JP2010209797A - Cross-flow fan, and air conditioner including the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cross-flow fan and an air conditioner including the same, effectively reducing electric power for driving. <P>SOLUTION: This cross-flow fan includes a rotating impeller composed of curved blades 42. Each of the blades 42 is provided with an outer peripheral edge portion 43 provided on the rotation centrifugal side of the impeller and an inner peripheral edge portion 44 provided on the rotation center side of the impeller. A plurality of dimples 45 transiting a boundary layer from a laminar flow to a turbulent flow are formed in the vacuum surface 4q of the blade 42 in the vicinity of the outer peripheral edge portion 43 along a direction with air flowing on the vacuum surface 4q of the blade 42. The dimples 45c of the plurality of dimples 45, provided apart from the outer peripheral edge portion 43 with the dimples 45 formed in the vicinity thereof, have depth shallower than the dimples 45a, 45b provided near the outer peripheral edge 43 than the dimples 45c. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a cross flow fan and an air conditioner equipped with the same.

  Generally, it is known to use a cross flow fan provided with a rotating impeller as a blower provided in a wall-mounted air conditioner. The impeller is formed by curved wings (blades), and it is known to provide dimples (small depressions) in the vicinity of the outer peripheral edge or inner peripheral edge of the wing (for example, Patent Document 1 and 2).

  Specifically, as shown in FIG. 11, for example, in the vicinity of the outer peripheral side edge portion 143, along the direction in which air flows into the negative pressure surface 104 q of the blade 142 (see arrow X in FIG. 11). A plurality of dimples 145 having the same shape for transitioning the boundary layer from laminar flow to turbulent flow are known. When the dimple 145 is formed in this way, the boundary layer on the suction surface 104q of the blade 142 is changed from laminar flow to turbulent flow, and secondary air flow in the dimple 145 (FIG. 11). The generation of the boundary layer can be suppressed by reducing the shearing force generated at the bottom of the boundary layer.

JP-A-3-210093 JP-A-3-210094

  By the way, energy saving of the cross flow fan is demanded, and when a plurality of dimples as described in Patent Documents 1 and 2 are formed, the power for driving the cross flow fan cannot be reduced. was there. Specifically, as shown in FIG. 11, a secondary air flow is generated in the dimple 145 as described above. There has been a problem that the power for driving cannot be effectively reduced.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a cross flow fan capable of effectively reducing power for driving and an air conditioner including the cross flow fan. .

  The invention according to claim 1 includes a rotating impeller formed by curved blades, and the blades are provided on an outer peripheral side edge provided on the rotating centrifugal side of the impeller and on a rotation center side of the impeller. In the crossflow fan including the inner peripheral edge portion, the boundary layer is disturbed from laminar flow on the suction surface of the blade in the vicinity of at least one of the outer peripheral edge portion and the inner peripheral edge portion. A plurality of dimples to be transitioned to the flow are formed along the air flow direction on the suction surface of the blade, and among the plurality of dimples, the dimple provided apart from one edge portion in the vicinity of the dimple is The dimple has a depth smaller than that of the dimple provided near the one edge.

  According to the same configuration, among the plurality of dimples, the dimple provided apart from one edge portion in the vicinity of the dimple is provided closer to the one edge portion than the dimple. Compared to, it has a small depth. That is, when air flows into the wing from one edge, the depth downstream of the one edge is larger than the depth of the upstream dimple provided near the one edge. The side dimple depth is small. By making the depths of the plurality of dimples different in this way, it is possible to suppress a loss due to a secondary air flow in the downstream dimple having a small effect of suppressing the development of the boundary layer. Therefore, the electric power for driving the cross flow fan can be effectively reduced.

  The invention according to claim 2 includes a rotating impeller formed by curved blades, and the blades are provided on an outer peripheral side edge provided on a rotating centrifugal side of the impeller and on a rotation center side of the impeller. In the cross flow fan comprising the inner peripheral side edge portion, the dimple for transitioning the boundary layer from laminar flow to turbulent flow in the vicinity of at least one of the outer peripheral side edge portion and the inner peripheral side edge portion, A plurality of dimples formed adjacent to each other along the direction of air flow on the suction surface of the blades have a depth from one edge where the dimples are formed in the vicinity to the other edge. It is characterized by becoming shallower.

