EP2064008A1 - Method and blank for producing a screw-tube conveyor and screw-tube conveyor produced in this way - Google Patents

Abstract

The invention relates to a method and a blank for producing a screw-tube conveyor in the form of a cylindrical rotary tube (110) with an internal screw spiral (120) for conveying and mixing a bulk material. To simplify the method and to create even long screw-tube conveyors with small diameters in an relation to their length, it is proposed according to the invention first to produce a one-piece blank, which comprises a base portion in the basic form of a parallelogram and having laterally mounted fins. In a second method step, the fins are then bent, preferably by 90°, with respect to the base portion. In a third method step, the base portion (112) is then bent along bending lines (115i) in such a way that the base portion forms a helical casing portion (111) of the rotary tube (110) and the previously bent-round fins (122) form segments of the screw spiral (120) arranged inside the rotary tube (110). The invention also relates to a screw-tube conveyor produced in this way.

Description

 METHOD AND CUTTING FOR MANUFACTURING A SCREW CONVEYOR AND THE like

MANUFACTURED SCREW CONVEYOR

The invention relates to two alternative methods and blanks for producing a screw tube conveyor in the form of a cylindrical rotary tube with an inner spiral screw for conveying and mixing a bulk material. Raw tending conveyors are used to treat bulk goods, especially in the pharmaceutical or food industry.

Screw tube conveyors are basically known in the art and e.g. defined in DIN 15 201. In addition to the continuous production of the bulk material, screw-tube conveyors always also serve for thorough mixing thereof; In many cases, they can also be used for surface design, for surface coating or for heat treatment of the bulk material. In contrast to so-called screw conveyors, which are not the subject of the invention, screw conveyor for the sole promotion of bulk material are less efficient.

In the traditional manufacture of a screw tube conveyor, a screw flight is fitted to the inside of a cylindrical rotary tube, e.g. welded, soldered, etc. by crawling people, welders, in the screw conveyor and there perform the joining work at the transition between the rotary tube and screw helix.

The length of the joining zone between the rotary tube and the screw helix is many times longer than the overall length of the screw tube conveyor. The joining zone is traditionally formed by a very long weld, possibly double-sided, which represents a significant cost factor in the manufacture of the screw conveyor. In order for such joining work to be possible at all, both the outer diameter and also the inner diameter of the rotary tube must have certain minimum values. The inside diameter of the rotary tube is determined by the height or depth of the screw flights. Also, the screw pitch must not be too small, in order to ensure the accessibility of the joining zone between the rotary tube and screw helix.

Based on this prior art, the invention has for its object to provide a method and a blank for producing a screw tube conveyor, which reduce both the time and cost of manufacturing the screw conveyor during its production very significant.

This object is achieved according to a first embodiment by the method claimed in claim 1. This method is characterized by the following steps:

a) producing a one-piece blank in the form of a basically parallelogram-shaped base section with at least one lateral tab, wherein the basically parallelogram-shaped base section is defined by a first and a second pair of respective opposite parallel edges, wherein on the base section bending lines between the second pair of Edges and parallel to these edges are provided extending and wherein the at least one tab is integrally formed on at least one of the edges of the first pair at the level between two adjacent bending lines or between one of the edges of the second pair and an adjacent bending line with the base portion;

b) folding the tab about a tab angle Y with respect to the base portion along the edge at which the tab is integrally connected to the base portion; and c) buckling of the base portion along the bending lines in each case by a jacket bending angle δ such that the base portion forms a helix and polygonförmi- gene shell portion of the rotary tube and the previously folded tab on the segment of the inside of the rotary tube screw flight.

In the first exemplary embodiment, a form-fitting transition between the inside of the rotary tube and the screw helix is ensured by the claimed one-piece formation of the blank in the form of the parallelogram-shaped base section with integrally formed tabs which are later bent over as segments of the helical screw Apart from the buckling of the tabs, joining operations for establishing the connection between the rotary tube and the screw helix inside the screw tube conveyor would be required. By bending over the tab relative to the base portion, a niche-free transition between the cylindrical rotary tube and the screw helix is formed, so that no bulk material can advantageously settle therebetween.

