JP2010201280A - Cyclone device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cyclone device efficiently separating granules from fine powder with simple constitution. <P>SOLUTION: The cyclone device 1 includes: a substantially cylindrical body 2 having an axial line X in a perpendicular direction; an inflow tube 3 communicated with the body 2 and connected along the tangential direction of the body 2; an inner cylinder 4 provided in the upper part in the body 2; an exhaust tube 5 provided on the upper side of the inner cylinder 4 and communicated therewith; an exhaust part 8 provided on the lower side of the body 2 and communicated therewith; and an air force introducing device 10 that is provided in the exhaust part 8 and that generates a ascending air current toward the lower end of the inner cylinder 4. Downward from the lower end of the inner cylinder 4, there is provided a guide board 13 for guiding the generated ascending air current along the circumferential direction, or at a position lower than the lower end of the inner cylinder 4, a suppression board 23 for suppressing circulation of a swirl flow of a primary air flowing in from the inflow tube 3 is provided. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a cyclone device, and more particularly to a cyclone device suitably used for fine powder removal.

When resin pellets are pneumatically transported, fine powder may be generated from the resin pellets.
If such fine powder adheres to the resin pellet, the molded product obtained using the resin pellet may cause problems such as fish eyes, so the resin pellet (particles) and fine powder are separated. It is required to remove fine powder.
It is known that such resin pellets (particles) and fine powder are separated by a cyclone.

  As such a cyclone, for example, a cylindrical main body having a vertical axis is provided, and an inflow pipe for allowing air particles transported to the cylindrical main body to flow into the cylindrical main body is tangent to the peripheral wall of the cylindrical main body. A discharge port for discharging powder particles from the cylindrical main body is formed at the lower end of the cylindrical main body, and transport air flows out of the cylindrical main body on the upper wall of the cylindrical main body. A cyclone has been proposed in which an outflow pipe is connected, a lower end of the outflow pipe faces into the cylindrical main body, and further includes an air supply means for supplying a rising air flow from the discharge port into the cylindrical main body. (For example, refer to Patent Document 1).

In this cyclone, when the air flow and the granular material flowing in from the inflow pipe descend by turning along the inner wall of the cylindrical part by pneumatic transportation, the granular material is separated into granular material and fine powder by centrifugal force. Is done.
In the vicinity of the lower end portion of the cylindrical main body, the airflow is reversed without decreasing the swirling speed of the swirling flow, and rises into the outflow pipe while rotating the center of the cyclone, and is discharged by the air feeding means. An ascending air flow from the outlet into the tubular body is supplied.

  Therefore, in this cyclone, while the granular material is pneumatically transported and the granular material is discharged from the lower discharge port, the fine powder can be removed (outflowed) upward from the outflow pipe together with the air flow.

JP 2008-110316 A

However, in recent years, in the cyclone apparatus, further improvement in the separation efficiency between the granular material and the fine powder is desired.
The objective of this invention is providing the cyclone apparatus which can isolate | separate a granule and fine powder efficiently with a simple structure.

  In order to achieve the above object, a cyclone device according to the present invention includes a substantially cylindrical main body having an axis in a vertical direction, and an inflow pipe that communicates with the main body and is connected along a tangential direction of the main body. And an inner cylinder part provided at the upper part in the main body part, an exhaust pipe provided on the upper side of the inner cylinder part and communicating with the inner cylinder part, provided on the lower side of the main body part, A communicating discharge section; an air force introducing device for generating an updraft directed to the lower end of the inner cylinder section; and an upward flow generated from the lower end of the inner cylinder section. And a guide member for guiding along the circumferential direction.

The aerodynamic force introduced from the aerodynamic force introduction device into the main body is generated as an upward air flow that simply goes upward without turning in the circumferential direction.
However, according to this cyclone device, the ascending airflow generated from the aerodynamic introduction device is swung in the circumferential direction below the lower end of the inner cylinder portion by the guide plate.
And in the main body part, the air containing the particles and fine powder flowing in from the inflow pipe descends while swirling along the tangential direction, and the air is circumferentially below the lower end of the inner cylinder part. Acts on the swirling updraft.

