EP0267620A1 - Friction-spinning roller - Google Patents

Abstract

In order to be able to choose a hole size in the manufacture of the friction spinning drums (1), which on the one hand counteracts the technological loss of fiber and jamming of foreign bodies sucked in, and on the other hand is advantageous in terms of flow technology, it is proposed that the friction spinning drum consist of a thick-walled support body (2) and a thin-walled sieve body ( 3) to manufacture. In this way, sieve holes (8) can be produced in the thin-walled sieve core (3), which have a sufficiently small cross-section to counter the aforementioned technological fiber loss. On the other hand, holes (9) with a sufficiently large cross section can be selected in the thick-walled support body (2) in order to prevent foreign bodies that are sucked in from becoming stuck.

Description

The invention relates to a friction spinning drum in the manner of a hollow sieve drum designed for radial air passage.

Such friction spinning drums are used in the friction spinning process known per se, in which, as a rule, two cylindrical drums rotate close together in the same direction, at least one of the two friction spinning drums being a sieve drum.

The task of such a screening drum is to take up the fibers fed thereon in a manner known per se by means of an air stream and to turn them into a thread in the region of the gusset of the two drums, which is drawn off in a direction essentially perpendicular to the direction of rotation of the drums, ie essentially parallel to the axis of rotation of the screening drum. The air flow required for conveying the fibers is pre-selected by means of an inside of the sieve drum suction nozzle through the holes in the sieve drum.

It is therefore understood that, on the one hand, the holes of this sieve drum must have a diameter which essentially prevents too many fibers from being absorbed by these holes during storage on the sieve drum and thereby either being sucked off and lost or only at the edge of the Cut the suction nozzle mouth and thereby shorten it.

On the other hand, the energy requirement of such a system should be as small as possible, the air requirement making up a significant proportion of the energy requirement. It is therefore the aim to choose the hole diameter as large as possible from this point of view in order to obtain the lowest possible resistance for the required amount of air per unit of time.

However, these two requirements placed on the hole diameter are diametrically opposed to each other.

From practice and based on patent publications, it is known that these holes generally have a diameter between 0.5 and 0.8 mm.

On the other hand, the sieve drums must have their own rigidity in order not to experience any deformation during operation, which means a minimum wall thickness of these drums of at least 1.5 mm, if brass is used and, for example, if the drum diameter is 50 mm. required.

However, it goes without saying that drilling in a 1.5 mm thick or thick material of such small holes with a number of holes per sieve drum of several tens of thousands of holes is not without problems and therefore expensive.

If additional requirements are placed on the hole shape, as is the case in DE OS No. 2919316, manufacturers of such sieve drums are faced with particular problems.

The object of the invention is therefore to find a sieve drum which can be manufactured inexpensively with sufficient inherent rigidity and small air resistance.

The invention solves this problem in that the spinning drum consists of an inner, perforated support body and an outer screen body attached to it.

The perforation of the support body advantageously has a larger hole cross section than the perforation of the screen body. In addition, it is advantageous for the production if the supporting body is a rigid hollow body and the sieve body is a flexible body mounted thereon. The sieve body can consist of a metal strip spirally drawn onto the support body or of a rectangular foil drawn onto the support body. Likewise, the screen body can be drawn onto the support body as a tubular film.

In this case, the perforations of the support body and of the screen body that result in the perforation can be coaxial.

However, an arrangement in which the number of perforations per unit area in the screen body is greater than the number of holes per unit area in the support body is also of great advantage. In this way there are several perforations in the sieve body, which can be made as small as desired, over each hole in the support body. The size and distribution of the holes in the support body can be selected according to the invention, taking into account the required strength of the support body, so that as many of the preferably evenly distributed perforations in the screen body offer air passage, ie are not blocked by the support body. Further advantageous embodiments are listed in the dependent claims.
The advantages of the invention are that, on the one hand, the difficult to manufacture small hole diameters can be made in a relatively thin material, while the thick-walled support body can be provided with holes, which can have a cross-section that can be chosen according to the thicker wall more suitable for production.

Another advantage is that the sieve body can be an expandable tape or film (even if the film is assembled into a tubular sieve body in a second operation), because this means that the side of the perforated film provided with the burrs as the outside of the sieve body can be selected, which offers the further advantage with a subsequent galvanic coating that the holes experience an expansion from the outside in. This extension not only offers an advantage in terms of the pneumatic resistance of the individual hole, but dirt particles penetrating through the individual holes may not get stuck in the subsequent hole cross section.

• Fig. 1 eine Ansicht einer erfindungsgemäßen Friktionsspinntrommel,
• Fig. 2 einen vergrößerten Ausschnitt A aus der Friktionsspinntrommel von Fig. 1, im Schnitt dargestellt,
• Fig. 3 einen vergrößerten Ausschnitt B aus der Oberfläche der Friktionsspinntrommel von Fig. 1,
• Fig. 4 eine Variante der Oberfläche gemäß Fig. 3,
• Fig. 5, 6 und 7 je eine Ansicht einer Anwendungsvariante der Friktionsspinntrommel von Fig. 1, und
• Fig. 8 einen vergrößerten Längsschnitt durch eine alternative Ausführung einer erfindungsgemäßen Friktionssprinntrommel.