The above object is achieved according to a second embodiment by the method claimed in claim 2, which is characterized by the following steps:

a) producing a one-piece blank comprising a base section 112 'in the form of a convex quadrilateral, preferably in the form of a parallelogram, with at least one lateral tab, the basically parallelogram-shaped base section being defined by a first and a second pair of respectively opposing, generally parallel edges; wherein bending lines are provided on the base portion between the second pair of edges and parallel to these edges, and wherein the at least one tab is at least one of the edges of the first pair at a height between two adjacent ones of the bending lines or between one of the edges of the second pair and an adjacent bending line is formed integrally with the base portion; b) folding the tab by a tab angle v 'relative to the base portion along the edge at which the tab is integrally connected to the base portion;

c) buckling of the base portion along the bending lines in each case by a jacket bending angle δ 'so that the base portion forms a helical shell portion of the rotary tube and the previously folded over tab forms a radially outwardly standing comb on the helical shell portion;

d) telescoping the helical skirt portion and a helical screw surface to the screw tube conveyor such that the comb overlies the screw surface at its periphery and a portion of the screw surface not covered by the comb represents the screw flight inside the screw tube conveyor; and

e) assembling the helical surface and the crest at the overlapping regions to the auger tube conveyor.

The two claimed methods for producing the screw conveyor by folding over the tabs and kinking the base portion advantageously also allow the production of relatively long screw tube with relatively small clear diameters, because, as I said, joining work inside the screw conveyor for connecting the screw spiral with the rotary tube no longer required are.

Because in both methods the screw conveyor is produced over a desired overall length so that individual passages or longitudinal sections are merely joined by spot welding, the risk of distortion is advantageously evident in the screw tube conveyors produced in this way, unlike the screw tube conveyors traditionally produced with helical weld seams lower. The screw tube conveyor produced by the two methods claimed comprises a rotary tube with a polygonal cross section due to the multiple kinked surface of the casing. This has the advantage that the mixing of the bulk material when rotating the screw conveyor relative to a rotary tube with a circular cross-section is significantly improved. In particular, this can advantageously be dispensed with by the installation of additional mixing elements, such as wings, paddles, plowshares, etc.

In both embodiments of the claimed method is between each two adjacent tabs on the base portion a V-shaped notch with an opening angle α between 0 ° and 180 ° provided.

Depending on whether a lateral bending angle δ, by which the base section is bent along a bending line, is smaller, equal to or greater than the opening angle α, the following constellations arise in the interior of the rotary tube in the first exemplary embodiment: If the lateral bending angle δ is equal to the opening angle α, so are the two adjacent tabs in the screw conveyor produced by the claimed method "on impact"; there is then no overlap of the two adjacent tabs. When the sheath bending angle δ is smaller than the opening angle α, a V-shaped notch or space remains between the two adjacent tabs. The mentioned gap has the advantage that bulk material can pass through the gap from a passage in an adjacent course of the screw tube conveyor, whereby a better mixing of the bulk material is achieved. If the jacket bending angle δ is greater than the opening angle, the two adjacent tabs overlap after bending along the bending lines.

In the second embodiment, the opening angle α is required to allow buckling of the base portion so that the tabs are radially outward.

The Laschenknickwinkel Y is preferably 90 ° in both embodiments; the screw helix is then aligned in the interior of the screw conveyor perpendicular to the lateral surface of the rotary tube. Advantageously, the material is punched in both embodiments for cutting to produce the blank, cut with a laser beam or milled.

The above object is further achieved by a blank for producing the screw tube conveyor. The advantages of this blank substantially correspond to the advantages mentioned above with reference to the claimed method

Moreover, it is advantageous that the blank is initially formed flat with the base portion and the at least one tab.

Furthermore, it is advantageous that metal sheets with a thickness of 0.3 to 3 mm can be selected for the blank and thus for the screw tube conveyor. Such thin sheet metal can not be used for traditionally produced screw tube conveyors because it does not permit high temperatures such as occur in long welds. In screw tube conveyors, which are produced according to the inventive method, but it is very useful because long welds are not mandatory; the use of such a thin metal sheet has the advantage that the heat capacity of the screw conveyor is low, and so that the duration of thermal balancing effects between bulk material and auger conveyor can be kept as short as possible when starting treatment processes.

