JP4403691B2 - Fan guard for blower unit - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
[0002]
  The present invention relates to a fan guard for a blower unit that is attached to an air outlet of a blower unit having a blower fan.
[Prior art]
[0003]
  For example, as a blower unit attached to an outdoor unit of an air conditioner, there is one configured to protect a blower fan by providing a fan guard at an air outlet of the blower fan.
[0004]
  As the above-mentioned fan guard, one in which a large number of radial ribs arranged radially and a large number of annular ribs arranged concentrically are integrally formed of a synthetic resin is well known. Radiation ribs and annular ribs in such synthetic resin fan guards have a flat cross-sectional shape along the rotational axis direction of the blower fan in order to maintain strength and reduce the pressure loss of the air flow passing therethrough. Yes.
[0005]
  In the case of the fan guard having the above-described structure, when an axial fan is employed as the blower fan, there is a problem that the radiating rib and the annular rib interfere with the blown air flow flowing from the blower fan into the fan guard. Therefore, a fan guard configured to incline the radiating rib with respect to a reference plane parallel to the rotation axis of the blower fan has been proposed (for example, see Patent Document 1).
[0006]
  In general, the blown air flow from the axial fan is a swirling and spreading flow having a velocity component of a predetermined magnitude in the rotational direction and the axial direction. Therefore, in Patent Document 1, the radiating rib has a shape having a flat cross section in the blowing flow direction, and the inclination of the radiating rib is defined as the inclination angle of the swirling blowing flow, that is, the axial velocity component and the circumferential velocity component. The inclination angle determined by the speed ratio is adjusted to reduce the noise and pressure loss caused by the blown airflow colliding with the radiation rib. The inclination angle of the radiating rib was set in correspondence with the inclination angle of the blown air flow at the portion where the blown air flow speed of the blower fan is maximized.
[0007]
  Moreover, in the said patent document 1, according to the blowing airflow of a ventilation fan (for example, axial flow fan) spreading and becoming a flow, the said annular rib is predetermined outward from the center part vicinity of a radial direction outward. By tilting the angle, the noise and pressure loss generated by the collision between the radial velocity component of the blown airflow and the annular rib are reduced.
[0008]
[Patent Document 1]
          JP2002-228192A.
[Problems to be solved by the invention]
[0009]
  However, the inclination angle of the swirling blown air flow of the axial fan is not constant in the entire radial region, but changes in the radial direction. That is, as shown in FIG. 13, the inclination angle α of the blown air flow is a downwardly convex curve with respect to the radial position (ie, dimensionless R = radius / fan guard radius) (ie, the hub side of the axial fan). Gradually decreases from the outer peripheral side to the outer peripheral side, has a minimum value at the central part and a slightly outer peripheral side, becomes substantially constant in a predetermined region, and gradually increases again in the vicinity of the outer periphery. As shown in FIG. 14, the velocity V of the blown air flow is an upwardly convex curve (ie, from the hub side of the axial fan) with respect to the radial position (ie, dimensionless R = radius / fan guard radius). The curve gradually increases toward the outer peripheral side, has a maximum value at the central part and slightly at the outer peripheral side, becomes substantially constant in a predetermined region, and gradually decreases again in the vicinity of the outer periphery. Therefore, in the radiating rib in the fan guard disclosed in Patent Document 1, the inclination angle of the blown air flow and the inclination angle of the radiating rib do not coincide in the entire radial region. For this reason, in the region where the inclination angle of the blown air flow does not coincide with the inclination angle of the radiating rib (that is, in the vicinity of the closing plate side or the outer peripheral side), there is interference between the blowing air flow and the radiating rib, and the noise caused by the interference In addition, pressure loss may increase.
[0010]
  In addition, in order to avoid the fan guard coming into contact with the rear edge of the blower fan and being damaged when the fan guard is deformed in the rotation axis direction of the blower fan due to an object collision or the like, the blower fan and the fan guard are separated from each other by a predetermined distance. It is common for them to be spaced apart. As a means for ensuring the predetermined distance described above, a cylindrical or rectangular wall surface (for example, a casing) is provided between the blower fan and the fan guard, or the outer frame of the fan guard has an axial thickness. In some cases, a radial rib and an annular rib are arranged on the downstream side. In either case, the wall surface (for example, the casing) or the outer frame is inclined parallel to the rotation axis of the blower fan or toward the axial center. In this case, the blown air flow of the blower fan is an outwardly expanded flow as a whole, but in the vicinity of the outer frame, it flows in the axial direction along the wall surface or the outer frame or axially inward.
[0011]
  However, as in the fan guard disclosed in Patent Document 1, when the annular rib is inclined outward by a predetermined angle from the vicinity of the central portion of the radial region, the outermost annular rib and the outer frame wall surface The airflow passing between the two is blocked, pressure loss increases, and there is a risk that the blown airflow interferes with the outermost annular rib or outer frame to increase noise.
[0012]
  The present invention has been made in view of the above points, and an object of the present invention is to reduce noise rise and pressure loss by adopting a configuration capable of minimizing interference with the blown air flow. .
