JPWO2018179075A1 - Propeller fan - Google Patents

Abstract

The propeller fan has a boss that rotates about an axis, and a plurality of blades disposed on an outer peripheral portion of the boss.The blade has a notch at a trailing edge, and the notch has The wing has three or more triangular cutouts in a top view, which are arranged from the inner circumferential end to the outer circumferential end of the wing. It is configured so that it becomes smaller after it becomes.

Description

  The present invention relates to a propeller fan used in a refrigeration cycle apparatus such as an air conditioner or a ventilator.

Conventionally, propeller fans (axial blowers) have been required to reduce noise. In view of this, a propeller fan has been proposed in which the noise is further reduced depending on the shape of the blade.
For example, Patent Document 1 discloses a propeller fan that “a blade trailing edge has a sawtooth shape”.

Japanese Patent Laid-Open No. 08-189497

  The propeller fan described in Patent Document 1 makes it possible to gradually merge the flow on the suction surface side and the pressure surface side of the blade by making the shape of the trailing edge of the blade a sawtooth. For this reason, the speed deficit is reduced in the vicinity of the trailing edge. As a result, the propeller fan described in Patent Document 1 has a reduced speed gradient and less turbulence. That is, in Patent Document 1, the shape of the trailing edge of the blade is used to reduce turbulence in the blade wake, thereby reducing noise and improving fan efficiency.

  However, in the propeller fan described in Patent Document 1, the shape of the trailing edge of the blade is made into a sawtooth shape, so that the vortex as a sound source can be subdivided, but the sawtooth shape becomes a flow of air. Not along. Therefore, the propeller fan described in Patent Document 1 has a problem that the static pressure is reduced and a sufficient low noise effect cannot be obtained.

  The present invention has been made to solve such a problem, and an object of the present invention is to provide a propeller fan that adopts a blade shape that takes static pressure into consideration and achieves low noise.

  A propeller fan according to the present invention has a boss that rotates about an axis, and a plurality of blades disposed on an outer peripheral portion of the boss, and the blade has a notch at a rear edge, The cutout has three or more triangular cutout portions arranged from the inner peripheral end to the outer peripheral end of the wing, and the notch portion has a depth and a width that are outer peripheral from the inner peripheral end of the wing. The structure is such that it once becomes large toward the end and then becomes small.

  According to the propeller fan of the present invention, the notch having three or more notch portions configured such that the depth and width are once increased from the inner peripheral end to the outer peripheral end of the blade and then decreased. Since it is formed at the trailing edge, an increase in static pressure can be ensured and a reduction in noise can be realized.

It is a perspective view which shows roughly the structure of the propeller fan which concerns on Embodiment 1 of this invention. It is an expansion perspective view which expands and shows one of the wing | blade of the propeller fan which concerns on Embodiment 1 of this invention. It is the schematic which expands and shows roughly the trailing edge part of one wing | blade of the propeller fan which concerns on Embodiment 1 of this invention. It is a schematic diagram for demonstrating the flow of the air in the blade | wing of the propeller fan which concerns on Embodiment 1 of this invention. It is a perspective view which shows schematically the structure of the propeller fan which concerns on Embodiment 2 of this invention. It is an expansion perspective view which expands and shows one of the wing | blade of the propeller fan which concerns on Embodiment 3 of this invention. It is the schematic which expands and shows roughly the trailing edge part of one wing | blade of the propeller fan which concerns on Embodiment 3 of this invention. It is the schematic which looked at some propeller fans which concern on Embodiment 4 of this invention on the upper surface.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, in the following drawings including FIG. 1, the relationship of the size of each component may be different from the actual one. Further, in the following drawings including FIG. 1, the same reference numerals denote the same or equivalent parts, and this is common throughout the entire specification. Furthermore, the forms of the constituent elements shown in the entire specification are merely examples, and are not limited to these descriptions.

Embodiment 1 FIG.
FIG. 1 is a perspective view schematically showing a configuration of propeller fan 100A according to Embodiment 1 of the present invention. FIG. 2 is an enlarged perspective view showing one of the blades 2A of the propeller fan 100A in an enlarged manner. FIG. 3 is a schematic diagram schematically showing an enlarged rear edge 24 portion of one blade 2A of the propeller fan 100A. FIG. 4 is a schematic diagram for explaining the air flow in the blade 2A of the propeller fan 100A. The propeller fan 100A will be described with reference to FIGS.

