EP0274987A2 - Adjustable yarn-measuring drum - Google Patents

Abstract

With this thread measuring spool (11) it is possible to easily change the diameter of the winding body formed from segments (13). Winding limiting elements (141, 151) in the area of the edge disks (14, 15) are attached in such a way that damage to the thread (11) or winding or underwinding of the winding body by the thread (11) is excluded.

Description

The invention relates to a thread measuring bobbin with a bobbin shaft consisting of a plurality of radially displaceable segments, the length of which essentially determines the bobbin width, and with an edge disk at each end of the bobbin shaft. Such thread measuring bobbins are used, for example, to pull the weft thread from the weft bobbin and to cut the weft thread to length in weaving machines by continuously feeding thread reserves of the same length per unit of time to a memory from which the weft thread is discontinuous, with a weft thread insertion element, e.g. an air jet is inserted in the rhythm of the weft insertion into the shed formed by the warp threads.

The length of the thread reserve and thus in many cases also the thread delivery speed of the thread measuring bobbin should advantageously be changeable. On the one hand, fabrics of different widths are often produced with a weaving machine. On the other hand, depending on the type of fabric that is produced, the weaving machines are operated with the same weaving width with different numbers of turns, ie different number of wefts per unit of time. It is common to use thread measuring bobbins with variable diameters or circumferences, which have a gear with a fixed gear ratio to the main loom drive are driven. The weft thread length is adjusted by changing the diameter of the thread measuring coil, also called the winding drum or spreading roller.

US Pat. No. 4,227,657 describes a thread measuring coil with a variable diameter, in which the shaft, or a band of flexible material forming the winding surface, can be displaced in the spiral grooves of the two peripheral disks. In this embodiment, however, the wound thread can penetrate into the grooves, which can lead to thread breaks as well as under and under-windings. In addition, relatively complex design measures must be taken to align the two peripheral disks in terms of the angle of rotation. Due to the frictional forces between the shaft and the slot walls, the exact setting of the winding circumference is quite difficult and time-consuming.

Even with the spreading roller described in DE-PS 29 28 382, with the mechanically sophisticated threaded spindle construction, the thread can get into the gap between the edge discs and shaft elements, which can also lead to thread breaks under and under windings.

In CH-PS 638 843 a winding drum is described in which the round rods forming the shaft are moved radially in circular segment-shaped grooves in the peripheral discs with the aid of a gear mechanism in each peripheral disc. This construction is mechanically complex and requires the use of round rods as shaft elements and, due to the pronounced polygonal shape of the winding, leads to uneven thread withdrawal from the weft thread bobbin at higher winding speeds, which can lead to thread breaks. In addition, the uneven thread take-off and the associated changing tension of the thread can result in high Voltage peaks, the measuring accuracy or cutting accuracy of the thread measuring coil are deteriorated inadmissibly.

The object of the invention is to provide a thread measuring bobbin with an adjustable diameter and thus variable winding circumference with simple constructional means, the shaft diameter of which can be adjusted in a simple manner in which it is impossible to wind or wrap the thread underneath and which ensures a uniform thread take-off and thus has improved cutting accuracy. This object is achieved according to the invention in that the thread measuring coil has winding-limiting elements in the area of the edge disks, which limit the width of the winding surface of the bobbin shaft, and that the clear width between the winding-limiting elements is smaller than the length of the radially displaceable segments of the bobbin shaft. Such a thread measuring spool allows all segments forming the bobbin shaft to be radially displaced by simply loosening, twisting and tightening again, for example a single adjusting or clamping disk, and thus adapting the circumference of the bobbin shaft of the thread measuring spool to the length required in each case. The winding limiting elements in the area of the edge discs prevent the thread from being wound behind or under the thread measuring spool. The dependent claims relate to particularly advantageous embodiments of the invention.

The invention is explained in more detail below on the basis of the exemplary embodiments illustrated in the drawings and parts thereof.