[Means for Solving the Problems]
[0013]
  In the present invention, as a first means for solving the above-mentioned problems, the air outlet 9 of the air blowing unit A having the air blowing fan 3 is attached to the air outlet 9 of the air blowing unit A and disposed around the outer periphery of the closing plate 14 disposed at the center. Between the outer frame 15 and a plurality of annular ribs 16, 16... Concentrically arranged at predetermined intervals in the radial direction around the center point of the closing plate 14. In the fan guard of the blower unit that includes a large number of radiation ribs 17, 17,... Radially extending toward the outer frame 15 and arranged at equal intervals in the circumferential direction, the radiation ribs 17, 17,. The inclination angle α ′ of the radiation ribs 17, 17... Is inclined between the closing plate 14 and the outer frame 15 while being inclined with respect to the rotation axis at a reference plane F parallel to the rotation axis 13 a of the fan 3. In the middle part of Constant region Z which is substantially constant in rice and a predetermined area value₀And the constant region Z₀Gradually decreasing region Z on the closing plate 14 side₁And gradually increasing region Z on the outer frame 15 side₂And set to haveOn the other hand, the annular ribs 16, 16,... Are inclined outward from the substantially central portion of the radial region to the outer peripheral side, and the inclination angle β is set to be gradually reduced in the vicinity of the outermost periphery, The outer frame 15 is inclined parallel to or toward the center with respect to the direction of the rotating shaft 13a of the blower fan 3, and the inclination angle of the outermost peripheral annular rib 16A in the annular ribs 16, 16,. Almost identical to the corneris doing.
[0014]
  With the above configuration, the blown air flow W from the blower fan 3 flows along the radial ribs 17, 17... In the fan guard 4 in the entire radial direction region of the fan guard 4. Therefore, the blown air flow and the radiation generated in the conventional device in which there is a region where the inclination angle of the blown air flow does not coincide with the inclination angle of the radiating rib (that is, near the closing plate side or the outer peripheral side). Interference with ribs is not generated, and noise and pressure loss can be reduced. Moreover, the change in the inclination angle α of the blown air flow W with respect to the radial position (that is, dimensionless R = radius / fan guard radius) (see FIG. 13) and the inclination angle α ′ of the radiating ribs 17, 17. In the radial region, there is a region where the inclination angle α of the blown air flow W does not coincide with the inclination angle α ′ of the radiating ribs 17, 17. Thus, the interference between the blown air flow and the radiating rib, which has been generated in the conventional apparatus, is almost completely eliminated, and noise and pressure loss can be greatly reduced.Further, the annular ribs 16, 16,... Are inclined outwardly from the substantially central portion of the radial region, and the inclination angle β is set to be gradually reduced in the vicinity of the outermost periphery. The blown air flow W from the blower fan 3 (that is, the outwardly spreading flow) passes along the annular ribs 16, 16... And the interference between the annular ribs 16, 16. In the vicinity of the outermost periphery, the blowing direction of the blown air flow W that has passed through the annular rib 16 is corrected in the axial direction, and the blockage phenomenon of the blown air flow W does not occur, contributing to the reduction of pressure loss. To do. Further, the outer frame 15 is inclined in parallel or inward with respect to the direction of the rotation shaft 13a of the blower fan 3, and the inclination angle of the outermost peripheral annular rib 16A in the annular ribs 16, 16,. Since the inclination angle is substantially the same as the inclination angle 15, the blown air flow W smoothly passes between the outermost peripheral annular rib 16 </ b> A and the outer frame 15, and noise rise and pressure loss can be reduced.
[0015]
  The present invention further provides a first for solving the above-mentioned problems.2As a means of1'sIn the fan guard of the blower unit provided with the means, the inclination angle α ′ of the radiation ribs 17, 17,... Is gradually changed in the range of 20 ° to 50 °.ToIn such a configuration, the inclination angle α ′ of the radiating ribs 17, 17,... Can be appropriately set in the entire radial direction region, and noise and pressure loss can be more reliably reduced.
[0016]
  According to the present invention, a first for solving the above-mentioned problems.3As a means of the above, the air blocking unit 14 having the air blowing fan 3 is attached to the air outlet 9 and is located between the closing plate 14 disposed in the center and the outer frame 15 disposed on the outer periphery, and the blocking plate A plurality of annular ribs 16, 16... Concentrically arranged at predetermined intervals in the radial direction around the center point of 14, and a plurality of radiation ribs extending radially from the closing plate 14 toward the outer frame 15. In the fan guard of the blower unit consisting of 17, 17,..., The annular ribs 16, 16,.Outer peripheral sideAnd the inclination angle β is set so as to gradually decrease in the vicinity of the outermost periphery, while the outer frame 15 is parallel to the direction of the rotating shaft 13a of the blower fan 3 orcenterThe inclination angle of the outermost peripheral annular rib 16A in the annular ribs 16, 16,... Is substantially the same as the inclination angle of the outer frame 15.
[0017]
  By configuring as described above, the outwardly spreading flow (that is, the blown air flow W) from the blower fan 3 passes along the annular ribs 16, 16. .. and interference with the blown air flow W can be reduced, and in the vicinity of the outermost periphery, the blown air flow W passing through the annular rib 16 is corrected in the axial direction to cause a blockage phenomenon of the blown air flow W. Therefore, the pressure loss can be reduced. In addition, the blown air flow W smoothly passes between the outermost peripheral annular rib 16A and the outer frame 15, and noise rise and pressure loss can be reduced.
