SK4297A3 - Auger press - Google Patents

Abstract

Spiral press is aimed to obtain vegetable oil from the material containing oil. Inserted and unpressed material is fed into the place of jet modified for pressing the oil out by means of delivery screw (8). To increase pressing out output there are on the driving shaft (12) in screw box (1) as one part consecutively connected two or more screw levels (9, 10) which are in term of delivery capability of wreaths of the screw and their rising made compatibly and between them is placed intermediate place (7) of the jet.

Description

Technical field

BACKGROUND OF THE INVENTION The present invention relates to a vegetable oil silage press with a conveyor slug that transports oil containing a starting material, for example, oil seeds or oilseed substantially fed and unpressed to the location of an oil-jet nozzle and a slug housing in which the conveyor slug is stored. In principle, it is cylindrical and has oil outlet openings for discharging at the nozzle location of the pressed oil, the oil outlet openings being spaced apart from the nozzle location in the housing region when viewed in the conveying direction of the snail. The oil outlet openings may be in the form of openings, slots or the like. Punching or screen-like slots can be provided, for example around the circumference of the cylindrical housing.

BACKGROUND OF THE INVENTION

A screw press of this kind has long been produced and operated by the applicant under the name Komet. In this press, conveyor slugs are provided in which, in their threads or in their threads, the oil-containing material, such as oil seeds or oilseed, is practically not compressed. The pressing and eventually crushing of the seed material takes place only at the point of the nozzle at the exit of the conveying slug. The pressed oil then flows against the conveying direction of the snail and protrudes at a distance of several, for example two to three, bypasses of the snail thread through holes, which are also, for example, sieves, from the press housing that surrounds the cylindrical snail. This simple conveyance and only local compression with a corresponding short-term pressure increase in the oil-containing material has the invaluable advantage that the oil-containing material is not overheated, i.e. it is not heated to the extent that heat-related damage to the natural product.

There are also known screw presses for obtaining vegetable oils, the slugs of which the oil-containing material already compresses continuously or stepwise inside the slug thread on the way to the nozzle location. These are described, for example, in DE-PS 817 687, DE-OS 87 51 705 and DE-OS 30 83 477. According to this prior art, a higher pressure is achieved in each compression and conveying stage. This is achieved, for example, in that the conveying volume of the slug threads in the transport direction decreases from one stage to the other or even within the interior of one stage. By conveying snails of this type, higher throughputs can be achieved than with conventional corresponding worm presses, but it is not possible to prevent overheating of the oil-containing material and the oil with corresponding thermal damage to the natural products.

In the process known from DE 53 81 983 A1, liquid from a mixture of solid and liquid is extruded through a perforated casing of a screw press. The known cotter press has at least one annular nozzle positioned between the housing and the slug shaft for generating a regional high pressure. The cloak that surrounds the slug shaft is, in principle, similar to that of the Comet press, carried out in a corresponding area of high pressure on the nozzle completely closed. However, the pressure in the molded material is gradually generated even before the start of the screw thread until it reaches its maximum at the nozzle location.

Furthermore, according to the above-mentioned DE 35 31 985 A1, in the case of an increase in pressure at the nozzle location from the slug region to the slug region, a roughly equal conveying volume is set up before each nozzle. However, these conditions can only be met if it has already been stated in the prior art when the dimensional ratios of the respective snail parts vary from step to step.

In order to increase the conveying capacity of the screw press in comparison with the Komet press described above, efforts have been made to deploy slugs with a considerably larger circumference and correspondingly larger conveying capacity of the slug thread. However, it has been shown that an increase in the radius of the slug thread necessarily results in an increase in the pitch of the transport slug since the two adjacent threads must not overlap. The transport volume of each thread of the transport snail is effective only to the extent that the thread cross-section does not cross the semicircle. In order to increase the transport volume, the individual threaded threads must therefore be wider, which necessarily results in an increase in the slug pitch.

Thus, in this worm press with only a conveying snail, the oil is extracted from the oil-containing material by compressing it between the last thread of the snail and between the nozzle-acting, through-hole annular gap, i.e. the nozzle slot. If the pitch of the snail is increased, it decreases in

With this nozzle location, the downforce efficiency, even when the machine turns more slowly. This effect consists in the fact that, in the case of greater inclination in the circumferential direction at the nozzle location, the length of the pressing region measured between the last threading cycle is slugs. which is only partially available and shortens between nozzles. The experiments finally showed. that neither increasing the slug radius nor increasing the pitch or even increasing the speed of the snail leads to a decisive increase in the displacement performance as long as the material containing the drawbar is only conveyed in the snail and only compressed directly in the nozzle area and oil is withdrawn therefrom.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION It is an object of the present invention to provide a screw press for obtaining vegetable oil in which oil containing feedstock is essentially transported by slug only and is therefore not heated by premature compression, but which, compared to the Komet press described above, pressed.

