JP6628186B2 - Separation device - Google Patents

Description

  The present invention relates to a separation device, and more particularly to a separation device for separating solids from air.

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

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

  A plurality of main blades for efficiently rotating the dust-mixed air are provided on the outer peripheral surface side of the cylinder. A hole is provided in a part of the cylinder to allow air to flow therein.

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

  In the dustproof device, when the dust-mixed air spirally descends while rotating at a 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, the air is purified by separating air and dust (solid).

JP 2001-87610 A

  In general, in the separation device, the size of the solid to be separated changes depending on the flow rate of the inflowing air, the rotation speed of the rotor, and the like.

  However, when a separation device is arranged upstream of an air conditioner having a blowing function of sending a predetermined amount of air, a desired separation performance of the separation device may not be obtained depending on a predetermined air flow of the air conditioner.

  An object of the present invention is to provide a separation device that can be linked with an air conditioner having a blowing function and that can efficiently separate solids from air.

  The separation device according to one embodiment of the present invention is provided upstream or downstream of an air conditioner having a blowing function, and separates solids in air. The separation device includes a rotor, a frame, a plurality of partition plates, a plurality of flow paths, a motor, and a drive circuit. The frame is cylindrical, and is arranged coaxially with the rotor so as to surround the rotor. The plurality of partition plates are arranged in a space between the rotor and the frame to divide the space. Each of the plurality of flow paths is defined by two adjacent partition plates among the plurality of partition plates, the rotor, and the frame. The motor rotates the rotor about a rotation axis of the rotor. The drive circuit drives the motor. Each of the plurality of partition plates is connected to the rotor, and is spirally formed around the rotation center axis of the rotor. In each of the plurality of flow paths, a first end side of the rotor is an upstream side and a second end side of the rotor is a downstream side in a direction along the rotation center axis of the rotor. The separation device further includes a first detection unit that detects generation of an electromotive force of the motor, a second detection unit that detects a predetermined change in power consumption of the motor, and a control unit that controls the drive circuit. . The controller causes the drive circuit to start driving the motor when the generation of the electromotive force of the motor is detected by the first detector, and when the predetermined change is detected by the second detector. Then, the driving circuit is controlled so that the rotation speed of the motor becomes a predetermined rotation speed.

  The separation device of the present invention can be linked with an air conditioner having a blowing function, and can efficiently separate solids from air.

FIG. 1A is a schematic sectional view of a separation device according to one embodiment of the present invention. FIG. 1B is a schematic perspective view of a separation unit in the separation device of the above. FIG. 2 is a schematic sectional view of a separation unit in the separation device of the above. FIG. 3 is a schematic perspective view of the separation device. FIG. 4 is a schematic explanatory view of an air purification system provided with the above separation device. FIG. 5 is a circuit diagram of the separation device of the above. FIG. 6 is an explanatory diagram of the operation of the separation device. FIG. 7 is an operation explanatory diagram in the case where the rotation direction of the motor is reversed in the separation device of the above. FIG. 8 is an operation explanatory diagram of a separation device according to a modification of one embodiment of the present invention.

  The drawings described in the following embodiments and the like are schematic diagrams, and the ratio of the size and thickness of each component in the drawings does not always reflect the actual dimensional ratio.

(Embodiment)
Hereinafter, the separation device 1 of the present embodiment will be described with reference to FIGS.

  The separation device 1 is provided upstream of an air conditioner 40 having a blowing function (see FIG. 4), and separates solids in the air.

  The separation device 1 includes the rotor 2, the frame 3, a plurality of (for example, two) partition plates 6, a plurality of (for example, two) flow paths 8, a motor 7, and a drive circuit 171. Prepare. The frame 3 has a cylindrical shape, and is arranged coaxially with the rotor 2 so as to surround the rotor 2. The plurality of partition plates 6 are arranged in the space 4 between the rotor 2 and the frame 3 to divide 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 3 among the plurality of partition plates 6. The motor 7 rotates the rotor 2 around a rotation center axis 20 of the rotor 2. The drive circuit 171 drives the motor 7. Each of the plurality of partition plates 6 is connected to the rotor 2 and is spirally formed around a rotation center axis 20 of 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 and the second end 22 side of the rotor 2 is the downstream side in the direction along the rotation center axis 20 of the rotor 2. The separation device 1 includes a first detection unit 11 that detects generation of an electromotive force of the motor 7, a second detection unit 12 that detects a predetermined change in power consumption of the motor 7, and a control unit 5 that controls a drive circuit 171. Is further provided. The control unit 5 causes the drive circuit 171 to start driving the motor 7 when the generation of the electromotive force of the motor 7 is detected by the first detection unit 11, and causes the second detection unit 12 to perform a predetermined change in the power consumption of the motor 7. Is detected, the drive circuit 171 is controlled so that the rotation speed of the motor 7 becomes a predetermined rotation speed.

