JP5293684B2 - Air conditioner indoor unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the following problem: generation of noise is caused by unevenness in distribution of discharged air pressure at an outer periphery of a turbo fan due to unevenness in distance between a heat exchanger and the turbo fan. <P>SOLUTION: In an indoor unit of an air conditioner in which the polygonal heat exchanger is disposed in a state of surrounding the outer periphery of the turbo fan having the cylindrical shape as a whole, a size of a clearance gap as a radial clearance between a cylindrical part of a shroud of the turbo fan and a duct part of a bell mouth is not constant in the circumferential direction, and the distance between the turbo fan and the heat exchanger at a part of a long distance, is determined to be long in comparison with that of a part of a short distance. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to an indoor unit of an air conditioner, and more particularly to an indoor unit of an air conditioner that generates an air flow using a turbo fan that is one type of centrifugal fan.

  The indoor unit of the air conditioner is installed indoors (rooms such as houses and offices) that perform air conditioning. The indoor air sucked from the suction port is heat-exchanged with the refrigerant circulating in the refrigeration cycle using a heat exchanger, In the heating operation, the indoor air is warmed, and in the cooling operation, the indoor air is cooled and blown into the room again from the outlet. For this purpose, a fan (blower fan) is provided inside the indoor unit body. Contains a heat exchanger.

  There are various types of indoor units for air conditioners, such as wall-mounted, floor-standing, ceiling-suspended, and ceiling-embedded types, but ceiling-embedded indoor units have a circular turbo that is a type of centrifugal fan. The arrangement is such that a heat exchanger surrounds the fan, and the turbo fan sucks room air in the direction of its rotational axis and discharges it from the outer periphery of the fan to the centrifugal direction (radially outward) over 360 degrees. When the indoor air that has passed through the turbofan passes through a heat exchanger that surrounds the fan, the indoor air exchanges heat with the refrigerant, is warmed or cooled, and is blown into the room from the outlet.

  Since the indoor unit of an air conditioner is mainly installed in a space where people exist, there is a high demand for low noise. In order to meet such demands, in an indoor unit of an air conditioner that uses a turbo fan as a conventional blowing means, a substantially rectangular heat exchanger surrounding the circular turbo fan is at a long distance from the turbo fan. Some corner portions are provided with a rectifying guide between the fan and the heat exchanger. By installing this rectifying guide, the uneven exhaust air pressure in the circumferential direction on the outer periphery of the turbo fan based on the non-uniformity of the distance between the turbo fan and the heat exchanger is corrected to reduce the blowing noise and the pressure loss of the exhaust air pressure It is intended to reduce this. (For example, refer to Patent Document 1).

  In addition, downstream of the bell mouth located on the inner peripheral side at a portion where the suction cylinder (bell mouth) for guiding air to the inlet of the shroud of the turbofan and the shroud overlap each other in a radial direction through a predetermined gap having a constant circumference. The end is bent in the centrifugal direction according to the curved shape of the shroud located on the outer peripheral side, and a part of the air flowing out from the turbofan flows into the turbofan again from the radial gap between the bell mouth and the shroud. There is one in which the direction of circulating flow is directed to the centrifugal direction. The direction in which the circulating flow blows out from the gap is aligned with the main flow of the turbo fan that flows into the turbo fan through the inner circumference of the bell mouth and flows in the centrifugal direction. The turbulence is suppressed, and noise caused by the flow turbulence is reduced and the air blowing performance is improved. (For example, refer to Patent Document 2).

JP 2003-83599 A (columns 0005 to 0010, FIG. 1, etc.) JP 2008-138536 A (columns 0088 to 0105, FIG. 3, FIG. 5, etc.)

  The installation of the rectifying guide shown in Patent Document 1 can alleviate the non-uniformity of the ventilation resistance due to the difference in the distance between the heat exchanger and the turbofan, but the air at the corner of the heat exchanger located downstream of the rectifying guide Becomes difficult to flow, and the heat exchange performance of the heat exchanger decreases. In order to compensate for this decrease, it is necessary to increase the rotation speed of the turbofan, and noise increases with the increase in rotation speed, which cannot be said to be effective in reducing noise. In addition, noise is generated when the air flow exhausted from the turbo fan collides with the rectifying guide, or the air flow that has passed through the rectifying guide generates vortices on the downstream side of the rectifying guide, leading to the generation of noise. There are concerns.

  In addition, when the turbo fan disclosed in Patent Document 2 is used in an indoor unit of a ceiling-embedded air conditioner having a configuration in which a substantially rectangular heat exchanger surrounds the fan, the heat exchanger and the turbo fan Therefore, the non-uniformity of the discharge air pressure in the circumferential direction on the outer periphery of the fan added to the main flow is not corrected, and a blowing sound is generated due to the non-uniform discharge air pressure. In the first place, the circulation flow is a flow generated due to the pressure difference between the fan blowing space and the shroud suction port, and the static pressure of the fan blowing space differs in the circumferential direction due to the difference in the distance between the heat exchanger and the turbofan. As a result, the flow rate of the circulating flow also varies in the circumferential direction, and the non-uniformity of the discharge air pressure on the outer periphery of the fan is not corrected, and there is a concern about noise increase due to the non-uniform discharge air pressure.

  The present invention has been made to solve the above-described problems, and reduces noise caused by non-uniformity in the distance between the heat exchanger and the turbo fan without deteriorating the blowing performance of the turbo fan. An object of the present invention is to provide an air conditioner indoor unit with low noise.

An indoor unit of an air conditioner according to the present invention includes a housing, a main plate, and a design panel having a suction port and a plurality of outlets formed around the suction port so as to cover the opening surface, A donut-shaped shroud formed concentrically with this main plate and facing the main plate at a predetermined interval and having a cylindrical portion formed in the center portion extending in the direction of the suction port, and sandwiched between the main plate and the shroud A turbo fan that consists of a plurality of blades that are connected and fixed to each other and is housed in a housing and generates an air flow from the suction port to the blowout port. Located between the suction port and the turbofan, the direction of the turbofan A bell mouth that has a duct portion extending inward and guides indoor air sucked from the suction port to the turbofan, a plurality of thin plate-like fins arranged in parallel at predetermined intervals, and these It is composed of metal pipes that are inserted in multiple stages while penetrating the fin, and is housed in the casing so as to surround the turbo fan in a polygonal shape, from the suction port A heat exchanger that exchanges heat with the indoor air sucked and discharged from the turbofan, and the downstream end of the air flow of the bell mouth duct portion is located on the inner peripheral side of the cylindrical portion of the shroud, The upstream end of the air flow in the section and the downstream end of the duct section overlap each other in the radial direction with a predetermined distance in the rotational axis direction of the turbofan, and between the cylindrical section and the duct section. the size of the gap is not constant amount circumferentially, be those who far portion is set larger than the partial distance is a short distance of the turbofan and the heat exchanger, the heat exchanger The container is parallel to the fins The direction extends linearly in the longitudinal direction of the outlet, and has a plurality of adjacent linear portions with a predetermined angular difference, and a bent portion positioned between the adjacent linear portions, and the interior of the housing A region sandwiching the straight line portion between the straight line connecting the rotation center O of the turbo fan and the longitudinal end point of the straight line portion of the heat exchanger is a straight line region, and a bent portion between the straight lines connecting the rotation center O and the longitudinal end point When the area between the turbo fan and the heat exchanger is divided into a plurality of areas with the area sandwiching the corner as a corner area, there is a position where the distance between the turbofan and the heat exchanger is the shortest, and the size of the gap in the corner area However, at any circumferential position in the angular region, the distance between the turbo fan and the heat exchanger in the straight region is set to be larger than the size of the gap at the closest position. .

  According to the present invention, in an indoor unit of an air conditioner in which a polygonal heat exchanger surrounds a turbo fan, the circumferential direction on the outer periphery of the turbo fan due to non-uniformity of the distance between the turbo fan and the heat exchanger The unevenness of the discharge air pressure distribution can be corrected to reduce the blowing sound caused by the uneven discharge air pressure, and an indoor unit of an air conditioner with low noise can be obtained.

It is the external view which looked at the indoor unit of the air conditioner in Embodiment 1 of this invention from the room. It is a longitudinal cross-sectional view of the indoor unit of the air conditioner in Embodiment 1 of this invention. It is a cross-sectional view of the indoor unit of the air conditioner in Embodiment 1 of this invention. It is a perspective view of the turbo fan accommodated in the indoor unit of the air conditioner in Embodiment 1 of this invention. It is a perspective view of the heat exchanger accommodated in the indoor unit of the air conditioner in Embodiment 1 of this invention. It is a figure explaining the state of the airflow of the blowing space in Embodiment 1 of this invention based on the cross section of an indoor unit. It is a figure explaining the state of the airflow of the blowing space in Embodiment 1 of this invention based on the longitudinal cross-section of an indoor unit. It is a figure explaining the gap in Embodiment 1 of this invention based on the cross section of an indoor unit. FIG. 3 is a longitudinal sectional view of a main part in the vicinity of a gap in Embodiment 1 of the present invention, where (a) shows the vicinity of the gap in the corner region R, and (b) shows the vicinity of the gap in the closest distance portion of the straight region Q. . It is a perspective view of the bell mouth in Embodiment 1 of this invention. It is a perspective view of the bell mouth of the modification in Embodiment 1 of this invention. It is a figure explaining the modification which changes the magnitude | size of the clearance gap in the circumferential direction in Embodiment 1 of this invention based on the cross section of an indoor unit. FIG. 6 is a longitudinal sectional view of a main part in the vicinity of a gap in the second embodiment of the present invention, where (a) shows the vicinity of the gap in the corner region R, and (b) shows the vicinity of the gap in the closest distance portion of the straight region Q. . It is a figure explaining the bell mouth in Embodiment 3 of this invention. It is a figure explaining the bell mouth in Embodiment 4 of this invention.

