EP0421924B1 - Process and device to repair warp defects in a loom - Google Patents

Description

The invention relates to a method and a device for eliminating warp thread breaks in a weaving machine, in which an auxiliary warp thread is drawn in towards the weaver side by means of a pulling device.

A method of this type is known from European patent application No. 0 259 915, but the warp thread break is not finally eliminated. An auxiliary warp thread is only drawn up to the reed.

It is an object of the present invention to provide a method and a device for correcting warp thread breaks, with or in which the warp thread break is quickly and completely eliminated.

This object is achieved in that the auxiliary warp thread is inserted by means of the device for pulling into at least one part through which the warp thread passes, such as a guard slat, a heald and a perforated needle inserted through the reed by the auxiliary warp thread being inserted into the guard slat as required by two pull-in tubes , Heald, perforated needle each from one Side to the other of the part in question is passed, alternately one or the other pull-in tube passes or takes over the auxiliary warp thread and the pull-in tubes move gradually from one part to the other, for example from the guard slat to the heald and from the heald to the needle.

In this way, the auxiliary warp thread is drawn in from the warp beam to the fabric edge and further beyond the fabric, so that the weaving operation can be continued without further interruptions. The ends of the previously extracted broken warp thread and the auxiliary warp thread lying on the fabric are either cut off a few weaving cycles after being drawn in or later, for example during the fabric inspection.

Fig. 1

schematisch eine Seitenansicht auf den Webbereich einer Webmaschine vom Spannbaum bis zum Gewebe;

Fig. 2

eine perspektivische Darstellung des Schwerts mit den Einziehrohren und einer Litze;

Fig. 2a

eine Teilansicht auf das Schwert gemäss Pfeil II in Fig. 2;

Fig. 2b

eine Seitenansicht eines Einziehrohres;

Fig. 3

eine Teilansicht auf den Webbereich vom Spannbaum bis zum Kettfadenwächter;

Fig. 3a

in einer Teilansicht den Grundriss der Anordnung in Fig. 3;

Fig. 3b

den Einziehvorgang in eine Wächterlamelle des Kettfadenwächters;

Fig. 4

eine Teilansicht des Webbereiches bei den Weblitzen und beim Webblatt;

Fig. 4a

den Einziehvorgang in das Webblatt;

Fig. 4b

einen Grundriss der Anordnung gemäss Fig. 4 als Ansicht gemäss Pfeil IV; und

Fig. 5

die gesamte Einrichtung zur Behebung von Kettfadenbrüchen in perspektivischer schematischer Darstellung.

The invention is described in more detail below with reference to the figures. Show it:

Fig. 1

schematically a side view of the weaving area of a weaving machine from the tension tree to the fabric;

Fig. 2

a perspective view of the sword with the pull-in tubes and a strand;

Fig. 2a

a partial view of the sword according to arrow II in Fig. 2;

Fig. 2b

a side view of a pull-in tube;

Fig. 3

a partial view of the weaving area from the tension tree to the warp thread monitor;

Fig. 3a

in a partial view the plan of the arrangement in Fig. 3;

Fig. 3b

the pulling process into a warp slat of the warp thread guard;

Fig. 4

a partial view of the weaving area with the healds and the reed;

Fig. 4a

the pulling process into the reed;

Fig. 4b

a plan view of the arrangement of Figure 4 as a view according to arrow IV. and

Fig. 5

the entire facility for rectifying warp thread breaks in a perspective schematic representation.

