JP2016145661A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner which suppresses interference of a vortex flow to the air sucked from a suction port and which can increase an air amount ventilating a cross flow fan, in an indoor unit including the cross flow fan, a heat exchanger, a rear guider and a stabilizer inside a blower circuit.SOLUTION: An air conditioner 100 includes a heat exchanger 106, a cross flow fan 107, a stabilizer 108 and a rear guider 109 in a blower circuit 105. Out of a tangential line of a blade outer peripheral circle of the cross flow fan 107, a straight line crossing a tongue part 108a vertically is defined as an outer peripheral circle tangential line L1, and an intersection point of the outer peripheral circle tangential line and the tongue part 108a is defined as a tip point 110. In an indoor unit 101, the cross flow fan 107 side from the tip point 110 of the tongue part 108a protrudes further to the cross flow fan 107 side than a virtual circle C1 in which a first circular arc 108b for forming the rear guider 109 side is extended from the tip point 110 of the tongue part 108a.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an air conditioner such as an air conditioner provided with a cross flow fan.

  In general, a blower circuit for ventilating a main body casing having a suction port and a blower outlet is formed, a crossflow fan is provided in the blower circuit, and a heat exchanger is arranged in the vicinity of the upstream of the crossflow fan. 2. Description of the Related Art An air conditioner having an indoor unit that blows out air from an air outlet after exchanging heat through air that has been sucked from the air inlet by rotation of the air through a heat exchanger is known.

  Such an indoor unit includes a rear guider and a stabilizer in order to form an air flow generated by the rotation of the cross flow fan. By the way, as the air flow inside the cross flow fan, a flow that flows through the cross flow fan and blows out from the outlet (main flow) is generated between the cross flow fan and the stabilizer and circulates in a spiral shape at the tip of the stabilizer. There is a flow (vortex flow). Then, the eddy current strikes the cross flow fan at a constant period and generates blade pitch sound.

  Here, as an example of a conventional indoor unit, an indoor unit 2 of an air conditioner 1 disclosed in Patent Document 1 will be described with reference to FIG. The air conditioner 1 forms a blower circuit 4 that ventilates the main body casing 3, and houses a heat exchanger 5 and a crossflow fan 6 that ventilates the heat exchanger 5 in the blower circuit 4. A rear guider 7 and a stabilizer 8 are provided in the vicinity of the fan 6.

  As shown in FIG. 6, the stabilizer 8 has an arc shape in which a cross-sectional shape in a direction orthogonal to the central axis of the cross flow fan 6 on the surface facing the cross flow fan 6 protrudes toward the cross flow fan 6 side. The cross section cut along a plane parallel to the central axis of the flow fan 6 has a shape in which rectangular convex portions 8a and concave portions 8b are alternately repeated.

  The cross-sectional shape of the stabilizer 8 cut along a plane orthogonal to the central axis of the crossflow fan 6 differs depending on the position where the plane orthogonal to the central axis of the crossflow fan 6 intersects the central axis of the crossflow fan 6. As a result, the vortex flow that is generated between the stabilizer 8 and the cross flow fan 6 and circulates in a spiral shape at the tip of the stabilizer 8 is changed into a different flow path corresponding to the rectangular convex portion 8a and the concave portion 8b of the stabilizer 8. Is divided into a plurality of vortex flows, and the blades of the cross flow fan 6 have different flow paths and intermittently traverse with a time difference to disperse the frequency of the wing pitch sound, which is detrimental to hearing The aim is to reduce the wing pitch sound.

Japanese Patent Laid-Open No. 4-80533

However, in the air conditioner 1 according to Patent Document 1, the vortex flow A generated between the convex portion 8 a of the stabilizer 8 and the cross flow fan 6 and the concave portion 8 b of the stabilizer 8 and the cross flow fan 6 are generated. Eddy current B is generated. The vortex B strikes the cross flow fan 6 at a location closer to the proximity of the cross flow fan 6 and the heat exchanger 5 than the vortex A. The portion where the vortex B hits the cross flow fan 6 has a higher air flow speed and a larger air volume than the portion where the vortex A hits the cross flow fan 6.

  Therefore, interference with the air sucked from the suction port due to the vortex B becomes stronger than before, and there is a risk that the air flow through the cross flow fan 6 is reduced or the blade pitch sound is amplified by disturbing the flow of the sucked air. is there.

  The present invention has been made in view of the above-described conventional problems, and suppresses interference with the air sucked from the suction port, relaxes the disturbance of the flow of the sucked air, and allows the air flowing through the crossflow fan to flow. It aims at providing the air conditioner which can increase quantity.