[0018]
  The present invention further provides a first for solving the above-mentioned problems.4As the means, the first and the firstTwo-wayIs the first3In the fan guard of the blower unit provided with the means, a plurality of continuous ribs that are continuous from the closing plate 14 to the outer frame 15 and arranged at equal intervals in the circumferential direction. A plurality of inner-layer side ribs 17B that are located between the continuous ribs 17A, 17A,... And extend from the closing plate 14 to a substantially central portion in the radial direction and arranged at equal intervals in the circumferential direction. And a plurality of outer layer side ribs 17C, 17C, which are located between the continuous ribs 17A, 17A,..., From a substantially central portion in the radial direction to the outer frame 15 and arranged at equal intervals in the circumferential direction. The number of the inner layer side ribs 17B, 17B,... Can be made smaller than the number of the outer layer side ribs 17C, 17C,. .. Can be secured to prevent the annular ribs 16, 16... From spreading in the radial direction when a foreign object enters between them, and the inner layer side rib 17 B is connected to the closing plate 14. Even if the number of the inner layer side ribs 17B is smaller than the number of the outer layer side ribs 17C, the strength at the center of the fan guard 4 is not reduced, and the fan guard 4 is bent when an axial load is applied. Can be ensured, and an increase in ventilation resistance of the blown air flow W from the blower fan 3 can be suppressed. As a result, contact with the blower fan 3 due to deformation of the fan guard 4 can be prevented, and noise and input of the blower fan 3 can be reduced. Moreover, since the closing plate 14 and the outer frame 15 are connected by a plurality of continuous ribs 17A, the strength of the fan guard 4 with respect to the axial load is further increased.
[0019]
  The present invention further provides a first for solving the above-mentioned problems.5As the means, the first and the first2Or the second3In the fan guard of the blower unit provided with the above means, a large number of inner layers on the side of the radial ribs 17, 17... From the closing plate 14 to the substantially central portion in the radial direction and arranged at equal intervals in the circumferential direction. The ribs 17B, 17B,... And a large number of outer layer side ribs 17C, 17C,... That extend from the center in the radial direction to the outer frame 15 and are arranged at equal intervals in the circumferential direction. .. Can be made smaller than the number of the outer layer side ribs 17C, 17C,.., And in this case, when the foreign matter enters between the annular ribs 16, 16,. 16, 16... Can be sufficiently strong to prevent the inner layer side rib 17 </ b> B from being connected to the closing plate 14, and the number of the inner layer side ribs 17 </ b> B can be set to the outer layer side rib 1. Even if the number is less than C, the strength at the central portion of the fan guard 4 is not reduced, and the strength capable of preventing the fan guard 4 from being bent when an axial load is applied can be secured. An increase in ventilation resistance of the blown air flow W from the fan 3 can be suppressed. As a result, contact with the blower fan 3 due to deformation of the fan guard 4 can be prevented, and noise and input of the blower fan 3 can be reduced.
DETAILED DESCRIPTION OF THE INVENTION
[0020]
  The preferred embodiments of the present invention will be described below with reference to the accompanying drawings.
[0021]
  First embodiment
  1 to 8 show a fan guard of a blower unit according to the first embodiment of the present invention.
[0022]
  As shown in FIG. 1, the fan guard 4 is attached to an outdoor unit A (an example of a blower unit) of an air conditioner. The outdoor unit A sucks outside air from the side surface and sucks outside air. The refrigerant is cooled or heated by exchanging heat with the refrigerant to form conditioned air, and is an upper blow type configured to blow out the conditioned air upward.
[0023]
  The outdoor unit A includes a casing 1 having a rectangular cross section having air suction ports 5 on three side surfaces, and a heat exchanger having a U-shaped cross section disposed along the air suction port 5 in the casing 1. 2, a blower fan 3 for sucking and blowing outside air, and a fan guard 4 disposed in the upper end opening of the casing 1. Although not shown in FIG. 1, the outdoor unit A includes a control unit disposed in the casing 1 so as to face the heat exchanger 2 and a compressor that compresses the refrigerant. ing.
[0024]
  The casing 1 includes a rectangular parallelepiped casing main body 6 having an open top, and an upper lid member 7 that covers an upper opening of the casing main body 6. The casing main body 6 is a metal formed by sheet metal processing, for example. It is a box made of thin plates.
[0025]
  The upper lid member 7 is made of an integrally molded product of synthetic resin, and is placed in a cylindrical shape from the upper end of the mounting portion 7a and a mounting portion 7a having a rectangular cross section that is mounted in the upper opening of the casing body 6. The wall surface portion 7b has a circular shape and is squeezed and extended, and the upper end of the wall surface portion 7b is an air outlet 9 to which the fan guard 4 is attached. On the upper inner surface of the wall surface portion 7 b of the upper lid member 7, a bell mouth 10 having a generally cylindrical shape and having upper and lower portions spread is provided.
[0026]
  The blower fan 3 is an axial fan composed of a cylindrical hub 11 located in the center and a plurality of blades 12, 12... Provided around the hub 11. It is arranged in the direction. The blower fan 3 is rotationally driven by a fan motor 13 having a rotary shaft 13 a pivotally attached to the center of the hub 11. The fan motor 13 is attached to the upper end of the casing body 6 via a support (not shown).