Embodiment 1 FIG.
FIG. 1 to FIG. 12 are views showing Embodiment 1 according to the present invention. FIG. 1 is an external view of the indoor unit 1 of the air conditioner shown in Embodiment 1 as viewed from the inside. FIG. FIG. 3 is a cross-sectional view of the indoor unit 1, and is a cross-sectional view taken along line X1-X2-X3-X4-X5-X6 in FIG. 2 is a cross-sectional view taken along line Y2-O-Y1 in FIG. FIG. 4 is a perspective view showing a turbo fan 10 that is housed in the indoor unit 1 as a blower and that is a type of centrifugal fan that generates an air flow, with a part thereof cut away. FIG. 5 is a perspective view of the heat exchanger 60 housed in the indoor unit 1 and surrounding the turbo fan 10. FIG. 6 is a diagram illustrating the state of airflow in the fan blowing space 41 of the indoor unit 1 and is based on the cross-sectional view of FIG. FIG. 7 is also a diagram for explaining the air flow in the fan blowing space 41, which is based on one side (0-Y1 cross section) of the longitudinal sectional view of FIG. FIG. 8 is a diagram illustrating the gap 20 of the indoor unit 1 based on the cross-sectional view of FIG. FIG. 9 is a longitudinal sectional view of the main part of the indoor unit 1 in the vicinity of the gap 20, where (a) shows the vicinity of the gap 20 in the corner area R, and (b) shows the vicinity of the gap 20 in the nearest distance part of the straight area Q. Is shown. FIG. 10 is a perspective view of a bell mouth 70 used in the indoor unit 1, and FIG. 11 is a modification of the bell mouth 70. FIG. 12 is a diagram for explaining a modification example in which the size of the gap 20 is changed in the circumferential direction based on a cross-sectional view.

  The indoor unit 1 of the air conditioner in Embodiment 1 is a ceiling-embedded type in which a casing 30 (see FIG. 2) of the indoor unit body is installed in the back of the ceiling, and the lower end opening surface of the casing 30 is viewed in plan view. A substantially rectangular design panel 31 covers the design panel 31 facing the room from the ceiling 9 as shown in FIG. In the center of the design panel 31, a suction port 32 for sucking room air into the indoor unit 1 main body (housing 30) is provided, and a suction grill 33 including a plurality of bars is attached to the suction port 32. An air filter 34 (see FIG. 2) that captures dust contained in the sucked room air is installed on the downstream side of the suction grill 33 in the suction port 32.

  The air filter 34 is detachably fixed to the inside of the suction grill 33 (upward in FIG. 2), and the suction grill 33 that is rectangular in a plan view rotates about a specific side as a fulcrum to the suction port 32. Since the suction grille 33 is rotated downward and opened, the air filter 34 can be attached and detached, and maintenance work such as cleaning and replacement of the air filter 34 can be performed. . Maintenance of the air filter 34 can be carried out by opening and closing the suction port 32 by electrically moving the suction grille 33 that detachably fixes the air filter 34 to the inside while maintaining the horizontal posture. You may comprise as follows.

  Around the suction grill 33 (suction port 32) of the design panel 31, a plurality of elongated rectangular outlets 35 are formed along the four sides of the substantially rectangular design panel 31. Each blowout port 35 is provided with a wind direction vane 36 that adjusts the direction of the blown airflow. In FIG. 1, a total of four outlets 35 are formed, one on each side, but the outlets 35 along one side may be divided into a plurality, for example, two. In FIG. 1, the white arrow represents the air flow.

  As shown in FIG. 2, the housing 30 of the indoor unit 1 is a box-like body that opens downward, and includes a top plate 37 that closes upward and a plurality of side plates 38 that surround the periphery. The casing 30 is substantially rectangular in plan view, but has an inclined surface at three of the four corners of the quadrangle (see FIG. 3). Inside the housing 30, a box-shaped heat insulator 39 is also fixedly disposed along the inner surface of the housing 30. The top plate 37 and the side plate 38 are made of a metal plate, and the heat insulator 39 is formed of foamed polystyrene.

  The housing | casing 30 is embedded in the back side of the ceiling 9 of a room or an office. A design panel 31 attached and fixed to the housing 30 protrudes indoors from the ceiling 9 and is exposed indoors. The ceiling 9, the top plate 37, and the design panel 31 are parallel to each other. Housed in the housing 30 are a heat exchanger 60 for exchanging heat between the turbo fan 10 that generates an air flow and the sucked room air and the refrigerant circulating in the refrigeration cycle. The turbo fan 10 is a blowing unit that sucks room air from the suction port 32 and generates an air flow from the suction port 32 to the blow-out port 35. The turbo fan 10 is disposed in the approximate center of the housing 30 in a plan view. The turbo fan 10 is disposed so as to surround the outer periphery (see FIG. 3). A fan motor 7 that rotationally drives the turbo fan 10 is installed on the back side of the turbo fan 10 (upward in FIG. 2).

  In FIG. 2, below the heat exchanger 60 is a drain pan that adheres to the surface of the heat exchanger 60 during cooling or dehumidifying operation, receives condensed water dripped from the heat exchanger 60 due to gravity, and discharges it to the outside. 8 is arranged. The drain pan 8 is fixed to the side plate 38 of the housing 30 with screws. A bell mouth 70 that smoothly guides the sucked indoor air to the turbo fan 10 is installed downstream of the suction grill 33 (suction port 32) and upstream of the turbo fan 10. The bell mouth 70 is located between the suction port 32 and the turbo fan 10 and is fixed to the drain pan 8 by screwing. In addition, a blowout air passage 3 communicating with the blowout port 35 of the design panel 31 is formed between the heat exchanger 60 and the heat insulator 39.

  As shown in FIG. 4, the turbo fan 10 has a substantially cylindrical shape as a whole, a main plate 11, and a donut-shaped shroud 12 disposed so as to face the main plate 11 with a predetermined gap therebetween, It is composed of a plurality of blades 13 sandwiched between the main plate 11 and the shroud 12 and connected and fixed to each of the main plate 11 and the shroud 12. The turbofan 10 has seven blades 13. The wing 13 extends in the radial direction from the front edge 13a located closer to the inner periphery of the main plate 11 and moves backward in the rotation direction F (progresses in the counter-rotation direction), and the rear edge 13b is disposed. The inside of the wing 13 has a hollow structure for weight reduction. FIG. 4 shows a state in which a part of the shroud 12 and a part of the wing 13 are notched for explanation.

  A cylindrical portion 14 serving as a fan suction port is formed in the central portion of the shroud 12. The end portion of the cylindrical portion 14 faces the suction port 32 of the design panel 31 and extends in the direction of the suction port 32. The center of the main plate 11 is a raised portion 11a that rises in a spherical shape toward the shroud 12, and the fan motor 7 is housed in a bowl-shaped space formed on the back surface of the raised portion 11a as shown in FIG. The That is, the back surface of the raised portion 11 a at the center of the main plate 11 serves as a motor storage space 15. The fan motor 7 is fixed to the top plate 37 constituting the housing 30 by screws (bolt fixing). Further, as shown in FIG. 2, the inner diameter of the shroud 12 is increased in an arc shape from the downstream end of the central cylindrical portion 14 toward the main plate 11.

  The fan motor 7 has a motor rotating shaft 6 at the center thereof. The motor rotating shaft 6 protrudes from the fan motor 7 to the turbo fan 10 side, and rotates when the fan motor 7 is energized. In a state where the indoor unit 1 is installed on the ceiling 9, the motor rotating shaft 6 protrudes so that the protruding end faces downward. A cylindrical boss portion 16 connected to the motor rotating shaft 6 is fixed to the top of the raised portion 11a of the main plate 11, and the rotational force of the motor rotating shaft 6 is transmitted to the boss portion 16 so that the turbo fan 10 is Rotate. The rotation center of the turbo fan 10 is the center of the motor rotation shaft 6 and the center of the cylindrical boss portion 16. The boss portion 16 is also one of the components of the turbo fan 10.

  The rotation axis direction H in FIG. 4 is the center line direction of the motor rotation shaft 6. An extension line of the center line of the motor rotation shaft 6 is defined as a rotation axis 5 of the turbo fan 10. The main plate 11 and the shroud 12 are also concentric with the rotation axis 5, and the plurality of blades 13 are also arranged concentrically with respect to the rotation axis 5. Here, the outer periphery 10a of the turbo fan 10 is generally a circle drawn by a locus when the rear edge 13b of the blade 13 serving as the air outlet rotates due to the function of the turbo fan 10, but here, Since it is used for the distance from the heat exchanger 60, the outer diameter of the shroud 12 or the outer diameter of the main plate 11 may be used. Note that the circle drawn by the locus of the trailing edge 13b of the wing 13 is the maximum diameter circle drawn by the locus of the trailing edge 13b when the trailing edge 13b is inclined or uneven. In the turbofan 10 shown in FIG. 4, the outer diameter of the main plate 11, the outer diameter of the shroud 12, and the diameter of the circle drawn by the locus of the trailing edge 13 b when the blade 13 rotates are substantially the same. Is a turbofan outer periphery 10a.

  Next, the heat exchanger 60 will be described with reference to FIG. The heat exchanger 60 includes a plurality of thin plate-like fins 67 arranged in parallel at a predetermined interval, and a metal pipe (here, a copper pipe) inserted through the fins 67 in a plurality of stages. 68, and the refrigerant circulating in the refrigeration cycle flows in the pipe 68. The direction in which the pipe 68 forms a step is the rotation axis direction H. As shown in FIG. 5, the heat exchanger 60 is formed by bending an elongated and flat product into a substantially rectangular shape, and both end portions 61 are at a predetermined angle with each other in an area A surrounded by an alternate long and short dash line. And located at a distance. Both end portions 61 are the respective ends (two locations) in the direction in which the fins 67 are arranged in parallel. If end plates are attached to the outside of the fins 67 located at the ends, the end portions 61 are the positions of the end plates. If there is no plate, it is the position of the fin 67 at the end. When the air flow passes through the heat exchanger 60, heat is exchanged between the room air and the refrigerant flowing through the pipe 68. As shown in FIG. 3, the gap between both end portions 61 is closed in the radial direction by a connecting plate 62. The connecting plate 62 is disposed on a line connecting the shortest distance between the both end portions 61. A pipe connection portion 66 connected to a refrigeration cycle (for example, an extended pipe connected to the outdoor unit) located outside the indoor unit 1 is disposed outside the connecting plate 62 in the radial direction.

  As shown in FIG. 5, since the heat exchanger 60 is formed in a substantially rectangular shape, there are three corner portions except for the area A where both end portions 61 are located at predetermined intervals. Each corner portion is a bent portion 63 that is bent in an arc shape. In one of the three corners, as shown in FIG. 3, in order to install the drain pump 4 for discharging the condensed water accumulated in the drain pan 8 to the outside of the corner in the radial direction, As shown by an area B in FIG. 5, a linearly inclined portion 69 is formed, and both sides of the inclined portion 69 are bent in an arc shape to secure a substantially triangular installation space on the outside. However, the corner portion indicated by area B is also handled as one bent portion 63 like the other two corner portions. In order to secure the installation space for the drain pump 4, the bend radius may be larger than the other two bend portions 63 without providing the inclined portions 69 at the corners of the area B. .

