DE3723524A1 - Cross-wound bobbin - Google Patents

Abstract

In the production of threads textured by false twisting, the threads are wound to form a cross-wound bobbin which is made biconical only in its lowest layers, specifically to a layer thickness of up to 30% of the total winding layer, but which is otherwise wound with straight end faces.

Description

The invention relates to a cheese from a thread and a process for their manufacture.

Threads can be cross-wound on cylindrical or conical Sleeves are wound up. The laying of the Thread either in a wild cross winding or in a Precision cross winding.

Under a wild cross winding is within the scope of this application understood a winding in which the mean value of the Traversing speed during the formation of the package (Winding travel) remains essentially constant. This changes the winding ratio (spindle speed / traversing speed speed) steadily in the course of the winding trip (real wild Kreuzwick lung) or in small jumps (graduated precision winding lung). Common feature of the wild cross winding is that the tangent of the crossing angle or pitch angle of the Thread on the bobbin (see DIN 61 801) during the winding cycle, if it is changed, not proportional to the spindle rotation number is changed or remains constant on average.

The real precision winding, on the other hand, stands out characterized in that the winding ratio in the course of the winding trip remains constant. This means that the tangent of the Crossing angle or pitch angle in the course of the winding travel from its greatest value at the beginning of the winding trip its lowest value proportional to the end of the winding cycle reduced to spindle speed.

For the types of winding and winding mentioned, it is known to manufacture the coils with sloping faces (cf. DIN 61 800, No. 1.1.1.3. and No. 1.1.2.4.). Such cylin Dried or conical cross-wound bobbins with sloping faces are referred to below as biconical coils.  

The production of these biconical coils takes place in that the length of the traversing stroke with which the thread is axially parallel is moved back and forth depending on the growing diameter of the coil slightly is reduced. If the end faces on a normal plane to the coil axis, the slope angle is the same 90 °. One speaks of cylindrical cheese with normal End faces or straight edges. If the slope angle of the end faces is less than 90 °, one speaks of conical or sloping faces. Because usually the Coils to the middle normal plane mirror-symmetrical are referred to as "biconical coils".

False twisted textured threads are used as synthetic fibers usually wound into cylindrical cross-wound bobbins. Around the threads without interruption, quickly and without thread tension It is also possible to remove voltage peaks from the coil the false twisted textured threads into biconical bobbins wound up.

The package for cross-wound bobbins according to this invention is suitable are particularly suitable for synthetic fibers that are heated and False threads are textured and crimped. With these There is thread in the usual biconical windings the danger that the coil will become very strong over time bulges that the threads form strikers (thread pieces that at the front edges slip out of their position and others cover layers lying further inward secantially) and others on the one hand, that the threads slide inwards on the bobbin, causing the cylindrical surface to bulge receives.

Biconical coils have the disadvantage that there is only one in them less thread volume can be stored than in cylin Dry coils with normal end faces with the same through knife and equal length.

The object of the invention is to develop coil forms that have good drainage properties, but in the same a large amount of thread can be stored in time.

For this purpose, it is proposed that the cheese only in its inner area is wrapped biconically and that outside this base winding the coil with normal front edges or only very weakly biconical end edges wrapped becomes. The layer thickness of the base winding is only a fraction and not more than a third of the total layer thickness. A layer thickness of 10 to 20 mm for the Basic development has proven to be sufficient.

The slope angle of the base winding is in any case much smaller than the slope angle of the rest Overall winding. The angle of repose of the base winding is preferably less than 80 °.

The angle of repose of the remaining total winding can be 90 ° be. That means: the rest of the overall winding can be normal Have front edges. Depending on the winding behavior of the However, it can also be useful for the rest of the thread Overall winding weakly to bob, in which case the Slope angle is definitely larger than the slope angle of the base winding.

The package according to the invention can also in the itself Racket-endangered base layer with very small Crossing angle can be wound up without a shows harmful bevel formation. In addition, the Cross-wound bobbin according to the invention with a relatively high Thread tension are wound up, since the risk that the Slip thread layers to the center of the traversing stroke by application of the relatively flat crossing angle becomes. It is therefore possible to use packages with a very high density To form (thread mass).  

