EP0293558A1 - Weft thread selection device for a loom - Google Patents

Abstract

The device contains a number of thread feeders (8, 8a), which are each arranged between the shed (2) and a weft supply spool and, depending on an actuating device (electromagnet 25), each have a drive part (push rod 16, 16a) between a standby position and a transfer position is adjustable, in each of which a weft thread (3, 3a) is presented to a weft insertion member (rapier head 11) for a subsequent weft insertion. The drive parts (push rods 16, 16a) can optionally be coupled to and decoupled from a driver (32) which is driven to oscillate in the rhythm of the weft insertion frequency, and each with an active actuating device (electromagnet 25) via a blocking element (lever arm 23) in one of the transfer positions of the thread feeder ( 8, 8a) corresponding working position can be blocked and decoupled from the blocking element (lever arm 23) in the case of a passive actuating device (electromagnet 25). Accordingly, the relevant thread feeder (8), provided that the same weft thread (3) is also intended for the next weft insertion, remains in the transfer position after the thread transfer and is only returned to the ready position before a weft thread change. This avoids unnecessary adjustment movements of the thread feeders (8, 8a) and low stresses on the device and the weft threads (3, 3a) are achieved.

Description

The invention relates to a weft selection device for a weaving machine with weft supply bobbins arranged outside the shed, with a number of thread feeders each intended for guiding a weft thread, each optionally via a drive part, which is driven in an oscillating manner by means of an associated actuating device with an oscillating rhythm of the weft insertion frequency Carrier can be coupled and decoupled from it, can be adjusted back and forth between a ready position and a transfer position, the respective weft thread being presented in the transfer position to a weft insertion element that can be inserted into the shed for a subsequent weft insertion.

In previous selection devices of the type mentioned, each thread feeder is moved back from the transfer position to the ready position after the thread transfer to the weft insertion member and is kept ready in this position for a further weft insertion, for which the weft thread guided by the thread feeder concerned is presented to the weft insertion member should. In a selection device of this type known from DE-PS 32 14 800, the thread feeders are each articulated to a fixedly mounted swing arm, which can be coupled to an electromagnet via a magnet armature arranged on it, which is mounted on a carrier carrier which vibrates in a rhythmic manner with the weft insertion frequency is arranged. The driver carrier can be pivoted via a cam drive between a rest position corresponding to the ready position of the thread feeder and a working position corresponding to the transfer position of the thread feeder and has a crossbar which carries all the electromagnets assigned to the swing arms. In accordance with the program controlling the weft thread selection, one of the swing arms is coupled to the driver carrier via the assigned, excited electromagnet and, together with the associated thread feeder, is led from the ready position to the transfer position. After each weft insertion, the thread feeder is returned from the transfer position against the ready position, even if the same weft thread is also intended for the immediately following weft thread insertion and the thread feeder in question for this or any further immediately following weft insertion from the standby position just reached is moved to the transfer position. Due to the unnecessary return and forward movements of the thread feeder and the corresponding deflection and feed movements of the weft thread, the interacting parts of the weft thread selection device and the weft threads are unnecessarily stressed, in particular a disadvantageous reduction in the operationally predetermined tension of the weft thread can move back and forth between a stretched position and a deflected position.

The invention has for its object to provide a weft thread selection device which is improved in this regard in particular and which allows the number of adjustment movements of the thread feeder and the drive parts interacting therewith to be limited to a minimum determined in each case solely by the predetermined program of the weft thread sequence and thus a corresponding one Reduction of the stress on the interacting parts of the device and a correspondingly quieter, gentler guiding of the weft threads compared to previous designs is guaranteed.

This object is achieved according to the invention in that the drive part is coupled to an actuating element of the actuating device via a fixedly mounted guide part which can be moved back and forth against the movement area of the driver and has a stop part which can be engaged in the movement area of the driver when the actuating device is active and can be disengaged in the case of a passive actuating device , and that the drive part is assigned a blocking element that can be controlled via the adjusting device, which can be adjusted between a release position that can be taken with a passive adjusting device and permits relative movements of the drive part and a blocking position that can be taken with an active adjusting device, and via which the drive part in a working position corresponding to the transfer position of the thread feeder active actuator can be blocked.