  In FIG. 1, a propeller fan 100A having five blades 2A is shown. However, the number of blades 2A is not particularly limited. Further, the cutout 25A is set for each blade regardless of the number of blades 2A, and the effect of implementing the propeller fan 100A according to Embodiment 1 of the present invention is obtained for each blade. Further, in FIG. 3, a notch portion 30c constituting a part of the notch 25A is shown as a representative example.

  Propeller fan 100 </ b> A includes boss 1 that rotates about axis RC and a plurality of blades 2 </ b> A that are disposed on the outer periphery of boss 1. The wing 2 </ b> A is surrounded by an inner peripheral end 21, an outer peripheral end 22, a front edge 23, and a rear edge 24. Further, a notch 25A is provided in the trailing edge 24 of the wing 2A. The cutout 25A is formed by arranging a plurality of cutout portions 30 having a triangular shape in a top view from the inner peripheral end 21 to the outer peripheral end 22 of the blade 2A.

  1 and 2 show an example in which the notch 25A is formed by the five notch portions 30, but the number of the notch portions 30 may be three or more, and the number is not particularly limited. In FIG. 2, the cutout portion 30a, the cutout portion 30b, the cutout portion 30c, the cutout portion 30d, and the cutout portion 30e are illustrated from the left side of the drawing, that is, from the inner peripheral end 32 side. The triangular shape in the top view means that the propeller fan 100A has a triangular shape when viewed from the axial direction (upper side in the drawing).

The notch 25A will be described in detail.
Each of the cutout portions 30 has a first end portion 25a and a second end portion 25b. The first end portion 25 a is one apex portion that is formed on the front edge 23 side of the cutout portion 30. That is, each of the first end portions 25a has one cutout portion 30. The second end portion 25 b is two apex portions formed on the rear edge 24 side of the notch portion 30. That is, the second end portion 25b has two each of the cutout portions 30.

  However, the second end portion 25b on the outer peripheral end 22 side of the notch portion 30a is common to the second end portion 25b on the inner peripheral end 21 side of the adjacent notch portion 30b. Similarly, the second end portion 25b on the outer peripheral end 22 side of the notch portion 30b is common to the second end portion 25b on the inner peripheral end 21 side of the adjacent notch portion 30c. Similarly, the second end portion 25b on the outer peripheral end 22 side of the notch portion 30c is common to the second end portion 25b on the inner peripheral end 21 side of the adjacent notch portion 30d. Similarly, the second end portion 25b on the outer peripheral end 22 side of the notch portion 30d is common to the second end portion 25b on the inner peripheral end 21 side of the adjacent notch portion 30e. In addition, the 2nd end part 25b by the side of the inner peripheral end 21 of the notch part 30a has the notch part 30a, and the 2nd end part 25b by the side of the outer periphery 22 of the notch part 30e has the notch part 30e.

  Each cutout portion 30 has two sides 253 that connect the first end 25a and the second end 25b. The side 253 on the inner peripheral end 21 side, which is one of the two sides, is the inner periphery 253i, and the side 253 on the outer peripheral end 22 side, which is one of the two sides, is the outer periphery 253o. Each of the cutout portions 30 is a space portion from the two second end portions 25b to the first end portion 25a.

  Here, a straight line connecting the adjacent second end portions 25b is L1, a perpendicular line passing through the first end portion 25a of each notch portion 30 with respect to L1 is L2, and an intersection of L1 and L2 is P. At this time, the distance between P and the first end portion 25 a is defined as the depth 251 of the notch portion 30, and the distance between the adjacent second end portions 25 b is defined as the width 252 of the notch portion 30.

  The depth 251 of the cutout portion 30 and the width 252 of the cutout portion 30 are formed such that the cutout portions 30 are once increased from the inner peripheral end 21 side to the outer peripheral end 22 side and then reduced. That is, as shown in FIG. 2, the cutout portion 30 is sequentially enlarged from the cutout portion 30a to the cutout portion 30c, and the cutout portion 30 is sequentially reduced from the cutout portion 30c to the cutout portion 30e, so that the cutout portion 30c is the largest size. It has become. The depth 251 of the cutout portion 30c and the width 252 of the cutout portion 30c are the maximum.