Then, the particles and fines in the air that flowed in from the inflow pipe are easily separated by the change of the air flow, and the powder falls to the discharge part, while the fine powder is discharged from the discharge pipe through the lower end of the inner cylinder part. Is done.
Therefore, the separation efficiency between the granular material and the fine powder can be improved with a simple configuration.
Further, in the cyclone device according to the present invention, the guide member is inclined along a direction opposite to a turning direction in which the air flowing in from the inflow pipe turns in the main body portion from the radially outer side toward the radially inner side. It is preferable that

The fine powder contained in the air flowing in from the inflow pipe swirls along the inner wall surface of the main body and is given centrifugal force, so that it partially stays below the lower end of the inner cylinder.
However, according to this cyclone device, the ascending airflow generated from the aerodynamic force introduction device swirls in the direction opposite to the swirling direction of the air swirling from the inflow pipe below the lower end of the inner cylinder portion by the guide member. .

  Therefore, below the lower end of the inner cylinder part, the air swirling from the inflow pipe collides with the rising airflow generated from the aerodynamic introduction device, the swirling speed is reduced, and the centrifugal force applied to the fine powder in the air Power is reduced. If it does so, it will become difficult to turn fine powder along the inner wall surface of a main-body part, and the turning speed of the turning of an updraft will fall (it will weaken), Therefore, fine powder will be discharged through the lower end of an inner cylinder part Is efficiently discharged.

As a result, the separation efficiency between the granules and the fine powder can be improved.
Further, in the cyclone device of the present invention, the guide member is inclined along the same direction as the turning direction in which the air flowing in from the inflow pipe turns in the main body portion from the radially outer side toward the radially inner side. It is preferable that
According to this cyclone device, the ascending airflow generated from the aerodynamic introduction device is swung in the same direction as the swirling direction of the air flowing from the inflow pipe and swirling below the lower end of the inner cylinder portion by the guide member.

  Therefore, below the lower end of the inner cylinder part, the air swirling from the inflow pipe is united with the rising air flow generated from the aerodynamic introduction device, and the swirling speed is increased, which is given to the particles in the air. Increased centrifugal force. As a result, the granules turn for a longer time along the inner wall surface of the main body, and a sufficient shearing force due to friction between the powder and the inner wall surface of the main body is imparted to the powder. Therefore, the fine powder adhering to the granules is detached from the powder and efficiently discharged from the lower end of the inner cylinder portion through the discharge pipe.

As a result, the separation efficiency between the granules and the fine powder can be improved.
Further, in the cyclone device according to the present invention, the aerodynamic introduction device is provided in the discharge portion, and an aerodynamic supply pipe sharing the axis of the main body, and an upper end of the aerodynamic supply pipe are closed, and the main body and the axis A substantially conical covering portion that shares the same, a through hole that penetrates the thickness direction is formed in the aerodynamic supply pipe, and a plurality of the guide members are provided on the upper surface of the covering portion. Is preferred.

According to this cyclone device, the aerodynamic force can be supplied into the main body through the through hole of the aerodynamic supply pipe, and the aerodynamic force is reliably guided along the circumferential direction by a plurality of guide members provided on the upper surface of the covering portion. Can be made.
Moreover, it can prevent that the granule which falls in a discharge part penetrate | invades into an aerodynamic supply pipe | tube from a through hole by a coating | coated part.

Therefore, it is possible to reliably improve the separation efficiency between the granules and the fine powder.
Further, in the cyclone device according to the present invention, the aerodynamic introduction device is provided in the discharge portion, and an aerodynamic supply pipe sharing the axis of the main body, and an upper end of the aerodynamic supply pipe are closed, and the main body and the axis A substantially conical covering portion that shares the same, and the pneumatic supply pipe has a through-hole penetrating in the thickness direction, and a plurality of the guide members are provided on the inner wall surface of the discharge portion. Is preferred.

According to this cyclone device, the aerodynamic force can be supplied into the main body portion from the through hole of the aerodynamic supply pipe, and the aerodynamic force is reliably ensured along the circumferential direction by a plurality of guide members provided on the inner wall surface of the discharge portion. You can be guided.
Moreover, it can prevent that the granule which falls in a discharge part from the lower end of a main-body part penetrate | invades into an aerodynamic supply pipe | tube from a through hole by a coating | coated part.