The solution according to the invention consists in a screw press of the kind described at the outset in that two or more slug stages are connected in series to the drive shaft in the slug housing as one piece, which are substantially identical in terms of the conveying volume of the slug threads and their pitches; between them there is an intermediate nozzle location having an annular gap, and that when viewed in the transport direction, they are spaced apart from each intermediate nozzle location on the periphery of the conveying slug in the slug housing. The development of the glazing and other embodiments of the invention are set out in the dependent claims.

According to the invention in terms of conveying identity, two or more threads of the slug are provided with substantially partial conveying slugs with the intermediate engagement of a single nozzle location in which the oil-containing material is extruded on a single shaft one after the other. Each of these intermediate nozzle locations has an oil outlet region associated with the periphery of the slug, to which a nozzle location with a plurality of slug threads is to be allocated. The partial transport slugs are preferably of equal length.

By connecting the individual transport slugs in one piece on a single shaft, a single motor is sufficient to drive the entire slug. At the outlet of the entire snail, i.e. the rear-engaging longer snail, the oil-containing material, as in the corresponding screw comet press, is deflected in the direction of the longitudinal axis of the snail towards the inside, is pressed and discharged in the conveying direction as a pressed pellet. The oil thus obtained flows against the material to be conveyed along the inner surface of the housing to the mesh outlet openings of the housing.

Only by dividing the molding of the oil-containing material into two or more stages, a task according to the invention for a given screw press is quite unexpectedly solved. This solution makes it possible to obtain, in spite of the increased conveying volume of the individual screw threads and the correspondingly increased screw pitch, the overall at least equal percentage of the pressed oil as in conventional presses, but it is possible for the unit to pass through the press. In the exemplary embodiment, instead of SO kg in a single die press, it could pass through a two-part press, that is, two longer conveyor presses per hour ISO kg of oil seeds at the same degree of oil pressing.

In each individual intermediate nozzle location between two longer conveying slugs having an annular gap, in the cotter press according to the invention, the oil-containing material is crushed and compressed as well as pressed between the outer ring, which is connected to the snail box and the inner ring, attached to the slug shaft. The annular gap, which is provided between the outer ring and the inner ring, is to be adapted in its cross-section, in particular in the radius direction, to the oil-containing material being processed. The larger the proportion of seed oil, oilseed, etc., the narrower the gap.

In order not to always have to disassemble the annular gap press on the handling of another oil-containing material with a greater or lesser proportion of oil, according to another preferred embodiment of the invention the annular gap of the intermediate nozzle location is formed between the inner ring which is connected to the conveyor slug. a drive shaft and having a conical outer surface and between an outer ring connected to the tapered housing and having a conical inner surface, the angles of increase of the two cones increasing or decreasing in the same direction, such that the permeable cross-section of the ring It is controllable by the relative displacement of the two rings, and so it is possible to adjust the oil content of the oil-containing material being processed. For this purpose, the outer ring may be provided with an actuatable actuating means from the outside of the housing to allow the outer ring to be displaced in the axial direction relative to the inner ring. Advantageously, the tapered inner ring can be mounted correspondingly slidable with the slug shaft.

In contrast to the described compression slugs with two or more stages, in which the oil-containing material is staggered step by step, the extrusion of the oil-containing material in the press according to the invention is essentially not or not at all, but practically only by crimping at the corresponding nozzle location. What is important here is that the pressure exerted at the individual nozzle location on the oil-containing material or the pressure created therein immediately drops to zero as soon as the material reaches the nozzle exit.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is explained in more detail below by way of example with reference to the drawing.

In FIG. 1 is a schematic illustration of a screw press in a partial longitudinal section along the axis of the press and in a partial side view.

In FIG. 8 shows the region of the intermediate point of the press nozzle.

DETAILED DESCRIPTION OF THE INVENTION

In FIG. 1 shows a screw press having a slug box 1 with an insert hopper 6 at one longitudinal end 2 and a press nozzle 6 at the other longitudinal end 2. The slug box 1 according to FIG. 1 has an end point 2 of the nozzle before the discharge nozzle 1 and an intermediate point 7 of the nozzle in the central region.

