CS195267B2 - Apparatus for selectable holding a shift element of textile machines - Google Patents

Abstract

1429154 Traverse mechanism JAKOB MULLER 10 Jan 1974 [10 Jan 1973] 01191/74 Heading D1J [Also in Division E2] An apparatus for selectively holding a reciprocating element 7 of a textile machine in one of its two terminal positions comprises: an energizable electromagnet 2; a holding element 4, the holding element being movable, when the electromagnet 2 is de-energized, from a first position in which it bears against the electromagnet into a second position, and wherein in one of its positions the holding element 4 locks the reciprocating element 7 in one of its terminal positions, there being:- a control mechanism 8, 9, 12, 13 synchronised with the machine for (a) moving the holding element from its second position into its first position; or (b) lifting the holding element off the electromagnet when the electromagnet is deenergized; or (c) carrying out both (a) and (b). 'In Fig. 1 the electromagnet 2, when energized, holds the element 4 out of locking engagement with the reciprocating element 7. When the electromagnet 2 is de-energized and a control cam 13 is rotated to a setting in which the protruding portion 13a of the cam 13 moves away from the roller 12, a lever 8 and therewith a member 9 are rocked clockwise by a spring 11 to permit a spring 6 to rock the element 4 to a setting in which the element 4 engages a notch in the reciprocating element 7. To release the reciprocating element 7 the control cam 13 is rotated until the protruding portion 13a of the cam 13 again rocks the roller 12 and thus the lever 8 upwardly. This causes the member 9 to rock the element 4 clockwise into engagement with the electromagnet 2. The electromagnet may then be energized to hold the element 4. With this embodiment the electromagnet need only be sufficiently strong to hold the element, but not strong enough to attract it away from the element 7. Fig. 3 shows an embodiment similar to Fig. 1 except that the control cam 13 now has a recess 13c; and the previous member 9 that is to the right of nose portion 4a of the element 4 is replaced by a member 14 that is to the left of the nose portion 4a. When the electromagnet is deenergized the spring 6 should rock the element 4 into engagement with the element 7. In case residual magnetism holds the element 4 against the electromagnet the cam 13 is rotated until the roller 12 is able to drop down into the recess 13c. This allows the spring 11 to rock the lever 8 and therewith the finger 14 clockwise so that the finger 14 acts against a part 4a of the element 4 to force it off the electromagnet. Fig. 6 (not shown) shows an apparatus incorporating the member 9 of Fig. 1 and the member 14 of Fig. 3, the cam 13 having a protruding portion 13a and a diametrically approved recess 13c. With this embodiment the element 4 can be mechanically rocked into engagement with the electromagnet by the member 9; be held there whilst the magnet is energized; and when the electromagnet is de-energised any residual magnetism can be overcome by causing the member 14 to rock the element 4 away from the electromagnet. In Fig. 8 the lever 20 is normally in a position such that a groove 20a thereof is in the setting illustrated in broken lines. A nose 18a on a reciprocating plunger 18 then moves freely between stops 20b and 20c at the ends of the groove 20a. When the cam 23 is rotated such that a protruding portion 23a forces the lever 20 to the right, the stop 20b engages the nose 18a and forces an armature plate 17 against an electromagnet 16. The magnet 16 may then be energized to hold the plunger 18 against reciprocation. When the electromagnet 16 is switched off the cam 23 is rotated to present the recess 23c to the roller 22 on the lever 20. The lever 20 then moves to the left and the spring 19 pulls the armature 17 away from the electromagnet 16. Normal reciprocation of the plunger 18 may then take place. If there is residual magnetism in the electromagnet the stop 20c on moving to the left engages the nose 18a to pull the armature 17 off the electromagnet 16.

Description

The present invention relates to an apparatus for:. optional. holding the sliding member of a textile machine, e.g. one end position in 'both' directions, with a retaining member formed as an electromagnet armature, which member is movable. of . the first position adjacent to the electromagnet, to -. second position. and which, in one position, extends into the path of the sliding member to hold it in the end position. · '·. ^: ··· ': · ·'. ''

Such a device is known from DAS No. 1535 270. In this device, the holding body is provided as a leaf spring, formed as an electromagnet anchor which is on One end held by a permanent magnet. This leaf spring extends in the normal position into the heald travel path and is pressed by the movable heald part against the electromagnet. If the solenoid does not wake up, the leaf spring will remain in its position on the solenoid. However, if the solenoid is energized, the leaf spring returns to its normal position due to its spring and blocks the heald. This known solution is very expensive and very expensive in construction. space-consuming because it contains two magnets. In addition, the '' spring bar '' cannot be reliably guaranteed from the electromagnet due to the rema. -. . . · 2 ·. ·. ·:. ·:

the electromagnets that are driven by direct current. ·, '

The object of the invention is to improve the known. device to be ". simple construction and. space-saving, and 'working' even at great 'working' machine speeds perfectly and without failures, it is to create a device to ensure 'reliable' lift up of the retainer. or the electromagnet should be as small as possible.

