JP5320435B2 - Cross-flow fan, molding die and fluid feeder - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cross-flow fan exhibiting excellent air blowing capacity, a molding die used for manufacturing the cross-flow fan, and a fluid feeding device including the cross-flow fan. <P>SOLUTION: The cross-flow fan includes a plurality of fan blades 21 arranged at intervals with each other in a circumferential direction. Each fan blade 21 has an inner edge 26 where air inflows and outflows, which is provided on an inner peripheral side and an outer edge 27 where air inflows and outflows, which is provided on an outer peripheral side. The fan blade 21 includes a wing surface 23 extending between the inner edge 26 and the outer edge 27. The wing surface 23 consists of a positive pressure surface 25 arranged on the rotating direction side of the cross-flow fan and a negative pressure surface 24 arranged on the back side of the positive pressure surface 25. The fan blade 21 has a blade cross-sectional shape with recessed portions 57, 56 formed on the positive pressure surface 25 and negative pressure surface 24 when the fan blade is cut by a plane orthogonal to the rotating shaft of the cross-flow fan. The positive pressure surface 25 has a plurality of recessed portions 57 (57p, 57q). <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention generally relates to a cross-flow fan, a molding die, and a fluid feeding device, and more specifically, to a cross-flow fan used in an air conditioner, an air purifier, and the like, and to the manufacture of the cross-flow fan. The present invention relates to a molding die and a fluid feeder including the cross-flow fan.

  Regarding conventional cross-flow fans, for example, Japanese Patent Application Laid-Open No. 2007-21352 discloses an air cleaner that aims to reduce the installation area and increase the blowing capacity (Patent Document 1). In the air cleaner disclosed in Patent Document 1, a vertically long crossflow fan driven by a motor is disposed in a main body having an air inlet and an air outlet at left and right ends, respectively.

JP 2007-21352 A

  In recent years, in order to preserve the global environment, further energy saving is required for household electrical equipment. For example, it is known that the efficiency of an electric device such as an air conditioner (air conditioner) or an air cleaner greatly depends on the efficiency of a blower included therein. Further, by reducing the weight of the fan blade provided in the blower as a rotating object, the power consumption of the motor for rotationally driving the fan blade can be reduced, and the efficiency as the blower or the fluid feeder can be improved. Are known.

  However, the aerofoil adopted as the cross-sectional shape of the fan blade is supposed to be applied to the wing of an aircraft in the first place, and has been mainly found in the field of aeronautical engineering. For this reason, airfoil fan blades are optimized primarily in the high Reynolds number region, and are not necessarily suitable for the cross section of fan blades used in low Reynolds number regions such as home air conditioners and air purifiers. I can't say that.

  Further, when a blade shape or a double arc is adopted as the cross-sectional shape of the fan blade, the thick portion exists in a range of 30 to 50% from the front edge of the fan blade. For this reason, the weight of the fan blade is increased, which causes an increase in friction loss during rotation. However, simply reducing the weight of the fan blades may reduce the strength of the fan blades and cause cracks and other quality defects.

  For these reasons, blade cross sections suitable as fan blades used in a low Reynolds number region are required for energy saving of electric devices such as home air conditioners and air purifiers. Further, there is a demand for a blade cross-sectional shape that has a high lift-drag ratio, is thin and light, and has high strength.

  As a fan used for a blower, there is a cross-flow fan (cross flow fan) that forms a flat blowout flow parallel to the rotation axis of the fan. A typical example of the use of the cross-flow fan is an air conditioner. While further energy saving is required for household electric appliances, low power consumption of air conditioners has a high priority. In order to reduce the power consumption of this air conditioner, there is a demand for increasing the air volume. When the air volume is increased, the performance of evaporation and condensation of the heat exchanger increases, and the power consumption of the compressor can be reduced correspondingly. However, if the airflow is increased, the power consumption of the fan increases. Therefore, the difference between the reduced power consumption of the compressor and the increased power consumption of the fan is the reduced power consumption. It is not possible to obtain the maximum effect. Further, when the rotational speed is increased with the same fan as means for increasing the air volume of the fan, the noise of the air conditioner increases.

  Moreover, the air cleaner is mentioned as another example of the use of a cross-flow fan. The requirements for air cleaners include an increase in dust collection capacity, that is, an increase in air volume and a reduction in noise, but there is a trade-off between these two.

  In order to satisfy both of these requirements, not only the noise from the air inlet and outlet of the air cleaner must be reduced, but also the noise of the once-through fan that sends out air must be fundamentally reduced. Further, in order to increase the air volume, it is necessary to increase the rotational speed of the cross-flow fan. In order to increase the rotational speed of the once-through fan, it is necessary to reduce the input to the fan. In addition, it is necessary to increase the strength of the fan blades to overcome the increase in centrifugal force that occurs as the rotational speed of the once-through fan increases.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to solve the above-described problems, and provide a cross-flow fan that exhibits excellent air blowing capability, a mold for use in manufacturing the cross-flow fan, and a fluid feed device including the cross-flow fan. It is to be.

