JP6191536B2 - Blower - Google Patents

Description

  The present invention relates to a blower that blows out sucked air to the outside.

  2. Description of the Related Art Centrifugal blowers equipped with a centrifugal multiblade fan are known as blowers that are disposed inside vehicle air conditioners, household air purifiers, and the like. The centrifugal multiblade fan is a fan having a rotating shaft that is rotated by a motor and a plurality of blades that are arranged in a cylindrical shape around the rotating shaft. When the blade rotates together with the rotating shaft, the surrounding air flows into the inner side of the blade along the axial direction of the rotating shaft (a space surrounded by a plurality of blades arranged in a cylindrical shape), and then from the inner side of the blade by centrifugal force. It flows out to the outside. Centrifugal multiblade fans include sirocco fans, radial fans, turbo fans, and the like.

  Such a centrifugal blower is preferably used as a blower for an air conditioner of a luxury car or a domestic air cleaner that is particularly required to be low noise because its operation sound is relatively low. There are many. In recent years, the demand for noise reduction has become more stringent, and various studies have been made to reduce not only motor operation noise, but also turbulence generated by turbulent air flow. Has been made.

  For example, the following Patent Document 1 describes an air conditioner that is a centrifugal blower having a configuration including a guide member that guides the flow of air in the vicinity of a suction port that is an air inlet and a centrifugal fan. Yes. In this air conditioner, the inflowing air first reaches the vicinity of the suction port, and then flows into the inside from the suction port while changing the flow direction along the side surface of the guide member formed in a conical shape. Since the flow direction changes smoothly when air flows in, the generation of turbulent sound due to air turbulence is suppressed.

JP 2008-241143 A

  By the way, the flow direction of the air sucked by the centrifugal blower is changed before reaching the blades of the centrifugal multiblade fan. That is, the air does not flow linearly, but reaches the blades of the centrifugal multiblade fan after bending and flowing. At that time, the flow velocity of the portion tends to increase due to the influence of the centrifugal force outside the bent flow, so that the flow velocity differs between the outside and the inside of the bent flow. Due to such a difference in flow velocity inside and outside, the velocity distribution of the air reaching the blades of the centrifugal multiblade fan tends to be non-uniform. As a result of intensive studies by the inventor, it has been found that the non-uniform air velocity distribution as described above is one of the causes of turbulent noise in the centrifugal blower.

  In particular, in recent years, it has been required to reduce the thickness of a centrifugal blower. In a thin centrifugal blower, it is necessary to bend the flow direction largely compared to a relatively thick centrifugal blower before air reaches the blades of the centrifugal multiblade fan. For this reason, the velocity distribution as described above is further non-uniform, and as a result, turbulent sound is further increased.

  The present invention has been made in view of such problems, and an object thereof is a blower that blows out sucked air to the outside and sufficiently suppresses the generation of turbulent sound even when the thickness is reduced. It is in providing the blower which can do.

In order to solve the above problems, a blower according to the present invention is a blower that blows out sucked air to the outside, and the centrifugal multiblade fan that sucks air and blows out the sucked air to the outside, and the centrifugal type A multi-blade fan is housed inside, and a case in which a suction port is formed so that air flows in from a direction along the rotation axis of the centrifugal multi-blade fan, and a flow of air passing through the suction port are guided. And a single or a plurality of guide plates for separating the air flow passing through the outside of the suction port and the air flow passing through the inside of the suction port. The guide plate includes a first portion disposed inside the case, and the first portion includes a first small diameter portion provided on the suction port side and the suction port sandwiching the first small diameter portion. And a first large-diameter portion provided on the opposite side. An air flow path that passes through the suction port is partitioned into a plurality of small flow paths by the guide plate, and an inlet portion that is an air inflow side and an outlet portion that is an air outflow side of each of the small flow paths The small channel formed inside the suction port when the ratio of the channel cross-sectional area of the outlet to the channel cross-sectional area of the inlet is the cross-sectional area enlargement ratio of the small channel Is larger than the cross-sectional area expansion rate of the small channel formed outside the suction port.

  In the blower of the present invention, air is sucked and blown by the rotation of the centrifugal multiblade fan. Therefore, the sucked air flows toward or along the straight line passing through the rotation axis of the centrifugal multiblade fan, and then the flow direction is changed so as to move away from the straight line and blown out. That is, a bent air flow is formed. Air inside such a bent flow tends to flow toward the outside of the bent flow due to centrifugal force. As a result, the air flow rate outside the bent flow may be faster than the air flow rate in other parts.

  Such a local increase in the flow velocity leads to a non-uniform velocity distribution and causes turbulent sound. Therefore, the blower according to the present invention includes a guide plate. The guide plate is a single plate or a plurality of plates arranged to guide the flow of air passing through the suction port, and passes through the outside of the suction port and the inside of the suction port. It arrange | positions so that it may isolate | separate from the flow of air.