Therefore, it is possible to reliably improve the separation efficiency between the granules and the fine powder.
The cyclone device of the present invention includes a substantially cylindrical main body having an axis in the vertical direction, an inflow pipe that communicates with the main body and is connected along a tangential direction of the main body, An inner cylinder part provided at the upper part, an exhaust pipe provided on the upper side of the inner cylinder part and communicating with the inner cylinder part, a discharge part provided on the lower side of the main body part and communicating with the main body part, An aerodynamic force introducing device for generating an upward air flow toward the lower end of the inner cylinder part provided in the discharge part, and air that is provided below the lower end of the inner cylinder part in the main body part and flows in from the inflow pipe And a suppressing member that suppresses the swirling of the swirling flow.

  According to this cyclone device, the swirling of the air flowing in from the inflow pipe is suppressed by the suppression member below the lower end of the inner cylinder portion in the main body portion. For this reason, the swirling speed of the air swirling from the inflow pipe decreases, and the centrifugal force applied to the fine powder in the air decreases. If it does so, it will become difficult to turn fine powder along the inner wall face of a main-body part, Therefore, it will be efficiently discharged | emitted from a discharge pipe via the lower end of an inner cylinder part.

As a result, the separation efficiency between the granules and the fine powder can be improved with a simple configuration.
In the cyclone device of the present invention, it is preferable that a plurality of the suppression members are provided on the inner wall surface of the main body.
In this cyclone device, the swirling of the air flowing from the inflow pipe can be reliably suppressed by a plurality of suppression members provided on the inner wall surface of the main body.

  According to the cyclone device of the present invention, it is possible to improve the separation efficiency between particles and fine powder with a simple configuration.

It is the schematic which shows one Embodiment (The aspect by which the turning direction of secondary air and primary air is a reverse direction, and a guide plate is provided in the upper surface of a coating | coated part) of this invention. It is a top view of the cyclone apparatus shown in FIG. It is a principal part side view of the secondary air introduction apparatus of the cyclone apparatus shown in FIG. It is a top view of the secondary air introduction apparatus shown in FIG. It is a top view of the secondary air introduction device of other embodiments (a mode in which turning directions of secondary air and primary air are the same direction) of the cyclone device of the present invention. It is the schematic which shows other embodiment (The aspect by which a guide plate is provided in the inner wall face of an upper casing) of the cyclone apparatus of this invention. It is the schematic which shows other embodiment (The aspect in which a suppression board is provided in the inner wall face of the lower part of a main-body part) of the cyclone apparatus of this invention.

FIG. 1 is a schematic view showing an embodiment of the cyclone device of the present invention (a mode in which the swirling directions of the secondary air and the primary air are opposite, and the guide plate is provided on the upper surface of the covering portion). FIG. 3 is a plan view of the cyclone device shown in FIG. 1, FIG. 3 is a side view of the main part of the secondary air introduction device of the cyclone device shown in FIG. 1, and FIG. 4 is a plan view of the secondary air introduction device shown in FIG. It is.
In the following description, the upstream side in the transport direction and the downstream side in the transport direction of air and powder (including fine powder and granules) are simply referred to as “upstream side” and “downstream side”.

1 and 2, the cyclone device 1 is applied to an aerodynamic transportation device, for example, by separating particles (pellets) and fine particles (dust) from powder particles made of plastic, and separating the particles. The body is used to feed other processing equipment such as, for example, a molding machine.
The cyclone device 1 includes a main body 2, an inflow pipe 3 that communicates with the main body 2, an inner cylinder 4 that is provided in the upper part of the main body 2, a discharge pipe 5 that communicates with the inner cylinder 4, and a main body 2, a discharge portion 8 communicating with 2, a secondary air introduction device 10 as an aerodynamic introduction device for generating an updraft, and a guide plate 13 as a guide member for guiding the generated updraft along the circumferential direction. And.

The main body 2 is formed in a substantially cylindrical shape having an axis X in the vertical direction, and integrally includes an outer cylinder 22 and a cone 7.
The outer cylinder portion 22 is formed in a substantially cylindrical shape having an axis line X in the vertical direction, and the lower end portion thereof is connected to the upper end portion of the conical portion 7. A substantially disk-shaped upper wall portion 9 is formed at the upper end portion of the outer cylindrical portion 22. The upper wall part 9 supports the inner cylinder part 4 so that the inner cylinder part 4 penetrates.