  The cross-flow fan according to the present invention includes a plurality of blade portions provided at intervals in the circumferential direction. The blade portion is arranged on the inner peripheral side and has an inner edge portion through which air flows in and out and an outer edge portion arranged on the outer peripheral side and through which air flows in and out. The blade portion is formed with a blade surface that extends between the inner edge portion and the outer edge portion. The blade surface includes a pressure surface arranged on the side of the cross-flow fan in the rotation direction and a suction surface arranged on the back side of the pressure surface. The blade portion has a blade cross-sectional shape in which concave portions are formed on the pressure surface and the suction surface when cut by a plane orthogonal to the rotation axis of the once-through fan. A plurality of recesses are formed on at least one of the pressure surface and the suction surface. The number of recesses formed on the pressure surface is greater than the number of recesses formed on the suction surface.

  According to the cross-flow fan configured in this way, when the cross-flow fan rotates, air flows in from the outer edge, passes through the blade surface, flows out from the inner edge, flows in from the inner edge, and passes through the blade surface. The air flow flowing out from the outer edge portion is alternately generated in each blade portion. At this time, a vortex (secondary flow) of the air flow is generated in the recess, so that the air flow (main flow) passing through the blade surface flows along the outside of the vortex generated in the recess. As a result, the blade portion behaves like a thick blade whose blade cross-sectional shape is thickened by the amount of vortex formation. As a result, the blowing capacity of the once-through fan can be improved.

  Also preferably, the recess has a groove cross section extending along the rotation axis of the cross-flow fan. The side surfaces of the groove cross section are formed so as to rise on both sides from the point where the depth of the recess becomes the largest. Preferably, the blade portion has a bent portion in which a center line of a blade cross-sectional shape extending between the inner edge portion and the outer edge portion is bent at a plurality of locations. The concave portion is formed by a bent portion. According to the cross-flow fan configured as described above, since the vortex of the air flow is generated in the concave portion formed by the bent portion, the blowing ability of the cross-flow fan can be improved.

  Preferably, the bent portion is bent at at least one place so that the depth of the concave portion is larger than the thickness of the blade portion. According to the cross-flow fan configured as described above, the vortex of the air flow can be more reliably generated in the recess.

  Preferably, the recess is formed in the vicinity of the inner edge and the outer edge. According to the cross-flow fan configured as described above, the above-described effect due to the concave portion is generated in the vicinity of the inner edge portion and the outer edge portion, and high lift force can be generated. Further, the formation of the bent portion can improve the strength of the blade portion in the vicinity of the inner edge portion.

  Preferably, the concave portion is formed in the blade central portion between the inner edge portion and the outer edge portion. According to the once-through fan configured as described above, the above-described effect due to the concave portion is generated in the blade central portion, and the blade portion can exhibit a stable ability as a blade. Further, the formation of the bent portion can improve the strength of the blade portion at the blade center portion.

  Preferably, the recess is formed so as to repeatedly appear on the pressure surface and the suction surface in a direction connecting the inner edge portion and the outer edge portion. According to the cross-flow fan configured as described above, since the vortex of the air flow is generated in the concave portion that repeatedly appears on the pressure surface and the suction surface, the blowing ability of the cross-flow fan can be improved more effectively.

  Preferably, the concave portion formed on the pressure surface constitutes a convex portion on the negative pressure surface, and the concave portion formed on the negative pressure surface constitutes a convex portion on the pressure surface. According to the cross-flow fan configured as described above, it is possible to easily obtain a blade cross-sectional shape in which a concave portion is formed on the pressure surface and the suction surface.

  Preferably, in the blade cross-sectional shape, the concave portion is formed between the convex portions appearing on the blade surface. The concave portions and the convex portions are formed alternately in the direction connecting the inner edge portion and the outer edge portion. According to the once-through fan configured as described above, since the vortex of the air flow is generated in the concave portion formed between the convex portions, the air blowing capability can be improved more effectively.

  Preferably, the blade portion has a blade cross-sectional shape having a substantially constant thickness between the inner edge portion and the outer edge portion. According to the once-through fan configured as described above, even when a blade portion having a blade cross-sectional shape with a substantially constant thickness is used, the blowing capacity can be improved.

  Preferably, the once-through fan is formed of a resin. According to the cross-flow fan configured as described above, a light and high-strength resin cross-flow fan can be realized.

  The molding die according to the present invention is used for molding the cross-flow fan described above. According to the molding die configured as described above, a lightweight and high-strength resin cross-flow fan can be manufactured.

  A fluid feeder according to the present invention includes a blower including any of the cross-flow fans described above and a drive motor that is coupled to the cross-flow fan and rotates a plurality of blade portions. According to the fluid feeder configured in this way, it is possible to reduce the power consumption of the drive motor while maintaining a high blowing capacity.

  As described above, according to the present invention, it is possible to provide a cross-flow fan that exhibits excellent blowing capacity, a mold for use in manufacturing the cross-flow fan, and a fluid feed device including the cross-flow fan. .

