JP5262000B2 - Dust remover - Google Patents

Description

  The present invention relates to a dust removing apparatus mainly using a filter.

  In a ventilation unit that sucks outside air in a house, office, factory, etc. and introduces it indoors, a dust removal device that uses a filter is installed to collect and remove dust and dust floating in the outside air. There is something that has been.

Conventionally, dust removal devices used in this type of ventilation unit are clogged when dust such as sand or dust adheres to the filter and accumulates, causing a reduction in ventilation airflow. Maintenance work such as replacement is frequently required. In order to simplify this maintenance work and lengthen the filter replacement cycle, a method using centrifugal force is known as a means for removing filter clogging. (For example, see Patent Document 1)
Hereinafter, the removal method will be described with reference to the dust removing device of FIG. The dust removing apparatus 101 in FIG. 7 is internally mounted in a casing 107 having a suction port 105 and a discharge port 106, with a filter unit 102 having a filter provided on a substantially cylindrical outer peripheral surface and a motor 103 coupled to each other by a coupling 104. Since the discharge port 106 is connected to the inside of the filter unit 102 and is connected to the casing 107 by a bearing 108, the filter unit 102 is rotatable. When collecting the dust in the airflow, the airflow including the dust flowing in from the suction port 105 is allowed to flow from the outside to the inside of the filter unit 102, whereby the dust is collected on the outer peripheral surface of the filter unit 102 and purified. The discharged gas flows out from the discharge port 106. And when clogging of a filter is removed, the dust adhering to an outer peripheral surface is wiped off by rotating the filter unit 102 and utilizing a centrifugal force.
Japanese Patent Laid-Open No. 11-057365

  In such a conventional dust removing device using the filter clogging removing means by centrifugal force, the force for removing dust from the filter is weak only by centrifugal force, and the dust remains on the filter without being completely removed. Further, when a laminated material is used for the filter, the dust once removed is reattached to the filter and the residual amount increases, and the frequency of occurrence of clogging of the filter increases. Moreover, the air path along which an airflow passes is complicated, and there exists a subject that the pressure loss as a dust removal apparatus is high. The present invention solves such a conventional problem, and the filter is provided with a centrifugal blower blade to rotate, so that in addition to the centrifugal force, an air flow is generated from the inside to the outside of the filter, and the drag is resisted. By acting, the force to wipe off dust becomes stronger, and at the same time, airflow passes through the filter gap, making it difficult for dust to re-adhere, reducing the frequency of clogging of the filter by reducing the residual dust on the filter . Moreover, it aims at providing the dust removal apparatus which can reduce the pressure loss of the air path which an airflow passes by the structure etc. which form a filter in a cone.

The dust removing apparatus of the present invention is configured by a cylindrical or conical filter for collecting dust, a rotating means for rotating the filter, and a fixing means for fixing the rotating means to the duct in a duct through which an airflow passes. In the cylinder of the filter, a plurality of centrifugal blower blades are evenly arranged, the filter is provided with the centrifugal blower blades, the upstream axial end face of the filter is closed, and the downstream axial direction The end surface is open, and the outer diameter of the downstream axial end surface is equal to or larger than the outer diameter of the upstream axial end surface and smaller than the duct inner diameter. When collecting airborne dust and removing the clogging of the filter, rotate the filter and the centrifugal fan blade to remove the filter from the inside simultaneously with the centrifugal force. To generate an air stream, comprising a cylindrical frame in said duct, with said filter within said cylindrical frame has a shape axial end face of the cylindrical frame smoothly connected to said duct interior surface, the said cylindrical frame A space between the rotating means is formed as an air passage, and shielding means for shielding a gap between the outer periphery of the downstream axial end face of the filter and the cylindrical frame is provided . By this means, in addition to the centrifugal force, air flow is generated from the inside to the outside of the filter by the centrifugal air blowing blade, and the drag force acts on the dust, so that the force to wipe off the dust is increased and at the same time the air flow passes through the filter gap. Since it becomes difficult for dust to reattach, it is possible to reduce the frequency of clogging of the filter by reducing the amount of dust remaining on the filter. Moreover, since the downstream axial end surface is larger than the outer diameter of the upstream axial end surface, the airflow in the duct becomes smooth and pressure loss can be reduced. Further, the cylindrical frame has a cylindrical shape, a space between the cylindrical frame and the rotating means is formed as an air passage, and shielding means is provided for shielding a gap between the outer periphery of the downstream axial end surface of the filter and the fixing means. As a result, since the dust removing device is integrated, the installation in the duct becomes easy. Further, since the end face in the axial direction of the cylindrical frame has a shape that is smoothly connected to the inner surface of the duct, the air flow in the duct can be made smooth, so that the pressure loss can be reduced. The dust removing device according to claim 1, wherein the rotating means is fixed to a cylindrical frame instead of a duct.