  By providing the guide plate as described above, the air inside the bent flow is suppressed from flowing toward the outside of the bent flow due to the centrifugal force. The air inside the bent flow is the air passing outside the suction port if the center of the suction port is the reference, and the air outside the bent flow is the center of the suction port Air that passes through the inside of the suction port. Therefore, the guide plate suppresses the air passing outside the suction port from joining the air passing through the central side of the suction port, so that a local increase in flow velocity due to the joining occurs. Is suppressed. As a result, the air reaches the blades of the centrifugal multi-blade fan after being bent and flows, but the velocity distribution of the air reaching the blades is substantially uniform, resulting in non-uniform velocity distribution. Generation of turbulent sound can be suppressed.

  ADVANTAGE OF THE INVENTION According to this invention, it is a blower which blows off the sucked air outside, Comprising: Even if it is a case where it thins, the blower which can fully suppress generation | occurrence | production of noise can be provided.

It is a perspective view which shows the external appearance of the centrifugal air blower which concerns on 1st embodiment of this invention. It is sectional drawing which shows the II-II cross section in FIG. It is a figure for demonstrating the flow of the air inside a centrifugal blower, Comprising: It is a figure explaining the case where there is no guide plate. It is a figure for demonstrating the flow of the air in a centrifugal blower inside, Comprising: It is a figure explaining the case where there exists a guide plate. It is a figure which shows typically the shape of the small flow path divided by the guide plate. It is sectional drawing which shows typically the structure of the centrifugal blower which concerns on 2nd embodiment of this invention. It is a figure which shows typically the shape of the small flow path divided by the guide plate.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In order to facilitate the understanding of the description, the same constituent elements in the drawings will be denoted by the same reference numerals as much as possible, and redundant description will be omitted.

  As shown in FIGS. 1 and 2, the centrifugal blower 10 according to the first embodiment of the present invention includes a case 20, a flat panel 30, a plurality of guide plates 41, 42, 43, 44, and a fan 50. And. In FIG. 1, the axis orthogonal to the flat panel 30 is defined as the y axis, and the x axis and the z axis are defined so as to define the xz plane orthogonal to the y axis. In FIG. 2 and subsequent figures, the x-axis, y-axis, and z-axis defined in FIG. 1 are described for convenience of explanation. FIG. 2 illustrates a cross-sectional view in the xy plane including II-II indicating a cross section in FIG.

  The case 20 is a substantially cylindrical container and houses a fan 50 therein. The case 20 includes a top plate 21, side plates 23, and a bottom plate 25. The top plate 21 forming the upper surface of the case 20 is formed so that the outer periphery thereof is substantially circular. A suction port 22, which is a substantially circular opening, is formed in the central portion of the top plate 21. The suction port 22 serves as an inlet for air sucked into the case 20 from the outside. A bell mouth 221 that extends toward the inside of the case 20 and bends so as to have a reduced diameter is formed on the edge of the suction port 22 in the top plate 21.

  A blower tube 231 is connected to a side plate 23 that forms a cylindrical side surface of the case 20. The blower tube 231 has a rectangular tube shape with a substantially rectangular cross section, and one side surface 231a is connected along the tangential direction of the side plate 23, and is provided in parallel with the one side surface 231a. The side surface 231b is connected to intersect the side plate 23. A top surface 231c and a bottom surface 231d are provided so as to connect the one side surface 231a and the other side surface 231b. The side plate 23 is formed with a substantially rectangular opening (not shown) so as to be connected to the blower tube 231. A blower port 24 is formed at the other end portion opposite to the one end portion connected to the side plate 23 of the blower tube 231. The air flow generated by the rotation of the fan 50 swirls in the space in the side plate 23, is sent out from the opening (not shown) of the side plate 23 to the blowing cylinder 231, and is blown out from the blowing port 24 to the outside.

  The flat panel 30 is a substantially circular plate and is arranged on the outer side of the case 20 so as to be separated from the top plate 21. The flat panel 30 is arranged in parallel to the top plate 21, and substantially the entire top plate 21 is viewed from the top (in the direction of viewing the case 20 from the flat panel 30, in the direction of viewing the negative direction from the positive direction of the y axis). Covering. The flat panel 30 is fixed to the case 20 by interposing a plurality of columns (not shown) standing on the top plate 21. Further, the guide plates 41 to 44 are fixed to the case 20 by the support columns.

  Ambient air sucked by the blower 10 flows from the side between the flat panel 30 and the top plate 21 and flows along the top plate 21 toward the suction port 22. Thereafter, the air flows into the case 20 from the suction port 22 and is blown out from the air blowing port 24 to the outside of the case 20.

  The guide plates 41 to 44 are plates arranged to guide the flow of air passing through the suction port 22. That is, it is arranged so as to guide both the flow of air flowing between the flat panel 30 and the top plate 21 toward the suction port 22 and the flow of air flowing through the suction port and flowing into the case 20. It is a board. Specific shapes and functions of the guide plates 41 to 44 will be described in detail later.

