DE9017176U1 - Wind sifter - Google Patents

Description

Wind sifter

The innovation relates to an air classifier for classifying dusty bulk materials, in particular lime, ground clinker, quartz powder, cement raw material or the like, with a housing, at least one material feed device, at least one finished product discharge device, a fixed blade ring provided inside the housing in its outer area and a rotor arranged concentrically within the blade ring so as to be able to rotate, including guide blades with a substantially cylindrical cross-section, wherein classifying air can be fed to the blade ring through at least one air inlet nozzle running tangentially on the housing.

DE-PS 35 45 691 discloses a device for classifying dusty bulk materials, in particular ground clinker, limestone or cement raw material by air sifting, whereby the material to be classified is fed via a material inlet to the cover plate of a cylindrical rotor with vertical rotor blades and is fed into a ring-cylindrical sifting chamber that extends between the rotor and a fixed blade ring surrounding it at a distance, through which sifting air is sucked in approximately tangentially by an external fan. Fine material is transported radially inwards due to the flow conditions within the sifter and discharged through a central discharge pipe, while coarse material is removed from the sifter by means of a discharge pipe provided in the outer peripheral area.

DE-AS 25 56 382 discloses a centrifugal air classifier with an essentially cylindrical classifying chamber, into which the classifying air and the material to be classified are introduced with a twist at the outer circumference, whereby the coarse material is removed at the outer circumference of the classifying chamber, and the classifying air together with the fine material is discharged through a central, stationary suction pipe covering the axial extent of the classifying chamber, whereby the suction pipe has inlet openings distributed around its circumference.

Furthermore, US-PS 1,746,686 discloses an air classifier which has a housing in which two classifying devices are arranged axially one above the other, by means of which a total of three fractions can be produced, which are discharged in the area of the housing bottom. As a result,

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Due to the superimposed viewing devices, the housing is relatively high axially, and the overall structure of the device is also to be regarded as complex.

Furthermore, DE-OS 35 21 638 describes a scattering air classifier, in particular for classifying cement, which includes a material feed, a spreading plate with drive that distributes the material flow to a material curtain, a classifying wheel, a classifying air supply opening and a coarse material and a fine material discharge. The material flow feed and the fine material discharge are arranged in the classifier axis and a conveyor trough is provided in a ring around the fine material discharge for the coarse material discharge, whereby the material curtain through which the classifying air flows is designed as a bell-shaped outer surface.

In the sifting gap of these wind sifters, also known as cross-flow sifters (sifting air is supplied laterally or tangentially), there are uneven flow speeds in a tangential direction. This leads to turbulence on the sifter rotor, which can lead to insufficient sifting. Another disadvantage is that this type of wind sifter only has the option of dividing the feed material into two sifting streams, namely the coarse material and the fine material portion.

However, in some applications, e.g. in the cement industry, it may be advantageous to divide the feed material into three or more material streams with different grain size distributions.

The aim of the innovation is to further develop an air classifier, as described for example in DE-PS 35 45 691, so that the feed material can be divided into at least three material streams with different grain size distributions with optimized classifying efficiency, without significantly changing the classifying concept, although it can certainly be useful to combine two or more material streams again after the classifying process.

This objective is achieved in accordance with the innovation by the rotor containing at least two concentrically arranged rotor blade rings including guide vanes, that below the rotor blade rings or the

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Guide vanes, several independent finished product discharge devices are provided, and that the grits are brought together outside the finished product discharge devices and can be discharged through a grit discharge device.

Advantageous further developments of the subject matter of the innovation can be found in the subclaims.

When using two rotor blade rings, the finished product discharge device is divided into a first and a second finished product discharge, which are separated from each other on the one hand and from the semolina discharge on the other hand by labyrinths, whereby the first finished product discharge can be operated optionally with or without air flow.

The finished product can be discharged either downwards, upwards or, depending on the application, both upwards (air flow) and downwards. The selection depends on the bulk material to be classified. The same applies to the selection and arrangement of the guide vanes. These can be straight or slightly curved and have different radial lengths. Alternatively or additionally, round rods can also be used as guide elements. Depending on the material, it may also be useful to make the guide vanes at least partially radially long enough to connect at least two rotor blade rings. However, this requirement only makes sense for rotor blade rings that are firmly connected to one another.