[0027]
  As shown in FIG. 2, the fan guard 4 is located between a circular blocking plate 14 disposed in the center and a circular outer frame 15 disposed on the outer periphery, and the center point of the blocking plate 14. , And annular ribs 16, 16... Concentrically arranged at predetermined intervals in the radial direction and radial ribs 17, 17... Extending radially from the closing plate 14 toward the outer frame 15. The radiating ribs 17, 17,... Are continuous from the closing plate 14 to the outer frame 15 (eight in the case of the present embodiment), and the continuous ribs 17A, 17A,. In the inner layer region Zi extending from the closing plate 14 to the substantially central portion in the radial direction, the inner layer side ribs 17B, 17B... Extending from the closing plate 14 to the substantially central portion in the radial direction, and the outer frame from the substantially central portion in the radial direction. Radial direction in outer zone Zo up to 15 It is composed of the outer layer-side rib 17C from a substantially central portion extending to said outer frame 15, by the 17C · ·. In this case, the continuous ribs 17A, 17A,... Are provided at equal intervals in the circumferential direction. Between the adjacent continuous ribs 17A, 17A, three outer layer side ribs 17C, 17C, 17C and two inner layers are provided. The side ribs 17B and 17B are provided at equal intervals in the circumferential direction. That is, the number of the inner layer side ribs 17B, 17B,... Is 8 less than the number of the outer layer side ribs 17C, 17C,.
[0028]
  As described above, when the foreign matter enters between the annular ribs 16, 16,..., Sufficient strength can be secured to prevent the annular ribs 16, 16,. Is connected to the closing plate 14, even if the number of the inner layer side ribs 17B is smaller than the number of the outer layer side ribs 17C, the strength at the central portion of the fan guard 4 is not reduced, and the axial load load is reduced. It is possible to secure a strength that can prevent the fan guard 4 from being bent when it is applied. Further, an increase in ventilation resistance of the blown air flow W from the blower fan 3 can be suppressed. Moreover, since the closing plate 14 and the outer frame 15 are connected by the eight continuous ribs 17A, 17A,..., The strength of the fan guard 4 with respect to the axial load is further increased.
[0029]
  Further, the closing plate 14, the outer frame 15, the continuous ribs 17A, 17A,..., The inner layer side ribs 17B, 17B,..., The outer layer side ribs 17C, 17C, and the annular ribs 16, 16,. It is made of an integrally molded product of synthetic resin (see FIG. 3). The outer frame 15 has a sleeve shape larger in diameter than the outer diameter of the blades 12, 12,. The fan guard 4 is mounted by fitting the outer frame 15 into the air outlet 9 at the upper end of the wall surface portion 7b.
[0030]
  The continuous ribs 17A, 17A,... And the inner layer side ribs 17B, 17B,... Are arranged radially from the closing plate 14 and curved convexly toward the downstream side in the rotational direction M of the blower fan 3. Is formed. Further, the outer layer side ribs 17C, 17C,... Are radially arranged in the outer layer region Zo of the fan guard 4 and are formed to be convexly curved toward the downstream side in the rotation direction M of the blower fan 3. Yes. By doing so, the ribs 17A, 17B, and 17C can easily follow the blown air flow W of the blower fan 3 that is blown out while spreading radially. Specifically, the ribs 17A, 17B, and 17C are formed to be convexly curved toward the downstream side in the rotational direction M so as to be substantially arc-shaped (see FIG. 4).
[0031]
  By the way, the inclination angle α of the swirling blown air flow of the blower fan 3 (that is, the axial fan) is not constant in the entire radial direction region but changes in the radial direction. That is, as shown in FIG. 13, the inclination angle α of the blown airflow is a downwardly convex curve (ie, from the hub side of the axial fan) with respect to the radial position (ie, dimensionless R = radius / fan guard radius). The curve gradually decreases toward the outer periphery side, has a minimum value at the center portion and slightly at the outer periphery side, becomes substantially constant in a predetermined region, and gradually changes again in the vicinity of the outer periphery. That is, the inclination angle α gradually changes in the range of 20 ° to 50 °.
[0032]
  Therefore, in the present embodiment, as shown in FIG. 5, the inclination angle α ′ of the radiating ribs (that is, the continuous rib 17A, the inner layer side rib 17B, and the outer layer side rib 17C) A constant region Z having a minimum value (for example, about 23 °) at an intermediate portion between the frame 15 and substantially constant in a predetermined region₀And the constant region Z₀Gradually decreasing region Z on the closing plate 14 side₁And gradually increasing region Z on the outer frame 15 side₂Are set to have. That is, the radiation ribs (that is, the continuous ribs 17A, the inner layer side ribs 17B, and the outer layer side ribs 17C) are inclined with respect to the rotation axis at the reference plane F parallel to the rotation shaft 13a of the blower fan 3, and The inclination angle α ′ of the radiating ribs (that is, the continuous rib 17A, the inner layer side rib 17B, and the outer layer side rib 17C) is gradually changed in the radial direction so as to correspond to the blowing angle α of the blowing air flow W of the blower fan 3. It is. Here, it is desirable that the inclination angle α ′ of the radiation ribs (that is, the continuous rib 17A, the inner layer side rib 17B, and the outer layer side rib 17C) is gradually changed in the range of 20 ° to 50 °.
[0033]
  In this manner, the change in the inclination angle α of the blown air flow with respect to the radial position (ie, dimensionless R = radius / fan guard radius) (see FIG. 13) and the radiating ribs (ie, the continuous rib 17A and the inner layer side rib 17B). And the inclination angle α ′ of the outer layer side rib 17C) coincide with each other in the entire radial direction region, and the inclination angle α of the blown air flow is equal to the radiating rib (that is, the continuous rib 17A, the inner layer side rib 17B, and the outer layer side rib 17C). Interference between the blown air flow and the radiating rib, which has occurred in the conventional device in which there is a region that does not coincide with the inclination angle α ′ (that is, in the vicinity of the closing plate 14 side or the vicinity of the outer peripheral side), is almost complete. The noise and pressure loss can be greatly reduced.
