JP3621892B2 - Indoor unit and air conditioner - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an indoor unit and an air conditioner that provide a comfortable indoor environment by heating or cooling, and in particular, it is possible to reduce operation noise generated in a blower system of an indoor unit that employs a tangential fan. The present invention relates to a technique suitable for the indoor unit and the air conditioner.
[0002]
[Prior art]
An air conditioner is composed of two large components, an indoor unit and an outdoor unit. Each of these units includes an indoor heat exchanger and an outdoor heat exchanger that perform heat exchange between the refrigerant and the indoor air and between the refrigerant and the outdoor air.
[0003]
These indoor heat exchangers and outdoor heat exchangers are elements constituting a refrigerant circuit by adding other elements such as a compressor and an expansion valve. Refrigerant physically circulates in this circuit, and it will also follow the state change circulation process of high-temperature high-pressure gas, low-temperature low-pressure gas, high-temperature high-pressure liquid, and low-temperature low-pressure liquid, and realize indoor air conditioning. . This indoor air conditioning is directly realized by heat exchange between the refrigerant in the indoor heat exchanger and the indoor air.
[0004]
By the way, during heating operation, the refrigerant that is made into a high-temperature and high-pressure gas by the compressor is sent to the indoor heat exchanger, and the refrigerant is condensed by exchanging heat between this refrigerant and the room air. Is realized as a liquid refrigerant. Moreover, at the time of air_conditionaing | cooling operation, a high-temperature / high pressure gaseous refrigerant is sent to an outdoor heat exchanger, and it heat-exchanges with outdoor air, and it is set as a high temperature / high pressure liquid refrigerant. After that, the high-temperature and high-pressure liquid refrigerant is decompressed by passing it through the expansion valve, sent to the indoor heat exchanger as a low-temperature and low-pressure liquid refrigerant, and the refrigerant is evaporated by exchanging heat between this refrigerant and the room air. Thus, low temperature and low pressure gasification is realized.
[0005]
[Problems to be solved by the invention]
By the way, in the case of the air conditioner mentioned above, the actual condition is that the casing shape of the indoor unit is determined empirically from the past. Among such air conditioners that are widely used for home use, for example, a tangential fan (cross flow fan) has been generally employed as a fan provided in an indoor unit. .
[0006]
In this case, indoor air (room air) sucked by a tangential fan (hereinafter referred to as “fan”) passes through the indoor heat exchanger and is air-conditioned, and then the outer peripheral surface of the fan and the air path wall surface of the casing. The air is blown from the outlet to the room through the air passage formed between the two. In such an indoor unit, the air blower system in the casing, such as the stabilizer shape provided on the upstream side of the fan, is further improved in terms of aerodynamic performance such as air volume and noise, thereby further improving the merchantability of the air conditioner. Further improvement is desired.
Against this background, it is necessary to find basic rules for optimizing the stabilizer shape, etc., and by designing according to these rules, it is easy to reduce the noise and increase the efficiency of the blower system It is desirable to be able to do this.
[0007]
The present invention has been made in view of the above circumstances, and it is easy to design for improving the aerodynamic performance by optimizing the shape of the air blower system formed in the indoor unit of the air conditioner, particularly the stabilizer shape. The goal is to provide an indicator of
[0008]
[Means for Solving the Problems]
The present invention employs the following means in order to solve the above problems.
The indoor unit according to claim 1 performs heat exchange between a tangential fan for sucking room air from the suction port and blowing it out from the blower outlet, and the refrigerant supplied from the room air and the outdoor unit. In an indoor unit comprising an indoor heat exchanger, an indoor unit control unit composed of various electric circuit elements, and a casing for storing these devices,
A tongue-shaped stabilizer having a surface facing the tangential fan on the upstream side of the tangential fan;
In the indoor air inflow portion upstream of the stabilizer, a guide is provided for guiding the flow of the indoor air in a substantially central direction of the tangential fan,
The guide forms an air guide surface that is continuous with a tip portion of the surface of the stabilizer,
When the extension line in the flow direction along the upper surface forming the discharge port serving as the air passage outlet in the casing is defined as a, the stabilizer tongue end angle α formed by the surface of the stabilizer and the extension line a is from 50 degrees. It is characterized by being in the range of 60 degrees (50 degrees ≦ α ≦ 60 degrees).