  The fan 50 is a centrifugal multiblade fan and generates a suction force required when the blower 10 sucks air. The fan 50 includes a motor 51, a rotating shaft 52, a support plate 53, and a plurality of blades 54.

  The motor 51 is a rotary electric motor, and is fixed to a position that is approximately the center of the bottom plate 25 inside the case 20. The rotation shaft 52 is a metal rod arranged such that a center line CA, which is a virtual line along the rotation center, is along the normal direction of the bottom plate 25. The rotating shaft 52 is for transmitting the rotational force of the motor 51 to a support plate 53 described later. When the motor 51 is driven by a control device (not shown), the rotation shaft 52 rotates around the center line CA.

  The support plate 53 is a plate-shaped member having a substantially circular shape, and includes a central portion 531, an outer peripheral portion 532, and an inclined portion 533. The central portion 531 is a disc-shaped portion provided in the center of the support plate 53. The outer peripheral portion 532 is an annular portion provided outside the central portion 531 so as to be separated from the central portion 531. The inclined portion 533 is a portion that connects the central portion 531 and the outer peripheral portion 532. The center of the center portion 531 is fixed to the upper end of the rotation shaft 52, and the support plate 53 is supported from below by the rotation shaft 52. An inclined portion 533 is formed between the central portion 531 and the outer peripheral portion 532 so that the outer peripheral portion 532 is at a position lower than the upper end of the rotation shaft 52 (position close to the bottom plate 25).

  The blades 54 are a plurality of plates arranged so as to extend upward (from the top plate 21 side) from a part of the outer peripheral portion 532 and the inclined portion 533. All of the blades 54 have the same shape and are arranged so as to be substantially parallel to each other. A ring 55 is disposed above the blades 54, and the upper ends of all the blades 54 are fixed to the ring 55. In addition, since the blades 54 are arranged so as to form a cylindrical shape as a whole at positions corresponding to only a part of the outer peripheral portion 532 and the inclined portion 533, a plurality of blades 54 are provided at the center and the upper side of the support plate 53. A space SP surrounded by the blades 54 is formed.

  When the motor 51 is driven and the rotating shaft 52, the support plate 53, and the blades 54 are rotated about the center line CA, centrifugal force is applied to the air in the vicinity of the blades 54, so that the air passes through the blades 54 from the space SP. As a result, air flows outward. Due to this air flow, a negative pressure is generated in the space SP, and air flows into the case 20 from the suction port 22. The air that has passed through the blades 54 and has reached the vicinity of the side plate 23 flows through the inside of the case 20 and the blower cylinder 231 along the side plate 23, and is then blown out from the blower opening 24 at the end of the blower cylinder 231. .

  As is clear from the above description, the fan 50, which is a centrifugal multiblade fan, enters the space SP from the direction along the center line CA (from the upper side in FIG. 2, from the direction toward the negative direction from the y-axis positive direction). Air is sucked and blown out toward the outside. In the present embodiment, the circular suction port 22 formed in the top plate 21 is formed at a position where the center line CA passes through the center thereof. In other words, the suction port 22 is formed in the case 20 at a position where air flows in from the direction along the rotation shaft 52.

  The shape of the guide plates 41, 42, 43, 44 will be described with reference to FIG. The guide plate 41 is a metal plate formed so that the outer shape in a top view is substantially the same circle as the flat panel 30. The guide plate 41 has a flat plate portion 41a and a bent portion 41b. The flat plate portion 41a is a portion arranged outside the bent portion 41b and has a substantially annular shape. The flat plate portion 41 a is substantially parallel to the flat panel 30 and is in contact with the flat panel 30 from the lower surface side.

  In the bent portion 41b, a half cross section centered on the center line CA is an arc-shaped cross section that approximates an arc obtained by dividing a circle into a third. The bent portion 41b is smoothly connected to the flat plate portion 41a so that the tangent at the end on the flat plate portion 41a side is along the flat plate portion 41a. The bent portion 41b is arranged such that a tangent line at a portion closest to the center line CA is along the center line CA. The cross-sectional shape of the bent portion 41b is a line-symmetric shape with the center line CA as the center.

  The guide plate 41 is inclined so as to approach the lower side (suction port 22 side) as it approaches the center line CA from the outer peripheral side, and has a shape whose cross section is bent as shown in FIG. A portion of the guide plate 41 arranged outside the case 20, that is, a portion above the top plate 21 in FIG. 2 is provided on the suction port 22 side (that is, the lower side, the y-axis negative direction side). It has a small-diameter portion 411 and a large-diameter portion 412 provided on the opposite side to the suction port 22 (that is, the upper side and the y-axis positive direction side) across the small-diameter portion 411. It has become. A portion from the small diameter portion 411 to the large diameter portion 412 of the guide plate 41 corresponds to the second portion in the present invention.