  An air conditioner according to the present invention includes a main body casing provided with a suction port and an air outlet, a blower circuit provided in the main body casing, a cross flow fan provided in the blower circuit, and a tongue portion. A stabilizer, a rear guider, and a heat exchanger, and the cross-sectional shape of the tongue is an outer circumferential circle tangent of a straight line perpendicular to the tongue of the outer circumferential circle of the cross flow fan, When the intersection point between the outer circumferential tangent and the tongue portion is a tip point, the cross flow fan side from the tip point is closer to the cross flow than a virtual circle extending a first arc forming the rear guider side from the tip point. It protrudes to the fan side.

  As a result, the main flow that passes through the cross flow fan and blows out from the blowout port flows smoothly from the tip end of the tongue portion to the blowout port along the first arc that forms the rear guider side. On the other hand, the cross flow fan side from the tip of the tongue protrudes from the tip of the tongue toward the cross flow fan from a virtual circle extending from the first arc that forms the rear guider side. Compared to the case, the vortex generated between the cross flow fan and the stabilizer and circulated in a vortex shape at the tip of the stabilizer circulates to the cross flow fan in the vicinity of the tongue and is sucked from the suction port. Thereby, interference with the air passing through the heat exchanger of the vortex flow is suppressed, the disturbance of the flow of the suction air of the cross flow fan can be reduced, and the amount of air that the cross flow fan passes can be increased.

The air conditioner according to the present invention can suppress interference with the air sucked from the suction port, relax the disturbance of the flow of the sucked air, and increase the amount of air that the cross flow fan passes.

Sectional drawing which shows an example of a structure of the air conditioner which concerns on Embodiment 1 of this invention. The expanded sectional view which shows the stabilizer vicinity of the air conditioner which concerns on Embodiment 1 of this invention. Sectional drawing which shows an example of a structure of the air conditioner which concerns on Embodiment 2 of this invention. The expanded sectional view which shows the stabilizer vicinity of the air conditioner which concerns on Embodiment 2 of this invention. Sectional drawing which shows the indoor unit of the air conditioner which concerns on patent document 1 The perspective view which shows the stabilizer of the air conditioner which concerns on patent document 1

1st invention is a stabilizer provided with the main body casing provided with the suction inlet and the blower outlet, the ventilation circuit provided in the said main body casing, the crossflow fan provided in the said ventilation circuit, and the tongue part And a rear guider and a heat exchanger, and the cross-sectional shape of the tongue portion is a tangent line of the outer periphery circle of the cross flow fan with a straight line perpendicular to the tongue portion as an outer periphery circle tangent line, and the outer periphery circle When the intersection of the tangent and the tongue is a tip point, the cross flow fan side from the tip point is closer to the cross flow fan side than a virtual circle extending a first arc that forms the rear guider side from the tip point. It is an air conditioner that projects.

  According to this, the main flow which blows off from a blower outlet through a crossflow fan flows smoothly to a blower outlet along the 1st circular arc which forms the rear guider side from the front-end | tip point of a tongue part. On the other hand, the cross flow fan side from the tip of the tongue protrudes from the tip of the tongue toward the cross flow fan from a virtual circle extending from the first arc that forms the rear guider side. Compared to the case, the vortex generated between the cross flow fan and the stabilizer and circulated in a vortex shape at the tip of the stabilizer circulates to the cross flow fan in the vicinity of the tongue and is sucked from the suction port. Thereby, interference with the air passing through the heat exchanger of the vortex flow is suppressed, the disturbance of the flow of the suction air of the cross flow fan can be reduced, and the amount of air that the cross flow fan passes can be increased.

  In a second aspect of the present invention, in particular, in the air conditioner of the first aspect, the cross flow fan side from the tip is formed by a second arc, and the radius R2 of the second arc is the radius of the first arc. It is larger than R1.

  According to this, the vortex generated between the cross flow fan and the stabilizer and circulated in a spiral shape at the tip of the stabilizer does not cause stagnation or fine vortex from the tip of the tongue on the surface on the cross flow fan side, It can be guided to the cross flow fan in the vicinity of the tongue. For this reason, interference with the air sucked from the suction port is suppressed, the disturbance of the flow of the suction air of the cross flow fan can be reduced, and the amount of air that the cross flow fan passes can be increased.

  In the third aspect of the invention, in particular, in the air conditioner of the second aspect, the first arc tangent of the first arc at the tip point and the second arc tangent of the second arc at the tip point are the same straight line. It is what.

