DE1535270C - Jacquard machine with individually electromagnetically controlled strands - Google Patents

Description

The invention relates to a jacquard machine, in particular for high-speed weaving machines with individually electromagnetically controlled strands that move between two end positions by two forces of which one stronger intermittently in the backward movement, the other weaker and constant, constantly acting in the forward movement, and in which, furthermore, the Litzifrr 'for the purpose of patterning in the end position into which they have been brought by the intermittently acting force, are temporarily retained by an electromagnetically controllable locking device. As such The wave weaving machine is primarily considered, since the classic weaving machines use the Machine speed not only through the shedding, but just as strongly through the weft insertion is limited. ·

In the known machines, the warp yarns are for the purpose of patterning by means of the strands perpendicular to the KetUläche by two forces moving, of which the greater intermittently in the one RICH ¹ tung, the reverse direction, the other weaker, continuously in the other direction, the forward direction, act, and the warp threads are controlled in an end position by locking devices, temporarily held. .

In addition to the locking devices that are mechanically controlled by punch cards or the like, there are also Electromagnetically controlled machines became known, in which the mechanical. Scanning the Sample cards are carried out by mechanical-electrical scanning using contacts. The transfer this pattern inipulse on the strands and thus the warp threads happens instead of the locking device as before to the strands by means of cords, from the scanning device by means of electrical conductors to directly Electromagnets attached to the machine and equipped with a locking device. Included but hardly any increases in the speed of the work step are achieved, and neither is the effort less large than with the usual mechanical method. Such a mechanical-electrical scanning is complicated and cumbersome, the scanning takes a certain amount of time and the magnets to operate the locking devices inevitably have a certain size, which in turn the he / .iclable warp density influences. Noise generation and electricity consumption are other reasons that cause such Make arrangement practically impracticable. Also for. a control of the electromagnetic locking devices by means of electronic means, the effort is due to the high power consumption and due to the large number of elements to be controlled, quite apart from the fact that this the achievable working speed is still limited by the known locking devices is.

The present invention aims to overcome these disadvantages. The jacquard machine according to the present invention is characterized in that each strand part has a latch and that a magnet system is assigned to each stranded wire part, which has an armature designed as a leaf spring, which leaf spring in their. Normal position due to its intrinsic tension with its free end in the Movement path of the detent of the associated strand part protrudes and during the backward movement of the Strand part is pressed by this to the magnetic core and when moving forward depending on the Excitation of the magnet system is held either on the core, so that the strand movement is released is, or is released from the core and engages in the latching of the stranded part so that the stranded wire is in its End position is held.

The use of a permanent magnet has proven to be particularly useful for the magnet system proven, its magnetic flux via a bracket,

ίο the core and over the leaf spring when applied is closed and the core of which is surrounded by a coil, whose Magnetisierurigssinn dem Magnetic flux of the permanent magnet counteracts, so that when the coil has current flowing through it, the core does not

Possesses attraction. .

The jacquard machine according to the invention can be used for normal or wave weaving machines. The mechanism of the intermittently acting force is different. While he was in the first

«O If all strands are moved at the same time and the control impulses for all magnets must be carried out at the same time, is the operation of the strands in wave weaving machines on different love lines Carrier of the intermittently acting force divided,

as the one corresponding to the wave movement in time ^ perform a staggered movement. The control impulses to the magnets are not applied to all magnets at the same time, but separately for each group. Within such a group of the wave web

machine, the strand control is carried out in exactly the same way as otherwise over the entire width of the normal riveting machine.

In the drawing is an embodiment of the Erfmdungsgegeiistaiules shown. It shows

F i g. 1 schematically a loom in side view with the arrangement of two locking devices for the control of the strands,

Fig. 2 shows an embodiment of such a locking device,

3 shows the same device with the other end position of the strand,

F i g. 4 the device with locked braid,
5 shows the device in an enlarged view at the moment of the fall of the locking spring and,

Fig. 6 shows a cross section through a strand in its Guide. ''

Fig. 1 shows schematically a loom in side view. On a warp beam 10 is one Chain Il wound up. This runs over a backrest 12 to strands 13 and 13 'with eyes 32 and 32'. From there it runs to the stop edge 14, from which the tissue 20 after it has formed a breast tree 15 and has passed a switching drum 16 with pressure roller 17, is wound onto a tree 18.

The shuttle 21 is transported through the shed 19 formed by the warp threads. On one Fixed support 22 are tension springs 23 and 23 'attached to the strands 13 and with their free ends 13 'hold. In the area of the other ends of the strands, the two locking devices 25 and -25 'are arranged, each of which is in operative connection with a specially designed Litzentcil 24. In the Healds 13 and 13 'are attached to eyes 32 and 32' through which warp threads 33 and 33 'run. the Movement mechanism of the intermittently acting force consists of a slide 26 with two ■ Eyes 27 and 27 'which carry bolts 28 and 28'. The slide 26 is mounted in two bearings 29 and

stands with a disk 31 via a connecting rod 30 in drive connection.