  With the above configuration, the separation device 1 can be linked with the air conditioning equipment having a blowing function, and can efficiently separate solids from air. The air conditioner 40 has a blowing function of sending a predetermined amount of air. The air conditioner 40 is, for example, a blower that blows air from an upstream side to a downstream side, and is capable of flowing air to a space 4 between the rotor 2 and the frame 3 in the separation device 1 provided on the upstream side. it can. The “upstream side” here means the upstream side (primary side) when viewed in the direction of air flow. Further, the “downstream side” here means the downstream side (secondary side) when viewed in the direction of air flow.

  Examples of the solid in the air include fine particles and dust. Examples of the fine particles include a particulate substance. Examples of the particulate matter include primary product particles that are directly discharged into the air as fine particles, and secondary product particles that are generated as fine particles in the air that are released into the air as a gas. Examples of the primary generated particles include soil particles (eg, yellow sand), dust, plant particles (eg, pollen), animal particles (eg, mold spores), and soot. As the classification of the size of the particulate matter, for example, PM2.5 (fine particulate matter), PM10, SPM (suspended particulate matter), and the like can be given. PM2.5 is fine particles that pass through a particle sizer having a particle diameter of 2.5 μm and a collection efficiency of 50%. PM10 is fine particles that pass through a particle sizer having a particle diameter of 10 μm and a collection efficiency of 50%. SPM is a fine particle that passes through a particle sizer having a particle diameter of 10 μm and a collection efficiency of 100%, corresponds to PM 6.5-7.0, and is a small particle slightly smaller than PM10.

  Preferably, the separation device 1 further includes a rotating plate 9. The rotating plate 9 is annular, and is connected to the plurality of partition plates 6. The drive circuit 171 rotates the rotor 2. Each of the plurality of partition plates 6 is connected to the rotor 2. The rotating plate 9 is connected to the plurality of partition plates 6 on each downstream side of the plurality of flow paths 8. In the separation device 1, the separation unit 10 including the rotor 2, the frame 3, the plurality of partition plates 6, and the rotating plate 9 forms a central opening (central outlet) 25 and an outer peripheral opening (outer peripheral outlet) 35. Preferably, it is provided. The center outlet 25 is located on the rotation center axis 20 side of 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 flow paths 8 and is opened in a direction orthogonal to the rotation center axis 20. The outer peripheral outlet 35 is located outside the plurality of partition plates 6 in a 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 flow paths 8 and is opened in a direction orthogonal to the rotation center axis 20. The rotating plate 9 has a size that covers the plurality of partition plates 6 and the space 4 on the downstream side of each of the plurality of flow paths 8 when viewed from the direction along the rotation center axis 20. The “size that covers the plurality of partition plates 6 and the space 4 on the downstream side of each of the plurality of flow channels 8” is not limited to the size that covers the entire plurality of partition plates 6 and the space 4. Any size may be used as long as the cross-sectional area of each passage 8 can be reduced. With the above configuration, the separation device 1 can efficiently separate solids from air. The air blower constituting the air conditioner 40 controls the flow direction of air downstream of at least one of the plurality of flow paths 8 toward the center outlet 25. Thereby, the separation device 1 can separate the solid from the air more efficiently.

  FIG. 4 is a schematic configuration diagram of an air purification system 300 including the separation device 1.

  In the air purification system 300, the separation device 1 is disposed on the upstream side of the air conditioning equipment 40. In other words, the air conditioner 40 is arranged downstream of the plurality of flow paths 8.

  The blower constituting the air conditioner 40 is an electric fan having a blower function of sending a predetermined amount of air. In the air purification system 300, the air can be made to flow through the plurality of flow paths 8 of the separation device 1 by operating the air conditioning equipment 40. The electric fan is, for example, an axial fan.

  The air purification system 300 includes a first duct 311 for flowing air into the dwelling unit 400, and the separation device 1 is connected to a downstream end of the first duct 311. In the separation device 1, each of the plurality of flow paths 8 communicates with the internal space of the first duct 311. Preferably, the air purification system 300 includes a filter device 42 between the separation device 1 and the air conditioner 40 for further purifying the air purified by the separation device 1. In this case, the air purification system 300 includes, for example, a second duct 312 interposed between the separation device 1 and the filter device 42, and a third duct 313 interposed between the filter device 42 and the air conditioner 40. Preferably, it is provided. The filter device 42 is, for example, an air filter such as a HEPA filter (high efficiency particulate air filter). The “HEPA filter” is an air filter having a particle collection rate of 99.97% or more for particles having a particle diameter of 0.3 μm at a rated flow rate and having an initial pressure loss of 245 Pa or less. The filter device 42 does not require 100% particle collection efficiency as an essential condition. However, the filter device 42 preferably has a higher collection efficiency of solids contained in the air. In FIG. 4, the flow of the air is schematically shown by white arrows. FIG. 4 schematically shows fine particles 161 separated from the air by the separation device 1 and ultrafine particles 162 collected by the filter device 42. The ultrafine particles 162 are fine particles having a smaller particle size than the fine particles 161 and having a particle size that can be removed by a HEPA filter.