  Further, since the filter forms a conical surface and the apex side of the cone is the upstream side, the air flow in the duct can be made smooth while increasing the area of the filter, so that the pressure loss can be reduced.

In addition, the filter is vibrated by providing vibration means for vibrating the filter at a position facing the filter cylinder on the inner surface of the extended cylindrical frame until the cylindrical frame covers the filter in the duct axial direction. In addition, the force to remove dust together with the centrifugal force and drag becomes stronger.

In addition, the cylindrical frame is extended until it covers the filter in the axial direction of the duct, and by providing sweeping means for slidingly contacting the filter at a position facing the filter cylinder on the inner surface of the extended cylindrical frame , dust on the filter surface is removed. The effect of wiping off directly is added, and the force to wipe off dust is increased in combination with centrifugal force and drag force.

In addition, by providing a dust collection box vertically below the position of the cylindrical frame facing the filter cylinder, dust removed by rotation of the filter can be collected in one place, so that the inside of the duct is not soiled, Further, since dust does not rise, reattachment to the filter can be suppressed.

  Further, the sweeping means is a linear brush, the linear brush is arranged in the duct axial direction, and the brush tip is slidably contacted with the filter, so that the load caused by the sliding contact when rotating the filter is reduced. Since it can be made small, the power consumption of the clogging removal operation can be reduced.

  Further, since the dust collection box can be separated from the fixing means and moved in the duct axial direction, only the accumulated dust can be taken out and discarded without removing the dust removing device from the duct.

In addition, by filtration apparatus to be able to move in the duct, when removing the dust remover, such as maintenance and replacement of the duct, it can be drawn out even easier a small duct diameter.

  In addition, the clogging removal operation performed by rotating the filter is performed by detecting the absence of airflow in the duct, so that the user can check the filter's eyes during daily operation without being aware of maintenance. Since it is possible to remove clogging and the removal operation is performed each time, dust adhesion to the filter can be minimized.

  Further, when a certain time has elapsed since the previous filter clogging removal operation, the filter clogging removal operation is performed, so that the user can periodically remove clogging of the filter without being aware of maintenance.

  In addition, when a certain amount of time has elapsed after the air flow in the duct has elapsed, filter clogging removal operation is performed to effectively remove clogging of the filter without the user being aware of maintenance. can do.

  In addition, the filter clogging removal operation is performed when the clogged state of the filter is detected and the clogged state exceeds a certain level, so that the user can efficiently remove the filter without being aware of maintenance. Clogging can be removed. Since the clogging state is detected, the removal operation is not performed unnecessarily, so that the power consumption required for the removal can be minimized.

  According to the present invention, a cylindrical or conical filter is provided with a centrifugal blower blade and rotated, and in addition to centrifugal force, an air flow is generated from the inside to the outside of the filter, and a drag acts on the dust. At the same time, the air flow through the air gaps in the filter makes it difficult for the dust to re-adhere, reducing the amount of dust remaining on the filter and reducing the frequency of clogging of the filter. It is possible to provide a dust removing device that can reduce the pressure loss of the road.