If a plurality of tabs are formed on one and the same edge of the base portion, they may be formed either adjacent or only occasionally in the sense of non-adjacent there. If two tabs are not adjacent, this has the effect that even with the assembled auger tube conveyor between these two tabs a gap remains. This gap then has the same advantageous effect as the above-mentioned V-shaped gap between two adjacent tabs, which then arises when the Mantelknickwinkel is smaller than the opening angle between the two tabs. So that all adjacent flaps or segments of the screw helix in the interior of the screw conveyor "abut" against each other and thus form a spiral helix without gaps and without overlaps, it is necessary that the opening angle α of the V-shaped notches between each two adjacent tabs and the both boundary angles ßi and ß2, which are measured in each case between the outer tabs and plumb lines on the edge of the base portion, are dimensioned so that a _t + ßi + ß ₂ together are 360 ° and that, as already mentioned above, the lateral bending angle δ , are formed according to the opening angles α. If said angle sum of α, + βi + β _{2 is} smaller than 360 ° measured over a length of the base portion corresponding to the circumference of the rotary tube, the adjacent tabs are at least partially overlapped in the assembled screw tube conveyor. In the other case, if the angle sum is greater than 360 °, the said gaps between the adjacent tabs arise.

The formation of the edges opposite the base portion of the trapezoidal lugs in the form of a circular arc has the advantage that in the screw conveyor produced according to the invention a tubular opening in the form of a circular cylinder is formed with a clear radius approximately the radius of the circular arc.

In the method according to the invention, the tabs can be arranged on two opposite edges of the base portion. After bending the tabs around the respective lashing angle y and the subsequent buckling of the base section along the bending lines, the resulting helical sections of the screw conveyor (aisles), depending on the design of the parallelogram base section, ie depending on the intended increase for the screw conveyor, either immediately adjacent, ie be touching, or spaced from each other. If the gears of the screw conveyor are in direct contact with each other at a suitable pitch, then the previously folded tabs of the individual gears are at least partially adjacent to one another. It is then recommended that these tending to fold the folded tabs together, for example by a spot weld; In this way, the screw conveyor is substantially stabilized. In contrast to the prior art, the spot welding can be done at the edge of the breakthrough, ie at the easily accessible upper edge of the tabs; it does not need to take place at the transition zone, which is much more difficult to access, between the rotary tube and the spiral screw.

In general, the production of screw tube conveyors, even with a large overall length in the two methods according to the invention, is substantially facilitated by the fact that individual (partial) longitudinal sections can be prefabricated and later only have to be joined together. The joining takes place in each case at the edge or connection points of two adjacent (sub) length sections and is particularly simple if the respectively attached longitudinal section in turn is not too long (so that the connection point is accessible from the opposite end of the longitudinal section) and if its diameter or radius is as large as possible.

In principle, the screw conveyor with the method according to the invention can also be produced with a blank in which the tabs are formed only on one of the edges of the parallelogram-shaped base section. The thickness of the helix is then formed only by the thickness of a single tab, but not by the thickness of two adjacent tabs, as in the previous case. In addition, it is then necessary for the helical jacket sections of the rotary tube formed by buckling of the base section to be joined together by a helical weld seam. Although the mantle surface of the rotary tube is then easily accessible, the production of the weld is still costly in this case due to the relatively large length of the weld, which is why this embodiment is only suboptimal.

If it is desired that the rotary tube produced by the method according to the invention is just limited at at least one of its two ends, for example for mounting a flange, then it is necessary for the two opposite edges of the first pair of edges are cut at an acute angle tapering at this end.

Finally, the above object is achieved by a screw tube conveyor. The screw tube conveyor produced by the method and the blank according to the invention has the advantages mentioned above with reference to the method and the blank.