  The heat exchanger 60 is configured in a straight line between adjacent bent portions 63 and between both end portions 61 and the bent portion 63, and this portion is a straight portion 64. Since the heat exchanger 60 has a substantially rectangular shape, there are four straight portions 64 along each side. As shown in FIG. 5, the three bent portions 63 and the end portions 61 are located between four linear portions 64 that are adjacent to each other with an angle difference of about 90 ° in the direction in which the fins 67 are arranged in parallel. (Area A) exists. Except both end portions 61, the intersection of the straight portion 64 and the bent portion 63, that is, the end point in the longitudinal direction of the straight portion 64, and the bending start point of the bent portion 63 is a straight end 65. Both end portions 61 are also end points in the longitudinal direction of the straight portion 64, and the end points of the straight portion 64 are either the straight end 65 or both end portions 61. In addition, the longitudinal direction of the linear part 64 of the heat exchanger 60 substantially coincides with the longitudinal direction of the outlet 35 in the indoor unit 1. Here, the longitudinal direction of the straight portion 64 is also a direction in which the fins 67 of the heat exchanger 60 are arranged in parallel, and is orthogonal to the rotation axis direction H in the indoor unit 1.

  The turbo fan 10 to which the rotational force is transmitted through the motor rotation shaft 6 by the rotation of the fan motor 7 rotates around the rotation axis 5 in the direction of arrow F shown in FIG. 4, and the cylindrical portion at the center of the shroud 12. Air (room air) is sucked in from the (fan suction port) 14 in the rotation axis direction H. Then, the direction of the air flow is changed to the radial direction (centrifugal direction), and the air is passed between the blades 13 and 13. The sucked air rises in pressure when passing between the blades 13 and is discharged from the outer periphery 10a of the turbofan 10 to the periphery (in the direction of 360 degrees). The discharged air flow passes through the heat exchanger 60, and the air and the refrigerant exchange heat in the process of passing through the heat exchanger 60.

  As shown in FIG. 3, the indoor unit 1 has a configuration in which a substantially rectangular heat exchanger 60 surrounds the outer periphery in the radial direction of the circular turbofan 10 inside the housing 30, and therefore, the turbofan outer periphery 10 a. The radial distance between the heat exchanger 60 and the heat exchanger 60 differs depending on the position of the heat exchanger 60. The straight line portion 64 of the heat exchanger 60 is a short distance, and the bent portion 63 is a long distance. That is, the radial distance between the turbo fan outer periphery 10 a and the straight portion 64 of the heat exchanger 60 is smaller than the radial distance between the turbo fan outer periphery 10 a and the bent portion 63 of the heat exchanger 60. Note that the heat exchanger 60 has a substantially rectangular shape instead of a circular shape. When the indoor unit 1 surrounds the turbo fan 10, the effective length of the heat exchanger through which an air flow can pass rather than a circular shape is used. This is because a larger heat exchange area can be secured.

  Here, as shown in FIG. 3, the inside of the housing 30 of the indoor unit 1 is partitioned into a plurality of virtual regions. A region where the connecting plate 62 is sandwiched between two straight lines connecting the rotation center O (rotation axis 5) of the turbo fan 10 and both end portions 61 of the heat exchanger 60 is defined as a connecting plate region P. Two regions sandwiching the straight line portion 64 between the straight line connecting the rotation center O and both end portions 61 and the straight line connecting the rotation center O and the straight line end 65 are defined as straight line regions Q1 and Q2, respectively. Two regions sandwiching the straight line portion 64 between straight lines connecting the end 65 are defined as straight line regions Q3 and Q4, respectively. Since both the straight end 65 and both end portions 61 are end points in the longitudinal direction of the straight portion 64, a region sandwiching the straight portion 64 between the straight lines connecting the rotation center O and the end point of the straight portion 64 is a straight region Q (Q1 to Q1). Q4). In addition, the three regions sandwiching the bent portion 63 between the straight lines connecting the rotation center O and the straight end 65 are defined as corner regions R1, R2, and R3, respectively. In this way, four straight regions Q, three corner regions R, and one connecting plate region P are defined. The piping part 63 is located in the connecting plate region P, and the drain pump 4 is located in the corner region R3.

  The corner bent portion 63 shown by area B of the heat exchanger 60 in FIG. 4 is located in the corner region R3 in FIG. 3, but as described above, the bent portion 63 located in the corner region R3 is Compared to the straight portion 64 (the length in the fin parallel direction), it has a slanted portion 69 that is linear, but at the corner of the housing 30, the outer periphery of the turbofan compared to the straight portion 64. Since it is located at a long distance from 10a, the corner region R3 is also handled in the same manner as the other two corner regions R1 and R2.

  Regarding the radial distance between the turbo fan outer periphery 10a and the heat exchanger 60, in the linear region Q, the distance between the turbo fan outer periphery 10a and the linear portion 64 is not constant over the entire circumferential direction of the region. For example, in the straight line region Q3, the radial distance between them is the smallest at the center in the circumferential direction of the region Q3 (indicated by the Y3-O3 line in FIG. 3). The radial distance increases. Here, the circumferential direction is the same direction as the rotation direction or counter-rotation direction of the turbofan 10.

  In any straight region Q, there is a position where the turbo fan outer periphery 10a and the straight portion 64 are closest to each other, and the radial distance between them is the shortest, and the straight end 65 or both ends 61 from the position. The distance in the radial direction between the two increases with increasing heading. However, since the positions of both end portions 61 and the straight end 65 are not all symmetrical with a phase difference of 90 degrees in the circumferential direction with respect to the rotation center O, the turbo fan outer periphery 10a is not in all the straight regions Q. The position at which the straight line portion 64 is closest is not the center of the straight line area Q in the circumferential direction as in the straight line area Q3.

  As shown in FIG. 3, the positions at which the turbo fan outer periphery 10a and the linear portion 64 are closest to each other in the linear regions Q1 to Q4 have an angular difference of 90 ° in order. In FIG. 3, in the straight line area Q1, the position indicated by the distance L1 is the closest position. Similarly, the straight line area Q2 is indicated by the distance L2, the straight line area Q3 is indicated by the distance L3, and the straight line area Q4. Then, the position indicated by the distance L4 is the closest position. Here, since the center of the turbo fan 10 and the heat exchanger 60 is concentric, L1 = L2 = L3 = L4. The position closest to the straight line region Q3 is the center of the straight line region Q in the circumferential direction.

  As shown in FIG. 2, the bell mouth 70 is located on the downstream side of the airflow (upward in FIG. 2), and a duct portion 71 whose end face faces the turbofan 10 and extends in the direction of the turbofan 10. The curved surface portion 72 whose inner diameter increases from the upstream end of the portion 71 toward the upstream side of the air flow, and is smoothly connected to the curved surface portion 72 and substantially parallel to the design panel 31 in the indoor unit 1 to the outer periphery of the curved surface portion 72. It has a wide air passage wall 73. The bell mouth 70 is fixed to the casing 31 via the drain pan 8 by screwing the air passage wall 73 to the drain pan 8. The air passage wall 73 functions to partition the fan suction space 40 formed between the suction grill 33 and the bell mouth 70 and the fan blowing space 41 formed between the turbofan outer periphery 10 a and the heat exchanger 60. have.

  The downstream end (including the tip) of the duct portion 71 of the bell mouth 70 is located on the inner peripheral side of the cylindrical portion 14 of the shroud 12, and the downstream end of the duct portion 71 and the upstream end of the cylindrical portion 14. Are overlapped in the radial direction by a predetermined distance Gh (see FIG. 9) in the rotation axis direction H. A gap 20 is interposed in the radial direction in the overlapping portion between the two. The gap 20 is provided between the shroud cylindrical portion 14 and the bell mouth duct portion 71 and has a radial clearance due to the inner diameter φDs of the cylindrical portion 14 being larger than the outer peripheral dimension of the duct portion 71. In order to prevent the contact between the turbo fan 10 and the bell mouth 70 during the rotation of the turbo fan 10 in consideration of the rotation of the turbo fan 10 and the positional deviation when the bell mouth 70 is assembled. The gap 20 is indispensable. Note that the distance Gh (the length of the gap 20 in the rotation axis direction H) of the portion where the duct portion 71 and the cylindrical portion 14 overlap in the radial direction via the gap 20 in the radial direction is the indoor unit 1 Then, it is set to about 10 mm.

  When the fan motor 7 is energized in the indoor unit 1, the turbo fan 10 rotates, and due to the suction action of the turbo fan 10, indoor air passes through the suction grille 33 and the air filter 34 to the fan suction space 40. And the downstream side of the duct portion 71 of the bell mouth 70 enters the inside of the cylindrical portion 14 of the shroud 12 that is the fan suction port, so that the indoor air in the fan suction space 40 passes through the bell mouth 70 and is reliably turbocharged. It is sucked into the fan 10. Note that by forming the downstream end portion of the duct portion 71 of the bell mouth 70 in a tapered shape toward the tip (downstream end), it is possible to prevent the vortex generation of the air flow in the vicinity of the tip of the duct portion 71.

  The indoor air changes the direction of flow from the rotation axis direction H to the radially outer side (centrifugal direction) inside the turbofan 10 and is pressurized between the blades 13 to 360 ° from the turbofan outer periphery 10 a to the fan blowing space 41. Discharged in the direction. The room air discharged to the fan blow-out space 41 passes through the heat exchanger 60 and is cooled or warmed by exchanging heat with the refrigerant flowing through the pipe 68 of the heat exchanger 60 during the passage. The air is blown out into the room through the path 3 while being guided in the direction of the wind vane 36 from the air outlet 35.

  The flow of air discharged from the turbo fan outer periphery 10a to the fan blowing space 41 is caused by the rotation direction F of the turbo fan 10 (clockwise in FIG. 6) due to the rotation of the turbo fan 10, as indicated by solid arrows in FIG. ), The discharged air collides with the heat exchanger 60 obliquely from the fan blow-out space 41. Therefore, the total amount of air exhausted from the turbofan outer periphery 10a does not pass through the heat exchanger 60, and a part of the air does not pass through the heat exchanger 60 and swirls in the fan blowing space 41, where Since the static pressure in the fan blowing space 41 is higher than the static pressure inside the cylindrical portion 14 of the shroud 12 that is the fan suction port, that is, there is a pressure difference between the two spaces, the cylindrical portion 14 of the shroud 12 and the bell mouth The air flows again into the turbo fan 10 from the gap 20 formed between the duct portion 71 and the duct portion 71.