According to a first aspect of the present invention, there is provided a dust removing device including a filter for collecting dust formed in a cylindrical shape or a conical shape in a duct through which an airflow passes, a rotating means for rotating the filter, and the rotating means as a duct. A plurality of centrifugal fan blades are uniformly arranged in the filter cylinder, the filter includes the centrifugal fan blades, and the upstream axial end surface of the filter is closed. The downstream axial end face is open, the outer diameter of the downstream axial end face is equal to or larger than the outer diameter of the upstream axial end face and smaller than the duct inner diameter, and airflow passes through the duct. When airflow flows through the filter from the outside to the inside to collect floating dust and remove the clogging of the filter, the filter and the centrifugal fan blades are rotated to obtain centrifugal force. Sometimes the inner airflow is generated outwardly from, comprises a cylindrical frame in said duct, with said filter within said cylindrical frame has a shape axial end face of the cylindrical frame smoothly connected to said duct inside surface, said A space between the cylindrical frame and the rotating means is formed as an air passage, and shielding means for shielding a gap between the outer periphery of the downstream axial end surface of the filter and the cylindrical frame is provided. In addition to the centrifugal force, the centrifugal air blowing blades generate airflow from the inside to the outside of the filter, and the drag acts on the dust, increasing the force to remove dust and at the same time, the airflow passes through the filter gap and the dust is regenerated. Since it becomes difficult to adhere, it is possible to reduce the clogging frequency of the filter by reducing the residue of dust on the filter. In addition, since the downstream axial end surface is larger than the outer diameter of the upstream axial end surface, the airflow in the duct is smooth, and pressure loss can be reduced. Further, the cylindrical frame has a cylindrical shape, a space between the cylindrical frame and the rotating means is formed as an air path, and shielding means for shielding a gap between the outer periphery of the downstream axial end surface of the filter and the cylindrical frame is provided. As a result, since the dust removing device is integrated, there is an effect that the mounting in the duct becomes easy. In addition, since the end face in the axial direction of the cylindrical frame is smoothly connected to the inner surface of the duct, the air flow in the duct can be smoothed, so that pressure loss can be reduced. The dust removing device according to claim 1, wherein the rotating means is fixed to a cylindrical frame instead of a duct.

Further, since the filter forms a conical surface and the apex side of the cone is the upstream side, the air flow in the duct can be made smooth while increasing the area of the filter, and thus the pressure loss can be reduced.

The dust removing device according to claim 3 of the present invention is the dust removing device according to claim 1 or 2, wherein the fixing means is extended until it covers the filter in the duct axial direction, and is opposed to the filter cylinder on the inner surface of the extended fixing means. By providing a vibration means for applying vibration to the filter at the position, vibration is applied to the filter, and the action of removing dust in combination with centrifugal force and drag force is enhanced.

The dust removing device according to claim 4 of the present invention is the dust removing device according to claim 1 or 2, wherein the fixing means is extended until it covers the filter in the duct axial direction, and is opposed to the filter cylinder on the inner surface of the extended fixing means. By providing the sweeping means in sliding contact with the filter at the position, an action of directly wiping the dust on the filter surface is added, and the action of removing the dust in combination with the centrifugal force and the drag becomes stronger.

The dust removing device according to claim 5 of the present invention is the dust removing device according to claim 3 or 4 , wherein the dust collecting box is provided vertically below the position opposite to the filter cylinder of the fixing means, so that the dust removing device is removed by rotating the filter. Since the collected dust can be collected in one place, the inside of the duct is not soiled, and the dust does not rise, so that it is possible to suppress reattachment to the filter.

The dust removing device according to claim 6 of the present invention is the dust removing device according to claim 4 or 5 , wherein the sweeping means is a straight brush, the straight brush is arranged in the duct axial direction, and the bristles of the brush serve as a filter. Since the sliding contact is made evenly, the load due to the sliding contact when the filter is rotated can be reduced, so that the power consumption of the clogging removal operation can be reduced.

The dust removing device according to claim 7 of the present invention is the dust removing device according to claim 5 or 6, wherein the dust collecting box can be separated from the fixing means and moved in the duct axial direction, so that the dust removing device can be removed from the inside of the duct. Only the accumulated dust can be taken out and discarded.