It is a side view which shows the cross-flow fan in Embodiment 1 of this invention. It is a cross-sectional perspective view which shows the cross-flow fan along the II-II line | wire in FIG. It is sectional drawing which shows the fan blade provided in the once-through fan in FIG. It is sectional drawing which shows the air conditioner in which the cross-flow fan shown in FIG. 1 is used. It is sectional drawing which expands and shows the blower outlet vicinity of the air conditioner in FIG. It is sectional drawing which shows the air flow produced in the blower outlet vicinity of the air conditioner in FIG. FIG. 6 is a cross-sectional view showing a phenomenon that occurs on the blade surface of the fan blade in the upstream region shown in FIG. 5. It is the figure which represented typically the fan blade shown in FIG. FIG. 6 is a cross-sectional view showing a phenomenon that occurs on the blade surface of the fan blade in the downstream region shown in FIG. 5. FIG. 10 is a diagram schematically showing the fan blade shown in FIG. 9. It is sectional drawing which shows the 1st modification of the once-through fan in FIG. It is sectional drawing which shows the 2nd modification of the once-through fan in FIG. It is sectional drawing which shows the 3rd modification of the once-through fan in FIG. It is sectional drawing which shows the metal mold | die for a molding used at the time of manufacture of the once-through fan in FIG. In a present Example, it is a graph which shows the relationship between the air volume of a crossflow fan, and the power consumption of the motor for a drive. In a present Example, it is a graph which shows the relationship between the air volume of a once-through fan, and a noise value. In a present Example, it is a graph which shows the pressure flow characteristic of a cross-flow fan.

  Embodiments of the present invention will be described with reference to the drawings. In the drawings referred to below, the same or corresponding members are denoted by the same reference numerals.

(Embodiment 1)
1 is a side view showing a cross-flow fan according to Embodiment 1 of the present invention. FIG. 2 is a cross-sectional perspective view showing the cross-flow fan along the line II-II in FIG.

  Referring to FIGS. 1 and 2, cross-flow fan (cross flow fan) 10 in the present embodiment has a plurality of fan blades 21. Cross-flow fan 10 has a substantially cylindrical appearance as a whole, and a plurality of fan blades 21 are arranged on the side surface of the substantially cylindrical shape. Cross-flow fan 10 is integrally formed of resin. Cross-flow fan 10 rotates in the direction indicated by arrow 103 about a virtual center axis 101 shown in the figure.

  The cross-flow fan 10 is a fan that blows air in a direction orthogonal to the central axis 101 that is a rotation axis by a plurality of rotating fan blades 21. The cross-flow fan 10 takes air from the outer space on one side with respect to the central shaft 101 into the inner space of the fan when viewed from the axial direction of the central shaft 101, and further takes the taken air into the central shaft 101. This is a fan sent out to the outer space on the other side. Cross-flow fan 10 forms an air flow that flows in a direction intersecting center axis 101 in a plane orthogonal to center axis 101. Cross-flow fan 10 forms a planar blow-out flow parallel to central axis 101.

  The cross-flow fan 10 is used at a rotational speed in a low-lay nozzle number region applied to a fan such as a household electric device.

  Cross-flow fan 10 is configured by combining a plurality of impellers 12 arranged in the axial direction of central shaft 101. In each impeller 12, the plurality of fan blades 21 are provided at intervals in the circumferential direction around the central axis 101.

  Cross-flow fan 10 further includes an outer peripheral frame 13 as a support portion. The outer peripheral frame 13 has a ring shape extending annularly around the central axis 101. The outer peripheral frame 13 has an end surface 13a and an end surface 13b. The end surface 13 a is formed so as to face one direction along the axial direction of the central axis 101. The end surface 13 b is disposed on the back side of the end surface 13 a and is formed to face the other direction along the axial direction of the central axis 101.

  The outer peripheral frame 13 is provided between the adjacent impellers 12 in the axial direction of the central shaft 101.

  When attention is paid to the impeller 12A and the impeller 12B in FIG. 1 arranged adjacent to each other, a plurality of fan blades 21 provided in the impeller 12A are erected on the end surface 13a and extend in the axial direction of the central shaft 101. It is formed so as to extend in a plate shape along. The plurality of fan blades 21 provided in the impeller 12 </ b> B are erected on the end surface 13 b and are formed to extend in a plate shape along the axial direction of the central shaft 101.

  The plurality of fan blades 21 have the same shape. In the present embodiment, the plurality of fan blades 21 are arranged at a random pitch in the circumferential direction around the central axis 101.

  The fan blade 21 has an inner edge portion 26 and an outer edge portion 27. The inner edge portion 26 is disposed at an end portion on the inner peripheral side of the fan blade 21. The outer edge portion 27 is disposed at the outer peripheral end of the fan blade 21. The fan blade 21 is formed to be inclined in the circumferential direction about the central axis 101 from the inner edge portion 26 toward the outer edge portion 27. The fan blade 21 is formed to be inclined in the rotational direction of the cross-flow fan 10 from the inner edge portion 26 toward the outer edge portion 27.

  The fan blade 21 is formed with a blade surface 23 including a positive pressure surface 25 and a negative pressure surface 24. The positive pressure surface 25 is disposed on the rotational direction side of the cross-flow fan 10, and the negative pressure surface 24 is disposed on the back side of the positive pressure surface 25. When the cross-flow fan 10 rotates, a pressure distribution that is relatively large on the positive pressure surface 25 and relatively small on the negative pressure surface 24 is generated as an air flow is generated on the blade surface 23. The fan blade 21 has a generally curved shape between the inner edge portion 26 and the outer edge portion 27 so that the positive pressure surface 25 side is concave and the negative pressure surface 24 side is convex.

