SE516633C2 - Headbox for delivering jet of stock to forming zone for wet-forming fiber web, has mounting arrangement comprising oblong engagement bodies received in oblong recesses provided in upstream end portion of vane(s) - Google Patents

Abstract

A headbox includes a mounting arrangement for detachably mounting an upstream end portion of vane(s) in the headbox. The mounting arrangement comprises an engagement member and an elongate structural element. The engagement member comprises oblong engagement bodies. The upstream end portion of the vane is provided with oblong recesses for receiving the engagement bodies. A headbox for delivering a jet of stock to a forming zone in a former for wet-forming a fiber web comprises a slice (8) having a chamber (12) and an opening (15). A turbulence generator (7) is provided for supplying stock(s) to the slice chamber. An mounting arrangement is provided for detachably mounting the upstream end portion (25) of vane (21) in the headbox. The mounting arrangement comprises an engagement member (26) and an elongate structural element (27). The engagement member is connected to the vane at the upstream end portion. The elongate structural element has a longitudinal groove, which opens at its opposing ends for receiving the upstream end portion of the vane and the engagement member, to secure the vane in the machine direction. The engagement member comprises oblong engagement bodies. The upstream end portion of the vane is provided with oblong recesses of predetermined length. The recesses are arranged at predetermined distance from each other, and extend parallel with the upstream edge of the vane at a predetermined distance. They are adapted to receive the engagement body for detachably mounting the engagement body in the upstream portion of the vane.

Description

- an engaging means connected to the wing at said upstream end portion, and - an elongate structural member having a longitudinal groove open at its opposite ends for receiving the upstream end portion of the wing. and its engaging means for fixing the wing in the machine direction.

In a known construction of engaging means, which is used in practice, the engaging means consist of engaging pins, which are generally referred to as rivets. The rivets are arranged in holes in the upstream end portion of the wing and have perpendicularly projecting end portions on both sides of the wing for cooperating with a groove in a structural element, e.g. a mounting strip of the turbulence channel group, so that the wing is fixed in the machine direction. SE 9800642-2 describes a headbox, the wings of which are mounted by means of engaging pins, which are enclosed by a sleeve of resilient material to be able to move laterally under the influence of forces from the side walls of the groove, which forces arise during wing mounting in the mounting strip or the like.

Such rivets with or without sleeves must be made especially for this purpose and in a special way.

The work of mounting the rivets in the carefully designed holes in the wing is time consuming. The arrangement of rivets for mounting the wing will therefore be costly. When the wing is mounted at the turbulence channel group, the groove is left open towards the nozzle chamber between the positions of the rivets so that there is a risk that fibers will accumulate in the groove between the rivets, which fiber accumulations can cause difficulties in disassembling the wing from the headbox.

A wing consisting of a plastic material, e.g. fiberglass-reinforced epoxy plastic, absorbs moisture from the environment while it is being stored and transported. Even after mounting in the headbox, it will absorb moisture from the surroundings, which now consists of the stockings. The wing has a tapered thickness in the machine direction so that the downstream part is thinner than the upstream part. This means that the saturation in moisture occurs earlier in the thinner part than in the thicker part, which means that the wing will elongate and thereby dent at its free downstream edge and the thin portion extending therefrom, while the thicker part works against such elongation because it still absorbs moisture. It will be appreciated that such dents interfere with the stock layers at the nozzle opening and upstream thereof.

