DE3024853A1 - WINDSCREEN DEVICE - Google Patents

Description

PATENT ADVERTISER DIFL-ING DR. MANFRED RAU

D-8500 NUREMBERG 91 PO Box 91 0480 LANGE ZEILE 30 TELEFON O9II / 37I 47 TELEX Oi / 23

Nuremberg, June 3rd, 1980

Kawasaki Jukogyo Kabushiki Kaisha No. 14, Higashikawasaki-cho 2-chome, Ikuta-ku, Kobe-shi, Hyogo-ken, Japan

Wind sifting device

030064/0852

description

The invention relates to an air sifter for separating fine pulverized material from coarse pulverized material using an air stream.

In a known wind sifting device, pulverized material is largely affected by its impact Separating blades of a rotor scattered and crashed against the wall of a separation chamber and the generation centrifugal forces caused by the flow of air in vortex form can hardly be expected. Hence this species of devices unable to increase the selectivity with which the separation is effected, as a great difference between a force directed towards the wall of the separation chamber acting on the pulverized Material acts and a force directed towards the center of the separation chamber, which also acts on the pulverized Material works, exists. In this description, the sharpness with which the separation is effected is that Degree to which the amount of the coarse particles contained in the fine particles is decreased when deviations exist in the diameter of the particles to be separated. Increasing the selectivity with which the separation is effected, requires an increase in volume of the separation chamber in order to mutually influence the Prevent particles, such as from a collision. This means that the amount of pulverized material

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processed by this type of apparatus per unit cross-sectional area of the separation chamber will. Increasing the amount of powdered material processed by the device requires an increase in the size of the air separator, with the result that the specific need of energy to drive the separating vanes of the rotor (energy / amount of de ^ pulverized material per unit area processed) is increased. at

another known type of wind sifting device

pulverized material is produced largely through the use of centrifugal forces created by one in the separation chamber vortex flow generated are generated separately. This type of device is designed so that the Separation of fine particles from coarse particles by colliding the pulverized material with the separating blades cannot be expected, as is the case with the first-mentioned type of known device. In addition, the separating vanes have a large extension radially to the separating chamber, so that a force acting on it is directed to scatter the powdered material and which is exerted by the separating vanes, radially to the Separation chamber can become uneven. This causes a difference between the scattering force applied to the Wall of the separation chamber is directed and a force which is directed towards its center. In other words, it will creates a difference between the forces exerted on the pulverized material, viewed radially to the separation chamber.

The invention therefore provides a Windsicht__ _- .A device, wherein the separation of fine particles from coarse partial

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Chen is effected by having a stream of air containing powdered material treated in the separation chamber is to be allowed to flow in vortex form to impart centrifugal forces to the pulverized material and then by pushing the pulverized material against the blades of the rotor, which is driven in rotation, bounces so that the coarse particles are scattered to the wall of the separation chamber, while the fine particles through an outlet opening in the upper middle area the separation chamber is formed, together with a stream of air that ventilates through there from the device to the outside will be promoted out.

The invention also provides a wind sifting device which bypassing the aforementioned disadvantages of the prior art technology is able to increase the selectivity with which the air separation is effected, and one large amount of pulverized material per unit cross-sectional area processed in the separation chamber.

The invention further provides an air separator which vigorously flows the air in the separation chamber in a vortex shape to increase the selectivity with which the wind sifting is effected and at the same time the amount of the pulverized material processed per area of the separation chamber.

The invention thus creates an air classifier in which an air stream enters a separation chamber through an inlet is inserted at its lower end and contains powdered material to be processed in the separation chamber, in vortex form is flowed to the pulverized

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Subject material to centrifugal forces. The device has a winged rotor against which the Powdered material is bounced as it rotates, causing coarse particles to hit the inner wall surface the separation chamber and separate them from other smaller diameter particles in the air stream. The air flow is then out of the separation chamber through an outlet opening in the center of an upper portion of the separation chamber passed out so that fine particles are carried by a centripetal air stream and from the device, after causing the coarse particles to separate from the fine particles, were discharged.