  Further, the air purification system 300 preferably includes, for example, a distributor 318 disposed downstream of the air conditioner 40, and a fourth duct 314 disposed between the air conditioner 40 and the distributor 318. . A plurality of fifth ducts 315 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 fifth ducts 315 on the downstream side. The first duct 311, the separation device 1, the second duct 312, the filter device 42, the third duct 313, the air conditioner 40, the fourth duct 314, the distributor 318, and the fifth duct 315 are arranged behind the ceiling of the dwelling unit 400. Preferably.

  Since the air purification system 300 includes the separation device 1, it is possible to suppress the particles 161 such as PM2.5 from reaching the filter device 42, the air conditioner 40, the plurality of sections 401 in the dwelling unit 400, and the like. . Further, the air purification system 300 can extend the life of the filter device 42, the air conditioner 40, and the like downstream of the separation device 1. For example, 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 and the like collected by the filter device 42. Thus, in the air purification system 300, the frequency of replacing the filter device 42 can be reduced. The air purification system 300 is not limited to the configuration in which the filter device 42 and the air conditioner 40 are housed in different housings, and may include the filter device 42 in the housing of the air conditioner 40. In other words, the air conditioner 40 may include the filter device 42 in addition to the blower.

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

  As described above, the separation device 1 includes the rotor 2, the frame 3, the plurality of (for example, two) partition plates 6, the plurality of (for example, two) flow paths 8, the motor 7, And a circuit 171.

  The rotor 2 is formed in a column shape. The rotor 2 is configured so as not to pass air and solids contained in the air. More specifically, the rotor 2 is a non-porous structure. As a material of the rotor 2, for example, metal, synthetic resin, or the like can be adopted. The rotor 2 preferably has conductivity. Thereby, in the separation device 1, it is possible to suppress charging of the rotor 2.

  In FIG. 1B, the rotation direction of the rotor 2 is schematically indicated by thick arrows. The rotation direction of the rotor 2 is a clockwise direction when the rotor 2 is viewed from the first end 21 side. The rotation direction of the rotor 2 is a counterclockwise direction when the rotor 2 is viewed from the second end 22 side. The rotation of the rotor 2 allows the separation device 1 to apply a force in the rotation direction about the rotation center axis 20 to the air flowing into each of the plurality of flow paths 8.

  The frame 3 is formed in a cylindrical shape. As the material of the frame 3, for example, metal, synthetic resin, or the like can be used. The frame 3 preferably has conductivity. Thereby, in the separation device 1, it is possible to suppress charging of the frame 3.

  The frame 3 surrounds the rotor 2 and is arranged coaxially with the rotor 2. “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 plurality of partition plates 6 are arranged in the space 4 between the rotor 2 and the frame 3 to divide the space 4. Each of the plurality of partition plates 6 is spirally formed around the rotation center axis 20 of the rotor 2. “Spiral” refers to the shape formed by at least a portion of a left-handed spiral. “At least a portion of the left-handed spiral” means that the number of revolutions of the left-handed spiral may be less than one.

  When the predetermined rotation direction of the rotor 2 is clockwise (clockwise) as viewed from the first end 21 side of the rotor 2, each of the plurality of partition plates 6 is directed from the first end 61 to the second end 62. Thus, it can be regarded as a spiral in a spiral direction along the direction opposite to the predetermined rotation direction of the rotor 2. Therefore, the separation device 1 can improve the sizing performance.

  As a material of each of the plurality of partition plates 6, for example, metal, synthetic resin, rubber, or the like can be adopted. The plurality of partition plates 6 preferably have conductivity. Thereby, the separation device 1 can suppress the electrification of the plurality of partition plates 6.

  The plurality of partition plates 6 are connected to only the rotor 2 among the rotor 2 and the frame 3 as described above. The phrase “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, for example, is formed integrally with the rotor 2. Including cases. Since the separation device 1 has a plurality of partition plates 6 that are not connected to the frame 3, the drive circuit is more complicated than a case where the plurality of partition plates 6 are fixed to both the rotor 2 and the frame 3 and both are rotated. 171 can be reduced, and low power consumption can be achieved.

  It is preferable that each of the plurality of partition plates 6 is arranged such that a gap is formed between the partition plate 6 and the inner peripheral surface 33 of the frame 3. In other words, the separation device 1 has a gap between each of the plurality of partition plates 6 and the inner peripheral surface 33 of the frame 3. Thereby, in the separation device 1, there is an advantage that manufacture is easy.

  The plurality of partition plates 6 are preferably connected to the rotor 2 such that a part of each of the partition plates 6 is located closer to the rotary plate 9 than the rotor 2 in a direction along the rotation center axis 20 of the rotor 2.