  A part of the bent portion 41b is inserted into the suction port 22 and is disposed in the space SP. As shown in FIG. 2, the cross-sectional shape of the guide plate 41 is a shape that is bent continuously and smoothly from the outside to the inside of the case 20. A portion of the guide plate 41 disposed inside the case 20, that is, a portion below the top plate 21 in FIG. 2 is provided on the suction port 22 side (that is, the upper side, the y-axis positive direction side). It has a small-diameter portion 413 and a large-diameter portion 414 provided on the side opposite to the suction port 22 across the small-diameter portion 413 (that is, the lower side, the y-axis negative direction side). It has become. A portion from the small diameter portion 413 to the large diameter portion 414 of the guide plate 41 corresponds to the first portion in the present invention.

  In the present embodiment, the guide plate 41 has a shape obtained by rotating the cross section shown in FIG. 2 around the center line CA. For this reason, the shape in the cross section perpendicular to the center line CA is a circle centered on the center line CA.

  Each of the guide plates 42 to 44 has a shape similar to that of the guide plate 41, and each cross section has a shape symmetrical with respect to the center line CA. The guide plate 42 is disposed at a position outside the guide plate 41 when viewed from the center line CA, and a small flow path 410 partitioned by these is formed between the guide plate 41 and the guide plate 42. ing. The guide plate 43 is disposed at a position outside the guide plate 42 as viewed from the center line CA, and a small flow path 420 partitioned by these is formed between the guide plate 42 and the guide plate 43. ing. The guide plate 44 is disposed at a position outside the guide plate 43 as viewed from the center line CA, and a small flow path 430 partitioned by these is formed between the guide plate 43 and the guide plate 44. ing. Further, a small flow path 440 partitioned by these is formed between the guide plate 44 and the top plate 21 and the bell mouth 221 of the case 20.

  The air flowing in the small flow paths 410 to 440 flows along the flat panel 30 so as to approach the center line CA, and then flows into the space SP from the suction port 22 while smoothly changing the flow direction. . After flowing into the space SP, the flow direction is further changed to flow away from the center line CA. The small flow paths 410 to 440 partitioned by the guide plates 42 to 44 are all bent flow paths so that the air flow becomes such a flow.

  The function of the guide plates 41 to 44 having the above shape will be described with reference to FIGS. 3 and 4. First, the flow of air sucked into the blower 10 when the guide plates 41 to 44 are not present will be described with reference to FIG. 3, and then the guide plates 41 to 44 are present with reference to FIG. The flow of the air sucked into the blower 10 in the case of performing will be described. FIG. 3 schematically shows a cross section similar to that shown in FIG. 2, but shows the flow of air sucked into the blower 10 when the guide plates 41 to 44 are not present. .

  As already described, when the motor 51 is driven and the blades 54 are rotated, a negative pressure is generated in the space SP, whereby air flows into the case 20 from the suction port 22. Even in the case where the guide plates 41 to 44 are not present, the sucked air flows along the flat panel 30 so as to approach the center line CA, and then flows into the space SP from the suction port 22 while changing the flow direction. To do. The air flowing into the space SP further changes its flow direction and flows in a direction away from the center line CA. The air that has flowed into the space SP flows toward the blades 54.

  The flow of air bent in this way is indicated by arrows with symbols FL1, FL2, and FL3 in FIG. In the following, the air flows indicated by these arrows are denoted as bent flows FL1, FL2, and FL3, respectively.

  The bent flow FL1 is a flow in the outermost part of the bent flow. That is, the air flow passes through the vicinity of the flat panel 30, the vicinity of the center line CA, and the vicinity of the support plate 53 in order, and then passes through the lower portion (portion on the bottom plate 25 side) of the blades 54.

  The bent flow FL3 is a flow in the innermost portion of the bent flow. That is, the air flows in such a manner that it passes through the vicinity of the top plate 21 and the vicinity of the edge of the suction port 22 (bell mouth 221) in order, and then passes through the upper portion (portion on the top plate 21 side) of the blades 54. is there.

  The bent flow FL2 is an air flow between the bent flow FL1 and the bent flow FL3. The bent flows FL1, FL2, FL3 are all bent flows as described above, and are substantially parallel to each other.

  When the air is bent and flows in this way, the air receives a centrifugal force from the inside to the outside of the bent flow. A part of the air in the bent flow FL3 leaves the bent flow FL3 and joins the bent flow FL2 due to the influence of the centrifugal force. Such an air flow is indicated by an arrow AR1 in FIG.

  Similarly, part of the air in the bent flow FL2 leaves the bent flow FL2 and joins the bent flow FL1 due to the influence of centrifugal force. Such an air flow is indicated by an arrow AR2 in FIG.