  According to this configuration, the depth of a plurality of dimples formed along the direction in which air flows on the suction surface of the blade and adjacent to each other is determined from one edge where these dimples are formed in the vicinity. It becomes shallower toward the other edge. For this reason, when air flows into the wing from one edge, it is provided away from the one edge compared to the depth of the upstream dimple provided near the one edge. The depth of the downstream dimple is reduced. By making the depths of the plurality of dimples different in this way, it is possible to suppress a loss due to a secondary air flow in the downstream dimple having a small effect of suppressing the development of the boundary layer. Therefore, the electric power for driving the cross flow fan can be effectively reduced. A plurality of dimples formed along the direction in which the air flows and provided adjacent to each other and becoming shallower from one edge to the other edge are a plurality of dimples provided in the vicinity of the one edge. The dimples may be several dimples, or may be all the dimples constituting a plurality of dimples provided in the vicinity of the one edge.

According to a third aspect of the present invention, the crossflow fan according to the first or second aspect is provided.
According to this configuration, since the cross flow fan according to claim 1 or 2 is provided, the power for driving the cross flow fan can be effectively reduced.

  ADVANTAGE OF THE INVENTION According to this invention, the loss by a secondary air flow can be suppressed and the electric power for driving a crossflow fan can be reduced effectively.

Sectional drawing which shows schematic structure of the air conditioner provided with the crossflow fan which concerns on embodiment of this invention. The perspective view which shows the crossflow fan which concerns on the same embodiment. The perspective view which shows the impeller which concerns on the same embodiment. The perspective view which shows the wing | wing (blade) which concerns on the same embodiment. The figure which shows the suction surface of the wing | blade which concerns on the same embodiment. It is sectional drawing of the wing | blade which shows the dimple which concerns on the same embodiment, Comprising: The figure which shows the cross section of S1-S1 part shown in FIG. Sectional drawing which shows the cross section of the metal mold | die for shape | molding the wing | blade which concerns on the embodiment. The schematic cross section which shows the cross section of the metal mold | die for shape | molding the wing | blade which concerns on the embodiment. Sectional drawing which shows the cross section of the metal mold | die for shape | molding the wing | blade which concerns on the embodiment, and the shape | molded wing | blade. Sectional drawing of the wing | blade which shows the dimple based on the embodiment. Sectional drawing of the wing | blade which shows the conventional dimple.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, an arrow A indicates an axial direction which is a direction parallel to an axis serving as a rotation center of the rotating impeller. In addition, the arrow S indicates the rotating centrifugal side away from the center of rotation of the rotating impeller in the direction perpendicular to the axial direction, and the arrow U indicates the rotating impeller in the direction perpendicular to the axial direction. The center of rotation approaching the center of rotation is shown.

  As shown in FIG. 1, an air conditioner 1 according to this embodiment is a wall-mounted indoor unit, and the air conditioner 1 is disposed in a casing 2 and a casing 2 that are casings of the air conditioner 1. The heat exchanger 3 is configured by a cross flow fan 4 disposed on the downstream side of the heat exchanger 3 in the air flow.

  On the upper side and the front side of the casing 2, an air suction port 21 that is a space into which air is sucked into the casing 2 is provided, and on the front side and the lower side of the casing 2 is a space in which air is blown out of the casing 2. An air outlet 22 is provided. The air outlet 22 is provided with a vertical blade 23 and a horizontal blade 24 in order to adjust the direction of air blown from the air outlet 22.

  Further, in the casing 2, a guide portion 25 for guiding the air blown by the crossflow fan 4 to the front side of the casing 2 and a backflow prevention for preventing the air blown by the crossflow fan 4 from flowing backward. The tongue 26 is formed integrally with the casing 2.

  The heat exchanger 3 includes a front heat exchange portion 3a disposed in the casing 2 above the front side of the cross flow fan 4 and a rear side heat exchange disposed in the casing 2 above the rear side of the cross flow fan 4. It is comprised by the part 3b. The air flowing in from the air suction port 21 passes through the heat exchanger 3 configured as described above to become cooled or heated conditioned air, which is conditioned by the cross flow fan 4 from the air outlet 22. It is blown into the room.

  The cross flow fan 4 includes an impeller 41 having blades (blades) 42, a casing 2 that forms a flow path of air blown by the cross flow fan 4, and an electric motor (not shown) that rotates the impeller 41. It is comprised by. That is, the electric motor drives the cross flow fan 4 by supplying electric power to the electric motor.