  In the separation device 1, by rotating the rotor 2, it is possible to apply a force in the rotation direction around the rotation center axis 20 to the air flowing into each of the plurality of flow paths 8. The separation device 1 can flow the air flowing into each of the plurality of flow paths 8 from the upstream side to the downstream side of each of the plurality of flow paths 8 while rotating the air spirally around the rotor 2. In the separation device 1, when the rotor 2 rotates, the velocity vector of the air flowing through each of the plurality of flow paths 8 changes the velocity component in the direction parallel to the rotation center axis 20 and the rotation direction around the rotation center axis 20. And a velocity component of Therefore, the separation device 1 can efficiently separate solids from air while reducing the size.

  Each of the plurality of flow paths 8 has a spiral shape along two partition plates 6 that define the flow path 8. The air inlet of each of the plurality of flow paths 8 is on the first end 21 side of the rotor 2. The air outlet of each of the plurality of flow paths 8 is on the second end 22 side of the rotor 2.

  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, for 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 combined 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, a metal, a synthetic resin, or the like can be adopted. The rotating plate 9 preferably has conductivity. Thereby, the separation device 1 can suppress the 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 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 center 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 open in a direction orthogonal to the rotation center axis 20 of the rotor 2.

  Further, in the separation device 1, the separation unit 10 includes the 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 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 flow paths 8 and is opened in a direction orthogonal 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 a 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 larger centrifugal force has been applied through the outer peripheral outlet 35 in each of the plurality of flow paths 8. 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 open in a direction orthogonal to the rotation center axis 20 of the rotor 2.

  Preferably, the separation device 1 further includes a rotary cylinder 19 connected to the rotary plate 9 downstream of the rotary plate 9. In other words, it is preferable that the separation unit 10 includes the rotating cylinder 19. Accordingly, the separation device 1 can suppress the fine particles 161 discharged from the outer peripheral outlet 35 from returning to the air passing through the opening 92 of the rotating plate 9.

  The motor 7 for rotating the rotor 2 is, for example, a DC motor. The motor 7 includes a motor main body 71 and a columnar rotating shaft (shaft) 72 partially protruding from the motor main body 71. In the motor 7, the outer peripheral shape of the motor main body 71 is preferably circular. The outer diameter of the motor main body 71 is preferably smaller than the inner diameter of each of the frame 3 and the rotating plate 9. The outer diameter of the motor main 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 rotation shaft 72 of the motor 7. In the separation device 1, the rotation shaft 72 and the rotor 2 are connected so that the axis of the rotation shaft 72 and the rotation center axis 20 of the rotor 2 are aligned. Thereby, the motor 7 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 7. The rotation angular velocity of the rotor 2 is the same as the rotation angular velocity of the rotation shaft 72 of the motor 7.

  The separation device 1 preferably includes a power supply unit 17 (see FIG. 5) that supplies power to the drive circuit 171. The power supply unit 17 is a power supply circuit that generates and outputs a voltage (for example, a DC voltage of 100 V) suitable for the drive circuit 171 from an AC voltage supplied from an external AC power supply. The power supply circuit is, for example, a switching power supply circuit.

  The separation device 1 includes a power supply unit 17, a drive circuit 171, a first detection unit 11, a second detection unit 12, a case 170 accommodating the control unit 5, and the like. The motor 7 is supported by a pipe 18 projecting from a case 170. The wiring that electrically connects the drive circuit 171 and the motor 7 is preferably housed in the pipe 18 so as not to be exposed.

  In the separation device 1, for example, the shapes 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 specified particle size can be separated. As the fine particles having a specified particle size, for example, particles having an aerodynamic particle size of 1.0 μm are assumed. By "aerodynamic particle size" is meant the diameter of a particle whose aerodynamic behavior is equivalent to a spherical particle with a specific gravity of 1.0. The aerodynamic particle size is the particle size determined from the settling velocity of the particles. Examples of the solid remaining in the air without being separated by the separation device 1 include fine particles having a smaller particle diameter (in other words, fine particles having a smaller mass) than the fine particles supposed to be separated by the separation device 1. .

  In the separation device 1, when the air supply by the air conditioner 40 is started, the control unit 5 controls the drive circuit 171 to rotate the motor 7. Thereby, in the separation device 1, the solid contained in the air passing through each of the plurality of flow paths 8 can be discharged to the outside from the outer peripheral outlet 35, and the air from which the solid has been separated flows from the central outlet 25 to the downstream side. Can be. Therefore, the separation device 1 can efficiently separate the solid from the air. In FIGS. 1A, 1B and 2, the flow of air before solids are separated is schematically shown by bordering arrows (arrows with dot hatching), and the flow of air from which solids are separated is indicated by white arrows. It is shown schematically. 1A, 1B and 2, the fine particles 161 are schematically illustrated as a solid discharged from the outer peripheral outlet 35. The fine particles 161 are fine particles having the above-mentioned specified particle size, and are assumed to be particles having an aerodynamic particle size of 1.0 μm.

  The separation device 1 preferably includes an outer shell 100. The outer shell 100 is formed in a rectangular parallelepiped shape. The outer shell 100 is configured to house the separation unit 10, the case 170, and the like. The outer shell 100 is formed of, for example, metal.