  Such a part of the air flow is referred to as a circulation flow J. The flow of air passing through the heat exchanger 60 from the turbo fan outer periphery 10a through the fan blowing space 41, which is not a circulating flow, is referred to as a main flow K. In FIG. 6, the flow indicated by the dotted line arrow is the circulation flow J, and the flow indicated by the solid line arrow is the main flow K. In addition, a solid line arrow with a symbol S in FIG. 7 is an effective suction flow S that flows into the turbofan 10 from the fan suction space 40 through the inner peripheral side of the bell mouth 70. The air discharged from the turbo fan outer periphery 10a includes the air of this effective suction flow S and the air that flows through the gap 20 by the circulation flow J and flows into the turbo fan 10 again. In addition, the circulation flow J and the main flow K shown in FIG. 7 are drawn excluding components that proceed in the rotation direction F for easy explanation.

  Here, the static pressure in the fan blowing space 41 is not uniform over the circumferential direction of the turbofan 10. The static pressure varies depending on the distance between the turbofan outer periphery 10a and the heat exchanger 60. In the part where the distance between the two is smaller, that is, where the width of the fan blowing space 41 is narrower, the position of the heat exchanger 60 that provides ventilation resistance is closer to the turbofan outer periphery 10a that serves as an airflow outlet, and therefore. As the flow rate increases, the static pressure increases. At the fan outlet 41 facing the straight portion 64, for example, located in the straight region Q3, the circumferential center (indicated by the Y3-O line in FIG. 3) where the distance between the turbofan outer periphery 10a and the heat exchanger 60 is the smallest. ) The static pressure is the highest in the vicinity, and the static pressure becomes lower than the static pressure in the vicinity of the center as the distance between the two increases from there toward the straight end 65.

  Further, the distance (radial distance) of the heat exchanger 60 relative to the turbofan outer periphery 10a is relatively larger in the corner region R than in the straight region Q. The average distance in the circumferential direction between the two in the corner region R is larger than the average distance in the circumferential direction between the two in the straight region Q. Here, the average distance is an average value of distances at a plurality of locations that are equally spaced in the circumferential direction in each region, for example, 10 locations that are equally spaced in each region. Since the circumferential angle ranges of the respective regions are not the same, the equal angular widths are different depending on the regions in order to have the same number. Therefore, when the relative comparison is made between the straight region Q and the corner region R, the static pressure in the fan blowing space 41 is higher in the straight region Q than in the corner region R. As described above, the static pressure distribution in the circumferential direction also exists in the fan blowing space 41 in the straight region Q. However, the average of the static pressure in the fan blowing space 41 in each region is the heat exchanger for the turbo fan outer periphery 10a. This means that the straight line area Q, which includes the positions corresponding to the distances L1 to L4 and is a short distance, is higher than the angular area R where the distance of 60 is a long distance.

  The circulation flow J is caused by the pressure difference between the two spaces because the static pressure in the fan blow-out space 41 is higher than the static pressure inside the cylindrical portion 14 of the shroud 12 that is the fan suction port. If the gap 20 serving as the air path is a constant amount in the entire circumferential direction, taking a certain straight region Q, the distance of the heat exchanger 60 to the turbo fan outer periphery 10a in the straight region Q is as follows. The pressure difference at the closest position (the positions indicated by the distances L1 to L4 in FIG. 3 and hereinafter referred to as the nearest distance point) becomes the largest, and the flow rate of the circulating flow J in this vicinity Is larger than other parts. If the gap 20 is a constant amount, the circulating flow J is more likely to flow into the gap 20 at a location where the pressure difference is larger.

  Further, comparing the flow rate of the swirling flow J in the straight region Q and the corner region R, the straight region Q having a higher average static pressure in the fan blowing space 41 has an average flow rate value than that in the corner region R. Is big. Here, the average value of the flow rate refers to the average flow rate per unit angle in the circumferential direction in each region, and is a value obtained by dividing the flow rate in the region by the circumferential angle width of the region. For example, in the linear region Q3, the flow rate in the unit angle range including the Y3-O line is larger than the flow rate per unit angle outside the range, but the flow rate distribution per unit angle in such a region is averaged. It is a thing.

  In this way, the gap 20 has a constant amount in the entire circumferential direction due to the non-uniformity of the distance between the turbo fan outer periphery 10a and the heat exchanger 60 generated by the substantially rectangular heat exchanger 60 surrounding the circular turbo fan 10. If so, the flow rate of the circulating flow J flowing into the turbofan 10 through the gap 20 is also nonuniform in the circumferential direction. If the flow rate of the circulating flow J in the circumferential direction is non-uniform, the flow rate of air discharged from the turbo fan outer periphery 10a is also non-uniform in the circumferential direction, and the discharge air pressure at the fan outer periphery 10a is non-uniform, resulting in blowing noise. . While the turbo fan 10 makes one revolution, the exhaust air pressure at the fan outer periphery 10a changes due to the difference in the distance between the turbo fan outer periphery 10a and the heat exchanger 60, and the blowing sound induced by the fluctuation of the exhaust air pressure is generated. is there.

  In the conventional centrifugal blower, for example, as described in Patent Document 2, the gap 20 through which the circulating flow J passes is a constant amount throughout the circumferential direction. The same applies to the case of being mounted on an indoor unit of an air conditioner, and the size of the gap 20 is constant over the circumferential direction. The size of the gap 20 is generally any one of 3 to 7 mm depending on the size of the indoor unit of the air conditioner (from a small home size to a large building size). It was set constant. Therefore, as described above, the exhaust air pressure at the fan outer periphery 10a is not uniform, and the blowing sound is generated.

  When the gap 20 is a constant amount in the entire circumferential direction, the flow rate of the circulating flow J is nonuniform in the circumferential direction due to nonuniformity of the distance between the turbofan outer periphery 10a and the heat exchanger 60, but the effective suction flow Since the flow rate of S is substantially uniform in the circumferential direction, the flow rate of air discharged from the turbofan outer periphery 10a, which is the sum of the flow rate of the effective suction flow S and the flow rate of the circulation flow J, is mainly the circulation flow J. It becomes non-uniform in the circumferential direction due to non-uniform flow rate. Since the flow rate of the circulating flow J is generally less than 10% of the flow rate of the air discharged from the turbo fan outer periphery 10a, the fluctuation range in the 360 ° direction of the flow rate of the air discharged from the turbo fan outer periphery 10a is so large. There is no. However, even if the variation in the exhaust flow rate is not large, this becomes uneven in the circumferential discharge air pressure at the outer periphery of the turbofan 10a and is caused by the variation in the discharge air pressure in the circumferential direction (variation during one rotation). If blown sound is generated, the noise cannot be ignored, and measures to reduce it are required.

  FIG. 8 illustrates the gap 20 having a radial clearance between the shroud cylindrical portion 14 and the bell mouth duct portion 71 of the indoor unit 1 of the air conditioner according to the first embodiment that overlaps in the radial direction. In this indoor unit 1, the size of the gap 20 is constant in the circumferential direction in order to reduce the blowing noise caused by the uneven exhaust air pressure in the circumferential direction on the turbo fan outer periphery 10 a described above. The size of the gap 20 in the corner region R is not the amount, but the position where the distance between the turbofan outer periphery 10a and the heat exchanger 60 is the shortest in the closest distance region, that is, in the straight region Q (distance L1 in FIG. 3). Is set to be larger than the size of the gap 20 at the position indicated by L4. The size of the gap 20 in the corner region R is larger than the size of the gap 20 at the closest distance in the linear region Q at any circumferential position in the region.

  Further, the average size of the gap 20 in the corner region R is larger than the average size of the gap 20 in the straight region Q. Here, the average size is an average value of the sizes of the gaps 20 at a plurality of locations that are equally spaced in the circumferential direction in each region, for example, 10 locations that are equally spaced in each region. Since the circumferential angle ranges of the respective regions are not the same, the equal angular widths are different depending on the regions in order to have the same number.

  Further, in the straight line region Q, the size of the gap 20 at the nearest distance point is the smallest, and the size of the gap 20 on the straight line connecting the rotation center O and the straight line end 65 as the circumferential end of the region is the same. It is the largest. That is, in the straight region Q, the size of the gap 20 in the outer circumferential portion (portion adjacent to the corner region R) in the straight region Q is larger than the size of the gap 20 in the nearest distance point. Yes. Δq1 to δq4 shown in FIG. 8 are the sizes of the gaps 20 at the closest distances in the linear regions Q1 to Q4, respectively, and the sizes of the smallest gaps 20 in the respective linear regions Q. Then, from the nearest distance point to the point on the straight line connecting the rotation center O and the straight line end 65, that is, toward the corner region R in the circumferential direction, the size of the gap 20 becomes larger than δq1 to δq4, respectively. It is good to go.

  The size of the gap 20 (δq1 to δq4 shown in FIG. 8) at the closest distance in the straight region Q, that is, the size of the gap 20 that is the smallest in the circumferential direction is the rotational run-out of the turbofan 10 and the bell mouth 70. In consideration of the positional deviation at the time of assembling, the size is necessary to prevent the shroud turbofan 10 and the bell mouth 70 from coming into contact with each other during the rotation of the turbofan 10. This is the size of the gap when the amount is constant over the entire direction. Hereinafter, the size of the gap 20 will be referred to as a standard gap amount. Δq1 to δq4 shown in FIG. 8 are all equal in size (meaning that they are equal in design, and differences due to dimensional tolerance and assembly tolerance are included in the same size). It is a gap amount.

,
FIG. 9 is a longitudinal sectional view of the main part in the vicinity of the gap 20. FIG. 9A shows the periphery of the gap 20 in the corner region R1, and FIG. 9B shows the periphery of the gap 20 at the closest distance in the straight region Q3. A large δq3 of the gap 20 shown in FIG. 9B is a standard gap amount. Let φDb be the outer diameter (diameter) of the duct portion 71 of the bell mouth 70 at the location where the standard gap amount is formed. If the inner diameter (diameter) of the cylindrical portion of the shroud 12 having a circular cross section is φDs, the standard gap amount δq3 is (φDs−φDb) / 2. The same applies to δq1, δq2, and δq4. The standard gap amount is the minimum value of the size of the gap 20 in the first embodiment, and is the size of the gap 20 at the closest distance portion of the linear region Q.