The conical portion 7 has an upper end connected to the lower end of the outer cylindrical portion 22 and is formed in a substantially conical cylindrical shape whose diameter is gradually reduced from the upper side to the lower side. A lower end portion of the conical portion 7 serves as a discharge port 6 for discharging the particles to the discharge portion 8.
The discharge port 6 discharges particles from the cone portion 7 to the discharge portion 8 and is also an introduction port for introducing secondary air as aerodynamic force from the secondary air introduction device 10 to the main body portion 2.

The inflow pipe 3 is provided in order to pneumatically transport the primary air including the powder particles from the inflow pipe 3 to the outer cylinder portion 22, and is formed in a substantially circular tube shape.
The inflow pipe 3 extends in the horizontal direction at the upper part of the outer cylinder part 22, is connected along the tangential direction of the outer cylinder part 22, and communicates with the outer cylinder part 22. Specifically, the downstream end of the inflow pipe 3 has a direction (a tangential direction one side) in which the granular material pneumatically transported to the main body 2 can turn along the direction A counterclockwise in plan view in the main body 2. Are connected to the outer cylinder portion 22. Moreover, although not shown in figure, the storage tank in which the granular material (a granular material and a fine powder are contained) was stored is connected to the upstream edge part of the inflow tube 3. FIG.

  The inner cylinder part 4 is formed in a substantially cylindrical shape having a smaller diameter than the outer cylinder part 22 sharing the axis X of the main body part 2, and is spaced apart from the outer cylinder part 22 radially inward. 22 is provided in parallel. Further, the inner cylinder portion 4 is supported in the middle in the vertical direction through the upper wall portion 9, and the upper end portion communicates with the discharge pipe 5. Further, the lower end portion of the inner cylinder portion 4 is disposed above (on the outer cylinder portion 22 side) the boundary between the outer cylinder portion 22 and the conical portion 7.

  The discharge pipe 5 is provided in the upper end part of the inner cylinder part 4, is extended in the horizontal direction, and is formed in the substantially cylindrical shape. That is, the discharge pipe 5 is connected to the upper end portion of the inner cylinder portion 4 above the upper wall portion 9 and communicates with the inner cylinder portion 4. A suction device such as a suction blower is connected to the downstream end of the discharge pipe 5 (not shown). The suction device is a drive source for the pneumatic transportation of primary air containing the granular material.

The discharge part 8 is provided in the lower part of the main body part 2, is formed in a substantially cylindrical shape sharing the axis X of the main body part 2, and includes a casing 11 integrally including an upper casing 19 and a lower casing 20. Yes.
The upper casing 19 has an upper end connected to the lower end of the conical portion 7 and is formed in a substantially conical cylinder shape that gradually increases in diameter from the upper side to the lower side.

The lower casing 20 has an upper end connected to the lower end of the upper casing 19. The lower casing 20 is formed in a substantially cylindrical shape.
The discharge unit 8 is provided with a hopper (not shown) that is continuous with the lower end of the lower casing 20 below the lower casing 20.
The secondary air introduction device 10 is a device that is provided in the discharge portion 8 and generates an upward air flow (secondary air) toward the lower end portion of the inner cylinder portion 4.

The secondary air introduction device 10 includes a secondary air supply pipe 14 as an aerodynamic supply pipe and a covering portion 15.
The secondary air supply pipe 14 is formed in a substantially cylindrical shape, and a downstream end is provided in the casing 11 and communicates with the discharge part 8 through a through hole 12 described later. The upstream end of the secondary air supply pipe 14 is open to the atmosphere.

Specifically, in the casing 11, the secondary air supply pipe 14 extends from the downstream end portion toward the lower side (vertical direction lower side), and then bends to the side (horizontal direction). After passing through the casing 20 and extending out of the casing 11, it is bent upward (upward in the extending direction).
Further, in the secondary air supply pipe 14, a portion extending in the vertical direction in the casing 11 shares the axis X of the main body portion 2, and an upper end portion thereof is closed by a covering portion 15 described below. Further, in the secondary air supply pipe 14, a through hole 12 described below is formed in an upper portion extending in the vertical direction.