  FIG. 3 is a cross-sectional view showing a fan blade provided in the cross-flow fan in FIG. FIG. 3 shows the blade cross-sectional shape of the fan blade 21 when cut along a plane orthogonal to the central axis 101 that is the rotation axis of the cross-flow fan 10.

  Referring to FIGS. 1 to 3, fan blade 21 is formed to have the same blade cross-sectional shape even if it is cut at any position in the axial direction of central shaft 101. The fan blade 21 is formed to have a thin blade cross-sectional shape. The fan blade 21 is formed to have a substantially constant thickness (the length between the positive pressure surface 25 and the negative pressure surface 24) between the inner edge portion 26 and the outer edge portion 27.

  The fan blade 21 has a blade cross-sectional shape in which a recess 57 is formed on the pressure surface 25 of the blade surface 23 and a recess 56 is formed on the suction surface 24 of the blade surface 23. A plurality of concave portions 56 and 57 are formed on at least one of the positive pressure surface 25 and the negative pressure surface 24.

  In the present embodiment, a plurality of recesses 57 (recesses 57p and 57q) are formed on the positive pressure surface 25. On the positive pressure surface 25, convex portions 52 (52p, 52q, 52r) are further formed. The convex portion 52 is formed so as to protrude in the rotational direction of the cross-flow fan 10. A concave portion 57 is formed by a valley portion between the convex portions 52 arranged adjacent to each other. For example, a concave portion 57p is formed by a valley portion between the convex portion 52p and the convex portion 52q. The concave portions 57 and the convex portions 52 are formed alternately in the direction connecting the inner edge portion 26 and the outer edge portion 27. The recess 57 has a substantially U-shaped cross-sectional shape.

  A plurality of convex portions 51 (convex portions 51p, 51q) are further formed on the negative pressure surface 24. The convex portion 51 is formed so as to protrude in a direction opposite to the rotation direction of the cross-flow fan 10. A concave portion 56 is formed by the valley portion between the convex portions 51 arranged adjacent to each other. In the present embodiment, the concave portion 56 is formed by the valley portion between the convex portion 51p and the convex portion 51q. Yes. The concave portions 56 and the convex portions 51 are formed alternately in the direction connecting the inner edge portion 26 and the outer edge portion 27. The recess 56 has a substantially U-shaped cross-sectional shape.

  The concave portion 57 and the convex portion 51 are formed at positions corresponding to the front and back surfaces of the positive pressure surface 25 and the negative pressure surface 24, respectively, and the convex portion 52 and the concave portion 56 are positions corresponding to the front and back surfaces of the positive pressure surface 25 and the negative pressure surface 24, respectively. Is formed. In the present embodiment, the concave portion 57 formed on the positive pressure surface 25 constitutes the convex portion 51 on the negative pressure surface 24, and the concave portion 56 formed on the negative pressure surface 24 constitutes the convex portion 52 on the positive pressure surface 25. The concave and convex portions formed on the positive pressure surface 25 and the negative pressure surface 24 corresponding to the front and back surfaces have the same cross-sectional shape.

  The recesses 57 and 56 have a groove shape extending along the axial direction of the central shaft 101. The groove portion including the recesses 57 and 56 is formed to extend continuously between one end and the other end of the fan blade 21 in the axial direction of the central shaft 101. A groove portion composed of the concave portions 57 and 56 is formed to extend linearly between one end and the other end of the fan blade 21 in the axial direction of the central shaft 101.

  In the present embodiment, the number of the recesses 57 formed on the pressure surface 25 is larger than the number of the recesses 56 formed on the suction surface 24.

  In FIG. 3, a center line 106 in the thickness direction (direction connecting the pressure surface 25 and the suction surface 24) of the blade cross-sectional shape of the fan blade 21 is shown. The fan blade 21 has a bent portion 41 where a center line 106 of the blade blade cross-sectional shape of the fan blade 21 is bent at a plurality of locations between the inner edge portion 26 and the outer edge portion 27. The concave portions 56 and 57 are formed by the bent portion 41.

  In the present embodiment, the fan blade 21 has bent portions 41 at three positions between the inner edge portion 26 and the outer edge portion 27. The fan blade 21 has a bent portion 41 </ b> A disposed in the vicinity of the inner edge portion 26 and the outer edge portion 27, and a bent portion 41 </ b> B disposed in the blade central portion between the inner edge portion 26 and the outer edge portion 27. The bent portion 41 </ b> A has a concave portion 57 formed on the positive pressure surface 25 and a convex portion 51 formed on the negative pressure surface 24. The bent portion 41 </ b> B has a convex portion 52 formed on the positive pressure surface 25 and a concave portion 56 formed on the negative pressure surface 24.