  Then, the size of the gaps 20 in the corner regions R1 to R3 indicated by δr1 to δr3 in FIG. 8 is larger than the standard gap amount (δq1 to δq4) at any circumferential position in the region. It is configured. Each of the linear regions Q1 to Q4 includes a portion where the size of the gap 20 is a standard gap amount and a portion where the gap is larger. In the connecting plate region P, the size δp of the gap 20 is constant at the standard gap amount. Details of this will be described later.

  In order to realize the gap 20 having a non-constant amount in the circumferential direction, as shown in FIGS. 3 and 8, the bell mouth 70 used in the first embodiment has a duct portion 71 in a cylindrical shape, that is, The cross-sectional shape (cross-sectional shape cut by X3-X4 in FIG. 2) is not circular, and the corner region R portion connects the positions of the four closest regions of the four linear regions Q (FIG. 9B). ) To be located on the inner side (close to the rotation axis 5) than the circle represented by φDb. That is, the duct portion 71 is formed such that the corner region R portion is closer to the rotational axis 5 in the radial direction than the portion forming the standard gap amounts δq1 to δq4. The bell mouth 70 of the first embodiment is made of resin and is integrally formed, and a duct portion 71 having a non-circular cross-sectional shape can be easily formed.

  However, if the duct portion 71 is recessed by the corner region R portion so as to be located inside the straight region Q portion, a boundary between the corner region R and the straight region Q, that is, a straight line connecting the rotation center O and the straight line end 65. A step will be formed in the upper duct portion 71. As described above, the circulation flow J has a component that proceeds in the rotation direction F of the turbofan 10, and this is the same in the gap 20. Therefore, if such a step is formed, the circulation flow J There is a concern that J may collide with the step in the gap 20 to generate new noise associated with the collision. Here, “depress” means to be positioned on the inner side of the circular shape (see FIG. 9) having the outer diameter φDb of the duct portion 71 of the bell mouth 70 at the position where the standard gap amount is formed. That is, it is partially recessed in the direction of the rotation axis 5.

  Therefore, in the bell mouth 70, as shown in FIG. 3 and FIG. 8, the corner region R portion of the duct portion 71 is positioned inside the position where the standard gap amounts δq1 to δq4 of the straight region Q portion are formed. The duct portion 71 is formed so as to be recessed inward from the middle in the circumferential direction of the linear region Q portion located on both sides of the corner region R portion. In this manner, the duct portion 71 is continuously depressed inward from the middle of the straight region Q, and the angular range in the circumferential direction in which the duct portion 71 is depressed is larger than the angular range of the corner region R, so that the corner region R portion of the duct portion 71 By forming the, the uneven step in the circumferential direction does not occur in the duct portion 71, and the concern that the circulating flow J collides with the duct portion 71 in the circumferential direction (in the rotational direction F) to generate noise may be eliminated. it can.

  Then, the size of the gap 20 gradually increases (increases) from the middle of the straight region Q toward the corner region R, that is, the amount of depression to the inside of the duct portion 71 starts from the middle of the straight region Q. By forming the duct portion 71 so that the gap 20 in the corner region R portion is maximized by being continuously recessed toward the corner region R portion so that the gap 20 becomes the largest, the nearest distance point is also obtained in the straight region Q. It is possible to configure so that the gap 20 at the minimum becomes a standard value (standard gap amount), and the size of the gap 20 on the outer side in the circumferential direction is larger than the standard gap amount.

  Further, in the linear region Q portion of the duct portion 71, the position where the inward indentation on both the left and right sides in the circumferential direction starts including the position of the nearest distance point (for example, indicated by a point E in the linear region Q4 in FIG. 8). In the range between the two positions), the size of the gap 20 is constant at the standard gap amount (for example, constant at δq4 in the straight line area Q4 in FIG. 8), and the adjacent corner area from the position where the inward depression starts. The size of the gap 20 is gradually increased toward R, and the size of the gap 20 in the corner region R is configured on a straight line connecting the rotation center O and the straight end 65. That is, the size of the gap 20 is a standard gap amount in a predetermined range in the circumferential direction including the position of the nearest distance point.

  In the straight line region Q, the range in which the size of the gap 20 becomes the standard gap amount is as narrow as possible, and from there on the straight line connecting the rotation center O and the straight line end 65, that is, gradually toward the corner region R. It is desirable that the size is increased. Further, when the size of the gap 20 is gradually increased in the straight region Q, it is preferable that the gap 20 is continuously and smoothly increased, and it is desirable that no step is formed in the circumferential direction as much as possible.

  3 and 8, the size (δr1 to δr3) of the gap 20 in the corner region R is the maximum value in the circumferential direction of the gap 20 and is substantially constant in the inner circumferential direction of the corner region R. It may be configured such that the maximum value is obtained at the center of the direction and gradually decreases from the position toward the straight line connecting the rotation center O and the straight line end 65, that is, toward the adjacent straight line region Q. Good. That is, even in the corner region R, the size of the gap 20 may not be constant.

  FIG. 10 is a perspective view of the bell mouth 70 in this embodiment as viewed from the side where the turbo fan 10 is located. In the drawing, a circle indicated by a dotted line indicates the outer diameter of the duct portion 71 where the standard gap amount is formed. A circle formed by φDb. The duct portion 71 located in the corner region R is located on the inner side (center side) as shown by a dotted line as shown in the figure, and for this reason, a part of the duct portion 71 is located inside the circle indicated by a dotted line. In order to make it indent, it is dented inward smoothly so that a level | step difference may not arise in the circumferential direction of the duct part 71. FIG.

  The bell mouth 70 is formed with notches 74 and 75 in which two corners of the air passage wall 73 are cut in a substantially triangular shape. The notch 74 is located in the connecting plate region P, and the connecting plate 62 is disposed outside the notch 74. Further, the notch 75 is located in the corner region R3, and the inclined portion 69 (see FIG. 5) of the heat exchanger 60 is disposed outside the notch 75. The bell mouth 70 is formed of resin here, but may be integrally formed of sheet metal.

  As shown in FIG. 9, in the first embodiment, the size (δr1 in FIG. 9) of the gap 20 in the corner region R (corner region R1 in FIG. 9) is approximately equal to the standard gap amount (δq3 in FIG. 9). It is configured to be twice as large. How much the size of the gap 20 in the corner region R is larger than the standard gap amount is appropriately set depending on the unevenness of the distance between the turbofan outer periphery 10a and the heat exchanger 60.

  As described above, in the indoor unit 1 in which the gap 20 whose size changes in the circumferential direction is configured, the average size of the gap 20 in the corner region R where the static pressure of the fan blowing space 41 is lower than the straight region Q. However, since it is larger than the average size of the gap 20 in the straight region Q, the ventilation resistance when the circulating flow J passes through the gap 20 is smaller than that of the straight region Q. Therefore, the amount of ventilation of the circulating flow J passing through the gap 20 in the corner region R is increased in the corner region R as in the straight region Q as compared with the case where the standard gap amount is constant. Since the ventilation resistance is relatively small, the static pressure is relatively small, and even in the corner region R where the pressure difference between the fan blowing space 41 and the fan suction port (inside the cylindrical portion 14 of the shroud 12) is small, the circulation flow J Inflow into the gap 20 and passage through the gap 20 are facilitated.

  An increase in the air flow rate of the circulation flow J in the corner region R means a decrease in the air flow rate of the circulation flow J in the linear region Q, so that the uneven flow rate of the circulation flow J in the circumferential direction is corrected. .

  Further, the size of the gap 20 in the corner region R is made larger than the size of the gap 20 (standard gap amount) at the position where the static pressure of the fan blowing space 41 is the highest (the closest distance point), and in the conventional circumferential direction. Compared to the case where the size of the gap 20 is constant at the standard gap amount and the ventilation resistance of the gap 20 is equal in the circumferential direction, the ventilation resistance of the gap 20 in the corner region R is the same as that of the gap 20 at the closest distance. Since the flow resistance is smaller than the ventilation resistance, the circulation flow J to the gap 20 in the vicinity of the position of the nearest distance point where the circulation amount of the circulation flow J is relatively large in the circumferential direction due to the large pressure difference. Therefore, the non-uniform flow rate of the circulating flow J in the circumferential direction is corrected.

  Also in the straight region Q, the size of the gap 20 is larger on the outer side in the circumferential direction and closer to the corner region R than the position of the nearest distance point. Due to the pressure distribution (higher at the nearest distance point and lower toward the straight line end 65), the circulation flow in the straight region Q that occurs when the size of the gap 20 is constant at the standard gap amount in the conventional circumferential direction. The non-uniform flow rate of J (the flow rate in the vicinity of the closest distance point is large and the flow rate in the portion located outside in the circumferential direction is small) is corrected, and the flow rate of the circulating flow J in the entire circumferential direction including the corner region R is corrected. Non-uniformity will be corrected.

  Further, since the size of the gap 20 in the straight region Q gradually increases from the middle of the straight region Q toward the corner region R, the distance between the turbo fan outer periphery 10a and the heat exchanger 60 increases. Accordingly, as the size of the gap 20 increases and the static pressure in the fan blowing space 41 decreases corresponding to the distance between the two, the airflow resistance of the gap 20 also decreases. And the flow rate of the circulating flow J in the circumferential direction is corrected so as to approach evenly.

  As described above, the configuration of the gap 20 included in the indoor unit 1 of this embodiment corrects the non-uniformity in the circumferential direction of the flow rate of the circulating flow J, thereby reducing the circumferential discharge air pressure at the turbo fan outer periphery 10a. The non-uniformity is corrected, the fluctuation of the exhaust air pressure during one rotation is reduced, and the blowing sound generated due to the fluctuation can be reduced. Thus, it becomes possible to reduce the noise (the above-mentioned blowing sound) that has been generated due to the non-uniformity of the distance between the turbo fan outer periphery 10a and the heat exchanger 60. For this reason, compared with the case where the size of the conventional gap 20 is constant in the circumferential direction with the standard gap amount, the indoor unit 1 can be reduced in noise.