The design of the weft thread selection device according to the invention allows a temporary decoupling of the thread feeder that is in the transfer position and the drive parts interacting therewith from the driver that is inevitably driven at the rate of the weft insertion frequency, provided that the adjusting device assigned to the thread feeder concerned - corresponding to the respective weft thread selection program - for the Weft insertion of the same weft thread remains activated in the following weaving cycle. If a different weft thread is provided for the weft insertion for the following weaving cycle, the blocking element is released by the blocking element which is appropriately moved into the release position in the case of a passive adjusting device and is returned to a rest position corresponding to the ready position of the thread feeder.

From DE-PS 26 44 648 a weft selection device of the type mentioned is known in which each of the thread feeders is assigned a locking hook connected to a control magnet, by means of which one end of a pivotable drive lever connected to the thread feeder is held when the magnet is excited . Through the locking hook of this known device, however, only the articulation point of the drive lever is determined when the thread feeder is pivoted. By means of the drive levers which can optionally be articulated on the locking hook, the thread feeders are also returned from the transfer position to the ready position after each thread transfer in this arrangement. A blocking of the thread feeder in the transfer position is not provided for in this known device and is also not possible.

Embodiments of the subject matter of the invention are specified in the dependent claims.

The embodiment emphasized in claim 2, in which both the drive and the blocking of the thread feeder take place via the same drive part directly adjoining the driver, results in a particularly compact and reliable construction of the device, which in particular requires small adjustment paths of the interacting parts.

The embodiment according to claim 7 allows the use of actuating devices with small actuating forces, since these actuating devices are only provided for the transmission of the switching information to the actuating device, while the blocking and releasing of the drive part connected to the relevant thread feeder takes place in each case via the actuating device coupled to the machine drive .

The embodiment according to claim 9 allows, within certain design limits, an arrangement of the drive, blocking and control parts interacting with the driver that is largely independent of the operational arrangement of the thread feeders. In particular, the adjustment of the weaving machine to different weaving widths only requires a corresponding adjustment of the thread feeder, while the drive parts interacting with the driver can remain in their position given by the connection to the machine drive.

• Fig. 1 Teile einer erfindungsgemäss ausgebildeten Schussfaden-Auswählvorrichtung mit einem in Bereitschaftsstellung gehaltenen Fadenzubringer;
• Fig. 2 die Vorrichtung nach Fig. 1 mit in Uebergabe­stellung gehaltenem Fadenzubringer;
• Fig. 3 Teile einer erfindungsgemäss ausgebildeten Schuss­faden-Auswählvorrichtung in einer abgewandelten Ausführungsform, mit einer zugeordneten Betäti­gungseinrichtung und mit einem in Bereitschafts­stellung gehaltenen Fadenzubringer;
• Fig. 4 die Vorrichtung nach Fig. 3 mit in Uebergabestellung gehaltenem Fadenzubringer;
• Fig. 5 und 6 die Vorrichtung nach Fig.3 mit in Bereitschaftsstellung gehaltenem Fadenzubringer, bei unterschiedlichen Betriebsstellungen der Betätigungseinrichtung;
• Fig. 7 Teile einer erfindungsgemäss ausgebildeten Schuss­faden-Auswählvorrichtung in einer weiteren abge­wandelten Ausführungsform.

Further details emerge from the following description of exemplary embodiments of the invention shown schematically in the drawing in conjunction with the claims. The drawing shows:

• 1 shows parts of a weft thread selection device designed according to the invention with a thread feeder held in the standby position;
• FIG. 2 shows the device according to FIG. 1 with the thread feeder held in the transfer position;
• 3 parts of a weft thread selection device designed according to the invention in a modified embodiment, with an associated actuating device and with a thread feeder held in the standby position;
• FIG. 4 shows the device according to FIG. 3 with the thread feeder held in the transfer position;
• 5 and 6 the device according to FIG. 3 with the thread feeder held in the standby position, in different operating positions of the actuating device;
• Fig. 7 parts of a weft thread selection device designed according to the invention in a further modified embodiment.