In Fig. 1, the warp 10 is deflected into the horizontal via the tensioning tree 14. In the warp thread monitor 2 with the slats 20, 21, a slat 21 is in the contact position on the contact rail 23, since the warp thread 11 drawn into it is broken. As will be explained in the following, a narrow lane can be formed in the warp chain 10 by means of the lamella 21 and the contact rail 23, into which a sword 50 is inserted to widen the lane. Before being immersed in the warp 10, the sword 50 is controlled horizontally in the weft direction of the weaving machine to the height of the guard plate 21 by means of a travel drive, not shown. The position of the guard slat 21 and thus the desired position for the sword 50 can be determined, for example, with a special commercially available warp thread monitor, by the resistance of a wire in the weft direction from one side of the warp thread monitor 2 to the contact point the guard plate 21 is determined, from which its position can be determined in a simple manner if the resistance per unit length of the wire is known. The end of the broken warp thread 11 lying on the warp side is detected by a removal device 80, for example with a suction nozzle 81, which was controlled in the same position as the sword 50 via the alley formed between the warp threads 12, 13. The suction nozzle 81 pivots in the direction of arrow 81 'to a cutting and holding device 82, where the portion of the broken warp thread 11 held by the suction nozzle 81 is deposited and severed in order to be connected to an auxiliary warp thread 1 in a subsequent operation. On the other side of the warp thread monitor 2 in FIG. 1, the end of the broken warp thread 11 located there can also be grasped and pulled up by means of the suction nozzle 81. This is necessary so that when the sword 50 is moved in the direction 50˝, the broken warp thread 11 cannot build up on its front side in the direction of the arrow 50˝. By moving the sword 50, as can be seen from FIG. 4b, a free working space is also created in the area of the package of heald frames 3, in which strands 30 and 31 are guided. All strands 30 with intact warp threads are thus laterally displaced with the exception of the strand 31, into which the auxiliary warp thread 1 is to be drawn. It is assumed that the broken warp thread 11 is passed through the strand eye 32 of the strand 31. This strand is later selected by the sword 50. On the front side of the package 3 of the heald frames, the section of the broken warp thread 11 lying there can be gripped by the suction nozzle 81˝ and pulled into position 11˝ in FIG. 1 on the reed 4. The broken warp thread 11˝ can be easily detected in this uppermost position by a suction nozzle 83, since it lies above the other warp threads 12, and forward over the Tissue 100 are drawn by means of the suction nozzle 83. The parts of the broken weaving thread 11 are thus removed from the weaving area. It is expedient to steer the warp 10 into the shed closing position, all of the heddle eyes 32 being at the same height as shown in FIG. 1.

2, the sword 50 is shown in a working position with the healds 30, 31. Above the tip 51 of the sword 50, wings 50a, 50b extend from the sword 50, which become wider along the shaft 50c with increasing height. The ends 500a, 500b of the wings 50a, 50b are directed toward each other inwards so that the individual warp threads 12, 13 are not deflected brusquely when the sword 50 is moved against the arrow II within the warp. In the wings 50a, 50b, in the displacement direction of the sword 50, in front of its shaft 50c, there is a sensor 54 and a light source, which generate a signal when the sword is moved in the direction of arrow 50˝ when the strand 31 into which the auxiliary warp thread 11 is inserted should be at the level of the connecting line V of the sensor 54 and the light source 55. The device 5 for locating the heald 31 with the sword 50 is then only moved further by the distance between the connecting line V and the groove 52 in the shaft 50c, so that the device 5 comes to a standstill after the heald 31 has been retracted into the groove 52. After the position of the strand 31 has been determined by the sensor 54 and the sword has come to a standstill after the strand 31 has been retracted, the pull-in position for the pull-in tubes 71 and 72 is thus also determined beforehand. The controller S of the device 101 according to FIG. 5 registers for this the movement of the arm 56, the sword 50, and controls the arms 715 and 725 of the pull-in tubes 71 and 72 so that they come into the threading position in the strand 31. In the position shown in FIG. 2, the Auxiliary warp threads can be threaded into the heddle eye 32 by pushing the device 7 for pulling in a warp thread into the opening 53 of the sword 50, the blowing opening 72a of the left draw-in tube 72 according to FIG. 2a on one side of the heddle eye 32 auxiliary warp thread 1 through the heddle eye 32 blows into the suction opening 71c of the right-hand pull-in tube 71. This process can also be seen in the plan in Fig. 4b.

2b shows the right-hand draw-in tube 71 in a side view, the suction opening 71c, a slot 71b and the blowing opening 71a being visible. An air flow L through the draw-in tube 71 creates a negative pressure at the suction opening 71c and leaves the draw-in tube through the blow opening 71a, the flow being deflected at right angles to the longitudinal extent of the draw-in tube 71. The auxiliary warp thread 1 can be pulled out of the pull-in tube 71 again through the slot 71b when the pulling-in process has ended. The suction of the auxiliary warp thread 1 into the suction opening 71c is supported in that the blowing opening 72a of the left-hand pull-in tube 72 lies opposite the suction opening 71c.

