JP6376504B2 - Separation device - Google Patents

Description

  The present invention relates to a separation device, and more particularly to a separation device that separates solids in a gas.

  Conventionally, as this kind of separation device, for example, a dustproof device for separating dust from air is known (Patent Document 1).

  The dustproof device described in Patent Document 1 includes a cylinder (rotor), an outer cylinder (frame body) surrounding the cylinder, a rotor, a sirocco fan, and a fan motor.

  A plurality of main blades (partition plates) for efficiently rotating the dust mixture air are provided on the outer peripheral surface side of the cylinder. A part of the cylinder is provided with a hole through which air flows.

  The rotor has a vent that guides air through the interior of the cylinder to the sirocco fan.

  In the dustproof device, when the dust mixed air spirally descends while rotating at high speed, a stronger centrifugal force acts on the dust having a larger mass than the air, so that the dust is pushed toward the wall surface of the outer cylinder.

  In the dustproof device, air is cleaned by separating air and dust.

  In the field of separation devices, development of separation devices that can efficiently separate solids from gas is desired.

JP 2001-87610 A

  An object of the present invention is to provide a separation apparatus capable of efficiently separating a solid from a gas.

  The separation device according to one aspect of the present invention is disposed in a rotor, a cylindrical frame that is disposed coaxially with the rotor so as to surround the rotor, and a space between the rotor and the frame. A plurality of partition plates for partitioning the space, a plurality of flow passages each defined by the two partition plates adjacent to each other among the plurality of partition plates, the rotor and the frame, and the plurality of partition plates. An annular rotating plate coupled to the rotor; and a driving device that rotates the rotor. Each of the plurality of partition plates is connected to the rotor. In each of the plurality of flow paths, the first end side of the rotor is the upstream side and the second end side of the rotor is the downstream side in the direction along the rotation center axis of the rotor. Each of the plurality of partition plates has the first end surface on the upstream side and the second end surface on the downstream side in a direction along the rotation center axis. The rotating plate is connected to the plurality of partition plates on the second end face side of each of the plurality of partition plates. The separation device is on the rotation center axis side of the plurality of flow paths on the downstream side of each of the plurality of flow paths, communicates with at least one of the plurality of flow paths, and is orthogonal to the rotation center axis. At least one central outlet that is open in a direction to be moved, and on the downstream side of each of the plurality of flow paths, in a direction perpendicular to the rotation center axis, outside the plurality of partition plates, and An outer peripheral outlet that communicates with at least one flow path and is open in a direction perpendicular to the rotation center axis. The rotating plate is sized to cover the plurality of partition plates and the space on the downstream side of each of the plurality of flow paths.

FIG. 1A is a schematic cross-sectional view of a separation apparatus according to Embodiment 1 of the present invention. FIG. 1B is a schematic perspective view of a separation unit in the separation device according to the embodiment. FIG. 2A is a schematic cross-sectional view of a separation unit in the separation apparatus same as above. 2B is a schematic cross-sectional view corresponding to the X1-X1 cross section of FIG. 2A. FIG. 2C is a schematic cross-sectional view corresponding to the X2-X2 cross section of FIG. 2A. FIG. 3 is a schematic explanatory diagram of an air purification system provided with the above separation device. FIG. 4 is a schematic perspective view of an outdoor unit to which the above separation device is applied. FIG. 5A is a schematic cross-sectional view of a separation unit in a separation apparatus according to a first modification of Embodiment 1 of the present invention. FIG. 5B is a schematic cross-sectional view corresponding to the X1-X1 cross section of FIG. 5A. FIG. 5C is a schematic cross-sectional view corresponding to the X2-X2 cross section of FIG. 5A. FIG. 6 is a schematic perspective view of a separation unit in the separation apparatus of the above. FIG. 7A is a schematic front view, partly broken, of a separation unit in a separation apparatus according to a second modification of Embodiment 1 of the present invention. FIG. 7B is a schematic cross-sectional view corresponding to the X1-X1 cross section of FIG. 7A. FIG. 7C is a schematic cross-sectional view corresponding to the X2-X2 cross section of FIG. 7A. FIG. 8A is a schematic cross-sectional view of a separation unit in a separation apparatus according to a third modification of Embodiment 1 of the present invention. FIG. 8B is a schematic cross-sectional view corresponding to the X1-X1 cross section of FIG. 8A. FIG. 8C is a schematic cross-sectional view corresponding to the X2-X2 cross section of FIG. 8A. FIG. 9A is a schematic front view, partly broken, of a separation unit in a separation apparatus according to a fourth modification of Embodiment 1 of the present invention. FIG. 9B is a schematic cross-sectional view corresponding to the X1-X1 cross section of FIG. 9A. FIG. 9C is a schematic cross-sectional view corresponding to the X2-X2 cross section of FIG. 9A. FIG. 10 is a schematic perspective view of a main part of the separation device. FIG. 11 is a schematic cross-sectional view of a separation apparatus according to Embodiment 2 of the present invention. FIG. 12 is a schematic perspective view of the separation device. FIG. 13 is a schematic explanatory diagram of an air purification system provided with the above separation device.

  Each drawing described in the following embodiments and the like is a schematic diagram, and the ratio of the size and thickness of each component in the drawing does not necessarily reflect the actual dimensional ratio.

(Embodiment 1)
Below, the separation apparatus 1 of this embodiment is demonstrated based on FIG. 1A, 1B, 2A, 2B, 2C, 3 and 4. FIG.