  According to this, the main flow that is blown out from the outlet through the cross flow fan at the front end point and the vortex flow that is generated between the cross flow fan and the stabilizer and circulates in a spiral shape at the front end of the stabilizer are the first. The flow can be smoothly divided into the arc and the second arc, and the air flow can be prevented from being disturbed in the vicinity of the tip point.

  In a fourth aspect of the present invention, in particular, in the air conditioner of the first aspect, an intersection of the first arc and the flat portion provided in the stabilizer is a continuous contact, and the connection is selected from straight lines orthogonal to the outer circumferential tangent. When a straight line intersecting the point is a connecting part orthogonal straight line, and a part located between the tip point and the connecting part orthogonal straight line is a tip part, the tip part is closer to the cross flow fan side than the outer circumferential tangent line. The thickness is larger than the thickness on the rear guider side from the outer circumferential circle tangent.

  According to this, the cross flow fan side from the front end point of the tongue can be designed in a shape that can positively apply the vortex to the cross flow fan at a desired location. For this reason, interference with the air sucked from the suction port is suppressed, the disturbance of the flow of the suction air of the cross flow fan can be reduced, and the amount of air that the cross flow fan passes can be increased.

  In the air conditioner according to the fourth aspect of the invention, in particular, in the air conditioner of the fourth aspect of the invention, as the tip approaches the connecting portion orthogonal straight line from the tip, the thickness on the cross flow fan side from the outer circumference tangent and the outer circumference circle The difference from the tangent to the thickness on the rear guider side becomes larger.

According to this, the vortex generated between the cross flow fan and the stabilizer and circulated in a vortex shape at the tip of the stabilizer can be further guided to the cross flow fan near the tongue. For this reason, interference with the air sucked from the suction port is suppressed, the disturbance of the flow of the suction air of the cross flow fan can be reduced, and the amount of air that the cross flow fan passes can be increased.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Each embodiment described below is an example, and the present invention is not limited to each embodiment.

(Embodiment 1)
The air conditioner 100 according to the present embodiment includes an outdoor unit (not shown) and an indoor unit that are connected to each other through a refrigerant pipe. FIG. 1 is a cross-sectional view illustrating an example of a configuration of an air conditioner 100 according to the present embodiment. FIG. 2 is an enlarged cross-sectional view showing the vicinity of the stabilizer 108 of the air conditioner 100 according to the present embodiment. 1 and 2 show a cross section of the cross flow fan 107 on a plane orthogonal to the central axis.

  As shown in FIG. 1, the indoor unit 101 includes a blower circuit 105 for passing air through a main body casing 104 having a suction port 102 and a blower outlet 103, and a heat exchanger 106 and a cross flow fan 107 inside the blower circuit 105. A stabilizer 108 and a rear guider 109 are provided.

  The suction port 102 is provided on the front surface of the main body casing 104, and the air outlet 103 is provided below the front surface of the main body casing 104. For this reason, the blower circuit 105 is bent during the period from the inlet 102 to the outlet 103.

  The heat exchanger 106 heats or cools the air sucked from the suction port 102 by the cross flow fan 107 by heat exchange.

  The cross flow fan 107 is a blower that blows air taken in from the suction port 102 to the heat exchanger 106 and then blows the air into the room from the air outlet 103. The cross flow fan 107 is configured to be rotatable about a central axis provided in the lateral width direction of the main body casing 104. The cross flow fan 107 has a configuration in which an end plate provided at an end portion and a plurality of fan bodies are connected in series. The fan body has a configuration in which a support plate is attached to at least one end of an impeller having a plurality of blades arranged in an annular shape.

  The stabilizer 108 is disposed below the heat exchanger 106 and below the cross flow fan 107. The rear guider 109 is disposed on the back side of the cross flow fan 107 so as to face the stabilizer 108.

  The stabilizer 108 and the rear guider 109 are for forming a flow of air generated by the rotation of the cross flow fan 107. The stabilizer 108 and the rear guider 109 constitute a blow-out side of the blower circuit 105 (downstream side of the cross flow fan 107) together with left and right walls (not shown).

  The stabilizer 108 is located in the vicinity of the downstream of the cross flow fan 107, is positioned on the downstream side of the tongue 108 a and the tongue 108 a that stabilizes the vortex generated in the vicinity of the front of the cross flow fan 107. And a flat surface portion 108d serving as a diffuser for recovering the pressure of the air conveyed by the air.