The advantage for precision bobbins results from the invention: the thickness of the thread layer that can be formed on a sleeve is on the one hand due to the largest possible crossing angle that is to be traveled at the beginning of the winding travel and on the other hand due to the lowest possible crossing angle that is at the end of the bobbin is driven, limited. The greatest possible crossing angle results from the risk that the thread slips on the smooth sleeve and on the relatively smooth first layers in the direction of the center of the traversing stroke. This leads to deformations of the edges and the surface of the spool and subsequently also to malfunctions. The smallest possible crossing angle results from the risk of strikers forming. This danger increases as the crossing angle becomes smaller. The greatest possible crossing angle can be increased further by the invention. Thus becomes possible (= _^half the diameter difference = outer radius of the cross-wound bobbin minus sleeves radius) to form coils of greater precision total pulse layer.

In one embodiment of the invention, the base layer is covered with increasing crossing angle formed, the increase on the slope angle is matched. Through this execution succeeds in comparing the thread tension very significantly moderate and thus the quality of the bobbins and threads improve.

The process for producing the package is noticeable characterized in that in the course of the winding trip with decreasing Stroke reduction is driven, the stroke reduction at the latest after a base winding with a layer thickness that is less than a third of the total layer thickness, to one much less amount is withdrawn. The stroke min change in the area of the remaining overall winding preferably less than 0.1 mm stroke reduction per millimeter Coil diameter increase. As a stroke reduction, the one side decrease of the traverse stroke in the course of the winding travel designated.  

The stroke reduction is measured on one face. The Stroke reduction is usually done depending on the growing coil diameter. A suitable change direction for the production of a cylindrical cheese with biconical front edges is e.g. B. in DE-PS 19 16 580 shown.

The strong biconical winding of the base layer has U. a very strong voltage drop. this will compensated according to the invention in that the traversing frequency proportional to the stroke reduction is increased so that the Traversing speed remains essentially constant.

In Fig. 1, a cheese is shown in side view, which is made according to this invention. The thread is wound on the sleeve 1 to form a cheese. The initial stroke HA was 250 mm. Then there was first a basic winding with a layer thickness SB of 15 mm and a strong stroke reduction at an embankment angle beta of 75 °. This resulted in a stroke reduction ^{(HA - HB)} / ₂ of 4 mm. There was then a further winding without Hubminde tion, so with normal front edges, up to a final diameter D of 300 mm with a sleeve diameter d of 82 mm.

It turned out that this was already racket-free Coils could be wound with a crossing angle gamma between the threads, far below the usual Values (24 °).

This showed that the measure according to this inven Two additive advantages can be achieved:

Firstly, the storage of a larger one Thread mass allows. On the other hand, it also becomes one Reduction of the crossing angle without damaging the coil enables. The reduction in the crossing angle in turn  also contributes to the fact that larger thread masses on the Coil can be saved. On the other hand, the That also tends to reduce the crossing angle Running behavior of the thread from the bobbin.

Cross-wound bobbins made from false twisted textured threads show u. U. temporal changes in their end faces. It can happen that the end faces bulge outwards. In order to compensate for this tendency to bulge, a coil was produced in a parallel test, in which a stroke reduction was carried out after the base layer SB , which was, however, considerably less than when winding the base layer. While the slope angle beta of the base layer was approx. 75 °, the angle alpha of the remaining total layer was 85 °. This resulted in no significant reduction in the density of the coil. However, it was achieved that the coil above the base layer had almost ideal normal end faces after a short time.

In the embodiment, it was shown that the Hubminde tion, ie the decrease in stroke and thus the slope angle for the base layer and for the rest of the total layer are each constant. However, it is also possible to have the stroke reduction steadily decrease with increasing diameter during the winding cycle. As a result, as the line 2 shows, there is an end face whose slope angle increases steadily from the sleeve with increasing diameter up to 90 ° or slightly less.

In Fig. 2, a conical cheese is shown in view and axial section. The sleeve 1 is conical. When winding the spindle axis 4 to the dashed indicated traversing device 3 at half the cone angle. The traversing device 3 was operated with the stroke H at the beginning of the winding travel. There was then a strong Hubminde tion at both ends, labeled dH . This resulted in a biconical base layer with the layer thickness SB and the cone angle beta. The angle beta is between 65 and 75 °. Following the base layer SB , the package was wound without further stroke reduction, that is to say with straight end edges, up to the total winding layer SG .

In Fig. 3 the diagram of the traversing frequency NC is shown as a function of the winding layer formation S for a wild winding.