  The separation device 1 includes a rotor 2, a frame body 3, a plurality (for example, three) of partition plates 6, a plurality of (for example, three) flow paths 8, a rotating plate 9, a drive device 7, Is provided. The frame 3 has a cylindrical shape and is disposed coaxially with the rotor 2 so as to surround the rotor 2. The plurality of partition plates 6 are arranged in the space 4 to partition the space 4. Each of the plurality of flow paths 8 is defined by two adjacent partition plates 6, the rotor 2, and the frame body 3 among the plurality of partition plates 6. The rotating plate 9 has an annular shape and is connected to the plurality of partition plates 6. The drive device 7 rotates the rotor 2. Each of the plurality of partition plates 6 is connected to the rotor 2. In each of the plurality of flow paths 8, the first end 21 side of the rotor 2 is the upstream side in the direction along the rotation center axis 20 of the rotor 2, and the second end 22 side of the rotor 2 is the downstream side. Each of the plurality of partition plates 6 has an upstream first end surface 61 and a downstream second end surface 62 in the direction along the rotation center axis 20. The rotating plate 9 is connected to the plurality of partition plates 6 on the second end face 62 side of each of the plurality of partition plates 6. Further, the separation device 1 includes at least one center side opening (hereinafter also referred to as “center outlet”) 25, an outer periphery side opening (hereinafter also referred to as “outer periphery outlet”) 35, and an airflow control unit 40 (see FIG. 3). And). The center outlet 25 is located closer to the rotation center shaft 20 than the plurality of partition plates 6 on the downstream side of each of the plurality of flow paths 8. The center outlet 25 communicates with at least one of the plurality of channels 8 and is opened in a direction perpendicular to the rotation center axis 20. The outer peripheral outlet 35 is outside the plurality of partition plates 6 in the direction orthogonal to the rotation center axis 20 on the downstream side of each of the plurality of flow paths 8. The outer peripheral outlet 35 communicates with at least one of the plurality of channels 8 and is opened in a direction perpendicular to the rotation center axis 20. The rotating plate 9 is sized to cover the plurality of partition plates 6 and the space 4 on the downstream side of each of the plurality of flow paths 8. With the above configuration, the separation device 1 can efficiently separate a solid from a gas. The separation device 1 preferably includes the blower 5 (see FIG. 3) and the airflow control unit 40. The blower 5 is configured to flow gas into the space 4 between the rotor 2 and the frame 3. The airflow control unit 40 controls the flow direction of the gas on the downstream side of at least one of the plurality of channels 8 in the direction toward the center outlet 25. Thereby, the separation device 1 can more efficiently separate the solid from the gas.

  “Arranged coaxially with the rotor 2” means that the frame 3 is arranged so that the center line of the frame 3 is aligned with the rotation center axis 20 of the rotor 2. The “upstream side” in the present specification means the upstream side (primary side) when viewed in the gas flow direction. In addition, “downstream side” in the present specification means the downstream side (secondary side) when viewed in the gas flow direction. The “size covering the plurality of partition plates 6 and the space 4 on the downstream side of each of the plurality of flow paths 8” is not limited to the size covering the entirety of the plurality of partition plates 6 and the space 4. Any size can be used as long as the cross-sectional area of each of the channels 8 can be reduced. The center side opening (center outlet) 25 and the outer periphery side opening (outer periphery outlet) 35 are in the separation unit 10 including the rotor 2, the frame body 3, the plurality of partition plates 6, and the rotating plate 9.

  In FIGS. 1B, 2B, and 2C, the rotation direction of the rotor 2 is schematically shown by thick arrows. The rotation direction of the rotor 2 is a counterclockwise direction when the rotor 2 is viewed from the first end 21 side. The rotation direction of the rotor 2 is a clockwise direction when the rotor 2 is viewed from the second end 22 side. The separation device 1 can apply a force in the rotation direction around the rotation center axis 20 to the gas flowing into each of the plurality of flow paths 8 as the rotor 2 rotates. In the separation device 1, the rotor 2 is rotated counterclockwise as viewed from the first end 21 side, and the blower 5 operates to rotate the substance passing through each of the plurality of flow paths 8 in a spiral manner. be able to. “Rotating in a spiral” has the same meaning as turning in a spiral.

  Examples of the gas include air and exhaust gas. Examples of the substance passing through each of the plurality of flow paths 8 include gas molecules constituting a gas, solids contained in the gas, and the like. Examples of gas molecules include nitrogen molecules and oxygen molecules. Examples of the solid include fine particles and dust. Examples of the fine particles include particulate substances. Examples of the particulate matter include primary generated particles that are directly released into the atmosphere as fine particles, and secondary generated particles that are generated as fine particles in the air that are released into the atmosphere as a gas. Examples of the primary generated particles include soil particles (such as yellow sand), dust, vegetable particles (such as pollen), animal particles (such as mold spores), and soot. Examples of the size classification of the particulate matter include PM2.5 (microparticulate matter), PM10, SPM (floating particulate matter) and the like. PM2.5 is a fine particle that passes through a sizing device having a particle diameter of 2.5 μm and a collection efficiency of 50%. PM10 is a fine particle that passes through a sizing device having a particle diameter of 10 μm and a collection efficiency of 50%. SPM is fine particles that pass through a sizing device having a particle diameter of 10 μm and a collection efficiency of 100%, corresponds to PM 6.5-7.0, and is slightly smaller than PM10.

  In the separation device 1, the rotor 2 is rotated by the driving device 7 and the airflow control unit 40 is operated. Thereby, in the separation apparatus 1, the solid contained in the airflow generated in each of the plurality of flow paths 8 can be discharged from the outer peripheral outlet 35 to the outside, and the gas from which the solid is separated flows from the central outlet 25 to the downstream side. be able to. Therefore, the separation device 1 can efficiently separate the solid from the gas.

  In FIGS. 1A and 1B, the gas flow before the solid is separated is schematically shown by a framing arrow (an arrow with dot hatching), and the gas flow from which the solid is separated is schematically shown by a white arrow. It is shown in 1A, 1B, 2A, and 2C schematically show the fine particles 161 as solids discharged from the outer peripheral outlet 35.

  The blower 5 (see FIG. 3) for flowing gas into the space 4 between the rotor 2 and the frame 3 is constituted by a fan. The fan is an electric fan. Thereby, in the separation apparatus 1, it is possible to flow gas through the plurality of flow paths 8 by operating the blower 5. As the electric fan, for example, an axial fan can be adopted. The blower device 5 is disposed on the downstream side of the drive device 7.

  In the separation device 1 of the present embodiment, the blower device 5 is disposed on the downstream side of the plurality of flow paths 8. In the separation device 1 of the present embodiment, the air blower 5 includes the air flow control unit 40 that controls the flow direction of the gas on the downstream side of at least one of the plurality of channels 8 in the direction toward the center outlet 25. Also serves as. In other words, the airflow control unit 40 in the separation device 1 of the present embodiment is configured by the blower device 5.