[0034]
  Further, in the present embodiment, the annular ribs 16, 16,..., As shown in FIG.Outer peripheral sideThe inclination angle β is set to gradually decrease in the vicinity of the outermost periphery. In this case, the wall surface portion 7 b of the upper lid member 7 and the outer frame 15 of the fan guard 4 are in relation to the rotating shaft 13 a of the blower fan 3.centerInclined to the side. If it does in this way, the outward spreading flow (namely, blowing airflow W) from blower fan 3 will pass along annular ribs 16,16, ..., annular rib 16, blowing airflow W, In the vicinity of the outermost periphery, the blowing direction of the blown air flow W that has passed through the annular rib 16 is corrected in the axial direction, so that the blockage phenomenon of the blown air flow W does not occur and the pressure loss is reduced. Can be achieved.
[0035]
  It is desirable that the inclination angle β of the outermost peripheral annular rib 16A in the annular ribs 16, 16,... Be substantially the same as the inclination angle of the outer frame 15. In this case, the blown air flow W smoothly passes between the outermost peripheral annular rib 16A and the outer frame 15, and noise rise and pressure loss can be reduced. The outer frame 15 may be parallel to the direction of the rotation shaft 13a of the blower fan 3.
[0036]
  In addition, it is desirable to increase the thickness of the annular rib 16B, to which the outer end of the inner layer side rib 17B and the inner end of the outer layer side rib 17C are connected, to ensure a higher strength.
[0037]
  Further, as shown in FIG. 7, the annular ribs 16, 16,.Outer peripheral sideMay be inclined at a predetermined angle β (for example, β = 5 ° to 15 °). As shown in FIG. 8, the outer frame 15 is made parallel to the direction of the rotating shaft 13a of the blower fan 3 and is annular. The ribs 16, 16,...Outer peripheral sideMay be inclined at a predetermined angle β (for example, β = 5 ° to 15 °).
[0038]
  Second embodiment
  FIG. 9 shows a fan guard of a blower unit according to a second embodiment of the present invention.
[0039]
  In this case, the radiating ribs 17, 17... Are inner layer side ribs 17 B, 17 B,... Extending from the closing plate 14 to the substantially central portion in the radial direction in the inner layer region Zi extending from the closing plate 14 to the substantially central portion in the radial direction. In the outer layer region Zo from the substantially central portion in the radial direction to the outer frame 15, the outer layer side ribs 17 </ b> C, 17 </ b> C,. In this case, the outer layer side ribs 17C, 17C,... And the inner layer side ribs 17B, 17B,... Are provided at equal intervals in the circumferential direction, and the number of the inner layer side ribs 17B, 17B,. , 17C... In this case, when the foreign matter enters between the annular ribs 16, 16,..., Sufficient strength can be secured to prevent the annular ribs 16, 16,. Since it is connected to the closing plate 14, even if the number of the inner layer side ribs 17B is less than the number of the outer layer side ribs 17C, the strength at the central portion of the fan guard 4 will not decrease, and the axial load load will be reduced. In addition, it is possible to secure a strength that can prevent the fan guard 4 from being bent, and to suppress an increase in ventilation resistance of the blown air flow W from the blower fan 3. As a result, contact with the blower fan 3 due to deformation of the fan guard 4 can be prevented, and noise and input of the blower fan 3 can be reduced. It should be noted that the circumferential interval (in other words, the number) of the inner layer side ribs 17B, 17B,... And the outer layer side ribs 17C, 17C,. . Since other configurations and operational effects are the same as those in the first embodiment, the description thereof is omitted.
[0040]
  Third embodiment
  FIG. 10 shows a fan guard of a blower unit according to a third embodiment of the present invention.
[0041]
  In this case, both the closing plate 14 and the outer frame 15 of the fan guard 4 are rectangular, and all of the radiating ribs 17, 17... Are radially connected so as to connect the closing plate 14 and the outer frame 15. And is formed to be convexly curved toward the downstream side in the rotational direction M of the blower fan 3 so as to be substantially arcuate. Note that the obstruction plate 14 may be circular. In this way, since the closing plate 14 and the outer frame 15 are directly connected by all the radiation ribs 17, 17..., The strength of the fan guard 4 is improved. Since the circumferential interval between the radiating ribs 17, 17... Needs to be large enough to prevent foreign matter from entering, the number of the radiating ribs 17, 17. The number of the radiating ribs 17, 17,... Becomes too large on the inner peripheral side of the fan guard 4 (in other words, the circumferential interval between the radiating ribs 17, 17,... Becomes too narrow as necessary). There is a possibility that the draft resistance of the air flow from the fan 3 is increased. Since other configurations and operational effects are the same as those in the first embodiment, the description thereof is omitted.
[0042]
  Fourth embodiment
  FIG. 11 shows a fan guard of a blower unit according to a fourth embodiment of the present invention.
