JP3879725B2 - Cross flow fan, air conditioner - Google Patents

Description

  The present invention relates to an indoor unit having at least one suction port, a blow-out port, a cross flow fan connected to a fan motor, and an air conditioner having such a cross low fan and a heat exchanger.

  In an air conditioner using a cross flow fan, for example, as shown in Japanese Patent Laid-Open No. Hei 5-195811, the air flow sucked into the cross flow fan is reversed in the direction of rotation on the suction side of the cross flow fan. A pre-turn was made to increase the discharge air volume of the cross flow fan.

JP-A-5-195981

  However, in the configuration of the guide vanes described above, wind hits the pressure surface side of the crossflow fan rotor blade, and the angle of attack of the rotor blade increases, so the blade is likely to stall, the fan motor input is large, and the noise is increased. Or the power consumption of the fan motor increases.

  The present invention has been made to solve such a problem, and a cross-flow fan and an air conditioner that can reduce power consumption and rotational speed of a fan motor necessary for obtaining a predetermined air volume and reduce noise. The purpose is to provide.

The present invention is provided with a plurality of stationary blades only at locations away from the stabilizer on the windward side of the suction portion of the crossflow fan, and the wind direction is changed by these stationary blades so that the wind strikes the suction surface side of the crossflow fan rotor blade. It is intended.

  In the present invention, the shape of the tip of the inner peripheral blade of the cross flow fan is changed to an edge shape.

  According to the crossflow fan and the air conditioner of the present invention, it is possible to reduce the power consumption and the rotational speed of the fan motor necessary for obtaining a predetermined air volume, and to reduce the noise.

Embodiment 1 FIG.
FIG. 1 is a cross-sectional view of an indoor unit of an air conditioner according to Embodiment 1 of the present invention, and FIG. 2 is a diagram showing a trace of air in the indoor unit according to Embodiment 1 of the present invention.

In FIG. 1, 1 is a cross flow fan, 2 is a heat exchanger, 3 is a refrigerant pipe, 4 is a prefilter, 5 is an air purifier, 6 is a suction port, 7 is a blowout port, and constitutes an indoor unit 8. is doing.
Next, the operation of the indoor unit 8 will be described. When the cross flow fan 1 is rotated by rotation of a fan motor (not shown), air 9 outside the indoor unit 8 is sucked from the suction port 6, and the prefilter 4, the heat exchanger 2, and the cross flow fan 1 are moved. Via, it blows out from the blowout port 7. Here, the pre-filter-4 and the air cleaning device 5 remove dust contained in the air 10, the heat exchanger 2 exchanges heat with the air 10, and the air 10 is cooled during the cooling operation and is heated during the heating operation. Heat.

  FIG. 2 is a diagram illustrating the air trace in the indoor unit 8, and the region 11 is a part of the suction region of the cross flow fan 1. FIG. 3 is a diagram showing the relative speed distribution of the cross flow fan 1 in the region 11. FIG. 4 shows the angle of attack. FIG. 5 is a diagram illustrating a cross-sectional view of the indoor unit 8 when a plurality of stationary blades 21 which are features of the first embodiment of the present invention are installed. 6 and 7 are diagrams for explaining how to determine the shape of the stationary blade 21.

  In FIG. 3, 13 is a suction surface of the blade 12 of the cross flow fan 1, and 14 is a pressure surface. A vortex 15 is generated at the suction surface 13. In FIG. 4, point A is the end point of the leading edge 19 of the wing 12, point B is the end point of the trailing edge 20, and the angle of attack 16 is an angle formed by the straight line AB and the relative velocity vector 18 of the air 9 at the point A. The direction of the arrow 17 is positive.

  When a vortex is generated on the negative pressure surface 13, the power consumption of a fan motor (not shown) necessary for obtaining a predetermined air volume increases, the rotational speed of the fan motor (not shown) increases, There is a problem that the noise generated from the unit 8 increases. Such a problem occurs when the angle of attack 16 shown in FIG. 4 is large. In order to solve this problem, in the first embodiment of the present invention, a plurality of stationary blades 21 are installed on the windward side of the suction area of the crossflow fan 1 as shown in FIG. The shape of the stationary blade 21 is determined as follows.