The invention is explained in more detail below with the aid of drawings which only show execution routes. It shows:

• 1 is a view of a friction spinning drum according to the invention,
• 2 shows an enlarged detail A from the friction spinning drum of FIG. 1, shown in section,
• 3 shows an enlarged section B from the surface of the friction spinning drum of FIG. 1,
• 4 shows a variant of the surface according to FIG. 3,
• 5, 6 and 7 are each a view of an application variant of the friction spinning drum of Fig. 1, and
• Fig. 8 is an enlarged longitudinal section through an alternative embodiment of a friction spinning drum according to the invention.

A friction spinning drum 1 comprises a support body 2 with a screen body 3 mounted thereon, the type of which will be described later.

The support body 2 is designed as a hollow body and is firmly connected at one end to a stub shaft 4. A shaft 5 belonging to the shaft end serves to receive a roller bearing 6, by means of which the friction spinning drum 1 is rotatably mounted. A drive belt 7 engages the shaft 5 for driving the friction spinning drum.

As shown in detail in Fig. 1, the screen has body 3 sieve holes 8 and the support body 2 through holes 9. A suction nozzle 10 provided at the opposite axial end of the friction spinning drum protrudes into the support body in a manner known per se and sucks air through the sieve and through-holes by means of a nozzle mouth (not shown) provided close to the cylindrical inner wall of the support body. Such a suction arrangement is known per se from the friction spinning process and is therefore not described further.

The sieve holes 8 and the through holes 9 are provided in the support body 2 and in the sieve body 3 within a perforated area a marked with dash-dotted lines.

2 shows a section of the support body 2 and the screen body 3 marked A in FIG. 1, in which the wall thickness of the support body 2 is marked with a W and the wall thickness of the screen body 3 with a V.

Furthermore, it can be seen from this that the manufacturing ridges 11, which are exaggerated for clarification, are directed against the outside of the friction spinning drum. Furthermore, the screen body is coated on its cylindrical outer surface with a galvanic layer 12, for example by hard chromium plating, possibly with Cu or Ni intermediate layers, which for physical reasons builds up around the manufacturing burrs more than in the adjacent parts. In addition, the galvanic layer also builds up in a preselected layer thickness with respect to the wall thickness V of the screen body 3 Kind in the depth of the sieve holes, as shown in Fig. 2, so that the sieve holes take a diffuser-like shape. This brings the advantages mentioned at the outset that on the one hand the diffuser-like shape brings a fluidic advantage and on the other hand dirt particles sucked in through the sieve holes 8 do not get stuck in the sieve holes.

Another advantage of the reinforced structure of the galvanic layer around the manufacturing ridge is that a small ring-shaped elevation is created around each sieve hole, which improves the frictional relationships of the surface of the sieve body 3.

For example, the wall thickness W of a support body made of brass shown in FIG. 2 can be 1.5 to 2 mm, and the wall thickness V of a screen body made of a nickel-chromium alloy can be 0.5 to 0.8 mm. The thickness of the galvanic layer in the surface parts between the ring-shaped elevations is approximately 0.2 mm.

2 and 3 that the through holes 9 have a larger cross section than the smallest cross section of a sieve hole. In the case of round holes, for example, the smallest cross section of the sieve hole can have a diameter of 0.5 mm and the diameter of the through hole can be 0.8 or 1.0 mm, depending on the hole spacing, so that the supporting body still has enough material between the through holes so that it fulfills its task from the standpoint of strength can.

This has the advantage that the holes in the screen body can be drilled without problems in conventional drilling or punching processes or in the electron beam drilling process due to the small wall thickness V. The through holes 9 of the support body can be drilled without problems due to the much larger diameter in the conventional drilling method, even with a wall thickness W of 2 mm or more.

As can also be seen from FIGS. 2 and 3, the sieve holes are arranged coaxially with the through holes, but this is not absolutely necessary. There is definitely the possibility of providing significantly larger through holes which do not have the same pitch as the sieve holes, whereby the spacing of the hole centers is to be understood as the pitch. Such embodiments will be described later in connection with FIG. 8. In addition, the sum of all cross sections of the perforations 9 of the support body 2 which result in the perforation has a larger proportion of the total area of the perforated area a than the sum of all cross sections of the holes 8 of the sieve body 3.

Furthermore, it can be seen from FIG. 4 that the screen holes do not necessarily have to have a round cross section, but that other shapes are possible, in particular if the manufacturing process is a stamping process. 4 shows square sieve holes, but could also be holes with other shapes. The same applies to the through holes if a different method is used instead of the drilling method to obtain the through holes in the support body 2, for example an injection molding process.

FIGS. 5, 6 and 7 show different types of how the screen body 3 can be shaped and fitted onto the support body 2.

Fig. 5 has a band-shaped sieve body 3a, which is wound spirally on the support body and connected to it by any type of connection. The type of connection can be gluing, for example, by gluing the beginning and the end in the zones outside the perforated area a to the supporting body. The spiral winding is carried out in such a way that the band body windings touch each other in order to avoid air passage at this contact point 13. In addition, there is the possibility of welding the strip body turns at this point of contact with laser beams.