  In this way, due to the centrifugal force, part of the air is directed to the outside of the bent flow, so the flow rate of the bent flow FL1 (the flow of the air that passes through the innermost of the suction ports 22) is the outermost flow. There is a tendency that it becomes larger than the flow velocity of the other bent flows FL2, FL3. As a result, the flow velocity distribution of the air reaching the blades 54 is not uniform, high-speed air (bending flow FL1) reaches the lower end portion of the blades 54, and low-speed air (bending flow FL3) reaches the upper end portion. ) Will be reached. As a result of intensive studies by the present inventors, when such an uneven velocity distribution occurs in the air reaching the blades 54, the operating sound (turbulent sound) of the blower 10 increases. Is known.

  If the guide plates 41 to 44 are not present, the air flow to be sucked is as shown above and as shown in FIG. 3, and turbulent noise is generated due to the velocity distribution. The blower 10 according to the present embodiment is actually provided with the guide plates 41 to 44, thereby suppressing the non-uniform velocity distribution as described above and suppressing an increase in turbulent sound.

  FIG. 4 schematically shows a cross section similar to that shown in FIGS. 2 and 3, but unlike FIG. 3, the air sucked into the blower 10 while being guided by the guide plates 41 to 44. Shows the flow. In FIG. 4, the flow in the small flow path 410 among the flow of air sucked is shown as a bent flow FL11. Similarly, the flow in the small flow path 420 is shown as a bent flow FL12, the flow in the small flow path 430 is shown as a bent flow FL13, and the flow in the small flow path 440 is shown as a bent flow FL14.

  The shape of the guide plates 41 to 44 is such that the guide plates 41 to 44 are divided into a plurality of flows along the bent flows FL1 to FL3 (that is, the air flow when there is no guide plate 41 or the like) shown in FIG. ing. That is, the flow direction of each of the small flow paths 410 to 440 defined by the guide plates 41 to 44 and the top plate 21 is substantially along the air flow when the guide plates 41 to 44 are not present. ing.

  However, when the guide plates 41 to 44 are provided as shown in FIG. 4, unlike the case of FIG. 3, the bending flows FL11 to FL13 are separated from each other by the guide plates 41 to 44. For this reason, centrifugal force acts on each bent flow FL13 and the like, but there is no flow where, for example, a part of air from the bent flow FL13 joins the bent flow FL12.

  That is, the phenomenon that the air passing through the outside of the suction port 22 (near the bell mouth 221) merges with the air passing through the inside of the suction port 22 (near the center line CA) is shown in FIGS. This is prevented by the guide plates 41 to 44 shown in FIG. Since the local increase in the air flow rate due to the merging is suppressed, the velocity distribution of the air reaching the blades 54 becomes substantially uniform. That is, the flow velocities of the bent flows FL11, FL12, FL13, FL14 are substantially equal to each other. As a result, generation of noise due to non-uniform velocity distribution is also suppressed.

  In recent years, it has been strongly demanded to reduce the thickness of the blower 10, that is, to reduce the size in the vertical direction (y-axis direction) in FIG. When the thickness is reduced in this way, the radius of curvature of the bent flow path is further reduced, and the centrifugal force received by the air is further increased. However, in the present embodiment, since the joining of the bent flows is reliably suppressed by the guide plates 41 to 44, the flow velocity distribution of the air reaching the blades 54 is kept substantially uniform even when the thickness is reduced. Can do.

  The portions where the shapes of the guide plates 41 to 44 are devised will be described in more detail with reference to FIG. 2 again. In the vicinity of the upstream end of the small channel 410 and the like, the flat panel 30, the guide plates 41 to 44, and the top plate 21 are parallel to each other. Moreover, in the said part, the space | interval of the mutually adjacent guide plates and the space | interval of the guide plate 44 and the top plate 21 are all equal.

  In FIG. 2, the cross section of the opening (inlet) at the upstream end of the small flow path 410 is indicated by a dotted line DI1. Similarly, the cross section of the opening at the upstream end of the small flow path 420 is indicated by a dotted line DI2, the cross section of the opening at the upstream end of the small flow path 430 is indicated by a dotted line DI3, and the upstream end of the small flow path 440 A cross section of the opening at is indicated by a dotted line DI4. The dotted lines DI1 to DI4 have the same length. With the configuration described above, the cross-sectional areas of the small channels 410 to 420 are equal to each other on the inlet side.

  On the other hand, in the vicinity of the downstream end portion (end portion on the space SP side) of the small flow path 410 and the like, the distance between the guide plate 41 and the guide plate 42 is the largest, and the guide plate 44 and the top plate 21 are separated from each other. The interval of is the narrowest. The channel cross-sectional areas of the small channels 410 to 420 are not equal to each other on the outlet side, and gradually decrease from the inner side (guide plate 41 side) to the outer side (top plate 21 side).

  In FIG. 2, the cross section of the opening (exit) at the downstream end of the small flow path 410 is indicated by a dotted line DO1. Similarly, the cross section of the opening at the downstream end of the small flow path 420 is indicated by a dotted line DO2, the cross section of the opening at the downstream end of the small flow path 430 is indicated by a dotted line DO3, and the downstream end of the small flow path 440 A cross section of the opening at is indicated by a dotted line DO4. As apparent from the above description, the dotted lines DO1 to DO4 have the longest dotted line DO1 and the shortest dotted line DO4.