It is advantageous that the screw conveyor can have one or more passages. To achieve a desired greater overall length, it is possible to prefabricate several lengths of the screw tube conveyor with the inventive method and then join these lengths to the screw conveyor in the desired overall length.

It is advantageous if the screw tube conveyor has at least one of its ends a flange, which is preferably attached to the folded tabs in the region of one end of the screw conveyor tube, e.g. is welded. The flange at one end of the screw tube conveyor may e.g. be formed in the form of a gear, which is for engaging the screw conveyor with a, driven by a drive means pinion engageable. At its other, possibly the gear opposite end, a further flange may be provided, which is designed as a raceway. The race is then used for rotatably supporting the screw conveyor on preferably conical rollers. The conical design of the rollers is used to exert an axial pressure on the auger tube conveyor on an existing abutment.

Finally, it is advantageous if the screw tube conveyor coated inside, preferably enamelled, because then with the coating possibly existing narrow gaps or impact gaps between two adjacent tabs of the screw helix can be closed.

The description is a total of 12 figures attached, where FIG. 1 shows a screw tube conveyor produced according to the invention;

FIG. 2 shows a blank according to the invention for producing the screw tube conveyor; according to a first embodiment

3 shows a blank of Figure 2 with folded tabs;

Figure 4 shows a blank with folded according to the first embodiment straps and partially kinked base section;

FIG. 5 shows a first gear of the auger tube conveyor produced by the bending of the flaps and the base section according to the invention with a second gear approach, wherein the flaps in the region of the second gear approach and the adjacent flanges of the first gear are initially still spaced from one another;

Figure 6 is a screw tube conveyor of Figure 5, wherein the tabs of the approach of the second gear and the adjacent tabs of the first gear are connected to each other by a spot weld;

FIG. 7 shows a screw tube conveyor according to the invention produced according to the first embodiment with flanges in the form of a pinion and in the form of a race;

8 shows a blank for the production of the screw tube conveyor according to a second embodiment;

9 shows a blank with folded according to the second embodiment tabs and partially folded over base portion;

FIG. 10 shows a helical screw surface; FIG. 11 shows a screw tube conveyor assembled according to the second exemplary embodiment; and

FIG. 12 shows a screw conveyor according to FIG. 11 with a cylindrical housing

shows.

The invention will now be described in detail in the form of embodiments with reference to said figures. In the individual figures, the same technical elements are designated by the same reference numerals. A reference number without a comma refers to a first embodiment, while a reference number with apostrophes refers to a second embodiment of the method according to the invention for the production of a screw tube conveyor.

Figures 1 and 8 relate to the invention in general and relate to all embodiments. In contrast, Figures 2-7 relate to the first and Figures 9-12, the second embodiment.

FIG. 1 shows a screw tube conveyor 100 produced by the method according to the invention. It comprises a cylindrical rotary tube 110 with an internal screw flight 120 for conveying and mixing a bulk material. The bulk material is introduced into the screw conveyor 100 at one end of the screw conveyor via an inlet 180 and, after it has been transported in the direction of transport R by rotating the screw conveyor, leaves it via an outlet 190.

The method according to the invention for producing the screw tube conveyor shown in FIG. 1 will be described in more detail below with reference to FIGS. 2 to 8. The method according to the invention provides, in a first step, for the production of a one-piece blank, from which the screw tube conveyor is later formed. The blank is preferably made of flat sheet metal having a thickness of 0.3 to 0.8 mm by punching this sheet, for example, according to the contour of the blank or cut by means of a cutting device, such as a laser beam source.

The blank for the inventive method consists, as shown in Figure 2, of a parallelogram-shaped base portion 112 laterally integrally formed thereon tabs 122. The base portion is due to its parallelogram-shaped configuration by a first pair of opposite edges 1a, 1b and by a second pair defined by opposite edges 2a and 2b. Bend lines 115 are provided on the base portion, extending between the second pair of edges 2a, 2b and parallel to these edges. The lugs 122 integrally formed on the side of the base section are respectively formed between two adjacent bending lines or between one of the edges 2a, 2b of the second pair of edges and a respectively adjacent bending line 115, = ₁ , 115j = ₉ on the base section.