[0043]
  In this case, the closing plate 14 in the fan guard 4 has a circular shape and the outer frame 15 has a rectangular shape, and all of the radiation ribs 17, 17... Connect the closing plate 14 and the outer frame 15. And linearly extending radially. The obstruction plate 14 may be rectangular. In this way, since the closing plate 14 and the outer frame 15 are directly connected by all the radiation ribs 17, 17..., The strength of the fan guard 4 is improved. Since the circumferential interval between the radiating ribs 17, 17... Needs to be large enough to prevent foreign matter from entering, the number of the radiating ribs 17, 17. The number of the radiating ribs 17, 17,... Becomes too large on the inner peripheral side of the fan guard 4 (in other words, the circumferential interval between the radiating ribs 17, 17,... Becomes too narrow as necessary). There is a possibility that the draft resistance of the air flow from the fan 3 is increased. Since other configurations and operational effects are the same as those in the first embodiment, the description thereof is omitted.
[0044]
  Fifth embodiment
  FIG. 12 shows a fan guard of a blower unit according to a fifth embodiment of the present invention.
[0045]
  In this case, the closing plate 14 and the outer frame 15 of the fan guard 4 are both circular, and all of the radiation ribs 17, 17... Connect the closing plate 14 and the outer frame 15 and are linear. Are formed to extend radially. The obstruction plate 14 may be rectangular. In this way, since the closing plate 14 and the outer frame 15 are directly connected by all the radiation ribs 17, 17..., The strength of the fan guard 4 is improved. Since the circumferential interval between the radiating ribs 17, 17... Needs to be large enough to prevent foreign matter from entering, the number of the radiating ribs 17, 17. The number of the radiating ribs 17, 17,... Becomes too large on the inner peripheral side of the fan guard 4 (in other words, the circumferential interval between the radiating ribs 17, 17,... Becomes too narrow as necessary). There is a possibility that the draft resistance of the air flow from the fan 3 is increased. Since other configurations and operational effects are the same as those in the first embodiment, the description thereof is omitted.
【The invention's effect】
[0046]
  According to the first means of the present invention, the closing plate 14 provided in the central portion and the outer frame 15 provided in the outer periphery are attached to the air outlet 9 of the blower unit A having the blower fan 3. A plurality of annular ribs 16, 16... Concentrically arranged at predetermined intervals in the radial direction around the center point of the closing plate 14, and from the closing plate 14 toward the outer frame 15. In the fan guard of the blower unit that includes a plurality of radial ribs 17, 17... That extend radially and are equally spaced in the circumferential direction, the radial ribs 17, 17. Is inclined with respect to the rotational axis at a reference plane F parallel to the horizontal axis, and the inclination angle α ′ of the radiation ribs 17, 17... Is minimum at an intermediate portion between the closing plate 14 and the outer frame 15. And in a given area Constant region Z which is substantially constant have₀And the constant region Z₀Gradually decreasing region Z on the closing plate 14 side₁And gradually increasing region Z on the outer frame 15 side₂So that the blown air flow W from the blower fan 3 can flow along the radial ribs 17, 17... In the fan guard 4 in the entire radial direction region of the fan guard 4. In the conventional apparatus in which there is an area where the inclination angle α of the blown air flow W does not coincide with the inclination angle α ′ of the radiating ribs 17, 17. Interference between the generated blown air flow and the radiating ribs does not occur, and noise and pressure loss can be reduced. Moreover, the change in the inclination angle α of the blown air flow W with respect to the radial position (that is, dimensionless R = radius / fan guard radius) (see FIG. 13) and the inclination angle α ′ of the radiating ribs 17, 17. In the radial region, there is a region where the inclination angle α of the blown air flow W does not coincide with the inclination angle α ′ of the radiating ribs 17, 17. Thus, the interference between the blown air flow and the radiating rib which has been generated in the conventional apparatus is almost completely eliminated, and there is an effect that noise and pressure loss can be greatly reduced.Further, the annular ribs 16, 16,... Are inclined outwardly from the substantially central portion of the radial region, and the inclination angle β is set to be gradually reduced in the vicinity of the outermost periphery. The blown air flow W from the blower fan 3 (that is, the outwardly spreading flow) passes along the annular ribs 16, 16... And the interference between the annular ribs 16, 16. In the vicinity of the outermost periphery, the blowing direction of the blown air flow W that has passed through the annular rib 16 is corrected in the axial direction, and the blockage phenomenon of the blown air flow W does not occur, contributing to the reduction of pressure loss. There is also an effect of doing. Further, the outer frame 15 is inclined in parallel or inward with respect to the direction of the rotation shaft 13a of the blower fan 3, and the inclination angle of the outermost peripheral annular rib 16A in the annular ribs 16, 16,. Since the inclination angle is substantially the same as the inclination angle 15, the blown air flow W smoothly passes between the outermost peripheral annular rib 16 </ b> A and the outer frame 15, and noise increase and pressure loss can be reduced. There is also an effect.
[0047]
  As in the second means of the present invention, in the fan guard of the blower unit provided with the first means, the inclination angle α ′ of the radiating ribs 17, 17,... Is gradually reduced in the range of 20 ° to 50 °. In such a configuration, the inclination angle α ′ of the radiation ribs 17, 17... Can be set appropriately in the entire radial direction region, and noise and pressure loss can be more reliably reduced. it can.