• Fig. 1 einen Schnitt durch eine erfindungsgemässe Fadenmessspule,
• Fig. 2 und 3 zwei verschiedene Stellscheiben für das radiale Verschieben der Segmente,
• Fig. 4 die Aufsicht auf einen Teil einer Rand­scheibe mit zwei verschiedenen Arten von Wickelbegrenzungselementen und radial verschiebbaren Segmenten,
• Fig. 5 im Schnitt die Seitenansicht eines Segmen­tes, das Wickelbegrenzungselemente und einen fadenschonenden Belag aufweist,
• Fig. 6 ein Segment mit darauf befestigtem, faden­schonendem Wickelbelag mit Träger, in einer Seitenansicht.

Show it:

• 1 shows a section through a thread measuring coil according to the invention,
• 2 and 3 two different shims for the radial displacement of the segments,
• 4 shows the top view of part of an edge disk with two different types of winding limiting elements and radially displaceable segments,
• 5 is a sectional side view of a segment which has winding limiting elements and a thread-protecting covering,
• Fig. 6 shows a segment with attached, thread-saving wrap with carrier, in a side view.

The thread measuring bobbin 1 shown in FIG. 1 is driven via the tubular body 21 with flange 12, which is seated on the shaft 19 by the motor 2. The drive can also take place via a gear directly with the main motor of a weaving machine, not shown here. The segments 13, of which only one is shown in section here, together with the two edge disks 14, 15 essentially form the thread measuring bobbin. The thread 11 is wound on the T-shaped segments 13 forming the drum-shaped bobbin shaft. The segments 13 each have a radially inward extension 131 with a cam 132 which is guided and positioned radially in the spiral groove 161 of the adjusting disk 16, for example. On the other hand, the extension 131 is in the grooves 121 of the Flange 12 guided radially. The jacket parts or segment bases 133 of the T-shaped segments 13 forming the winding cylinder are guided through the edge disks 14, 15 and the winding limiting elements 141, 151. The distance perpendicular to the two edge disks 14, 15 between the winding limiting elements 141, 151 of the two edge disks 14, 15, in the example shown, determines the winding width of the thread measuring bobbin and defines the clear width W between these winding limiting elements, which is smaller than the width B of the the winding body-forming jacket parts or segment bases 133, or the clear width L between the two edge disks 14, 15. With the central screw bolt 17, which is screwed frontally into the drive shaft 19, the clamping disk 18 is pressed axially against the edge disk 14 and the adjusting disk 16 . The radial extension 131 of the segments 13 is clamped between the flange 12 and the adjusting disc 14 when the screw bolt 17 is tightened. The peripheral disk 15 is connected to the flange 13, for example, by a plurality of screws 152, only one of which is shown here.

The radial displacement of the segments 13 and thus the change in the circumference of the thread measuring bobbin 1 takes place in the example shown by turning the adjusting disk 16, which is easily possible after loosening the screw bolt 17. The clamping disk 18 can, for example, have an elliptical ring 182 and the adjusting disk have an elliptical ring 162, which engage in one another and via which rotary movements of the clamping disk 18 are transmitted to the adjusting disk 16. This rotation of the adjusting disc 16 causes and determines, via the spiral groove 161 and the cams 132 guided therein, the radial displacement and positioning of the segments 13. In the desired setting of the Thread measuring coil, the screw bolt 17 is screwed tight, so that the parts of the thread measuring coil are held against one another in a rotationally fixed manner. If the groove 161 of the adjusting disk 16 is spiral, the extensions of the various segments forming the shaft have different lengths, so that the jacket parts or segment bases 133 form a circular-cylindrical coil shaft.

Fig. 2 shows schematically another embodiment of an adjusting disc 16ʹ with a spiral groove 161ʹ, which has a greater change in curvature than the spiral groove 161 shown only in section in Fig. 1 ° limited.

The adjusting disc 16ʹʹ shown schematically in FIG. 3 has eight grooves 161ʹʹ arranged symmetrically around the center Z. The use of an adjusting disk 16ʹʹ with such grooves 161ʹʹ allows segments with the same length of the extension 131 to be used.