The tabs 122 may be provided on both edges 1a and 1b of the first pair of edges or on only one of these edges. Furthermore, the tabs can be either adjacent to each of these margins or only isolated, in the sense of not adjacent to each other. In the event that two adjacent tabs are provided on one of the edges, it is necessary to provide a V-shaped recess 117 between these two tabs, which in each case acts on the jointly assigned bending line 115; is aligned and the two adjacent tabs separated from each other. The opening angle α between the two adjacent tabs can be between 0 ° and 180 °. In Figure 2, the tabs are all exemplified trapezoidal. The legs 122a and 126a of the offset to the base portion 112 - opposite trapezoidal tabs 122, 126 lie on a straight line g. This has the advantage that a cutting tool for cutting the legs 122a, 126a only lifted to bridge the base portion, but not curved, which simplifies the production of the blank is simplified. Not all opening angles α, of a blank have to be the same. The same applies to the lashing buckling angle v, and the sheath bending angle δj.

After the first step of the process according to the invention just described, i. 2, this blank is processed in a second method step, as shown in FIG. 3, such that the tabs 122 are each separated by a tab angle v relative to the base section 112 along that edge 1a, 1b at which the tab is integrally connected to the base portion, is folded over. The structure shown in FIG. 3 then arises.

Finally, in a third method step, the structure shown in FIG. 3 and, in particular, the base section 112 along the said bending lines 115j are each bent by a lateral bending angle δj.

In Figure 4, the base portion is first kinked only two times, while it is shown kinked in Figures 4 and 5 at all bending lines 115j. As shown in Figures 5 and 6, the original base portion of the blank then forms a helical shell portion 111 of the rotary tube 110 and the previously folded tabs 122 then form respective segments of the screw helix 120 disposed inside the rotary tube.

In FIGS. 5 to 7 it is clear that the base section 112 must be parallelogram-shaped if the screw tube conveyor produced according to the invention is to have a pitch> 0, as shown in FIGS. 5 to 7.

It can also be seen in FIGS. 5 and 6 that the individual adjacent tabs 122, which have previously been folded over, are now arranged side by side "in abutment" and thus form the spiral helix 120. In order for the respective adjacent tabs to abut each other, it is necessary for the individual jacket bending angles δj shown in FIGS. 3 and 4 to be equal to the opening angles α of the V-shaped notches 117 between two adjacent tabs also shown there. Furthermore, it is necessary that as illustrated in Figure 2, the adjacent flaps on one of the edges 1a, 1b of the base portion 112 over a length L _u, which corresponds to the circumference of the rotary tube 110, satisfy the following conditions: The opening angle α, with i = 1 - 9 of the V - shaped incisions 117 between each two adjacent tabs add up together with the two boundary angles ßi and ß ₂ together 360 °. In this case, the boundary angles ßi and ß ₂ respectively between the legs of the outer flaps and the plumb lines Li, L ₂ , which are perpendicular to the edges 1a, 1b of the base portion 112, measured.

If the said angle sum α, + βi + β _{2 is} smaller than 360 ° and the associated jacket bending angles δ at the associated bending lines 115, in the individual case, are greater than the respective opening angles α _h, then an overlapping of two occurs in these individual cases adjacent tabs in the formation of the screw tube conveyor (not shown).

Alternatively, a jacket bending angle δ may be smaller than an associated opening angle α; This then has the consequence that during the manufacture of the screw conveyor between the two lugs involved a gap or a V-shaped gap remains. Bulk material may pass through the gap, which may contribute to improved mixing of the bulk material. Such a gap is designated in FIG. 6 by the reference symbol SP.