Dust removing system according to claim 8 of the present invention, in the dust removing system according to claim 2, by filtration apparatus to be able to move in the duct, when removing the dust remover, such as maintenance and replacement of the duct, Even if the duct diameter is small, it can be easily pulled out. For example, the handle is provided so that the dust removal device can move in the duct, so that when the dust removal device is removed from the duct for maintenance or replacement work, it can be easily pulled out even if the duct diameter is small. Have

The dust removing apparatus according to claim 9 of the present invention is the dust removing apparatus according to any one of claims 1 to 8, wherein the clogging removal operation performed by rotating the filter is performed by detecting that no airflow is passing through the duct. , The user can remove the clogging of the filter during daily operation without being aware of maintenance, and the dust removal on the filter is minimized because the removal operation is performed each time. It has the effect of being able to.

The dust removing device according to claim 10 of the present invention is the dust removing device according to claim 9, wherein when a certain time has elapsed from the previous filter clogging removal operation, the user performs maintenance by performing the filter clogging removal operation. Even if it is not conscious, it has the effect | action that the clogging of a filter can be removed regularly.

The dust removing device according to claim 11 of the present invention is the dust removing device according to claim 9 , wherein when the airflow passes through the duct and the fixed time elapses, the filter clogging removal operation is performed. The user can effectively remove the clogging of the filter without being aware of maintenance.

The dust removing device according to claim 12 of the present invention is the dust removing device according to claim 9 , wherein the filter clogging removal operation is performed when the clogging state of the filter is detected and the clogging state exceeds a certain level. Due to the feature, the user can efficiently remove the clogging of the filter without being aware of the maintenance. Since the clogging state is detected, the removal operation is not performed unnecessarily, so that power consumption necessary for removal can be minimized.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
1 is an overall side cross-sectional view of the dust removing apparatus according to Embodiment 1 of the present invention, FIG. 2 (a) is a cross-sectional view showing dust collecting during the same air flow, and FIG. 2 (b) is a filter clogging removing operation. It is sectional drawing which shows time.

  As shown in FIG. 1, it is installed in a duct 2 through which airflow passes. The filter 3 is formed in a cylinder, and a plurality of centrifugal fan blades 4 are equally arranged in the cylinder. The centrifugal blower blades 4 have a sirocco fan blade shape and are arranged in such a direction that the wind flows from the inside to the outside of the cylinder when rotating to remove clogging of the filter 3. The centrifugal blower blade 4 may be a turbofan blade shape.

  The upstream axial end face 5 of the filter 3 is closed and its diameter is D1, the downstream axial end face 6 is open and its diameter is D2, and the inner diameter of the duct 2 is Dd. For example, the dimensions are D1 = 50 mm and D2 = 140 mm and Dd = 150 mm, and the relationship is Dd> D2> D1. A bowl-shaped rectifying cone 7 is attached to the upstream axial end face 5 of the filter 3 as a rectifying member. The filter 3 is connected to an electric motor 8 that is a rotation means at the center of rotation of the filter 3, and the motor 8 is fixed to the inner surface of the duct 2 by a flange fitting 9 that is a fixing means so that the rotation center of the filter 3 coincides with the central axis of the duct 2. It is fixed.

  A brush 10 formed in a cylinder is attached to the downstream axial end face 6 of the filter 3 as a shielding means for shielding a gap with the inner surface of the duct 2. The outer diameter of the brush 10 is equal to the inner diameter of the duct 2, and the bristle material is nylon and the diameter is 0.3 mm. The bristle material is thin and weak, and the planted with high density is excellent in shielding the gap, and the resistance load when the filter 3 rotates is also reduced.

  In the above configuration, when an air flow including dust passes through the duct 2, the air flow flows from the outside to the inside of the filter 3 as shown in FIG. 2A, and the floating dust adheres to the filter 3 and is captured. The collected and purified airflow flows downstream. At this time, the outer diameter D2 of the downstream axial end face 6 is larger than the outer diameter D1 of the upstream axial end face 5 of the filter 3, and the rectification action of the rectifying cone 7 suppresses the generation of vortices in the duct 2 and the air flow. Since it becomes smooth, pressure loss can be reduced.