4 shows the flange 42 with the edge disk 50. Two different types of winding limiting elements 151 and 52 are shown, which simultaneously serve as radial guide elements for the segments 13 and 33, respectively. In these examples, the winding limiting elements 151, 52 are part of the peripheral disk 50. While the winding limiting elements 151 protrude into the winding space between two segments 13 in each case, the winding limiting elements 52 engage in recesses in the jacket parts or segment bases of the segments 33. The winding limiting elements 52 have, for example, the shape of Half cylinders. The second edge disk, not shown here, also has winding limiting elements. Usually at one certain version of the thread measuring drum uses a certain type of winding limiting elements. Fig. 4 shows, for the sake of simplicity only, two different examples of segments and winding limitation elements on a single winding limitation element. In the practical version, you will choose a unique shape of the winding limiting elements for a thread measuring coil. Both designs limit the winding body formed from the segments laterally in such a way that jamming, back-winding or under-winding of the thread is impossible.

However, as shown in FIG. 5, for example, the winding limiting elements can also be lateral flanks 313ʹ and 313ʹʹ of the segments 313. A thread measuring spool constructed from such segments is in itself largely safe from back-winding. As additional protection against thread damage, the edge discs 144 can also have a cover 144ʹ. In the example shown in FIG. 5, the base or the winding surface of the segment 133 is provided with a rubber-like thread-protecting covering 139. Such protective coverings 139 are also shown on the segments of FIGS. 1 and 4.

In the segment 313ʹ shown in FIG. 6, a carrier plate 39 with the thread-protecting covering 339 is fastened on the jacket part or the segment base 333ʹ. This design makes it easy to replace the worn covering 339.

Claims (11)

1. Thread measuring bobbin, with a bobbin shaft consisting of a plurality of radially displaceable segments, the length of which essentially determines the bobbin width, and each with an edge disk at the two ends of the bobbin shaft, characterized in that the thread measuring bobbin (1) in the region of the edge disks (14, 15) Has winding limiting elements (141, 151, 52) which limit the width of the winding surface of the bobbin shaft and that the clear width (W) between the winding limiting elements (141, 151) is smaller than the length of the radially displaceable (13. 33, 313, 313ʹ) Segments of the spool shaft. 2. Thread measuring bobbin according to claim 1, characterized in that the winding limiting elements (313ʹ) are parts of displaceable segments (313). 3. Thread measuring bobbin according to claim 1, characterized in that the winding limiting elements (141, 151, 52) are parts of the edge discs (14, 15, 50) which project radially beyond the winding surfaces of the segments (13, 133) in both directions. 4. Thread measuring bobbin according to claim 1, characterized in that segments (313) and edge discs (14, 15, 50) have winding limiting elements (313ʹ, 141, 151, 52). 5. Thread measuring coil according to one of claims 1 to 4, characterized in that winding limiting elements (141, 151, 50) are radial guide elements for the segments (13, 33, 313). 6. Thread measuring bobbin according to one of claims 1 to 5, characterized in that each segment (13, 33, 313) has at least one radially directed extension (131) with at least one lateral guide cam (132) and each guide cam in a guide groove (161, 161ʹ, 161ʹʹ) of a rotatable disc (16, 16ʹ, 16ʹʹ) of a radial adjustment device. 7. Thread measuring bobbin according to claim 6, characterized in that each guide cam (132) engages in a spiral groove (161, 161ʹ) of the radial adjustment device. 8. Thread measuring bobbin according to claim 7, characterized in that a rotatable disc (16, 16ʹ) has a single spiral groove (161, 161ʹ) in which the guide cams engage. 9. Thread measuring bobbin according to claim 6, characterized in that the rotatable disc (16ʹʹ) of the radial adjustment device has a plurality of adjusting grooves (161ʹʹ) with the same course, based on the axis of rotation of the thread measuring bobbin. 10. Thread measuring bobbin according to one of claims 1 to 9, characterized in that the segments (13, 33, 313, 313ʹ) on the segment base (333) have an elastic winding covering (339, 139). 11. Thread measuring bobbin according to claim 10, characterized in that the elastic material (339) on a Carrier (33) is applied, which is attached to the segment base (333).

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