This object is achieved according to the invention in that the armature of the electromagnet. Yippee . provided with a cam which is v. Operatively connected to at least one actuator provided on the lever, and the free end of the lever is connected to one end of the first spring, the second end of which is connected to the magnet magnet holder, the electromagnet armature being one end of the second spring, the other end of which is connected to the electromagnet holder.

... The development of the invention lies. in that the lever with the actuating device consisting of at least one actuating bar is pivotally arranged on the pin and in the center of the lever a roller is provided which engages on the control disc. /,

A preferred embodiment of the invention. it also consists in that the 'lever' with the operating mechanism,. made up of at least one stop, it’s sliding in its holder and is on its poison

195287 nom end provided with a pulley that abuts the steering disc.

A final feature of the invention is that the armature of the electromagnet is designed as a holding hook for the sliding member.

The advantage of the invention is that, because the retaining member is pressed, the electromagnet can be sized in a smaller design since it does not have to perform any stroke. Moreover, since the holding member is pushed away from the non-energized magnet, the holding member cannot remain so-called adhered due to the remangence of the magnet.

1 and 2 show a first embodiment of the device according to the invention, FIGS. 3 and 4 show a second embodiment, FIGS. 5 to 7 show a third embodiment, and FIG. a fourth embodiment of the device according to the invention.

The device shown in Figures 1 to 7 is provided with an electromagnet 2 mounted in a holder 1, the coil of which can be connected to a voltage source via two coil leads 3. The electromagnet is excited according to a control program.

The armature 4 of the solenoid 2 is formed as a holding hook, which is mounted in the holder 1, pivotally about the axis 5. The armature 4 engages a spring 6 which is connected at one end to the armature 1 of the solenoid 2. of the non-energized solenoid 2 from its first position in which it rests on the solenoid 2 (Fig. 1, Fig. 3 and Fig. 5) to a second position (Fig. 2, Fig. 4, Fig. 6) in which it engages with the sliding recess of the organ 7, for example of the sinker, and holds it in the first end position. This sliding member 7 is driven by a reciprocating movement in the cycle of the textile machine between two end positions. The second end position of the slide 7 is indicated by dashed lines. This sliding member 7 can, for example, serve to control the yarn guiding device of the textile machine.

The armature 4 is provided with a cam 4a with which it engages a control device, which is variously designed in the embodiments of Figures 1 to 7.

In the embodiment according to FIGS. 1 and 2, the actuator is provided with a lever 8 which is rotatable at one end about an axis 10 and at the other end supported by a spring 1 over the spring 11. The spring 11 ensures that the pulley 12 abuts the control curve of the control disc 13. The end of the lever 8 rotatable about the axis 10 is provided with a control bar 9 which engages the cam 4a.

The control disc 13 rotates according to the movement of the sliding member 7 in the cycle of the textile machine. The pulley 12, as shown in FIG. 1, interacts with the protruding portion 13a of the control disc 13, the lever 8 is lifted and rotated to a position in which the control bar 9 acting on the cam 4a presses the armature 4 onto the electromagnet 2 (Fig. 1). When the control disc 13 is further rotated, the spring 11 pushes the lever 8 downwards and the control bar 9 rotates clockwise from the position shown in Fig. 1 to the position shown in Fig. 2. In this position, the armature 4 engages in the sliding member 7, which at this point in time is in its lower end position, and the spring 6 pulls the armature 4 into its retracted position from the electromagnet. it holds it firmly in its end position (fig. 2).

As soon as the protruding portion 13a of the control disc 13 now engages the pulley 12, the lever 8 is raised again and rotates the control element 9 formed in the counterclockwise direction. In this case, the control bar 9 moves the cam 4a, whereby the armature 4 is again adjacent to the electromagnet 2.

When the solenoid 2 is energized, the armature 4 adjacent to it is held firmly and cannot be pulled away from the solenoid 2 by the spring 6. The slider 7 cannot here be held firmly in its end position, but performs its reciprocating movement without hindrance.

Since the armature 4 is brought to the solenoid 2 from the position shown in FIG. 2 by the control bar 9, the solenoid 2 does not have to pull the armature 4 out of its drop-out position but merely retain this adjacent armature 4. perform no lift.

In the embodiment according to FIGS. 3 and 4, the control device, similar to the example shown in FIGS. 1 and 2, is provided with a lever 8 rotatable about an axis 10, which is supported at one end by a spring 11 on the support 1. a lever 12 is rotatably mounted on a pulley 12, which is pressed by a spring 11 onto a control curve of a control disc 13 which rotates in the cycle of the textile machine.