  Here, for each of the small channels 410 and the like, the ratio of the channel cross-sectional area of the outlet to the channel cross-sectional area of the inlet is defined as the “cross-sectional area enlargement ratio” of the small channel. The cross-sectional area enlargement ratio of the small flow path 410 is the largest, the cross-sectional area enlargement ratio of the small flow path 420 is the second largest, and the cross-sectional area enlargement ratio of the small flow path 430 is the third largest. Thus, the cross-sectional area enlargement ratio of the small flow path 440 is the smallest. That is, the cross-sectional area enlargement ratio of the small flow path formed on the inner side (side closer to the center line CA) is the cross-sectional area enlargement ratio of the small flow path formed on the outer side (the side far from the center line CA). Is bigger than. In the present embodiment, the values of the respective cross-sectional area enlargement ratios are all smaller than 1.

  By the way, it should be noted that the magnitude relation of the channel cross-sectional area for each small channel 410 or the like is not simply determined by the length of the dotted line DI1 or the like in FIG. This will be described with reference to FIG. FIG. 5 schematically shows the shape of the small flow path 410 partitioned by the guide plate 41 and the guide plate 42. As shown in FIG. 5, the channel cross-sectional area at the entrance of the small channel 410 is the area of a surface FG1 obtained by rotating the dotted line DI1 in FIG. 2 around the center line CA. Further, the channel cross-sectional area at the outlet portion of the small channel 410 is an area of a surface FG2 obtained by rotating the dotted line DO1 in FIG. 2 around the center line CA.

  The magnitude relationship between the area of the surface FG1 and the area of the surface FG2 is not determined only by the length of the dotted line DI1 and the dotted line DO1. Even if the dotted line DI1 is shorter than the dotted line DO1, the dotted line DI1 is larger in the distance from the center line CA. Therefore, the area of the surface FG1 (the flow path cross-sectional area at the inlet portion) is larger than that of the surface FG2. It becomes larger than the area (the cross-sectional area of the flow path at the outlet portion). Although only the small flow path 410 is illustrated in FIG. 5, the same applies to the size of the cross-sectional area of the other small flow paths (420 to 440).

  Returning to FIG. 2, the description will be continued. Each of the small channels 410 has a smaller channel cross-sectional area as it approaches the outlet from the inlet. For this reason, the air flow rate through each small flow path gradually increases as it goes downstream. In the present embodiment, as described above, the cross-sectional area enlargement ratio of the small flow path formed on the inner side (side closer to the center line CA) is formed on the outer side (side far from the center line CA). It is larger than the cross-sectional area enlargement ratio of the small flow path.

  Therefore, the flow velocity of the air flowing through each small flow channel 410 and the like is substantially the same at the inlet portion, but at the outlet portion, the flow velocity of the small flow channel 440 having the smallest cross-sectional area expansion rate. Is the largest.

  With such a configuration, air having a relatively high flow velocity is supplied toward the vicinity of the upper end portion of the blade 54 that tends to have the lowest flow velocity. On the other hand, air having a relatively low flow rate is supplied toward the vicinity of the lower end portion of the blade 54 that tends to have the highest flow rate. As a result, the flow velocity distribution of the air reaching the blades 54 is more uniform.

  In this embodiment, the guide plates 41 to 44 are arranged so as to extend from the outside of the case 20 to the inside, but the guide plate may be arranged only inside the case 20. Good. That is, it is good also as a structure where only the part below the top plate 21 exists among the guide plates 41 thru | or 44 shown in FIG. Even in such an embodiment, the flow of air bent in the space SP can be guided by the guide plates 41 to 44, and the flow velocity distribution of the air reaching the blades 54 can be made substantially uniform.

  Conversely, the guide plate may be arranged only outside the case 20. That is, only the part above the top plate 21 may exist among the guide plates 41 to 44 shown in FIG. Even in such a mode, the flow of air bent when flowing into the suction port 22 is guided by the guide plates 41 to 44, and the flow velocity distribution of the air reaching the blades 54 is made substantially uniform. be able to. In this case, in view of the fact that the air bends and flows in the space SP (there is no guide plate 41 or the like), the flow velocity of air from the innermost small flow path 410 to the space SP is the outermost small flow path. It is desirable to configure so as to be slower than the flow velocity of air from 440 toward the space SP.

  In the present embodiment, the four guide plates 41 to 44 are provided, but the number of guide plates may be changed as appropriate. For example, a single guide plate may be provided instead of a plurality of guide plates.

  Subsequently, a blower 10A according to a second embodiment of the present invention will be described with reference to FIG. The blower 10 </ b> A is different from the blower 10 in that it does not have a flat panel and the shape of the guide plate, but other configurations are the same as the blower 10. For this reason, below, only the structure different from the air blower 10 of 10 A of air blowers is demonstrated.