Inlet boxes, which have devices for releasably mounting a wing in a turbulence channel group, are known from a large number of patents. The known devices have engaging means which are designed as continuous, transverse thickenings or the like in the upstream edge of the wing, see e.g. US 4,6l7,091, US 5,013,406, US 4,566,945, US 4,504,360 and EP 0 607 249 B1. The engaging means may also be fixedly mounted to the upstream edge or portion of the wing as shown in US 3,843,470, US 4,128,455 and US 4,445,974. The known engaging means, which are fixedly mounted to the wing or formed as thickenings, form a continuous joint in the groove in the turbulence channel group, whereby fibers cannot penetrate into the groove. However, the joint-forming engaging means can be easily damaged when the wing rotates due to pressure drops on one side of the wing, whereby the joint can hit the front edges of the groove, which can be relatively sharp. The object of the present invention is to provide a multilayer inlet carriage which has its or its wings mounted directly or indirectly to the turbulence channel group by means of a device which is easier to manufacture and mount and which can be manufactured at a lower cost than the known arrangements which include rivets. u a I ~ o o | u o! 10 15 20 25 30 35 516 ess 4 The inlet carriage as well as the device according to the invention is characterized in that the engaging means comprises a plurality of elongate engaging bodies and that the upstream end portion of the wing is provided with a plurality of elongate recesses of predetermined length, which recesses are arranged at predetermined distances from each other , extends parallel to the upstream edge of the wing at a predetermined distance therefrom and is arranged to receive at least one of said engaging bodies for releasably mounting the engaging body in the upstream end portion of the wing.

The invention is described in more detail in the following with reference to the drawings.

Figure 1 is a cross-sectional view in the machine direction of a portion of a multilayer headbox mounted to discharge a multilayer mold jet into a gap leading to a forming zone in a roll-type dual wire former.

Figure 2 is a sectional view of a device for direct mounting of one of the wings located in the nozzle chamber of the headbox in connection with a pipe group in the headbox according to figure 1.

Figure 3 is a sectional view of a device for indirect mounting of a wing at e.g. a pipe group.

Figure 4 is a plan view of a part of a wing of the headbox according to Figure 1.

Figure 5 is a side view of the wing of Figure 4.

Figure 6 is an enlarged portion of the wing of Figure 4 with an engaging member according to a first embodiment consisting of recesses in the wing and engaging tubes therefor. Figure 7 shows three engagement tubes for co-operation with one of the recesses according to Figure 6.

Figure 8 is a sectional view taken along line VIII-VIII of Figure 6 showing a bent tongue for receiving a short engagement tube of Figure 7.

Figure 9 is a plan view of a part of a wing with an engaging member according to a second embodiment.

Figure 10 is a sectional view taken along the line X-X in Figure 9.

Figure 11 is a plan view of a wing made with a circular arc-shaped downstream edge for mounting in this shape in the headbox with engaging means similar to that of Figure 6.

Figure 12 shows the wing according to figure ll in stretched form with the aid of the forces which the stock currents exert on the wing.

Figure 13 is a sectional view of a wing divided into two wing sections with a device similar to that of Figure 2 for direct mounting of the two wing sections to each other.

The headbox 1 schematically shown in Figure 1 is arranged to discharge a two-layer jet of stock into a gap 2, which leads to a forming zone in a double-wire former of the roll type. Only certain parts of the dual wire former are shown.

The double wire former comprises an inner forming wire 3 running in an endless loop, a rotatable forming roller 4 located inside the loop of the inner forming wire 3, an outer forming wire 5 running in an endless loop, and a rotatable breast roller 6 located inside the loop of the outer forming wire 5. 10 15 20 25 30 35 516 m.

The inlet carriage has a turbulence generator which defines a turbulence channel group 7, which in the embodiment shown in Figure 1 consists of a pipe group. Instead of a group of pipes, which is also referred to as a pipe package or tube bank, a block with continuously drilled channels can be used. The inlet drawer shown further has a nozzle 8 located downstream of the pipe group 7, which comprises a bottom part 9, a top part 10 and two ends 11, which extend between the bottom part 9 and the top part 10. The four mentioned construction elements 9, 10, 11 enclose between a nozzle chamber 12, which converges from its upstream end 13 in the direction of the stock stream and ends at its downstream end 14 in a nozzle opening 15, the width of which can be adjusted by rotating the top part 10 about an axis relative to the bottom part 9 by means of a suitable mandrel. adapter (not shown).