  The two sides 253 of the cutout portion 30 each have an arc shape that is convex toward the outer peripheral end 22 side. The radius of curvature of the arc of the inner periphery 253i is Ri, and the radius of curvature of the arc of the outer periphery 253o is Ro. At this time, the inner periphery 253i and the outer periphery 253o are configured to satisfy the relationship Ri <Ro.

  Next, the effect produced by the propeller fan 100A will be described along with the operation of the propeller fan 100A based on FIG. In FIG. 4, the air flow in the blade 2A is indicated by arrows.

The operation of the propeller fan 100A will be described.
When a motor (not shown) attached to the boss 1 is rotationally driven, the three-dimensional solid wing 2A shown in FIG. 1 rotates together with the boss 1 in the direction indicated by the arrow A about the axis RC. An airflow (air flow) is generated by the rotation of the blade 2A. The upstream side of the blade 2A is a negative pressure surface, and the downstream side is a positive pressure surface.

The effect of the propeller fan 100A will be described.
In the propeller fan 100A, as in a general propeller fan, the air flow on the outer peripheral end 22 side on the surface of the blade 2A flows toward the outer peripheral end 22 side by the centrifugal force in the vicinity of the trailing edge 24 as shown by an arrow ST1. It becomes a biased flow.
In the propeller fan 100A, similarly to a general propeller fan, the air flow on the inner peripheral end 21 side on the surface of the blade 2A is a flow along the inner peripheral end 21 as shown by an arrow ST2.

  Incidentally, the propeller fan 100A has a notch 25A formed in the trailing edge 24 of the blade 2A. Therefore, in the propeller fan 100A, air flows in the outer periphery 253o of the cutout portion 30 as indicated by the arrow ST3. That is, in the outer periphery 253o of the cutout portion 30, the air flow is essentially parallel to the arrow ST1, so by making Ro larger than Ri, the air flow extends along the blade surface long as shown by the arrow ST3. It will be.

  In the propeller fan 100A, air flows in the inner periphery 253i of the cutout portion 30 as indicated by an arrow ST4. In other words, since the air flow is originally substantially orthogonal to the arrow ST1 at the inner periphery 253i of the cutout portion 30, the air flow is along the inner periphery 253i as indicated by the arrow ST4 by making Ri smaller than Ro. Can be bent smoothly. Therefore, if Ri is larger than Ro, the air flow cannot be bent suddenly and cannot follow the wing surface. However, in the propeller fan 100A, by making Ri smaller than Ro, the inner periphery of the notch 30 Even at 253i, it becomes possible to keep the airflow along the blade surface longer.

  As described above, according to the propeller fan 100A, by forming the notch 25A in the trailing edge 24 of the blade 2A, it becomes possible to keep the air flow in the vicinity of the trailing edge 24 along the blade surface long. Increase in static pressure can be secured.

  Further, the velocity distribution of the air flow indicated by the arrow ST1 increases once as the centrifugal force increases from the inner peripheral end 21 side toward the outer peripheral end 22 side. The leak flow shown occurs. As a result, the work of the blade 2A is reduced, and the speed starts to decrease. The higher the speed, the larger the vortex that becomes the sound source. In order to subdivide this, it is necessary to increase the depth 251 of the cutout portion 30 and the width 252 of the cutout portion 30.

Therefore, the propeller fan 100A is configured such that the depth 251 of the cutout portion 30 and the width 252 of the cutout portion are once increased from the inner peripheral end 21 side to the outer peripheral end 22 side and then reduced. By doing so, the velocity distribution of the blade surface, the depth 251 of the notch portion 30 and the width 252 of the notch portion are combined more appropriately, and the effect of ensuring an increase in static pressure is sufficiently exhibited.
Therefore, according to the propeller fan 100, by forming the notch 25A in the trailing edge 24 of the blade 2A, the effect of subdividing the vortex as a sound source can be sufficiently exerted without reducing the static pressure. Can be realized.