[0048]
  No. of the present invention3According to this means, it is mounted on the air outlet 9 of the blower unit A having the blower fan 3, and is between the closing plate 14 disposed in the center and the outer frame 15 disposed on the outer periphery, A large number of annular ribs 16, 16... Concentrically arranged at predetermined intervals in the radial direction with the center point of the closing plate 14 as the center, and a plurality of radially extending ribs from the closing plate 14 toward the outer frame 15. In the fan guard of the blower unit comprising the radiating ribs 17, 17,..., The annular ribs 16, 16,.Outer peripheral sideAnd the inclination angle β is set so as to gradually decrease in the vicinity of the outermost periphery, while the outer frame 15 is parallel to the direction of the rotating shaft 13a of the blower fan 3 orcenterAnd the outer peripheral annular rib 16A has an inclination angle substantially the same as the inclination angle of the outer frame 15, and flows outwardly from the blower fan 3 (that is, Since the blown air flow W) can pass along the annular ribs 16, 16,..., Interference between the annular ribs 16, 16, .. and the blown air flow W can be reduced, and in the vicinity of the outermost periphery. This has the effect that the blowing direction of the blown air flow W that has passed through the annular rib 16 is corrected in the axial direction so that the blockage phenomenon of the blown air flow W does not occur and the pressure loss can be reduced. In addition, the blown air flow W smoothly passes between the outermost peripheral annular rib 16A and the outer frame 15, and there is an effect that noise rise and pressure loss can be reduced.
[0049]
  No. of the present invention4As in the first means, the first and secondTwo-wayIs the first3In the fan guard of the blower unit provided with the means, a plurality of continuous ribs that are continuous from the closing plate 14 to the outer frame 15 and arranged at equal intervals in the circumferential direction. A plurality of inner-layer side ribs 17B that are located between the continuous ribs 17A, 17A,... And extend from the closing plate 14 to a substantially central portion in the radial direction and arranged at equal intervals in the circumferential direction. And a plurality of outer layer side ribs 17C, 17C, which are located between the continuous ribs 17A, 17A,..., From a substantially central portion in the radial direction to the outer frame 15 and arranged at equal intervals in the circumferential direction. The number of the inner layer side ribs 17B, 17B,... Can be made smaller than the number of the outer layer side ribs 17C, 17C,. .. Can be secured to prevent the annular ribs 16, 16... From spreading in the radial direction when a foreign object enters between them, and the inner layer side rib 17 B is connected to the closing plate 14. Even if the number of the inner layer side ribs 17B is smaller than the number of the outer layer side ribs 17C, the strength at the center of the fan guard 4 is not reduced, and the fan guard 4 is bent when an axial load is applied. Can be ensured, and an increase in ventilation resistance of the blown air flow W from the blower fan 3 can be suppressed. As a result, contact with the blower fan 3 due to deformation of the fan guard 4 can be prevented, and noise and input of the blower fan 3 can be reduced. Moreover, since the closing plate 14 and the outer frame 15 are connected by a plurality of continuous ribs 17A, the strength of the fan guard 4 with respect to the axial load is further increased.
[0050]
  No. of the present invention5As in the first means, the first and secondTwo-wayIs the first3In the fan guard of the blower unit provided with the above means, a large number of inner layers on the side of the radial ribs 17, 17... From the closing plate 14 to the substantially central portion in the radial direction and arranged at equal intervals in the circumferential direction. The ribs 17B, 17B,... And a large number of outer layer side ribs 17C, 17C,... That extend from the center in the radial direction to the outer frame 15 and are arranged at equal intervals in the circumferential direction. .. Can be made smaller than the number of the outer layer side ribs 17C, 17C,.., And in this case, when the foreign matter enters between the annular ribs 16, 16,. 16, 16... Can be sufficiently strong to prevent the inner layer side rib 17 </ b> B from being connected to the closing plate 14, and the number of the inner layer side ribs 17 </ b> B can be set to the outer layer side rib 1. Even if the number is less than C, the strength at the central portion of the fan guard 4 is not reduced, and the strength capable of preventing the fan guard 4 from being bent when an axial load is applied can be secured. An increase in ventilation resistance of the blown air flow W from the fan 3 can be suppressed. As a result, contact with the blower fan 3 due to deformation of the fan guard 4 can be prevented, and noise and input of the blower fan 3 can be reduced.
[Brief description of the drawings]
FIG. 1 is a side view in which a part of a blower unit (outdoor unit) using a fan guard according to a first embodiment of the present invention is shown in cross section.
FIG. 2 is a plan view showing a fan guard of the blower unit according to the first embodiment of the present invention.
FIG. 3 is a partially enlarged perspective view showing a main part of a fan guard of the blower unit according to the first embodiment of the present invention.
FIG. 4 is a perspective view in which a part of a fan guard and a blower fan portion of the blower unit according to the first embodiment of the present invention is omitted.
FIG. 5 is an explanatory diagram for determining the shape of the radiating rib constituting the fan guard of the blower unit according to the first embodiment of the present invention.
FIG. 6 is an enlarged cross-sectional view of a main part of the fan guard of the blower unit according to the first embodiment of the present invention.
FIG. 7 is an enlarged cross-sectional view of a main part showing a modification of the fan guard of the blower unit according to the first embodiment of the present invention.
FIG. 8 is an enlarged cross-sectional view of a main part showing another modification of the fan guard of the blower unit according to the first embodiment of the present invention.
FIG. 9 is a plan view showing a fan guard of a blower unit according to a second embodiment of the present invention.