The through holes 12 are formed as round holes that penetrate the thickness direction of the secondary air supply pipe 14, and a plurality of through holes 12 are provided along the circumferential direction of the secondary air supply pipe 14 at intervals.
Further, the secondary air supply pipe 14 is provided with a filter 18 and a valve 17. The filter 18 is installed at an upstream end portion of the secondary air supply pipe 14 and includes, for example, a dust removing device such as an air breather. The valve 17 is interposed on the downstream side of the filter 18 in the secondary air supply pipe 14 outside the casing 11.

As shown in FIG. 1 and FIG. 3, the covering portion 15 is provided at the upper end portion of the secondary air supply pipe 14 in the casing 11, and is disposed opposite to the upper casing 19 at a distance from the inside in the radial direction. Yes.
The covering portion 15 is provided on the upper portion of the through hole 12 so as to cover the through hole 12. More specifically, the covering portion 15 is disposed to face the upper side of the through hole 12 with a space therebetween.

Further, the covering portion 15 shares the axis X with the main body portion 2 and is formed in a substantially conical shape (a camp shape or a cone shape) whose diameter is gradually increased from the upper side toward the lower side.
The peripheral end portion (radially outer end portion) of the covering portion 15 is larger than the outer diameter of the secondary air supply pipe 14 and is disposed so as to include the secondary air supply pipe 14 when projected in the vertical direction. . Moreover, the lower end part (radial direction outer side edge part) of the coating | coated part 15 is arrange | positioned so that the upper part of the through-hole 12 may be included when it projects in a horizontal direction.

A plurality of guide plates 13 are provided in the casing 11 so as to stand on the upper surface of the covering portion 15. As shown in FIG. 3 and FIG. 4, each guide portion 13 has a substantially rectangular plate shape (substantially rectangular fin shape), and is arranged at intervals in the circumferential direction of the covering portion 15.
Each guide plate 13 is disposed to be inclined with respect to the radial direction of the covering portion 15. Specifically, each guide plate 13 is disposed so as to be inclined along a clockwise direction B in plan view from the radially outer side to the radially inner side of the covering portion 15 in plan view.

As shown in FIG. 4, the angle α formed between the direction along the guide plate 13 and the radial direction of the covering portion 15 in a plan view is not particularly limited, and is appropriately selected depending on the processing capacity and scale of the cyclone device 1. For example, it is set to 30 to 80 degrees, preferably 40 to 75 degrees.
As shown in FIGS. 3 and 4, the lower end portion of the radially outer end portion of the guide plate 13 is disposed at the same position as the radially outer end portion (circumferential end portion) of the covering portion 15. The lower end portion of the radially inner end portion of the cover portion 15 is arranged at a midpoint from the radially outer side of the covering portion 15 toward the radially inner side so as to expose the central portion of the covering portion 15 (radial center portion, upper end portion). ing. Note that the upper end portion of the radially inner end portion of the guide plate 13 is disposed slightly below the discharge port 6.

As shown in FIG. 1, a space partitioned by the inner wall surface of the upper casing 19 and the upper surface of the covering portion 15 between the upper casing 19 and the covering portion 15 is secondary air in the secondary air introducing device 10. The guide passage 21 guides the guide along the circumferential direction.
Next, a method for separating particles and fine particles and a method for removing fine particles using the cyclone device 1 will be described.

In this method, first, in FIG. 1 and FIG. 2, a suction blower (not shown) connected to the discharge pipe 5 is driven.
Thereby, the inside of the main-body part 2 becomes pressure reduction, and the air (primary air) containing a granular material is pneumatically transported. That is, primary air flows from the inflow pipe 3 into the main body 2.
Then, the powder particles in the primary air are swung in the counterclockwise direction A in plan view along the inner wall surface of the outer cylinder portion 22 in the main body portion 2, and the powder particles While sufficiently giving a shearing force due to friction with the inner wall surface of the outer cylindrical portion 22 and separating the particles and fine particles contained in the particles, the air flow (swirl flow) of the particles and the primary air, Lower to cone 7.