Embodiment 2. FIG.
FIG. 5 is a perspective view schematically showing a configuration of propeller fan 100B according to Embodiment 2 of the present invention. The propeller fan 100B will be described with reference to FIG.
In the second embodiment, differences from the first embodiment will be mainly described, and the same parts as those in the first embodiment will be denoted by the same reference numerals and description thereof will be omitted. FIG. 5 shows a propeller fan 100B having five blades 2B. However, the number of blades 2B is not particularly limited. In addition, the notch 25B is set for each blade regardless of the number of blades 2B, and the effect of implementing the propeller fan 100B according to Embodiment 2 of the present invention is obtained for each blade.

  Propeller fan 100 </ b> B includes boss 1 that rotates about an axis RC and a plurality of blades 2 </ b> B that are disposed on the outer periphery of boss 1. The wing 2 </ b> B is surrounded by an inner peripheral end 21, an outer peripheral end 22, a front edge 23, and a rear edge 24. Further, a notch 25B is provided in the trailing edge 24 of the wing 2B. Similarly to the cutout 25A described in the first embodiment, the cutout 25B is formed by arranging a plurality of cutout portions 30 having a triangular shape in top view from the inner peripheral end 21 to the outer peripheral end 22 of the blade 2B. In FIG. 5, the state in which the notch 25 </ b> B is formed by the five notch portions 30 is shown as an example, but it is sufficient that the notch portions 30 are three or more. Note that the configuration of the cutout portion 30 is as described in the first embodiment.

The notch 25B will be described in detail.
The radius position of the second end 25b located on the inner peripheral end 21 side of the cutout portion 30a with respect to the axial center RC is Rki, and the radius of the second end portion 25b located on the outer peripheral end 22 side of the cutout portion 30e with respect to the axial center RC. The position is Rko, and the radial position of the outer peripheral end 22 of the blade 2B with respect to the axial center RC is Rf. The notch 25B is formed at a position satisfying the relationship of Rki / Rf> 0.65 and Rko / Rf <0.95. That is, when each of Rki / Rf and Rko / Rf has a radius ratio, the notch 25B is provided in a radius ratio range of 0.65 to 0.95.

  More specifically, the value determined by the second end 25b located on the innermost peripheral end 21 side of the notch portion 30 constituting the notch 25B and the outermost end 22 which is the outermost side of the blade 2 is set to the minimum value. The range of the radius ratio is determined with a value determined by the second end portion 25b located on the outermost end 22 side of the cutout portion 30 constituting 25B and the outermost end 22 being the outermost side of the blade 2 as a maximum value. The

The effect of the propeller fan 100B will be described.
When the notch 25B is formed in a region having a radius ratio of 0.65 or less, the centrifugal force acting on the air flow is small, and the influence of the air flow biased toward the outer peripheral end 22 (see arrow ST1 shown in FIG. 4) is small. It will be a thing.
Further, when the notch 25B is formed in a region having a radius ratio of 0.95 or more, an effect of pushing back the air flow toward the inner peripheral end 21 works due to the influence of the leakage flow (see arrow V shown in FIG. 4). An air flow biased toward the end 22 (see arrow ST1 shown in FIG. 4) is unlikely to occur.

  That is, the propeller fan 100B is provided with the notch 25B in the range of the radius ratio of 0.65 to 0.95, which is the region where the air flow biased toward the outer peripheral end 22 side is most noticeable due to the centrifugal force. Therefore, according to the propeller fan 100B, by forming the notch 25B in the optimum range of the trailing edge 24 of the blade 2B, it becomes possible to keep the air flow in the vicinity of the trailing edge 24 long along the blade surface. Thus, it is possible to more effectively ensure an increase in static pressure. Therefore, according to the propeller fan 100B, the effect of subdividing the vortex serving as the sound source can be sufficiently exerted without lowering the static pressure, so that noise reduction can be realized.

Embodiment 3 FIG.
FIG. 6 is an enlarged perspective view showing one of the blades 2C of the propeller fan 100C according to Embodiment 3 of the present invention. FIG. 7 is a schematic view schematically showing an enlarged rear edge 24 portion of one blade 2C of the propeller fan 100C. The propeller fan 100C will be described with reference to FIGS.