  In the indoor unit 1, the size of the gap 20 in the portion where the static pressure of the fan blowing space 41 is relatively low, that is, the portion where the distance between the turbo fan outer periphery 10 a and the heat exchanger 60 is long is set as the fan blowing space 41. By setting the distance between the part having a relatively high static pressure, that is, the distance between the turbo fan outer periphery 10a and the heat exchanger 60 to be larger than the size of the gap 20 in the short distance part, the turbo fan outer periphery 10a and the heat exchanger The airflow resistance of the gap 20 is changed in the circumferential direction corresponding to the static pressure distribution of the fan blowing space 41 due to the non-uniformity of the distance to 60 (in the portion where the static pressure of the fan blowing space 41 is relatively low). Therefore, the non-uniformity in the circumferential direction of the flow rate of the circulating flow J is corrected, so that the circumferential direction of the turbo fan outer periphery 10a is corrected. Is uneven outgoing air pressure corrective, it is possible to reduce the blowing noise that occurred due to the variation of the discharge pressure during one rotation.

  The indoor unit 1 of this embodiment is intended to make the flow rate distribution in the circumferential direction of the circulating flow J as uniform as possible, and the overall circulating flow rate J is equal to the standard circulation rate of the conventional gap 20. Since it does not increase compared with the case where it is a fixed amount in the circumferential direction, the blowing performance of the turbo fan 10 does not deteriorate.

Further, in the indoor unit 1, by correcting the non-uniformity in the circumferential direction of the flow rate of the circulating flow J, the flow rate of the air discharged from the turbo fan outer periphery 10a also stabilizes with little fluctuation in the 360 ° direction. Therefore, the static pressure distribution in the fan blowing space 41 is also corrected in the direction of equalization. That is, compared with the case where the conventional gap 20 has a constant circulation amount and a constant amount in the circumferential direction, the difference in static pressure between the closest distance portion in the straight region Q and the fan blowing space 41 in the corner region R (in the corner region R). Is smaller). As a result, the load fluctuation during one rotation of the turbofan 10 is reduced, the input of the fan motor 7 can be reduced, and the efficiency of the turbofan 10 can be increased. This is because even if the average load during one rotation is the same, the input with the fan motor 7 can be suppressed when the load fluctuation during one rotation is smaller. As a result, the indoor unit 1 is an air conditioner with low noise and high efficiency and excellent energy saving performance.

  Here, the connecting plate region P will be described. In the connecting plate region P, there is a connecting plate 62 that connects both end portions 61 of the heat exchanger 60, and the connecting plate 62 is between the both end portions 61 of the heat exchanger 60 that are located at a predetermined interval. The portion where the fins 67 do not exist is blocked to prevent the air flow that has not been heat exchanged by the heat exchanger 60 (the air flow discharged from the turbofan 10) from flowing out to the blowing air passage 3. . Therefore, there is no air flow that passes through the connecting plate 62 from the inside to the outside. As described above, the connecting plate 62 prevents air flow from the fan blowing space 41 to the blowing air passage 3, and therefore the ventilation resistance here is large, and the radial distance between the turbo fan outer periphery 60 a and the connecting plate 62 is small. Even if it is longer than the nearest distances L1 to L4 of the straight region Q, the static pressure of the fan blowing space 41 in the connecting plate region P is static in the fan blowing space 41 in the corner region R, as is the case with the closest distance of the straight region Q. Higher than pressure.

  Therefore, since the fan blowing space 41 in the connecting plate region P is a portion where the static pressure is relatively high when viewed in the circumferential direction, the size of the gap 20 in the corner region R is larger than the size of the gap 20 in the connecting plate region P. Must be set to be larger. Here, the size δp of the gap 20 in the connecting plate region P is not made larger than the standard gap amount, but is kept constant at the standard gap amount as the gap 20 at the closest distance, and the ventilation resistance of the gap 20 is large. The state is maintained. Along with the fact that the gap 20 in the corner region R is larger than the standard gap amount and the ventilation resistance in this portion is reduced, conventionally, the ventilation amount of the circulating flow J is relatively large based on the large pressure difference. By reducing the ventilation amount of the circulation flow J to the gap 20 in the connected plate region P, the ventilation amount of the circulation flow J in the corner region R can be increased. As a result, the non-uniformity in the flow rate of the circulation flow J in the circumferential direction including the connecting plate region P is corrected, and the non-uniformity in the circumferential discharge air pressure at the turbo fan outer periphery 10a is corrected. Noise generated due to fluctuations in the discharge air pressure can be reduced.

  As shown in FIG. 8, the distance from the closest distance indicated by the distance L1 of the linear region Q1 adjacent to the connecting plate region P in the circumferential direction to the linear region Q2 adjacent to the connecting plate region P on the opposite side to the linear region Q1. The size of the gap 20 is constant at a standard gap amount δq1 (= δq2 = δp) at least in the range of 90 ° in the circumferential direction across the connecting plate region P up to the closest distance point indicated by L2. Note that the size of the gap 20 in the connecting plate region P is not necessarily the standard gap amount, and is equal to or larger than the standard gap amount according to the distance between the turbofan outer periphery 10a and the connecting plate 62, and is a corner region. What is necessary is just to make smaller than the magnitude | size of the gap | interval 20 in R. However, the size of the gap 20 in the corner region R is set larger than the size of the gap 20 in any circumferential position of the connecting plate region P at any circumferential position.

  The non-circular cross-sectional shape of the duct portion 71 is determined by the relative positional relationship between the turbo fan 10 and the heat exchanger 60 and the configuration and form of the heat exchanger 60. Therefore, even if the turbo fan 10 is common, if those elements are changed, the cross-sectional shape of the duct portion 71 needs to be changed accordingly. For example, if the degree of unevenness of the distance between the turbofan outer periphery 10a and the heat exchanger 60 is larger, it becomes necessary to expand the size of the gap 20 in the corner region R to a size exceeding twice the standard gap amount. There is also a possibility.

  Therefore, if the bell mouth 70 is not integrally formed and the duct portion 71 is a separate body and the separate duct portion 71 is fixed to the curved surface portion 72 as shown in FIG. Corresponding to the relative positional relationship of the heat exchanger 60 and changes in the configuration and form of the heat exchanger 60, only the duct portion 71 is manufactured individually without manufacturing the entire bell mouth 70 individually. Can be shared.

  In the description so far, the duct portion 71 of the bell mouth 70 where the size of the gap 20 is desired to be larger than the standard gap amount is set to be larger than the circular shape having the outer diameter φDb where the size of the gap 20 is the standard gap amount. By being located inside, that is, recessed toward the rotation axis 5, the size of the gap 20 is changed in the circumferential direction (the minimum is the standard gap amounts δq1 to δq4 and δp, and the maximum is δr1 of the gap 20 in the corner region R). δr3).

  However, the size of the gap 20 may be changed in the circumferential direction without making the duct portion 71 non-circular. An example is shown in FIG. In this modification, the bell mouth duct portion 71 is formed in a circular cross section. However, the circular outer diameter φDc is a dimension that can secure the sizes δr1 to δr3 of the gap 20 in the corner region R. In other words, the inner diameter φDs of the shroud cylindrical portion 14 is used to obtain a dimension that satisfies φDc = φDs− (δr1 * 2). Here, δr1 may be replaced with δr2 or δr3.

  Then, the gap adjusting member 76 is attached to the outer peripheral surface of the duct portion 71 (outer diameter φDc) where the size of the gap 20 is desired to be reduced, and the size of the gap 20 is changed in the circumferential direction. The gap adjusting member 76 is attached to the linear region Q and the connecting plate region P, and is a resin molded product. The gap adjusting member 76 has the same height as the duct portion 71 (length in the rotation axis direction H), and both end surfaces in the rotation axis direction H are flat. And the inner side surface makes the curved surface shape along the outer peripheral surface shape of the duct part 71. As shown in FIG. Further, the outer side surface has a mountain shape with the top portion corresponding to the size of the gap 20 as a standard gap amount, and the outer side end of the outer side surface is smoothly lowered toward the corner region R. By forming such a mountain shape, also in the straight region Q, the size of the gap 20 gradually increases in the circumferential direction from the closest distance point (standard gap amount) toward the corner region R. Can be changed.

  As shown in FIG. 12, the gap adjusting member 76 may be individually attached or welded to a required portion of the outer peripheral surface of the duct portion 71 (in FIG. 12, three gap adjusting members 76 are installed). Each gap adjusting member 76 is connected in a ring shape with a ring member, and the ring member is attached or welded to the outer peripheral surface of the duct portion 71, or the ring member is fitted to the outer peripheral surface of the duct portion 71 and attached. Also good. In this case, the duct portion 71 has to reduce the outer diameter φDc by twice the thickness of the ring member.

  Heretofore, the heat exchanger 60 having a substantially rectangular shape has been described in a form surrounding the outer periphery of the circular turbofan 10, but the heat exchanger is not limited to a rectangular shape, and other than a rectangular shape. The same effect can be obtained even with a polygonal shape. The heat exchanger surrounding the circular turbo fan 10 may be bent into a triangle or a hexagon. In that case, the angle difference between the linear portions 64 adjacent to each other with the bent portion 63 interposed therebetween is not about 90 ° of the heat exchanger 60 of the first embodiment, but about 60 ° in the case of a triangle, If there is, it will be about 120 °.

Embodiment 2. FIG.
In the first embodiment, the distance between the turbo fan outer periphery 10a and the heat exchanger 60 is changed by changing the size of the gap 20 through which the circulating flow J passes in the circumferential direction to change the ventilation resistance in the circumferential direction. Although the non-uniformity of the flow rate in the circumferential direction of the circulation flow J caused by the non-uniformity is corrected as much as possible, the flow rate of the effective suction flow S increases when the flow rate of the circulation flow J is small. Therefore, it goes without saying that the air blowing efficiency of the turbo fan 10 is improved. Since the circulating flow J is to blow the air flow once discharged from the turbo fan 10 by the turbo fan 10 again, the flow rate is reduced as much as possible, and the flow rate of the effective suction flow S is increased accordingly. This is desirable in terms of efficiency.

  Therefore, in the second embodiment, as described above, the indoor unit 1 of the first embodiment in which the uneven flow rate in the circumferential direction of the circulation flow J is corrected is further provided with means for reducing the flow rate of the circulation flow J. The indoor unit will be described.

