DE3741650C1 - Apparatus for classifying dust-like bulk materials - Google Patents

Abstract

The invention relates to a method for classifying dust-like bulk materials, in particular ground clinker, limestone or cement raw material and materials of related type of the chemical and food industries, by classification by air. The material to be classified is fed to the centrifugal plate (13) of a cylindrical rotor (11) and fed to a classifying space (18) in the form of an annular cylinder, which extends between the rotor (11) and a stationary blade ring comprising guide blades (21), which surrounds the rotor (11) at a distance. While the coarse material sinks downwards in the classifying space (18), the fine material is conveyed into the interior of the rotor (11), drawn off at the top and fed to cyclone separators (6) connected downstream for separation of fine material and classifying air. In order to prevent the occurrence of spray material in the fine material, the rotor (11) is designed so as to have an at least partially open bottom (15), and a discharge plate (16) for the spray material occurring in the interior of the rotor is arranged below the rotor bottom. <IMAGE>

Description

The invention relates to a device for classifying dusty bulk goods, especially of ground Clinker, limestone or cement raw material and related Chemical and food industry materials Air classification, the material to be classified over a Material inlet of the cover plate of a cylindrical rotor fed with vertical rotor blades and one ring-cylindrical viewing space is given up, which is between between the rotor and a surrounding area fixed blade ring extends through the of minde At least one outside fan, for example is promoted tangentially in the viewing space, so that in the abandoned Material contained fines due to the difference between the air speed of the sucked in by the fan and radially by the rotor externally pumped air into the interior of the rotor promotes and by a Fein arranged above the rotor good discharge discharged vertically upwards and the coarse material in the viewing space sinks down and discharged via a coarse material discharge becomes.

With classifying devices of the type described above gets inside the rotor under certain circumstances not only fine material taken away from the visible air, but also so-called spray grain, d. H. a grain fraction that is finer than the selected coarse material, but coarser than the ge wished fines. This spray grain occurs in particular when high fineness of the finished goods (fine goods) ver be obtained, such as for special cements, Kalkpro products for plastering and the like.  

In the known classifying devices, such a Spray material discharge cannot be prevented with the fine material, because the spray grain ver a certain time inside the rotor remains, accumulates there and at least partially with the Fines are carried upwards because there is no possibility for the spray grain after entering the rotor inside this rotor again differently than over the fine leave good discharge.

The invention has for its object the known Classifying device of the type described above to further develop that with little design effort too a finished product with particularly high fineness can be produced can, which is also free of spray grain.

The solution to this problem by the invention is characterized in that the rotor with at least one partially open floor and that below the A discharge plate for the inside of the rotor falling spray grain is arranged.

With this further development of the known Classifying device creates the possibility that especially with high fineness of the finished goods in the rotor inside spraying grain the rotor over the at least can leave partially open ground. Especially in the central area of this floor is low Flow velocity of the sifting air, so that inside of the rotor penetrated spray grain at this point due to gravity falls down and in this way emerges from the rotor. This spray grain gets onto the discharge plate arranged below the rotor base, the due to its centrifugal effect the spray grain radially after hurled outside. The spray grain gets in this way  the current of the sinking downward in the cylindrical visual space Coarse good and with this - if necessary, to another Zer reduction process - dissipated.

With the invention is thus very little constructive Effort and without additional space or additional energy the costs of using the further developed classifying device device for the production of fine goods with particularly high fineness possible without the risk that spray grain in too casual amount occurs in the fines.

According to a further feature of the invention, the one below discharge plate with guide plates arranged on the rotor base Raising of the fine grain sprayed grain into the rotor be provided inside. This way it will be fine contaminated spray grain before it is finally on the discharge plate reached, returned to the rotor by lifting and subjected to an indulgence here. The unwanted end separation of fine material together with the spray grain is on prevented this way.

To the overall height of the classifying device according to the invention may decrease according to another feature of the invention the ring-shaped space in the lower part surrounding the discharge plate part of the housing via an annular, vented discharge route to be connected to the coarse material discharge nozzle. Alternatively, this space in the lower part of the housing can also be used a discharge cone connected to the coarse material discharge pipe will.