The invention is described below on the basis of preferred embodiments described in more detail with reference to the drawings. Show it:

Fig. 1 is a section of a preferred embodiment of the wind sifting device according to the invention;

Fig. 2 is a plan view of the wind icht rr device shown in Fig. 1;

Fig. 3 is a section showing part of the vane rotor of the device of Figs 2 shows;

. Fig. 4 is a right side view of the _ part shown in Fig 3 of the bladed rotor;

FIG. 5 shows a section on an enlarged scale of part of the separating chamber of the device from FIG. 1 and 2;

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Fig. 6 is a section of another preferred embodiment of the invention;

7 shows a section along the line VII-VII in FIG. 6;

Fig. 8 is a section of part of the separation chamber of Embodiment in Fig. 6; and

9 shows a section of yet another preferred embodiment according to the invention.

Fig. 1 is a cross-sectional view of an embodiment, and Fig. 2 is a plan view thereof. The wind sifting device has a housing 2 defining a separation chamber 1, a rotor 3 provided with blades, which around a vertical axis is rotatably mounted in the separation chamber, a deflection element 4 in the form of an upside-down cone, which is coaxially attached to the lower portion of the rotor provided with blades, a drive device 5 to the To drive rotation of the rotor provided with blades, an outlet opening 6 in a cover plate 2a of the housing is formed substantially coaxially with it, an inlet channel 7 for an air flow in the lower region the separation chamber 1 is arranged substantially coaxially to it, a shaft 8 for discharging coarse particles, the is connected to the lower region of the housing 2 in such a way that it is at a distance outside from the outer edge of the inlet channel 7 for the air flow is located, a plurality of air flow connection channels 9a-d, which at one End are connected to the outlet opening 6 and tangentially outward from it in the direction of rotation of the Rotor provided with blades extend, and a plurality

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of cyclones 10, each of which with the outer end one of the air flow connection ducts 9a-d is connected, on.

An air stream containing pulverized material to be processed is, as indicated by an arrow 11, introduced through the inlet duct for the air flow 7 and flows upwards in the separation chamber 1, in which the air flow, as indicated by arrows 12, is passed through the winged rotor to over the air flow connection channels 9a-9d to be conveyed to the cyclones 10. In the separation chamber, centrifugal forces, one Stray force and a force directed towards the center of the separation chamber 1 exerted on the pulverized material, such as will be described below, so that coarse particles differ from fine particles due to the size differences be separated in these forces. The separated coarse particles flow along the wall of the housing 2 below and are emptied from the device via channel 8. The fine particles by the coarse particles are separated are collected in the cyclones 10. Clean air from the cyclones 10 is drawn through an intake fan 14 withdrawn through outlet channels 13 and removed from the cyclones 10.

The separation chamber 1 has a cylindrical area 16 and an upside-down conical area 17, which are concentric are connected to each other. The outlet opening 6 has a smaller diameter than the cylindrical one Area 16 and is essentially concentric with it. An outlet channel 15 at its upper end is closed by an end plate 15a, is in the w

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arranged essentially concentrically to the outlet opening 6. The drive device 5 has a motor 18 which is fastened to the end plate 15a, an intermediate transmission 19, which is connected to the output shaft of the motor 18, and a drive shaft 20 which is connected to the output shaft of the intermediate gear 19 is connected and extends downward on. The drive shaft 20 extends through the end plate 15 into the middle area of the separating chamber 1.

FIG. 3 is a sectional view showing a part of the winged rotor 3, and FIG. 4 is a view of FIG to the right of the part of the rotor provided with vanes shown in FIG. 3. The winged rotor / points a mounting plate 21, which is arranged horizontally and at the lower end of the drive shaft 20 at right angles attached to it in the cylindrical area 16, a plurality of support parts 22, which are attached to the outer edge area of the Mounting plate 21 are attached and are circumferentially spaced from each other, and a A plurality of wings 23, each of which is supported by one of the support parts 22 with a perpendicular extension that is larger is as the transverse extension that is carried on. A plurality of threaded openings 24 are formed in the mounting plate 21 (four openings are shown), which are radially spaced from each other, around screws 25 for fastening of the support parts 22 to be taken up on the mounting plate 21. In each wing 23 there is a plurality of threaded openings 26 (six openings are shown) that are spaced apart from each other both perpendicularly and transversely are located and the threaded connections in itself screws 27 for attaching each wing 23 to one of the support

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parts 22 pick up. By suitable choice of the positions of the threaded openings 24, it is possible to change the fastening positions adjust the wing 23 radially to the mounting plate 21. By suitable choice of the positions of the threaded openings 26 it is possible to adjust the height of the wings in relation to the mounting plate 21.