  Next, when the dust adhering to the filter 3 is removed and the clogging is removed, as shown in FIG. 2B, the motor 8 is driven to rotate the filter 3 when the airflow does not pass through the duct 2. If it is made, centrifugal force will generate | occur | produce and dust will fly to an outer peripheral side. In addition to centrifugal force, the centrifugal blower blades 4 generate an air flow from the inside to the outside of the filter 3, and a drag acts on the dust, so that the force to remove the dust is increased and at the same time the air flow passes through the gap of the filter 3. Becomes difficult to reattach. As a result, the residual dust can be reduced and the clogging of the filter 3 can be suppressed, so that the frequency of clogging can be reduced. The time for rotating the filter 3 is, for example, within 30 seconds to 3 minutes, and the dust adhering to the filter 3 can be removed within this time.

  In addition, as a control means for performing the filter clogging removal operation, a sensor detects that airflow does not pass through the duct 2 and drives the electric motor to rotate the filter. For example, a wind speed sensor for detecting the air volume in the duct is used as the sensor, but a pressure sensor for detecting a pressure difference may be used. With this control means, the user can remove clogging of the filter 3 during daily operation without being aware of maintenance, and dust adheres to the filter 3 to perform the removal operation each time. Can be minimized.

  Further, the control means for performing another filter clogging removal operation rotates the filter by driving the electric motor when a predetermined time has elapsed from the previous filter clogging removal operation. In order to detect a certain time, for example, a timer counter is used. With this control means, the user can periodically remove clogging of the filter 3 without being aware of maintenance.

  Further, the control means for performing other filter clogging removal operation is to rotate the filter by driving the electric motor when a certain time has elapsed after the time during which the airflow passes through the duct 2. In order to detect a certain time, for example, a timer counter and a wind speed sensor are used in combination. With this control means, the user can efficiently remove clogging of the filter 3 without being aware of maintenance.

  In addition, although it changes also with the air pollution degree of the area to install in a fixed time, the time corresponded for 2 months which is the cleaning period of the filter 3 provided in the conventional dust removal apparatus, for example is mentioned.

  Further, the control means for performing the filter clogging removal operation detects the clogged state of the filter 3 and rotates the filter by driving the electric motor when the clogged state exceeds a certain level. In order to detect the clogging state, for example, a method of measuring the light transmittance of the filter by combining an LED and a photocoupler is used, but a method of detecting the differential pressure before and after the filter may be used.

  With this control means, the user can efficiently remove clogging of the filter 3 without being aware of maintenance. Since the clogging state is detected, the removal operation is not performed unnecessarily, so that the power consumption required for the removal can be minimized. Although the setting of the clogging state varies depending on the connected air blowing means and the necessary air volume, for example, there is a state where the air volume is reduced to 80% with respect to the initial air volume.

(Embodiment 2)
The same parts as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. 3 is an overall side cross-sectional view of the dust removing apparatus according to Embodiment 2 of the present invention, FIG. 4 (a) is the same front view, and FIG. 4 (b) is the same rear view. As shown in FIGS. 3, 4 (a) and 4 (b), the filter 3 is formed in a conical shape, and a plurality of centrifugal blowing blades 4 are equally arranged in the cone. The fixing means is a cylindrical frame 11 molded of resin, and a space with the electric motor 8 is formed as an air passage 12.

  A labyrinth structure 13 as a shielding means is provided between the outer periphery of the downstream axial end face 6 of the filter 3 and the cylindrical frame 11. Since the labyrinth structure 13 can easily realize a shielding means by processing the downstream axial end surface 6 of the filter 3 and the cylindrical frame 11, it is possible to reduce the cost without adding expensive parts such as a bearing. . A high performance filter 14 is disposed downstream of the electric motor 8. The filter 3 is, for example, polypropylene or a metal net, and has a dust removal efficiency of 30% or more.