In the drawing is an embodiment of the Invention shown according to the classifying device, namely

Fig. 1 is a schematic representation of the classifying apparatus provided in section illustrates, including a lying outside the fan and a plurality of cyclone separator

Fig. 2 is a vertical section through the actual classifying besides cyclone separators,

Fig. 3 is a plan view of Fig. 2,

Fig. 4 is an enlarged partial section through the rotor,

Fig. 5 is a horizontal section along the section line VV in Fig. 4 and

Fig. 6 a of Fig. 2 corresponding section through the actual classifier with an age-native formation of the coarse material discharge.

The overall presentation in Fig. 1 shows a Klassiervorrich device 1, which is the material to be classified, direction by a Zerkleinerungsvor coming dust-like bulk material is supplied by a transport device 2. In the illustrated embodiment, this is an air trough with two outlet ports 2 a , which lead the bulk material through two material inlet pipes 3 of the classifying device 1 . The visual air for the classifying device 1 is generated in the exemplary embodiment by an external fan 4 , which operates in recirculation mode. For this purpose, the suction line 5 of the fan 4 is connected to immersion tubes 6 a of several cyclone separators 6 . These cyclone separators 6 , the fine air loaded visual air is fed via tangentially opening air lines 7 , which in turn are connected to the fine material discharge opening at the top of the classifying device 1 . The pressure side of the fan 4 is connected via one or more pressure lines 8 approximately tangentially to the housing of the classifying device 1 . The actual classification device 1 is driven by a motor 9 .

The structure of the classifying device 1 best results from FIGS. 2 to 5. These representations show that the motor 9 drives a vertical rotor shaft 10 , which is composed of two sections and on which a two-part rotor 11 is fastened. This rotor 11 has at the top an annular spinner 13 connected to the rotor shaft 10 via spokes 12 , to which the visible material is fed through the material inlet pipes 3 . Each section of the rotor 11 comprises an annular ring of rotor blades 14 . The bottom end of the rotor 11 is formed by an at least partially open bottom 15 . A discharge plate 16 , which rotates with the rotor 11 , is arranged below the base 15 .

The rotor 11 is surrounded at a distance by fixed guide vanes 17 , so that a visible space 18 is formed, which has the shape of a cylinder with an annular cross section. In this ring-cylindrical classifier chamber 18 supplied from the spreader disk 13 material to be separated passes. The separation of the material fed through the material inlet pipes 3 into fine and coarse material takes place as follows:

The material to be classified first reaches the centrifugal plate 13 of the rotatably driven rotor 11 and is thereby centrifuged outwards in the radial direction, so that it enters the ring-cylindrical viewing space 18 from above. In this viewing space 18 , the material to be classified is subjected to a suction effect, which results from the difference between the air speed of the viewing air supplied through the fixed guide vanes 17 and the air conveyed outwards by the rotor blades 14 due to the rotation. Since the air speed of the visible air supplied to the blade ring from guide blades 17 via the pressure line 8 is greater than the speed of the air moved by the rotor rotation from the rotor blades 14 , there is an overall air flow across the entire circumference of the blade rings consisting of guide blades 17 transversely to the ring-cylindrical visible space 18 and through the ring of rotor blades 14 into the interior of the two-part rotor 11 .

This movement of the classifying air takes a portion of the falling material in the classroom 18 down into the interior of the rotor 11 according to its speed. This entrained material forms the fine material component, which depends on the air speed set in each case. The material that is not taken into the interior of the rotor 11 falls down as coarse material through the viewing space 18 and reaches a lower housing part 19 , from which it is fed to a coarse material discharge pipe 20 .

The loaded with fine material separating air is inside the rotor 11 moves upward and passes over the existing within the ring-shaped spin plate 13 opening in the top side of the rotor 11 and a stationary guide vane ring 21 which lead to the cyclone separators 6 air lines. 7 Due to the tangential supply of the fine-laden sighting air to the cyclone separators 6 , there is a rotating air movement in the cyclone separators 6 , which leads to the fine material falling on the walls of the cyclone separator 6 , whereas the clearing-air freed from the fine matter falls over the immersion tubes 6 a the suction line 5 of the fan 4 arrives. The fines separated in the cyclone separator 6 are drawn off at the lower end through a fume discharge pipe 22 .

