The present invention relates to a screw centrifuge for the continuous separation of flowable substances of different densities. More particularly, the present invention relates to a screw centrifuge, in which an air extraction member is provided before a feed chamber to generate a suction flow co-directional with the delivery direction of an inflow tube.
In screw centrifuges for the continuous separation of flowable substances of different kinds, one critical area is where the mixture inflow tube leads into the feed chamber, since portions of the mixture may flow back, because of turbulence or excessive throughput, into the cavity of a hollow shaft of a conveying screw and become deposited inside a cavity of the conveying screw. To remedy this problem, in known designs openings are provided in the wall of the hollow shaft of the conveying screw, through which openings these product deposits can escape into the region of the screw blade. However, product deposits may over time become baked into such cavity and in particular into dead spaces thereof, and thus produce an imbalance on the rotating conveyor screw.
Attempts have therefore been made to circumvent the problem of product deposits in the comparatively large cavity of the conveyor screw by mounting inside the hollow shaft a protective tube through which the mixture inflow tube leads to the feed chamber. The problem is only partially solved in this fashion, however, since the danger still exists that the comparatively narrow annular space between the protective tube and the mixture inflow tube may become clogged with back-flowing portions of the mixture.
It is the object of the present invention to improve a screw centrifuge of the above construction to prevent backflows at the end of the inflow tube, so that deposits due to back-flowing portions of the mixture are effectively prevented.
To achieve this object, according to the present invention, an air extraction member is provided before the feed chamber in the delivery direction of the inflow tube, which member generates, in the annular space enclosing the inflow tube, a suction flow co-directional with the delivery direction in the inflow tube.
This suction flow at the outer periphery of the inflow tube prevents, with simple means, a backflow of portions of the mixture back into the cavity of the hollow shaft, since the suction flow counteracts any such backflow and prevents mixture particles from entering the annular space.
If, in one embodiment of the invention, the inflow tube extends through a protective tube that delimits the annular space from the cavity of the hollow shaft, the suction flow is considerably accelerated because of the comparatively small cross section of the annular space, more efficiently counteracting any undesired backflow.
In one embodiment of the invention, the air extraction member has a central entry region into which projects the end of the inflow tube leading to the feed chamber. In one variant of this embodiment that is relatively inexpensive due to its simple design, the air extraction member can be embodied as an impeller part of a centrifugal pump.
This impeller part can be embodied integrally with the hollow shaft and comprises suction channels that proceed from the central entry region and lead, with a profile curved oppositely to the rotation direction of the hollow shaft, to the screw blade.
The result of the invention is on the one hand that product deposits cannot settle in the comparatively large cavity of the hollow shaft, while simultaneously eliminating the danger that the comparatively narrow protective tube can be clogged by back-flowing portions of the product. The air extraction member ensures that during rotation of the conveyor screw, air is constantly being extracted through the annular space, which is thereby always ventilated and thus kept free of deposits.
The invention is explained below with reference to an exemplifying embodiment that is depicted in the drawings, in which:
Arranged inside hollow shaft 28 is an inflow tube 30 for the mixture to be separated, which enters inflow tube 30 in the direction of arrow 32. Inflow tube 30 extends through a coaxial protective tube 34 that is fixedly joined to hollow shaft 28 and delimits cavity 36 of hollow shaft 28 from annular space 38 (
Free end 40 of inflow tube 30 leads into a feed chamber 42, configured in hollow shaft 28, from which radial feed openings 44 lead into the region of screw blade 26. In one embodiment, free end 40 of inflow tube 30 does not extend into feed chamber 42.
Cylindrical portion 18 of rotor drum 14 is closed off by an end wall 46 that has weir openings 48 for the output of light phase 50, which flows into an output conduit 52 of housing 10.
Provided in conical portion 20 of the rotor wall are discharge openings 54 for heavy phase 56, which is transported, in accordance with the arrows illustrated, from screw blade 26 to discharge openings 54.
The depictions in
When the screw centrifuge is in operation, the rotation of delivery screw 22 (and therefore of impeller part 62) ensures that a suction flow, drawn with dashed arrows in
A further advantage is that the suction flow generated according to the present invention in the direction of the arrows drawn with dashed lines provides assistance in achieving high throughputs V, so that a large partial volume flow V1 is forced by the centrifugal pump system, under pressure, into the region of screw blade 26.
Number | Date | Country | Kind |
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10 2005 025 784 | Jun 2005 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2006/062026 | 5/3/2006 | WO | 00 | 11/7/2008 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/131425 | 12/14/2006 | WO | A |
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