DE2341609C3 - Ring twisting machine - Google Patents

Description

The invention relates to a ring twisting machine according to the preamble of claim 1.

Such a ring twisting machine is known from DE-PS 61 504.

In this known ring twisting machine, the compressed air nozzles are aligned radially in order to close the spinning ring center. The magnets are on this machine low hollow provided in the annular surface as well as in the opposite surface of the spinning ring; However, at least in their predominant Afizähi they are opposite with their poles of the same name arranged. The magnetic force therefore acts in a repulsive sense, while the compressed air acts in a radial manner Direction perpendicular to the magnetic force acts. In this machine, the repulsive force of the magnets on the one hand and the weight of the ring on the other hand is kept wrong balance. But this can be more disadvantageous Way an oscillation of the spinning ring in the axial direction Direction result and that caused by the always existing yarn tension that tries to Pull the clamping ring upwards.

Another disadvantage of this device is that the compressed air used also oscillates in the transverse direction or a rotational movement of the spinning ring can not prevent when the spinning ζ »Β. experiences a transverse movement or a rotary movement due to the thread force.

ο From CH-PS 4 11 481 it is already known to have a magnetic force of attraction act between the two parts in a guide device whose parts moving against each other are supported by a gas cushion. However, this measure serves the purpose of exerting a pre-tensioning force on the gas cushion and the magnitude of the magnetic force is therefore based on the desired pre-tensioning force. Since the purpose of this guide device is a contactless movement of one part along a guide path, magnets are also only arranged in one of the parts.

From DE-PS 15 10 918 finally a ring twisting machine with a revolving clamping ring known, wherein the spinning ring is held by compressed air at a distance from the ring rail, the radiai and axially from the Ring bank flows against the spinning ring. Magnets are not provided for this machine, the storage takes place rather, solely by means of the compressed air.

The invention is therefore based on the object of a ring twisting machine according to the preamble of the claim 1 to improve so that the free-floating Fenaltene spinning ring both in open and Downward direction as well as in the radial direction is kept more stable.

According to the invention, this object is achieved by the features of claim 1.

According to the invention, the spinning ring is at a distance from the ring rail and in a stable state by the Counteraction of the compressed air and the magnetism Attraction. This achieves excellent spacing stability. Through the intermittently arranged, attractive magnets are also used in transverse movements of the spinning ring causes a restoring force and also a stability against rotational movements, whereby the yarn treatment speed can be increased significantly.

Embodiments of the invention are shown in the drawing and described below. It shows

Fig. 1 is a graph showing the course of the magnetic attraction force and the compressed air force points to the spinning ring depending on its distance from the ring rail.

F i g. 2a and b show an embodiment of the ring twisting machine.

F i g. 2a is a cross-sectional view of a spinning ring and a ring bench.

Fig. 2b is a plan view of part of the ring rail, a section along the line X-X in Fig. 2 B

60; represents the left half of Fig.2a, while a Section along the line Y * Y in Fig.2b the right Represents half of Fig. 2a;

Fig. 3a and b shows another embodiment of the Ring twisting machine

F i g, 3a is a cross-sectional view of a spinning ring and a ring rail.

Figure 3b is a top plan view of part of Figure 3b Ring rail;

4 shows a schematic view of arrangements the magnet;

Fig. 5 is a schematic view of a preferred one Arrangement of the in the embodiments of FIG. 2 and 3 magnets used;

Figure 6 is a cross-sectional view of a spinning ring and a ring rail, with compressed air also flowing out from the side wall of the ring rail.

The diagram of Fig. 1 shows the relationship between a) the repulsion caused by a compressed air jet is generated and b) the magnetic force of attraction, the distance between the spinning ring and the ring rail as the abscissa and the pneumatic or magnetic force taking into account the Ring weight is plotted as the ordinate. The intersection of the In both curves there is a point of stability at which the resulting force is zero, since it is pneumatic Repulsion and magnetic attraction p'.us ring weight opposite in their direction equal in size are.