A weaving shed 2 formed by warp threads 1 and weft threads 3, 3a of a rapier weaving machine 4 are indicated in FIGS. 1 and 2. The warp threads 1 are not of one The warp beam shown is guided via heald frames 5 against a goods not shown, which receives the fabric 6 formed in the tip of the shed 2. Several weft threads 3, 3a, for example of different colors, are each guided in a manner known per se from a weft storage spool (not shown) arranged outside the shed 2 through a guide eyelet 7 of an associated rod-shaped thread feeder 8 or 8a to the edge 10 of the fabric 6. The thread feeders 8, 8a are parts of the weft thread selection device arranged on the weft insertion side of the weaving machine 4, which can contain a corresponding number, for example eight such thread feeders 8, 8a. 2 shows two of these thread feeders 8 and 8a, by means of which one of the weft threads 3 and 3a is presented to a weft insertion element that can be inserted into the shed 2, in the example shown a gripper head 11, for a subsequent weft insertion. The relevant weft thread 3 or 3a is inserted into the shed 2 by the rapier head 11, which can be arranged in a known manner, for example on a flexible weft insertion belt, not shown, and to the fabric 6 by a reed not shown in the tip of the shed 2 struck.

The thread feeders 8, 8a are each formed on a first arm 13 of a two-armed lever 14 or 14a designed as an angle lever, the second arm 15 of which is articulated to a drive part designed as a push rod 16 or 16a. The levers 14 and 14a, of which only the lever 14 is visible in FIG. 1, can be shown side by side as shown, each pivotable on a possibly common, be fixedly arranged axis 17 which is attached to the frame of the loom 4, not shown. The levers 14, 14a can each be braced under the action of a return spring 18 fastened to the machine frame against a stationary stop part 20 which extends over the arms 13 of all levers 14, 14a. The stop part 20 holds the levers 14, 14a in the rest position shown in FIG. 1, in which the relevant thread feeder 8 or 8a assumes a corresponding ready position, in which the weft thread 3 or 3a is deflected from the range of movement of the hook head 11 .

The push rods 16, 16a can each be clamped by a second return spring 21 fastened to the second arm 15 of the lever 14 or 14a against a guide part in the form of a two-armed latch lever 22, which has a first arm 23 and which can be brought together with the associated push rod 16 or 16a has a second arm 24 which can be brought together with a stationary actuating device, as shown in the illustration with an electromagnet 25. 1 and 2, only the pawl lever 22 cooperating with the front push rod 16 is shown. The pawl levers 22 can, as shown, be pivotably mounted side by side on a common axis 26. Each of the pawl levers 22 can be supported with its arm 24 - under the action of the return spring 21 and a compression spring 27 arranged between the arm 24 and the electromagnet 25 - against a common stop rod 28 which extends over all the arms 24 and through which the arm 24 in question passive electroless associated electromagnet 25 is kept at a short distance from the electromagnet 25.

In this release position of the pawl lever 22 shown in FIG. 1, the push rod 16 is supported with a sliding surface 30 on a support section 31 of the lever arm 23. In this case, the push rod 16 is held in a rest position at a short distance below the range of movement of a driver 32 which is fastened on a shaft 33. The shaft 33 is in a manner not shown, e.g. coupled to the drive of the weaving machine 4 via a known cam arrangement. Via the shaft 33, the driver 32 is inevitably driven to oscillate in the rhythm of the weft insertion frequency - between the rear end position 32 ′ shown in FIG. 1, drawn with full lines, and a front end position 32 ′, drawn with dash-dotted lines. The driver 32 has a ledge section 34 which runs across all the push rods 16, 16a and is intended to be brought together with correspondingly opposing stop parts 35 formed on each of the push rods 16, 16a. The stop parts 35 are each formed on a stepped end section 36 of the surface of the push rod 16, 16a facing the driver 32. The end section 36 is dimensioned such that the stop part 35, when the associated electromagnet 25 is activated, can be engaged from the rest position shown in FIG. 1 in front of the ledge part 34 of the driver 32 located in the rear end position 32 'and thus in its range of motion .

At an end section 37 of the surface facing the latch lever 22, which is offset from the sliding surface 30, each Push rod 16 or 16a is formed a second stop section 38 which is intended to be brought together with a blocking section 40 formed at the end of arm 23 of ratchet lever 22.

The electromagnets 25 are influenced depending on a control device, not shown, in accordance with a predetermined weft selection program. When the electromagnet 25 assigned to the push rod 16 is excited, the arm 24 of the pawl lever 22 is attracted against the action of the compression spring 27, the push rod 16 being raised by the arm 23 and the stop part 35 being brought together with the ledge part 34 of the driver 32. By the driver 32, the push rod 16 is guided along the support portion 31 of the ratchet lever 22 from the rest position according to FIG. 1 against the working position shown in FIG. 2, while the push rod 16a is in its position by the associated electromagnet, not shown, in its Fig. 2 indicated rest position is kept outside the range of motion of the driver 32. Accordingly, the lever 14 with the thread feeder 8, against the action of the return spring 18, is pivoted from the rest position according to FIG. 1 into the transfer position according to FIG. 2, the weft thread 3 being presented to the hook head 11 for the next weft insertion, while the lever 14a is his Maintains the rest position and the weft thread 3a, like the other weft threads, not shown, remains in its position deflected from the range of movement of the hook head 11.