  The driving device 7 that rotates the rotor 2 is constituted by a motor 70. The motor 70 has a cylindrical rotating shaft 72 protruding from a motor body (body) 71. In the motor 70, the outer peripheral shape of the motor main body 71 is preferably circular. The outer diameter of the motor body 71 is preferably smaller than the inner diameters of the frame body 3 and the rotating plate 9. The outer diameter of the motor body 71 is preferably smaller than the outer diameter of the rotor 2. In the separation device 1, the rotor 2 is connected to the rotating shaft 72 of the motor 70. In the separating apparatus 1, the rotary shaft 72 and the rotor 2 are coupled so that the axis of the rotary shaft 72 and the rotation center axis 20 of the rotor 2 are aligned. Thereby, the motor 70 can rotate the rotor 2. The rotation direction of the rotor 2 is the same as the rotation direction of the rotation shaft 72 of the motor 70. The rotational angular velocity of the rotor 2 is the same as the rotational angular velocity of the rotating shaft 72 of the motor 70.

  The separation device 1 preferably includes a power supply device 17 (see FIG. 1A) that supplies power to the drive device 7. The power supply device 17 includes, for example, a power supply circuit module 171 that generates and outputs a voltage suitable for the drive device 7 from an AC voltage supplied from an external AC power supply, and a case 172 that houses the power supply circuit module 171. ing. The motor 70 constituting the driving device 7 is supported by a pipe 18 protruding from the case 172 of the power supply device 17. The wiring that electrically connects the power supply device 17 and the drive device 7 is preferably accommodated in the pipe 18 so as not to be exposed.

  When the driving device 7 is configured by the motor 70, the separation device 1 may include a setting unit that sets the rotation speed of the rotation shaft 72 of the motor 70. Thereby, in the separating apparatus 1, it is possible to appropriately change the rotation speed of the rotating shaft 72 of the motor 70 depending on the size of the solid required to be separated. The setting unit can be configured by, for example, a potentiometer.

  In the separation device 1, for example, the shape of the frame 3, the rotor 2, and the plurality of partition plates 6, and the rotation speed of the rotor 2 are set so that fine particles having a prescribed particle diameter can be separated. As fine particles having a prescribed particle diameter, for example, particles having an aerodynamic particle diameter of 1.0 μm are assumed. “Aerodynamic particle size” means the diameter of a particle such that the aerodynamic behavior is equivalent to a spherical particle with a specific gravity of 1.0. Aerodynamic particle size is the particle size measured by the sedimentation rate of the particles. Examples of the solid that remains in the gas without being separated by the separation device 1 include fine particles having a smaller particle diameter than the fine particles that are supposed to be separated by the separation device 1 (in other words, fine particles having a small mass). .

  FIG. 3 is a schematic configuration diagram of an air purification system 300 including the separation device 1.

  Of the separator 1, a module that does not include the blower 5 and the airflow control unit 40 (hereinafter referred to as a separator main body 1 a) is disposed in the housing 302 (see FIG. 4) of the outdoor unit 301 that is disposed outdoors of the dwelling unit 400. Is done. On the other hand, the air blower 5 and the airflow control unit 40 are disposed on the ceiling of the dwelling unit 400. When the separating apparatus 1 does not include the blower 5 and the airflow control unit 40 as constituent elements, the separating apparatus 1 is configured by the separating apparatus main body 1a.

  The separation device main body 1 a is configured to discharge fine particles 161 in the air out of the housing 302 in the outdoor unit 301. The fine particles 161 are fine particles having the above-mentioned prescribed particle diameter, and are assumed to be particles having an aerodynamic particle diameter of 1.0 μm.

  The housing 302 may constitute the outer shell 100 of the separation device 1. The outer shell 100 is configured to house the rotor 2, the frame body 3, the plurality of partition plates 6, the rotating plate 9, and the driving device 7. Further, the above-described power supply device 17 is also housed in the outer shell 100. The power supply device 17 is fixed to the outer shell 100. The outer shell 100 is made of metal.

  The separation device 1 can be configured to include a plurality of supports (not shown) that support the outer shell 100. Thereby, in the separation apparatus 1, it becomes possible to provide a space between the outer shell 100 and the installation surface (for example, a floor surface) of the separation apparatus 1.

  The outer shell 100 is formed with an air inlet 101, a solid outlet 102 for discharging solids such as fine particles 161, and a cleaned air outlet 103. A first mesh 111 is preferably disposed at the inlet 101 of the outer shell 100. A second mesh 112 is preferably disposed at the solid outlet 102 of the outer shell 100. A plurality of solid discharge ports 102 are formed in the outer shell 100. In the separating apparatus 1, the frame 3 is fixed to the outer shell 100. More specifically, in the separation device 1, the frame 3 is fixed to the peripheral portion of the inflow port 101 in the inner wall surface of the outer shell 100. The plurality of solid discharge ports 102 are formed apart in a direction along the outer peripheral direction of the frame 3. The second mesh 112 is preferably smaller in mesh size than the first mesh 111.

  The separation device 1 preferably includes a rotating cylinder 19 connected to the rotating plate 9 on the downstream side of the rotating plate 9. In other words, the separation unit 10 preferably includes the rotating cylinder 19. Accordingly, the separation device 1 can suppress the return of the fine particles 161 discharged from the outer peripheral outlet 35 to the gas that has passed through the opening 92 of the rotating plate 9.

  In addition, the separation device 1 preferably includes a cylindrical duct 15 held on the inner peripheral surface of the outlet 103 in the outer shell 100. The duct 15 is preferably housed in the outer shell 100. The duct 15 includes a first end 151 on the upstream side and a second end 152 on the downstream side. A bearing 16 disposed inside the first end 151 is fixed to the first end 151 of the duct 15. The bearing 16 holds the rotating cylinder 19 rotatably. As a result, in the separation device 1, the rotating structure including the rotor 2, the plurality of partition plates 6, and the rotating plate 9 can be rotated more stably.

  Further, as shown in FIGS. 1A and 4, the separating device 1 preferably includes a bearing 13 that rotatably holds the tip of the rotating shaft 72 of the motor 70. The bearing 13 is held by a plurality of beams 14 supported by the outer shell 100. Thereby, in the separation apparatus 1, it becomes possible to rotate the rotor 2 more stably.