The F i g. 2a, 2b show an embodiment in which the ring rail 2 has an inner ring-shaped compressed air chamber 3. The ring rail 2 has a cylindrical side wall 4 and an annular base 5. The spinning ring 6 has an outer diameter which is slightly smaller than the inner diameter of the ring rail 2, and it is held at a distance from the ring rail 2. Compressed air comes from a compressed air source '/, which is provided on the annular base 5 of the ring rail 2, flows through the compressed air chamber 3 through openings 8 of compressed air lines and flows out via a pressure chamber 9 to keep the spinning ring 6 floating. The pressure chamber 9 is a channel about 1 mm deep and temporarily holds the expelled air to form a pressurized J5 layer. This is advantageous for maintaining a stabilized floating state of the spinning ring. Column-shaped permanent magnets 1, Γ with the same cross-section are provided in this embodiment. They are each in corresponding positions on the spinning ring 6 and the ring rail 2 (both are made of non-diagnostic material) and arranged on a radius which is approximately the same as that of the mouths 8 of the compressed air lines. As in Fig. 2a, the surfaces of the permanent _{magnetism I 1} Γ are slightly below the surfaces of the ring rail and spinning ring. When air flows out from the mouths under controlled pressure, the spinning ring 6 is held in a stable floating manner in space without coming into contact with the ring rail 2. The yarn 10 runs through the gap 11 between the spinning ring 6 and the ring rail 2 and is guided to a bobbin 13 which is held and rotated by a spindle 12. The ring rail 2 oscillates by means of a conventional drive device, which is not shown, specifically along the spool 13 in the axial direction.

3a and b show another embodiment of the ring twisting machine. In addition to the spinning ring 6 and the ring rail 2, magnet holders 15, 15 ', which are fastened to these and are made of a non-magnetic material, are provided. The "permanent magnets 1, Γ are arranged along the circumference of the magnet holder, the magnet holders 15, 15 'and the permanent magnets of the spinning ring and ring holder are spaced b from each other, while the gap between the spinning 6 and the ring rail 2 is denoted by a In this embodiment, the spinning ring β and the ring rail 2 can also consist of a magnetizable material.

In the aforementioned two embodiments, the surfaces of the magnets are slightly below the Arranged surfaces of the ring or the ring rail, whereby the magnets kept out of the yarn path will.

Different combinations of the magnets are shown schematically in Fig. 4, wherein the side of the spinning ring and the side of the ring rail can either extend upwards or downwards. In Fig. 5, as shown in the legend, obliquely lined parts (c) represent magnets and dotted parts (d) represent non-magnetic parts.

A preferred arrangement of permanent magnets is shown in FIG. There are neighboring Magnetic poles of the permanent magnets t, Γ in alternately arranged opposite layers and a magnetizable material 24, 24 'bridges the Surfaces of the permanent magnets on the spinning ring side or the ring bank side. Dab ^ i results in a magnetic flux, as indicated by the two dash-dotted lines in FIG. 5 shown. This increases in advantageously the effectiveness of the permanent magnets. This also applies if the magnets 1 and / or Γ are electromagnets.

The forces by which the spinning ring is stabilized in the embodiments described above, act as follows: When compressed air from the mouths of the compressed air lines on the ring-shaped base the ring bank flows out, the repulsion of the spinning ring is due to the static and dynamic Pressures of the air brought into balance with the magnetic attraction (plus the weight of the Spinning ring). If a force is exerted on the spinning ring, which gives him a transverse movement or a Want to give rotary motion, the magnets exert a restoring force through which such movements of the Spinning ring can be largely prevented.

It is also possible to have an air flow on the cylindrical side wall against the side surface of the spinning ring to emit through mouths 8 ', as shown in FIG. 6 is shown. This increases the stability of the spinning ring further improved.

example 1

A yarn twisting device whose spinning ring and ring rail are the same as those shown in FIG. 2a and b have the shapes shown, was used when winding a yarn into a bobbin.