  With such a configuration, the concave portion 57 is formed in the vicinity of the inner edge portion 26 and the outer edge portion 27, and the concave portion 56 is further formed in the blade central portion between the inner edge portion 26 and the outer edge portion 27. The fan blade 21 has a substantially W-shaped blade cross-sectional shape.

  The bent portion 41 is bent at at least one location so that the depth T of the concave portions 56 and 57 is larger than the thickness t of the fan blade 21. The bent portions 41 are formed so that the folding directions are alternately opposite to each other in the direction connecting the inner edge portion 26 and the outer edge portion 27. The bent portion 41 is formed to be bent so as to be rounded. The bent portion 41 may be formed to be bent so as to form a corner portion.

  The structure of the cross-flow fan 10 according to the first embodiment of the present invention described above will be described together. The cross-flow fan 10 according to the present embodiment is a plurality of blade portions provided at intervals in the circumferential direction. A fan blade 21 is provided. The fan blade 21 is arranged on the inner peripheral side and has an inner edge portion 26 through which air flows in and out, and an outer edge portion 27 arranged on the outer peripheral side and through which air flows in and out. The fan blade 21 is formed with a blade surface 23 extending between the inner edge portion 26 and the outer edge portion 27. The blade surface 23 includes a positive pressure surface 25 disposed on the side of the cross flow fan 10 in the rotational direction and a negative pressure surface 24 disposed on the back side of the positive pressure surface 25. The fan blade 21 has a blade cross-sectional shape in which concave portions 57 and 56 are formed in the positive pressure surface 25 and the negative pressure surface 24 when the fan blade 21 is cut by a plane orthogonal to the central axis 101 as the rotation axis of the once-through fan 10. A plurality of recesses 57 (57p, 57q) are formed on the pressure surface 25 as at least one of the pressure surface 25 and the suction surface 24.

  Next, the structure of an air conditioner (air conditioner) in which the cross-flow fan 10 in FIG. 1 is used will be described.

  FIG. 4 is a cross-sectional view showing an air conditioner in which the cross-flow fan shown in FIG. 1 is used. Referring to FIG. 4, an air conditioner 110 is installed indoors and is provided with an indoor unit 120 provided with an indoor heat exchanger 129, and installed outdoors and provided with an outdoor heat exchanger and a compressor (not shown). It consists of an outdoor unit. The indoor unit 120 and the outdoor unit are connected by piping for circulating the refrigerant gas between the indoor side heat exchanger 129 and the outdoor side heat exchanger.

  The indoor unit 120 has a blower 115. The blower 115 includes a cross-flow fan 10, a drive motor (not shown) for rotating the cross-flow fan 10, and a casing 122 for generating a predetermined airflow as the cross-flow fan 10 rotates.

  The casing 122 has a cabinet 122A and a front panel 122B. The cabinet 122A is supported by a wall surface in the room, and the front panel 122B is detachably attached to the cabinet 122A. A blowout port 125 is formed in the gap between the lower end portion of the front panel 122B and the lower end portion of the cabinet 122A. The air outlet 125 is formed in a substantially rectangular shape extending in the width direction of the indoor unit 120 and is provided facing the front lower side. A lattice-shaped suction port 124 is formed on the upper surface of the front panel 122B.

  An air filter 128 that collects and removes dust contained in the air sucked from the suction port 124 is provided at a position facing the front panel 122B. In a space formed between the front panel 122B and the air filter 128, an air filter cleaning device (not shown) is provided. The dust accumulated in the air filter 128 is automatically removed by the air filter cleaning device.

  Inside the casing 122, an air passage 126 through which air flows from the suction port 124 toward the blowout port 125 is formed. The outlet 125 is provided with a vertical louver 132 that can change the outlet angle in the left-right direction, and a plurality of horizontal louvers 131 that can change the outlet angle in the up-down direction in the front upper direction, the horizontal direction, the front lower direction, and the direct lower direction. It has been.

  An indoor heat exchanger 129 is disposed between the cross-flow fan 10 and the air filter 128 on the air passage 126. The indoor heat exchanger 129 has meandering refrigerant pipes (not shown) that are arranged in a plurality of stages in the vertical direction and in a plurality of rows in the front-rear direction. The indoor heat exchanger 129 is connected to a compressor of an outdoor unit installed outdoors, and the refrigeration cycle is operated by driving the compressor. Due to the operation of the refrigeration cycle, the indoor heat exchanger 129 is cooled to a temperature lower than the ambient temperature during the cooling operation, and the indoor heat exchanger 129 is heated to a temperature higher than the ambient temperature during the heating operation.

  FIG. 5 is an enlarged cross-sectional view showing the vicinity of the outlet of the air conditioner in FIG. With reference to FIGS. 4 and 5, casing 122 has a front wall portion 151 and a rear wall portion 152. The front wall portion 151 and the rear wall portion 152 are disposed to face each other with a space therebetween.

  On the path of the air passage 126, the cross-flow fan 10 is disposed so as to be positioned between the front wall portion 151 and the rear wall portion 152. The front wall portion 151 is formed with a protruding portion 153 that protrudes toward the outer peripheral surface of the cross-flow fan 10 and makes the gap between the cross-flow fan 10 and the front wall portion 151 minute. The rear wall 152 is formed with a protrusion 154 that protrudes toward the outer peripheral surface of the cross-flow fan 10 and makes the gap between the cross-flow fan 10 and the rear wall 152 minute.