The pipe group 7 comprises two superimposed pipe sections 16, 17 for feeding two different stocks into the nozzle chamber 12, the lower pipe section 16 and the upper pipe section 17 each having three rows of tubes 18 arranged next to each other. The rows of pipes 18 extend across the machine direction. The pipe sections 16, 17 are separated by a mounting strip 19, which extends across the machine direction and which connects the pipe sections 16, 17 to each other. In the same way, two adjacent rows of pipes 18 are separated by similar mounting strips 19, which likewise extend across the machine direction and which connect the rows of pipes 18 to each other. The pipes 18 open with their outlet ends 20 directly into the nozzle chamber 12, and the said mounting strips 19 are located at these outlet ends 20. The pipe group 7 is connected at its upstream end to a feed system (not shown), which comprises two stockpiles and suitable flow spreaders for distributing each stock to the rows of pipes 18 in the associated pipe section 16, 17 and evenly distributing the stock within each row of pipes 18. canon: 10 15 20 25 30 35 516 ess ïï “= - In the embodiment shown, the headbox comprises five wings 21, of which the middle wing is a stock divider wing which divides the nozzle chamber 12 into a lower stock channel 22 and an upper stock channel 23. The lower stock channel 22 communicates with the lower pipe section 16 and the upper stock channel 23 with the upper pipe section 17. The said middle partition wing extends a distance past the nozzle opening 15. The other wings 21 are only turbulence vanes, which have their downstream ends located inside the nozzle. the vent chamber 12 at a predetermined distance from the nozzle opening 15, divides the stock channels 22, 23 into three sub-stock channels 24, which are joined in the respective stock channel 22, 23 upstream of the nozzle opening 15. The wings 21 are relatively rigid and consist of a metal material, usually titanium. , or a plastic material, usually glass or carbon fiber reinforced epoxy plastic. The thickness of the wing within the upstream end portion is normally in the range 3.0-4.0 mm.

The headbox 1 comprises a device for releasably mounting the upstream end portion 25 of each wing 21 either directly or indirectly at the turbulence channel group 7. The mounting device comprises an engaging member 26, which is connected to the wing 21 at its upstream end portion 25, and an elongate structural member 27. In the embodiment shown in Figures 1 and 2, the structural element 27 is formed by said mounting strip 19, which has an elongate groove 28 for receiving the upstream end portion 25 of the wing 21 and its engaging means 26 for fixing the wing 21 in the machine direction. The groove 28 is open at its spaced apart ends and has a side opening 29 facing the nozzle chamber 12. The side opening 29 has a width (perpendicular to the wing 21) which is slightly smaller than the engaging member 26 so that it is retained in the groove 28 and which is slightly larger than the thickness of the wing 21 so that it can be moved without friction along the side opening of the groove 28. u n nu n 10 15 20 25 30 35 516 633 ning 29 during assembly. The height of the groove 28 (perpendicular to the wing) is slightly larger than the engaging member 26 so that it can be moved along the groove 28 without friction during assembly. The wing 21 is suitably chamfered at its rear narrow side so that even when it rotates around the engaging member 26 it goes up or down free from the opposite walls of the groove 28.

In the embodiment shown in Figure 3, the structural element 27 is formed by a special connecting strip 30, with which the wing 21 is indirectly releasably mounted at the mounting strip 19. The connecting strip 30, which consists of metal, e.g. bronze, is as long as the width of the wing 21 and comprises a first, downstream engaging part 31, a second, upstream engaging part 32 and a web part 33 connecting these engaging parts. The first engaging part 31 is provided with an elongate, continuous groove 34 for receiving the upstream end portion 25 of the wing 21 and its engaging means 26 for fixing the wing 21 and the connecting strip 30 to each other seen in the machine direction. The groove 34 is open at its mutually facing ends and has a side opening 35 which faces in the machine direction. The side opening 35 has a width (perpendicular to the wing) which is slightly smaller than the engaging member 26 so that it is retained in the groove 34 and which is slightly larger than the thickness of the wing 21 so that it can be moved without friction along the side opening 35 of the groove 34 during assembly. . The height of the groove 34 (perpendicular to the wing) is slightly larger than the engaging member 26 so that it can be moved along the groove 34 without friction during assembly. Inside the groove 34 of the engaging member 26 there is a continuous elongate guide groove 36 for receiving the rear edge portion 37 of the wing 21. The guide groove 36 is located in line with the side opening 35 and has the same width as this. The second engaging portion 32, which has a substantially circular cross-section, is received in a continuous, elongate groove 38 in the mounting strip 19 for fixing the connecting strip 30 in the machine direction. The groove 38 is substantially similar to the groove 28 of the engaging member 26 of Figure 2. The groove 38 is thus open at its spaced apart ends and has a side opening 39 facing the nozzle chamber 12. The side opening 39 has a width (perpendicular to the wing 21) which is slightly smaller than the engaging part 32 so that it is retained in the groove 38. The height of the groove 38 (perpendicular to the wing) is slightly larger than the engaging part 32 so that it can be moved along the groove 38 without friction during assembly. The thickness of the web part 33 is slightly less than the width of the side opening 39, so that the entire connecting strip 30 together with the wing 21 becomes articulated around the bearing shaft of the round engaging part 32 in a hinge-like manner. In addition, the holding of the web part 33 to the thicknesses of 31, 32 is that the web part 33 itself becomes bendable. Thereby, thickness so small in the two engaging parts is ensured that the connecting strip 30 does not break at the web part 33, when a wing 21 is pressed away from its normal free-carried position due to a temporary pressure drop in one stock channel and / or pressure increase in that mold channel which is located on the other side of the wing 21.