The spinning ring had an outside diameter of 200 mm and an inside diameter of 150 mm. a side wall height of 20 mm and a weight of 1.5 kg. The ring rail had an outer wall inner diameter of 200.7 mm, and the height of its outer wall was 20 mm. The spinning ring and the ring rail were made of brass, which is a non-magnetizable material. On the ring rail 45 openings of compressed air lines were provided, each of which had a diameter of 0.7 mm, through which air was supplied ^{with an absolute pressure of 3 kg / cm 2;} Six columnar permanent magnets, each of which had a magnetic remanence of 13.0 KGauss and a diameter of 7 mm and a length of 10 mm, were provided on the spinning ring or the ring rail in such a way that they attracted one another.

When using this device, a yarn was wound onto a bobbin with a skein of yarn

speed of 3000 m / miri ₍ a spindle speed of 19,000 rpm and a winding tension of 50 g. The spinning ring did not touch the ring rail and did not rotate, but was held stably in a floating state and wound the yarn in a stable state. The wound yarn was twisted with a twist of 6.3 T / m.

Example 2

The same spinning ring and ring rail as in Example I were used; The magnets were however not intended, but the ring was kept floating by the compressed air alone. When using this device, yarn was wound around a bobbin at a yarn speed of 600 m / min and a spindle speed of 10,000 rpm The spinning ring began to turn as soon as the yarn speed increased, and a (s the rotating speed of the spinning ring reached about 500 r.p.m., the spinning ring started to spin eccentrically, hit the ring rail And the thread broke. As a result it was not possible to wrap the sink full.

Example 3

Same ring and ring holder as in Example I. were used. The magnets were not provided, however, and 45 mouths from Dfückluftlciturigeri each with a diameter of 0.7 mm would additionally provided on the side wall of the ring rail

K) hen through which air was supplied with an absolute pressure of 3 kg / cm ^2.

Using this device, thread would be fed to the bobbin at a gas speed of 600 m / min and a spindle speed of 10,000 rpm wrapped.

As the number of revolutions of the spinning ring 1000 to 1200 U.p.m, the spinning ring began to get eccentric to turn, hit the side wall of the ring bench and GafhbFiich irai. Consequently it was not possible to fully wind the thread around the bobbin.

For this purpose 4 sheets of drawings

Claims (6)

Patent claims: 1. Ring twisting machine with a spindle that has a Wears bobbin, a spinning ring surrounding the spindle and a spindle essentially surrounding, raisable and lowerable ring rail, which consists of a cylindrical side wall and a vertical one there is arranged annular base area, wherein for contactless holding of the Spinning ring in the ring rail this and the spinning ring arranged in the circumferential direction at a distance from each other Magnets and the ring rail one with a compressed air source and with in the gap between the Spinning ring and the ring bank opening compressed air lines have connected chamber, thereby characterized in that the mouths (8) of the compressed air lines in the annular Base (5, 19) of the ring rail are arranged so that the compressed air with respect to the ring rail (2) in flows out in the axial direction and that all arranged in the spinning ring (6) and the ring rail (2) Magnets (1, 1 ') are polarized so that an axially acting magnetic attraction force of the Compressed air counteracts the force exerted on the spinning ring. 2. Apparatus according to claim 1, characterized in that the magnets (1, Γ) are columnar Permanent magnets with alternating polarity are made of magnetizable !! Material (14,24 ') are bridged. 3. Device narh Ansp-uch 2, characterized in that that the magnets (1,1 ') of the spinning ring (6) and the ring rail (2) are essentially the same Have area. 4. Apparatus according to claim 1, characterized in that the magnets (1, V) by means of a magnet holder (15) on the spinning ring (6) or the ring rail (2) are arranged (F i g. 3a). 5. Apparatus according to claim I, characterized in that the compressed air lines on the the annular base of the ring rail (2) open into une pressure chamber (9). 6. Apparatus according to claim 1, characterized in that the pole faces the magnets somewhat are arranged deeper than the surface of the spinning ring (6) or the ring rail (2).