  The casing 122 has an upper guide part 156 and a lower guide part 157. The air passage 126 is defined by the upper guide portion 156 and the lower guide portion 157 on the downstream side of the air flow from the cross-flow fan 10.

  The upper guide portion 156 and the lower guide portion 157 are continuous from the front wall portion 151 and the rear wall portion 152, respectively, and extend toward the blowout port 125. The upper guide portion 156 and the lower guide portion 157 curve the air sent out by the cross-flow fan 10 so that the upper guide portion 156 is on the inner peripheral side and the lower guide portion 157 is on the outer peripheral side, and forward and downward. It is formed to guide. The upper guide portion 156 and the lower guide portion 157 are formed so that the cross-sectional area of the air passage 126 increases as it goes from the cross-flow fan 10 toward the outlet 125.

  In the present embodiment, the front wall portion 151 and the upper guide portion 156 are formed integrally with the front panel 122B. A rear wall portion 152 and a lower guide portion 157 are formed integrally with the cabinet 122A.

  FIG. 6 is a cross-sectional view showing the air flow generated in the vicinity of the air outlet of the air conditioner in FIG. Referring to FIGS. 5 and 6, an upstream outer space 146 is formed on the upstream side of the cross-flow fan 10 on the path on the air passage 126, and an inner side (circumference) of the cross-flow fan 10 is formed. An inner space 147 is formed on the inner peripheral side of the plurality of fan blades 21 arranged in the direction, and a downstream outer space 148 is formed on the downstream side of the cross-flow fan 10 in the air flow. .

  When the cross-flow fan 10 is rotated, air flowing from the upstream outer space 146 to the inner space 147 through the blade surface 23 of the fan blade 21 in the upstream region 141 of the air passage 126 with the protrusions 153 and 154 as a boundary. A flow 161 is formed, and air flows from the inner space 147 through the blade surface 23 of the fan blade 21 toward the downstream outer space 148 in the downstream region 142 of the air passage 126 with the protrusions 153 and 154 as boundaries. 161 is formed. At this time, an air flow vortex 162 is formed at a position adjacent to the front wall portion 151.

  FIG. 7 is a cross-sectional view showing a phenomenon that occurs on the blade surface of the fan blade in the upstream region shown in FIG. FIG. 8 is a diagram schematically showing the fan blade shown in FIG.

  7 and 8, in the upstream region 141, when an air flow from the upstream outer space 146 toward the inner space 147 is formed, the air flows from the outer edge portion 27 on the blade surface 23 of the fan blade 21. Then, an air flow that passes over the blade surface 23 and flows out from the inner edge portion 26 is generated. At this time, a clockwise air flow vortex 63 (secondary flow) is formed in the concave portion 57 formed in the positive pressure surface 25, and a counterclockwise air flow is formed in the concave portion 56 formed in the negative pressure surface 24. Vortex 62 is generated. As a result, the air flow 61 (main flow) passing over the blade surface 23 flows along the outside of the vortices 63 and 62 generated in the recesses 57 and 56.

  FIG. 9 is a cross-sectional view showing a phenomenon that occurs on the blade surface of the fan blade in the downstream region shown in FIG. FIG. 10 is a diagram schematically showing the fan blade shown in FIG.

  Referring to FIGS. 9 and 10, when an air flow from the inner space 147 toward the downstream outer space 148 is formed in the downstream region 142, the air flows from the inner edge portion 26 on the blade surface 23 of the fan blade 21. Then, an air flow that passes over the blade surface 23 and flows out from the outer edge portion 27 is generated. At this time, a counterclockwise air flow vortex 68 (secondary flow) is formed in the concave portion 57 formed in the positive pressure surface 25, and a clockwise air flow is formed in the concave portion 56 formed in the negative pressure surface 24. Vortex 67 is generated. Thereby, the air flow 66 (main flow) passing over the blade surface 23 flows along the outside of the vortices 68 and 67 generated in the recesses 57 and 56.

  That is, in the once-through fan 10, when the fan blade 21 moves from the upstream region 141 to the downstream region 142, the air flow direction on the blade surface 23 is reversed, and accordingly, vortices generated in the recesses 57 and 56. The direction of rotation is also reversed.

  In cross-flow fan 10 according to the present embodiment, although fan blade 21 has a thin blade cross-sectional shape, the blade cross-section is equal to the depth of recesses 57 and 56 in which vortices (secondary flow) are formed. It behaves like a thick wing with a thickened shape. As a result, the lift generated by the fan blade 21 can be greatly increased. Further, the strength of the fan blade 21 can be improved by the bent structure by the bent portion 41. As a result, the reliability with respect to the strength of the cross-flow fan 10 can be improved.

  Further, in cross-flow fan 10 according to the present embodiment, recess 56 is formed in the blade central portion between inner edge portion 26 and outer edge portion 27. With such a configuration, it is possible to further obtain an effect of suppressing the separation of the airflow generated at the blade central portion. Thereby, the broadband noise which generate | occur | produces in the once-through fan 10 can be suppressed effectively.