Basically, according to this invention, the traversing frequency is possible
leave constant ( Fig.3.1 ),
slightly in order to constantly change an average value M like a saw tooth for the purpose of mirror disturbance ( Fig. 3.2),
to be reduced several times in a hyperbolic branch 5 in proportion to the spindle speed and to be increased to an initial value 7 when a lower value 6 is reached (graduated precision winding, Fig. 3.3).

In all these cases the crossing angle remains constant ( Fig. 3.1) or changes only within certain permitted limits ( Fig. 3.2, Fig. 3.3).

Also in the diagram of Fig. 3.3, a mean value M is obtained for the traversing frequency.

In FIG. 4, the diagram of the traversing frequency NC is shown for a special case. It has already been mentioned that u. U. also a very strong change in thread tension occurs. This can be prevented if the traversing frequency has a relatively low initial value and then rises in a curve 8 during the basic winding initially very strongly and proportionally to the stroke reduction dH and then either remains constant (curve 9 ) or only weakly in accordance with the lower slope (see FIG. 1, angle alpha) continues to increase after curve 10 .

The curves 8, 9 and 10 according to FIG. 4 are either the traversing frequency or merely their mean value, by which the traversing frequency is changed in accordance with the regularities described in FIGS. 3.2 and 3.3.

In Fig. 5 the diagram of the traversing frequency for a genuine precision winding is shown. The traversing frequency is shown over the layer thickness. It can be assumed that the thread will be delivered at a constant speed. It follows that the spindle speed drops with increasing layer thickness. The precision winding is characterized in that the crossing angle remains constant and therefore the traversing frequency drops hyperbolic proportionally to the spindle speed.

The possibility according to this invention to wrap a base layer with a stronger cone angle also gives the possibility of further increasing the initial oscillation frequency. The area additionally opened up for precision winding by the invention is hatched in the diagram according to FIG. 5.

Fig. 6 shows part of the traversing device shown in DE-PS 19 16 580 = US-PS 37 30 448 for producing a biconical winding. Writing in deviation from the above-mentioned patent, the sword is shown in Fig. 6 29 with its sliding edge 30 so that a base layer having reinforced biconical batch is prepared. For this purpose, the sliding edge 30 has a projecting projection A in the region in which the sliding edge 30 bears against the coupling member 28 while the base layer is being wound. This approach causes a biconical winding with an increased cone angle to be formed. For the description of FIG. 6, reference is made to the above-mentioned patents.

Claims (12)

1. cheese
from a thread wound on a sleeve, characterized in that
the coil only in a base layer (SB) , the thickness of which is up to 30% of the total coil layer (SG) ,
has sloped end faces, while in the remaining total winding layer the slope angle of the end faces is substantially larger than in the base layer and only slightly less than or equal to 90 °. 2. cheese according to claim 1, characterized in that the slope angle (beta) of the base layer is smaller than 80 °. 3. cheese according to claim 2, characterized in that the slope angle (alpha) of the residual layer (SG - SB) is greater than 80 °. 4. cheese according to one of the preceding claims, characterized in that the thread is an endless multifilament chemical thread that is textured by heat treatment and false twisting.   5. Cross-wound bobbin according to one of the preceding claims, characterized in that the cross-wound bobbin in the region of the base layer (SB) has a crossing angle which decreases proportionally to the base layer thickness. 6. Method of making a package according to one of the previous claims, characterized in that a diameter-dependent when winding the base layer Stroke reduction of the traversing stroke is made is stronger than the stroke reduction when winding the remaining total spool layer. 7. The method according to claim 6, characterized in that the amount of stroke reduction when winding the base layer and when winding the remaining total winding layer in each case is constant. 8. The method according to claim 6 or 7, characterized in that after winding the base layer on the stroke reduction less than 0.1 mm stroke reduction per millimeter knife increase (84.3 °) drops. 9. The method according to any one of claims 6 to 8, characterized in that the coil is formed on a conical sleeve. 10. The method according to any one of claims 6 to 9, characterized in that the coil at least in the area of the remaining total coil layer with a constant traversing speed is formed.   11. The method according to any one of claims 6 to 9, characterized in that the coil at least in the area of the rest Total winding layer with constant winding ratio (spindle speed / traversing speed) is formed. 12. The method according to any one of claims 6 to 11, characterized in that the coil with at least in the area of the base layer Traversing speed is wound, the propor tionally increases to reduce the stroke.