When grinding, for example, cement, the subject matter of the application can result in the following advantages:

- the feed material is divided into product fines and coarses, whereby the coarses can be fed to the clinker pre-crushing and the fines to a ball mill,

- the feed material can be divided into PZ 45, PZ 35 and semolina.

In addition, the subject matter of the invention has the following advantages over the standard:

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- depending on the design of the separator and the operating mode, the user has the choice between several separating gap thicknesses and diameters, whereby the user has more flexibility in the separating grain size,

- the flow conditions in the viewing gap between the two rotor blade rings are more uniform than in the radially outer viewing gap, which allows the user to achieve an improved separation effect,

- it is possible to obtain at least three solid material streams with different grain size distribution in one operation,

- the proportion of sprayed grain between the coarse grit discharge and the second finished product discharge can be significantly reduced.

If the finished product discharge devices are each operated with one air flow, a so-called "dead flow" will occur in the separation curve, corresponding to the ratio of the air flow rates at the second finished product discharge to that at the first finished product discharge. The normally disadvantageous "dead flow" can be advantageous if, for example, PZ 45 and PZ 35 are to be produced at the same time. The "dead flow" means that a high proportion of fines remains in the PZ 35, which can contribute to a tolerable water requirement of the PZ 35.

The innovation is shown using an example in the drawing and is described as follows. Shown are:

Figure 1 - Longitudinal section through the new wind sifter Figure 2 - Top view of Figure 1 in cross section.

Figure 3 - Wind sifter with two independently driven rotor blades as a schematic diagram

Figures 4 and 5 - Wind sifter with two rotor blades and

between these extending guide vanes

Figure 6 - Wind sifter with an upper and a lower Finished goods discharge device

Figures 7 and 8 - Wind sifter with guide vanes of different lengths PAT6097AT

Figures 9 and 10 - Wind sifter with additional guide elements designed as round rods

Figures 1 and 2 show the new wind sifter 1 in longitudinal section and in cross section. The following components are shown:

a housing 2, an upper material feed device 3 in the form of a pipe, two air inlet nozzles 4,5 running tangentially on the housing 2, a first finished product discharge device 6, a second finished product discharge device 7 and a grit discharge device 8. In this example, two radially outer blade rings 9,10 arranged axially one above the other are provided within the housing 2. A rotor shaft 11 is arranged concentrically within these blade rings 9,10, which is guided in bearings 12,13 in the area of its two ends. The drive for the rotor shaft 11 is only indicated here by the direction of the arrow. Rigidly connected to the rotor shaft 11 are two axially superimposed rotor blade rings 14,15 and 16,17, including guide vanes 14',15' and 16',17', which are provided in a similar way to the axially superimposed blade rings 9,10. In this example, the rotor blade rings 14,15 and 16,17 are firmly connected to the rotor shaft 11 via radial webs 18,19,20. In order to reduce the amount of sprayed grain between the grit discharge 8 and the finished product discharge devices 6,7, labyrinths 21,22 are provided in the lower area of the rotor blade rings 16,17.

The functionality of the new wind sifter 1 is roughly as follows:

The material to be classified first reaches the cover plate 23 of the rotating rotor blade rings 14, 15 and 16, 17 and is thereby thrown outwards in a radial direction so that it enters from above into the ring-cylindrical screening spaces 24, 25, which are formed on the one hand between the rotor blade rings 14, 15 and 16, 17 and on the other hand between the rotor blade ring 15 and 17 and the blade ring 9 and 10. In these screening spaces 24, 25, the material to be classified is exposed to a suction effect, which results from the difference between the air speed of the air supplied by the stationary blade rings 9 and 10.