  13 is a cross-sectional view of the main part around the gap 20 of the indoor unit according to the second embodiment. FIG. 13A corresponds to a cross-sectional view taken along the line Y1-O in FIG. FIG. 6B shows the periphery, and FIG. 4B corresponds to a cross-sectional view taken along the line Y3-O in FIG. 3 and shows the periphery of the gap 20 at the closest distance portion of the straight region Q. In the second embodiment, the same or equivalent parts as those in the first embodiment are denoted by the same reference numerals and the description thereof is omitted.

  The indoor unit according to the second embodiment is different from the indoor unit 1 according to the first embodiment in the shape of the bell mouth. Specifically, the end portion of the duct portion 71, that is, the end portion on the downstream side in the air flow. The shape is different. As shown in FIG. 13, the bell mouth 80 shown in the second embodiment has a duct tip enlarged portion 77 at the downstream end (tip portion) of the duct portion 71, and this duct tip enlarged portion. 77 has a tapered shape that gradually becomes thinner from the upstream of the air flow (effective suction flow S) in the rotation axis direction H toward the downstream, and from the upstream of the air flow (effective suction flow S) in the rotation axis direction H. The curved shape is such that the diameter gradually increases outward (in the centrifugal direction) in the radial direction toward the downstream. The shape is such that it gradually warps toward the shroud cylindrical portion 14 while becoming thinner toward the tip. The duct tip enlarged diameter portion 77 is formed continuously from the straight portion of the duct portion 71.

  At this time, the size of the gap 20 indicates the radial distance between the end of the duct tip enlarged portion 77, that is, the downstream end of the air flow and the inner peripheral surface of the shroud cylindrical portion 14. Therefore, the distance between the end of the duct tip enlarged portion 77 and the inner peripheral surface of the shroud cylindrical portion 14 at the closest distance portion of the straight region Q is the standard gap amount. FIG. 13B shows a cross section of the straight region Q3 at the closest distance, so the size of the gap 20 is δq3, which is the standard gap amount. Similarly, in FIG. 13A, since the gap 20 in the corner region R1 is illustrated, this is represented by the distance between the end of the duct tip enlarged portion 77 and the inner peripheral surface of the shroud cylindrical portion 14. The size of the gap 20 is δr1. The aspect in which the size of the gap 20 changes in the circumferential direction is the same as in the first embodiment.

  By forming the duct tip enlarged portion 77 having the above-described shape at the downstream end portion of the duct portion 71 of the bell mouth 80, the circulation flow passing through the gap 20 with the nonuniform flow rate in the circumferential direction corrected. When J passes through the gap 20, the inner diameter of the shroud 12 (including the inner circumference of the cylindrical portion 14) is increased by the duct tip enlarged portion 77 while proceeding in the turbo fan rotation direction F through the gap 20. The flow changes to That is, the duct tip diameter increasing portion 77 changes the component of the circulating flow J that advances in the rotation axis direction H in the radial direction.

  Therefore, the effective suction flow S flowing into the turbofan 10 from the fan suction space 40 (see FIG. 7) through the inner peripheral side of the duct portion 71 of the bell mouth 80 cannot be pushed away in the rotational axis direction H by the circulation flow J. . If so, the effective suction flow S can be smoothly changed in the radial direction without being affected by the circulation flow J. As a result, the effective suction flow S whose direction is changed in the radial direction is hindered, and the circulation flow J is difficult to flow into the gap 20, and the effective suction flow S is not hindered (pushed away) by the circulation flow J. Therefore, the flow rate of the effective suction flow S increases relatively, and the flow rate of the circulation flow J can be decreased.

  As described above, in the second embodiment, in addition to the first embodiment, the downstream end of the duct portion 71 of the bell mouth 80 is gradually moved in the rotation axis direction H from the upstream side to the downstream side of the air flow. Since the duct tip enlarged portion 77 having a curved shape in which the diameter gradually increases outward in the radial direction is formed, the flow rate of the circulating flow J is not uniform in the circumferential direction. Is corrected, unevenness in the discharge air pressure in the circumferential direction on the turbo fan outer periphery 10a is corrected, the flow rate of the circulation flow J can be decreased, and the flow rate of the effective suction flow S can be increased. Thereby, the ventilation performance of the turbo fan 10 can be improved. As a result, the indoor unit of the second embodiment can be an air conditioner that is more efficient and more energy efficient than the indoor unit 1 of the first embodiment while reducing noise.

Embodiment 3 FIG.
In the third embodiment, the flow rate of the circulating flow J is different from the above-described second embodiment, in addition to the indoor unit 1 of the first embodiment in which the non-uniform flow rate in the circumferential direction of the circulating flow J is corrected. A description will be given of an indoor unit provided with means for reducing the above. FIG. 14 is an explanatory diagram of the bell mouth 81 used in the indoor unit according to the third embodiment, in which the right half shows a longitudinal sectional view and the left half shows a side view. In the third embodiment, the same or equivalent parts as those in the first and second embodiments are denoted by the same reference numerals and the description thereof is omitted.

  The indoor unit of the third embodiment is different from the indoor unit 1 of the first embodiment in the configuration of the bell mouth. Specifically, the duct unit 71 is formed thick, and the thick duct unit A plurality of grooves 78 a along the rotational axis direction H are provided on the outer peripheral surface 79 of 71 so as to be juxtaposed in the circumferential direction, and an uneven shape is formed on the outer peripheral surface 79. The groove 78a is a concave groove that is provided so as to cut the outer peripheral surface 79 of the thick duct portion 71, and does not communicate with the inner peripheral side. The grooves 78a are formed on the entire outer peripheral surface 79 with a predetermined interval in the circumferential direction. The depth of the groove 78a is about 1.5 mm, and is limited to about 2/3 at most with respect to the thickness of the thick duct portion 71. The plurality of grooves 78a are equally spaced in the circumferential direction, and the circumferential widths are all the same.

  In this bell mouth 81, the duct tip enlarged portion 77 shown in the second embodiment is formed at the downstream end (tip portion) of the duct portion 71, so the groove 78a is formed at the tip ( The cross-sectional shape in the rotational axis direction H is substantially arcuate from the curved end 72 to the curved end 72 (which is also the end of the duct tip enlarged portion 77). Here, the duct tip enlarged portion 77 is not necessarily provided and may be omitted. That is, the duct portion 71 may be linear from the contact point with the curved surface portion 72 to the downstream end (tip). In this case, the groove 78 a is a concave groove opened on the downstream end side of the duct portion 71. At this time, the taper may be tapered toward the straight tip.

  In an indoor unit of an air conditioner using a bell mouth 81 in which a plurality of grooves 78a are formed along the rotational axis direction H in the circumferential direction on the outer peripheral surface 79 of the duct portion 71 shown in the third embodiment. The size of the gap 20 is indicated by the radial distance between the outer peripheral surface 79 of the thick-walled duct portion 71 and the inner peripheral surface of the shroud cylindrical portion 14. Also in the indoor unit of the third embodiment, the aspect in which the size of the gap 20 changes in the circumferential direction is the same as that of the first embodiment.

  By forming the plurality of grooves 78a as described above on the outer peripheral surface 79 of the duct portion 71 of the bell mouth 81, the non-uniform flow rate in the circumferential direction is corrected and the circulating flow J passing through the gap 20 is rotated by the turbofan. When passing through the gap 20 while having a component proceeding in the direction F, the flow along the outer circumferential surface 79 of the duct portion 71 while proceeding in the rotational direction F, that is, the side closer to the outer circumferential surface 79 of the duct portion 71 in the gap 20. Since the flow is disturbed by the outer peripheral surface 79 that is uneven by the plurality of grooves 78a, pressure fluctuations are generated, and this also propagates to the flow close to the inner peripheral surface side of the shroud cylindrical portion 14, so the ventilation of the gap 20 The resistance will increase overall.

  For this reason, it becomes difficult for the circulating flow J to flow through the gap 20, and the flow rate of the circulating flow J relatively decreases, so that the flow rate of the effective suction flow S can be increased. Further, as shown in FIG. 14, if the duct tip enlarged portion 77 is formed at the downstream side end portion of the duct portion 71, the effect described in the second embodiment is also exhibited, so effective suction. The effect of increasing the flow rate of the flow S and decreasing the flow rate of the circulation flow J becomes more remarkable.

  When the depth of the groove 78a is deep, the turbulence of the circulating flow J flowing through the gap 20 becomes severe and the pressure fluctuation becomes large, and new noise (sound that makes the user of the air conditioner feel uncomfortable) is generated. Or the circulating flow J may collide with the side wall located on the downstream side with respect to the rotation direction F of the groove 78a to generate new noise, and the depth of the groove 78a is It is desirable to make it less than half of the standard gap amount. If the pressure fluctuations or flow collisions occur at such a depth, there will be no noise at a level that would make the air conditioner user feel uncomfortable.

  Since the groove 78a is formed to disturb the flow component of the circulating flow J in the vicinity of the outer peripheral surface 79 in the fan rotation direction F, a side wall is not necessarily required upstream in the rotation direction F. The cross-sectional shape in the circumferential direction of the groove 78a may not be a substantially rectangular shape, but may be a substantially right triangle shape in which a side wall is formed only at a position downstream in the rotational direction F with respect to the circumferential direction. Similarly, in order to disturb the flow component in the fan rotation direction F of the circulating flow J in the vicinity of the outer peripheral surface 79, the plurality of grooves 78a may not be equally spaced in the circumferential direction, and the circumferential direction of the groove 78a may be The widths need not all be the same.

  As described above, in the third embodiment, in addition to the first embodiment, the outer peripheral surface 79 of the duct portion 71 of the bell mouth 81 is provided with a plurality of grooves 78a along the rotation axis direction H parallel to the circumferential direction. Since the uneven shape is formed on the outer peripheral surface 79 of the duct portion 71, the non-uniformity in the circumferential direction of the flow rate of the circulating flow J is corrected, and the non-uniformity in the circumferential discharge air pressure in the turbo fan outer periphery 10a is corrected. In addition, the flow rate of the circulation flow J can be decreased and the flow rate of the effective suction flow S can be increased. Thereby, the ventilation performance of the turbo fan 10 can be improved. As a result, the indoor unit of the third embodiment can be an air conditioner that is more efficient and more energy efficient than the indoor unit 1 of the first embodiment while reducing noise.