  According to the cross-flow fan 10 according to the first embodiment of the present invention configured as described above, the lift force generated by the rotation of the fan blade 21 in the low lay nozzle number region applied to a fan such as a home electric appliance. Can be greatly increased. Thereby, the power consumption for driving the cross-flow fan 10 can be reduced.

  Further, in cross-flow fan 10 in the present embodiment, fan blade 21 can be made thinner by that amount while improving strength of fan blade 21 by bending portion 41. Thereby, the cross-flow fan 10 can be reduced in weight or cost-reduced. For the above reasons, it is possible to realize the cross-flow fan 10 having a blade cross-sectional shape that has a high lift-drag ratio, is thin and light, and has high strength.

  Moreover, according to the air conditioner 110 in Embodiment 1 of this invention, the power consumption of the drive motor for driving the cross-flow fan 10 can be reduced by using the cross-flow fan 10 excellent in ventilation capability. . Thereby, the air conditioner 110 that can contribute to energy saving can be realized.

  In the present embodiment, an air conditioner has been described as an example. However, in addition to this, for example, an air purifier, a humidifier, a cooling device, a ventilating device, or the like can be used as a flow-through device in the present invention. It is possible to apply a fan.

(Embodiment 2)
In the present embodiment, various modifications of cross-flow fan 10 in the first embodiment will be described.

  FIG. 11 is a cross-sectional view showing a first modification of the cross-flow fan in FIG. Referring to FIG. 11, fan blade 21 has a blade cross-sectional shape in which concave portion 77 is formed on positive pressure surface 25 and concave portion 76 is formed on negative pressure surface 24.

  The positive pressure surface 25 is further formed with a plurality of convex portions 72 (72p, 72q). A concave portion 77 is formed by a valley portion between adjacent convex portions 72. In the present modification, a plurality of concave portions 76 (76p, 76q) are formed in the negative pressure surface 24. On the negative pressure surface 24, a plurality of convex portions 71 (71p, 71q, 71r) are further formed. A concave portion 76 is formed by a valley portion between adjacent convex portions 71.

  Compared with the fan blade 21 in FIG. 3, the fan blade 21 has a substantially W-shaped blade cross-sectional shape in which the concave portion and the convex portion are inverted between the positive pressure surface 25 and the negative pressure surface 24. In this modification, the number of concave portions 76 formed on the negative pressure surface 24 is larger than the number of concave portions 77 formed on the positive pressure surface 25.

  Note that the number of recesses formed on the suction surface 24 and the number of recesses formed on the pressure surface 25 may be equal.

  FIG. 12 is a cross-sectional view showing a second modification of the cross-flow fan in FIG. Referring to FIG. 12, in the present modification, a plurality of recesses 77 (77p, 77q, 77r) are formed in positive pressure surface 25. A plurality of convex portions 72 (72p, 72q, 72r, 72s) are further formed on the positive pressure surface 25. A concave portion 77 is formed by a valley portion between adjacent convex portions 72. A plurality of recesses 76 (76p, 76q) are formed in the negative pressure surface 24. On the negative pressure surface 24, a plurality of convex portions 71 (71p, 71q, 71r) are further formed. A concave portion 76 is formed by a valley portion between adjacent convex portions 71.

  As shown in this modification, a plurality of recesses may be formed on both the pressure surface 25 and the suction surface 24.

  FIG. 13 is a cross-sectional view showing a third modification of the cross-flow fan in FIG. Referring to FIG. 13, in this modification, fan blade 21 has a relatively small thickness at a position adjacent to inner edge portion 26 and outer edge portion 27 as a whole, and a blade between inner edge portion 26 and outer edge portion 27. It has a blade cross-sectional shape in which the thickness gradually increases toward the center.

  The positive pressure surface 25 is formed with a recess 77p and a recess 77q in the vicinity of the inner edge 26 and the outer edge 27, respectively. In the negative pressure surface 24, a recess 76 is formed at the center of the blade between the inner edge portion 26 and the outer edge portion 27. The recess 77 and the recess 76 are formed so as to be recessed from the surface of the blade surface 23 that curves and extends between the inner edge portion 26 and the outer edge portion 27. The concave portion 77 and the concave portion 76 include the thickness t1 of the fan blade 21 at the position where the concave portion 77p is formed, the thickness t2 of the fan blade 21 at the position where the concave portion 76 is formed, and the fan blade 21 at the position where the concave portion 77q is formed. Is formed so as to be equal to the thickness t3.

  As an example of this modification, the fan blade 21 is not limited to a structure having a thin cross-sectional shape as a whole, and may have another cross-sectional shape. As shown in FIG. 3, the fan blade 21 is not limited to the structure in which the concave portion 57 and the concave portion 56 are formed by the bent portion 41, and the concave portion 76 and the concave portion 77 are formed in a planar shape or a curved surface shape as in this modification. The structure may be formed by partially denting the extending wing surface 23.

  According to the cross-flow fan in the third embodiment of the present invention configured as described above, the effects described in the first embodiment can be similarly obtained.