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classifying air and the air conveyed outwards by the rotor blade rings 14,15 and 16,17 due to the rotation. Since the air speed of the classifying air supplied to the blade ring 9,10 via the air inlet nozzles 4,5 is greater than the speed of the air moved by the rotor blade rings 14,15 and 16,17 due to the rotor rotation, an overall air flow results on the entire circumference of the outer blade rings 9 and 10, transverse to the ring-cylindrical classifying spaces 24,25 and through the rotor blade rings 14,15 and 16,17 into the interior 26 of the housing 2.

This movement of the sifting air takes, depending on its speed, a portion of the material falling down in the sifting chambers 24, 25 into the sifting chamber 24 on the one hand and into the interior 26 on the other. The sifted material thus forms the fine material fractions, which depend on the air speed and rotor speed set in each case. The material not sifted into the area of the sifting gap 24 or the interior 26 falls down as coarse material and reaches the lower part 27, from which it is discharged by the grit discharge device 8, for example with the aid of an air conveyor trough (not shown in more detail). The fine material portion, which is formed in the area of the screening space 24 between the rotor blade rings 14, 15 and 16, 17, reaches the ring-cylindrical upper part 28 of the finished material discharge device 6, while the other fine material portion is collected in the interior 26 of the housing 2 and fed to the finished material discharge device 6 via a cylinder 29. The finished material discharge devices 6, 7 are connected to the cylindrical sections 28, 29 and taper in a funnel shape, being arranged concentrically to one another. The finished material discharge device 6 runs into the discharge pipe 30 and the finished material discharge device 7 runs out into the discharge pipe 31, from where the materials are fed to their further destinations.

Figure 3 shows an alternative air classifier 32, which also includes two rotor blade rings 33,34, which are arranged concentrically to the radially outer blade rings 9. In contrast to Figures 1 and 2, the rotor blade rings 33,34 including guide vanes 33',34' are not connected to one another but can be driven separately. The rotor blade ring 33 is connected on the one hand to a hollow shaft 35 and in

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its lower area 37. The rotor blade ring 34 is firmly connected to a drive shaft 36 (not shown) guided inside the hollow shaft 35 and mounted at the top and bottom. Both rotor blade rings 33, 34 can thus be driven at different speeds using drives not shown in more detail in order to achieve an optimal viewing effect tailored to different materials in each case. The finished product discharge devices 6, 7 are designed analogously to Figure 1 and run into the discharge pipes 30 and 31 respectively.

Figures 4 and 5 show a wind sifter 38, which in terms of its basic structure corresponds to the wind sifter shown in Figure 1. The main differences to the wind sifter according to Figure 1 are that the rotor blade rings 39, 40 are radially relatively thin, with the guide blades 41 being radially long enough to connect both rotor blade rings 39, 40 to one another. The finished product discharge devices 6, 7, which open into the discharge pipes 30, 31, are provided in a similar way to those in Figure 1, so that despite the arrangement of the rotor blade rings 39, 40 in relation to the guide blades 41, it is possible to produce two fine fractions of different grain sizes here too.

Figure 6 shows another alternative design of a wind sifter 42. The wind sifter 42 is constructed in the same way as that shown in Figure 1. The differences are that the finished product discharge devices 43, 44 are arranged in such a way that part of the air-material mixture flowing radially inwards between the rotor blade rings 45, 46 reaches the finished product discharge device 43 and thus the discharge pipe 47 arranged underneath, and the remaining part of the air-material mixture is conveyed upwards into the finished product discharge device 44 as a result of a negative pressure generated in the inner area 48 of the wind sifter 42 and is drawn off there via a pipe 49. The grits are discharged via a discharge pipe 8 as shown in Figure 1.

The wind sifter 50 shown in Figures 7 and 8 corresponds in terms of its structure to the wind sifter described in Figure 4. Here too, the rotor blade rings 39, 40 are radially relatively narrow, whereby, as can be seen in particular from Figure 8, on the one hand, guide vanes

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fine 41 are provided, which connect the two rotor blade rings 39,40 to one another, and on the other hand guide vanes 41' are provided, which are radially shorter and are only connected to the rotor blade ring 40. Alternatively, it is also possible to connect the guide vanes 41 to the inner rotor blade ring 39 or to provide an alternating design.