  The air purification system 300 includes a first duct 311 for flowing the air purified by the outdoor unit 301 into the dwelling unit 400, and a filter device 317 for further purifying the air supplied by the first duct 311. Prepare. The filter device 317 includes, for example, a HEPA filter (high efficiency particulate air filter) as an air filter. The “HEPA filter” is an air filter having a particle collection rate of 99.97% or more with respect to particles having a particle size of 0.3 μm at a rated flow rate and an initial pressure loss of 245 Pa or less. The filter device 317 does not make particle collection efficiency of 100% an essential condition. However, it is preferable that the filter device 317 has a higher collection efficiency of the solid contained in the gas.

  In FIG. 3, the air flow is schematically shown by white arrows. FIG. 3 schematically shows the fine particles 161 separated from the air by the separation device main body 1a and discharged, and the ultrafine particles 162 collected by the filter device 317. The ultrafine particles 162 are fine particles having a particle size smaller than that of the fine particles 161 and a particle size that can be removed by a HEPA filter.

  The air purification system 300 includes a second duct 312 disposed between the filter device 317 and the blower device 5, a distributor 318 disposed on the downstream side of the blower device 5, and the blower device 5 and the distributor 318. 3rd duct 313 arrange | positioned between these. A plurality of fourth ducts 314 for supplying air to each of a plurality of sections 401 (for example, a living room, a bedroom, etc.) in the dwelling unit 400 are connected to the distributor 318. The distributor 318 distributes the air supplied from the upstream side to the plurality of fourth ducts 314 on the downstream side. The filter device 317, the second duct 312, the blower device 5, the third duct 313, and the distributor 318 are disposed on the ceiling of the dwelling unit 400.

  In the air purification system 300, the outdoor unit 301 includes the separation device main body 1a, so that it is possible to prevent the fine particles 161 such as PM2.5 from reaching the filter device 317. As a result, the air purification system 300 can extend the life of the filter device 317. In other words, in the air purification system 300, it is possible to suppress an increase in pressure loss due to an increase in the total mass of fine particles or the like collected by the filter device 317. Thereby, in the air purification system 300, the replacement frequency of the filter device 317 can be reduced.

  In the separation device 1, as illustrated in FIG. 1A, the drive device 7 is disposed on the downstream side of the plurality of flow paths 8, and the blower device 5 (see FIG. 3) is disposed on the downstream side of the drive device 7. In short, in the separation apparatus 1, the plurality of flow paths 8, the drive apparatus 7, and the blower apparatus 5 are arranged in the order of the plurality of flow paths 8, the drive apparatus 7, and the blower apparatus 5 in the direction in which gas flows in the separation apparatus 1. Yes. The blower device 5 may be disposed near the drive device 7 on the downstream side of the drive device 7. In this case, the blower device 5 may be provided in the separation device main body 1a.

  The separation device 1 may have a configuration in which an operation unit of an operation switch that starts operation of the blower device 5 and the driving device 7 is exposed from the outer shell 100.

Flow rate of the separation device 1, for example, it may be appropriately set within a range of 250m ³ / h~3000m ³ / h.

  Each component of the separation device 1 will be described in more detail below.

  The rotor 2 is formed in a cylindrical shape. The rotor 2 is configured not to pass the gas and the solid contained in the gas. More specifically, the rotor 2 is a non-porous structure. As a material of the rotor 2, for example, a metal, a synthetic resin, or the like can be used. The rotor 2 preferably has conductivity. Thereby, in the separation apparatus 1, it becomes possible to suppress charging of the rotor 2.

  The frame 3 that surrounds the rotor 2 and is arranged coaxially with the rotor 2 is formed in a cylindrical shape. As a material of the frame 3, for example, a metal, a synthetic resin, or the like can be used. The frame 3 is preferably conductive. Thereby, in the separation apparatus 1, it becomes possible to suppress the charging of the frame 3.

  Each of the plurality of partition plates 6 arranged in the space 4 between the rotor 2 and the frame body 3 and dividing the space 4 is formed in a rectangular plate shape. In each of the plurality of partition plates 6, the longitudinal direction is a direction along the rotation center axis 20, the short side direction is a direction along the radial direction of the rotor 2, and the thickness direction is a direction along the rotation direction of the rotor 2. It is arrange | positioned so that it may become (angular direction). In short, each of the plurality of partition plates 6 is arranged such that the first surface and the second surface in the thickness direction intersect each other in the direction along the rotation direction of the rotor 2.

  The length in the longitudinal direction of each of the plurality of partition plates 6 is larger than the length of the rotor 2 on the rotation center shaft 20. The plurality of partition plates 6 are coupled to the rotor 2 such that a part of each of the partition plates 6 is positioned closer to the rotating plate 9 than the rotor 2 in the direction along the rotation center axis 20 of the rotor 2.

  As a material of each of the plurality of partition plates 6, for example, metal, synthetic resin, rubber or the like can be employed. It is preferable that the some partition plate 6 has electroconductivity. Thereby, in the separation apparatus 1, it becomes possible to suppress charging of the plurality of partition plates 6.

  The plurality of partition plates 6 are connected to only the rotor 2 of the rotor 2 and the frame 3 as described above. “Connected only to the rotor 2” is not limited to the case where each of the plurality of partition plates 6 is formed as a separate member from the rotor 2 and is fixed to the rotor 2, but is formed integrally with the rotor 2, for example. Including cases. In the separation device 1, since the plurality of partition plates 6 are not connected to the frame body 3, the drive device is compared with the case where the plurality of partition plates 6 are fixed to both the rotor 2 and the frame body 3 and both are rotated. 7 can be reduced, and power consumption can be reduced.

  Each of the plurality of partition plates 6 is preferably arranged such that a gap 30 is formed between the inner peripheral surface 33 of the frame body 3. In other words, the separation device 1 has a gap 30 between each of the plurality of partition plates 6 and the inner peripheral surface 33 of the frame 3. Thereby, in the separation apparatus 1, there exists an advantage that manufacture becomes easy. Further, in the separation device 1, compared to the case where the plurality of partition plates 6 are fixed to both the rotor 2 and the frame body 3 and both are rotated, or when the plurality of partition plates 6 are in contact with the frame body 3, The load on the drive device 7 can be reduced, and the power consumption can be reduced.

  The plurality of partition plates 6 are preferably arranged at equal intervals around the rotor 2. In the separation device 1, it is preferable that the plurality of partition plates 6 are arranged radially when viewed from the first end 21 side of the rotor 2. In short, each of the plurality of partition plates 6 preferably protrudes outward in the radial direction of the rotor 2 from the rotor 2.