When a tubular aperture 130, as shown in FIG. 6, is desired inside the screw tube conveyor, the edges 124 of the trapezoidal tabs 122 opposite the base portion must be cut in the form of a circular arc. The position of the circular arc with respect to the base portion 112 and the radius r of the circular arc are respectively suitably to choose. If the screw tube conveyor has more than one gear, as shown in Figures 5 to 7, then it is advantageous that parallel to each other and adjacent tabs 122, = ₁ , 122, = _{10 are} joined together. Advantageously, this assembly takes place in the form of a spot welded joint 129. FIG. 7 shows an external view of a screw tube conveyor produced according to the invention. The screw tube conveyor 100 shown there consists of a plurality of longitudinal sections produced according to the invention, which are joined together in each case at the connection points Vi-V ₄ in the axial direction. The individual longitudinal sections Ti - T ₄ each have only a relatively short axial extent, whereby an assembly of the individual courses of a longitudinal section with each other at the parallel tabs, for example by the mentioned point welds, is simplified.

It can be seen in FIG. 7 that, at the end regions E of the screw conveyor, the edges 1a, 1b of the base section 112, which after folding along the bending lines form the lateral surfaces of the rotary tube 110, deviate from the basic parallelogram shape. Tapered tapered. This makes it possible for the rotary tube 110 to terminate in a plane perpendicular to the axial orientation of the rotary tube. This flat conclusion at the two ends of the screw conveyor 100 allows there to attach a flange, which is preferably connected to the existing there, also in the said plane extending tabs. The flange 140 may be in the form of a gear, as shown for the left end of the screw tube conveyor 100 shown in FIG. This gear is for rotating the screw conveyor 100 with a pinion 151 engageable. The pinion is part of a drive device 150 for driving the screw tube conveyor 100. The flange 140 may also be formed in the form of a race 142, as shown for the right end of the screw tube conveyor 100 shown in FIG. The race is used there for rotatably supporting the screw conveyor 100 on preferably conically shaped rollers 160. The gear and the race are preferably formed concentrically and coaxially with the same radius.

Hereinafter, the second embodiment of the invention for producing the screw tube conveyor with reference to the figures 8 - 12 described in more detail. For the description of the figures, as far as possible, reference is made to analogous figures relating to the first exemplary embodiment, the same technical features being provided with the same reference numerals as the single one Difference that the reference numerals for the corresponding elements in the second embodiment have a single quote. The method according to the second embodiment comprises the following steps:

In a first step, a one-piece blank according to FIG. 8 is produced; In this regard, reference is made to Figure 2 and the associated description. The only difference between the blank according to the second embodiment and the blank according to the first embodiment is that the lateral tabs 122 'in the second embodiment are preferably convex in the form of a circular arc as compared to the first pair of edges 1a, 1b is indicated in Figure 8.

In a second step, the tabs 122 'are then bent 90 ° by a tab angle v' in relation to the base section 112 '.

In a third method step, the base section 112 'is then bent along the bending lines 115' j by a lateral bending angle δ 'in such a way that the base section forms a helical jacket section of the rotary tube 110', as shown in FIG. The previously folded over at least one tab 122 'then forms a radially outwardly standing comb 113' on the helical shell portion 111 '. As a result of this described bending of the base section, at least one passage of the rotary tube 110 'is formed; However, it can also be formed a plurality of parallel gears, as shown in Figure 11.

In a fourth method step according to the second embodiment, the helical jacket section 111 'and a helical screw surface 125' shown in FIG. 10 for producing the screw tube conveyor - as shown in FIG. 11 - are pushed into one another. The comb 113 'then overlaps or overlaps the screw surface 125' on its periphery and can be joined together there, preferably spot-welded. At the same time, that part of the helical screw surface 125 ', which is not covered by the comb, forms the helix 120' inside the screw tube conveyor. The screw tube conveyor produced according to the second embodiment offers - compared to the screw conveyor produced according to the first embodiment - the advantage that the joining of the tabs or the comb with the screw surface 125 'is very easy, because these areas are accessible from the outside. Therefore, a plurality of juxtaposed passages of the screw conveyor can be simultaneously assembled or manufactured in the screw conveyor produced according to the second embodiment, while the number of connectable in a single step operations is limited in the first embodiment, because of the local there only limited accessibility of the tabs to be connected in Inside the auger tube conveyor.