Next, the primary air descending to the conical portion 7 is acted on the ascending airflow described below, which is swung in the circumferential direction while being guided by the guide plate 13 below the lower end portion of the inner cylinder portion 4.
Then, the particles and the fine powder in the primary air are easily separated by the change of the air flow, and the powder falls to the discharge portion 8 through the discharge port 6, while the fine powder passes through the lower end of the inner cylinder portion 4. And discharged from the discharge pipe 5.

Moreover, since the fine powder contained in the primary air flowing in from the inflow pipe 3 swirls along the inner wall surface of the conical part 7 and is given centrifugal force, it is lower than the lower end part of the inner cylinder part 4. In part, it stays partially.
Then, secondary air is introduced from the secondary air introduction device 10 into the main body 2 together with the driving of the suction blower described above. The secondary air becomes a rising airflow toward the lower end of the inner cylinder portion 4 in the main body portion 2.

  Specifically, in FIGS. 1, 3, and 4, in the secondary air introduction device 10, the suction device (not shown) connected to the discharge pipe 5 drives the secondary air supply pipe 14 via the upstream end portion. Air is supplied into the casing 11 by sucking air (air) and discharging the air from the through hole 12 into the casing 11 in the radially outward direction. And the air discharged toward the outer side in the radial direction wraps around from the lower side of the covering part 15 to the upper side so as to bypass the peripheral end of the covering part 15, and then from the outer side in the radial direction of the covering part 15. Inwardly, it is guided in the guide passage 21 along the direction B in the clockwise direction in plan view by the guide plate 13 and is introduced into the main body 2 from the discharge port 6 as secondary air that is an updraft.

In that case, secondary air can be supplied into the main body 2 from the through hole 12 of the aerodynamic supply pipe 14, and the secondary air is surrounded by a plurality of guide plates 13 provided on the upper surface of the covering portion 15. It can be made to guide reliably along a direction.
In the cyclone device 1, the ascending air flow generated from the secondary air introduction device 10 flows from the inflow pipe 3 in the main body portion 2 below the lower end portion of the inner cylinder portion 4 of the main body portion 2 by the guide plate 13. The swirling direction of the swirling primary air swirls in the direction opposite to the swirling direction (counterclockwise direction A in plan view) and the opposite direction (clockwise direction B in plan view).

  Therefore, the primary air that has flowed in from the inflow pipe 3 collides with the secondary air (ascending airflow) generated from the secondary air introduction device 10, and the turning speed is reduced and is given to the fine powder in the primary air. Centrifugal force decreases. If it does so, it will become difficult to turn fine powder along the inner wall face of the main-body part 2, and the turning speed of turning of an updraft will fall (it will weaken), Therefore, fine powder floats up smoothly, an inner cylinder part 4 is efficiently discharged from the discharge pipe 5 via the lower end portion of 4.

In particular, dust having a large diameter (same size as a granule) is more difficult to swivel, and therefore floats more smoothly and is efficiently discharged.
And although not shown in figure, the fine powder and dust discharged | emitted from the inner cylinder part 4 via the discharge pipe 5 are introduce | transduced into a dust collection filter, for example, and are collect | recovered.
On the other hand, the granules fall in the casing 11 of the discharge unit 8 from the discharge port 6 and are temporarily stored in a hopper (not shown) of the discharge unit 8.

Further, the particles that fall in the casing 11 of the discharge portion 8 from the discharge port 6 are prevented from entering the secondary air supply pipe 14 from the through hole 12 by the covering portion 15.
In the above-described separation of the granular material, the separation efficiency between the granular material and the fine powder can be improved with a simple configuration.
In the above description, the secondary air introduction apparatus 10 sucks the air from the secondary air supply pipe 14 and introduces the secondary air into the main body 2 by driving the suction blower of the discharge pipe 5. For example, although not shown, instead of driving the above-described suction blower or by driving the above-described suction blower, by driving a blower such as a blower connected to the upstream side of the secondary air supply pipe 14 Secondary air can also be introduced.