Hereinafter, the shape of the tongue 108a will be described. The tongue 108 a is provided across the entire width of the main body casing 104 or the cross flow fan 107 in the central axis direction of the cross flow fan 107. The main portion of the tongue 108 a has the same cross-sectional shape in the direction perpendicular to the central axis of the cross flow fan 107 over the main body casing 104 or both ends of the cross flow fan 107. That is, the cross-sectional shape of the tongue portion 108a only needs to be the same in the main portion of the tongue portion 108a. For example, some cross-sectional shapes such as end portions near the left and right walls may be different.

  As shown in FIG. 2, the cross section of the tongue 108 a is formed in a substantially arc shape that protrudes downward from the cross flow fan 107.

  The arc forming the tongue 108a is mainly formed by two arcs. Of the tangents of the outer circumference of the blade of the cross flow fan 107, a straight line that intersects perpendicularly with the tongue 108a of the stabilizer 108 is defined as an outer circumference tangent L1, and an intersection between the outer circumference tangent L1 and the tongue 108a is defined as a tip point 110. A portion below the tip point 110 of the tongue portion 108a (rear guider 109 side) is formed by a first arc 108b, and a portion above the tip point 110 (cross flow fan 107 side) is formed by a second arc 108c.

  The cross flow fan 107 side from the tip point 110 of the tongue portion 108a protrudes toward the cross flow fan 107 from a virtual circle C1 extending from the tip point 110 of the tongue portion 108a to the first arc 108b that forms the rear guider 109 side. . Here, the radius R2 of the second arc 108c is larger than the radius R1 of the first arc 108b.

  Also, the first arc tangent L2 that is the tangent of the first arc 108b at the tip point 110 and the second arc tangent L3 that is the tangent of the second arc 108c at the tip point 110 are the same straight line.

  Furthermore, the point where the distance between the tongue portion 108a and the cross flow fan 107 is closest is located on the second arc 108c. Note that the upper end of the second arc 108c may be smoothly connected to a reverse arc (a concave arc when viewed from the crossflow fan 107).

  Next, the flow of air generated by the rotation of the cross flow fan 107 will be described. The cross flow fan 107 blows air in a substantially tangential direction of a circle (blade outer circumference circle) virtually connecting the outer peripheral ends of the blades, passes through the cross flow fan 107 and flows out of the outlet 103 (main flow). Then, a flow (vortex flow) generated between the cross flow fan 107 and the stabilizer 108 and circulating in a spiral shape is generated. The main flow and the vortex flow are separated from each other at the front end point 110 of the tongue portion 108a.

  Of the main flow, the flow in the vicinity of the stabilizer 108 flows from the front end point 110 of the tongue 108a to the outlet 103 along the first arc 108b that forms the rear guider 109 side. Therefore, if the radius R1 of the first arc 108b is excessively large, the air along the first arc 108b flows in a direction that obstructs the main flow at an angle with respect to the outlet 103, and the cross flow fan 107 is It will disturb the air flowing through. However, in the air conditioner 100 according to this embodiment, the cross-sectional shape of the tongue portion 108a is formed by two arcs having different curvatures of the first arc 108b and the second arc 108c with the tip point 110 as a boundary. The curvature of the first arc 108b (the radius R1 of the virtual circle C1) can be designed to have an appropriate dimension without being affected by the arc below the tip point 110.

On the other hand, the vortex generated between the cross flow fan 107 and the stabilizer 108 strikes the cross flow fan 107 at a constant period, and generates blade pitch sound. However, in the air conditioner 100 according to the present embodiment, the radius R2 of the second arc 108c is equal to the first arc 108b.
Is larger than the radius R1 of the imaginary circle C1. As a result, the vortex flow when the cross flow fan 107 side from the tip point 110 of the tongue portion 108a is formed with the same arc (arc of radius R1) as the first arc 108b that forms the rear guider 109 side from the tip point 110 (see FIG. 2 (flow of the broken line arrow f in FIG. 2) circulates to the cross flow fan 107 in the vicinity of the tongue portion 108a. Thereby, it is possible to suppress the vortex from being sucked from the suction port 102 and interfering with the air passing through the heat exchanger 106. For this reason, the disturbance of the flow of the suction air of the crossflow fan 107 can be relieved, and the air volume which the crossflow fan 107 ventilates can be increased.