As described above, the airflow connecting passages extend 9a-9d tangential to the peripheral wall of the outlet channel 15, the channels 9a-9d at intervals of 90 ° to each other in the direction of extension. This arrangement allows the force that the air in Vortex shape can flow, are evenly distributed with respect to the band of the outlet channel 15, and the generation of a Vortex flow is facilitated.

5 is a sectional view, on an enlarged scale, of a part of the separation chamber 1. A stream of air, the pulverized containing material to be treated flows up through the inlet channel 7 for the air flow into the Separation chamber 1, in which the flow cross-section of the air increased and the upward flow velocity is decreased as it gradually goes up through the upside down conical area 17 and the cylindrical Area 16 of the separation chamber 1 flows. In this way, coarse particles of relatively large dimensions fall in the air stream are contained by their own weight in the shaft 8. In addition, the upstream bounces Air flow in the cylindrical region 16 against the deflector 4 and the mounting plate 21 and its direction of flow is changed so that it is radially outward of the Mounting plate 21 flows. This causes coarse particles

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medium size contained in the air stream by inertial force against the deflection element 4 and the mounting _plate: collide, so that such particles suddenly come to a standstill by the obstacle and fall down by gravity. In this way, the coarse particles of a relatively large extent fall along the inner wall surface of the housing 2 and are drained out of the separation chamber 1 through the duct 8.

The air flow, the direction of flow of which has been changed in the cylindrical area 16 and which flows radially outwards to the mounting plate or separating chamber 1, changes its flow direction again in the upper area of the separating chamber 1 and flows through the blades 23 radially inward of the mounting plate 21 Particles of relatively small expansion by inertial force as a result of this sudden change in the flow direction against the wall of the separation chamber 1, so that they fall into the channel 8 along the inner wall surface of the housing 2. The air flow flows in a whirling flow through the outlet opening 6 into the outlet channel 15, from which it is guided tangentially outward into the air flow connecting channels 9a-9d. This causes the air in the separation chamber 1 to flow in a vortex shape, and at the same time, the rotation of the bladed rotor 3 also causes the air to flow in a vortex shape, so that the eddy currents thus generated become a violent vortex air flow in the separation chamber 1. As a result, centrifugal forces F ^, which are generated by such an eddy current, and a scattering force F ₂ , which is generated by the collision of the air with the blades 23, are exerted on the coarse particles in the air flow

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so that they become the inner wall surface of the housing 2 and fall into shaft 8. On the other hand is the sum of the centrifugal forces F. and the scattering force F- acting on fine particles, small as these the latter have a small mass, so that these particles are directed towards the center of the separation chamber Air flow are carried away, flow through the outlet duct 15 into the air flow connection ducts 9a-9d the cyclones 10 are promoted and collected therein.

If it is desired to change the forces acting on the pulverized material being processed, must

21 you just move the wings 23 radially to the mounting plate / and adjust their positions with the help of the screws 25. By changing the radial position of the vanes 23, the distance between the vanes 23 and the drive shaft 20 is changed and, as a result, the forces F 1 and F _{1 are changed.} With this change, a further change occurs in a force F ₃ which is directed towards the center of the separation chamber 1, whereby the selectivity with which the separation of the coarse particles from the fine particles is effected can be adjusted. It is also possible, through a suitable choice of the position of the threaded openings 26 in order to adjust the height of the wings 23, to change the distance a between the wings 23 and a lower end 15b of the outlet channel 15. This increases or decreases the amount of the pulverized material that flows directly to the discharge duct 15 without flowing through the vanes 23, whereby the processing of the pulverized material can be accomplished as desired.