  Each of the plurality of flow paths 8 defined by the two adjacent partition plates 6, the rotor 2, and the frame 3 among the plurality of partition plates 6 is formed along the rotation center axis 20 of the rotor 2. Therefore, in the separation device 1, it is possible to apply a rotational force around the rotation center axis 20 to the gas flowing into each of the plurality of flow paths 8 by rotating the rotor 2. The separation device 1 can flow the gas flowing into each of the plurality of channels 8 from the upstream side to the downstream side of each of the plurality of channels 8 while rotating spirally around the rotor 2. In the separation device 1, the rotation speed of the rotor 2 causes the velocity vector of the gas flowing through each of the plurality of flow paths 8 to have a velocity component in a direction parallel to the rotation center axis 20 and a rotation direction around the rotation center axis 20. The velocity component of Therefore, the separation device 1 can efficiently separate the solid from the gas while reducing the size.

  The rotating plate 9 connected to the plurality of partition plates 6 is annular and has an opening 92. The rotating plate 9 is formed in an annular shape as an example. The rotating plate 9 is arranged so that the thickness direction of the rotating plate 9 is aligned with the direction along the rotation center axis 20 of the rotor 2. The inner diameter of the rotating plate 9 (the diameter of the opening 92 of the rotating plate 9) is larger than the outer diameter of the rotor 2. The radius of the opening 92 of the rotating plate 9 is smaller than the dimension of the radius of the rotor 2 and the length of the partition plate 6 along the radial direction of the rotor 2. The outer diameter of the rotating plate 9 is larger than the outer diameter of the frame 3. As a material of the rotating plate 9, for example, metal, synthetic resin, or the like can be used. The rotating plate 9 preferably has conductivity. Thereby, in the separation apparatus 1, it becomes possible to suppress charging of the rotating plate 9.

  In the separation device 1, the separation unit 10 includes a central outlet 25 formed on the downstream side of each of the plurality of flow paths 8. Here, the center outlet 25 is located closer to the rotation center axis 20 of the rotor 2 than the plurality of partition plates 6 on the downstream side of each of the plurality of flow paths 8. The central outlet 25 in the separation device 1 is an opening defined by two adjacent partition plates 6, the rotor 2, and the rotating plate 9. In short, the center outlet 25 is opened in a direction perpendicular to the rotation center axis 20 of the rotor 2.

  In the separation device 1, the separation unit 10 includes an outer peripheral outlet 35 formed on the downstream side of each of the plurality of flow paths 8. Here, the outer peripheral outlet 35 is located outside the plurality of partition plates 6 in a direction orthogonal to the rotation center axis 20 of the rotor 2. The outer peripheral outlet 35 communicates with at least one of the plurality of channels 8 and is opened in a direction perpendicular to the rotation center axis 20 of the rotor 2. The outer peripheral outlet 35 is farther from the rotation center axis 20 than the center outlet 25 in the direction orthogonal to the rotation center axis 20 of the rotor 2. In other words, in the direction orthogonal to the rotation center axis 20 of the rotor 2, the distance between the outer peripheral outlet 35 and the rotation center axis 20 is longer than the distance between the center outlet 25 and the rotation center axis 20. Thereby, the separation device 1 can discharge the solid to which a greater centrifugal force is applied in each of the plurality of flow paths 8 through the outer peripheral outlet 35. The outer peripheral outlet 35 in the separation device 1 is an opening between the frame 3 and the rotating plate 9. In other words, the outer peripheral outlet 35 in the separation device 1 is a gap between the frame 3 and the rotating plate 9. The outer peripheral outlet 35 is opened in a direction perpendicular to the rotation center axis 20 of the rotor 2.

  Further, in the separation device 1, a blower device 5 that flows gas into the space 4 between the rotor 2 and the frame body 3 is disposed on the downstream side of the plurality of flow paths 8. The blower 5 in the separation device 1 of the present embodiment also serves as an air flow control unit 40 that controls the gas flow direction on the downstream side of at least one of the plurality of channels 8 in the direction toward the center outlet 25. ing.

In the separation apparatus 1, the gas that has entered the outer shell 100 from the outside of the outer shell 100 through the inlet 101 flows into the plurality of flow paths 8. The solid contained in the gas entering from the outside of the outer shell 100 toward the inner peripheral surface 33 of the frame 3 from the rotation center axis 20 of the rotor 2 when rotating in a spiral manner in each of the plurality of flow paths 8. Subject to direction centrifugal force. The solid subjected to the centrifugal force moves toward the inner peripheral surface 33 of the frame 3 and rotates spirally along the inner peripheral surface 33 in the vicinity of the inner peripheral surface 33 of the frame 3. In the separation device 1, the solid rotating around the outer peripheral outlet 35 is discharged through the outer peripheral outlet 35 by the centrifugal force acting on the solid. The centrifugal force acting on the solid is proportional to the mass of the solid and the radius of the circular motion of the solid. The radius of the circular motion is a distance between the rotation center axis 20 and the solid in a direction orthogonal to the rotation center axis 20 of the rotor 2. If the mass of the solid is m, the velocity of the solid is v, and the radius of the circular motion is r, the magnitude of the centrifugal force is mv ² / r. Here, assuming that the angular velocity is ω, since v = rω, the magnitude of the centrifugal force is mω ² r. In short, a centrifugal force having a magnitude proportional to the square of ω acts on the solid.

  In the separation apparatus 1 described above, the solid contained in the gas flowing into each of the plurality of flow paths 8 can be efficiently discharged from the outer peripheral outlet 35, and the gas from which the solid has been separated is centered. Since it is possible to flow downstream from the outlet 25, it is possible to efficiently separate the solid from the gas. In short, the separation device 1 includes the outer peripheral outlet 35 and the size of the rotating plate 9 is large enough to cover the plurality of partition plates 6 and the space 4 on the downstream side of each of the plurality of flow paths 8. Even if the centrifugal force increases, it is possible to prevent the solid from scattering and passing through the center outlet 25.

