DE19962645A1 - Weir device for affecting a centrifuge for treated liquid uses an outlet in a rotating centrifugal drum via a weir running round the drum with axial adjustment of a throttle to affect the outlet's axial width and change pond depth. - Google Patents

Abstract

Treated liquid passes out through an outlet (13) from inside a rotating centrifugal drum (2) via a weir (20,20') running round the drum. This outlet is between the weir and an axially adjustable throttle element (12) allocated to it. Axial adjustment of the throttle affects the axial width of the outlet and changes pond depth within the centrifugal drum.

Description

The invention relates to a weir device for a centrifuge, in particular Solid bowl screw centrifuge for two and multi-phase operation, with one clarified liquid via a centrifugally driven drum revolving weir from the inside of the centrifuge drum to the outside a passage is drained between the weir and one of these associated, axially adjustable throttle element is formed, the axial Adjustment affects the axial width of the passage and thereby adjustable throttling effect the pond depth within the centrifuge bowl changed accordingly.

Known centrifuges of the type in question are usually according to the Conception designed, the pond depth, d. H. the radial dimension between the Inner wall of the drum and the operation due to the centrifugal force adjusting approximately cylindrical surface of the pond mirror to the axis of rotation seen to determine that the overflow edge of a weir is correspondingly radially adjustable.

Known centrifuges are in the discharge area of a clarified liquid phase Provide breakthroughs that can serve as a weir, but are common weir disks downstream of these openings in the direction of flow assigned the actual overflow edge for the liquid to be drained form and because of their interchangeability allow at least a first Presetting the pond depth.

As an example of ways to change the overflow edge of a weir design in order to determine the pond depth within the centrifuge drum, is referred to DE-OS 39 21 327. There is a multitude of  Opportunities demonstrated, radial weir adjustments, including through Settings coaxial to the axis of rotation of the centrifuge drum movements to make; in this context are also bellows-shaped Elements used.

A weir device of the type mentioned is known from DE-PS 43 20 265 known; there is a throttle disc axially to the weir as seen from the outside spaced apart, between which and the weir a passage is formed, through which the liquid to be drained flows approximately radially. The throttle plate When viewed radially inward, it partially overlaps the overflow openings of the Weir. The throttle plate is axially adjustable, so that the axial width of the Passage is adjustable. Due to the throttling effect of the passage taking into account the flow resistance of the liquid to be drained the inlet etc. the pond height of the suspension within the centrifuge drum adjustable. In this known centrifuge, the throttle disc is opposite the centrifuge drum driven at high speed and thus its weir however silent, so that considerable energy losses occur (Fluid brake). In addition, there is a risk that from the in the Passage and there due to the difference in speed between weir and Throttle disc violent turbulence liquid splashes radially and thus into the Area of the drum bearing. Such an impairment of the Drum bearings cause increasing maintenance requirements. When the The centrifuge creates a surge of liquid in the direction of the drum bearing.

The invention has for its object a weir device at the beginning mentioned type with regard to the need for drive energy and in particular also to make maintenance work cheaper.

This object is achieved in that the Throttle element with the centrifuge drum and thus rotating around the weir is arranged.

Through the throttle element adjacent to the weir and the passage identical rotational speed is that from the centrifuge drum liquid drained outside in terms of its flow conditions not affected. Braking actions and therefore more  Energy expenditure is avoided. Injection marks of the drained Liquid in the direction of the drum bearing is therefore already so far reduced.

In a particularly preferred embodiment, the throttle element is in the axial Directionally deformable disc designed like a membrane, the preferably on their in the culvert, d. H. the weir, facing away with a the deformable controllable force can be applied. The deformation the membrane towards the weir and thus towards one Reduction of the axial width of the passage is preferably through a Pneumatic or hydraulic controllable pressure medium selectively adjustable causes. Mechanical adjustment devices are also possible, especially if the throttle element is designed in the manner of a piston instead of a membrane becomes.

The design of the throttle element as a membrane, which is basically only on their outer periphery - connection to the centrifuge drum - or to its inner Periphery - connection to the centrifuge drum hub - on the drum In a preferred embodiment, both must be specified To connect peripheral areas to the centrifuge drum and so far completely isolate the drum bearing from the drained liquid. To for this purpose, for example, a radially extending flange ring be provided, which is fixed to the drum hub at the same time as the membrane is and in its radially outer region, the outer periphery of the annular Membrane holds. Due to the relatively complete shielding of the Drum bearing is also affected by the collapse of the Liquid ring inside the centrifuge when it is switched off and thus caused liquid surge controllable.

The membrane can consist of a metallic material; the ones in here Deformation paths to be considered in the direction of a throttling Gap narrowing is relatively small. The membrane can also be made of an elastic plastic - possibly multi-layer composition - exist, the side of the membrane facing the passage or weir  with an abrasion and / or erosion protection coating or the like can be provided.