[0009]
According to such an indoor unit, by designing the stabilizer tongue end angle α to be 50 degrees ≦ α ≦ 60 degrees, it is possible to achieve low noise in the fan blower system at the same air volume.
Further, since the guide for guiding the flow of room air toward the substantially central direction of the tangential fan is provided at the room air inflow portion of the stabilizer, it is possible to achieve low noise in the fan air blowing system at the same air volume.
[0010]
The indoor unit according to claim 2 performs heat exchange between a tangential fan for sucking room air from the inlet and blowing it out from the outlet, and the refrigerant supplied from the room air and the outdoor unit. In an indoor unit comprising an indoor heat exchanger, an indoor unit control unit composed of various electric circuit elements, and a casing for storing these devices,
A tongue-shaped stabilizer having a surface facing the tangential fan on the upstream side of the tangential fan;
In the indoor air inflow portion upstream of the stabilizer, a guide is provided for guiding the flow of the indoor air in a substantially central direction of the tangential fan,
The guide forms an air guide surface that is continuous with a tip portion of the surface of the stabilizer,
When the fan diameter of the tangential fan is D and the actual height of the stabilizer is h, the ratio of the stabilizer actual height h to the fan diameter D is 25% or less (h / D ≦ 25%). It is characterized by setting.
[0011]
According to such an indoor unit, the noise of the fan blower system at the same air volume can be reduced by designing the ratio of the actual height h of the stabilizer to the fan diameter D to be h / D ≦ 25%. can do.
Further, since the guide for guiding the flow of room air toward the substantially central direction of the tangential fan is provided at the room air inflow portion of the stabilizer, it is possible to achieve low noise in the fan air blowing system at the same air volume.
[0014]
The indoor unit according to claim 3 performs heat exchange between a tangential fan for sucking room air from the inlet and blowing it out from the outlet, and the refrigerant supplied from the room air and the outdoor unit. In an indoor unit comprising an indoor heat exchanger, an indoor unit control unit composed of various electric circuit elements, and a casing for storing these devices,
A tongue-shaped stabilizer having a surface facing the tangential fan on the upstream side of the tangential fan;
In the indoor air inflow portion upstream of the stabilizer, a guide is provided for guiding the flow of the indoor air in a substantially central direction of the tangential fan,
The guide forms an air guide surface that is continuous with a tip portion of the surface of the stabilizer,
When the extension of the flow direction along the upper surface forming a discharge port as a wind passage outlet in said casing has a a, a formed stabilizer tongue blade angle α is 50 degrees of the surface of the stabilizer and the extension line a Within the range of 60 degrees ( 50 degrees ≤ α ≤ 60 degrees)
The fan diameter of the tangential fan D, when the actual height of the stabilizer was is h, as the ratio of the fan diameter D stabilizer actual height to h is equal to or less than 25% (h / D ≦ 25 %) It is characterized by setting .
[0015]
According to the indoor unit, it is possible to achieve further low noise fan blower system in the same air volume by the synergistic effect of the physician each other.
[0016]
The air conditioner according to claim 4 includes an outdoor heat exchanger, a compressor that sends a high-temperature and high-pressure gaseous refrigerant to the heat exchanger, and an outdoor unit control unit that includes various electric circuit elements. An outdoor unit,
And an indoor unit according to any one of claims 1 to 3 .
[0017]
According to such an air conditioner, since the indoor unit that can easily achieve noise reduction at the same air volume is provided, it is possible to provide an air conditioner with excellent aerodynamic performance and high merchantability.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of an indoor unit and an air conditioner according to the present invention will be described with reference to the drawings.