A conveyor slug 2 is rotatably mounted in the interior of a snail box X having a substantially inner cylindrical surface. The conveyor slug 2 comprises, in an exemplary embodiment, a first slug stage 2 and a second slug stage 12, i.e. longer conveyor slugs of the first and second conveyor stages. . The first sliding stage 2 and the second sliding stage 12 are at least identical with respect to the conveying volume and the pitch of the individual threads 11 of the slug and around the modified slug box 1. The two snail stages g and 12 are provided as one piece on the drive shaft 12, which is associated with an engine (not shown) or other drive. Between the two slug stages 2 and 10 there is located the described intermediate point 7 of the nozzle. This consists of an outer ring 15 and an inner ring 14, which is mounted, for example, on the drive shaft 12.

Between the outer ring 15, which is connected to the snail box 1, and the inner ring 14, which connects the two snail stages a and 10 to the drive shaft 18, is compressed. optionally crushed and molded oil-containing material which is fed to the insertion hopper S in the insertion direction 15. The oil obtained obtained against the conveying direction 16 of the snail, i.e. in the opposite direction with respect to the conveying oil-containing material, returns to the region of the first snail stage ä and protrudes on its periphery from the press through a screen 17 equipped with a screen, e.g. which are spaced apart from some of the exterior portions of the slug threads 11 in front of the intermediate point of the lysis when viewed in the transport direction 16. The oil flow 1S can then move along the drawn arrow on the inner surface 19 of the snail box 1 up to the openings of the screen 17 provided with the screen.

While the pressed oil flows against the conveying direction 16, the at least partially oil-free material is further conveyed in the conveying direction 16 through an annular gap 80 which is formed between the outer ring 15 and between the inner ring 14 between the light spot 7 of the nozzle. The inner ring 14 is preferably mounted on the drive shaft 12 so that the partially oil-free material moves further only through the annular gap 80. In this case, the inner ring 14 is preferably to be displaceably mounted or slidable with the drive shaft 12.

Because part of the material loses its volume, the intermediate point 7 of the nozzle is oil, the pressure of the material that has been sharply increased, almost suddenly, immediately to zero, immediately between zero and thread between the last thread 21 and the intermediate point 7 of the nozzle. the material passes through an annular gap 21 ·. This pressureless material is then conveyed by the second slug stage 10 in the embodiment of FIG. 1 to the end point 6 of the nozzle. In principle, however, it is also possible to provide a plurality of non-adjacent nozzle locations 7. In the region of the nozzle end point 6, the oil-free material is then deflected, as in the applicant's comets described above, in the direction of the slug axis 88, i.e. inside, and in the nozzle crown 23 it is pressed so that it finally exits through the outlet 24 in 16 psleta transport 85.

In this region at the end of the slug, the oil-containing material is first deflected between the last thread 21 and the convex end face 27 of the truncated cone of the conveyor slug 8 and between it a substantially parallel, concave inner surface 88 of the nozzle, e.g. of the slug box 1, approximately in the direction of the slug axis 88. In this case, the oil-containing material is crushed and subsequently pressed in the nozzle crown 85 which is upstream of the outlet 24. The oil-free material, i.e. the remaining oil cake, then exits in the form of a pellet 26 from the nozzle. At the same time, the oil obtained flows in the direction of the arrow 16 of the conveying snail S transport in the opposite direction to the sieve outlet 50 in the snail box 1.

The slug region according to the invention at the intermediate point 7 of the nozzle is explained in more detail on the basis of FIG. 8th

The oil-containing material which is conveyed by means of the first jet stage 8 to the intermediate nozzle location 7 in the conveying direction 16 is in the region between the last thread 81 which is only partially available and between the intermediate nozzle location 7 crushed or sliced and molded. the oil obtained flows in the direction of the oil flow 16, that is opposite the direction of transport 16. At the same time, at least partially the oil-free material passes due to the fact that no further passage in the direction of the arrow 31 is provided through the annular gap SO to the second slip stage 10.

The permeable cross-section of the annular gap 80 is selected such that a volume containing material past the unit of time into the insertion hopper S can pass directly through the annular gap 80 after withdrawal at the intermediate point 2 of the nozzle per unit of pressed oil volume. after passing through the annular gap 80 immediately to zero. This pressure-free material is conveyed without pressure to the second intermediate nozzle point 7 or to the nozzle end point g by the second screw stage 10.