  The high-performance filter 14 is obtained, for example, by pleating a nonwoven fabric and has a dust removal efficiency of 60% or more. The filter 3 is laminated to improve dust removal efficiency. For example, the dust removal efficiency may be 50% or more. The cylindrical frame 11 extends in the axial direction upstream of the duct 2 to cover the filter 3, and the extended axial end surface is smoothly connected to the inner surface of the duct 2 with an orifice shape 15 that hardly generates vortices and the like. . Further, a dust collection box 16 is provided between the inner surface of the duct 2 at a position vertically below the cylindrical frame 11. The dust collection box 16 is usually fixed to the cylindrical frame 11, but can be separated and moved in the axial direction on the downstream side of the duct 2. Furthermore, a linear brush 18 as a sweeping means that slides on the tongue 17 of the centrifugal blower and the filter 3 is provided at a position facing the filter 3 on the inner surface of the cylindrical frame 11, and the filter 3 rotates from the dust collection box 16. A tongue 17 is disposed in the direction, and a linear brush 18 is disposed in the reverse rotation direction.

  The tongue portion 17 has a triangular plate shape and maintains a uniform gap with the filter. The straight brush 18 is arranged in the duct 2 axial direction, and the hair ends are in sliding contact with the filter 3 evenly. The hair material is nylon and has a diameter of 0.3 mm. The hair material which is thin and has a long bristle is excellent in the effect of removing dust, and the resistance load when the filter 3 rotates is also reduced. A handle 19 is provided on the axial end surface 6 on the downstream side of the cylindrical frame 11, but is folded vertically downward and fixed to the end surface of the cylindrical frame 11 during normal use.

  In the above configuration, when the air flow including dust passes through the duct 2, the filter 3 is conical, so that the air flow in the duct 2 can be made smooth and the area of the filter 3 is increased. Further, since the amount of dust retained increases, clogging is difficult. The airflow flowing through the filter 3 collects dust and flows through the high-performance filter 14 on the downstream side. As a result, since only the fine dust that could not be collected by the filter 3 is collected by the high-performance filter 14, the frequency of clogging can be reduced while improving the dust collection efficiency as the dust removing device 1. . Next, when removing dust adhering to the filter 3 and removing clogging, if the motor 8 is driven and the filter 3 is rotated when the airflow does not pass through the duct 2, the centrifugal force is added to the centrifugal force. An air flow is generated from the inside to the outside of the filter 3 by the blowing blades 4, but the air flow is increased by the tongue portion 17. Further, since the linear brush 18 wipes off dust adhering to the surface of the filter 3, the force for removing the dust becomes strong. Dust removed by the straight brush 18 is accumulated in the dust collection box 16.

  Next, when the removed dust accumulates in the dust collection box 16 and is taken out to the outside, the folded handle 19 is unlocked and lifted upward, so that the dust collection box 16 becomes the shaft of the duct 2. You can move freely in the direction. In this state, the dust collection box 16 is pulled out of the duct 2 in the axial direction and the accumulated dust is discarded. When the filter 3 or the high performance filter 14 is replaced or the electric motor 8 is inspected after a long period of use, if the handle 19 is pulled out and pulled out, the dust collector 1 is integrated and the outside of the duct 2 is integrated. It can be taken out easily and can be replaced and inspected easily.

(Embodiment 3)
The same parts as those in the first or second embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. FIG. 5 is an overall side cross-sectional view of the third embodiment, and FIG. 6 is a front view of the third embodiment.

As shown in FIGS. 5 and 6, the tongue 17 of the centrifugal blower and the spring member 20 having elastic restoring force as vibration means for applying vibration to the filter 3 are disposed at a position facing the filter 3 on the inner surface of the cylindrical frame 11. A plurality of protrusions 21 are provided on the outer peripheral surface of the filter 3, and when the filter 3 rotates, vibration is generated by the collision between the spring material 20 and the protrusions 21. As the spring material, for example, a thin plate of resin or metal having a thickness of about 0.3 mm to 0.5 mm is used. The rotation speed of the filter is, for example, 1200 min ⁻¹ or more.

  In the above configuration, when the dust adhered to the filter 3 is wiped off to remove clogging, the motor 8 is driven to rotate the filter 3 when the airflow does not pass through the duct 2. The centrifugal air blowing blade 4 generates an air flow from the inside to the outside of the filter 3, but the tongue portion 17 increases the air flow. Further, the vibration applied to the filter 3 increases the force for removing dust. Since the rotation of the filter 3 is used as an excitation source, there is an advantage that it is not necessary to provide another power for exciting the filter 3.