FIG. 2 is an explanatory diagram showing the overall configuration of the air conditioner. The air conditioner includes an indoor unit 10 and an outdoor unit 20. The indoor unit 10 and the outdoor unit 20 are connected by a refrigerant pipe 21 through which the refrigerant conducts, an electric wiring (not shown), and the like. Two refrigerant pipes 21 are provided, and the refrigerant flows from the indoor unit 10 to the outdoor unit 20 on one side and from the outdoor unit 20 to the indoor unit 10 on the other side.
[0019]
The indoor unit 10 is configured such that a base 11 and a front panel 12 serving as a casing are integrally formed. The base 11 includes various devices such as a plate fin tube type indoor heat exchanger 13 and a substantially cylindrical tangential fan (hereinafter referred to as “fan”) 14. The base 11 is provided with an indoor unit control unit 15 composed of various electric circuit elements and the like in order to perform various operation controls on the other indoor unit 10. The indoor unit control unit 15 is provided with an appropriate indicator 15a for displaying an operation status and an error mode. The indicator 15a can be visually recognized from the outside by a see-through portion 12a provided on the front panel 12. A mounting plate 16 is provided behind the base 11 so that the indoor unit 10 can be installed on an indoor wall or the like.
[0020]
The front panel 12 has suction grilles (suction ports) 12b formed on the front surface and the upper surface, respectively. Indoor air (room air) is sucked into the indoor unit 10 from multiple directions by the suction grill 12b. Incidentally, an air filter 17 is provided behind the suction grill 12b, and functions to remove dust such as sucked air. Further, the front panel 12 has an air outlet 12c formed below, from which warmed air or cooled air (that is, conditioned air) is blown out. In addition, this air suction and air blowing are performed when the fan 14 rotates.
[0021]
The indoor unit 10 described above includes a remote controller (remote controller) 30 as an operation unit that performs various driving operations. The remote controller 30 is provided with various switches, a liquid crystal display unit, and the like, and directs various operation operation signals, set temperatures, and the like of the air conditioner to a receiving unit (not shown) of the indoor unit control unit 15, for example, infrared rays. It can be transmitted as a signal. Note that the operation of the air conditioner can be partly performed by switches (not shown) provided at appropriate positions in the indoor unit.
[0022]
The outdoor unit 20 includes an outdoor heat exchanger 20b, a propeller fan 20c, a compressor 20f, an outdoor unit control unit 20g, and the like in a housing 20a. The outdoor heat exchanger 20b is configured by a refrigerant pipe having a large number of plate-like fins around it, and is for realizing heat exchange between the refrigerant and the outdoor air. Propeller fan 20c is designed to improve the heat exchange efficiency of outdoor heat exchanger 20b by always taking new air into casing 20a by generating an air flow that escapes from the back to the front in casing 20a. Is provided.
[0023]
A fingered 20d and a fan guard 20e are provided on the surface of the casing 20a where the outdoor heat exchanger 20b and the propeller fan 20c face each other. The fingered 20d is provided so that the plate-shaped fin is not damaged by an unexpected impact from the outside. Similarly, the fan guard 20e is provided for the purpose of protecting the propeller fan 20c from external impact.
[0024]
The compressor 20f converts a low-temperature and low-pressure gas refrigerant into a high-temperature and high-pressure gas refrigerant and discharges it, and plays a central role among the components constituting the refrigerant circuit. Incidentally, the refrigerant circuit is not only the compressor 20f but also the indoor heat exchanger 13, the outdoor heat exchanger 20b, the refrigerant pipe 21, the expansion valve, and a four-way valve (expansion valve and four-way valve) that defines the flow direction of the refrigerant. The valve is a circuit that circulates the refrigerant between the indoor unit 10 and the outdoor unit 20.
[0025]
The outdoor unit control unit 20g performs operation control on the propeller fan 20c, the compressor 20f, and other various devices provided in the outdoor unit 20, and is composed of various electric circuit elements.