As described above, according to the invention, an air

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stream containing pulverized material to be processed, introduced from below into a separation chamber and forcibly through the outlet opening, which is arranged in the upper region of the separation chamber, tangentially to the outside thereto pushed out. This causes a vortex flow to be formed in the separation chamber, and this vortex flow becomes with a vortex flow created by rotation of the bladed rotor into a violent one Vortex flow united. Combined with the clash of the powdered material with the winged one Rotor, the violent vortex flow exerts a force on the pulverized material that has hitherto been achieved with similar conventional ones Fixtures could not be reached. It is therefore possible to tell the difference between this force and the force of the air flow, which is directed towards the center of the separation chamber, and thereby the selectivity with which the processing of the pulverized material is effected to increase. The wings extend vertically, so that when the air stream containing the pulverized material hits the blades that pass through the blades created and exerted forces on the pulverized material in a substantially uniform radial manner to the separation chamber, whereby they contribute to the selectivity with which the treatment of the pulverized Material is caused to increase. This enables pulverized material of a high degree of concentration to process in the separation chamber, which makes it possible to have an overall compact size for the air classifier and to reduce the area on which the device is installed. A decrease the size of the wind sifting device makes it possible

to reduce the specific energy requirement. The direction of flow of the air flow entering the separation chamber 1

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through the inlet duct 7 for the air flow, which is arranged below the rotor 3 provided with blades, introduced is and flows up therein is also changed by the deflector 4 and goes radially to the separation chamber outward and thereafter, the air stream flows through the rotor 3 provided with blades and changes its direction again to flow inwardly into the separation chamber as previously described. The inlet channel 7 also has for the air flow a diameter which is smaller than the diameter of the cylindrical area 16 of the chamber 1, surrounding the rotor 3 provided with blades. In this way, the flow velocity of the air stream is reduced while it rises higher, thereby making it possible to separate the coarse from the fine particles.

FIG. 6 shows another embodiment in a sectional view, and this embodiment in plan view is similar to the first embodiment which was shown in FIG. 2. The wind sifting device has, wep. the first embodiment, a separation chamber 1 delimiting housing 2, a rotor provided with blades / which is rotatably supported in the separation chamber 1 about a vertical axis, a drive device 5 to drive the rotation of the rotor provided with blades 3, an inlet channel 7 for an air stream which is arranged in the lower region of the separation chamber 1 substantially coaxially with it, a swirl ^{device 4 1} , which is carried at the upper end of the inlet channel 7 for the air flow in the separation chamber 1, a shaft 8 to discharge coarse particles, which is connected to the lower portion of the housing 2 in a manner that it is arranged at a distance outside from the outer edge of the inlet duct 7 for an air flow, a plurality of air flow connecting channels 9a-9d, which with an outlet opening 6, which in a Cover plate 2a of the

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Housing 2 is formed substantially coaxially to it, are connected and tangentially to the outside in the Direction of rotation 30 of the rotor 3 provided with blades extend, and a plurality of cyclones 10, of which each is connected to the outer end 1 of one of the air flow connection channels 9a-9d.

In operation, a stream of air containing powdered material to be treated is directed in the direction of the arrow 11 passed through the inlet channel 7 for the air flow into the separation chamber 1 and flows upward therein. The airflow is by the swirler 4 'at the top End of the inlet channel 7 for the air flow caused in a whirling motion, which is in the same direction as the The direction of rotation 30 of the rotor 3 provided with blades is directed to flow while it is let into the separation chamber 1 will. In this way, the air stream flows through the rotor 3 provided with blades in the direction of the arrows 12, while it flows in a whirling motion in the separation chamber 1, and then becomes through the outlet opening 6 to it left tangentially outward in the air flow connection channels 9a-9d, from which the air flow to respective Cyclones 10 is performed. Centrifugal forces, a scattering force and one towards the center act in the separation chamber 1 the separation chamber 1 directed force on the pulverized material in the air stream, as to be described below so that the pulverized material is processed by the size differences between these forces. the separated coarse particles flow down along the inner wall surface of the housing 2 and are through the Shaft 8 drained. The fine particles in the air stream are collected in the cyclones 10, from which air, the does not contain powdered material by suction

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withdrawn with the help of the suction fan 14 and through the outlet channels / on the outside space is released.

The separating chamber 1 has a cylindrical region 16 and an upside-down conical area 17 which are concentrically connected to one another. The outlet opening 6 has has a smaller diameter than the cylindrical portion 16 and is substantially concentric therewith. A Outlet channel 15, which is closed at its upper end by an AbSchlußρlatte 15a, is essentially arranged concentrically to the outlet opening 6. The drive device / has a motor attached to the end plate 15a, a reduction gear 19 connected to the output shaft of the motor 18 is connected, and a Drive shaft 20, which is connected to the output shaft of the reduction gear 19 and extends downwards extends, on. The drive shaft 20 extends through the end plate 15a into the middle area of the separating chamber 1 .