For hygienic reasons, the screw tube conveyor according to FIG. 11 can be packed, for example, into a cylindrical housing 170, see FIG. 12, whereby the comb projecting radially outwards is covered for a viewer. The housing 170 rests on the comb 113 'and is preferably joined together, e.g. soldered. This results in a helical cavity 172 between the housing 170, the comb 113 'and the base portion 112'. The cavity 172 is preferably formed e.g. evacuated for insulation purposes; It is then a thermal treatment of the bulk material inside the screw conveyor more efficient possible. The comb 113 'supports the housing 170 against the base portion 112', even with negative pressure in the cavity 172 due to the vacuum. It may also be possible to simply solder the housing 170 with the comb 113 'under vacuum. The flanges and the pinion can also be mounted on the screw conveyor produced according to the second embodiment, as shown by way of example in FIG. 7 for the screw tube conveyor produced according to the first exemplary embodiment.

Claims

claims

1. A method for producing a screw tube conveyor (100) in the form of a cylindrical rotary tube (110) with internal screw helix (120) for conveying and mixing a bulk material, comprising the following steps:

Forming a one-piece blank comprising a base portion (112) in the form of a convex quadrilateral having at least one lateral tab (122), said base portion being defined by first and second pairs of respective opposite edges ((1a, 1b); (2a, 2b) Bending lines (115 'i) are provided on the base portion between the second pair of edges (2a, 2b) and parallel to these edges, and wherein the at least one tab (122) is provided on at least one of the edges (1a , 1b) of the first pair is formed integrally with the base portion at a height between two adjacent ones of the bend lines or between one of the edges (2a, 2b) of the second pair and an adjacent bend line (115i);

Folding over the tab (122) by a tab angle Y with respect to the base portion (112) along that edge (1a, 1b) at which the tab is integrally connected to the base portion; and

Buckling of the base portion (112) along the bending lines (115 i) in each case by a jacket bending angle δ so that the base portion a helical shell portion (111) of the rotary tube (110) and the previously folded tab (122) a segment of which is arranged inside the rotary tube Helix spiral (120) forms.

2. A method for producing a screw tube conveyor (100 ') in the form of a cylindrical rotary tube (110') with internal screw helix (120 ') for conveying and mixing a bulk material, comprising the following steps:

Fabricating a one-piece blank comprising a base portion (112 ') in the form of a convex quadrilateral having at least one lateral flap (122'), the base portion being defined by first and second pairs of respective opposite edges ((1a, 1b); , 2b)), wherein on the base portion bending lines (115 'i) are provided extending between the second pair of edges (2a, 2b) and parallel to these edges, and wherein the at least one tab (122') is provided on at least one of the edges (1a, 1b) of the first pair are integrally formed with the base portion at the height between two adjacent ones of the bending lines or between one of the edges (2a, 2b) of the second pair and an adjacent bending line (115 'i);

Kinking of the tab (122 ') by a Laschenknickwinkel γ ^! opposite the base portion (112 ') along the edge (1a, 1b) at which the tab is integrally connected to the base portion;

Buckling of the base portion (112 ') along the bending lines (115' j) in each case by a jacket bending angle δ 'so that the base portion a helical shell portion (111') of the rotary tube (110 ') and the previously folded over tab (122') forming a radially outward ridge (113 ') on the helical skirt portion (111');

Telescoping the helical shell portion (111 ') and a helical screw surface (125') to the screw tube conveyor so that the crest (113 ') overlies the helical surface at its periphery, and that a portion of the helical surface not covered by the crest represents the helical coil inside the helical tube conveyor; and

Joining the helical surface and the comb at the overlapping regions to the screw tube conveyor (100 ¹ ).

3. The method according to claim 2, characterized in that the screw tube conveyor (100 ¹ ) is installed in a preferably cylindrical housing.

4. The method according to any one of the preceding claims, characterized in that for the Laschenknickwinkel y, y 'preferably applies: y = 90 ° and y' = 90 °.

5. The method according to any one of the preceding claims, characterized in that the production of the blank is carried out by punching the material for the blank or, for. with a laser beam, is cut.