3 shows the weaving area in the warp thread monitor 2 while the auxiliary warp thread 1 is being drawn in. The sword 50 is immersed in a movement according to arrow 50 'in the warp 10 and has a widened alley, as can be seen in Fig. 3b. Fig. 3a shows the moment of immersion of the sword 50 between the warp threads 12 and 13, which are adjacent to the broken warp thread 11. The guard plate 21 is in its lowered position 21 'inclined, whereby the alley has formed between the adjacent warp threads for the immersion of the sword 50. The inclination of the slat 21 can be done achieve that slots in the contact rail 23 are made oblique and the contact rail 23 and a mounting rail 22 are moved in the longitudinal direction against each other. Such a warp thread monitor is shown, for example, in Swiss patent specification 169 657. The lamella 21 is gripped by a holder 24 and pulled up for the subsequent pull-in operation.

A section of the broken warp thread 11 in FIG. 3 has been connected in a knotting or splicing device 76 to a cut-off piece of an auxiliary warp thread 1. The auxiliary warp thread is fed to the device 7 for pulling in the auxiliary warp thread 1 by means of a metering and feeding device 73 with a pair of rollers 74. The pair of rollers 74 can pass the auxiliary warp thread 1 in a rotating manner, and after the end of the transport of the auxiliary warp thread 1, the pair of rollers is separated in the direction of arrow 73 '. In the device 7 for pulling in the warp thread 1, the auxiliary warp thread is guided horizontally to the warp thread monitor 2 through the right pull-in tube 71, for example according to FIG. 3b. The auxiliary warp thread 1 is then inserted into the guard slat 21 and blown further into the left draw-in tube 72.

As soon as the sword 50 is in its working position according to FIG. 4 at the heald 31, the left draw-in tube 72 can be pushed as described above to the heald eye 32 of the heald 31, where the auxiliary warp thread 1 through the heald eye 32 back into the right draw-in tube 71 is threaded. To pull into the reed, the pull-in tube 71 can be moved further according to the arrows 71 'in Fig. 4a. Through the reed 4, a perforated needle 60 is inserted between the leaf lamella 40 from the tissue 100. The perforated needle comes to coincide with the right pull-in tube 71, after which the Auxiliary warp thread is blown into the piercing needle. 4a shows that the pull-in needle 71 and the perforated needle 60 lie above the uppermost warp thread 12, the threading process being able to proceed unhindered. As mentioned, all the warp threads 12 and 13 can also be horizontal, or the position of the fabric 100 is changed by pulling it down. This can be achieved by moving a fabric support (not shown) downwards or by moving all heald frames 3 downwards. In this case, the perforated needle 60 can remain at the level of the closed position F according to FIG. 4a. Then the perforated needle 60 is pulled back in the direction of arrow 60 'by the reed 4 until the new auxiliary warp thread 1 which is drawn in lies over the fabric 100. A thread clamp 61, which rests laterally on the piercing needle, prevents the auxiliary warp thread 1 from sliding out of the piercing needle 60 prematurely.

In Fig. 5 the functional elements of the device 101 are shown schematically with drive means. The sword 50 is displaced horizontally and vertically by an arm 56 in the direction of the arrows at 56, and the pull-in tubes 71 and 72 are displaced horizontally by means of the arms 715 and 725, respectively. Rollers 710 are provided for guiding and driving the arms 715, 725.

After removal of the broken warp thread from the warp 10, an auxiliary warp thread spool 10 'is first drawn off by means of an auxiliary blowing tube 73' and the warp thread is inserted into the auxiliary tube 72 '. The auxiliary warp thread 1 moves in the direction of the pair of rollers 74. The auxiliary warp thread is detected by the pair of rollers 74 and introduced into a memory 75, which the auxiliary warp thread first traverses horizontally until it passes the sensor 91. With the delivery of a sensor signal from the sensor 91 to the control S when the weft thread runs past, a counter is set in motion which holds the revolutions of a drive motor 74 'in the pair of rollers 74. The pair of rollers 74 then continues to run until a predetermined number of revolutions of the drive motor 74 'or a predetermined length of the auxiliary warp thread 1 is reached. The tip of the auxiliary warp thread 1 has meanwhile reached the splicer 76 through the memory 75, in which the tip of the auxiliary warp thread is detected after a signal from the sensor 94 has been emitted as the auxiliary warp thread passes. When the auxiliary warp thread is conveyed further by the pair of rollers 74, an auxiliary warp thread supply will then form in the memory 75. The suction nozzle 81, which has sucked in the broken warp thread from the warp 10, inserts it into the knotting or splicing device 76, where it is connected to the tip of the auxiliary warp thread 1. Then the end of the broken warp thread 10 'in the suction nozzle 21 can be cut off by scissors 79. When the conveying and storing process of the auxiliary warp thread 1 has ended, the pair of rollers 74 stands still and then reverses its direction of rotation according to arrow 74b. At the same time, blowing air is introduced into the auxiliary pipe 72 'in the conveying direction to the pull-in pipe 71. The auxiliary warp thread was previously cut by scissors 77. By turning the pair of rollers 74 backwards, the auxiliary warp thread 1 is now controlled through the auxiliary tube 72 ', which is slit laterally, moved to the pull-in tube 71. From there, as described, the auxiliary warp thread is blown into the lamella 21 and further into the draw-in tube 72. The remaining process steps were also set out above. The pull-in pipes 71 and 72 are temporarily supplied with blown air via the air connections 71d and 72d. In the control S is the program for the on and that Switching off the blown air for the pull-in pipes 71 and 72 stored.