  Further, in the air conditioner 100 according to the present embodiment, the first arc tangent L2 and the second arc tangent L3 are the same straight line, that is, the first arc 108b and the second arc 108c are tangent at the tip point 110. . For this reason, the tongue part 108a is opposed to the air flow blown out by the cross flow fan 107 in a direction substantially tangential to the outer peripheral circle of the blade by a line (a point in terms of a cross-sectional shape).

  As a result, out of the air flow blown out by the cross flow fan 107 in the substantially tangential direction of the outer peripheral circle of the blade, the flow in the vicinity of the stabilizer 108 has a stagnation point only at the tip point 110 of the tongue 108a, and the air in the tongue 108a. Disturbances and losses due to collisions can be minimized. Further, the main flow and the vortex flow separated from the tip point can be smoothly divided into the first arc 108b and the second arc 108c, respectively, and the air flow can be prevented from being disturbed in the vicinity of the tip point 110.

  Note that the configuration of the air conditioner 100 according to the present embodiment is particularly effective when the air blower circuit 105 bends from the inlet 102 to the outlet 103.

(Embodiment 2)
FIG. 3 is a cross-sectional view illustrating an example of the configuration of the air conditioner 200 according to the present embodiment. FIG. 4 is an enlarged cross-sectional view showing the vicinity of the stabilizer 108 of the air conditioner 200 according to the present embodiment. 3 and 4, elements common to the first embodiment are denoted by common reference numerals. In the present embodiment, the difference from the first embodiment is the shape of the tongue 108a, and this will be described below.

  In the first embodiment, the sectional shape of the tongue portion 108a above the tip point 110 is formed by the second arc 108c having the curvature radius R2, whereas in the present embodiment, the cross-sectional shape above the tip point 110 is above the tip point 110. The cross-sectional shape is formed by a substantially elliptical arc. This arc is a circular arc that is convex toward the cross flow fan 107. Note that the upper end of this arc may be smoothly connected to a reverse arc (a concave arc when viewed from the cross flow fan 107).

  Details of this shape will be described below with reference to FIG. In FIG. 4, the intersection point between the first arc 108 b and the flat portion 108 d located on the side of the stabilizer 108 facing the rear guider 109 side is defined as a continuous contact 111. Of the straight lines orthogonal to the outer circumferential tangent line L1, a straight line that intersects the continuous contact 111 is defined as a connected part orthogonal straight line L4. A portion located between the tip point 110 and the connecting portion orthogonal straight line L4 is referred to as a tip portion 112.

  At this time, the tip 112 is thicker above the outer circumference tangent L1 (cross flow fan 107 side) than the thickness below the outer circumference tangent L1 (rear guider 109 side). Further, the difference between the thickness above and below the outer circumferential circle tangent line L1 increases from the tip point 110 toward the flat surface portion 108d.

More specifically, a perpendicular line extending from an arbitrary point on the outer circumferential circle tangent line L1 to the surface forming the outer shape of the tongue portion 108a downward (from the rear guider 109 side) from the tip point 110 is defined as a virtual first perpendicular line V1. The length of the virtual first perpendicular line V1 is set as a length H1. That is, the length from the arbitrary point on the outer circumferential circle tangent L1 to the intersection of the virtual first perpendicular V1 and the surface forming the outer shape of the tongue portion 108a (that is, the surface below the tongue portion 108a) is the length H1. And

  Further, a vertical line raised from an arbitrary point on the outer circumferential circle tangent L1 to the surface forming the outer shape of the tongue 108a from the tip point 110 to the upper side (cross flow fan 107 side) is defined as a virtual second vertical line V2. Then, the length of the virtual second perpendicular V2 is set as a length H2. That is, the length from an arbitrary point on the outer circumferential tangent line L1 to the intersection of the virtual second perpendicular V2 and the surface forming the outer shape of the tongue portion 108a (that is, the surface above the tongue portion 108a) is the length H2. And

  Then, the cross-sectional shape of the tongue 108a is formed so that length H2> length H1. Further, the tip 112 is formed such that the length H2 gradually becomes larger than the length H1 as it approaches the connecting portion orthogonal straight line L4 from the tip 110.

  The vortex generated between the cross flow fan 107 and the stabilizer 108 hits the cross flow fan 107 at a constant period and generates blade pitch sound. However, in the air conditioner 200 according to the present embodiment, the cross flow fan 107 side from the tip point 110 of the tongue portion 108a is formed in a substantially oval shape. As a result, the design can be performed with a dimension that allows the vortex to be positively applied to the cross flow fan 107 at a desired location.