  The separation device 1 may include a plurality of supports (not shown) that support the outer shell 100. Thereby, in the separation device 1, it is possible to provide a space between the outer shell 100 and the installation surface of the separation device 1.

  The outer shell 100 is formed with an air inlet 101 and a cleaned air outlet 103. It is preferable that a first mesh 111 is arranged at the inflow port 101 of the outer shell 100. In the separation device 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 periphery of the inflow port 101 on the inner wall surface of the outer shell 100.

  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 has 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 rotatably holds the rotary cylinder 19 of the separation unit 10. Thus, the separation device 1 can more stably rotate the rotating structure including the rotor 2, the plurality of partition plates 6, and the rotating plate 9 in the separation unit 10.

  Further, it is preferable that the separating device 1 includes a bearing 13 that rotatably holds the tip of the rotating shaft 72 of the motor 7. The bearing 13 is held by a plurality of beams 14 supported by the outer shell 100, as shown in FIG. Thereby, the separation device 1 can rotate the rotor 2 more stably.

In the separation device 1, air that has entered the inside of the outer shell 100 from the outside of the outer shell 100 through the inflow port 101 flows into each of the plurality of flow paths 8. The solid contained in the air 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 spirally rotating in each of the plurality of flow paths 8. Subject to centrifugal force in the direction. The solid that has been subjected to the centrifugal force moves toward the inner peripheral surface 33 of the frame 3 and spirally rotates along the inner peripheral surface 33 near the inner peripheral surface 33 of the frame 3. Then, 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 a 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 the distance between the rotation center axis 20 and the solid in a direction orthogonal to the rotation center axis 20 of the rotor 2. Assuming that 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, if 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.

  The separation device 1 can efficiently discharge the solids contained in the air flowing into each of the plurality of flow paths 8 from the outer peripheral outlet 35, and remove the air from which the solids are separated from the central outlet 25. Since it is possible to flow downstream, solids can be efficiently separated from air. In short, the separation device 1 has 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 of the solid increases, it is possible to suppress the solid from scattering and passing through the center outlet 25. Thereby, the separation device 1 suppresses the 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 3. Becomes possible. Therefore, the separation device 1 can flow the purified air downstream.

  The separation device 1 preferably includes a container 120 that collects solids (fine particles 161 in the illustrated example) discharged from the outer peripheral outlet 35. The container 120 is housed in the outer shell 100. Thereby, the separation device 1 can collect the solid discharged into the outer shell 100 from the outer peripheral outlet 35 in the container 120, and can suppress the solid from scattering to the outside of the outer shell 100. .

  The container 120 is arranged below the separation unit 10. The container 120 is a tray (a container without a lid). In the separation device 1, 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 the separation device 1, the solid can be collected in the container 120.

  The outer shell 100 is formed with a port 130 (see FIG. 3) for taking the container 120 in and out. The container 120 is slidably held by the outer shell 100 and can be removed from the outer shell 100. Thereby, in the separation device 1, for example, a person can remove the container 120 from the outer shell 100, discard the solid in the container 120, and then attach the container 120 to the outer shell 100.

  Further, it is preferable that the separation device 1 includes a cylindrical body 45 fixed to a peripheral portion of the inflow port 101 on the outer wall surface of the outer shell 100. The tubular body 45 is preferably cylindrical.

  In the air purification system 300, the cylindrical body 45 is connected to the first duct 311 for flowing air into the dwelling unit 400, but is not limited thereto, and the cylindrical body 45 may also serve as the first duct 311. .

  The drive circuit 171 preferably includes, for example, a constant current circuit 172, a regulator 173, and a voltage control unit 174.

  The constant current circuit 172 is a circuit for supplying a constant current to the motor 7. The constant current circuit 172 includes, for example, an operational amplifier 1721, an npn-type bipolar transistor 1722, a first resistor 1723, and a second resistor (current detection resistor) 1724. In the constant current circuit 172, a series circuit of a bipolar transistor 1722 and a second resistor 1724 is connected to the motor 7 in series. Here, the collector terminal of the bipolar transistor 1722 is connected to the motor 7, and the emitter terminal of the bipolar transistor 1722 is connected to one end of the second resistor 1724. The other end of the second resistor 1724 is grounded. In the constant current circuit 172, the output terminal of the operational amplifier 1721 is connected to the base terminal of the bipolar transistor 1722 via the first resistor 1723. An inverting input terminal of the operational amplifier 1721 is connected to a connection point between the bipolar transistor 1722 and the second resistor 1724.

  The regulator 173 receives a voltage from the power supply unit 17 and generates a predetermined constant voltage. The regulator 173 is, for example, a three-terminal regulator and forms a step-down circuit.

  The voltage control unit 174 controls the voltage of the non-inverting input terminal of the operational amplifier 1721 so as to keep the voltage across the second resistor 1724 constant. The constant current circuit 172 generates a current value (“Iin” and a current value) determined by the voltage value (“Vin”) of the voltage of the non-inverting input terminal of the operational amplifier 1721 and the resistance value (“Rx”) of the second resistor 1724. Then, a constant current of Iin = Vin / Rx) can flow to the motor 7.