The said engaging member 26 comprises a plurality of elongate engaging bodies 40. The upstream end portion 25 of the wing 21 is provided with a plurality of elongate recesses 41 extending parallel to the transverse upstream edge 42 of the wing 21 at a predetermined distance therefrom and arranged to receive at least one of said engaging bodies 40 for releasably mounting the engaging body 40 in the upstream end portion 25 of the wing 21. The recesses 41 are continuous in the thickness direction of the wing 21. In the embodiment shown in Figures 4-8, each recess has an elongate U-shape so as to form two parallel elongate grooves 43, 44, see Figure 6, and a short, transverse groove 45 joining them, which grooves delimit an elongate tongue 46. of predetermined width. n o u Q n o 4 o n u n 10 15 20 25 30 35 516 633 10 The recesses 41 are arranged at a predetermined distance from each other and in line with each other, ie. at the same distance from the upstream edge 42. The engaging bodies 40 are designed as elongate, straight engaging tubes or sleeves with axial, through holes 47. The circular engaging tubes 40 are adapted to be carried on the tongue 46 of the U-recess, which is bendable out to a position so that its free end becomes available to receive an engagement tube 40 as illustrated in Figure 8. In the embodiment shown in Figures 4-8, a first group of longer engagement tubes 40a and a second group of shorter engagement tubes 40b are used. Each such longer engagement tube 40a has two axially diametrically opposed grooves 48 having a circumferential width slightly greater than the thickness of the wing 21 to allow the engagement tube 40a to be slid a corresponding distance into the wing 21 so that the tongue 46 will extend through the slot-free rear end of the long engagement tube 40a. On the remaining free part of the tongue 46, two shorter engagement tubes 40b are then threaded out of the second group, which fill up the remaining part of the recess 41.

The distance between two recesses 41 corresponds to the length of the slotted part of the longer engagement tube 40a. It will thus be appreciated that after assembly, the engagement tubes 40 will form a continuous tube row, with the engagement tubes 40 lying end to end one after the other. The engagement tubes 40 have an outer diameter which is slightly smaller than the height of the groove 28 resp. 34 in the construction element 27 so that the row of tubes supported by the wing can be slidably displaced along the groove 28 resp. 34 in the mounting of the wing 21 in the structural element 27. In the embodiment according to Figure 2, the engaging tubes form a joint around which the wing can rotate. In the embodiment according to Figure 3, the engaging part 32 forms this joint function.

The engagement tubes suitably consist of an acid-resistant material and have a diameter in the range 6-10 mm and a wall thickness of about 1 mm. The longer slotted engagement tube has a length in the range of 40-100 mm, while the shorter engagement tube, when used, has a length in the range of 15-30 mm. The length of a recess is in the range 30-100 mm and the distance between two recesses is in the range 30-100 mm. The distance between a recess and the upstream edge of the wing is at least 6 mm, preferably at least 8 mm. It will be appreciated that the parameters mentioned are carefully adapted to each other so that sufficient pour strength is obtained between two adjacent recesses and between each recess and the upstream edge 42 of the wing.