In the cyclone device 1, although not shown, an internal filter for preventing particles from entering the discharge pipe 5 can be provided in the inner cylinder portion 4.
In the above description, the upper end of the radially inner end of the guide plate 13 is disposed slightly below the discharge port 6. However, although not illustrated, for example, it is disposed slightly above the discharge port 6. You can also

FIG. 5 is a plan view of a secondary air introduction device according to another embodiment of the present invention (an embodiment in which the turning directions of the secondary air and the primary air are the same). In addition, about the member corresponding to each above-mentioned part, the same referential mark is attached | subjected in each subsequent figure, and the detailed description is abbreviate | omitted.
In the description of FIG. 4 described above, the guide plate 13 is provided so as to turn the secondary air in the clockwise direction B in the plan view. For example, as shown in FIG. It can also be provided to turn in direction A.

That is, the guide plate 13 is disposed so as to be inclined along the direction A counterclockwise in plan view as it goes from the radially outer side of the covering portion 15 toward the radially inner side in plan view.
According to the cyclone device 1, the rising air flow generated from the secondary air introduction device 10 is swung in the main air flow from the inflow pipe 3 in the main body 2 by the guide plate 13 (plan view). Turn in the same direction as clockwise direction A).

  Therefore, below the lower end portion of the inner cylinder portion 4 in the main body portion 2, the primary air that flows and swirls from the inflow pipe 3 is united with the secondary air of the updraft generated from the secondary air introduction device 10. Thus, the turning speed increases, and the centrifugal force applied to the particles in the primary air increases. If it does so, a granule will turn for a long time along the inner wall face of the cone part 7. FIG. Further, since the particles stay in the conical portion 7 for a long time while being blown upward by the ascending air current generated from the secondary air introduction device 10, the particles rotate along the inner wall surface of the conical portion 7 for a longer time. Can do.

Then, a shearing force due to friction between the powder and the inner wall surface of the conical portion 7 is sufficiently applied to the powder.
Therefore, the fine powder adhering to the granules is detached from the powder and efficiently discharged from the lower end portion of the inner cylinder portion 4 through the discharge pipe 5.
As a result, the separation efficiency between the granules and the fine powder can be improved.

FIG. 6 is a schematic view showing another embodiment of the cyclone device of the present invention (a mode in which the guide plate is provided on the inner wall surface of the upper casing).
In the above description, the guide plate 13 is provided on the upper surface of the covering portion 15, but the arrangement of the guide plate 13 is not particularly limited as long as it is below the lower end portion of the inner cylinder portion 4.
For example, as shown in FIG. 6, a plurality of guide plates 13 can be provided on the inner wall surface of the upper casing 19.

The upper end portion of the guide plate 13 is disposed at the same position as the discharge port 6.
The guide plate 13 is disposed so as to be inclined from the radially outer side of the upper casing 19 toward the radially inner side.
The guide plate 13 is below the lower end portion of the inner cylinder portion 4 of the main body portion 2 and has a swirling direction of primary air that swirls in the main body portion 2 through the inflow pipe 3 (a counterclockwise direction A in plan view). It may be arranged to be inclined so as to turn in the opposite direction (clockwise direction B in plan view) or may be arranged to be inclined so as to turn in the same direction (direction A counterclockwise in plan view). It may be.
In the cyclone device 1, similarly to the above, the ascending air current can be reliably guided along the circumferential direction by the guide plate 13, thereby reliably improving the separation efficiency between the granular material and the fine powder. Can do.

FIG. 7 is a schematic view showing another embodiment of the cyclone device according to the present invention (a mode in which the suppression plate is provided on the inner wall surface of the lower portion of the main body).
Further, for example, as shown in FIG. 7, instead of the above-described guide plate 13, a suppression plate 23 is provided as a suppression member that suppresses the swirling of the swirling flow of the primary air (air) flowing from the inflow pipe 3. You can also.

A plurality of suppression plates 23 are provided below the lower end portion of the inner cylinder portion 4, and a plurality of suppression plates 23 are provided so as to stand on the inner wall surface of the lower portion of the conical portion 7. Each restraining plate 23 is formed in substantially the same shape as the guide plate 13 described above, and the restraining portions 23 are radially spaced from each other over the circumferential direction of the conical portion 7 and centered on the axis X of the conical portion 7. Is arranged.
Further, each suppressing portion 23 extends in the substantially vertical direction along the radial direction of the conical portion 7.