The separation chamber 1 is similar in structure to that of the first embodiment shown in FIGS. 1 and 4 and its description is therefore omitted. The air flow connection channels 9a-9d are tangential to the cylindrical Wall of the outlet channel 15 connected and they are from each other at a distance of 90 ° in extension

direction. The force that strives to keep the air in us

to let the movement flow / in relation to the circumference of the outlet channel 15 evenly distributed in order to facilitate the generation of a vortex flow.

Fig. 7 is a sectional view taken along the line VII-VII

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6. The swirl device 4 ¹ has a lower support plate 31 of a horizontal ring shape, which is attached to the upper end of the inlet channel 7 for the air flow and extends radially outward from it, an upper support plate 32 of a horizontal ring shape, which is above the lower support plate 31 spaced therefrom, a plurality of guide plates 33 (eight plates are shown) extending perpendicularly between the lower and upper support plates 31 and 32 and spaced from each other with respect to the periphery of the plates 31 and 32, and a deflector 34, which is attached to the upper support plate in a manner that it closes the central opening on. The guide plates 33 are inclined radially with respect to the inlet duct 7 for the air flow in the direction of rotation 30 and form an air blow-off opening between adjacent guide parts 33. The deflector element 34 has a lower conical area 34a which tapers downwards and an "upper conical area 34b tapering upward, with the bottom portions of the two conical portions 34a and 34b fused in the body of the baffle 34. The upper conical portion 34b has an angle of inclination oC greater than the angle of repose of the pulverized material to avoid that the pulverized material is deposited on the upper conical portion 34b (see Fig. 6).

Fig. 8 is a sectional view, on an enlarged scale, of part of the separation chamber 1. The one through the inlet channel 7, air flow introduced for the air flow containing powdered material to be treated flows

so
up and bounces / against the deflector 34 that

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the direction of flow of the air flow is changed and the air flow flows radially to the inlet duct 7 for the air flow to the outside. In the swirler 4 ', the air flow is expelled through the blow-off openings 35 between the guide plates 33, and at this time the air flow is caused to flow in a whirling motion in the direction of rotation 30. In this way, the relatively large coarse particles contained in the air stream are forced against the inner wall surface of the housing 2 by centrifugal forces acting on them, and flow down the inner wall surface of the housing 2 into the channel 2, from which they are drained to the outside. The air flow flowing upwards in a whirling motion changes its flow direction in the upper region of the separation chamber 1 and flows through the blades 23 of the rotor 3 provided with blades. At this time, the air flow suddenly changes its flow direction so that the coarse particles "smaller in size are forced by inertial force against the inner wall surface of the housing 2 and flow along it down into the duct 8 to be discharged outside. The air flow becomes caused by the swirler 4 ¹ , as said, to flow in a swirling motion, and at the same time to flow in a vortex form when it flows up through the outlet opening 6 and the outlet channel 15 and into the air flow connection channels 9a-9d, the tangential are arranged to the outlet channel 15. A

even

Vortex flow becomes> äby the rotation of the winged Rotor 3 generated. In this way, a violent eddy current is generated in the separation chamber 1. As a result this is what the coarse particles in the air stream become

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centrifugal forces F generated by the eddy current and a stray force F generated by the collision of the air stream with the blades 23 and forced to flow against the wall surface of the separation chamber 1 in order to fall along the wall of the chamber 1 into the shaft 8. Meanwhile, the fine particles having no mass are _{subjected to centrifugal forces F 1} and the scattering force F "which are smaller than a centripetal force F", which is generated by and exerted on the air flow, so that the fine particles are subjected to a centripetal flow as it flows through the discharge duct 15 and the air flow connecting ducts 9a-9d to the cyclones 10 to be collected therein.

If the diameter of the fine particles to be separated from the coarse particles is to be changed, one need only move the blades 23 radially to the mounting plate 21 and select suitable positions for them. This arrangement changes the radial distance between the vanes 23 and the drive shaft 20. Meanwhile, the centripetal force generated by the air flow shows no substantial change, so that it is possible _{to obtain fine particles of a desired equilibrium particle size (a particle size resulting in F 1} + F "+ F ₃ = 0). By adjusting the height of the wings 23, the distance d between the outlet channel 15 and the wings 23 can also be changed. By making this adjustment, the amount of the pulverized material which flows directly to the discharge passage 15 without flowing through the blades 23 can be regulated so that the particle size of the fine particles can be adjusted

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- 24 can be adjusted to a desired degree.