On the side of the membrane facing axially away from the passage, a Pressure medium chamber can be provided which, depending on the type of pressure medium or Pressure supply different conditions suffices; the pressure medium - for example in the form of a controlling amount of water - radially from the inside fed via an annular chamber inlet, so that the pressure effect of this Water is caused by the centrifugal force, then the Pressure medium chamber in the radially outer area with a small calibrated Provide outlet opening in such a way that by controlling the Pressure medium chamber in the radially inner area of the amount of liquid supplied Deduction of the amount of liquid flowing through the outlet, the filling of the Pressure medium chamber and thus the axial deformation of the Membrane can determine. Another way of pressurizing the hydraulic or pneumatic pressure medium chamber is that Pressure medium is supplied via a so-called rotary union, that is one Device for transferring print media between a fixed one Feeding and a rotating forwarding with the lowest possible Pressure loss or leakage.

Preferred embodiments of the invention result from the subclaims and the description of the subsequently dealt with exemplary embodiments according to FIGS . 1 to 3, to which particular reference is made and the following description of which explains the invention in more detail; The exemplary embodiments all relate to the implementation of the measures according to the invention on a solid bowl centrifuge. Show it

Fig. 1 to the liquid discharge end portion having a solid-bowl helical conveyor centrifuge, in axial section, wherein the perforations in the end-wall region of the drum end themselves form the weir;

FIG. 2 shows a representation corresponding to FIG. 1 with an annular weir disk connected downstream of the openings in the end wall region of the centrifuge drum;

Fig. 3 is a representation corresponding to FIG. 1 with a modified pressure medium chamber.

In the figures, 1 is a solid bowl centrifuge - also a decanter called - with regard to their containing the separation of the clarified liquid axial end region shown; left over the extension of the centrifuge the solids discharge is extended. In the simplest way it is thereby by a two-phase decanter, d. H. one for separation treatment in the Drum interior abandoned suspension - solid-liquid mixture - is clarified under centrifugal force in the solids content and by this Liquid fraction separated, the latter from the range of interest here the left end of the decanter shown is drained.

Inside the centrifuge drum 2 is denoted overall by 3, disposed coaxially to the drum 2 from screw conveyor hub 4 and screw is provided in a known manner in this context helix. 5 The drum hub 7 is held on the bearing block or machine bed 10 via a roller bearing 8 , while the worm or worm hub 4 is supported on the drum hub 7 via a worm bearing 9 .

In the end wall - generally extending radially to the axis of rotation of the drum 2 - openings 11 of approximately any cross-sectional shape - circular, rectangular or oval etc. - are provided in the axial direction, which serve for the passage of the clarified liquid to be drained. In the example according to FIGS. 1 and 3, the radially outer edge regions of these openings 11 also form the weir 20 'in the sense of the teaching according to the invention.

A diaphragm 12 is assigned to these openings 11 or their radially outer edges and thus to the weir 20 'axially outwards, which is fixed in its inner peripheral area by means of screws 21 with the interposition of a flange ring 22 on the drum hub 7 . The radially outer end region of the flange ring 22 holds the peripheral outer region of the annular membrane 12 by means of screws 23 .

The liquid flowing off over the radially outer edge region of the openings - FIGS. 1 and 3 - is thrown radially outward due to its centrifugal component outside the drum 2 and thereby passes through the passage 13 , which is a circumferential ring gap, but can also be interrupted in principle. The passage is delimited axially outwards by the membrane 12 , that is to say it is located primarily between the weir 20 '- the radially outer region of the openings 11 in FIGS. 1 and 3 - and the membrane 12 . An axial expansion of the membrane 12 in the direction of the weir 20 'leads to an axial reduction in the passage width of the passage 13 and thus to a throttling of the clarified liquid radially emerging from the inside of the drum via the weir 20 ' with the result that the pond depth of the Suspension inside the centrifuge drum rises. When the axial width of the passage 13 is increased , the opposite effect occurs, as a result of which the axial displacement of the membrane center enables the pond depth to be controlled.

The control of the axial displacement movement of the membrane 12 towards the weir 20 'with increasing the throttling effect and the decreasing reduction of the throttling effect generally under the return movement of the throttle disc due to its elasticity and the liquid pressure of the liquid to be drained in the passage - can also be influenced in a targeted manner from the outside - happens via a pressure medium chamber 14 , which is provided as an annular space concentric to the drum axis of rotation between the membrane 12 and the flange ring 22 . This pressure medium chamber 14 is fed in its radially inner region via a pressure medium feed line 15 and has in its radially outer end region a chamber outlet 17 which is calibrated smaller, ie is designed to be throttled with respect to the inlet. This embodiment according to FIGS. 1 and 2 is based on the idea of introducing a pressure medium, for example water, via a feed channel 18 into an annular chamber inlet 16 , from which the pressure medium line 15 leads radially into the pressure medium chamber 14 , so that in this way Introduced water - other liquids of course possible - generates pressure in the pressure medium chamber 14 under centrifugal force. The pressure and the filling level and thus the force on the membrane is dependent on the amount of liquid entered through the supply line 15 in relation to the amount of liquid discharged through the chamber outlet 17 - so that the force and thus the bulging of the membrane 12 in the direction of the narrowing of the Passage 13 of the amount of liquid supplied through line 15 .

