The invention relates to a solid bowl screw centrifuge for continuous separation of a mixture of flowable substances having different densities.
In screw centrifuges of the existing art, for example in accordance with DE 39 21 327, the device for adjusting the liquid level comprises a weir that can be mechanically displaced during operation. The mixture to be separated is charged via a static inflow tube into a charging chamber integrated into the screw body and from there into the working space of the centrifuge, and is subjected to a corresponding centrifugal acceleration due to the drum rotation speed. In the working space of the centrifuge, the solid material, usually of higher density, settles against the inner wall of the drum and is conveyed by the conveyor screw to openings at the end of the conical drum and spun out. The clarified centrate (the light phase) flows in the screw flight oppositely to the solids transport direction and leaves the centrifuge through the weir opening.
The weir known from DE 39 21 327 is displaced in a radial direction via an axially shiftable ring and a deflection member in order to adjust the liquid level.
Another adjustment capability is described and depicted in EP 702 599 B1, in which the throttle disk of the weir is displaced axially so that the orifice can be modified relative to a stationary throttle disk.
DE 103 36 350 A1 describes and depicts a solid bowl screw centrifuge in which a scraper disk, which is preceded by a throttle disk, is arranged nonrotatably on the inflow tube that is stationary during operation. The two disks can be axially displaced by means of an electrical drive system. Alternatively, the throttle disk can be embodied as an element rotating with the drum.
The object on which the invention is based, in the context of a screw centrifuge of the type described hereinafter, is that of simplifying the design of the device for setting the liquid level while retaining the possibility of level adjustment during operation.
This object is achieved according to the present invention in that the device for adjusting the liquid level is made up of a control element having means for decelerating or accelerating the liquid particles of the light phase, which element is rotationally driven at a rotation speed different from the drum rotation speed and leaves open a flowthrough annular gap with respect to the drum inner wall.
This manner of achieving the object has the considerable advantage, as compared with the existing art, that adjusting the liquid level does not require a weir having a mechanical positioning mechanism, since a control element whose rotation speed is modifiable is instead provided.
As a refinement of the invention, the control element is embodied as an immersion disk whose surface discontinuities can decelerate or accelerate the liquid particles. Ribs axially protruding from the immersion disk are possible as surface discontinuities, but in addition also slits or holes in the immersion disk, projections, or roughened surface areas. These can be provided on one side or on both sides of the immersion disk.
An alternative possibility is to embody the control element as a vane rotor.
The control element can be fastened on the hollow shaft of the conveyor screw, so that the rotation speed of the control element is simultaneously linked to a change in the screw rotation speed.
In a variant of the invention, the control element can be rotatably mounted on a hollow stub shaft of the rotor drum and can be connected to a dedicated rotational drive system in the form of a motor. Upon a deceleration of the control element, the rotational drive system acts as output drive for a generator.
Further features and advantages of the invention are evident from the claims and from the description below of exemplifying embodiments that are depicted in the drawings, in which:
A conveyor screw 22, having a rotation speed differing from the drum rotation speed, is mounted in rotor drum 12 rotatably around axis 16. The rotational drive system necessary for this is likewise not depicted. Conveyor screw 22 is made up of a hollow shaft 24 to which screw flights 26 are attached for transporting the heavy phase to discharge openings 28 in conical drum segment 20.
An inflow tube 32 not depicted in
When the centrifuge is in operation, screw flights 26 deliver the high-density phase (solids), which assumes a level hp with respect to the drum inner wall, into conical drum segment 20, from which it is delivered via discharge opening 28. The liquid, light phase (centrate), having a level hF, flows in the opposite direction to end wall 40 that terminates cylindrical drum segment 18, control element 42 being arranged according to the present invention before said wall. In the example of
The pressure in the region of control element 42 behaves like that in a U-shaped tube, in which the centrate particles firstly flow radially with respect to drum inner wall 58, and then flow outward through annular gap 60 and overflow 62 in end wall 40.
P
F
=P
D,
such that, where z=centrifugal acceleration:
P
F
=h
F·ρF·z
P
D
=h
D·ρD·z
The differing angular speeds of rotor drum ωR and of control element ωS are indicated in
ωR=ωF.
The angular speed ωS of control element 42, embodied as an immersion disk 44 with or without ribs 46, is approximately equal to the angular speed ωD of the slurry (heavy phase), but different from ωF of the centrate:
ωS≈ωD≠ωF.
Three different cases will now be considered. In the first case, immersion disk 44 of control element 42 is assumed to be embodied without ribs 46, for example as depicted in
The second case corresponds to the sketches shown in
The third case corresponds to what is depicted in
The centrate particle enters gap 60 between immersion disk 44 and end wall 40 at the circumferential speed acquired at drum inner wall 58. In the region of ribs 46 or vanes 66, the centrate particle is forced to assume approximately the rotation speed of immersion disk 44 or vanes 66. The circumferential speed of the centrate particle is decelerated in accordance with the rotation speed of the immersion disk or vanes, and in accordance with the diameter in question. The deceleration energy is converted into electrical energy in the generator. The centrifugal acceleration acting on the centrate particle decreases in accordance with the lower circumferential speed. Equilibrium conditions in gap 60 between immersion disk 44 and drum inner wall 58 become established due to a decrease in the liquid level in working space 38 of the centrifuge. When vanes 66 are used, a separating wall 68 with respect to working space 38 of the centrifuge is necessary.
In the example of
The embodiment depicted in
Lastly,
Influencing the liquid level during operation of the centrifuge yields the following capabilities:
Number | Date | Country | Kind |
---|---|---|---|
10 2012 102 478.2 | Mar 2012 | DE | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2013/055956 | 3/21/2013 | WO | 00 |