A control bar 14 is mounted at the end of the lever 8 rotatable about the axis 10. The control bar 14 interacts analogously to the control bar 9 in Figs. 1 and 2 with the cam 4a of the armature 4, but is arranged on a different side of the cam 4a than the control bar 9.

When the armature 4 is in its position apportioned from the electromagnet 2 (Fig. 4), it locks the sliding member 7, which is in its lower end position. In this position, the armature 4 is held by the spring 8. When the solenoid 2 is energized, it pulls the armature 4 so that, as shown in FIG. 3, it engages the solenoid 2.

As long as the pulley 12 abuts the portion of the control curve 13b defined by points A and B, the control bar 14 does not act on the cam 4a (FIG. 3). If the pulley 12 is located in the recess 13c of the control. . . ·. 5 of the disc 13, the lever 8 is rotated by the spring 11, the control bar 14 being rotated clockwise and pushed. on cam 4a. Controls 8, 11, 12, 13, 14. the control bar 14 acts on the cam when the cam 14 is formed. when. the armature 4 abuts against the electromagnet 2: since this latter is not excited at this time, the armature 4 is pushed by the control bar 14 from the electromagnet 2 and rotated by the spring 6 to the position shown in Fig. 4.

Accordingly, if the electromagnet 2 is energized or not, the armature 4 is located in one or the other. position and. blocks the sliding member 7, respectively. it does not affect it.

The push-off of the anchor 4 by the control bar 14 from the solenoid 2 is of particular importance for DC magnets, since the anchor can get stuck on the solenoid 2 as a result of retentive magnetism due to remanent magnetism. - 4 when the solenoid 2 is not energized is lifted by the control bar 14.

In the embodiment shown in FIGS. 5 to 7, the actuator is formed as a combination of the actuators of FIGS. 1, 2 and 3. The lever 8, supported by one end by means of a spring 11 on the holder 1, is on the other The cams 4a are interposed therebetween and act upon the position of the lever 8. The position of the lever 8 is determined by the - control - disc 13, rotated in the cycle of the textile. of the machine which engages with a roller 12 rotatably mounted on the lever 8. '

Giant. 5 shows the armature 4 in its position adjacent to the electromagnet 2 in which the armature 4 is moved by the control bar 9 acting on the pouch 4a. In this case, the lever 8 is in its raised position to which it is pivoted by the projecting portion 13a of the control disc 13.

Upon further rotation of the control disc 13, the pulley 12 reaches a position in which it rests on a portion 13b of the control disc 13, resulting in the rotation of the lever 8 by the action of the spring 11.

If the solenoid 2 is now energized when the armature 4 abuts, then it is held firmly in this position and does not affect the reciprocating movement of the slide 7.

Conversely, if the solenoid 2 is not excited when the armature 4 is adjacent, when the part 13b engages the pulley 12, the armature 4, by the action of the spring 6, can rotate to its position which is free from the solenoid 2 following the control bar 9 which rotates 6. In this position, the armature 4 holds the slide 7 in the lower end position.

As the control disc 13 is further rotated, the pulley 12 engages in the recess 13c (FIG. 7). In this case, the lever 8 is further rotated and the control bar 14 presses on the cam 4a, in the event that the armature 4, after excitation of the solenoid 2, would remain attached to the solenoid 2 due to remanent magnetism. By acting of the control bar 14 on the cam 4a, the armature 4 is pushed away from the solenoid 2 and, by the action of the spring - 6, is rotated to its non-position from the solenoid 2 (Fig. 7).

Upon further rotation of the control disc 13, the pulley 12 again reaches a portion 13b of the control disc 13, resulting in a rotation of the lever 8 in an anti-clockwise direction. In this case, the lever 8 assumes the same position as in FIG. 14 does not act on the cam 4a of the armature 4.

Once the pulley 12 restarts on the protruding portion 13a of the control disc 13, the lever 8 together with the control bar 9 and 14 is further rotated counterclockwise. The control bar 9 begins to push the cam 4a. The armature 4 is thereby rotated in the direction of the electromagnet 2 until it reaches the electromagnet. Now, the above-described movement of the movements described above is repeated with the further rotation of the control disc 13.

Giant. 8 shows a further embodiment of the device according to the invention. An electromagnet -16 is mounted on the holder 15. The electromagnet armature 17 is in the form of a plate and is provided with a slide 18, which is guided in a sliding manner in the holding device or in the holding device. The spring 19, attached to the holder 15, is engaged with the slide 18 and tries to pull the slide 18 together with the armature 17 away from the electromagnet 16.