The position of the stop part 38 of each push rod 16 or 16a delimiting the sliding surface 30 is selected so that that in the working position of the push rod 16 shown in FIG. 2, the stop part 38 comes to lie in front of the end of the arm 23 of the pawl lever 22. Accordingly, the push rod 16, under the action of the return spring 21, is placed with the stepped end portion 37 on the end of the arm 23 and adjusted by the driver 32 moved into the front end position 32˝ in a corresponding operating position in which the stop part 38 one of the blocking section 40 assumes a slightly distant release position 38˝, which allows an unimpeded disengagement of the pawl lever 22 from the end section 37.

If the same weft thread 3 is also provided for the next weft insertion, the electromagnet 25 remains energized, so that the pawl lever 22 maintains its blocking position according to FIG. 2. Correspondingly, the push rod 16 following the catch 32 under the action of the return spring 18 is pressed with the stop part 38 onto the blocking part 40 of the ratchet lever 22 and remains in the working position according to FIG. 2. Accordingly, the same weft thread 3 becomes the hook head 11 for the following weft insertion presented, the driver 32 in the drive cycle corresponding to this following weft entry during its movement from the rear end position 32 'against the position shown in solid lines in Figure 2 performs an idle stroke and is only brought together in this position with the stop portion 35, which thereby in a position 35 Stellung corresponding to the front end position 32˝ of the driver 32. If the same weft thread 3 is also provided for the following weft insertion, the processes described are repeated.

If another weft thread is provided for the next weft insertion, after the transfer of the weft thread 3 to the rapier head 11, the current supply to the electromagnet 25 is interrupted, the pawl lever 22 being pivoted back against the release position according to FIG. 1 under the action of the compression spring 27. Accordingly, the pawl lever 22 under the action of the return spring 21 following push rod 16 is released from the 32 'moved back against its rear end position 32 and returned under the action of the return spring 18 along the support portion 31 of the ratchet lever 22 against the position of Figure 1.

When the driver 32 has reached its rear end position 32 ', one of the other push rods, e.g. the push rod 16a, by means of which the electromagnet assigned to it moves into the range of motion of the driver 32, is displaced by the latter in the manner described in the front end position corresponding to the transfer position of the relevant thread feeder 8a, the weft thread 3a being presented to the hook head 11 for weft insertion. According to the weft thread selection program, the thread feeder 8a, like the other thread feeders, not shown, can also be blocked by the assigned ratchet lever in the thread transfer position or released for returning to the ready position.

With the arrangement described, each time the weft thread is changed, the weft thread moved from the standby position against the transfer position is crossed with that after the previous one Weft entry against the ready position of the weft thread avoided, since the respective push rod corresponding to the weft thread to be inserted can only be inserted into the movement range of the driver 32 when the latter takes up its rear end position 32 'and all other push rods accordingly assume their rest positions.

In FIGS. 3 to 7, corresponding parts are provided with the same reference symbols.

The weft thread selection device according to FIGS. 3-6 likewise contains a plurality of thread feeders, of which only the thread feeder 8 is shown, together with the parts of the device assigned to it. In this device, the pawl levers 22 are each connected to the associated electromagnet 25 via an actuating device 43. The actuating device 43 contains a control lever 45 with lever arms 46 and 47 which can be pivoted by means of a fixedly mounted pin 44, a number of feeler levers 48 with lever arms 50 and 51 assigned to each of the latch levers 22 and a corresponding number each between one of the latch levers 22 and the associated electromagnet 25 arranged adjusting levers 53 with lever arms 54 and 55 and a control shaft 56 coupled to the drive of the weaving machine 4. The feeler levers 48 are each pivotally mounted on a common axis 49 which is fastened to the lever arm 46 of the control lever 45. Two corresponding control levers 45 can also be provided, which are connected by the axis 49. The adjusting levers 53 are each pivotally mounted on a common, fixed axis 52.