In the embodiment according to Figures 9 and 10, the wing 21 is provided with a plurality of elongate recesses 50 of rectangular shape, which recesses 50 extend parallel to the upstream edge 42 of the wing 21 at a predetermined distance therefrom. The recesses 50, which are continuous in the thickness direction of the wing 21, are arranged at predetermined, equal distances from and in line with each other. They are completely open, ie. they lack said tongue.

The engaging bodies 51 are in the form of elongate straight engaging tubes, sleeves or solid rods having a width (diameter) and length slightly smaller than the recesses 50 so that the engaging bodies 51 can be easily inserted into the recesses 50 to be received therein. and held in a centered manner relative to the wing 21, i.e. equal parts of each engaging body 51 are located on the upper side and the underside of the wing 21. Each engaging body 51 is provided with a plurality of side supports 52 in the form of e.g. pins or pins located on both sides of the wing 21 to hold the engaging body 51 in the right, centered position to facilitate insertion of the engaging bodies 51 into the corresponding grooves of the structural member 27 together with the upstream end portion 25 of the wing 21.

Figure 11 shows a wing 21, which is made with a concave, circular arc-shaped downstream edge 53. The upstream edge. v o | a o c u ø of 10 15 20 25 30 35 516 633 12 54 may have a corresponding convex shape. The side edges 55 in relation to the coincidences can also be formed with an oblique direction in the machine direction as shown, i.e. radii to the concave, circular arc-shaped downstream edge 53. The engaging bodies 40 are designed and arranged in the same manner as those in Figure 6 to form a continuous joint. They extend in an arc of a circle concentric with the concave downstream edge 53. § denotes a minimum width of the groove 28 made in the structural member 27 to enable frictionless insertion of the engaging bodies 40 and the upstream end portion 25 of the wing 21 into the groove 28. along its entire length.

The wing 21 consists of a liquid-absorbent, fiberglass-reinforced plastic material. The force indicated by a large arrow, which the force jets exert on the wing, causes the wing to extend forward and laterally so that the wing is extended to a rectangular shape as shown in Figure 12, the two smaller arrows indicating tensile stresses in the downstream end portion of the wing. If deemed suitable, the engaging bodies 40 can be arranged only within limited portions, counted from both side edges 55 of the wing, so that a central portion becomes free from engaging bodies.

The invention can also be applied to a two-part wing for releasably mounting the two wing sections to each other, the wing 21 being suitably mounted to the turbulence channel group 7 as described above. Such an embodiment is shown in Figure 13, the wing 21 being divided into an upstream wing section 56 and a downstream wing section 57.

The downstream wing section 57 is provided with a row of engaging bodies 40 at its upstream end portion 58 in the same manner as described above for the integral wing 21, which engaging bodies 40 are received in elongate heavy-duty recesses 50 as described above. The downstream end portion 59 of the upstream wing section 56 of the wing is in this case formed as an engaging part, which corresponds to the first engaging part 31 in the engaging part 31 in the embodiment according to Figure 3 with respect to the track. 34 design and location.

The engaging bodies are manufactured in a simple and inexpensive manner from e.g. pipes of suitable quality which are commercially available by simply cutting the pipe into desired lengths, some of which are provided with axial slots according to the embodiment described above. The recesses for the engaging bodies are also easy to perform with the required tolerance in the wing, e.g. with a punching tool. The engaging bodies adapted to the recesses are placed in the recesses in a simple and fast manner. 000619 Pl442SE T01 n o u ~ o ø. n u u

Claims (20)