Figures 9 and 10 show another air classifier 51, which in turn corresponds to the structure of the air classifier shown in Figure 4. The differences to Figure 4 are due to the fact that in addition to the guide vanes 41 between the rotor blade rings 39,40, on the one hand round bars 52 are provided in the area of the rotor blade ring 40 and on the other hand round bars 53 in the area of the rotor blade ring 39, whereby the round bars 52,53 serve as additional guide devices for the material flowing radially from the outside to the inside.

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Claims (14)

Protection claims 1. Air classifier for classifying dusty bulk materials, in particular lime, ground clinker, quartz powder, cement raw material or the like, with a housing, at least one material feed device, at least one finished product discharge device, a fixed blade ring provided inside the housing in its outer area and a rotor arranged concentrically within the blade ring so as to be able to rotate including guide blades with a substantially cylindrical cross-section, wherein classifying air can be fed to the blade ring through at least one air inlet nozzle running tangentially on the housing, characterized in that the rotor has at least two rotor blade rings (14, 15 or 16, 17, 33, 34, 39, 40, 45, 46) arranged concentrically to one another including guide blades (14', 15' or 16',17',33',34',41,41',52,53) includes that several independent finished grit discharge devices (6,7,43,44) are provided below the rotor blade rings (14,15 or 16,17,33,34,39,40,45,46) or the guide vanes (14',15' or 16',17',33',34',41,41',52,53) and that the grit is brought together outside the finished material discharge devices (6,7,43,44) and can be removed by a grit discharge device (8). 2. Air classifier according to claim 1, characterized in that the rotor blade rings (14, 15 or 16, 17, 39, 40, 45, 46) are rigidly connected to one another. 3. Air sifter according to claim 1, characterized in that the rotor blade rings (33, 34) can be driven independently of one another, in particular at different speeds. 4. Air sifter according to claims 1 and 2, characterized in that the guide vanes (41) of the individual rotor blade rings (39, 40) are at least partially radially wide enough that at least two rotor blade rings (39, 40) can be connected to one another, with at least two finished product discharge devices (6, 7) being provided axially below the guide vanes (41). PAT6097AP -Z- 5. Air classifier according to claims 1 to 4, characterized in that the guide vanes (41, 41') of the rotor vane rings (39, 40) are radially different in width. 6. Air sifter according to claims 1 to 4, characterized by further guide elements (52, 53) in the region of the rotor blade rings (39, 40) in the form of round rods. 7. Air sifter according to claims 1 to 6, characterized in that the finished product discharge devices (6, 7) are separated by labyrinths (21, 22) on the one hand from each other and on the other hand from the semolina discharge device (8). 8. Air sifter according to claims 1 to 7, characterized in that when using two rotor blade rings (14, 15 or 16, 17, 33, 34, 39, 40, 45, 46) one of the finished product discharge devices (7, 43) can be operated continuously and the other (6, 43) can be operated optionally with or without air flow. 9. Air sifter according to claims 1 to 8, characterized in that at least one finished product discharge device (44) is provided in the upper housing area of the air sifter (42), whereby a part of the finished product and possibly also the fines are discharged upwards in the air stream. 10. Air sifter according to claims 1 to 9, characterized in that the inlet (29) into the first finished product discharge device (6) is cylindrical and is arranged below the rotor blade ring (14 or 16). 11. Air sifter according to claim 10, characterized in that the first finished product discharge device (6) is designed to taper in a funnel shape and runs into a discharge pipe (30). PAT6097AP 12. Air sifter according to claims 1 to 11, characterized in that the inlet (28) into the second finished product discharge device (7) is designed as a ring cylinder and is arranged below the rotor blade rings (14, 15 or 16, 17). 13. Air sifter according to claim 12, characterized in that the second finished product discharge device (7), tapering in a funnel shape, concentrically surrounds the first finished product discharge device (6). 14. Air sifter according to claims 12 and 13, characterized in that the tapering region of the second finished product discharge device (7) runs into a discharge pipe (31). PAT6097AP