  Further, the major axis of the substantially ellipse is larger than the radius R1 of the virtual circle C1 obtained by extending the first arc 108b. Thereby, the vortex flow when the cross flow fan 107 side from the tip point 110 of the tongue portion 108a is formed with the same arc (arc of radius R1) as the first arc 108b that forms the rear guider 109 side from the tip point 110 (FIG. 4). Compared to the flow indicated by the broken line arrow f), the vortex flow (the flow indicated by the broken line arrow F2 in FIG. 4) in this embodiment can be prevented from interfering with the air sucked from the suction port 102. For this reason, the disturbance of the flow of the suction air of the crossflow fan 107 can be eased, and the amount of air that the crossflow fan ventilates can be increased.

  Moreover, in the front-end | tip part 112, the difference of length H1 and length H2 becomes large gradually as it approaches the connection part orthogonal straight line L4 from the front-end | tip point 110. FIG. As a result, the vortex flow circulating between the cross flow fan 107 and the stabilizer 108 can be further improved in the tongue 108a without causing stagnation or fine vortices on the surface on the cross flow fan 107 side from the front end point 110 of the tongue 108a. It can be guided to the cross flow fan 107 in the vicinity. Thereby, it is possible to suppress the vortex from interfering with the air sucked from the suction port 102. For this reason, the disturbance of the flow of the suction air of the crossflow fan 107 can be relieved, and the air volume which the crossflow fan 107 ventilates can be increased.

  In the air conditioner 200 according to the present embodiment, the cross-sectional shape on the cross flow fan 107 side from the tip point 110 of the tongue portion 108a is formed in a substantially elliptical shape, but is not limited to a substantially elliptical shape and has a length H1. And the length H2 satisfies H2> H1 and satisfies the fact that the difference between the length H1 and H2 gradually increases as the tip portion 112 approaches the connecting portion orthogonal straight line L4 at the tip portion 112. It is possible to form in the shape.

  Note that the configuration of the air conditioner 200 according to the present embodiment is particularly effective when the air blower circuit 105 is bent while it extends from the suction port 102 to the blower outlet 103.

  Since the air conditioner according to the present invention can increase the amount of air that is passed through the crossflow fan, it is suitable for use in home air conditioning and commercial air conditioning.

100, 200 Air conditioner 101 Indoor unit 102 Suction port 103 Air outlet 104 Main body casing 105 Blower circuit 106 Heat exchanger 107 Cross flow fan 108 Stabilizer 108a Tongue 108b First arc 108c Second arc 108d Plane portion 109 Rear guider 110 Tip point 111 continuous contact 112 tip C1 virtual circle L1 outer circumference circular tangent L2 first arc tangent L3 second arc tangent L4 connecting portion orthogonal straight line R1 first arc radius R2 second arc radius V1 virtual first perpendicular V2 virtual second perpendicular H1 virtual First perpendicular length H2 Virtual second perpendicular length

Claims (5)

A main body casing provided with a suction port and an air outlet, a blower circuit provided in the main body casing, a cross flow fan provided in the blower circuit, a stabilizer provided with a tongue, a rear guider, heat With an exchange,
The cross-sectional shape of the tongue is
Out of the tangent lines of the outer circle of the cross flow fan, a straight line that intersects perpendicularly with the tongue is an outer circle tangent, and the intersection of the outer circle and the tongue is the tip point.
The air conditioner is characterized in that the cross flow fan side from the tip point protrudes to the cross flow fan side from a virtual circle extending from a first arc forming the rear guider side from the tip point. The cross flow fan side from the tip point is formed by a second arc,
The air conditioner according to claim 1, wherein a radius R2 of the second arc is larger than a radius R1 of the first arc. The air conditioner according to claim 2, wherein a first arc tangent of the first arc at the tip point and a second arc tangent of the second arc at the tip point are collinear. . The intersection of the first arc and the flat portion provided in the stabilizer is a continuous contact,
Of the straight lines orthogonal to the outer circumferential tangent line, a straight line that intersects the continuous contact point is a connected part orthogonal straight line,
When a portion located between the tip point and the connecting portion orthogonal straight line is a tip portion,
2. The air conditioner according to claim 1, wherein a thickness of the tip portion on the cross flow fan side from the outer circumferential tangent is larger than a thickness on the rear guider side from the outer circumferential tangent. In the tip,
As approaching the connecting part orthogonal straight line from the tip point,
The air conditioner according to claim 4, wherein a difference between the thickness on the cross flow fan side from the outer circumferential tangent and the thickness on the rear guider side from the outer circumferential tangent increases.