  As shown in FIG. 6, an arc 22 and an arc 23 on the concentric circle of the cross flow fan 1 are drawn in the suction area of the cross flow fan 1. It is assumed that the radius of the arc 22 is larger than the radius of the cross flow fan 1 and the radius of the arc 23 is larger than the radius of the arc 22.

Next, as shown in FIG. 7, a plurality of points C _i (1 ≦ i ≦ N, N ≧ 2) are defined on the arc 22. Then, the absolute velocity vector U _i at the point C _i is obtained by experiment or calculation. The absolute velocity vector U _i is rotated about the point C _i so that the angle of attack 16 becomes small, that is, when viewed from the direction of FIG. 7, counterclockwise by θ degrees (0 <θ <40). A vector obtained by rotating the absolute velocity vector U _i is defined as V _i . A straight line passing through the point C _i and parallel to the vector V _i is defined as a straight line C _i D _i , and an intersection of the straight line C _i D _i and the arc 23 is defined as D _i . Then, the absolute velocity vector W _i at the point D _i is obtained by experiment or calculation. A straight line passing through the point D _i and parallel to the vector W _i is defined as a straight line D _i E _i . The intersection of the arc 22 and the straight line D _i E _i is set as a point E _i . An arbitrary curve that is in the triangle C _i D _i E _i (including on the boundary line) and passes through the points C _i and D _i is defined as a curve F _i . The curve F _i may be composed of one or more line segments. The shape of the stationary blade 21 is determined so as to include the curve F _i in the region (including on the boundary). In the diagram, the absolute and the velocity vector U _I, the absolute velocity vector U _i a rotated vector V _i, the vector of the absolute velocity vector W _i, etc., with a showing a vector "→" on the code ing.

Table 1 shows the power consumption, rotational speed, and indoor unit of a fan motor (not shown) when the amount of air blown from the blowout port 7 is 15 m ³ / min with and without the stationary blade 21. 8 is a diagram illustrating a result of measuring a noise value generated from FIG. The noise value is measured in accordance with JIS standards. FIG. 8 is a diagram for explaining how to determine the shape of the stationary blade 21 used for this measurement.

FIG. 8 is a diagram for explaining how to determine the shape of the stationary blade 21 used for this measurement.
A method of determining the shape of the stationary blade 21 will be described with reference to FIG. The radius of the cross flow fan 1 is 50 mm, the radius of the arc 22 is 53 mm, and the radius of the arc 23 is 57 mm. A vertical line from the rotation center 24 of the cross flow fan 1, the intersection of the arc 22 and the point C _2. The point moved 10 degrees to the fan rotation direction around the rotational center 24 of the cross flow fan 1 point C ₂ to a point C _1. Moreover, 10 degrees counter-rotation direction of the fan the point C ₂ around the rotational center 24 of the cross flow fan 1, 20 degrees, 30 degrees, ..., respectively the points have moved 80 °, the points C _3, point C _4, Point C ₅ ,..., Point C ₁₀ . As an example, the shape of the stationary blade 21 including the point C ₃ will be described. From the calculation, an absolute velocity vector U ₃ at the point C ₃ is obtained. A vector V ₃ obtained by rotating U ₃ counterclockwise about the point C ₃ by 10 degrees is obtained, and a point D ₃ , an absolute velocity vector W ₃ , and a point E ₃ are obtained as shown in FIG. A point that internally divides line segment C ₃ D ₃ into 1: 9 is point G ₃ , a point that internally divides line segment D ₃ E ₃ into 1: 9 is point H _3, and point C ₃ and point G ₃ , point H _3, to create a spline curve F ₃ passing through the point D _3. Creating a curve F ₃ 'of the curve F ₃ has moved once to the fan rotation direction around the rotational center 24 of the cross flow fan 1. A closed curved surface composed of the curve F ₃ , the curve F ₃ ′, the arc C ₃ C ₃ ′, and the arc D ₃ D ₃ ′ is defined as the shape of the stationary blade 21. Here, the shape of the stationary blade 21 including the point C ₃ has been described, but the shape of the stationary blade 21 including the point C _i other than the point C ₃ is determined in the same manner. In the first embodiment, the case where the number of the stationary blades 21 is 10 has been described. However, two or more blades may be used, and the case where the points C _i are equally spaced has been described. May be.