Particularly when high fineness of the finished goods (fine goods) are required, it cannot be avoided that with the fineness of a given fineness a grain fraction from the viewing space 18 enters the interior of the rotor 11 , which is finer than the coarse material selected, but larger than the desired fines. This grain fraction, which is referred to as spray grain, occurs increasingly in the case of fines separation in the higher Blaine range, ie in a range between 4500 and approximately 10,000 Blaine.

Because of the higher weight of this spray grain compared to the fine grain, this grain fraction collects in the lower part of the rotor 11 . Since in this lower part the flow speed of the sifting air is the lowest, a large part of the spray grain falls downwards and through the at least partially open bottom 15 onto the discharge plate 16 . This discharge plate 16 throws the spray grain into the stream of coarse material falling down from the viewing space 18 . In this way, the fine material drawn upwards from the inside of the rotor 11 is freed from the spray grain.

If the discharge plate 16 according to FIGS . 4 and 5 is provided with guide plates 24 , it can be achieved that the with fine material spray grain is raised before it is discharged through the discharge plate 16 into the interior of the rotor, where it is subjected to an indulgence. This prevents fine from getting into the coarse material discharge in an undesirable manner.

In the embodiment shown in the drawing, the discharge plate 16 surrounding the annular space of the lower housing part 19 via a likewise annular, vented discharge path 23 with the coarse material discharge tube 20 is connected. The use of such a vented discharge section 23 reduces the overall height of the classifying device 1 compared to a conventional funnel-shaped, coarse discharge. In Fig. 6 it is indicated with thin lines that, alternatively, the annular space of the lower housing part 19 can also be connected to the coarse material discharge pipe 20 via a discharge cone 25 if the lowest possible overall height is not important.

• Reference number list 1 classifier
  2 transport device
  2 a outlet connection
  3 material inlet pipe
  4 fan
  5 suction pipe
  6 cyclone separators
  6 a dip tube
  7 air line
  8 pressure line
  9 engine
  10 rotor shaft
  11 rotor
  12 spoke
  13 spin plates
  14 rotor blade
  15 floor
  16 discharge plates
  17 guide vane
  18 viewing space
  19 lower housing part
  20 coarse material discharge pipe
  21 wreath
  22 fine material discharge pipe
  23 discharge path
  24 baffle
  25 discharge cone

Claims (4)

1.Device for classifying dusty bulk materials, in particular of ground clinker, limestone or cement raw material and related materials of the chemical and food industry, by air sifting, the material to be classified being fed via a material inlet to the cover plate of a cylindrical rotor with vertical rotor blades and one ring-cylindrical viewing space is given, which extends between the rotor and a surrounding this, the fixed blade ring, through which at least one fan located outside air is conveyed approximately tangentially into the viewing space, so that the fine material contained in the material due to the difference conveyed into the interior of the rotor between the air speed of the air sucked in by the fan and the air conveyed radially outwards by the rotor and discharged vertically upwards by a fine material discharge arranged above the rotor, and the coarse material sinks downward in the viewing space and is discharged via a coarse material discharge, characterized in that the rotor ( 11 ) is designed with an at least partially open base ( 15 ) and in that a discharge plate ( 16 ) below the rotor base ( 15 ) is arranged for the spray grain occurring in the interior of the rotor. 2. Apparatus according to claim 1, characterized in that the discharge plate ( 16 ) is provided with guide plates ( 24 ) for raising the fine grain sprayed grain in the rotor interior. 3. Apparatus according to claim 1 or 2, characterized in that the discharge plate ( 16 ) surrounding, ring-shaped space in the lower housing part ( 19 ) via a ring-shaped, vented discharge path ( 23 ) with the Grobgutaus support tube ( 20 ) is connected. 4. Apparatus according to claim 1 or 2, characterized in that the discharge plate ( 16 ) surrounding, annular space in the lower housing part ( 19 ) via a discharge cone ( 25 ) with the coarse material discharge pipe ( 20 ) is connected.