  In the third embodiment, differences from the first and second embodiments will be mainly described, and the same parts as those in the first and second embodiments will be denoted by the same reference numerals and the description thereof will be omitted. In FIG. 6, one of the blades 2C constituting the propeller fan 100C is illustrated. The propeller fan 100C has, for example, five blades 2C, but the number of blades 2C is not particularly limited. Further, the cutout 25C is set for each blade regardless of the number of blades 2C, and the effect of implementing the propeller fan 100C according to Embodiment 3 of the present invention is obtained for each blade.

  Propeller fan 100 </ b> C includes boss 1 that rotates about axis RC and a plurality of blades 2 </ b> C that are disposed on the outer periphery of boss 1. The blade 2 </ b> C is surrounded by an inner peripheral end 21, an outer peripheral end 22, a front edge 23, and a rear edge 24. Further, a notch 25C is provided in the trailing edge 24 of the blade 2C. Similarly to the cutout 25A described in the first embodiment, the cutout 25C is formed by arranging a plurality of cutout portions 30 having a triangular shape in top view from the inner peripheral end 21 to the outer peripheral end 22 of the blade 2C. In FIG. 6, a state in which the notch 25 </ b> C is formed by the five notch portions 30 is illustrated as an example, but the number of the notch portions 30 may be three or more. Note that the configuration of the cutout portion 30 is as described in the first embodiment.

The notch 25C will be described in detail.
In the first embodiment, each notch portion 30 is formed such that the depth 251 of the notch portion 30 and the width 252 of the notch portion 30 are once increased from the inner peripheral end 21 side to the outer peripheral end 22 side and then decreased. However, the radius of curvature Ri of the inner periphery 253i of each notch portion 30 is not described.
Therefore, in the propeller fan 100C, in addition to the contents of the first embodiment, the size of the radius of curvature Ri of the arc of the inner periphery 253i of each notch portion 30 is considered.

  Specifically, the notch portions 30 are cut so that the radius of curvature Ri of the inner periphery 253i of each notch portion 30 becomes smaller in a region where the depth 251 of the notch portion 30 and the width 252 of the notch portion 30 are larger than the reference value. In a region where the depth 251 of the portion 30 and the width 252 of the cutout portion 30 are small, the portion 30 is increased. The reference value is an average value of the depth 251 and the width 252 of the notch portion 30 or the maximum depth 251 of the notch portion 30 and the width 252 of the notch portion 30 and the minimum notch portion. An intermediate value of the depth 251 of 30 and the width 252 of the notch portion 30 can be set as appropriate.

  Here, the depth 251a, the depth 251b, and the depth 251c in order from the largest in the depth 251 of the cutout portion 30 are, for example, 251b = 0.9 × 251a, for example, 251c = 0.9 × 251b. And Further, the radius of curvature Ri of the arc of the inner periphery 253i is set to Ria, Rib, and Ric, respectively, corresponding to the depth 251a, the depth 251b, and the depth 251c. At this time, it is configured to satisfy the relationship of Rib = 0.95 × Ria and Ric = 0.95 × Rib.

  In FIG. 7, the relationship between the notch portion 30c, the notch portion 30d, and the notch portion 30e is illustrated as an example. The cutout portion 30a can be formed with the same depth 251 and the same width 252 as the cutout portion 30e, for example. Similarly, the cutout portion 30b can be formed with the same depth 251 and the same width 252 as the cutout portion 30d, for example. However, it is not essential to form the cutout portions 30 at the symmetrical positions with the same depth 251 and the same width 252. The symmetrical position is a position where the depth 251 of the cutout portion 30 and the width 252 of the cutout portion 30 once increase from the inner peripheral end 21 side to the outer peripheral end 22 side and then decrease. Further, the depth 251 and the width 252 of all the cutout portions 30 may be different. Note that the same configuration is applied to the width 252 of the cutout portion 30.