  Thus, in the conventional case where there is no stationary blade 21 on the windward side of the suction area of the crossflow fan 1, the angle of attack 16 of the blade 12 is large and the vortex 15 is likely to be generated on the negative pressure surface 13 of the blade 12, so There are problems that the power consumption and the rotational speed of a fan motor (not shown) necessary for obtaining the air volume are large, and that the noise generated from the indoor unit 8 is large.

  In the first embodiment of the present invention, a plurality of stationary blades 21 are provided on the windward side of the suction region of the cross flow fan 1 as described above, and the wind direction is directed by the stationary blades 21 toward the suction surface side of the blades 12 of the cross flow fan 1. The vortex 15 generated on the suction surface 13 of the blade 12 can be reduced by changing the angle of attack so that the angle of attack 16 of the blade 12 is reduced, so that it is necessary to obtain a predetermined air volume as shown in Table 1. The power consumption and the rotational speed of the fan motor (not shown) can be reduced, and the noise generated from the indoor unit 8 can be reduced.

Embodiment 2. FIG.
FIG. 9 is a cross-sectional view of an indoor unit of an air conditioner according to Embodiment 2 of the present invention and a diagram showing a stationary blade.
In FIG. 9, 25 is a windward stationary blade, 26 is a leeward stationary blade, 27 is an arc, and the radius of the arc 27 is larger than the radius of the arc 22 and smaller than the radius of the arc 23. Assume that the intersection of the arc 27 and the curve C _i D _i is a point K _i , the windward stationary vane 25 includes the curve D _i K _i , and the leeward stationary vane 26 includes the curve K _i C _i .

  When the indoor unit 8 is operated by changing the rotational speed of the cross flow fan 1, the angle of attack 16 changes depending on the rotational speed. The angle of attack 16 is defined using the relative velocity vector Vr [m / s], but the absolute velocity vector is V [m / s], the radius vector is r [m], and the rotation speed is ω. [rad / s]

              Vr = V−r × ω

The relationship holds. For this reason, when the rotational speed ω [rad / s] changes, the angle of attack 16 also changes, and the optimum shape of the stationary blade 21 differs for each rotational speed.

Table 2 shows the characteristics of the cross flow fan 1 when the amount of air blown from the indoor unit 8 is 10 m ³ / min using the experimental apparatus and the stationary blade 21 used to obtain the experimental results shown in Table 1. It is the experimental result to represent.

As described above, the stationary blade 21 which has the effect of reducing the power consumption of the fan motor (not shown) at 15 m ³ / min is conversely a fan motor (not shown) at 10 m ³ / min. The power consumption is worsened and the rotation speed is also increased.

  Therefore, it is necessary to change the deflection angle by the stationary blade 21 in accordance with the rotational speed. Therefore, in the case of the second embodiment, the stationary blade 21 is divided into the windward stationary blade 25 and the leeward stationary blade 26, and the windward stationary blade 25 and the leeward stationary blade 26 are separated into separate stepping motors 28 and the like. The turning angle is changed by changing the number of rotations by operating. Of course, as long as the turning angle can be changed, the stationary blade 21 may be divided into those other than the windward stationary blade 25 and the leeward stationary blade 26.

Here, the turning angles of the stationary blades 25 and 26 are determined in advance by experiment or calculation for each rotation speed. This way when changing the deflection angle according to the rotation speed, air flow rate 5 m ^{3 /} min blown out from the indoor unit 8, the characteristics of the cross flow fan 1 in the case of 10 m ^{3 /} min in Tables 3 Show.

  As described above, when the turning angle of the stationary blade 21 is not changed according to the rotational speed of the cross flow fan 1, the necessary fan motor (which is necessary for obtaining a predetermined air volume by the stationary blade 21 when the rotational speed is changed). There is a problem that power consumption increases.