A cam 18a is provided on the slide, which engages the groove 20a of the lever 20 guided in the holder 15. The groove 20a is defined by two stops. 20b and 20c acting on the cam 18a.

At one end, the control lever 20 is connected to the spring 21. The opposite end of the lever 20 is provided with a roller 22 which is pressed by the spring 21 against the control curve of the control disc 23 rotated in the cycle of the textile machine.

The apparatus of FIG. 8 operates in the same manner as the apparatus shown in FIGS. 5 to 7.

If, as shown in FIG. 8, the protruding portion 23a of the control disc 23 on the roller 22 is moved, the lever 20 is moved against the force of the spring 21 and the stop is pressed against the cam 18a, thereby pressing the armature 17 na elek. tromagnet 16.

In this position of the armature 17 in which it is adjacent to the electromagnet 16, the free end of the slide 18 is located outside the movement path of the slide which performs a reciprocating movement (not shown) corresponding to the slide 7 in Figures 1 to 7. Thus, the reciprocating movement of the sliding member is not affected.

When the control disc 23 continues to rotate, the pulley 22 reaches a portion 23b of the control disc 23, resulting in axial displacement of the lever 20 caused by the spring 21.

If, at this point in time, the electromagnet 16 with the adjacent armature 17 is energized, »я ^л . л?

195287 this is. firmly held and not followed by the movement of the control lever 20.. _; . If, however, the electromagnet magnet 16 is not energized, the armature 17 and the slide 18, following the tension of the spring 19, follow the sliding movement of the levers 20. However, if the armature 17 remains due to remen- dent magnetism on the electromagnet _; 16, then pushes the stop 20c onto the cam 18a when the roller 22 falls into the recess 23c of the control disc 23. This causes the armature 17 to be raised and allows the ram 18 to be axially displaced.

The control lever 20 and also the slide 18 are moved up to the position indicated by dashed, in which the slide blocks the slider referred to above and not shown in its end position, as explained in Figures 1 to 7.

In the embodiment of FIG. 8, it would also be possible to provide a slide 20 at its end so that with an anchor 17 adjacent to the electromagnet 16 blocking the slide in its one end position and the dropped position of dimension 17 shown in dashed lines would move the slide was not affected.

If necessary, one or the other of the stops 20b and 20c on the control lever 20 may be omitted in order to only raise or press the armature 17.

It goes without saying that in all the examples _

design. temporal. the moment of excitation, respectively. EMC excitation 2, resp. 16; it must be in tune with the movement of the sliding member 7 and the corresponding rotation of the control disc 13, respectively. As already mentioned, both the reciprocating movement of the sliding body 7 and the rotation of the control disc 13, respectively. 23 takes place in the cycle of the textile machine. ? ·

By means of the device described, the movement of the sliding member or the slider can be influenced as desired. management body as described. Depending on whether or not the electromagnet is energized at a particular point in time, the retaining member formed as an electromagnet anchor blocks the sliding member, such as platinum, optionally in its end position.

As described above, the actuator moves the armature toward or out of the electromagnet when the electromagnet is not energized.

The anchor is pushed onto the electromagnet by means of a control device; it does not have to be designed as a lifting magnet, but only as a holding magnet. ; ·

Mechanical lifting of the armature when the electromagnet is not energized avoids any disturbances in operation that could be caused by the armature being trapped by the electromagnet due to remanent magnetism.

Claims (4)

OF THE INVENTION An apparatus for selectively retaining a sliding member of a textile machine, such as sinker, driven in one end position in both directions, with a retaining member formed as an electromagnet anchor, the member being movably movable from a first position abutting the electromaghet to a second position and which in one position interferes with. a travel path of the sliding member for holding it in an end position, characterized in that the armature (4, 17) of the electromagnet (2, 16) is provided with a cam (4a, 18a) which is in operative connection with at least one actuator, provided on the lever (8, 20) and the free end of the lever (8, 20) is connected to one end of the first spring (11, 21), the other end of which is connected to the electromagnet (2, 16) holder (1, 15). wherein one end of the second spring (6, 19) is connected to the armature (4, 17) of the electromagnet (2, 16), the other end of which is connected to the electromagnet holder (1, 15). (2, 16). 2. Device according to claim 1, characterized in that the lever (8) with a control device consisting of at least one control strip (9, ₁₄₎ is pivotally mounted on the pin (10), and in the middle on the lever (8) is arranged roller (12) which bears against the control disc (13). Device according to claim 1, characterized in that the lever (20) with the actuating device consisting of at least one stop (20b, 20c) is displaceably arranged in the holder (15) of the electromagnet (16) and is provided with a roller at one end (22), which abuts the control disc (23). . . Device according to Claims 1 to 3, characterized in that the armature (4,17) of the electromagnet (2, 16) is designed as a holding hook for the sliding member (7).