As already explained, it is generally desirable to adapt the flow cross section of the annular gap to the oil content of the corresponding material. This is to ensure that with the conveying speed of the snail only the oil-free material can pass through the annular gap 80, possibly with a proportion of oil that has not been expelled at the respective nozzle location, and the oil flow 16 already extruded from the material flows an intermediate location 7 of the nozzle in the opposite direction. With the corresponding adjustment of the flow cross section of the annular gap gg, it is thus also determined to what extent the material to be de-oiled at the respective intermediate nozzle point 7 is to be removed.

In order to achieve an optimum oil push-off effect at or in front of the intermediate nozzle 7, according to a further preferred embodiment of the invention, the annular gap 80 is in principle formed as a gap between two truncated coaxial surfaces, one of the truncated cones slidingly relative to the second truncated cone surface in the direction of the axis of the cone. Thus it is possible to vary the distance between the frustoconical surfaces and thus the permeable cross-section of the annular gap 80. Preferably, the annular gap 80 between the nozzle easy locations 7 is formed between the inner ring 14 which is connected to the conveyor slug g, e.g. a conical-shaped inner surface 33 formed at least partially between the frusto-conical outer surface 8 and the outer ring 13 connected to the slug 1 at least in part by a drive shaft 16, with an angle of increase of both The cones are aligned identically and the conical permeable cross-section of the annular gap 80 can be adjusted relative to each other by offsetting the outer ring 13 and the inner ring 1 ±. Thus, it is possible for the diameter of the annular gap 80, i.e. of the conical surfaces or of the truncated conical surfaces, to be increased or decreased in the conveying direction 16. In an exemplary embodiment, an increasing diameter is preferred.

Relatively displaceable outer ring 18 and inner ring 14 relative to each other in the direction of the slug axis 88 can be accomplished by providing a corresponding adjustability of the outer ring 15 and / or inner ring 14. Adjustability of outer ring 15 has the advantage that the outer ring 13 can be externally easier to reach and control. The displaceability of the inner ring 14, which, for example, is mounted on the drive shaft 18, which passes through the conveyor slug 8, has the advantage that the inner ring 14 can be slidable on the drive shaft 18 or can be moved together with the drive shaft 18 relative to the outer ring i £.

A screw press for recovering vegetable oil from an oil-containing material has been described. In the press, the material is fed substantially as it was inserted and uncompressed to the location of the nozzle adapted to press the oil by means of a conveying slug g. In order to increase the pressing power, at least two sub-conveying slugs are connected in a consecutive manner on one shaft, in respect of the shape of the screw thread, between which one intermediate nozzle point is connected in each case.

Claims (5)

PATENT Claims w Vi-W4 / 1. A screw press for obtaining vegetable oil with a transport slug. which transports oil containing feedstock, for example, oil seeds or oilseed substantially fed and uncompressed to the location of an oil-jet nozzle, and with a slug housing in which the conveyor slug is supported, which is essentially formed in a cylinder of cylinders and has oil outlet openings for discharging at the nozzle location of the pressed oil, the oil outlet openings being spaced apart from the nozzle location in the housing region when viewed in the conveying direction of the snail, characterized in that they are as one piece on the drive shaft (13) two or more snail stages (9, 10) connected consecutively, which are substantially identical with respect to the conveying volume of the snail's threads (11) and their pitch and between them there is an intermediate nozzle (7) having an annular gap (30) ) and that, when viewed in the transport direction (16), they are spaced from each intermediate point (7) of the nozzle at the periphery a conveying snail (S) in the snail housing (1) of the oil drain (17, 50). 3. A screw press as claimed in claim 1, characterized in that. The annular gap (30) is formed at the intermediate point (7) of the nozzle as a gap between the two coaxial surfaces of the truncated cone. Screw press according to claim 3, characterized in that the diameter of the annular chamber 14 Ry-ΜV ry (30) in the transport direction (16) increases. Screw press according to at least one of Claims 1 to 5, characterized in that the annular gap (30) of the intermediate nozzle location (7) is formed between the inner ring (14) which is connected to the conveyor slug (8). optionally by its drive shaft (13) and having a conical outer surface (33), and between an outer ring (13), which is connected to a snail housing (1) and having a conical inner surface (33), the angles of increase of both cones in the same direction they increase or decrease and that the permeable cross-section of the annular gap (30) is operable by relative relative displacement of the two rings (13, 14). Screw press according to one of Claims 3 to 4, characterized in that the inner ring (14) is inserted relative to the outer ring (15) relatively displaceably on the drive shaft (13), optionally with the drive shaft (13) in the axial direction. (33) slug. Screw press according to one of Claims 3 to S, characterized in that the outer ring (15) is mounted relative to the inner ring (14) relative to the sliding box (D) or the adjacent part of the sliding box (1).