  In the second embodiment of the present invention, as is clear from the above description, the windward stationary vane 25 and the leeward stationary vane 26 are used, and the turning angle is variable according to the rotational speed of the crossflow fan 1. Thus, the power consumption of a fan motor (not shown) necessary for obtaining a predetermined air volume can be reduced.

Embodiment 3 FIG.
FIG. 10 is a diagram illustrating a cross flow fan according to Embodiment 3 of the present invention, and FIG. 11 is a diagram illustrating power consumption of a fan motor (not shown).
FIG. 11 shows a fan motor (not shown) when the airflow blown from the indoor unit 8 is 15 m ³ / min when the diameter D of the cross flow fan 1 is changed to 95 mm and the blade number N is changed from 20 to 40. 2) represents the experimental results of the relationship between the power consumption of the first flow and the diameter / number of blades of the crossflow fan 1.

  Thus, the power consumption of the fan motor (not shown) is minimized when the diameter / number of blades (D / N) of the cross flow fan 1 is 3.4 [mm / sheet]. Since the measurement accuracy in this experiment is considered to include an error of about 2 W, the diameter / number of blades (D / N) of the cross flow fan 1 is 3.05 ≦ D / N ≦ 3.8 [mm. / Sheet], the power consumption of the fan motor (not shown) can be reduced.

  Next, the reason for this will be described. In the indoor unit 8, the power consumption of a fan motor (not shown) that drives the cross flow fan 1 necessary for obtaining a predetermined air volume is calculated as follows. If the number of blades is large, the blade wind speed increases and the static pressure on the blade surface decreases, so the power consumption of the fan motor (not shown) increases. If the blade number is small, the blade wind speed decreases, Since the static pressure on the blade surface increases, the power consumption of the fan motor (not shown) decreases. However, in the actual flow, separation occurs on the blade surface of the cross flow fan 1. When the number of blades of the cross flow fan 1 is large, the static pressure difference between the adjacent negative pressure surface 13 and the pressure surface 14 increases, and when the number of blades is small, the static pressure difference between the adjacent negative pressure surface 13 and the pressure surface 14 decreases. The static pressure is higher on the pressure surface than on the negative pressure surface.

  Considering the Navier-Stokes equation that defines the flow of fluid, the pressure term is expressed by (static pressure difference / distance) / density, and has the same dimension as acceleration. Accordingly, when the number of blades of the cross flow fan 1 is large, the static pressure difference between the adjacent suction surface 13 and the pressure surface 14 is increased, and the distance is decreased. That is, the pressure term increases, and the working force from the pressure surface 14 toward the suction surface 13 increases, so that the vortex 15 hardly occurs on the suction surface 13. On the other hand, when the number of blades of the cross flow fan 1 is small, the static pressure difference between the adjacent negative pressure surface 13 and the pressure surface 14 becomes small and the distance becomes large. That is, the pressure term is reduced, and the force acting from the pressure surface 14 toward the suction surface 13 is reduced, so that the vortex 15 is likely to be generated on the suction surface 13. When the vortex 15 is generated on the negative pressure surface 13, the static pressure on the negative pressure surface 13 is lowered, and a force that decelerates the rotation of the cross flow fan 1 works. Therefore, a fan motor (not shown) necessary for obtaining a predetermined air volume is used. Power consumption increases.

  Therefore, if the number of blades of the cross flow fan 1 is large, the wind speed between the blades increases and the static pressure on the blade surface decreases, so the power consumption of the fan motor (not shown) increases, but the pressure term increases. Therefore, the vortex 15 is less likely to be generated on the negative pressure surface 13, and an increase in power consumption of a fan motor (not shown) due to the generation of the vortex 15 can be suppressed. On the other hand, if the number of blades of the cross flow fan 1 is small, the wind speed between the blades decreases and the static pressure on the blade surface increases, so that the power consumption of the fan motor (not shown) is reduced, but the pressure term is reduced. Therefore, the vortex 15 is likely to occur on the negative pressure surface 13, and the power consumption of the fan motor (not shown) is likely to increase.

  Thus, the power consumption of the fan motor (not shown) is such that the relationship between the diameter D of the crossflow fan 1 and the number N of blades satisfies 3.05 ≦ D / N ≦ 3.8 [mm / sheet]. When there is not, there exists a subject that the power consumption of the fan motor (not shown) required in order to blow out predetermined air volume from the indoor unit 8 is large.