  As shown in FIG. 2, the impeller 41 of the crossflow fan 4 includes a large number of blades 42, a support member 4a connected to the end of the blade 42 in the axial direction A and supporting the blades 42, and a support member 4a. The rotating shaft 4b is connected to the output shaft (not shown) of the electric motor. A plurality of blades 42 are provided along the rotational direction of the impeller 41 by providing a plurality of blades 42 at the end of the support member 4a on the rotary centrifugal side. By providing the blades 42 between the support members 4 a, a plurality of blades 42 provided in the axial direction A are provided along the rotation direction of the impeller 41.

  One support member 4a and the blades 42 connected thereto are made of resin. In this embodiment, as shown in FIG. 3, the support member 4a and the blades 42 are integrally injected by a mold. Molded.

  As shown in FIG. 4, the curved wing 42 includes a positive pressure surface (pressure surface) 4 p that is a surface on the rotational direction side where the pressure increases when the impeller 41 in a stationary state rotates, It has a negative pressure surface 4q which is a surface on the side opposite to the rotation direction in which the pressure decreases when the impeller 41 in the rotating state rotates.

  Further, the blade 42 includes an outer peripheral side edge 43 provided close to the rotating centrifugal side of the impeller 41 and an inner peripheral side edge 44 provided close to the rotational center side of the impeller 41. The outer peripheral side edge 43 of the blade 42 is curved in the rotational direction of the impeller 41.

  In the present embodiment, as shown in FIG. 5, in the vicinity of the outer peripheral edge 43, the air flows into the negative pressure surface 4 q of the blade 42 (see arrow X in FIG. 6). A plurality of dimples 45 for transitioning the boundary layer from laminar flow to turbulent flow are formed. FIG. 6 is a cross-sectional view of the S1-S1 portion of FIG.

  As described above, the cross flow fan 4 includes the rotating impeller 41 formed by the curved blades 42, and in the vicinity of the outer peripheral side edge 43 of the blades 42, A plurality of dimples for transitioning the boundary layer from laminar flow to turbulent flow are formed along the direction in which air flows into the blades 42 from the outer peripheral edge 43 (hereinafter referred to as “inflow direction X”). . With such a configuration, the boundary layer on the suction surface 4q of the blade 42 is changed from laminar flow to turbulent flow, and a secondary air flow (see arrow X2 in FIG. 10) is generated in the dimple 45. This can reduce the shearing force generated at the bottom of the boundary layer and suppress the development of the boundary layer. That is, gas separation can be suppressed by the dimple 45.

  Here, in the present embodiment, out of the plurality of dimples 45, the dimple 45c provided apart from the outer peripheral side edge 43 formed in the vicinity of the dimple 45 is an outer peripheral side edge than the dimple 45c. Compared to the dimples 45 a and 45 b provided near the center 43, the depth is smaller. Hereinafter, the dimple 45 according to the present embodiment will be described in detail.

  The dimples 45 are small depressions having a predetermined depth. In the present embodiment, three rows of dimples 45a, 45b, and 45c are formed along the inflow direction X on the suction surface 4q of the blade 42. ing. The plurality of dimples 45a provided in a line along the axial direction A is a dimple 45 provided closest to the outer peripheral edge 43 among the three lines of dimples 45a, 45b, and 45c. A plurality of dimples 45 c provided in a line along the axial direction A are dimples 45 provided on the downstream side of the dimple 45 a in the inflow direction X. The plurality of dimples 45b provided in one row along the axial direction A is a dimple 45 provided between one row of dimples 45a and one row of dimples 45c in a direction perpendicular to the axial direction A. is there.

  As shown in FIG. 6, the depths of the two rows of dimples 45 b and 45 c provided adjacent to each other increase from the outer peripheral side edge 43 formed in the vicinity to the inner peripheral side edge 44. It becomes shallower. That is, the dimple 45c provided on the downstream side of the air flow in the inflow direction X has a smaller depth than the dimples 45a and 45b provided on the upstream side of the air flow in the inflow direction X. . In the present embodiment, the dimple 45a and the dimple 45b have the same depth, and the dimples 45a, 45b, and 45c have the same diameter. In addition, the “dimple depth” here is the maximum depth of the dimple.