The control shaft 56, which is designed as a camshaft, interacts with the lever arms 54, which are designed as a magnet armature, of all the actuating levers 53. Accordingly, each of the adjusting levers 53 is adjustable in each case in the rhythm of the weft insertion frequency between a rest position shown in full lines in FIGS. 3 and 6, distant from the electromagnet 25 and from the pivoting range of the lever arm 50 of the feeler lever 48, and a blocking position shown in full lines in FIG , in which the lever arm 54 is applied to the associated electromagnet 25 or at least brought close to it and the lever arm 55 projects into the pivoting range of the lever arm 50 of the feeler lever 48. With passive, i.e. The electromagnet 25 is de-energized, the actuating lever 53 is returned from the locked position into the rest position according to FIGS. 3 and 6 by the compression spring 27. According to the representation according to Figure 4, the actuating lever 53 is activated, i.e. excited electromagnet 25 held in the locked position.

The control lever 45 is coupled to the drive of the weaving machine 4 by a rod 57 articulated on its arm 47, for example via a cam arrangement (not shown), and is inevitably between a rest position shown in full lines in FIG. 3 and a dot-dash line in this figure or 4, 5 and 6 with full lines shown working position 45 'driven oscillating. The feeler levers 48 articulated in the control lever 45 via the axis 49 each have on one lever arm 50 an end section 58 that can be brought together with the end of the lever arm 55 of the adjacent actuating lever 53 and are each via a guide rod 60 movably attached to the other lever arm 51 and a prestressed one Compression spring 61 is coupled to the associated ratchet lever 22, which is designed as an angle lever in the example shown. The guide rod 60 is pivotally articulated at one end on the arm 23 of the ratchet lever 22 containing the blocking section 40 and at the other end in a sliding block 62 which is rotatably mounted on the lever arm 51 and can be displaced in the direction of its longitudinal axis. According to the illustration, the guide rod 60 can be surrounded by the compression spring 61, which is supported on the one hand against a collar of the guide rod 60 and on the other hand against the sliding block 62. The rest position of the feeler lever 48 shown in full lines in FIGS. 3 and 6 and distant from the locking lever 53 is determined by the position of a screw nut 63 which is adjustably arranged at the free end of the guide rod 60 and against which the sliding block 62 is pressed by the compression spring 61.

The arm 23 of the pawl lever 22 supporting the push rod 16 is pressed in the position corresponding to the rest position of the pushrod 16 according to FIGS. 3 and 6 under the action of a prestressed compression spring 64 against a support bracket 65 which extends over the arms 23 of all the pawl levers 22. The compression spring 64 can, as shown, be arranged between the support bracket 65 and the second arm 24 of the pawl lever 22.

In Figure 3, the push rod 16, the control lever 45, the feeler 48 and the actuating lever 53 are shown in their rest positions, which they - with de-energized electromagnet 25 and in the illustrated angular position of the control shaft 52 and in its rear position 32 'driver located 32 - can take at the end of each weaving cycle.

In each weaving cycle, the control lever 45 is inevitably adjusted via the rod 57 from the rest position according to FIG. 3 into the working position 45 ′ according to FIGS. 4, 5 and 6 and back again into the rest position according to FIG. 3. By the control shaft 56 which is inevitably driven according to arrow 66, all adjusting levers 53 are at the same time adjusted from the rest position according to FIG. 3 into the blocking position 53 ′ shown in FIGS. 4 and 5, in which the adjusting lever 53 corresponding to the respectively selected thread feeder 8 is adjusted by the correspondingly predetermined one Selection program excited electromagnet 25 is held. The remaining actuating levers 53, which are not shown on the same axis 52, are each lifted from the corresponding, correspondingly de-energized electromagnet 25 under the action of the compression spring 27 and returned to the rest position according to FIG. 3. The actuated lever 53 held by the energized electromagnet 25 in the blocking position 53 'projects with its arm 55 into the pivoting range of the lever arm 50 of the associated feeler lever 48 and thus forms a stop for the end portion 58 thereof. Accordingly, when the control lever 45 is pivoted simultaneously into its working position 45 'of the feeler lever 48 according to FIG. 3 pivoted clockwise about its axis 49, its arm 51 being pressed against the action of the compression spring 61 against the lever arm 23 of the ratchet lever 22, the sliding block 62 being lifted off the screw nut 63 and the push rod 16 from its rest position 3 is pressed against the driver 32 in the position 16 'shown in FIG. 4 with dash-dotted lines.