  However, in the third embodiment of the present invention, the power consumption of the fan motor (not shown) is such that the relationship between the diameter D of the crossflow fan 1 and the number N of blades is 3.05 ≦ D / N. Since the relationship of ≦ 3.8 [mm / sheet] is satisfied, it is possible to reduce the power consumption of a fan motor (not shown) necessary for blowing a predetermined air volume from the indoor unit 8.

  In the third embodiment, the relationship between the fan diameter D of the crossflow fan and the number N of blades is defined as 3.05 ≦ D / N ≦ 3.8 [mm / sheet], and the fan of the crossflow fan is used. Although the diameter D is not specified, the fan diameter D should satisfy the condition of D ≦ 120 mm in view of the effect of reducing the power consumption of the fan motor, and the condition of 80 ≦ D ≦ 120 mm should be considered if the air volume is taken into consideration. By satisfying the relationship of fan diameter D to be satisfied and 3.05 ≦ D / N ≦ 3.8 [mm / sheet], a predetermined air volume can be obtained, and the necessary power consumption of the fan motor This is desirable in terms of reducing.

Embodiment 4 FIG.
FIG. 12 is a diagram showing a cross flow fan according to Embodiment 4 of the present invention. In FIG. 12, reference numeral 30 denotes a ring, a plurality of rings are provided in the cross flow fan 1, and the blades 12 are fixed. FIG. 13 shows the power consumption of a fan motor (not shown) when the blown air flow rate is 15 m ³ / min when the fan diameter D of the cross flow fan 1 is 90 [mm] and the pitch L of the ring 30 is 30 to 60 mm. And (D + 2000) / L represent the experimental results. However, (the total length of the cross flow fan 1−the number of rings 30 × the pitch of the rings 30) is 625 mm. That is, the thickness of the ring 30 is changed according to the pitch of the ring 30.

FIG. 14 is a diagram showing a power spectrum of noise generated from the indoor unit 8 at 15 m ³ / min when (D + 2000) / L is changed, and FIG. 15 is a diagram showing a ring when (D + 2000) / L is changed. It is a figure showing the calculation result of the distribution of the blowing air volume [m3 / min] between 30 and the suction air volume [m3 / min].

  As shown in FIG. 13, as the value of (D + 2000) / L increases, the power consumption of a fan motor (not shown) necessary to obtain a predetermined air volume decreases. Next, the reason will be described. As shown in FIG. 14, when (D + 2000) /L≧38.0, the noise generated from the indoor unit 8 in the frequency range of 600 to 900 [Hz] compared to when (D + 2000) /L=34.8. The peak value of the power spectrum is gone. Further, as shown in FIG. 15, the distribution of the blown air volume and the intake air volume is small between the rings 30. This is because the ring functions as a rectifying plate, and the smaller the pitch of the ring 30, the less turbulence of the wind between the rings 30. Therefore, a fan motor (not shown) required to obtain a predetermined air volume is shown. Z)) power consumption is reduced.

  Thus, when the fan diameter D [mm] of the cross flow fan 1 and the pitch L [mm] of the ring 30 are (D + 2000) / L <38.0, there is a problem that the predetermined air volume is large.

  In Embodiment 4 of the present invention, when the fan diameter D of the crossflow fan and the distance L between the rings satisfy the relationship of (D + 2000) /L≧38.0, the turbulence of the wind between the rings 30 is suppressed, The power consumption of a fan motor (not shown) necessary for obtaining a predetermined air volume can be reduced.

Embodiment 5 FIG.
16 is a diagram showing a stabilizer according to Embodiment 5 of the present invention, FIG. 17 is a diagram showing experimental results of power consumption of the fan motor, and FIG. 18 is a circulating vortex generated inside the crossflow fan. FIG. 19 is a diagram showing a calculation result of the distribution of the circulating vortex between the rings.