[0026]
In addition to the above, the outdoor unit 20 is provided with a pedestal 20h in order to support the housing 20a and avoid the influence of external vibration and the like. The wall of the casing 20a close to the compressor 20f is provided with a panel 20i that can be removed in order to perform maintenance or the like of the compressor 20f.
[0027]
Below, the effect | action of the air conditioner which consists of these structures is demonstrated separately in each case at the time of heating operation and air_conditionaing | cooling operation.
First, at the time of heating operation, the refrigerant converted into high-temperature and high-pressure gas by the compressor 20 f passes through the refrigerant pipe 21 and is sent to the indoor heat exchanger 13 of the indoor unit 10. In the indoor unit 10, heat is given from the high-temperature and high-pressure gaseous refrigerant passing through the indoor heat exchanger 13 to the indoor air taken in from the suction grill 12 b by the fan 14. Thereby, warm air is blown out from the blower outlet 12c below the front panel 12. At the same time, the high-temperature and high-pressure gaseous refrigerant is condensed and liquefied in the indoor heat exchanger 13 to become a high-temperature and high-pressure liquid refrigerant.
[0028]
The high-temperature and high-pressure liquid refrigerant is sent again to the outdoor heat exchanger 20b in the outdoor unit 20 through the refrigerant pipe 21. The outdoor unit 20 passes through an expansion valve (not shown) and is reduced in pressure to become a low-temperature and low-pressure liquid refrigerant. The low-temperature and low-pressure liquid passes through the outdoor heat exchanger 20b from the new outdoor air taken into the housing 20a by the propeller fan 20c. The liquid refrigerant will take heat away. This causes the low-temperature and low-pressure liquid refrigerant to evaporate and become a low-temperature and low-pressure gas refrigerant. This is sent again to the compressor 20f, and the above process is repeated.
[0029]
Next, during the cooling operation, the refrigerant flows in the refrigerant circuit in the opposite direction to the above. That is, the refrigerant converted into a high-temperature and high-pressure gas by the compressor 20f passes through the refrigerant pipe 21 and is sent to the outdoor heat exchanger 20b, and heats the outdoor air to condense and liquefy it to become a high-temperature and high-pressure liquid refrigerant. This high-temperature and high-pressure liquid refrigerant passes through an expansion valve (not shown) to become a low-temperature and low-pressure liquid refrigerant, and is sent again to the indoor heat exchanger 13 through the refrigerant pipe 21. Here, the low-temperature and low-pressure liquid refrigerant takes heat from the room air and cools the room air, and the refrigerant itself evaporates and becomes a low-temperature and low-pressure gas refrigerant. This is sent again to the compressor 20f, and the above process is repeated.
[0030]
These operations are controlled by the cooperation of the indoor unit controller 15 housed in the indoor unit 10 and the outdoor unit controller 20g housed in the outdoor unit 20.
[0031]
Hereinafter, characteristic portions of the present invention will be described with reference to FIG. In addition, FIG. 1 used here shows the fan 14 and its ventilation system among the cross sections in alignment with the AA of FIG.
In the indoor unit 10 described above, the fan 14 is operated to suck indoor air from the suction grille 12b, and to pass through the indoor heat exchanger 13 and heat-exchanged conditioned air into the room from the outlet 12c. A fan blower system is provided. This fan blower system is provided with an air passage 40 that guides conditioned air to the air outlet 12c.
[0032]
The air passage 40 is a space formed between the outer peripheral surface 14a of the cylindrical fan 14 and the air passage wall surface 41 provided on the base 11 that is a constituent member of the casing.
The inlet 42 of the air passage 40 is on a line connecting the fan center C, which is the axial center when the fan 14 rotates, and the point K on the air passage wall surface 41, and the inlet width is Wi. The point K is a starting point of the casing winding (concave curved surface in the flow direction of the air passage wall surface 41), and is generally on the upper rear side (wall side) of the fan 14 when viewed from the front panel 12 side of the indoor unit 10. Is located.