According to the illustration in FIG. 4, the stop part 35 of FIG Push rod 16 in front of the driver 32 located in its rear end position 32 ', so that the push rod 16 is subsequently moved into the division of labor shown in full lines in FIG. 4, the thread feeder 8 is pivoted into the transfer position shown and the weft thread 3 is the gripper head 11 for weft insertion is presented. If the same weft thread 3 is provided for the following weft insertion, the electromagnet 25 remains energized, and the push rod 16 is held in the manner already described by the blocking section 40 of the pawl lever 22 engaging in the stepped end section 37 in the working position according to FIG. 4. If a weft thread 3 other than that shown is provided for the following weft insertion, the current supply to the electromagnet 25 is interrupted, so that the feeler lever 48 is released by the adjusting lever 53 pivoted back into its rest position, the pawl lever 22 under the action of the compression spring 64 from the End portion 37 disengaged and the push rod 16 is returned to its rest position according to Figure 3.

FIG. 5 shows the operating position of the device in a weaving cycle, in which a weft thread 3 other than the one shown is provided for the weft insertion and accordingly the thread feeder 8 shown, together with the other thread feeders, not shown, not shown, with the electromagnet 25 de-energized is kept in standby. According to this illustration, the adjusting lever 53 is held in the locking position 53 'determined only by the shape and the angular position of the control shaft 56, in which his arm 55 a stop for the arm 50 of the assigned feeler lever 48, which in the manner described - via the compression spring 61 and the arm 23 of the ratchet lever 22 - presses against the push rod 16. The course and duration of the movement cycles of the driver 32, the control shaft 56 and the control lever 45 are coordinated with one another in such a way that the locking position 53 'determined by the angular position of the control shaft 56' of the actuating lever 53 is only reached when the ledge part 34 of the driver 32 has already moved beyond the position in the rest position of the push rod 16 of the stop section 35 which can be merged with the strip section 34. Accordingly, the push rod 16 is pressed by the arm 23 of the ratchet lever 23 against the driver 32, but is not coupled to it.

According to the illustration in FIG. 6, after a short period of time determined by the shape of the control curve of the control shaft 56, the actuating lever 53 is returned to its rest position under the action of the compression spring 27, so that the feeler lever 48 is released and the latch lever 22 is returned against its support bracket 65 and the push rod 16 is removed from the driver 32.

By cyclically moving the lever arms 54 of all adjusting levers 53 to the associated electromagnets 25, magnets with a low magnetic force can be used, since the forces required for coupling and decoupling the interacting parts of the device are essentially applied by springs 61 and 64.

FIG. 7 shows the thread feeder 8 in the thread transfer position and two further thread feeders 8a, 8b with weft threads 3a, 3b in their ready position.

These thread feeders 8, 8a, 8b are each pivotably articulated on an axis 67 and each are coupled to the associated lever 14 via a flexible transmission part, in the embodiment shown a Bowden connection 68. Correspondingly, the thread feeders 8, 8a and 8b can be set within the design limits given by the dimensions of the weaving machine, regardless of the arrangement of the drive parts interacting therewith — levers 14, push rods 16 and drivers 32. The arrangement of the thread feeders 8, 8a, 8b can therefore be adjusted relative to these drive parts and, for example, set up for different weaving widths of the weaving machine.

As can further be seen from FIG. 7, the surface of the push rod 16 facing the driver 32 can have a concave end section 36a which is designed with a radius of curvature R which corresponds to the radius of the swivel range of the strip section 34. A corresponding concave surface section 39 adapted to this swivel range can also be provided in the middle longitudinal section of the push rod 16 adjoining the stop section 35. As a result, the push rod 16 can be held substantially stationary near the driver 32 or in contact with it, both in the blocked operating position according to FIG. 7 and in the disengaged rest position, so that the engagement and disengagement of the push rod 16 each have correspondingly small adjustment paths of the ratchet lever 22 requires. To limit the A pivot screw 28a can also be assigned to the lever arms 24 as shown in the illustration.

The or some of the contact surfaces of the stop parts 35 and 38, the strip part 34 and the blocking part 40 as well as further, correspondingly interacting contact surfaces of the devices described can each be coated with a wear-resistant material, e.g. Tungsten carbide, coated or formed on an insert made of the appropriate material.