In the fifth embodiment, the protrusion height 34 of the protrusion 33 in the width direction of the stabilizer 31 that is the front surface direction from the back surface of FIG. 16 is divided for each ring 30 as shown in FIG. 12, that is, the ring 30 and the ring 30 Change within one block. Specifically, for example, when the block width, which is the distance between the ring 30 and the block 30, is z ₀ , and the distance from one end of the ring 30 is z, the protrusion of the stabilizer protrusion 33 in the block Crest or sawtooth-shaped stabilizer whose height 34 is maximum at z / z ₀ = 0.25, 0.75 is the stabilizer 35, and the protrusion height 34 of the protrusion 33 is maximum at z / z ₀ = 0.5. The stabilizer 36 is a mountain or sawtooth stabilizer, and the stabilizer 37 is a stabilizer that does not change the projection height 34 in the width direction of the block.

FIG. 17 shows that when the pitch of the ring 30 is 30 to 70 mm and the projection height 34 of the stabilizer 31 is not changed, and when the stabilizer 35 and the stabilizer 36 are used, the air volume blown from the indoor unit 8 is 15 m ³ / It is a figure showing the experimental result of the noise value generated from indoor unit 8 at the time of min.
As described above, the stabilizers 35 and 36 can reduce the noise value generated from the indoor unit 8 when the predetermined air volume is larger than that of the stabilizer 37.

Next, the reason will be described. In FIG. 18, the rotation center 24 of the crossflow fan 1 and the point 38 having the lowest static pressure of the circulating vortex generated inside the crossflow fan 1 are connected by a straight line 39, and the perpendicular 40 is lowered from the rotation center 24. An angle formed by the straight line 39 and the perpendicular 40 is defined as θ [deg]. FIG. 19 is a diagram showing the distribution of the vortex position θ [deg] between the blocks 32. As shown in FIG. 19, the vortex position θ [deg] takes a minimum value in the vicinity of z / z ₀ = 0, 1 or z / z ₀ = 0.5. When the vortex position θ [deg] is small, the angle of attack 16 of the blade 12 in the suction region of the crossflow fan 1 increases, and a vortex is generated on the negative pressure surface 13, thereby reducing the power consumption of the fan motor (not shown). Cause an increase. On the other hand, when the height 34 of the protrusion 32 of the stabilizer 31 is high, the vortex position θ [deg] is small, and when the height 34 is low, the vortex position θ [deg] is large. Therefore, if the height 34 is reduced in the vicinity of z / z ₀ = 0, 1 or z / z ₀ = 0.5 where the vortex position θ [deg] is reduced, the vortex position θ [deg] is increased. . As described above, the height 34 is different when 0 ≦ z / z ₀ ≦ 1, but the height 39 is changed smoothly. Accordingly, the angle of attack 16 of the blade 12 in the suction area of the cross flow fan 1 does not increase, and vortices are less likely to be generated on the suction surface 13, and the noise value generated from the indoor unit 8 can be reduced.

  Thus, the stabilizer 37 that does not change the height 34 of the protrusion 32 of the stabilizer 31 in the width direction of the cross flow fan 1 has a problem that the noise value generated from the indoor unit 8 is large.

In the fifth embodiment of the present invention, the space between the rings 30 is one block, and the height 34 of the protrusion 32 of the stabilizer 31 is z / z ₀ = 0.25, 0.75, or z / z ₀ within the one block. By providing stabilizers 35 and 36 that are maximum at 0.5, and changing the height of the protrusion at the tip of the stabilizer like a saw blade within one block, the noise value generated from the indoor unit 8 at a predetermined air volume can be reduced. Can be small.

Embodiment 6 FIG.
20 and 21 are views showing the blades of the crossflow fan according to Embodiment 6 of the present invention, and FIGS. 22 and 23 are views showing the static pressure distribution in the blowout region of the crossflow fan.

FIG. 20 is a diagram showing a chamfered shape at the outer peripheral side tip of the cross flow fan 1, and FIG. 21 is a diagram showing an edge shape with a chamfered inner tip. Table 5 shows that the outer peripheral side tip of the cross flow fan 1 has a chamfered shape, the inner peripheral side tip is chamfered into an edge shape, and the inner peripheral side tip of the cross flow fan 1 has a rounded corner of R0.1. In comparison, the power consumption of a fan motor (not shown) when the air volume blown from the indoor unit 8 is 15 m ³ / min when using the blades 42 is shown.

