DE3248060A1 - Pressing-out device - Google Patents

Abstract

A pressing-out device is devised for separating mixtures of liquids and solids, by means of which a very high pressing-out pressure can be built up and by means of which the pressed-out liquid can be discharged at the main point where it is released, without liquid outlet apertures causing a noticeable drop of pressure in this region. Insertion of axial outlet bores, which are open towards the screw axis, in pins which are connected to liquid outlet pipes, permit the liquid to be discharged. Arrangement of a rebound, which causes the stationary pinpoints to find a running surface, is achieved in that the proportions of solid, which are small anyway, in the pressed-free liquid which reach the pin bores are reduced even further, so that the pressed-free liquid can be diverted without difficulty into clarification plants.

Description

Extrusion device

===================== The invention relates to an extrusion device for separating the liquid from the solid components of a liquid-solid mixture according to the preamble of claim 1 from DE-OS 30 46 384 of the applicant a device for squeezing liquid igkeitsfeststoffgemischen known with pins protruding through the press cylinder. Axial bores are arranged in the pins for the discharge of the expelled liquid.

Due to the introduction of axial and open to the screw axis Drain holes in the pins that communicate with drainage pipes achieved that the squeezed out liquid immediately at the point of its release can be discharged without a noticeable loss of pressure through the discharge openings must be accepted and in particular without the once pressed free Liquid or the intercellular or inter-volume water pressed free in the case of organic substances re-mixes with the solids.

The pins themselves make the product turn with the worm prevented, so that a high delivery rate and thus a high pressure in the pen cylinder area is built up so that the released liquid through the drain holes in the pens due to the high Pressure drop of, for example 10 - 500 bar in the press cylinder and 1 bar (atmospheric pressure) in the drain holes can be easily discharged.

Because the distance between the pen tips and the bottom of the screw thread relatively small, for example 0.3 mm, is also achieved that only very small solids that do not block the drainage holes are also removed will. The pin tips are adapted to the roundness of the worm core.

It has now been shown in practice that the solids content of the pressed liquid is usually so small, despite the small distance, that the forwarding of the loaded with low solids content, pressed free Liquid. Is harmless in sewage treatment plants.

In special cases, e.g. when dewatering slightly toxic solids, however, it is desirable to reduce the solids content even further.

It is therefore the object of the invention to show an extrusion device, which works according to the separation gap principle and ensures a separation of mixtures with extremely low solids content in the pressed liquid.

The problem is solved by what is laid down in the patent claims Characteristics .

Due to the arrangement of the step-shaped, radial recess, on the reason of which the stationary pins intervene, we achieved that no solid fractions can be pressed into the separation gap by the following good, because in the lower Separation gap area the leeward pressure is lowered in front of the pen tips and because the pen tips arranged lower are as the corridor base. The pen tips will be covered by the stepped arrangement of the recess in the material flow direction, so that a pressure reduction takes place on one side and on the other side no material can be pressed into the separating gap.

It has been shown that the arrangement of the pen tips In the material flow direction, covering, step-shaped recesses covering the solids content the freed liquid could be reduced again by over 80%, so that the .abgepreßte liquid can be safely discharged into any sewage treatment plant.

By introducing a rectangular cross section on the inlet side Groove, which is conical on the output side, in the screw core into which the Engaging pen tips becomes a very inexpensive and easy method for that Solution of the problem disclosed, which also has the advantage that at the same time as screwing in the groove, a very precise running surface for the in some Only 0.3 mm thick separating gap is created between the pin tips and the groove base the pin tips must be adapted to the rounding of the groove base.

The embodiment disclosed in claim 3 comes without a turning dn the snail core because on the core there is a ring with a pointing towards the pins raised, beveled edge welded on or turned out of the full core will.

With this embodiment, the solids are pushed up and then through the free, radical spaces between the individual pins further promoted.

It should be emphasized that in all of the disclosed embodiments on the back of the pins as seen in the direction of material flow, i.e. the lee side, a negative pressure is created, so that the pressure in front of the pins is particularly high exposed solid parts lightly push their released liquid to the rear, the leeward side of the pens, from where they can be unhindered by solids parts can get into the separating gap.

By combining several trained with drain holes Pins to orthogonal pin planes is achieved that the expelled liquid can flow circumferentially in several places.-The adjustability of the pins with regard to their immersion depth causes a change in the delivery rate and thus the pressure build-up, but in particular an adaptation of the squeezing device of different sized solid constituents.

Based on the drawing, a preferred embodiment of the Invention explained.

1 shows a schematic longitudinal section through an extrusion device.

Fig. 2 and 3 special designs of the recess in longitudinal section.

FIG. 4 shows a detail X from FIG. 1.

1 with the extrusion screw is referred to, which is in the press cylinder 2 is arranged. The screw is driven by a drive unit not shown in FIG Rotational movement offset where through the material to be pressed from the feed area 4 is conveyed forward to the outlet opening 20.

In the press cylinder 2 in the inner jacket are in the screw axis direction extending grooves 3 introduced, which are triangular in cross section can. However, the grooves can also be rectangular or semicircular be.

In the pin cylinder area 5, the press cylinder 2 is opened radially by means of Pins showing the screw axis and reaching down to the bottom of the flight of screw 1 6 penetrated. The pins 6 are interruptions 7 of the helically extending Associated screw webs 8, in a width approximately corresponding to the diameter of pins 6.

The pins 6 are screwed into the press cylinder 2 and by means of Locked nuts 9. The individual pins 6 can correspondingly far into the press cylinder 2 screwed in to adjust the distance between the pen tip and the worm core to be able to vary.

The pins 6 are combined to form individual pin levels 10, 11 and 12.