  INDUSTRIAL APPLICABILITY The dust removal apparatus of the present invention is useful for collecting and purifying floating dust when supplying outdoor air for ventilation and air conditioning of buildings. Further, the present invention can be applied to an air conditioner or an air purifier that is used while circulating indoor air.

Sectional drawing of the dust removal apparatus of Embodiment 1 of this invention Sectional drawing which shows the time of dust collection of the airflow of the dust removal apparatus and the filter clogging removal operation ((a) sectional view showing the dust collection time, (b) sectional view showing the filter clogging removal operation) ) Sectional drawing of the dust removal apparatus of Embodiment 2 of this invention Front view and rear view of the dust removing device ((a) front view, (b) rear view) Sectional drawing of the dust removal apparatus of Embodiment 3 of this invention Front view Sectional drawing which shows the filter unit of conventional invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Dust remover 2 Duct 3 Filter 4 Centrifugal ventilation blade 5 Upstream axial end face 6 Downstream axial end face 7 Rectifying cone 8 Electric motor 9 Flange fitting 10 Brush 11 Cylindrical frame 12 Air path 13 Labyrinth structure 14 High performance filter 15 Orifice shape 16 Dust Collection Box 17 Tongue 18 Linear Brush 19 Handle 20 Spring Material 21 Projection

Claims (12)

The filter has a cylindrical or conical filter for collecting dust, a rotating means for rotating the filter, and a fixing means for fixing the rotating means to the duct. A plurality of centrifugal fan blades are uniformly disposed therein, the filter includes the centrifugal fan blades, the upstream axial end surface of the filter is closed, and the downstream axial end surface is opened, The outer diameter of the downstream axial end face is equal to or greater than the outer diameter of the upstream axial end face and smaller than the duct inner diameter. When the airflow passes through the duct, the airflow flows from the outside to the inside of the filter. When collecting floating dust and removing clogging of the filter, rotate the filter and the centrifugal fan blades to generate an air flow from the inside to the outside simultaneously with the centrifugal force.
Comprising a cylindrical frame in said duct, with said filter within said cylindrical frame has a shape axial end face of the cylindrical frame smoothly connected to said duct inside surface, the space between the rotating means and the cylindrical frame There are formed as air passages, the filtration apparatus you characterized in that the outer circumference of the downstream axial end surface of the gap between the cylindrical frame provided with shielding means for shielding of the filter. The dust removing device according to claim 1, wherein the rotating means is fixed to the cylindrical frame instead of the duct. Cylindrical frame is extended to cover the filter duct axis direction, according to claim 1 or, characterized in that a vibrating means for vibrating the filter in the filter cylinder with the opposite position of the inner surface of the cylindrical frame extended 2. A dust removing device according to 2. Cylindrical frame is extended to cover the filter duct axis direction, according to claim 1 or 2, characterized in that a sliding contact with sweeping means to the filter in the filter cylinder with the opposite position of the inner surface of the cylindrical frame extended The dust removing device described in 1. The dust removing device according to claim 3 or 4 , wherein a dust collection box is provided vertically below a position of the cylindrical frame facing the filter cylinder. 6. The dust removing apparatus according to claim 4 , wherein the sweeping means is a linear brush, the linear brush is disposed in the duct axial direction, and the hair ends of the brush are in sliding contact with the filter evenly. The dust removing apparatus according to claim 5 or 6 , wherein the dust collecting box is separated from the cylindrical frame and is movable in the duct axial direction. Filtration apparatus according to claim 2, the filtration apparatus is characterized in that it can be moved in the duct. 9. The dust removing apparatus according to claim 1, wherein the clogging removal operation performed by rotating the filter is performed by detecting that no airflow passes through the duct. The dust removal device according to claim 9 , wherein the filter clogging removal operation is performed after a predetermined time has elapsed since the previous filter clogging removal operation. 10. The dust removing device according to claim 9 , wherein the filter clogging removing operation is performed when a certain time has elapsed after the time during which the airflow passes through the duct. 10. The dust removing device according to claim 9 , wherein when the clogged state of the filter is detected and the clogged state exceeds a certain level, the filter clogging removing operation is performed.

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