  The blower 10A includes four guide plates 41A to 44A arranged so as to surround the center line CA. Each of the guide plates 41A to 44A has a cross-sectional shape that is line-symmetric about the center line CA.

  The guide plate 44 </ b> A is disposed on the outermost side, and the outer peripheral surface thereof is in contact with the edge of the suction port 22. Of the guide plate 44A, a portion arranged outside the case 20, that is, a portion above the top plate 21 in FIG. 6, is a small diameter portion 441A provided on the suction port 22 side (ie, the lower side), and a small diameter portion. It has a large-diameter portion 442A provided on the opposite side (ie, the upper side) of the suction port 22 with the portion 441A interposed therebetween, so that the entirety is a horn type. A part of the guide plate 44 </ b> A is inserted through the suction port 22. A portion from the small diameter portion 441A to the large diameter portion 442A in the guide plate 44A corresponds to the second portion in the present invention.

  The guide plate 43A is disposed on the inner side (center line CA side) than the guide plate 44A. A portion of the guide plate 43A arranged outside the case 20, that is, a portion above the top plate 21 in FIG. 6, is a small-diameter portion 431A provided on the suction port 22 side (ie, the lower side), and a small-diameter portion. It has a large-diameter portion 432A provided on the opposite side (that is, the upper side) to the suction port 22 with the portion 431A interposed therebetween, so that the whole is a horn type. A portion from the small diameter portion 431A to the large diameter portion 432A in the guide plate 43A corresponds to the second portion in the present invention.

  A part of the guide plate 43A is inserted through the suction port 22. Of the guide plate 43A, a portion disposed inside the case 20, that is, a portion below the top plate 21 in FIG. 6, is a small diameter portion 433A provided on the suction port 22 side (ie, the upper side), and a small diameter portion. It has a large-diameter portion 434A provided on the side opposite to the suction port 22 (that is, the lower side) across the portion 433A, and the whole is a horn type. A portion from the small diameter portion 433A to the large diameter portion 434A in the guide plate 43A corresponds to the first portion in the present invention.

  Both of the guide plates 42A and 41A have substantially the same shape as the guide plate 43A. However, for the guide plate 41A arranged on the innermost side, the shape of the portion arranged outside the case 20 is not a horn shape, and has the same diameter from the upper side to the lower side, That is, it has a cylindrical shape. In the present embodiment, the guide plates 41A to 44A all have the same distance (height) from the upper end position to the top plate 21.

  A small channel 410A partitioned by these is formed between the guide plate 41A and the guide plate 42A. Between the guide plate 42A and the guide plate 43A, a small flow path 420A partitioned by these is formed. Between the guide plate 43A and the guide plate 44A, a small flow path 430A partitioned by these is formed.

  Also in the present embodiment, the air flow passing through the inside of the suction port 22 and the air flow passing through the outside are separated by the guide plates 41A to 44A.

  As in the case of FIG. 2, in FIG. 6, the cross section of the opening (inlet) at the upstream end of the small flow path 410A is indicated by a dotted line DI1A. Similarly, the cross section of the opening at the upstream end of the small flow path 420A is indicated by a dotted line DI2A, and the cross section of the opening at the upstream end of the small flow path 430A is indicated by a dotted line DI3A. As apparent from the above description, the dotted lines DI1A to DI3A have the same length.

  On the other hand, in the vicinity of the downstream end (the end on the space SP side) of the small flow path 410A and the like, the distance between the guide plate 44A and the guide plate 43A is the smallest, and the guide plate 42A and the guide plate 41A The interval is the widest.

  In FIG. 6, the cross section of the opening (exit) at the downstream end of the small flow path 410A is indicated by a dotted line DO1A. Similarly, the cross section of the opening at the downstream end of the small flow path 420A is indicated by a dotted line DO2A, and the cross section of the opening at the downstream end of the small flow path 430A is indicated by a dotted line DO3A. As apparent from the above description, the dotted lines DO1A to DO3A have the shortest dotted line DO3A and the longest dotted line DO1A.

  Also in this embodiment, the cross-sectional area expansion rate of the small flow path 410A which is the innermost flow path is the largest. Further, the cross-sectional area enlargement ratio of the small flow path 420A which is the outer flow path is the second largest, and the cross-sectional area enlargement ratio of the small flow path 430A which is the outermost flow path is the smallest.

  In the present embodiment, the value of the cross-sectional area enlargement ratio of the small flow path 430A is smaller than 1, and the value of the cross-sectional area enlargement ratio of the small flow path 420A is also smaller than 1. That is, for the small channel 430A and the small channel 420A, the channel cross-sectional area at each outlet is smaller than the channel cross-sectional area at the inlet.