[0033]
The air passage 40 is formed from the inlet 42 to the outlet 43 in the rotation direction of the fan 14 (clockwise in the illustrated example). The width of the air passage 40, that is, the air passage width W, gradually increases from the inlet width Wi of the inlet 42 to the outlet width Wo of the outlet 43. The outlet width Wo is a distance until a line passing through the end point M of the casing winding on the casing wall surface 41 and orthogonal to the air path center line 44 reaches the outlet upper surface 45.
A front panel 12 is disposed in front of the outlet 43 in the flow direction (the front side of the indoor unit 10), and an outlet 12c of the panel 12 opens toward the room. In a general configuration, a louver (not shown) for adjusting the left and right blowing directions is disposed in the vicinity of the outlet 43, and a flap (not shown) for adjusting the upper and lower blowing directions is arranged at the outlet 12c. It is installed.
In the figure, reference numeral 46 denotes an inversion portion of the incoming air, and 50 denotes a stabilizer provided on the upstream side of the fan 14.
[0034]
Of the fan air passage system including the air passage 40 described above, in the first embodiment, the shape of the stabilizer 50, particularly the stabilizer tongue end angle α, is defined as described below.
Here, when the fan diameter of the fan 14 is D and the extension line in the flow direction along the outlet upper surface 45 forming the discharge port serving as the outlet 43 of the air passage 40 in the casing is a, it faces the fan 14. The angle α formed by the stabilizer surface 51 and the extension line a is called the stabilizer tongue angle, and is set so that the tongue angle α is in the range of 50 to 60 degrees (50 degrees ≦ α ≦ 60 degrees). To do.
[0035]
FIG. 3 shows the results of measuring noise on the same air volume basis by appropriately changing the stabilizer tongue end angle α described above.
From this measurement result, the noise becomes lowest when the stabilizer tongue end angle α is set to around 57 degrees, and the noise increases even if the angle is decreased or increased with the angle as the bottom. I understood that. Therefore, with reference to the noise value corresponding to the stabilizer tongue angle α having the lowest noise in the same air volume base, an appropriate design range of the stabilizer tongue angle α is an angle in a range where ΔdB is increased by 1 dB (A) from this reference value. From the result shown in FIG. 3, the range of the stabilizer tongue end angle α is determined as 50 ° ≦ α ≦ 60 °.
Note that ΔdB = 1 dB (A) is based on the reason that the value of 1 dB (A) is a level at which the noise reduction effect can be clearly recognized in consideration of measurement errors and variations.
[0036]
Next, in the fan air passage system including the air passage 40 described above, in the second embodiment, the shape of the stabilizer 50, in particular, the actual height h of the stabilizer 50 is defined as described below.
Here, the actual height h of the stabilizer 50 will be described. As shown in FIG. 5, the stabilizer 50 has a mountain-valley shape (see FIG. 5A) having a height at the tip of the stabilizer 50, and a linear shape (FIG. 5 ( b)). The actual height h of the stabilizer 50 defines the effective height of the stabilizer from the extension line a. Therefore, in the case of a mountain and valley shape, the height from the extension line a to the valley portion 51a becomes the actual height h. In the case of a straight line shape, the height from the extension line a to the tip 51c is the actual height h.
The actual height h of the stabilizer 50 described above is such that h / D is 25% or less (h / D ≦ 25%) when the ratio (h / D) to the fan diameter D of the fan 14 is expressed as a percentage. Set.
[0037]
FIG. 4 shows a result of measuring noise on the same air volume basis by appropriately changing the above-described actual height h.
From this measurement result, it was found that the noise was lowest when h was set to be lower than about 15%, and the noise increased in both cases when increasing or decreasing from h corresponding to this lowest value. Therefore, an area within the range where ΔdB increases by 1 dB (A) with this minimum value as a reference is determined as an appropriate design range, and the range of h / D is determined as h / D ≦ 25% based on the result shown in FIG. . On the other hand, the lower limit of the actual height h of the stabilizer 50 is determined by the required water receiving height H that is higher (larger) than h corresponding to h / D≈15% at which noise is lowest. The required water receiving height H is a value necessary for preventing the outflow of condensed water generated in the indoor heat exchanger 14.