  As a result, in the separation device 1, it is possible to suppress a solid passing through the gap from passing through the center outlet 25 while adopting a configuration in which a gap is formed between each of the plurality of partition plates 6 and the frame body 3. Is possible. Therefore, in the separation apparatus 1, it becomes possible to flow the cleaner gas (air) to the downstream side.

  The separating device 1 includes ribs 11 (see FIGS. 2A and 2C) that protrude from the rotating plate 9 in one direction in the thickness direction of the rotating plate 9 and are positioned between two adjacent partition plates 6 among the plurality of partition plates 6. It is preferable to provide. As a result, in the separation device 1, even if the traveling direction of the solid that has spirally rotated along the inner peripheral surface 33 near the inner peripheral surface 33 of the frame 3 passes through the central outlet 25. Can be suppressed. Further, the separation device 1 can suppress the solid that has adhered to the inner peripheral surface 33 of the frame 3 from reaching the center outlet 25 when it is scattered. Moreover, the separation device 1 can easily guide the gas from which the solid is separated to the downstream side. In the separation device 1, a plurality of ribs 11 protruding from the rotating plate 9 are formed. Each of the plurality of ribs 11 has an arc shape in cross section perpendicular to the thickness direction of the rotating plate 9 (see FIG. 2C). “One direction in the thickness direction of the rotating plate 9” is the same direction as the direction from the second end 22 of the rotor 2 toward the first end 21.

  The separation device according to the first modification of the first embodiment will be described with reference to FIGS. 5A, 5B, 5C, and 6. FIG. The basic configuration of the separation device of the first modification is substantially the same as that of the separation device 1 of the first embodiment. In the separation device of the first modified example, the shapes of the rotor 2, the frame 3 and the plurality of partition plates 6 in the separation unit 10a are different from the separation unit 10 in the separation device 1 of the first embodiment. In FIGS. 5B, 5C, and 6, the rotation direction of the rotor 2 is schematically shown by thick arrows. Further, in FIGS. 5A and 5C, the gas flow before the solid is separated is schematically shown by a framing arrow (an arrow with dot hatching), and the gas flow from which the solid is separated is shown by a white arrow. It is shown schematically. 5A and 5C schematically illustrate the fine particles 161 as solids discharged from the outer peripheral outlet 35.

  The rotor 2 in the separation device of the first modification is formed in a truncated cone shape whose diameter gradually increases in the direction from the first end 21 to the second end 22 of the rotor 2. The frame 3 is formed in a cylindrical shape whose inner diameter gradually increases in the direction from the first end 21 to the second end 22 of the rotor 2. Thereby, in the separation device of the first modified example, it is possible to further increase the centrifugal force of the solid rotating in a spiral shape. Therefore, in the separation device of the first modified example, the solid can be discharged more efficiently from the outer peripheral outlet 35, and the gas from which the solid has been separated can flow from the central outlet 25 to the downstream side. It becomes possible to more efficiently separate the solid from the gas. Further, in the separation device of the first modified example, it is possible to reduce pressure loss when gas flows into each of the plurality of flow paths 8.

  The rotor 2 is open on the second end 22 side. In other words, the rotor 2 has a truncated cone shape in which the bottom surface (end surface) on the rotating plate 9 side is opened. The rotor 2 has a center outlet 25 formed at the second end 22.

  In the separation unit 10 a in the separation device of the first modification, a plurality of center outlets 25 are formed in the rotor 2. Here, in the separation device of the first modification, a center outlet 25 is formed in the rotor 2 on the rear side of each of the plurality of partition plates 6 in the rotation direction of the rotor 2. Thereby, in the separation device of the first modification, the center outlet 25 is formed in a region in which the solid existence probability is relatively small in the rotation region of the rotor 2 in the peripheral region of the second end 22 of the rotor 2. Therefore, it is possible to suppress the solid from passing through the center outlet 25. The separation device according to the first modification is based on the experiment result of the inventors of the present application that there is a region where the existence probability of the solid is relatively small on the rear side of each of the plurality of partition plates 6 in the rotation direction of the rotor 2. It is a form.

  The separation device of the second modification of the first embodiment will be described based on FIGS. 7A, 7B, and 7C. The separation device of the second modification has the same basic configuration as the separation device of the first modification. In the separation device of the second modification, the shapes of the plurality of partition plates 6 in the separation unit 10b are different from the separation unit 10a of the separation device of the first modification. In FIG. 7B and 7C, the rotation direction of the rotor 2 is typically shown by a thick arrow. In FIGS. 7A and 7C, the gas flow before the solid is separated is schematically shown by a framing arrow (an arrow with dots hatched), and the gas flow from which the solid is separated is shown by a white arrow. It is shown schematically. 7A and 7C schematically illustrate the fine particles 161 as solids discharged from the outer peripheral outlet 35.

  Each of the plurality of partition plates 6 in the separation unit 10 b of the separation device of the second modification is formed in a spiral shape around the rotation center axis 20 of the rotor 2. Thereby, in the separation device of the second modification, it is possible to increase the length of each of the plurality of flow paths 8 compared to the separation device of the first modification. Therefore, in the separation device according to the second modification, it is possible to more efficiently separate the solid from the gas.

  A separation device according to a third modification of the first embodiment will be described with reference to FIGS. 8A, 8B, and 8C. The separation device of the third modification has the same basic configuration as the separation device of the first modification. In the separation unit 10c in the separation device of the third modified example, the end surface of the rotor 2 on the rotating plate 9 side is open. The separation device according to the third modification is that the separation device according to the first modification further includes guide vanes 12 protruding from the rear end in the rotation direction of the rotor 2 at the outer peripheral portion of the center outlet 25 on the inner peripheral surface 23 of the rotor 2. Different from the separation device. The guide blades 12 are inclined to the rear side in the rotation direction of the rotor 2. In other words, the guide vane 12 is inclined in the direction opposite to the rotation direction of the rotor 2 with reference to the normal direction of the portion where the guide vane 12 protrudes at the outer peripheral portion of the center outlet 25 on the inner peripheral surface 23 of the rotor 2. Yes. The normal direction here is inward in the radial direction of the rotor 2. In the separation device of the third modified example, by further providing the guide vanes 12, it is possible to reduce pressure loss and to reduce power consumption compared to the separation device of the first modified example. Become. 8B and 8C, the rotation direction of the rotor 2 is schematically shown by a thick arrow. Further, in FIGS. 8A and 8C, the gas flow before the solid is separated is schematically shown by a framing arrow (an arrow with dot hatching), and the gas flow from which the solid is separated is shown by a white arrow. It is shown schematically. 8A and 8C schematically illustrate the fine particles 161 as solids discharged from the outer peripheral outlet 35.