Instead of electromagnets 25, other equivalent, e.g. pneumatic, adjusting devices may be provided. The selection device according to the invention can also be used on weaving machines with other weft insertion means, e.g. Gripper bars, drag guards or the like, are used. The use of a corresponding arrangement is also conceivable for entry systems with a fluid entry medium.

Claims (9)

1.Weft selection device for a weaving machine with weft supply bobbins arranged outside the shed (2), with a number of thread feeders (8, 8a, 8b) each for guiding a weft thread (3, 3a, 3b), each of which optionally via one Drive part (push rod 16, 16a), which can be coupled and decoupled by means of an assigned actuating device (electromagnet 25) with a driver (32) which is driven to oscillate in the rhythm of the weft insertion frequency, and can be adjusted back and forth between a ready position and a transfer position, wherein in the weft thread (3, 3a, 3b) in question is presented to a weft insertion member (rapier head 11) that can be inserted into the shed (2) for a subsequent weft insertion, characterized in that the drive part (push rod 16, 16a) with an adjusting element (arm 24, adjusting lever 53) of the actuating device (electromagnet 25) via a stationary bearing against which Movement range of the driver (32) back and forth movable guide part (pawl lever 22) is coupled and has a stop part (35) which can be engaged in the active actuating device (electromagnet 25) in the moving range of the driver (32) and disengaged in the passive actuating device (electromagnet 25), and that the drive part (push rod 16, 16a) is assigned a blocking element (lever arm 23) which can be controlled via the actuating device (electromagnet 25) and which between a relative movement of the drive part (push rod 16, 16a,) permitting release position and a lockable position which can be assumed when the actuating device (electromagnet 25) is active and via which the drive part (push rod 16, 16a) in a working position corresponding to the transfer position of the thread feeder (8, 8a, 8b) when the actuating device is active (electromagnet 25 ) can be blocked. 2. Selection device according to claim 1, characterized in that the drive part (push rod 16, 16a) is placed in its working position on a blocking section (40) of the blocking element (lever arm 23), placed transversely to the direction of movement of the drive part (push rod 16, 16a) Has stop section (38). 3. Selection device according to claim 2, characterized in that the drive part (push rod 16, 16a) is adjustable beyond the working position corresponding to the blocking position of the blocking element (lever arm 23) into an operating position corresponding to an end position (32˝) of the driver (32), in which the second stop section (38) assumes a release position (38˝) which is removed from the blocking section (40) and relieves the blocking element (lever arm 23). 4. Selection device according to one of claims 1 to 3, characterized in that at least one of the mergable parts (35 and 34 or 38 and 40) of the drive part (push rod 16, 16a) and the associated part (driver 32 or lever arm 23rd ) of the device, at least in the contact area, consists of a wear-resistant material, for example hard metal. 5. Selection device according to one of claims 1 to 4, characterized in that the blocking element (lever arm 23) on the guide part intended for engaging and disengaging the drive part (push rod 16, 16a) into or out of the range of motion of the driver (32) (Ratchet lever 22) is formed. 6. Selection device according to one of claims 1 to 5, characterized in that the guide part (pawl lever 22) with the adjusting element (arm 25) of the actuating device (electromagnet 25) is rigidly connected. 7. Selection device according to one of claims 1 to 5, characterized in that the guide part (pawl lever 22) with the actuating element (actuating lever 53) of the actuating device (electromagnet 25) is connected via an actuating device (43), which has a stationary, in rhythm the weft insertion frequency is driven by an oscillating control lever (45) and a feeler lever (48) articulated thereon, which has a stop part (lever arm 50) which can be brought together with the adjusting element (adjusting lever 53) in a locked position and one with an active adjusting device (electromagnet 25) against the guide part ( Pawl lever 22) has a clampable pressing part (lever arm 51). 8. Selection device according to one of the preceding claims, characterized in that the drive part (push rod 16, 16a) in at least one longitudinal section, which adjoins the catch (32) associated with the stop part (35), a concave with the catch (32) Surface area (36a, 39) which corresponds to the range of motion of the Driver (32) corresponding radius of curvature (R) is executed. 9. Selection device according to one of the preceding claims, characterized in that the connection between the drive part (push rod 16) and the thread feeder (8, 8a, 8b) is a flexible transmission part, e.g. contains a Bowden connection (68).

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