  On the other hand, the value of the cross-sectional area enlargement ratio of the small flow path 410A is larger than 1. That is, the channel cross-sectional area (the area of the surface obtained by rotating the dotted line DO1A around the center line CA and the area of the surface FG2A in FIG. 7) on the outlet side of the small channel 410A is the small channel. It is larger than the cross-sectional area of the channel on the inlet side of 410A (the area of the surface obtained by rotating the dotted line DI1A around the center line CA and the area of the surface FG1A in FIG. 7). FIG. 7 schematically shows the shape of the small flow path 410A partitioned by the guide plate 41A and the guide plate 42A.

  As described above, the value of the cross-sectional area enlargement ratio of the small flow path 430A formed on the outermost side is smaller than 1, and the value of the cross-sectional area enlargement ratio of the small flow path 410A formed on the innermost side is greater than 1. Is also big. By setting it as such a structure, the flow velocity in the exit part of 430 A of small flow paths becomes larger than the flow rate in an entrance part. On the other hand, the flow velocity at the outlet of the small channel 410A is smaller than the flow velocity at the inlet. As a result, air having a relatively high flow velocity is supplied toward the vicinity of the upper end portion of the blade 54 that tends to have the lowest flow velocity. On the other hand, air having a relatively slow flow rate is supplied toward the vicinity of the lower end of the blade 54 that tends to have the highest flow rate. As a result, the flow velocity distribution of the air reaching the blades 54 is more uniform.

  The embodiments of the present invention have been described above with reference to specific examples. However, the present invention is not limited to these specific examples. In other words, those specific examples that have been appropriately modified by those skilled in the art are also included in the scope of the present invention as long as they have the characteristics of the present invention. For example, the elements included in each of the specific examples described above and their arrangement, materials, conditions, shapes, sizes, and the like are not limited to those illustrated, but can be changed as appropriate. Moreover, each element with which each embodiment mentioned above is provided can be combined as long as technically possible, and the combination of these is also included in the scope of the present invention as long as it includes the features of the present invention.

10, 10A: Blower 20: Case 22: Suction port 41, 42, 43, 44, 41A, 42A, 43A, 44A: Guide plate 410, 420, 430, 440, 410A, 420A, 430A: Small channel 50: Fan 54: Blade 411, 413: Small diameter part 412, 414: Large diameter part

Claims (3)

A blower (10, 10A) for blowing out the sucked air to the outside,
A centrifugal multiblade fan (50) for sucking air and blowing the sucked air to the outside;
A case (20) in which the centrifugal multiblade fan is housed, and a suction port (22) is formed so that air flows in from a direction along the rotation axis (52) of the centrifugal multiblade fan; ,
Single or a plurality of guide plates (41) for guiding the flow of air passing through the suction port and separating the flow of air passing outside the suction port and the flow of air passing inside the suction port , 42, 43, 44), and
The guide plate has a first portion disposed inside the case,
The first portion includes a first small diameter portion (413) provided on the suction port side, and a first large diameter portion (414) provided on the opposite side of the suction port across the first small diameter portion, Have
The air flow path passing through the suction port is partitioned into a plurality of small flow paths (410, 420, 430, 440, 410A, 420A, 430A) by the guide plate,
For the inlet portion on the air inflow side and the outlet portion on the air outflow side of each small channel, the ratio of the channel cross-sectional area of the outlet portion to the channel cross-sectional area of the inlet portion is set to When the cross-sectional area enlargement ratio is taken,
The cross-sectional area enlargement ratio of the small channel formed inside the suction port is
A blower larger than the cross-sectional area expansion rate of the small flow path formed outside the suction port . A blower (10, 10A) for blowing out the sucked air to the outside,
  A centrifugal multiblade fan (50) for sucking air and blowing the sucked air to the outside;
  A case (20) in which the centrifugal multiblade fan is housed, and a suction port (22) is formed so that air flows in from a direction along the rotation axis (52) of the centrifugal multiblade fan; ,
  Single or a plurality of guide plates (41) for guiding the flow of air passing through the suction port and separating the flow of air passing outside the suction port and the flow of air passing inside the suction port , 42, 43, 44), and
The guide plate has a second portion arranged outside the case,
  The second portion includes a second small diameter portion (411) provided on the suction port side, a second large diameter portion (412) provided on the opposite side of the suction port across the second small diameter portion, Have
The air flow path passing through the suction port is partitioned into a plurality of small flow paths (410, 420, 430, 440, 410A, 420A, 430A) by the guide plate,
  For the inlet portion on the air inflow side and the outlet portion on the air outflow side of each small channel, the ratio of the channel cross-sectional area of the outlet portion to the channel cross-sectional area of the inlet portion is set to When the cross-sectional area enlargement ratio is taken,
  The cross-sectional area enlargement ratio of the small channel formed inside the suction port is
  A blower larger than the cross-sectional area expansion rate of the small flow path formed outside the suction port. In the small channel (410A) formed at the innermost side of the suction port, the value of the cross-sectional area enlargement ratio is larger than 1,
The blower according to claim 1 or 2 , wherein a value of the cross-sectional area enlargement ratio is smaller than 1 in the small flow path (430A) formed on the outermost side of the suction port.

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