Claims (8)

1. A method of clearing warp yarn breakages in a loom wherein draw-in means draw in a reserve warp yarn (1) towards the operator's end of the loom, characterised in that the draw-in means (5, 6, 7) draw the reserve warp yarn (1) into at least one member through which the warp yarn passes, such as a warp stop motion lamella (21), a heddle (31) and a guide (60) pushed through the reed (4) from the front, the reserve warp yarn (1) being fed through two draw-in tubes (71, 72) as required into the stop motion lamella (21), heddle (31) and guide (60) from one side to the other of the particular member (21, 31, 4) concerned, one draw-in tube (71) or the other draw-in tube (72) alternately transferring and taking over the reserve warp yarn (1), the draw-in tubes (71, 72) moving stepwise from one member to the other, for example, from the stop motion lamella (21) to the heddle (31) and therefrom to the guide (60).
2. A method according to claim 1, characterised in that once located the broken warp yarn (11) is engaged and severed at the warp end by means of an extractor (80) for connection to the reserve warp yarn (1) by a knotter or splicer (76) and after the insertion of a blade (50) the broken warp yarn (11) is at the operator's end (100) first engaged and raised by the extractor (8) between the group (3) of heddle shafts and the reed (4) through the agency of a suction nozzle (81˝), then raised by means of a second suction nozzle (83) between the reed (4) and the cloth (100) and conveyed back over the cloth (100) outside the weaving zone.
3. A method according to claim 1, characterised in that the reserve warp yarn is conveyed stepwise into the weaving zone by means of a dispensing and feeding device (73), one of the draw-in tubes (71) sucks in the reserve warp yarn (1) laterally through a suction orifice (71c) and advances it as far as the stop motion lamella (21) into which the reserve warp yarn (1) is required to be drawn and there the reserve warp yarn (1) is eased off the dispensing and feeding device (73) and blown through a blowing orifice (71a) through the lamella (21) into the suction orifice (72c) of the other draw-in tube (72) which therefore takes over the reserve warp yarn (1) by drawing the same from a slot (71b) between the suction orifice (71c) and the blowing orifice (71a) of the first draw-in tube (71).
4. A method according to claim 1, characterised in that one draw-in tube (72) blows the reserve warp yarn (1) through its blowing orifice (72a) into the heddle guide (32) of a heddle (31) centred in the blade (50) and the reserve warp yarn (1) is taken over by the suction orifice (71c) in the draw-in tube (71) on the other side of the heddle guide (32).
5. A method according to claim 1, characterised in that the reserve warp yarn (1) is blown into the guide (60) by means of the draw-in tube (71), drawn back by the guide (60) through the reed (4) and after having been drawn therethrough is pressed by means of a yarn clamp (61) on to the guide (60) so as to be kept tensioned.
6. Means for the practice of the method according to claim 1 for clearing warp yarn breakages in a loom having a warp yarn stop motion (2) having stop motion lamella, means (7) for drawing in the warp yarn and further means for selecting the heddle, characterised in that the draw-in means (7) are embodied by two draw-in tubes (71, 72) formed laterally with a blowing orifice (71a), a slot (71b) and a suction orifice (71c), a suction orifice (71c) being opposite a blowing orifice (72a) alternately during the drawing-in operation for the transfer of the reserve warp yarn (1).
7. Means according to claim 6, characterised in that means (6) for threading-up the reed are provided in the form of a guide (60) which can extend through the reed (4) and which for threading-up is movable before the exit orifice (71a) of one drawing-in tube (71).
8. Means according to claim 7 , characterised in that a yarn clamp (61) is associated with the guide (60) to retain the reserve warp yarn (81) in the guide.

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