  Next, the reason for this will be described. In the blowing region of the cross flow fan 1, wind flows from the inner peripheral side of the blade 12 toward the outer peripheral side. At this time, when the tip on the inner peripheral side is chamfered like the blade 42, the tip on the inner peripheral side becomes a stagnation point, and the static pressure increases and the dynamic pressure decreases as shown in FIG. This is because the amount of air blown out from the indoor unit 8 increases as the dynamic pressure increases, so that if the stagnation point exists at the inner peripheral side tip of the cross flow fan 1, the amount of air blown out from the indoor unit 8 decreases. On the other hand, when the tip of the inner peripheral side of the cross flow fan 1 is chamfered and has an edge shape like the blade 41, no stagnation point is generated at the tip of the inner peripheral side as shown in FIG. As a result of the calculation, the static pressure at the tip on the inner peripheral side of the blade 41 and the blade 42 in the blowout region of the cross flow fan 1 is about 10 to 20 [Pa] higher in the blade 42. Therefore, as shown in Table 3, the consumption of a fan motor (not shown) required to obtain a predetermined air volume is greater when the chamfer is chamfered than when the inner peripheral tip is chamfered. Electric power can be reduced.

  In the sixth embodiment, the case where the inner peripheral side of the blade 42 is chamfered to have an edge shape has been described. However, the same effect can be obtained even if the outer peripheral side is also chamfered to have an edge shape. . This can suppress the generation of a stagnation point at the outer peripheral tip of the blade 42 in the suction region of the cross flow fan 1, and therefore a fan motor (not shown) required to obtain a predetermined air volume from the indoor unit 8. )) Can be reduced.

  Thus, when the inner peripheral side tip of the cross flow fan 1 is not chamfered to have an edge shape, a stagnation point is generated at the inner peripheral side tip of the blade 42 in the blowing region of the cross flow fan 1. There is a problem that power consumption of a fan motor (not shown) necessary for obtaining a predetermined air volume from the indoor unit 8 is large.

  In the sixth embodiment of the present invention, the tip of the inner peripheral side of the cross flow fan 1 is chamfered into an edge shape, so that the stagnation point of the tip of the inner peripheral side of the blade 42 is generated in the blowing region of the cross flow fan 1. Since it can suppress that it produces | generates, the power consumption of the fan motor (not shown) required in order to obtain predetermined air volume from the indoor unit 8 can be reduced.

  In the description of the first to sixth embodiments, in accordance with the features of the main claims, according to the features of the main claims, for example, the rotational speed of the cross flow fan 1 provided with a plurality of stationary blades 21. Stabilizer between the rings of the crossflow fan 1 in which the fan diameter D of the crossflow fan 1 and the distance L between the rings satisfy the relationship of (D + 2000) /L≧38.0. Each of the embodiments has been described separately in terms of changing the height of the protrusion at the tip and changing the shape of the tip on the inner peripheral side of the crossflow fan 1 into an edge shape. In order to reduce power consumption, two or more of these may be arbitrarily combined. For example, a plurality of stationary blades 21 are provided, and the fan diameter D of the cross flow fan 1 and the inter-ring distance L satisfy the relationship of (D + 2000) /L≧38.0, or the fan of the cross flow fan 1 The diameter D and the distance L between the rings satisfy the relationship of (D + 2000) /L≧38.0, the height of the protrusion of the stabilizer-tip between the rings of the crossflow fan 1 is changed, and the crossflow Arbitrary combinations of the first to sixth embodiments are possible, for example, the shape of the tip of the inner peripheral side of the fan 1 is an edge shape.