The effect of the propeller fan 100C will be described.
As described in the first embodiment, making the inner periphery 253i of the cutout portion 30 in an arc shape increases the static pressure by smoothly bending the air flow along the inner periphery 253i and extending it along the blade surface for a long time. (See arrow ST4 shown in FIG. 4).
In addition, in the propeller fan 100C, the radius of curvature Ri of the arc of the inner periphery 253i is made smaller in the region where the air flow speed is faster. Thereby, according to the propeller fan 100C, it is possible to overcome the inertia of the fast air flow and bend the air flow along the inner periphery 253i, thereby further ensuring a static pressure increase. Therefore, according to the propeller fan 100C, the effect of subdividing the vortex serving as the sound source can be sufficiently exerted without lowering the static pressure, so that noise reduction can be realized.

Embodiment 4 FIG.
FIG. 8 is a schematic view of a part of the propeller fan 100D according to Embodiment 4 of the present invention as viewed from above. The propeller fan 100D will be described with reference to FIG.
In the fourth embodiment, differences from the first to third embodiments will be mainly described, and the same parts as those in the first to third embodiments will be denoted by the same reference numerals and the description thereof will be omitted. FIG. 8 shows one of the blades 2D constituting the propeller fan 100D. Propeller fan 100D has, for example, five blades 2D, but the number of blades 2D is not particularly limited. In addition, the notch 25D is set for each blade regardless of the number of blades 2D, and the effect of implementing the propeller fan 100C according to Embodiment 4 of the present invention is obtained for each blade.

  Propeller fan 100D has a boss 1 that rotates about an axis RC and a plurality of blades 2D that are disposed on the outer periphery of boss 1. The blade 2D is surrounded by an inner peripheral end 21, an outer peripheral end 22, a front edge 23, and a rear edge 24. Further, a notch 25D is provided in the trailing edge 24 of the wing 2D. Similarly to the cutout 25A described in the first embodiment, the cutout 25D is formed by arranging a plurality of cutout portions 30 having a triangular shape in top view from the inner peripheral end 21 to the outer peripheral end 22 of the blade 2D. In FIG. 8, a state in which the notch 25 </ b> D is formed by the five notch portions 30 is illustrated as an example, but the number of the notch portions 30 may be three or more. Note that the configuration of the cutout portion 30 is as described in the first embodiment.

The notch 25D will be described in detail.
As shown in FIG. 8, an arc passing through the first end 25a of the cutout portion 30a with the axis RC as the center is defined as an arc X1. An arc passing through the first end portion 25a of the cutout portion 30b with the axis RC as the center is defined as an arc X2. An arc passing through the first end portion 25a of the notch 30c with the axis RC as the center is defined as an arc X3. An arc passing through the first end portion 25a of the cutout portion 30d with the axis RC as the center is defined as an arc X4. Further, an arc passing through the first end portion 25a of the notch portion 30e with the axis RC as the center is defined as an arc X5.

  At this time, the 2nd end part 25b located in the inner peripheral end 21 side of the notch part 30a is located in the outer peripheral end 22 side rather than the circular arc X1. Similarly, the 2nd end part 25b located in the inner peripheral end 21 side of the notch part 30b is located in the outer peripheral end 22 side rather than the circular arc X2. Similarly, the 2nd end part 25b located in the inner peripheral end 21 side of the notch part 30c is located in the outer peripheral end 22 side rather than the circular arc X3. Similarly, the 2nd end part 25b located in the inner peripheral end 21 side of the notch part 30d is located in the outer peripheral end 22 side rather than the circular arc X4. Similarly, the 2nd end part 25b located in the inner peripheral end 21 side of the notch part 30e is located in the outer peripheral end 22 side rather than the circular arc X5.

  That is, in the propeller fan 100D, the radial position of the second end 25b with respect to the axial center RC on the inner periphery 253i of each of the plurality of cutout portions 30 is connected to the second end 25b and the inner periphery 253i. The notch 25D is configured so as to be positioned on the outer peripheral side with respect to the radial position with respect to the axial center RC of the one end portion 25a.