  In the separation device of the third modified example, a plurality (three in the illustrated example) of central outlets 25 are formed in the rotor 2. In the separation device of the third modification, a plurality of guide blades 12 (three in the illustrated example) are formed. The plurality of guide vanes 12 are preferably provided in the rotor 2 in a one-to-one correspondence with the plurality of central outlets 25 of the rotor 2.

  The guide vane 12 is a vane that guides a gas flow in a predetermined direction. In short, the guide blade 12 is a blade that guides the gas from which the solid is separated to the duct 15 (see FIG. 1A). The guide blade 12 is connected to the rotor 2. The guide blade 12 rotates around the rotation center axis 20 as the rotor 2 rotates.

  The separation device according to the third modification includes the blower device 5 (see FIG. 3) on the downstream side of the plurality of flow paths 8 as in the separation device according to the first embodiment, but is not limited thereto. In the separation device of the third modified example, the guide vane 12 constitutes an airflow control unit 40 that controls the gas flow direction on the downstream side of each of the plurality of flow paths 8 in the direction toward the center outlet 25. Thereby, in the separation apparatus of the third modified example, a configuration in which a blower is provided on the upstream side of the plurality of flow paths 8 can also be employed.

  The separation device according to the fourth modification of the first embodiment will be described with reference to FIGS. 9A, 9B, 9C, and 10. FIG. The separation device of the fourth modified example has substantially the same basic configuration as the separation device 1 of the first embodiment. The separation device of the fourth modification is different from the separation unit 10 in the shape of the plurality of partition plates 6 in the separation unit 10d. 9B, 9C, and 10, the rotation direction of the rotor 2 is schematically shown by a thick arrow. 9A, 9B, and 9C, the gas flow before the solid is separated is schematically shown by an edging arrow (the arrow with dot hatching), and the gas flow from which the solid is separated is shown by a white arrow. Is schematically shown. 9A and 9C schematically show the fine particles 161 as solids discharged from the outer peripheral outlet 35. FIG.

  Each of the plurality of partition plates 6 in the separation device of the fourth modified example is formed in a spiral staircase shape. Thereby, in the separation device of the fourth modification, it is possible to reduce the load on the blower 5 (see FIG. 3).

  Each of the plurality of partition plates 6 in the separation unit 10 d is connected to the rotor 2. Each of the plurality of partition plates 6 is a first functional portion (hereinafter also referred to as “first partition portion”) 611 formed along the rotation direction of the rotor 2 in a plane orthogonal to the rotation center axis 20 of the rotor 2. And a second functional part (hereinafter also referred to as “second partition part”) 612 formed along the rotation center axis 20 of the rotor 2.

  The shape of the first partition 611 is an arc shape along the rotation direction of the rotor 2 in a plane orthogonal to the rotation center axis 20 of the rotor 2. The shape of the second partition 612 is a straight line along the rotation center axis 20 when viewed from the direction orthogonal to the rotation center axis 20.

  In the separation device of the fourth modified example, the angular velocity of the substance passing through the first flow path formed between the two adjacent first partition portions 611 in the flow path 8 can be made larger than the rotational angular speed of the rotor 2. It becomes possible. Therefore, in the separation device of the fourth modified example, it is possible to further increase the centrifugal force acting on the solid among the substances passing through the first flow path in the flow path 8, and it is possible to reduce the size. In the separation device of the fourth modification, the angular velocity of the substance passing through the second flow path formed between two adjacent second partition portions 612 in the flow path 8 is made the same as the rotational angular speed of the rotor 2. It becomes possible. Therefore, the separation device of the fourth modification can reduce the pressure loss of the gas flowing in the flow path 8 in the second flow path in the flow path 8. In other words, the separation device of the fourth modification example can improve the blowing capacity by providing the second flow path in the flow path 8 and can reduce the load on the blower 5 (see FIG. 3). It becomes possible. Therefore, the separation device of the fourth modified example can achieve low power consumption because the flow path 8 includes the second flow path.

  In the separation device of the fourth modified example, each of the plurality of flow paths 8 includes the first flow path and the second flow path, so that the flow path 8 is linear along the rotation center axis 20 over the entire length. Compared to the case, the length of the flow path 8 can be increased while reducing the size in the direction along the rotation center axis 20.

(Embodiment 2)
Below, the separation apparatus 1B of this embodiment is demonstrated based on FIG. The basic configuration of the separation apparatus 1B of the present embodiment is the same as that of the separation apparatus 1 of the first embodiment. Regarding the separation device 1B of the present embodiment, the same components as those of the separation device 1 of the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  The separation device 1B of the present embodiment includes a container 120 that collects solids (in the illustrated example, fine particles 161) discharged from the outer peripheral outlet 35. The separation device 1B includes a solid discharge port in the outer shell 100 (see FIG. 1A) of the separation device 1 in an outer shell 100B that houses the rotor 2, the frame 3, the plurality of partition plates 6, the rotating plate 9, and the driving device 7. Instead of providing 102 and the second mesh 112, a container 120 is accommodated. Thereby, the separation device 1B can collect the solid discharged from the outer peripheral outlet 35 into the outer shell 100B in the container 120, and can suppress the solid from being scattered outside the outer shell 100B. .

  The container 120 is disposed below the separation unit 10. The container 120 is a tray (a container without a lid). In the outer shell 100, a port 130 (see FIG. 12) for taking in and out the container 120 is formed. The container 120 is slidably held on the outer shell 100 and can be detached from the outer shell 100. As a result, the separation device 1B can easily take out and discard the solid collected in the container 120 (the fine particles 161 in the example of FIG. 11).

  In the separation device 1B, the solid discharged from the outer peripheral outlet 35 enters the container 120 below the separation unit 10 by gravity sedimentation or the like. Thereby, in separation device 1B, solid is collected in container 120.

  Moreover, it is preferable that the separating apparatus 1B has a cylindrical body 45 (see FIG. 11) fixed to the peripheral portion of the inflow port 101 in the outer wall surface of the outer shell 100B. The cylinder 45 is preferably cylindrical.