It is a block diagram of the air conditioner which shows the structure of Embodiment 1 of this invention. It is a trace inside an air conditioner which shows the structure of Embodiment 1 of this invention. It is a relative velocity distribution figure of a blade of a cross flow fan which shows composition of Embodiment 1 of this invention. It is a block diagram of the blade | wing of a crossflow fan which shows the structure of Embodiment 1 of this invention. It is a figure showing sectional drawing of the indoor unit 8 when the some stationary blade 21 which is the characteristics of Embodiment 1 of this invention is installed. It is explanatory drawing which shows how to determine the shape of the stationary blade which shows the structure of Embodiment 1 of this invention. It is explanatory drawing which shows how to determine the shape of the stationary blade which shows the structure of Embodiment 1 of this invention. It is explanatory drawing which shows how to determine the shape of the stationary blade which shows the structure of Embodiment 1 of this invention. It is sectional drawing of the indoor unit of the air conditioner concerning Embodiment 2 of this invention, and a figure showing a stationary blade. It is a block diagram of the blade | wing of a crossflow fan which shows the structure of Embodiment 3 of this invention. It is a figure showing the relationship between the fan motor power consumption of the crossflow fan which shows the structure of Embodiment 3 of this invention, and a fan diameter / blade number. It is a block diagram of the crossflow fan which shows the structure of Embodiment 4 of this invention. It is a figure showing the relationship between the fan motor power consumption of the crossflow fan which shows the structure of Embodiment 4 of this invention, and the distance between rings. It is a figure showing the power spectrum of the noise which generate | occur | produces from the indoor unit 8 at the time of 15 m < ³ > / min when (D + 2000) / L is changed in Embodiment 4 of this invention. It is a figure showing the calculation result of the distribution of the blowing air volume between the rings 30 when changing (D + 2000) / L in Embodiment 4 of this invention, and the suction | inhalation air volume distribution. It is a figure showing the stabilizer of the cross low fan of Embodiment 5 of this invention. It is a figure showing the experimental result of the power consumption of the fan motor in Embodiment 5 of this invention. It is a figure showing the position of the circulation vortex inside the crossflow fan of Embodiment 5 of this invention. It is a figure showing the calculation result of distribution of the circulation vortex between the rings of the crossflow fan of Embodiment 5 of this invention. It is a figure for comparing with the blade | wing of the crossflow fan of Embodiment 6 of this invention. It is a figure showing the blade | wing of the crossflow fan of Embodiment 6 of this invention. It is a static pressure distribution map near the blade | wing of the crossflow fan of Embodiment 6 of this invention. It is a static pressure distribution map of the wing | blade vicinity of the crossflow fan which shows the structure of Embodiment 5 of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Cross flow fan, 2 Heat exchanger, 3 Refrigerant piping, 4 Pre filter, 5 Air purifier, 6 Air inlet, 7 Air outlet, 8 Indoor unit, 9 Fan motor, 10 Air, 11 area | region, 12 blades, 13 Negative Pressure face, 14 pressure face, 15 vortex, 16 angle of attack, 17 arrow, 18 relative velocity vector, 19 leading edge, 20 trailing edge, 21 stator blade, 22 arc, 23 arc, 24 center of rotation, 25 upwind stator blade, 26 Leeward stator vane, 27 arc, 28 stepping motor, 29 stepping motor, 30 ring, 31 stabilizer, 32 block, 33 protrusion, 34 protrusion height, 35 stabilizer, 36 stabilizer, 37 stabilizer, 38 vortex center, 39 perpendicular line, 40 Straight line, 41 wings, 4 Tsubasa.

Claims (6)

A cross flow fan connected to an indoor unit with at least one suction port, a blow port, and a fan motor, and a plurality of stationary blades only at a location away from the stabilizer on the windward side of the suction portion of the cross flow fan The cross flow fan is characterized in that the direction of the wind is changed by these stationary blades so that the wind hits the suction surface side of the cross flow fan rotor blade.   2. The cross flow fan according to claim 1, wherein a change angle of the plurality of stationary blades is movable, and a direction of change of a wind direction by the stationary blades is changed according to a rotation speed of the cross flow fan.   The cross flow fan according to claim 1 or 2, wherein the shapes of the plurality of stationary blades are different from each other. 4. The cross flow fan according to claim 1, wherein the shape of the tip of the inner peripheral blade of the cross flow fan is an edge shape. 5. The cross flow fan according to claim 4, wherein the outer peripheral side of the tip of the blade of the cross flow fan is rounded.   An air conditioner comprising the crossflow fan according to any one of claims 1 to 5 and a heat exchanger.

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