In the pins 6 axial drainage bores 19 are introduced, which with Drain pipes 14 are connected.

If there is no material in the dispenser, touch the pen tips not the snails 1. If a non-concentric position of the The screw to the cylinder comes about (one-sided contact with the cylinder), a Contact between the running surfaces and the worm cannot be ruled out.

The running surfaces of the pins 6 facing the screw core can therefore from a material combination with dry running properties or from bronze exist to reduce signs of wear and tear.

The liquid-solid mixture is through the funnel 17 into the Space 18 entered between the individual screw flights 8 and through the rotary movement the screw 1 is conveyed in the direction of the outlet opening 20.

In the catchment area 4, the goods experience a first compression and this is easy Squeezable liquid flows through the strainer openings 21 into a container. Thereafter, the material is promoted in de pin cylinder area 5, where it is in the Press cylinder 2 protruding pins 6 is prevented from rotating with the worm ke. So das.Gut builds up for a short time in front of the pins 6, which causes the pressure in the The worm thread rises until the gutlin is pushed along the path through the following guts is when the rotating worm gear content is at a free, not through pins 6 handicapped part of the scope arrives.

In the pen cylinder area, the greatest pressure is applied to what is to be pressed out Well exercised, whereby the intercellular resp.

Inter-volume water is released and thus a dry matter content Depending on the material, over 90% is obtained continuously and in just one operation will.

The outlet opening 20 is closed by means of a pressure-loaded cone 23 and only above a certain, preselected pressure does the outlet opening open 20. This measure also results in a further increase in pressure in the pin cylinder area 5.

The most important prerequisite for the high degree of drainage of the Liquid solids mixture, however, consists of the arrangement the axial drainage bores 13 in the pins 6, because thus in the area of the extrusion device, in which the water is squeezed out by means of the very high pressure, also one Drainage possibility for the released liquid was created.

It is of the essence that once released the fluid is set möolichst also to be discharged at the point of squeezing, without re-mixing can take place with the solid to a significant extent.

By making the drainage bores 13 in the pins 6, in particular However, achieved that the squeezed cell water liquid can be drained, without a significant loss of pressure in the pin cylinder area 5.

On the other hand, the high pressure build-up for the extrusion of the water needed to be able to achieve such high dry matter contents.

Beet leaves were added to the hopper and through the squeezer continuously passed through. It was a dry matter content of 40% in only achieved in one pass, which can be regarded as an extraordinarily good performance got to.

The pins with the drainage holes are between helical web sections arranged with radial web bores 25, the web bores 25 with an axial Screw bore 26 are in communication to also via this system on the cylinder wall to be able to discharge released liquid. In the back of the webs 8 are web back grooves 27 introduced, which the discharge of the pressed-free liquid on the cylinder inner wall favor considerably.

On the screw core, annular collars 15 are arranged, which in direction on the pins 6 to have a tapered elevation, as can be seen from the drawing X and from Fig. 4 can be seen.

In the material flow direction, behind the annular collars 15, there is a step-shaped Recess formed with a base 16, which together with the pin tips 19 form the separating gaps 22 for the discharge of the pressed-free liquid.

The annular collar 15 ensures that the pressure in the vertical gap 24 is reduced, as a result of which fewer solids get into the separating gap 22. if the material is pressed against pins 6, the liquid pressed free flows due to of the pressure drop in the separating gap 22 without any significant amount of solids are also torn into the separating gap 22.

In the embodiment shown in FIG. 2, the recess is formed by reducing the screw core, creating the vertical gap 24 and the separating gap 22 is formed with the reason 16. Pen tips 19 are through in this case too the vertical gap protected.

The embodiment shown in Fig. 3 shows an input side in Rectangular cross-section and tapering on the outlet side into the screw core introduced groove 28, the pin tips 19 forming separation gaps 22 with the base 16. This embodiment is particularly advantageous because the pins are formed by the groove 28 experience an additional tour.

REFERENCE CHARACTERISTICS LIST ====================================== 1 = snail 2 = press cylinder 3 = cylinder grooves 4 = feed area 5 = pin cylinder area 6 = Pins 7 = interruptions 8 = screw flights 9 = nuts 10 = pin level 11 = Pin level 12 = pin level 13 = drainage holes 14 = drainage pipes 15 = annular collars 16 = base 17 = funnel 18 = space 19 = pen tips 20 = outlet openings 21 = Strainer openings 22 = separating gap 23 = cone 24 = vertical gap 25 = web bore 26 = worm hole 27 = web back groove 28 = groove

Claims (3)

PATENT CLAIMS 1. Squeezing device for separating the liquid from the solid components of a liquid-solid mixture with one in one Press cylinder rotatable and drivable screw, with a helical on it arranged screw flight, with the press cylinder penetrating radially on the The screw axis pointing and reaching down to the bottom of the passage, combined into pin planes Pins with correspondingly wide breaks in the helical shape around the screw core extending screw flights are assigned, with axially in the pins and to the screw axis open drainage bores that are connected to drainage pipes stand, characterized in that a step-shaped, radial, circumferential return is arranged that the reason (16) of the return with the stationary pins (6) separating gap (22) forms for the discharge the expelled liquid. 2. Squeezing device according to claim 1, characterized in that the stepped recess is formed by a cross section on the input side Rectangular radial groove (28) in the worm core, tapering conically on the outlet side, in which the stationary pins (6) engage. 3. Squeezing device according to claim 1, characterized in that the step-shaped recess is formed by an arranged on the screw core, ring-shaped elevation that is beveled in the direction of the pins (collar) (15) and that the tips (19) of the pins (6) in the direction of material flow from the annular Survey (15) are covered.