Fig. 9 is a sectional view of still another embodiment in which parts similar to those shown in Figs. 1 to 7 are denoted by like reference numerals. In this embodiment, the mounting plate 21 of the bladed rotor 3 has a plurality of blades 37 of great transverse extent attached to the outer periphery of the plate and extending radially beyond the plate. By using this kind of vanes 37, the air flow which has been introduced into the separation chamber 1 through the inlet duct / for air flow and flows upward therein while being caused to flow in a whirling motion ^{by the swirler 4 1 can be made to flow} to flow through the blades 37, as indicated by arrows, and through the outlet opening 6 and the air flow connecting channels 9a-9d to the cyclones 10. In this embodiment, the distance d between the blades 37 and the outlet duct 15 is relatively large, and the air stream containing pulverized material to be processed flows directly between the blades 37 and the housing 2 without being influenced by the presence of the blades 37, so that coarse particles of relatively small size can be fed to the cyclones 10. This embodiment can be used in applications where the requirements for selectivity are not as strict as in the embodiments from FIGS. 1 to 7.

The embodiments shown in FIGS. 6 to 9 can, with the omission of the upper conical region 34b of FIG

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upper support plate 32 of the deflector 34 modified will.

Experiments were carried out using the wind sifting devices shown in FIGS. 1 to 8 on the selectivity of particles in the embodiment in which the air flow is guided directly through the inlet duct 7 for the air flow into the separation chamber 1 and in the embodiment , in which the swirl device 4 'is attached in the flow path of the air flow from the channel 7, carried out. The particles collected in the cyclones 10 of the two embodiments were sieved using a sieve with mesh openings of 88 µ. The results show that the coarse particles which did not pass the sieve were 13% in the embodiment without the swirler 4 'and 8% in the embodiment with the swirler 4 ¹ . From the results of the experiments it can be seen that the fact that the swirling device 4 'is provided to give the air stream flowing in the separation chamber 1 a greater swirling force, it is possible to increase the selectivity or the proportion of coarse particles in the air stream exits from the separation chamber 1 to reduce.

From the foregoing it is clear that in the wind sifting device according to the invention, the air flow passing through the inlet duct for the air flow is introduced into the separation chamber, is provided with a swirling force, especially if the swirl device is provided, which is in the same direction as the direction of rotation of the winged rotor is directed. A we-

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belstrom generated by this swirling force is, a vortex flow generated by the rotation of the bladed rotor, and a Vortex flow caused by the forced exit of the air flow through the outlet opening tangential to it is generated in the upper area of the separation chamber, combine into a single violent vortex flow in the separation chamber. Due to the effect of this violent vortex flow, the pulverized material becomes centrifugal forces in the air flow subjected to greater than the centrifugal forces previously used in similar conventional Devices were created. In this way, the size differences between the centrifugal forces that act on the air flow, a scattering force created by the collision of the air flow with the winged equipped rotor and a centripetal force of the air flow are increased, thereby the selectivity to increase. This allows an overall compact size to be obtained in an air separator, allows the area on which the device is installed to be reduced and enables the drive means has a reduced specific energy requirement.

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Claims (7)