The effect of the propeller fan 100D will be described.
As described in the first embodiment, making the inner periphery 253i of the cutout portion 30 in an arc shape increases the static pressure by smoothly bending the air flow along the inner periphery 253i and extending it along the blade surface for a long time. (See arrow ST4 shown in FIG. 4).
In addition, in the propeller fan 100D, since the first end 25a and the second end 25b on the inner periphery 253i are set in relation to the arc X passing through the first end 25a, the air flow is bent too much. The flow of air can be bent appropriately without causing bending loss due to. Thereby, according to the propeller fan 100D, a still higher static pressure can be secured. Therefore, according to the propeller fan 100D, the effect of subdividing the vortex serving as the sound source can be sufficiently exerted without lowering the static pressure, so that noise reduction can be realized.

  The propeller fan according to the present invention has been described in four embodiments, but the present invention is not limited to these embodiments, and various modifications or changes can be made without departing from the scope and spirit of the present invention. Further, the propeller fan may be configured by appropriately combining the contents described in each embodiment.

  The propeller fan described in each embodiment is one of refrigeration cycle apparatuses such as an air conditioner (for example, a refrigeration apparatus, a room air conditioner, a packaged air conditioner, a multi air conditioner for buildings), a heat pump water heater, and the like. Used in the cooling unit constituting the part. Specifically, it can be employed as a blower that supplies air to a heat exchanger mounted on a cooling unit.

  1 boss, 2A wing, 2B wing, 2C wing, 2D wing, 21 inner peripheral end, 22 outer peripheral end, 23 front edge, 24 rear edge, 25A notch, 25B notch, 25C notch, 25D notch, 25a first end, 25b 2nd end, 30 notch, 30a notch, 30b notch, 30c notch, 30d notch, 30e notch, 100A propeller fan, 100B propeller fan, 100C propeller fan, 100D propeller fan, 251 Depth, 252 Notch width, 253 sides, 253i inner periphery, 253o outer periphery.

A propeller fan according to the present invention has a boss that rotates about an axis, and a plurality of blades disposed on an outer peripheral portion of the boss, and the blade has a notch at a rear edge, The cutout has three or more triangular cutout portions arranged from the inner peripheral end to the outer peripheral end of the wing, and the notch portion has a depth and a width that are outer peripheral from the inner peripheral end of the wing. The cutout portion is configured so as to become small once it has become large toward the end, and the notch portion has one first end portion formed on the leading edge side of the wing and two second edges formed on the trailing edge side of the wing. a second end, and two sides connecting the second end portion and said first end portion has a, the two sides that have an arc shape protruding toward the outer peripheral end side, respectively .

Claims (6)

A boss that rotates around its axis,
A plurality of wings disposed on the outer periphery of the boss,
The wing
Has a notch in the trailing edge,
The notch is
Having three or more triangular cutout portions arranged from the inner peripheral edge to the outer peripheral edge of the wing;
The notch is
A propeller fan configured such that a depth and a width once increase from an inner peripheral end to an outer peripheral end of the blade and then decrease. The notch is
One first end formed on the leading edge side of the wing;
Two second ends formed on the trailing edge side of the wing;
Two sides connecting the first end and the second end; and
The propeller fan according to claim 1, wherein each of the two sides has an arc shape that is convex toward the outer peripheral end. The notch is
The propeller fan according to claim 2, wherein a radius of curvature of an inner periphery which is one of the two sides is configured to be smaller than a radius of curvature of an outer periphery which is one of the two sides. Rki is a radial position with respect to the axial center of the second end located on the innermost end side,
Rko is a radial position with respect to the axial center of the second end located on the outermost end side,
When the radial position with respect to the axial center of the outer peripheral edge of the blade is Rf,
The notch is
The propeller fan according to claim 2 or 3, wherein the propeller fan is formed at a position satisfying a relationship of Rki / Rf> 0.65 and Rko / Rf <0.95. The notch is
The radius of curvature of the inner periphery of the notch portion is increased in the region where the depth and width of the notch portion are smaller than the reference value, so that the radius and curvature of the notch portion are smaller in the region where the depth and width are larger than the reference value. It is comprised as follows. The propeller fan as described in any one of Claims 2-4. The notch is
The radial position with respect to the axial center of the second end portion on the inner periphery of the notch portion is on the outer peripheral end side than the radial position with respect to the axial center of the first end portion connected to the second end portion on the inner periphery. It is located in Propeller fan as described in any one of Claims 2-5.

Images