10 15 20 25 30 35 516 653 14 P A T E N T K R A V A headbox for delivering a stock jet to a forming zone in a wet web forming die, comprising - a nozzle (8) having a nozzle chamber (12) and a nozzle orifice (15), - a turbulence generator defining a turbulence channel group (7) for supplying at least one stock to the nozzle chamber (12), - at least one vane (21) arranged in the nozzle chamber (12), and - a device for releasably mounting the vane ( Upstream end portion (25) directly or indirectly at the turbulence channel group (7), the device comprising - an engaging member (26) connected to the wing (21) at said upstream end portion (25), and - an elongate structural member ( 27), having a longitudinal groove (28; 34) open at its opposite ends, for receiving the upstream end portion (25) of the wing (21) and its engaging means (26) for fixing the wing (21) in the machine direction, characterized in that the engaging means (26) comprises a plurality of elongate inlets gripping bodies (40; 51) and that the upstream end portion (25) of the wing (21) is provided with a plurality of elongate recesses (41; 50) of predetermined length, which recesses are arranged at a predetermined distance from each other, extending parallel to the upstream edge of the wing (21). (42) at a predetermined distance therefrom and are arranged to receive at least one of said engaging bodies (40; 51) for releasably mounting the engaging body (40; 51) in the upstream end portion (25) of the wing (21). Inlet box according to claim 1, characterized in that said construction element (27) consists of a mounting strip (19), which is fixedly mounted to said turbo- 5 cuoua ø oao 10 15 20 25 30 35 516 m, 15 drain channel group (7 ) or which is an integral part of the turbulence channel group (7), and having said groove (28) for receiving the upstream end portion (25) of the wing (21) and its engaging bodies (40; 51). Headbox according to claim 1, characterized in that said construction element (27) is constituted by a hinged connecting strip (30) with a first engaging part (31) and a second engaging part (32), which second engaging part (32) is designed for mounting in a groove (38) of a mounting strip (19), which is fixedly mounted to said turbulence channel group (7) or which is an integral part of the turbulence channel group (7), and which first engaging part (31) has said groove (34) for receiving the upstream end portion (25) of the wing (21) and its engaging bodies (40; 51). The headbox according to any one of claims 1-3, wherein the wing (21) consists of two wing sections (56, 57) arranged one after the other, characterized in that a second construction element, which has the same function as the first construction element (27), is formed by the downstream end portion (59) of the upstream wing section (56) provided with a continuous groove (34) extending across the machine direction, and the upstream end portion (58) of the downstream wing section (57) being provided with said engaging means (26). Headbox according to one of Claims 1 to 4, characterized in that the engaging bodies (40) are hollow and have an axially through hole (47) and in that each recess (41) has the shape of an elongate U with two parallel grooves (43, 44). ) and an intermediate tongue (46), which is arranged to be received in the hole (47) of the engaging body (40) for supporting at least a part of the engaging body (40). 10 15 20 25 30 35 5 16 6 3 3 šïï ”- n a a n o a ø: en 16 Inlet carriage according to claim 1, characterized in that engaging bodies (40a) of a first group are provided with two elongate, diametrical grooves (48), which have a width which is slightly greater than the thickness of the wing (21) within the upstream end portion (25). ), the locked engaging body (40a) being arranged to engage its locked portion with the wing (21) in the extension of the recess (41) at the root of the tongue (46) of the recess (41). Headbox according to claim 6, characterized in that the groove-free part of the engaging body (40a) is arranged to fill the entire length of the recess (41). Inlet carriage according to claim 6, characterized in that the groove-free part of the engaging body (40a) is arranged to fill a part of the recess (41), wherein engaging bodies (40b) of a second group are free of grooves and have a length which fills the the remainder of the recess (41) or a multiple thereof, said length corresponding to such a multiple. Inlet carriage according to Claim 1, characterized in that the length of the recesses (41), the distance between the recesses (41) and the length of the engaging bodies (40), respectively. lengths are so adapted to each other that the engaging bodies (40) form a continuous row in an end-to-end relationship from one side of the wing (21) to its other side. A headbox according to any one of claims 1-3, 5-9, characterized in that the wing (21) is made of a plastic material with a concave, circular arc-shaped downstream edge (53) and that said recesses (41) and their said engaging bodies (40) are arranged in a circular arc concentric with said concave downstream edge (53), said downstream edge (53) being straightened during operation under the influence of shear forces exerted by the stockings on the wing (21). 