  The wings 42 on which the dimples 45 are formed can be formed using, for example, a mold 5 as shown in FIG. More specifically, the mold 5 for forming the blades 42 includes a mold 51 for forming part of the positive pressure surface 4p and the negative pressure surface 4q, and a part of the negative pressure surface 4q on which the dimple 45 is formed. The mold 52 is disposed so as to surround the mold 51. The mold 52 is provided with a protrusion 53 for forming the dimple 45. A resin is injected into a space formed by the mold 51 and the mold 52, and the resin is cured to dimple. Wings 42 formed with 45 are formed. After the wings 42 are formed, each mold 52 is pulled out in the radial direction.

  FIG. 8 is a schematic cross-sectional view of the mold 5, showing a cross section parallel to the axial direction A, that is, a cross section parallel to the longitudinal direction of the blade 42 formed by the mold 5. After the blades 42 are formed, the mold 52 is pulled out in the radial direction, and the mold 51 and the mold 54 covering the end of the blade 42 in the axial direction A are pulled out in the axial directions A1 and A2. It is. That is, the mold 51 surrounded by the mold 52 and covering one end of the blade 42 in the axial direction A is pulled out in the axial direction A1, and the support member 4a is integrated with the ends of the plurality of blades 42. The mold 54 that covers the other end of the blade 42 in the axial direction A so as to be formed is pulled out in the axial direction A2. The molds 51, 52, and 54 are pulled out in this manner, whereby the mold 5 for forming the blades 42 is removed, and a plurality of blades 42 and an impeller 41 formed by these blades 42 are formed. Is done. In addition, the dashed-dotted line in FIG. 8 has shown the axis | shaft used as the center of rotation of the impeller 41. FIG.

  Here, in the present embodiment, the dimple 45c is formed to have a smaller depth than the dimples 45a and 45b provided closer to the outer peripheral side edge 43 than the dimple 45c. A plurality of dimples 45 can be easily formed in the direction X. That is, since the blades 42 are curved, when forming a plurality of blades 42 using one mold 52, the molds 52c are formed to form the dimples 45c when the mold 52 is removed after the blades 42 are formed. When the projection 53 formed on the mold 52 interferes with the wing 42, it is difficult to pull out the mold 52 in the radial direction, and it is difficult to remove the mold 5 from the wing 42. Therefore, the dimple 45c provided on the rotation center side of the impeller 41 is formed so as to have a smaller depth than the dimples 45a and 45b provided on the rotation centrifugal side of the impeller 41. The protrusion 53 of the mold 52 provided to form the center-side dimple 45 c can be prevented from interfering with the blade 42 when the mold 5 is removed. That is, as shown in FIG. 9 which is an enlarged view of the portion S2 indicated by the alternate long and short dash line in FIG. 7, the resin is injected into the space formed by the mold 51 and the mold 52 and the blades 42 are formed. Even if it exists, the metal mold | die 52 can be pulled out to radial direction.

  In the present embodiment, in the injection molding of the blades 42 made of resin, a large number of blades 42 constituting the impeller 41 and the support member 4a are formed by injection molding. That is, when the blades 42 are formed, the support members 4a are integrally formed at the end portions in the axial direction A of the blades 42 and the blades 42 provided along the rotation direction. The process can be simplified.

  When the dimple 45 is formed on the suction surface 4q of the blade 42 as described above, the secondary flow generated in the dimple 45c provided on the downstream side of the air flow is suppressed as shown in FIG. Is done. The dimple 45c provided on the downstream side of the air flow has a smaller effect of suppressing the development of the boundary layer than the dimples 45a and 45b provided on the upstream side of the air flow. The effect of suppressing the peeling is maintained.

  In the present embodiment, the depth of the dimple 45b is the same as the depth of the dimple 45a. However, the depth of the dimple 45b is made smaller than the depth of the dimple 45a and compared with the depth of the dimple 45c. You may enlarge it. That is, in the present embodiment, the plurality of dimples that become shallower from the outer peripheral side edge 43 toward the inner peripheral side edge 44 are several dimples 45 that are provided in the vicinity of the outer peripheral side edge 43. The dimples 45b and 45c may be all the dimples 45a, 45b and 45c constituting the plurality of dimples 45 provided in the vicinity of the outer peripheral side edge 43.

According to the cross flow fan 4 of the present embodiment, the following effects can be obtained.
(1) The plurality of dimples 45 b and 45 c provided adjacent to each other become shallower from the outer peripheral side edge 43 toward the inner peripheral side edge 44. That is, when air flows into the blades 42 from the outer peripheral edge 43, the distance from the outer peripheral edge 43 is larger than the depth of the upstream dimples 45 a and 45 b provided near the outer peripheral edge 43. The depth of the downstream dimple 45c provided is small. By making the depths of the plurality of dimples 45 different in this way, loss due to secondary air flow can be suppressed in the downstream dimple 45c that has a small effect of suppressing the development of the boundary layer. . Therefore, the power for driving the cross flow fan 4 can be effectively reduced.