In FIG. 6, the sieve body 3b consists of a rectangular film, which, when placed on the support body 2, rests tightly thereon without forming a substantial distance in the connecting joint 14. In addition, the joint can also be welded with a laser beam.

In FIG. 7, the sieve body 3c consists of a hollow body which is made of a material which has a smaller coefficient of expansion than the support body, ie the support body is selected from a material since the selection of the material for the sieve body has first priority, which has a larger coefficient of expansion than the screen body 3c. For pushing on the screen body 3c, the latter and the support body 2 are cooled to a temperature which is substantially below the normal ambient temperature, so that the support body 2 shrinks more when cooling than the screen body 3c, which enables the screen body 3c to be pushed onto the support body 2 without any problems . The outer diameter of the support body 2 is selected in comparison to the inner diameter of the screen body 3c such that when heated to normal temperature (not yet operating temperature), the screen body 3c lies snugly and without rotation on the support body 2. When heated to operating temperature, a precalculated tension is created in the screen body 3c.

The manufacture of such a hollow body can be carried out galvanically and is described in the simultaneously filed European patent application with the name "Process for producing a sieve body, friction spinning means for using the sieve body and friction spinning device for using the friction spinning means" of the same application, which is the priority of the Swiss application 04 543 / 86-6 claims.

8 shows a longitudinal section through a part of the surface of a screening drum 1, which is rotatably mounted about a longitudinal axis 1ʹ by means of a shaft and a shaft stub (not shown) in accordance with the arrangement of FIG. 1. In this example, the holes 9 a much larger opening cross section than the perforations 8 in the supporting body 2 in the sieve body 3 so that a large number of perforations 8 come to lie above each through hole 9. In this example, too, the perforations have a cross-sectional widening in the radially inward direction, so that blockage of these holes can be effectively avoided. A galvanic coating of the holes in the screen body is also provided here, but is not shown for the sake of illustration.

As in the other examples, a plasma coating could also be applied to the galvanic coating here, a coating of aluminum oxide or nickel diamond being preferred as the plasma coating.

In conclusion, it should be pointed out that the holes in the support body can be formed by mutually intersecting longitudinal grooves and circumferential grooves, the longitudinal grooves preferably being formed in the interior of the cylindrical hollow body forming the support body and the circumferential grooves being present in the outer surface of the hollow body. In this embodiment, the circumferential grooves can advantageously have the shape of a thread.

Claims (15)

1. friction spinning drum (1) in the manner of a hollow sieve drum designed for radial air passage,
characterized,
that the spinning drum (1) consists of an inner, perforated support body (2) and an outer screen body (3) attached to it. 2. friction spinning drum according to claim 1,
characterized,
that the perforation (9) of the support body (2) has a larger hole cross section than the perforation (8) of the sieve body (3). 3. friction spinning drum according to claim 1,
characterized,
that the support body (2) is a rigid hollow body and the sieve body (3) is a flexible body mounted thereon. 4. friction spinning drum according to claim 1,
characterized,
that the sieve body (3) consists of a metal band (3a) applied spirally to the support body (2). 5. friction spinning drum according to claim 1,
characterized,
that the sieve body (3) is drawn onto the support body (2) as a rectangular film (3b). 6. friction spinning drum according to claim 1,
characterized,
that the screen body (3) is drawn onto the support body (2) as a tubular film (3c). 7. friction spinning drum according to claim 2,
characterized,
that the perforations (8, 9) of the supporting body (2) and the sieve body (3) resulting in the perforation are coaxial. 8. friction spinning drum according to claim 2,
characterized,
that the sum of all cross sections of the perforations (9) of the support body (2) resulting in the perforation have a larger proportion of the total area of the perforated area (a) than the sum of all cross sections of the holes (8) of the sieve body (3). 9. friction spinning drum according to claim 1,
characterized,
that the screen body (3) has a coating (12) on its surface. 10. friction spinning drum according to claim 9,
characterized,
that the screen body (3) has a galvanic coating (12). 11. friction spinning drum according to claim 9,
characterized,
that the coating (12) consists of a galvanic coating and a plasma coating applied thereon consists, for example, of aluminum oxide or nickel diamond. 12. Friction spinning drum according to claim 10,
characterized,
that the galvanic coating (12) is roughened. 13. Friction spinning drum according to one of the preceding claims,
characterized,
that the screen body (3) is mounted on the support body (2) in such a way that any manufacturing burrs on the holes of the screen body (3) are located on the outer surface of this screen body. 14. Friction spinning drum according to one of the preceding claims 1 to 6 and 8 to 13, characterized in that the number of perforations per unit area in the screen body is greater than the number of holes per unit area in the support body. 15. Friction spinning drum according to claim 14, characterized in that the holes in the support body are formed by intersecting longitudinal grooves and circumferential grooves, the longitudinal grooves are preferably formed in the interior of a cylindrical hollow body and the circumferential grooves are present in the outer surface of the hollow body, the circumferential grooves in particular the Have the shape of a thread.

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