The invention relates to a process for winding a continuously supplied band onto a bobbin, with the bobbin being rotated and the band being reciprocated along the entire length of the bobbin at a winding angle by means of a cross-winding device, wherein each time the bobbin diameter has increased by a particular value, the winding ratio, i.e. the ratio between the number of bobbin rotations and the reciprocating motion (to-and-fro stroke) of the cross-winding device, is changed in steps.
Among experts, such a process for winding a continuously supplied band is referred to as “stepped precision winding” and is known, for instance, from DE 41 12 768 A, DE 42 23 271 C1 and EP 0 561 188, the latter providing a detailed general account of various types of bobbin shapes.
The band is wound onto cylindrical or conical bobbin cores in winding machines, whereby the speed of supplying the band to the bobbin core is relatively constant, since it has been predetermined by band-manufacturing machines provided upstream of the winding machine.
The appearance, strength and quality of the bobbins is strongly affected by the following parameters:
The winding angle α arises from the selected winding ratio V.
Stepped precision winding is a mixture of two basic winding methods of how to wind the supplied band onto a bobbin core, namely between “random winding” and “precision winding”.
The characteristic feature of random winding is a constant winding angle α contrasted by a variable ratio between the number of bobbin rotations and the traverse speed (=variable winding ratio V). In the winding ratio/bobbin diameter chart of
Disadvantageously, the number of windings per winding layer thereby decreases steadily as the bobbin diameter increases so that a bobbin is created whose band material has a different packing density at every bobbin diameter. Another adverse effect occurring during winding, referred to as “pattern development”, arises at certain ratios between bobbin diameters and traverse speeds, whereby, at those ratios, several layers of bandlets are superimposed almost exactly, thereby rendering the bobbin unstable. Therefore it is necessary to take measures to create “pattern interference”, f.i. wobbling.
Precision winding, on the other hand, is characterized by a constant winding ratio along the entire increasing bobbin diameter, which in turn means that the winding angle will decrease as the bobbin diameter increases. In the chart of
So as to alleviate the respective disadvantages of random winding and precision winding and combine their advantages, the “stepped precision winding” was recommended in the past. Said winding method is based on the concept that the winding ratio between predefined limiting diameters of a bobbin is kept constant and is changed in steps to a different value as soon as a respective limiting diameter has been reached, with the values of the winding ratios being chosen such that a graph of the winding ratio will roughly follow, across the bobbin diameter, the graph of a random winding for a particular winding angle. The advantage of stepped precision winding is that, on the one hand, “pattern development” is avoided since the volatile change of the winding ratio represents a “pattern interference measure”.
On the other hand, the winding angle does not become substantially smaller than the initial winding angle even if the bobbin diameter increases.
While the stepped precision winding yields the expected good result for the manufacture of yarn and thread bobbins, surprisingly poor results are often achieved if band bobbins are produced by stepped precision winding. The inadequacies of those band bobbins range from an irregular and therefore unsightly optical appearance to bobbins with varying, f.i. corrugated, diameters throughout their lengths, from irregular spindle fronts to an unstable winding structure.
Since such bobbins are usually used in rapidly operating machines such as circular looms, each irregularity of the bobbin structure can have fatal results, which, as the smallest consequence, will result in the rupture of the band as it is drawn off from the bobbin and, in the worst case, will involve the destruction of a part of the machine. Such damages are caused by unbalanced masses at irregular bobbins, by vibrations in the bands that gradually build up as they are drawn off etc. Furthermore, irregular bobbins will heat up rapidly if the bands are drawn off quickly, thus leading to fatigue and weakening of the band material, in particularly if said material is oriented plastic bands.
For that reason, a strong demand for an improved process of stepped precision winding exists in the industry.
The present invention provides such an improved process of stepped precision winding, characterized in that the winding ratio is changed stepwisely in essentially integral steps. The inventors have indeed discovered that the reason for an unsatisfactory bobbin structure during stepped precision winding lies in the sudden change in the layer pattern of the bands, caused by the stepwise change of the winding ratio and representing a point of discontinuity for the overall structure of the bobbin. In the worst-case scenario, those changed layer patterns will accumulate and lead to the above-mentioned irregularities or unequal packing densities. However, due to the measure according to the invention, the layer pattern will remain substantially unchanged even upon a stepwise change in the winding ratio so that a bobbin with an excellent structure, i.e. regular appearance and high packing density, will arise. A stepwise change in the winding ratio in essentially integral steps means that, with each change, the post-decimal point part of the winding ratio will change by 0.1 at the most, preferably 0.03 at the most, more preferably 0.01 at the most.
According to a preferred embodiment of the invention, with each change in the winding ratio, the post-decimal point part of said ratio is changed to such a degree that a constant partial overlap with an underlying band track will result, such as illustrated below by way of an example. In this way, a very stable bobbin structure is achieved.