6. blank for producing a screw tube conveyor (100, 100 ') in the form of a cylindrical rotary tube (110, 110') with internal screw helix (120, 120 '), comprising: a base portion (112, 112'), which by a first and a second pair of respective opposite edges ((1a, 1b); (2a, 2b)), and wherein on the base portion bend lines (115 i, 115 'i) between the second pair of edges (2a, 2b) and are provided extending parallel to these edges; and at least one tab (122, 122 ') disposed on at least one of the edges (1b) of the first pair of edges at a height of two adjacent the bending lines or between one of the edges (2a, 2b) of the second pair and an adjacent bending line (115 i, 115 'i) is integrally connected to the base portion.

A blank according to claim 6, characterized in that the blank is formed with the base portion (112, 112 ') and the at least one tab (122, 122') lying in a plane before it is bent to the screw tube conveyor.

8. Blank according to one of claims 6 or 7, characterized in that the blank made of metal, preferably made of sheet metal with a thickness of 0.3 - 3 mm.

9. Blank according to one of claims 6 to 8, characterized in that the tabs (122, 122 ') on the at least one of the edges (1a, 1b) are at least partially adjacent or only occasionally formed in the sense of non-adjacent.

10. blank according to one of claims 6 to 9, characterized in that - if at least two adjacent tabs are formed on one of the edges of the base portion - each two of the adjacent tabs by a on the commonly assigned bending line (115 i, 115 'i) aligned recess (117, 117 ') are separated from each other.

11. Blank according to one of claims 6 to 10, characterized in that the at least one tab (122, 122 ') is trapezoidal.

12. blank according to claim 11, characterized in that the base portion of the opposite edge (124, 124 ') of the trapezoidal tab (122, 122') in the first embodiment in the form of a concave or in the second embodiment in the form of a convex circular arc is cut.

13. A blank according to any one of claims 6 to 12, characterized in that the tabs (122- _1, 122, ₁₀₎ in the first embodiment, on the two opposite edges (1a, 1 b) of the first pair of edges are arranged such that they are after a later buckling of the tabs relative to the base portion and a later buckling of the base portion along the bending lines to two adjacent turns (gears) of the screw conveyor at least partially abut each other.

14. A blank according to any one of claims 6 to 13, characterized in that at least one end region (E) of the base portion (112) which forms an end of the screw conveyor after the bending of the base portion along the bending lines, the two opposite edges (1a, 1b) of the first pair of edges are tapered at an acute angle.

15. screw tube conveyor (100) in the form of a cylindrical rotary tube (110) with internal screw helix (120), made from the blank according to one of claims 6 to 14 by the method according to one of claims 1 to 5.

16. auger tube conveyor (100) according to claim 15, characterized in that the auger conveyor has a plurality of passages (G _h ).

17. auger tube conveyor (100) according to claim 16, characterized in that the individual passages (G _h ) of the screw conveyor are at least partially connected to each other by the first Embodiment then the adjacent inside the auger tube conveyor lugs (122i, 122i ₀ ) joined together, preferably (point) welded together, or by in the second embodiment, then adjoining the outside of the screw conveyor parts comb, periphery of the screw surface, comb are joined together.

18, screw conveyor (100) according to any one of claims 16 or 17, characterized in that the individual passages (G _h ) of the screw conveyor are at least partially interconnected by a helical weld (S) on the shell of the screw conveyor.

A screw tube conveyor according to any of claims 15-18, characterized in that the screw tube conveyor has a flange (140) at at least one of its ends which is preferably fixed to the folded tabs in the region of the end of the screw tube conveyor, e.g. welded, is.

20. auger tube conveyor according to claim 19, characterized in that the flange (140) is formed at one end of the screw conveyor in the form of a gear which for rotating the auger conveyor with a by a drive means (150) driven pinion (151) is engageable ,

21, screw conveyor (100) according to any one of claims 19 or 20, characterized in that the flange is formed on an optionally opposite to the gear end ais race (142) for rotatably supporting the screw tube conveyor (100) on preferably conically shaped rollers (160). ,

22, screw conveyor (100) according to any one of claims 15 - 21, prepared by the method according to one of claims 2-5, characterized by a cavity 172 between a housing 170, the comb 113 'and the base portion 112', wherein cavity 172 preferably is evacuated.