  The separation device 1 preferably includes a diode D1 connected in parallel to the motor 7 so as to have a polarity opposite to the direction of the current flowing from the constant current circuit 172 to the motor 7. Thereby, the separation device 1 can protect the motor 7 when the back electromotive force is generated in the motor 7.

  The separation device 1 includes the first detection unit 11, the second detection unit 12, and the control unit 5 as described above. The control device 190 including the first detection unit 11, the second detection unit 12, and the control unit 5 can be realized by, for example, causing a microcomputer to execute an appropriate program.

  The separation device 1 preferably includes a voltage measurement unit 181 that measures the input voltage of the motor 7 (the voltage across the motor 7), and converts the analog voltage value (voltage measurement value) output from the voltage measurement unit 181 into a digital signal. It is preferable to include an A / D converter 182 that converts the voltage into a voltage value and outputs the voltage value to the control device 190.

  The first detection unit 11 detects the generation of an electromotive force of the motor 7 due to the ventilation of the air conditioner 40. More specifically, the first detection unit 11 detects whether or not the electromotive force of the motor 7 is generated based on the voltage value output from the voltage measurement unit 181. The “electromotive force of the motor 7” here refers to the kinetic energy of the flow (wind) of the air flowing into the space 4 between the rotor 2 and the frame 3 when the motor 7 is stopped. This is a voltage generated in the motor 7 when converted into shaft power and the rotation shaft 72 of the motor 7 rotates together with the rotor 2. The “motor 7 drive stopped state” is a state in which the motor 7 is not driven by the drive circuit 171 and the rotation speed of the motor 7 is 0 rpm. In the separation device 1, when the electromotive force of the motor 7 is generated when the motor 7 is stopped, the sign of the voltage measured by the voltage measuring unit 181 becomes negative. When the measured voltage value of the voltage measuring unit 181 changes more than a first threshold value (for example, −0.7 [V] × coefficient), the first detecting unit 11 detects that the electromotive force of the motor 7 has occurred. The coefficient is 0.8. The coefficient is not limited to 0.8, but is preferably set in a range of, for example, about 0.5 to 0.9 in consideration of a variation in the measured voltage value.

  The second detector 12 detects a predetermined change in the power consumption of the motor 7. More specifically, the second detection unit 12 obtains the power consumption of the motor 7 by calculation using the voltage value output from the voltage measurement unit 181 and the current flowing through the motor 7, and determines a predetermined change in the power consumption of the motor 7. Is detected. “Detecting a predetermined change” means detecting that the change amount of the power consumption calculated this time with respect to the power consumption calculated last time is equal to or larger than a threshold. Here, the second detection unit 12 includes a storage unit that stores the obtained power consumption. When the drive circuit 171 includes the constant current circuit 172, the second detection unit 12 may detect a predetermined change in the power consumption by detecting a predetermined change in the measured voltage value.

  In the separation device 1, when the flow rate of the air flowing from the upstream side of the separation device 1 to the space 4 between the rotor 2 and the frame 3 increases, the torque of the motor 7 increases. Here, since the motor 7 is supplied with a constant current from the constant current circuit 172 (that is, the motor 7 is controlled with a constant current), the rotation speed of the motor 7 hardly changes, but the input voltage of the motor 7 is changed. Increases, the power consumption of the motor 7 increases. In the separation device 1, when the flow rate of the air flowing from the upstream side of the separation device 1 to the space 4 between the rotor 2 and the frame 3 decreases, the torque of the motor 7 decreases. Here, since the motor 7 is supplied with a constant current from the constant current circuit 172 (that is, the motor 7 is controlled with a constant current), the rotation speed of the motor 7 hardly changes, but the input voltage of the motor 7 is changed. Is reduced, the power consumption of the motor 7 is reduced. Therefore, the second detector 12 can detect a predetermined change in the power consumption of the motor 7.

  The control unit 5 causes the drive circuit 171 to start driving the motor 7 when the generation of the electromotive force of the motor 7 is detected by the first detection unit 11, and causes the second detection unit 12 to perform a predetermined change in the power consumption of the motor 7. Is detected, the drive circuit 171 is controlled so that the rotation speed of the motor 7 becomes a predetermined rotation speed (hereinafter, also referred to as “set rotation speed”).

The air conditioner 40 in the air purification system 300 is, for example, a blower that can switch a predetermined air volume (hereinafter, also referred to as a “set flow rate”) stepwise. The set flow rates are, for example, 0 m ³ / h, 150 m ³ / h, and 250 m ³ / h. In the air purification system 300, the air conditioner 40 blows air at a set flow rate downstream (to the distributor 318). As a result, air having substantially the same flow rate as the set flow rate of the air conditioner 40 flows through the separation device 1.