If the winding ratio is integral, i.e. if the winding ratio has no decimal-point part, pattern development will occur on the bobbin. In order to eliminate such pattern development, which renders the bobbin structure unstable, it furthermore is suggested according to the invention that the winding ratios are chosen such that their post-decimal point parts are at least two-digit. Furthermore, it is preferred for bobbins with plastic bands that the winding ratios are chosen to be close to 0 or 0.50 or 0.33 or 0.25, whereby the reversal points of the band at the front side of the bobbin will end up lying close to each other again after one, two, three or four to-and-fro strokes of the traversing band guide. Depending on the width of the bands to be wound up, the winding ratio can be changed such that a forward or backward-moving band winding is created or maintained, respectively.
Furthermore, certain winding angle ranges can be empirically specified for the respective widths of the bands and their material properties, which ranges provide for the best possible structure of the bobbin. In order to achieve this best possible bobbin structure, it is provided for the winding ratio to be changed such that the resulting winding angle will stay within said predetermined range. In case of oriented plastic bands with a width of between 2 and 10 mm, a winding angle range of 4 to 6° has proven to be advantageous, for instance.
In order to be able to adjust the winding ratios according to the invention with the required accuracy, it has proven to be beneficial if the bobbin is driven by a separate motor and the cross-winding device is also driven by a separate motor and the change in the winding ratio is performed electronically by stepwisely changing the ratio of the speeds of the two motors. Motors which are constructed as rotary-current drives with frequency converters or as direct-current drives can be controlled particularly well.
Furthermore, the instantaneous bobbin diameter can be calculated with great precision from a variance comparison of the linear band speed and the number of bobbin rotations.
By way of exemplary embodiments, the invention will now be explained in further detail with reference to the drawings. In the drawings:
A winding machine for carrying out the process according to the invention, as shown in simplified manner in
The winding machine is operated by a process of stepped precision winding. This means that, starting from an initial winding angle, at first a certain winding ratio is maintained when winding the band onto a bobbin core (thereby changing the winding angle). If the diameter of the bobbin reaches a predetermined value, the winding ratio will stepwisely be adjusted to a new value, which in turn will be maintained until the bobbin diameter has increased to another predetermined value, whereupon the winding ratio will again stepwisely be adjusted to a new value.
The winding ratio is adjusted by an “electronic gear”, i.e. an electronic regulation of the ratio between the speeds of the motor M1 driving the bobbin 2 and of a motor M2 reciprocating the cross-winding device 4. Again and again, the virtual “transmission ratio” of the two motors is stepwisely changed electronically upon reaching a certain diameter by imparting a changed speed to the traverse drive M2. Preferably, the drives M1, M2 are rotary-current drives with frequency converters or direct-current drives.
The instantaneous bobbin diameter is calculated, for example, from a variance comparison of the linear thread speed and the number of bobbin rotations.
In the chart of
In order to eliminate “pattern development”, the post-decimal point part of all winding ratios is chosen such that in each case at least two decimal places are provided; actually, the winding ratios exhibit even three decimal places except in the area where the bobbin diameter amounts to 125 mm. The post-decimal point part is close to 0.5 (actually between 0.557 and 0.514) so that the reversal point of the band will end up lying close to the previous reversal point again after two to-and-fro strokes of the cross-winding device. Further preferred value ranges of the post-decimal point part of the winding ratio are close to 0 or 0.33 or 0.25. However, none of those values should themselves be applied, since, in such case, pattern development would occur at every to-and-fro stroke or after three or four to-and-fro strokes of the cross-winding device, respectively. For a better understanding of the correlation between the post-decimal point part of the winding ratio and the shift angle, a bobbin 2 is schematically illustrated in front view in
Furthermore, it is preferred that the winding ratio is adjusted such in each case that a constant partial overlap of the band to be wound up with an underlying band track will result. If bands are wound onto bobbins, the following configurations of superimposed band tracks as illustrated in
In a preferred embodiment of the winding process according to the invention, each time the winding ratio is changed, the post-decimal point part of said ratio will be changed to such a degree that a constant partial overlap with an underlying band track will result. The ratio between the axial shift d and the winding ratio V can be determined from the following formula:
wherein the following applies:
By means of the above-indicated formula, a person skilled in the art is able to determine, from a desired shift d, the winding ratio V that is necessary therefor. In practice, it has turned out to be advantageous for the design of a bobbin with excellent stability that the shift d is selected such that an overlap of bandlets of appx. ½ a bandlet width b emerges (see
In case of a “forward-moving” winding of the band material, the band 5 being wound onto the bobbin 2 is deposited in front of the band material 5a located on the bobbin 2 which rotates in the direction of arrow 9, such as illustrated in
The above-indicated formula may also be rephrased such that the shift d can be calculated based upon a winding ratio that is known:
Number | Date | Country | Kind |
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A 770/2003 | May 2003 | AT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/AT04/00162 | 5/10/2004 | WO | 11/28/2006 |