[0038]
Next, in the fan air passage system including the air passage 40 described above, in the third embodiment, the stabilizer 50 provided with the guide 60 will be described.
The guide 60 is provided in a room air inflow portion of a stabilizer provided on the upstream side of the fan 14 so as to guide the flow of room air in a substantially central direction of the fan 14. The guide 60 is positioned on the upstream side of the stabilizer 50, that is, on the front panel 12 side of the stabilizer 50, and the axial direction of the fan 14 and the fan 14 are formed so as to form the air guide surface 61 connected to the actual height h of the stabilizer 50 described above. It is provided in the longitudinal direction of the stabilizer 50.
[0039]
By providing such a guide 60, the indoor air introduced by the operation of the fan 14 flows smoothly along the air guide surface 61 toward the center of the fan 14, so that the noise measurement result shown in FIG. As described above, when the noises based on the same air volume are compared, the noise is reduced when the guide 60 is provided.
[0040]
In this way, by designing the shape of the stabilizer 50 using the rules described in the first and second embodiments described above as an index, or by providing the guide 60 described in the third embodiment, In the fan blower system of the indoor unit 10, aerodynamic performance such as air volume and noise can be easily improved. Moreover, since the value prescribed | regulated by each embodiment is decided so that it may settle in the 1 dB (A) higher range from the noise value from which the noise of the same air volume base becomes the lowest, it is set as the stabilizer shape in the regulation value mentioned above. Thus, a stabilizer shape advantageous for low noise can be easily set.
[0041]
Moreover, although each embodiment mentioned above can obtain the effect of improving aerodynamic characteristics even if each is employed independently, if each embodiment is employed in an appropriate combination, that is, at least two or more are appropriately combined. By adopting the above, it is possible to further promote noise reduction of the stabilizer 50 and the fan air blowing system at the same air flow rate by a synergistic effect.
That is, the indoor unit 10 provided with the stabilizer 50 having a shape designed by adopting the above-mentioned regulations has excellent aerodynamic characteristics such as noise reduction of the fan blower system, and an air conditioner having this as a constituent element However, it becomes possible to improve the merchantability.
In addition, the structure of this invention is not limited to embodiment mentioned above, In the range which does not deviate from the summary of this invention, it can change suitably.
[0042]
【The invention's effect】
According to the indoor unit and the air conditioner of the present invention described above, an index used when determining the stabilizer shape of the indoor unit, that is, (1) the stabilizer tongue end angle α is defined as 50 ° ≦ α ≦ 60 °. (2) The actual height h of the stabilizer is determined as h / D ≦ 25%, and (3) the guide is provided in the indoor air inflow portion of the stabilizer, so that the fan blow system in the indoor unit is optimally designed. Can be easily implemented.
For this reason, it is possible to significantly and easily reduce the operation noise of the fan blower system in the indoor unit, compared to the conventional one, and the commercialization is improved by reducing the noise of the indoor unit and the air conditioner that uses this unit as a component. There is a remarkable effect of doing.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing first to third embodiments of an indoor unit according to the present invention, and shows a tangential fan and its blower system in a cross section taken along line AA of FIG. is there.
FIG. 2 is a partial cross-sectional perspective view showing an embodiment of an indoor unit and an air conditioner according to the present invention.
FIG. 3 is a graph for explaining the operation according to the first embodiment of the present invention, and is a graph showing a result of measuring noise based on the same air volume by appropriately changing a stabilizer tongue end angle (α). .
FIG. 4 is a diagram for explaining the operation according to the second embodiment of the present invention, in which the ratio of the actual height (h) of the stabilizer to the fan diameter (D) is appropriately changed, and noise based on the same air volume It is a graph which shows the result of having measured.