On the other hand, the separation device 1 can switch the predetermined number of rotations of the motor 7 stepwise by the control unit 5 controlling the drive circuit 171. More specifically, the control unit 5 controls the voltage control unit 174 of the drive circuit 171 so that the rotation speed of the motor 7 becomes a predetermined rotation speed. When the set flow rates are 0 m ³ / h, 150 m ³ / h, and 250 m ³ / h, the predetermined rotation speeds are, for example, 0 rpm, 2000 rpm, and 2500 rpm, respectively. In short, the separation device 1 can make a plurality of (three) predetermined rotation speeds correspond one-to-one to a plurality (three) set flow rates of the air conditioner 40.

FIG. 6 shows the set rotation speed of the motor 7 and the measured voltage of the voltage measurement unit 181 when the set flow rate of the air conditioner 40 changes in the order of 0 m ³ / h, 150 m ³ / h, 250 m ³ / h, 0 m ³ / h. The change of each value is shown. The power consumption of the motor 7 changes in the same tendency as the change in the measured voltage value.

If the set flow rate of the air conditioning equipment 40 when the motor 7 is a drive stop state is increased from 0 m ³ / h to 150m ³ / h, an electromotive force is generated in the motor 7. In FIG. 6, the measured voltage value of the voltage measuring unit 181 at this time is described as Vr (for example, -0.7 V). In this case, since the measured voltage value of the voltage measuring unit 181 changes more than the first threshold value (for example, -0.7 [V] × coefficient), the first detecting unit 11 determines that the electromotive force of the motor 7 has occurred. Is detected. Therefore, the control unit 5 causes the drive circuit 171 to start driving the motor 7. At this time, the set number of revolutions increases from 0 rpm to 2000 rpm, and the measured voltage value increases from Vr to 15V.

Thereafter, when the set flow rate of the air conditioning equipment 40 in a state in which the motor 7 is rotating at 2000rpm is increased from 150 meters ³ / h to 250 meters ³ / h, the torque of the motor 7 is increased, the measurement value of the voltage measuring unit 181 The power consumption increases from 15 V to 18 V (that is, the power consumption increases from Iin × 15 to Iin × 18). In other words, the voltage measured by the voltage measuring unit 181 increases by ΔV2 (that is, the power consumption increases by Iin × ΔV2). Therefore, the second detection unit 12 detects, for example, a predetermined change in which the power consumption increases by Iin × ΔV2 × coefficient. Therefore, the control unit 5 controls the drive circuit 171 to increase the set rotation speed from 2000 rpm to 2500 rpm and increase the measured voltage value from 18V to 20V. The separation device 1 can maintain the particle size characteristics by increasing the set rotation speed from 2000 rpm to 2500 rpm.

Thereafter, when the set flow rate of the air conditioner 40 decreases from 250 m ³ / h to 0 m ³ / h while the motor 7 is rotating at 2500 rpm, the torque of the motor 7 decreases, and the voltage measured by the voltage measurement unit 181 decreases. The power consumption is reduced from 20 V to 16 V (that is, the power consumption is reduced from Iin × 20 to Iin × 16). In other words, the voltage measured by the voltage measuring unit 181 decreases by ΔV3 (that is, the power consumption decreases by Iin × ΔV3). Therefore, the second detection unit 12 detects, for example, a predetermined change in which the power consumption decreases by Iin × ΔV3 × coefficient. Therefore, the control unit 5 controls the drive circuit 171 to reduce the set rotation speed from 2500 rpm to 0 rpm, and reduce the measured voltage value from 16 V to 0 V.

  As can be seen from the above description, the separation device 1 can be linked to the air conditioning equipment 40 having a blowing function of sending a predetermined amount of air without separately providing a flow rate sensor, and separate solids from the air. It becomes possible to separate efficiently. In short, the separation device 1 can be linked with the air conditioning equipment 40 without acquiring signals from the air conditioning equipment 40, the flow sensor, and the like, and can efficiently separate solids from air. .

The predetermined rotation direction of the rotor 2 is not limited to a clockwise direction when the rotor 2 is viewed from the first end 21 side, and may be a counterclockwise (counterclockwise) direction. In this case, each of the plurality of partition plates 6 can be regarded as a spiral in a spiral direction along the predetermined rotation direction of the rotor 2 from the first end 61 to the second end 62. In this case, the separation device 1 can reduce the pressure loss and reduce power consumption. In this case, the change of the measured voltage value of the voltage measuring unit 181 when the set flow rate of the air conditioner 40 changes in the order of 0 m ³ / h, 250 m ³ / h, 0 m ³ / h will be briefly described based on FIG. I do.

If the set flow rate of the air conditioning equipment 40 when the motor 7 is a drive stop state is increased from 0 m ³ / h to 250m ³ / h, an electromotive force is generated in the motor 7. In this case, since the voltage measured by the voltage measuring unit 181 changes more than the first threshold value, the first detecting unit 11 detects that the electromotive force of the motor 7 has occurred. Therefore, the control unit 5 causes the drive circuit 171 to start driving the motor 7. At this time, the set number of revolutions increases from 0 rpm to 2500 rpm, and the measured voltage value increases from 0 V to V1.