The embodiment of FIG. 2 differs from that of FIG. 1 essentially in that the openings 11 in the end wall 6 of the drum 2 downstream in the flow direction, that is, from the outside, a weir disk 20 is assigned non-rotatably, the ring - if necessary, also with openings and incisions - downstream of the openings in the direction of flow insofar as the depth of the pond is designed to be replaceable, if necessary. Otherwise, the exemplary embodiment according to FIG. 2 corresponds functionally to that according to FIG. 1.

FIG. 3 shows a further exemplary embodiment, the basic arrangements of which, as the corresponding reference numbers indicate, correspond to those of FIGS . 1 and 2. Deviating from this, the pressure medium chamber 14 is not provided with a radially outer chamber outlet. The pressure conditions in the chamber 14 are therefore determined exclusively via the pressure medium supply line 15 and the upstream supply channel 18 . The pressure state in the chamber 14 must therefore only be determined by the pressure medium fed in from the outside. For this purpose, a so-called rotary feedthrough is required, which is provided at 19 in the transition area between the stationary and the rotating parts of the centrifuge and which allows the transfer of pressure media or pressure conditions in a known manner without major losses.

Claims (12)

1. Weir device ( 12 , 13 , 20 ') for a centrifuge, in particular a solid bowl screw centrifuge ( 1 ) for two and multi-phase operation, in which a clarified liquid via a weir ( 20 , 20 ') rotating with the rotating centrifuge drum ( 2 ) from the inside of the centrifuge drum ( 2 ) to the outside through a passage ( 13 ) which is formed between the weir ( 20 , 20 ') and an associated, axially adjustable throttle element ( 12 ), the axial adjustment of the axial width of the Passage ( 13 ) influences and its adjustable throttling effect accordingly changes the pond depth within the centrifuge drum ( 2 ), characterized in that the throttling element ( 12 ) with the centrifuge drum ( 2 ) and thus the weir ( 20 , 20 ') is arranged all around. 2. Weir device according to claim 1, characterized in that the throttle element ( 12 ) is designed as an axially deformable disc, here so-called membrane, which is preferably acted upon on its side facing away from the passage ( 13 ) with a deformation-dependent controllable force . 3. Weir device according to claim 1 or 2, characterized in that a pneumatic or a hydraulic, controllable pressure medium is provided for the axial adjustment of the throttle element ( 12 ). 4. Weir device according to claim 2 or 3, characterized in that the membrane ( 12 ) on at least one of its peripheral areas - outside or inside - with the centrifuge drum ( 2 ) or the drum hub ( 7 ) is fixedly connected. 5. Weir device according to claim 4, characterized in that the membrane ( 12 ) as an annular throttle element comprising the axis of rotation in one of its peripheral edge areas - inside or outside - directly connected to the centrifuge drum ( 2 ) and the other edge area via one in this fixed connection received, radially extending flange ring ( 22 ) or the like is so far indirectly connected to the centrifuge drum ( 2 ) rotatably. 6. Weir device according to one of claims 2 to 5, characterized in that the membrane ( 12 ) consists of a metallic material. 7. Weir device according to one of claims 2 to 5, characterized in that membrane ( 12 ) consists of an elastic plastic - also multi-layer composition. 8. Weir device according to one of claims 2 to 7, characterized in that the passage ( 13 ) facing side of the throttle element ( 12 ) is provided with an abrasion and / or erosion protection coating or the like. 9. Weir device according to one of claims 1 to 8, characterized in that a pressure medium chamber ( 14 ) is formed on the side of the passage ( 13 ) axially facing away from the radially extending membrane ( 12 ). 10. Weir device according to claim 9, characterized in that the pressure medium chamber ( 14 ) has a radially inwardly directed inlet channel ( 15 ) for an adjustable control liquid, in particular water, and with a smaller in terms of flow resistance or diameter, the outside drainage channel ( 17 ) is provided. 11. Weir device according to claim 9, 10, characterized in that the pressure medium chamber ( 14 ) is connected fluidically to an inlet channel ( 15 , 18 ), which in turn is connected on the input side to a pressure-tight rotary union ( 19 ), via which the pressure medium chamber ( 14 ) a pressure-controllable medium - pneumatic or hydraulic - can be supplied. 12. Weir device according to one of claims 1 to 11, characterized in that the weir ( 20 ') with respect to the overflow through the radially outer edges of openings ( 11 ) of the centrifuge drum ( 2 ) immediately and / or - if necessary adjustable - downstream in terms of flow technology Weir elements ( 20 ) is formed.