Embodiment 4 FIG.
The indoor unit shown in the fourth embodiment is different from the third embodiment described above in the form of grooves formed on the outer peripheral surface of the duct portion of the bell mouth. In addition to the indoor unit 1 of the first embodiment that corrects the non-uniform flow rate in the circumferential direction, the indoor unit is provided with means for reducing the flow rate of the circulating flow J. FIG. 15 is an explanatory diagram of the bell mouth 82 used in the indoor unit according to the fourth embodiment. In contrast to the side view shown in the left half of FIG.
Only the left side view is shown. In the fourth embodiment, components that are the same as or equivalent to those in the first to third embodiments are denoted by the same reference numerals and description thereof is omitted. The bell mouth 82 shown in the fourth embodiment is different from the bell mouth 81 described in the third embodiment only in the form of a plurality of grooves formed in the outer peripheral surface 79 of the duct portion 71 shown below. Is the same as that of the third embodiment, and a description thereof is omitted here.

  On the outer peripheral surface 79 of the duct portion 71 of the bell mouth 82 shown in the fourth embodiment, the portion on the downstream side of the air flow in the rotational axis direction H is opposite to the turbo fan rotational direction F than the upstream portion. A plurality of inclined grooves 78b inclined in parallel are formed in parallel in the circumferential direction. As shown in FIG. 15, the inclined groove 78 b is inclined with respect to the rotation axis direction H in the circumferential direction by an angle θ in the direction opposite to the rotation direction F in the circumferential direction. The groove 78a shown in the third embodiment extends in the rotation axis direction H and θ = 0 °. However, in the inclined groove 78b, θ is larger than 0 °. The angle θ differs between the inclined groove 78b of the fourth embodiment and the groove 78a of the third embodiment. Similarly to the groove 78a, the inclined groove 78b is a concave groove provided so as to cut the outer peripheral surface 79 of the duct portion 71, and does not communicate with the inner peripheral side.

  In the fourth embodiment, a plurality of inclined grooves 78 b are formed on the outer peripheral surface 79 of the duct portion 71 of the bell mouth 82, so that the groove side wall located at the downstream side in the turbo fan rotation direction F is upstream of the rotation direction F. If the groove depth is the same as that of the groove 78a with θ = 0 ° shown in the third embodiment, the circulation flow J of the outer circumferential surface 79 is uneven. The turbulence can be increased, and the ventilation resistance of the gap 20 can be further increased.

  In other words, if the turbulence level of the circulating flow J due to the uneven shape of the outer peripheral surface 79 is equivalent, that is, if the increase in the ventilation resistance of the gap 20 is to be equivalent, θ = 0 ° shown in the third embodiment. As compared with the groove 78a, the groove depth can be reduced. That is, in order to obtain the same effect, the inclined groove 78b of the bell mouth 82 can be made shallower than the groove 78a of the bell mouth 81 shown in the third embodiment. As described in the third embodiment, if the groove depth is too deep, new noise may be generated. However, by using the inclined groove 78b, the groove 78a of the third embodiment is used. Since the groove depth can be reduced, this concern is dispelled.

  The fact that the depth of the groove can be reduced means that the thickness (the radial width) of the duct portion 71 that has been made thick in order to form the groove can also be reduced. The material can be reduced more than the bell mouth 81 of the third embodiment, and the resource can be saved.

  If the angle θ of the inclined groove 78b is too large, the turbulence of the circulating flow J flowing through the gap 20 becomes severe and the pressure fluctuation becomes large as in the case where the groove depth is increased. Therefore, the angle θ of the inclined groove 78b is preferably 60 ° or less, and the groove depth is made shallower than the groove 78a in which θ = 0 ° shown in the third embodiment, so that the same effect as the groove 78a is obtained. In this case, θ is preferably 30 ° or more, and preferably 30 ° ≦ θ ≦ 45 °. The inclined groove 78b shown in FIG. 15 is θ = 30 °. The plurality of inclined grooves 78b may not all have the same angle θ.

  As described above, in the fourth embodiment, in addition to the first embodiment, the outer circumferential surface 79 of the duct portion 71 of the bell mouth 82 is opposite to the rotational direction F in the circumferential direction with respect to the rotational axis direction H. A plurality of inclined grooves 78b whose downstream side is inclined by an angle θ is provided in the direction, and an uneven shape is formed on the outer peripheral surface 79 of the duct portion 71. Therefore, unevenness in the circumferential direction of the flow rate of the circulating flow J is corrected, and the turbofan The uneven discharge air pressure in the circumferential direction on the outer periphery 10a can be corrected, the flow rate of the circulation flow J can be reduced, and the flow rate of the effective suction flow S can be increased. Thereby, the ventilation performance of the turbo fan 10 can be improved. As a result, the indoor unit of the second embodiment can be an air conditioner that is more efficient and more energy efficient than the indoor unit 1 of the first embodiment while reducing noise.

  DESCRIPTION OF SYMBOLS 1 Air conditioner indoor unit, 3 blowing air path, 4 drain pump, 5 rotation axis, 6 motor rotation shaft, 7 fan motor, 8 drain pan, 9 ceiling, 10 turbo fan, 10a turbo fan outer periphery, 11 main plate, 11a uplift Part, 12 shroud, 13 wings, 13a leading edge, 13b trailing edge, 14 cylindrical part, 15 motor storage space, 16 boss part, 20 gap, 30 housing, 31 design panel, 32 suction port, 33 suction grille, 34 air Filter, 35 Air outlet, 36 Wind direction vane, 37 Top plate, 38 Side plate, 39 Heat insulator, 40 Fan suction space, 41 Fan air outlet space, 60 Heat exchanger, 61 Both ends, 62 Connecting plate 63 Bending part, 64 Straight part , 65 Linear end, 66 Piping connection, 67 Fin, 68 Piping, 69 Inclined part, 0 Bell mouth, 71 Duct portion, 72 Curved portion, 73 Air passage wall, 74, 75 Notch portion, 76 Gap adjusting material, 77 Duct tip enlarged portion, 78a groove, 78b Inclined groove, 79 Outer peripheral surface, 80, 81 , 82 Bell mouth, F turbo fan rotation direction, H rotation axis direction, J circulation flow, K main flow, O rotation center, P connecting plate region, Q, Q1-Q4 linear region, R, R1-R3 angular region, S effective Suction flow.

Claims (9)

A housing in which a design panel having a suction port and a plurality of outlets formed around the suction port is attached so as to cover the opening surface;
A main plate, a donut-shaped shroud formed concentrically with the main plate and facing the main plate at a predetermined interval and having a cylindrical portion extending in the direction of the suction port at a central portion; and between the main plate and the shroud A turbofan comprising a plurality of blades sandwiched and fixedly connected to each of the main plate and the shroud, housed in the housing, and generating an air flow from the suction port to the blowout port;
A bell mouth that is located between the suction port and the turbo fan and has a duct portion extending in the direction of the turbo fan and guides indoor air sucked from the suction port to the turbo fan,
The turbo is composed of a plurality of thin plate-like fins arranged in parallel at a predetermined interval and a metal pipe inserted through the fins in a plurality of stages, and has a polygonal shape. A heat exchanger that is housed in the housing so as to surround the fan, and exchanges heat with room air sucked from the suction port and discharged from the turbofan,
The downstream end of the bell mouth duct part in the air flow is located on the inner peripheral side of the cylindrical part of the shroud, and the upstream end part of the cylindrical part in the air flow and the downstream side of the duct part The end portion overlaps with a predetermined distance in the direction of the rotation axis of the turbofan, with a gap in the radial direction, and
The size of the gap between the cylindrical part and the duct part is not a constant amount in the circumferential direction, and the distance between the turbofan and the heat exchanger is longer than the short distance part. Is set to be large ,
In the heat exchanger, a direction in which the fins are arranged in parallel extends linearly in the longitudinal direction of the blowout port, and a plurality of adjacent linear portions having a predetermined angle difference and between the adjacent linear portions. And a bent portion located at
In the housing, a region sandwiching the straight portion between straight lines connecting the rotation center O of the turbofan and the longitudinal end point of the straight portion of the heat exchanger is a straight region, and the rotation center O and the longitudinal end point When the area sandwiching the bent portion between the straight lines connecting the two as a corner area, is divided into a plurality of areas,
In the linear region, there is a position where the distance between the turbofan and the heat exchanger is the shortest distance,
The size of the gap in the corner region is such that the distance between the turbo fan and the heat exchanger in the straight region is the shortest distance at any circumferential position in the corner region. An indoor unit of an air conditioner characterized by being set larger than the size . Average size of the gaps in the corner area, the indoor unit of an air conditioner according to claim 1, wherein greater than the average size of the gap in the linear region. In the linear region, the size of the gap in the portion close to the corner region in the linear region is larger than the size of the gap in a position where the distance between the turbofan and the heat exchanger is the shortest distance. The indoor unit of an air conditioner according to claim 1 or 2, wherein the indoor unit is large. The heat exchanger includes both ends of the fins arranged in parallel and are located at a predetermined interval from each other, and a connecting plate that closes a portion where the fins are not present between the two ends. ,
In the housing, when a region sandwiching the connecting plate between straight lines connecting the rotation center O of the turbofan and the both end portions of the heat exchanger is partitioned from the connecting plate region,
The size of the gap in the corner region is set larger than the size of the gap in any circumferential position of the connecting plate region at any circumferential position in the corner region. The indoor unit of the air conditioner according to any one of claims 1 to 3 . The size of the gap in the connecting plate region is the same as the size of the gap in a position where the distance between the turbo fan and the heat exchanger in the linear region is the shortest distance. 4. An indoor unit for an air conditioner according to 4 . The indoor unit of an air conditioner according to any one of claims 1 to 5 , wherein a cross-sectional shape of the duct portion of the bell mouth is non-circular. The end of the duct portion that is on the downstream side in the air flow has a tapered shape that gradually becomes thinner from the upstream to the downstream of the air flow in the rotation axis direction of the turbofan, and gradually in the centrifugal direction. The indoor unit of an air conditioner according to any one of claims 1 to 6 , wherein the indoor unit has a curved shape whose diameter increases. The outer peripheral surface of the duct section, according to any one of claims 1 to 7, wherein a plurality of concave grooves along the rotational axis of the turbofan is formed in parallel in the circumferential direction Air conditioner indoor unit. On the outer peripheral surface of the duct portion, a plurality of concave slopes in which a portion on the downstream side of the air flow in the direction of the rotation axis of the turbo fan is inclined in a direction opposite to the rotational direction of the turbo fan relative to the upstream portion. The indoor unit of an air conditioner according to any one of claims 1 to 7 , wherein the grooves are formed in parallel in the circumferential direction.

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