5A and 5B are diagrams showing examples of the shape of the tip of the stabilizer, in which FIG. 5A is a view of a mountain-shaped stabilizer as viewed from the fan side, and FIG. 5B is a view of a linear stabilizer as viewed from the fan side.
FIG. 6 is a diagram illustrating an operation according to the third embodiment of the present invention, and is a graph illustrating a result of measuring and comparing noises based on the same air volume with and without a guide.
[Explanation of symbols]
10 indoor unit 12 front panel 13 indoor heat exchanger 14 tangential fan (fan)
14a Outer peripheral surface 15 Indoor unit control part 20 Outdoor unit 21 Refrigerant piping 30 Remote controller (operation part)
40 Airway 41 Airway wall 42 Inlet 43 Outlet 44 Airway centerline 45 Outlet upper surface 50 Stabilizer 51 Stabilizer surface 60 Guide 61 Air guide surface

Claims (4)

From a tangential fan for sucking room air from the inlet and blowing it out from the outlet, an indoor heat exchanger for exchanging heat between the room air and the refrigerant supplied from the outdoor unit, and various electric circuit elements In an indoor unit comprising an indoor unit control unit and a casing for storing these devices,
A tongue-shaped stabilizer having a surface facing the tangential fan on the upstream side of the tangential fan;
In the indoor air inflow portion upstream of the stabilizer, a guide is provided for guiding the flow of the indoor air in a substantially central direction of the tangential fan,
The guide forms an air guide surface that is continuous with a tip portion of the surface of the stabilizer,
When the extension line in the flow direction along the upper surface forming the discharge port serving as the air passage outlet in the casing is defined as a, the stabilizer tongue end angle α formed by the surface of the stabilizer and the extension line a is from 50 degrees. An indoor unit that is in a range of 60 degrees (50 degrees ≤ α ≤ 60 degrees). From a tangential fan for sucking room air from the inlet and blowing it out from the outlet, an indoor heat exchanger for exchanging heat between the room air and the refrigerant supplied from the outdoor unit, and various electric circuit elements In an indoor unit comprising an indoor unit control unit and a casing for storing these devices,
A tongue-shaped stabilizer having a surface facing the tangential fan on the upstream side of the tangential fan;
In the indoor air inflow portion upstream of the stabilizer, a guide is provided for guiding the flow of the indoor air in a substantially central direction of the tangential fan,
The guide forms an air guide surface that is continuous with a tip portion of the surface of the stabilizer,
When the fan diameter of the tangential fan is D and the actual height of the stabilizer is h, the ratio of the stabilizer actual height h to the fan diameter D is 25% or less (h / D ≦ 25%). An indoor unit that is set. From a tangential fan for sucking room air from the inlet and blowing it out from the outlet, an indoor heat exchanger for exchanging heat between the room air and the refrigerant supplied from the outdoor unit, and various electric circuit elements In an indoor unit comprising an indoor unit control unit and a casing for storing these devices,
A tongue-shaped stabilizer having a surface facing the tangential fan on the upstream side of the tangential fan;
In the indoor air inflow portion upstream of the stabilizer, a guide is provided for guiding the flow of the indoor air in a substantially central direction of the tangential fan,
The guide forms an air guide surface that is continuous with a tip portion of the surface of the stabilizer,
When the extension of the flow direction along the upper surface forming a discharge port as a wind passage outlet in said casing has a a, a formed stabilizer tongue blade angle α is 50 degrees of the surface of the stabilizer and the extension line a Within the range of 60 degrees ( 50 degrees ≤ α ≤ 60 degrees)
The fan diameter of the tangential fan D, when the actual height of the stabilizer was is h, as the ratio of the fan diameter D stabilizer actual height to h is equal to or less than 25% (h / D ≦ 25 %) An indoor unit that is set . An outdoor unit comprising: an outdoor heat exchanger; a compressor for sending a high-temperature and high-pressure gaseous refrigerant to the heat exchanger; and an outdoor unit control unit composed of various electric circuit elements;
An air conditioner comprising the indoor unit according to any one of claims 1 to 3 .

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