  (2) The dimple 45c on the rotation center side of the suction surface 4q of the blade 42 is smaller than the dimples 45a and 45b on the rotary centrifugal side than the dimple 45c. For this reason, it is possible to prevent the projection 53 provided on the mold 52 to form the dimple 45 c on the rotation center side from interfering with the blade 42 when the mold 5 is removed. As a result, the mold 5 for forming the blades 42 can be easily removed, and a plurality of dimples 45 can be easily formed in the inflow direction X using the mold 5.

  Moreover, in the manufacturing process of the wing | blade 42 which concerns on this embodiment, the support member 4a is integrally formed in the edge part of the axial direction A of the some wing | blade 42 provided along the rotation direction. For this reason, the manufacturing process of the impeller 41 can be simplified.

  Moreover, since the air conditioner 1 which concerns on this embodiment is equipped with the crossflow fan 4 which can acquire the effect of said (1), (2), the effect according to said (1), (2). Can be obtained.

  In addition, this invention is not limited to the said embodiment, A various design change is possible based on the meaning of this invention, and they are not excluded from the scope of the present invention. For example, you may change the said embodiment as follows.

  In the above embodiment, the dimple 45 is formed in the vicinity of the outer peripheral side edge 43 of the blade 42, but the dimple 45 may be formed in the vicinity of the inner peripheral side edge 44 of the blade 42.

  In addition, dimples 45 may be formed in the vicinity of both the outer peripheral edge 43 and the inner peripheral edge 44 of the blade 42. That is, the dimple 45 may be formed in the vicinity of at least one of the outer peripheral edge 43 and the inner peripheral edge 44.

  When the dimple 45 is formed in the vicinity of both the outer peripheral side edge 43 and the inner peripheral side edge 44 of the blade 42, the direction in which air flows into the blade 42 is the blowing side M and the suction side N. (See FIG. 1). Therefore, the dimples provided in the vicinity of the outer peripheral side edge portion 43 and the dimples provided in the vicinity of the inner peripheral side edge portion 44 may be configured to become shallower in different directions.

  DESCRIPTION OF SYMBOLS 1 ... Air conditioner, 2 ... Casing, 3 ... Heat exchanger, 3a ... Front side heat exchange part, 3b ... Rear side heat exchange part, 4 ... Cross flow fan, 4a ... Support member, 4b ... Rotating shaft, 4p ... Positive Pressure surface, 4q ... Negative pressure surface, 5 ... Mold, 41 ... Impeller, 42 ... Blade (blade), 43 ... Outer edge, 44 ... Inner edge, 45, 45a, 45b, 45c ... Dimple, 51 52, 54 ... mold, 53 ... projection.

Claims (3)

The blade includes a rotating impeller formed by curved blades, and the blade includes an outer peripheral side edge provided on a rotating centrifugal side of the impeller and an inner peripheral side edge provided on a rotation center side of the impeller. In the cross flow fan comprising a part,
In the vicinity of at least one of the outer peripheral side edge and the inner peripheral side edge, a dimple for causing the boundary layer to transition from laminar flow to turbulent flow is provided on the suction surface of the blade. Are formed along the direction in which air flows in
Among the plurality of dimples, the dimple provided apart from the one edge where the dimple is formed in the vicinity is more than the dimple provided near the one edge than the dimple. The cross flow fan is characterized by having a small depth. The blade includes a rotating impeller formed by curved blades, and the blade includes an outer peripheral side edge provided on a rotating centrifugal side of the impeller and an inner peripheral side edge provided on a rotation center side of the impeller. In the cross flow fan comprising a part,
In the vicinity of at least one of the outer peripheral side edge and the inner peripheral side edge, a dimple for causing the boundary layer to transition from laminar flow to turbulent flow is provided on the suction surface of the blade. Are formed along the direction in which air flows in
The cross flow fan, wherein a plurality of the dimples provided adjacent to each other has a depth that decreases from the one edge portion in the vicinity of the dimple toward the other edge portion.   An air conditioner comprising the crossflow fan according to claim 1.

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