Claims 1y wind sifting device, marked through a housing (2) which has a separation chamber (1) vertical axis limited; a rotor (3) provided with blades, which is mounted in the separating chamber (1), the rotor (3) being a horizontal one Mounting plate (21) which is rotatable about the vertical axis, and a plurality of wings (23) with large vertical extension, which is attached to an outer edge region of the horizontal mounting plate (21) and are located on the circumference at a distance from one another, has; a drive device (5) to drive the winged To drive the rotor (3) to rotate about the vertical axis; an inlet channel (7) for an air flow, which at a The lower end of the separation chamber (1) is connected essentially coaxially with it, the inlet channel (7) for the Air flow has a smaller diameter than an area (16) of the separation chamber (1), which is provided with wings Surrounds the rotor (3) and its upper end is located below the rotor (3) provided with blades; a shaft (8) which is connected to a lower end of the housing (2) and extends at a distance to the outside) * from the outer edge of the inlet duct (7) for the air flow to discharge coarse particles from the separation chamber (1); an outlet opening (6) which is in an upper region of the Housing (2) is formed essentially concentrically with the separation chamber (1), the outlet opening a - 3 - 030064/0852
ORIGINAL INSPECTED has a smaller diameter than the upper portion (16) of the housing; a plurality of air flow connection channels (9a-d) which connect to the outlet opening (6) and extending tangentially outward therefrom in the same direction (30) as the rotation of the winged one Extend rotor (3); and a plurality of pulverized material collectors (10) each attached to one end of one of the Air flow connection channels (9a-d) is connected. 2. Air view .. device according to claim 1, characterized in that that the rotor (3) provided with blades is provided with devices (22, 24, 25/22, 26, 27), which allow the positions of the wings (23) on the mounting plate (21) to be changed radially to the mounting plate and / or adjust the height of the wings (23) on the mounting plate (21). 3. Wind sifting device according to claim 1 or 2, characterized by a deflecting element (4) in the form of an upside-down one Cone that is coaxial on a lower region of the mounting plate (21) of the rotor (3) provided with blades is attached to it. 4. Wind sifting device, characterized by a housing (2) defining a separation chamber (1) with a vertical axis; a vane rotor mounted in the separation chamber (1), the vane one Rotor (3) a horizontal mounting plate (21) which is rotatable about the vertical axis, and a plurality of blades (23, 37), which at an outer edge area of the horizontal 030064/0852 . 3 · right mounting plate (21) are fixed and are circumferentially spaced from one another, has; drive means (5) for driving the vane rotor (3) to rotate about the vertical axis; an inlet duct (7) for an air flow which is substantially coaxial at a lower end of the separation chamber (1) is connected to it, wherein the inlet channel (7) for the air flow has a smaller diameter than a Area (16) of the separation chamber (1) which surrounds the rotor (3) provided with blades, and its upper end below the rotor (3) provided with blades is arranged; a swirler (4 ') # which essentially horizontal upper (32) and lower (31) support plates at the upper end of the inlet channel (7) for an air flow are mounted perpendicular to each other at a distance, and a plurality of guide plates (33) between the upper and the lower support plate are arranged and are circumferentially equidistant from each other, comprises, wherein the guide plates (33) in a direction radially outwards towards the inlet duct (7) for an air flow are inclined in the direction of rotation (30) of the rotor (3) provided with blades; and a plurality of air vent openings (35), each of which by adjacent guide plates (33) and the upper (32) and lower (31) Support plate is limited to a connection between the interior of the inlet channel (7) for an air flow and the Maintain the interior of the separation chamber (1); a shaft (8) connected to a lower end of the housing (2) is connected and is at a distance to the outside from the outer edge of the inlet duct (7) for the air flow, to discharge coarse particles from the separation chamber (1); 030064/0852 an outlet opening (6) which is in an upper region of the Housing (2) is formed essentially concentrically with the separation chamber (1), the outlet opening a has a smaller diameter than the upper region (16) of the housing (2); a plurality of air flow connection channels (9a-d) which connect to the outlet opening (6) and extending tangentially outward therefrom in the same direction (30) as the rotation of the winged one Extend rotor (3); and a plurality of cyclones (10) each of which is connected to one end of one of the air flow communication channels (9a-d) is. 5. Wind visibility. device according to claim 4, characterized in that that the blades (23) of the rotor (3) provided with blades have a large vertical extension, and that the rotor (3) provided with blades is provided with devices (22, 24, 25/22, 26, 27) which allow to change the position of the wings (23) on the mounting plate (21) radially to the mounting plate and / or adjust the height of the wings (23) on the mounting plate (21). 6. Windsicht_jrorrichtung according to claim 4, characterized that the wings (37) of the rotor provided with wings each have a large transverse extension and extend radially outward from the mounting plate (21). 7. Wind sifting device according to one of claims 4 to 6, characterized in that the turbulence Q3Q064 / 0852 direction (4 ') is provided with a deflection element (34), which is attached to a lower portion of the upper support plate (32), and wherein the deflector (34) is conical Has shape (34a, 34b) and tapers downwards and concentric to the inlet duct (7) for the air flow is. 030064/0852