10 15 20 25 30 35 s 1 e e s s i? àfzë-Ilšïïlšï 17 Device of an inlet box for releasably mounting a wing (21) upstream end portion (25) directly or indirectly at a turbulence channel group (7), which inlet box is arranged to deliver a stock jet to a forming zone in a former for wet forming a fiber web. and comprises - a nozzle (8), having a nozzle chamber (12) and a nozzle opening (15), - a turbulence generator, which defines said turbulence channel group (7) for supplying at least one stock to the nozzle chamber (12) and - at least a wing (21) arranged in the nozzle chamber (12), the device comprising - an engaging member (26) connected to the wing (21) at said upstream end portion (25), and - an elongate structural member (27) , having a longitudinal groove (28; 34) open at its opposite ends, for receiving the upstream end portion (25) of the wing (21) and its engaging means (26) for fixing the wing (21) in the machine direction , characterized in that the engaging means (26) enters comprises a plurality of elongate engaging bodies (40; 51) and that the upstream end portion (25) of the wing (21) is provided with a plurality of elongate recesses (41; 50) of predetermined length, which recesses are arranged at a predetermined distance from each other, extending parallel to the upstream edge of the wing (21). (42) at a predetermined distance therefrom and are arranged to receive at least one of said engaging bodies (40; 51) for releasably mounting the engaging body (40; 51) in the upstream end portion (25) of the wing (21). Device according to claim 11, characterized in that said structural element (27) consists of a mounting strip (19), which is fixedly mounted to said turbulence channel group (7) or which is included as an integral part of the turbulence channel group (7), and which said groove (28) for receiving the upstream end portion (25) of the wing (21) and its engaging bodies (40; 51). Device according to claim 12, characterized in that said construction element (27) consists of a joint-forming connecting strip (30) with a first engaging part (31) and a second engaging part (32), which second engaging part (32) is designed for mounting in a groove (38) of a mounting strip (19), channel group (7) or which is included as an integral part in which is fixedly mounted to said turbulence-turbulence channel group (7), and which first engaging part (31) has said groove (34) for receiving the upstream end portion (25) of the wing (21) and its engaging bodies (40; 51). The wing (21) consists of two successive wing sections (56, 57), characterized in that a second construction device according to any one of claims 11-13, wherein structural elements having the same function as the first structural element (27). ), is formed by the downstream end portion (59) of the upstream swing section (56), which is provided with a continuous groove (34) extending across the machine direction, and the upstream end portion (58) of the downstream swing section (57) is provided with said engaging means (26). 15. in that the engaging bodies (40) are hollow and have a device according to any one of claims 11-14, characterized by axially through holes (47) and that each recess (41) is in the form of an elongate U with two parallel grooves (43, 44). ) and an intermediate tongue (46), which is arranged to be received in the hole (47) of the engaging body (40) for supporting at least a part of the engaging body (40). Device according to claim 11, characterized in that engaging bodies (40a) of a first group are provided with two elongate, diametrical grooves (48), which have a width which is slightly greater than the thickness of the wing (21) within the upstream end portion (25). ), wherein the grooved engaging body. o ø. ~ «N Q u no 10 15 20 25 30 35 516 633 19 (40a) is arranged to be brought with its grooved part into engagement with the wing (21) in the extension of the recess (41) at the root of the tongue (46) of the recess (41). . Device according to claim 16, characterized in that the groove-free part of the engaging body (40a) is arranged to fill the entire length of the recess (41). Device according to claim 16, characterized in that the groove-free part of the engaging body (40a) is arranged to fill a part of the recess (41), wherein engaging bodies (40b) of a second group are free from grooves and have a length which fills the the remainder of the recess (41) or a multiple thereof, said length corresponding to such a multiple. Device according to Claim 11, characterized in that the length of the recesses (41), the distances between the recesses (41) and the length of the engaging bodies (40), respectively. lengths are so adapted to each other that the engaging bodies (40) form a continuous row in an end-to-end relationship from one side of the wing (21) to its other side. Device according to any one of claims 11-13, 15-19, characterized in that the wing (21) is made of a plastic material with a concave, circular arcuate downstream edge (53) and that said recesses (41) and their said engaging bodies ( 40) are arranged in an arc of a circle concentric with said concave downstream edge (53), said downstream edge (53) being straightened during operation under the influence of shear forces exerted by the stockings on the wing (21). 000619 P1442SE T01