. 14C, the length of the electrical component unit 5 is shorter than that in the embodiment shown in FIG. Therefore, the first inclined surface 33A is provided beside the side surface 51 of the electrical component unit 5, while the second inclined surface 33B is provided beside the side surface 52 different from the side surface 51 of the electrical component unit 5. It has been. When the electrical component unit 5 has a rectangular parallelepiped shape, for example, the side surface 52 is a side surface adjacent to the side surface 51.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to these embodiment, A various change, improvement, etc. are possible in the range which does not deviate from the meaning.

  In the embodiment, the structural component adjacent to the bell mouth 2, that is, the structural component that causes the second surface 32 to protrude from the first surface 31 to the shroud 8 side on the facing surface 30 of the bell mouth 2 is the electrical component unit 5. The case of being was illustrated. However, such a structural component is not limited to the electrical component unit 5 and may be another component such as a drain pan or a heat exchanger adjacent to the bell mouth 2.

DESCRIPTION OF SYMBOLS 1 Indoor unit of air conditioner 2 Bell mouth 2A Air inlet in bell mouth 5 Electrical component unit as an example of structural part 8 Shroud 8A Air inlet in shroud 20 Bell mouth main body 21 First part of bell mouth main body 22 The second portion of the bell mouth body 23 The slope portion 26 The step reducing member 30 The facing surface 31 The first surface of the facing surface 32 The second surface of the facing surface 33 The inclined surface of the facing surface 33A The first inclined surface 33B The second inclined surface 34 Bell mouth Back side of the back side of the inclined surface in 51 Side surface in the electrical component unit A Shaft of the impeller (rotary shaft)
D Rotation direction of impeller F0 Main air flow F1 Swirl airflow G Gap S Gap space

Claims (4)

A bell mouth (2) provided with an air inlet (2A);
An impeller (6) having a shroud (8) provided with an air inlet (8A) guided by the bell mouth (2),
The bell mouth (2) has an opposing surface (30) provided around the suction port (2A) while facing the shroud (8) in the axial direction of the impeller (6),
The opposing surface (30)
The first surface (31);
A second surface (32) corresponding to a region where the structural component (5) adjacent to the bell mouth (2) is disposed and projecting toward the shroud (8) from the first surface (31); ,
An air conditioner comprising: an inclined surface (33) provided between the first surface (31) and the second surface (32). The inclined surface (33)
Air flowing along the rotational direction (D) of the impeller (6) in the gap space (S) between the facing surface (30) and the shroud (8) is transferred from the first surface (31) to the first surface. A first inclined surface (33A) for guiding the second surface (32);
Second inclined surface (33B) for guiding the air flowing along the rotational direction (D) of the impeller (6) from the second surface (32) to the first surface (31) in the gap space (S). The air conditioner according to claim 1, comprising: The bell mouth (2)
A bell mouth body (20) in which the suction port (2A) is formed;
The step reduction member (26) which makes a level | step difference of the said 1st surface (31) and the said 2nd surface (32) small by being attached to the said bellmouth main body (20) is provided in Claim 1 or 2 The air conditioner described. The structural component (5) is an electrical component unit (5),
The bell mouth (2) has a back surface (34) facing the side surface (51) of the electrical component unit (5) on the back side of the inclined surface (33),
The back surface (34) and the side surface (51) of the electrical component unit (5) are provided by tilting the back surface (34) with respect to the side surface (51) of the electrical component unit (5). The air conditioner according to any one of claims 1 to 3, wherein a gap (G) is formed between the two.

Images