(Embodiment 3)
In the present embodiment, a mold for molding used in manufacturing the cross-flow fan 10 in FIG. 1 will be described.

  FIG. 14 is a cross-sectional view showing a molding die used when the cross-flow fan in FIG. 1 is manufactured. Referring to FIG. 14, a molding die 210 has a fixed side die 214 and a movable side die 212. The fixed mold 214 and the movable mold 212 define a cavity 216 that has substantially the same shape as the cross-flow fan 10 and into which a fluid resin is injected.

  The molding die 210 may be provided with a heater (not shown) for enhancing the fluidity of the resin injected into the cavity 216. The installation of such a heater is particularly effective when, for example, a synthetic resin with increased strength such as an AS resin containing glass fiber is used.

  According to the molding die 210 configured in this way, a cross-flow fan having a blade cross-sectional shape that has a high lift-drag ratio, is thin, light, and has high strength can be manufactured by resin molding.

(Embodiment 4)
In the present embodiment, the cross-flow fan 10 shown in FIG. 1 and the cross-flow fan for comparison including fan blades in which the blade surface 23 is not formed with recesses and projections are respectively shown in FIG. Various embodiments that are incorporated into the conditioner 110 and performed using the air conditioner 110 will be described.

  In the embodiment described below, a cross-flow fan 10 having a diameter of φ100 mm and a length of 600 mm and a cross-flow fan for comparison are used, and the size and arrangement of the fan blade 21 are excluded without the presence or absence of concave and convex portions. Were the same.

  FIG. 15 is a graph showing the relationship between the air flow rate of the cross-flow fan and the power consumption of the driving motor in this embodiment. Referring to FIG. 15, in this embodiment, in the case where crossflow fan 10 is used and the case where a crossflow fan for comparison is used, the flow rate of the motor for driving at each flow rate is changed while the flow rate is changed. The power consumption was measured. As a result of the measurement, it was confirmed that the cross-flow fan 10 reduced the power consumption of the driving motor at the same air volume as compared with the cross-flow fan for comparison.

  FIG. 16 is a graph showing the relationship between the air volume of the cross-flow fan and the noise value in this example. Referring to FIG. 16, in this example, the noise value at each air volume was measured while changing the air volume in each of the case where the cross-flow fan 10 was used and the case where the cross-flow fan for comparison was used. . As a result of the measurement, it was confirmed that the noise value at the same air volume was reduced in the cross-flow fan 10 as compared with the cross-flow fan for comparison.

  FIG. 17 is a graph showing the pressure flow characteristics of the cross-flow fan in this example. Referring to FIG. 17, the figure shows the pressure flow characteristics (P: static pressure−Q: air volume) of cross-flow fan 10 at a constant rotational speed and a cross-flow fan for comparison. Referring to FIG. 17, cross flow fan 10 has an improved PQ characteristic particularly in a region with a small air volume, as compared with cross flow fan for comparison.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  The present invention is mainly applied to household electric appliances having a blowing function such as an air purifier and an air conditioner.

10 Cross-flow fan 12, 12A, 12B Impeller 13 Outer frame 13a, 13b End surface 21 Fan blade 23 Blade surface 24 Negative pressure surface 25 Positive pressure surface 26 Inner edge portion 27 Outer edge portion 41, 41A, 41B Bent portion 51, 52, 71, 72 Convex Part 56, 57, 76, 77 Recess 61, 66, 161 Air flow 62, 63, 67, 68, 162 Vortex 101 Center axis 106 Center line 110 Air conditioner 115 Blower 120 Indoor unit 122 Casing 122A Cabinet 122B Front panel 124 Suction Mouth 125 Outlet 126 Air passage 128 Air filter 129 Indoor heat exchanger 131 Horizontal louver 132 Vertical louver 141 Upstream area 142 Downstream area 146 Upstream outer space 147 Inner space 148 Downstream outer space 151 Front wall 152 Rear wall Part 153, 154 Protruding portion 156 Upper guide 157 Lower guide 210 Molding die 212 Movable die 214 Fixed die 216 Cavity

Claims (4)

A plurality of blade portions that are arranged on the inner peripheral side, have an inner edge portion through which air flows in and out, and an outer edge portion that is arranged on the outer peripheral side and through which air flows in and out, and are provided at intervals in the circumferential direction. ,
The blade portion includes a pressure surface that extends between the inner edge portion and the outer edge portion, and is disposed on the side of the cross-flow fan in the rotational direction, and a suction surface disposed on the back side of the pressure surface. A wing surface is formed,
The blade portion has a blade cross-sectional shape in which a concave portion is formed in the pressure surface and the suction surface when cut by a plane orthogonal to the rotation axis of the once-through fan,
The cross- flow fan , wherein the number of the recesses formed on the pressure surface and the number of the recesses formed on the suction surface are different . The cross- flow fan according to claim 1 , wherein the number of the recesses formed in the suction surface is greater than the number of the recesses formed in the pressure surface . A molding die used for molding the cross-flow fan according to claim 1 or 2 with a resin .   A fluid feeder comprising a blower comprising the cross-flow fan according to claim 1 and a drive motor connected to the cross-flow fan and rotating the plurality of blade portions.