FIG. 10 is a plan view showing a fan guard of a blower unit according to a third embodiment of the present invention.
FIG. 11 is a plan view showing a fan guard of a blower unit according to a fourth embodiment of the present invention.
FIG. 12 is a plan view showing a fan guard of a blower unit according to a fifth embodiment of the present invention.
FIG. 13 is a characteristic diagram showing a relationship between a dimensionless R (radius / fan guard radius) and an inclination angle α (°) of a blown air flow in an axial fan.
FIG. 14 is a characteristic diagram showing the relationship between dimensionless R (radius / fan guard radius) and the velocity V (m / s) of the blown air flow in the axial fan.
[Explanation of symbols]
  3 is a blower fan, 4 is a fan guard, 9 is an air outlet, 13 is a fan motor, 13a is a rotating shaft, 14 is a closing plate, 15 is an outer frame, 16 is an annular rib, 16A is an outermost annular rib, 17 is Radiation rib, 17A is a continuous rib, 17B is an inner layer side rib, 17C is an outer layer side rib, A is a blower unit (outdoor unit), F is a reference plane, W is a blown air flow, Z₀Is a substantially constant region, Z₁Is the gradually decreasing region, Z₂Is the gradually increasing region, α is the inclination angle of the blown air flow, α ′ is the inclination angle of the radiation rib, and β is the inclination angle of the annular rib.

Claims (5)

It is attached to the air outlet (9) of the blower unit (A) having the blower fan (3), and includes a closing plate (14) disposed in the center and an outer frame (15) disposed on the outer periphery. A plurality of annular ribs (16), (16),... Which are concentrically arranged at predetermined intervals in the radial direction around the center point of the closing plate (14), and from the closing plate (14) A fan guard for a blower unit comprising a plurality of radiating ribs (17), (17),..., Which extend radially toward the outer frame (15) and are arranged at equal intervals in the circumferential direction. (17), (17),... Are inclined with respect to the rotational axis at a reference plane (F) parallel to the rotational axis (13a) of the blower fan (3), and the radiation ribs (17), ( 17)... The inclination angle (α ′) of the closing plate (14) and the outer frame ( In rice and a predetermined region of the minimum value in the intermediate portion between the 5) and the constant region that is substantially constant (Z _0), decreasing of the closure plate (14) side across the constant region (Z ₀₎ The annular ribs (16), (16),... Are substantially centered in the radial region while being set to have a region (Z ₁ ) and a gradually increasing region (Z ₂ ) on the outer frame (15) side. And the inclination angle (β) is set so as to gradually decrease in the vicinity of the outermost periphery, and the outer frame (15) is connected to the rotating shaft (13a) of the blower fan (3). ) Direction or parallel to the center, and the inclination angle of the outermost peripheral annular rib (16A) at the annular ribs (16), (16) is substantially the same as the inclination angle of the outer frame (15). fan guard of a blower unit, characterized in that Do was with. The radial ribs (17), (17) the inclination angle · · (alpha '), and of the claims 1 Symbol mounting of the blower unit, characterized in that so as to gradual change in the range of 20 ° to 50 ° Fan guard. It is attached to the air outlet (9) of the blower unit (A) having the blower fan (3), and includes a closing plate (14) disposed in the center and an outer frame (15) disposed on the outer periphery. A plurality of annular ribs (16), (16),... Which are concentrically arranged at predetermined intervals in the radial direction around the center point of the closing plate (14), and from the closing plate (14) A fan guard of a blower unit comprising a plurality of radial ribs (17), (17),... Extending radially toward the outer frame (15), wherein the annular ribs (16), (16),. and the inclination angle is inclined in the outer peripheral side outside the substantially central portion of the radial region (beta), while set to gradually decrease in the outermost vicinity of the outer frame (15), the blower the axis of rotation of the fan (3) (13a) parallel to the direction or Features with tilting to the center side, the annular rib (16), that it has no substantially the same as the inclination angle (16) the inclination angle of the outermost annular rib (16A) in ..., the outer frame (15) The fan guard of the blower unit. A plurality of continuous ribs (17A) arranged from the closing plate (14) to the outer frame (15) at regular intervals in the circumferential direction, with the radiation ribs (17), (17),. (17A) .. and a plurality of the ribs between the continuous ribs (17A), (17A)... From the closing plate (14) to a substantially central portion in the radial direction and arranged at equal intervals in the circumferential direction. Between the inner side ribs (17B), (17B)... And the continuous ribs (17A), (17A)..., Extending from a substantially central portion in the radial direction to the outer frame (15) and in the circumferential direction. The plurality of outer layer side ribs (17C), (17C),... Arranged at equal intervals, and the number of the inner layer side ribs (17B), (17B),. , (17C) .. before characterized by being less than the number of Claim 1, 2 Contact and 3 fan guard of a blower unit according to any one claim of. The radiating ribs (17), (17),... Extend from the closing plate (14) to a substantially central portion in the radial direction and are arranged at a plurality of inner layer side ribs (17B) (equally spaced in the circumferential direction). 17B) ..., and a large number of outer layer side ribs (17C), (17C) ..., which are arranged at equal intervals in the circumferential direction from the radial center to the outer frame (15), the inner layer-side ribs (17B), (17B) wherein the number of ... outer ribs (17C), (17C) the preceding claims, characterized in that it has less than the number of ... 1, 2 any contact and 3 of A fan guard for the blower unit according to claim 1.

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