Thereafter, when the set flow rate of the air conditioner 40 decreases from 250 m ³ / h to 0 m ³ / h while the motor 7 is rotating at 2500 rpm, the measured voltage value of the voltage measurement unit 181 increases from V1 to V2 (that is, , Power consumption increases from Iin × V1 to Iin × V2). In other words, the voltage measured by the voltage measuring unit 181 increases by ΔV3 (that is, the power consumption increases by Iin × ΔV3). Therefore, the second detection unit 12 detects, for example, a predetermined change in which the power consumption increases by Iin × ΔV3 × coefficient. Therefore, the control unit 5 controls the drive circuit 171 to reduce the set number of revolutions from 2500 rpm to 0 rpm and decrease the measured voltage value from V2 to 0V.

  Next, an operation example of the separation device according to the modified example of the embodiment will be described based on the torque-rotation speed characteristics shown in FIG. In the separation device 1 of the embodiment, the drive circuit 171 includes the constant current circuit 172 that supplies a constant current to the motor 7, whereas in the separation device of the modified example, the drive circuit 171 supplies a constant voltage to the motor 7. The difference is that a voltage circuit is provided. Other configurations of the separation device of the modified example are the same as those of the separation device 1 of the embodiment, and thus illustration and description are omitted.

  In the separation device of the modified example, when the flow rate of the air flowing from the upstream side of the separation device to the space 4 between the rotor 2 and the frame 3 increases, the torque of the motor 7 increases. Here, a constant voltage (the voltage value is set to “Ea”) is applied from the drive circuit to the motor 7 (that is, the motor 7 is controlled at a constant voltage). , The power consumption of the motor 7 decreases. Therefore, the second detector 12 can detect a predetermined change in the power consumption of the motor 7. The control unit 5 controls the drive circuit so that the rotation speed of the motor 7 becomes the predetermined rotation speed when the second detection unit 12 detects a predetermined change in the power consumption of the motor 7.

  Similar to the separation device 1 of the embodiment, the separation device of the modified example can be interlocked with an air conditioner having a blowing function of sending a predetermined amount of air, and can efficiently separate solids from air. It becomes.

  The materials, numerical values, and the like described in the embodiments are merely preferable examples, and are not intended to limit the invention. Further, in the present invention, it is possible to appropriately change each of the configuration and the shape without departing from the scope of the technical idea.

  For example, the separation device 1 may be a separation device that is provided downstream of an air conditioner having a blowing function of sending air of a predetermined air volume and separates solids in the air.

  The air conditioner 40 is not limited to a blower, but may be, for example, a ventilation device, an air conditioner, an air supply cabinet fan, or an air conditioning system including a blower and a heat exchanger.

  The air-conditioning equipment 40 downstream or upstream of the separation device 1 is not limited to equipment provided in a house, but may be equipment provided in a building other than a house, a vehicle, or the like.

  Further, in the separation device 1, the outer peripheral outlet 35 may be formed directly on the frame 3.

  Further, the rotating plate 9 may be annular, and is not limited to an annular shape, and may be, for example, a gear shape. Here, the term “annular” is not limited to a completely closed shape, but also includes a shape in which a slit is partially formed (for example, a C-shape).

DESCRIPTION OF SYMBOLS 1 Separation device 2 Rotor 20 Rotation center axis 21 1st end 22 2nd end 3 Frame 33 Inner peripheral surface 4 Space 5 Control part 6 Partition plate 7 Motor 8 Flow path 11 First detection part 12 Second detection part 40 Air conditioning equipment 171 drive circuit

Claims (1)

A separation device provided on the upstream or downstream side of an air conditioner having a blowing function to separate solids from air,
Rotor and
A cylindrical frame surrounding the rotor and disposed coaxially with the rotor;
A plurality of partition plates arranged in a space between the rotor and the frame to partition the space,
Each of a plurality of flow paths defined by two adjacent partition plates and the rotor and the frame body among the plurality of partition plates,
A motor that rotates the rotor about a rotation center axis of the rotor;
A drive circuit for driving the motor,
Each of the plurality of partition plates is connected to the rotor, and is spirally formed around the rotation center axis of the rotor,
In each of the plurality of flow paths, a first end side of the rotor is an upstream side in a direction along the rotation center axis of the rotor, and a second end side of the rotor is a downstream side,
A first detection unit that detects generation of the electromotive force of the motor;
A second detection unit that detects a predetermined change in power consumption of the motor;
A control unit that controls the driving circuit,
The control unit causes the drive circuit to start driving the motor when the generation of the electromotive force of the motor is detected by the first detection unit, and when the predetermined change is detected by the second detection unit. Controlling the drive circuit so that the rotation speed of the motor becomes a predetermined rotation speed,
A separation device characterized by the above-mentioned.

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