  FIG. 13 is a schematic configuration diagram of an air purification system 320 including the separation device 1B.

  Separation device 1B is arranged behind the ceiling of dwelling unit 400, for example. The separation device 1B may include the blower 5 and the airflow control unit 40. The air blower 5 and the airflow control unit 40 are arranged behind the ceiling of the dwelling unit 400 as in the air purification system 300 (see FIG. 3) provided with the separation device 1 of the first embodiment. Regarding the air purification system 320, the same components as those of the air purification system 300 are denoted by the same reference numerals, and description thereof is omitted.

  In the air purification system 320, the cylinder 45 (see FIG. 11) is connected to the duct 310 for flowing air into the dwelling unit 400. However, the present invention is not limited to this, and the cylinder 45 may also serve as the duct 310. Good.

  In the air purification system 320, it is not necessary to install an outdoor unit outside the dwelling unit 400 unlike the air purification system 300. Moreover, in the air purification system 320, since it is not necessary to provide the solid discharge port 102 (see FIG. 1A) in the outer shell 100B of the separation device 1B, it is possible to prevent solids from entering the outer shell 100B from the outside. In the air purification system 320, for example, a person can remove the container 120 of the separation device 1B from the outer shell 100B and discard the solid in the container 120.

  The materials, numerical values, and the like described in the first embodiment, the first to fourth modifications of the first embodiment, and the second embodiment are merely preferred examples, and are not intended to be limiting. Furthermore, in the present invention, the configuration and the shape can be appropriately changed without departing from the scope of the technical idea.

  For example, in the separation device 1 of the first embodiment, the separation devices of the first to fourth modifications of the first embodiment, and the separation device 1B of the second embodiment, the outer peripheral outlet 35 is formed directly on the frame body 3. Also good.

  Moreover, the rotary plate 9 should just be cyclic | annular, and may be not only a cyclic | annular form but a gear shape, for example. In addition, the “annular” in this specification includes not only a completely closed shape but also a shape (for example, a C shape) in which a slit is formed in part.

  The ribs 11 (see FIGS. 2A, 2B, and 2C) may be provided in the separation devices of the first to fourth modifications of the first embodiment and the separation device 1B of the second embodiment.

  Further, the guide vanes 12 (see FIGS. 8A and 8C) in the separation device of the third modification of the first embodiment are the separation device 1 of the first embodiment, the separation device of the first modification, the separation device of the second modification, and You may provide in the separation apparatus of 4th modification, and the separation apparatus 1B of Embodiment 2, respectively.

  Further, in the separation device of the fourth modification of the first embodiment and the separation device 1B of the second embodiment, the rotor 2 is formed in a truncated cone shape like the separation device of the first modification of the first embodiment. 3 may be formed in a cylindrical shape whose inner diameter gradually increases in the direction from the first end 21 to the second end 22 of the rotor 2.

DESCRIPTION OF SYMBOLS 1 Separator 2 Rotor 20 Rotation center axis 21 1st end 22 2nd end 25 Center side opening 3 Frame 33 Inner peripheral surface 35 Outer peripheral side opening 4 Space 5 Blower 6 Partition plate 61 1st end surface 62 2nd end surface 7 Drive Device 8 Flow path 9 Rotating plate 10 Airflow control unit 11 Rib 12 Guide vane

Claims (9)

A rotor, a cylindrical frame disposed around the rotor and coaxially with the rotor, and a plurality of partition plates arranged in a space between the rotor and the frame to partition the space; A plurality of flow passages each defined by two partition plates adjacent to each other among the plurality of partition plates, the rotor and the frame, an annular rotary plate coupled to the plurality of partition plates, and the rotor And a drive device for rotating,
Each of the plurality of partition plates is connected to the rotor,
In each of the plurality of flow paths, the first end side of the rotor is the upstream side in the direction along the rotation center axis of the rotor, and the second end side of the rotor is the downstream side,
Each of the plurality of partition plates has the first end surface on the upstream side and the second end surface on the downstream side in a direction along the rotation center axis,
The rotating plate is connected to the plurality of partition plates on the second end face side of each of the plurality of partition plates,
On the downstream side of each of the plurality of flow paths, located closer to the rotation center axis than the plurality of partition plates, communicates with at least one of the plurality of flow paths, and opens in a direction perpendicular to the rotation center axis. At least one central outlet and at least one of the plurality of flow paths outside the plurality of partition plates in a direction orthogonal to the rotation center axis on the downstream side of each of the plurality of flow paths. An outer peripheral outlet that communicates with the flow path and is open in a direction orthogonal to the rotation center axis,
The rotating plate is sized to cover the plurality of partition plates and the space on the downstream side of each of the plurality of flow paths.
Separation device characterized by that. There is a gap between each of the plurality of partition plates and the inner peripheral surface of the frame,
The separation device according to claim 1. A rib protruding from the rotating plate in one direction of the thickness of the rotating plate and positioned between two adjacent partition plates of the plurality of partition plates;
The separation apparatus according to claim 1 or 2, wherein A plurality of the center outlets are formed in the rotor, and the center outlet is formed in the rotor on the rear side of each of the plurality of partition plates in the rotation direction of the rotor.
The separation device according to any one of claims 1 to 3, wherein The rotor has an open end surface on the rotating plate side,
A guide vane that protrudes from the rear end in the rotation direction of the rotor at the outer peripheral portion of the center outlet on the inner peripheral surface of the rotor and is inclined to the rear side in the rotation direction;
The separation device according to any one of claims 1 to 4, wherein The rotor is formed in a truncated cone shape having a diameter that gradually increases in a direction from the first end to the second end of the rotor;
The frame is formed in a cylindrical shape whose inner diameter gradually increases in a direction from the first end to the second end of the rotor.
The separation apparatus according to any one of claims 1 to 5, wherein: Each of the plurality of partition plates is formed in a spiral around the rotation center axis of the rotor,
The separation apparatus according to any one of claims 1 to 6, wherein Each of the plurality of partition plates is formed in a spiral staircase shape,
The separation apparatus according to any one of claims 1 to 6, wherein A blower that flows gas into the space, and an airflow control unit that controls the flow direction of the gas on the downstream side of at least one of the plurality of flow paths in a direction toward the center outlet. The separation device according to any one of claims 1 to 8, characterized in that

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