According to the cyclone device 1, the swirling of the primary air flowing in from the inflow pipe 3 is suppressed by the suppression unit 23 below the lower end portion of the inner cylinder portion 4 in the main body unit 2. More specifically, swirling of the primary air can be reliably suppressed by a plurality of suppressing portions 23 provided on the inner wall surface of the main body portion 4.
Therefore, the turning speed of the turning primary air is lowered, and the centrifugal force applied to the fine powder in the primary air is lowered. If it does so, it will become difficult to turn fine powder along the inner wall face of the main-body part 4, Therefore, it will be efficiently discharged | emitted from the discharge pipe 5 via the lower end part of the inner cylinder part 4. FIG.

On the other hand, the ascending airflow generated from the secondary air introduction device 10 does not swirl along the circumferential direction of the main body 2 and simply goes toward the lower end of the inner cylinder 4. The particles stay in the conical portion 7 for a long time while being blown upward by the ascending air current, and thus can turn along the inner wall surface of the conical portion 7 for a longer time.
As a result, the separation efficiency between the granules and the fine powder can be improved with a simple configuration.

  Although not shown, for example, in the cyclone device 1, the guide plate 13 and the suppression plate 23 described above can be used in combination.

DESCRIPTION OF SYMBOLS 1 Cyclone apparatus 2 Main body part 3 Inflow pipe 4 Inner cylinder part 5 Discharge pipe 8 Discharge part 10 Secondary air introduction apparatus 12 Through hole 13 Guide plate 14 Secondary air supply pipe 15 Covering part 23 Suppression part A Plane view anticlockwise Direction B Plane direction clockwise X axis

Claims (7)

A substantially cylindrical body having an axis in the vertical direction;
An inflow pipe that communicates with the main body and is connected along a tangential direction of the main body;
An inner cylinder provided in the upper part of the main body,
A discharge pipe provided on the upper side of the inner cylinder part and communicating with the inner cylinder part;
A discharge portion provided on the lower side of the main body portion and communicating with the main body portion;
An aerodynamic introduction device for generating an upward air flow provided in the discharge portion and directed toward a lower end of the inner cylinder portion;
A cyclone device comprising: a guide member provided below the lower end of the inner cylinder portion for guiding the generated ascending airflow along the circumferential direction. The said guide member is inclined along the direction opposite to the turning direction in which the air which flowed in from the said inflow pipe turns in the said main-body part as it goes to radial inside from radial outside. The cyclone device according to 1. The said guide member is inclined along the same direction as the turning direction in which the air which flowed in from the said inflow pipe turns in the said main-body part as it goes to radial inside from radial outside. The cyclone device according to 1. The power introduction device is
An aerodynamic supply pipe provided in the discharge part and sharing the axis of the main body part;
The upper end of the aerodynamic supply pipe is closed, and includes a substantially conical covering portion sharing an axis with the main body portion,
A through hole penetrating the thickness direction is formed in the aerodynamic supply pipe,
The cyclone device according to any one of claims 1 to 3, wherein a plurality of the guide members are provided on an upper surface of the covering portion. The power introduction device is
An aerodynamic supply pipe provided in the discharge part and sharing the axis of the main body part;
The upper end of the aerodynamic supply pipe is closed, and includes a substantially conical covering portion sharing an axis with the main body portion,
A through hole penetrating the thickness direction is formed in the aerodynamic supply pipe,
The cyclone device according to any one of claims 1 to 3, wherein a plurality of the guide members are provided on an inner wall surface of the discharge portion. A substantially cylindrical body having an axis in the vertical direction;
An inflow pipe that communicates with the main body and is connected along a tangential direction of the main body;
An inner cylinder provided in the upper part of the main body,
A discharge pipe provided on the upper side of the inner cylinder part and communicating with the inner cylinder part;
A discharge portion provided on the lower side of the main body portion and communicating with the main body portion;
An aerodynamic introduction device that is provided in the discharge portion and generates an upward airflow toward the lower end of the inner cylinder portion;
A cyclone device comprising: a suppression member that is provided below the lower end of the inner cylinder portion in the main body portion and suppresses the swirling of the swirling flow of air flowing in from the inflow pipe.   The cyclone device according to claim 6, wherein a plurality of the suppression members are provided on an inner wall surface of the main body.

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