In the F i g. 2 to 6. specially designed electromagnets are shown as locking devices, which can be used to operate the jacquard machine. A strand part 24 is attached to each strand 13, which is arranged in the area of the movement mechanism generating the intermittent movement is. The strand part 24 slides in a guide groove 35 cut into a guide part 34 is. An ann 42, which serves as a support for a magnet system, is attached to the guide part 34. This magnet system consists of a permanent magnet 38 which, via a bracket 39, has a: Core 36 is in a conductive connection? The core 36 is of a coil 37 constituting a winding surround. The permanent magnet 38 is in a conductive connection with a leaf spring 40 acting as an armature, so that the magnetic flux from the permanent magnet 38 via the bracket 39, via the core 36 and the leaf spring 40 is closed when the leaf spring 40 rests on the core 36. If this is the case. the leaf spring 40 is held on the core 36 by the permanent magnetic flux. the Leaf spring 40 has a bent piece 41 at her.frei end, which as a result of the internal stress the spring 40, when the spring is released from the core 36, to a surface 43 on the leaf spring support 34 ' Concern comes. The core 36 is, as already mentioned, surrounded by the coil 37, in such a way that at Current flow through the coil, the magnetism created in the core 36, the permanent magnetic flux cancels or counteracts it. So when the leaf spring 40 rests on the core 36 and this through the coil is excited, there is no magnetic force in the core .36 present, and the leaf spring 40 is from The core 36 is released and moves with its free end under its internal stress upwards to the Contact surface 43. The heald part 24 has a catch 47 starting from its lower edge, which from two edges 44 and 45 is limited. The front flank 45 is curved and towards the lower edge rounded. The edge behind the catch 47 is slightly opposite the front edge set back, so that the strand part 24 after the pressing of the spring on the core is free to the left can move.

The heald part 24 also has on its upper side a catching catch 46 which is open to the front and into which the am Eye 27 attached bolts 28 of the slide 26 engages during the backward movement of the slide 26 and takes the strand backwards.

The whole thing works as follows: The warp threads 33 (Fig. 1) are between the backrest 12 and the breast tree 15 under a certain tension and by laterally pulling out the Strands 13, here to the left or right, the subject 19 is formed in the usual way, through which the shuttle 21 is moved to insert the weft thread. With jacquard machines usually stays always one group of warp threads 33 'in the basic position (right; while another group 33 is raised in each case to generate a specific pattern and for the passage of the Protecting. After each shooter pass, the raised threads return to their original position, and any other thread group is lifted for the next shuttle pass to create a specific pattern. The strands 13 are in the example shown gv'gen the train of the constantly acting springs 23 of the locking devices 25 held in their basic position. To find the subject for every shooter change, the disc 31 rotates and moves the slide 26 back and forth. Come here every time in the right end position, the bolts 28 lie in the catch 46 of the heald parts 24, d. Hall

ίο Stranded parts are taken off shortly before the end of the lift The slide 26 is suspended from the bolt 28 and lifted slightly from the support surface 43 of the stationary guide part. The locking devices 25 now determine which strands the next time with the slider 26,

15. Pulled by springs 23, allowed to go to the left. The slide 26 can, if this requires the passage of the shooter, in the end positions for a short time stand still. This is particularly necessary with the usual machines, until one shooter the whole Weaving width has happened, while with wave weaving machines the shed is immediately in front of you Schützen opens and immediately afterwards changes to the next position.

In the F i g. 2 to 6 is the guidance and control

as and the hanging of the strands are explained in more detail.

In Fig. 2, the strand 13 with the strand part 24 is just in the right dead center; the flank 45 of the catch 47 with the lower edge of the heddle part 24 have pressed the spring hedge 41 downwards during the movement of the heddle part 24 to the right, so that the leaf spring 40 comes to rest on the core 36. If at that moment the coil 37 is not below Current. Stands, the permanent magnetic force is strong enough to move the leaf spring in the position shown in FIG. 2 drawn To hold the position, even if the strand is leaning against the bolt 28 again to the left (Fig. 3). the The stranded part 24 can move the slide 26 unhindered and under the tension of the spring 23 follow to the left until the left end position and back to the right end or control position. The spring 23 is so strong that it is together with the stranded wire all movements of the bolt 28 participates, although this is only one-sided in the catch 46 of the Litz grips. .

In Fig. 4 that position is shown, which is when walking forward, i. H. to the left, the slide 26 from the rear dead position arises when the strand is held in its end position.

If, at the beginning of the movement of the slide 26 to the left, a current surge is applied to the coil 37, this momentarily weakens the permanent magnetic field so strongly that it is no longer able to To hold the spring 40 against its internal tension on the core 36. So this falls away and strives to rest with its bent-up end against the surface 43 (FIG. 5). But she cannot do this yet, because the strand part 24 stands in the way with its flank 45. The slider with the braid must still be move a little to the left until this is possible.

During this stroke, the end 41 of the> moves Spring 40 at the same time in the catch 47 inwards and thus locked after it rests on the machine-fixed Stop surface 43 of the strand the way to the left. This therefore remains under the tension of the spring 23 suspended while the bolt 28 wanders empty to the left and back again.

For safety reasons, the surface 43 is designed somewhat obliquely from top to bottom left, so

the strand, ζ. B. by vibrations, do not fall off can while it is hung.

When the bolt 28 comes back, it again engages in the catch 46 and releases the stranded wire from it The stop on the flank 44 of the detent 47, and the strand in turn presses the spring 40 at the end of the stroke again to the magnetic core 36, whereby the bent-up part 41 emerges again from the latch 47 at the same time. The magnet system can thus create a new one again Give order. . . ,

In Fig. 5 shows the moment in which the spring 40 is released from the magnetic core 36 in a somewhat more precise manner. This happens shortly after the dead center has been passed, but before the flank 44 is a spring strength away from surface 43. The strand moves relatively slowly to the left in the vicinity of its dead center, while the spring comes to rest very quickly on the flank 45 due to its own span and its very small mass. The Fcderbcweguii £, is therefore ao faster than the movement of the strand at this stage, so that the spring slides inward along the flank 45 in the detent 47. Therefore, the slot 47 must also be only slightly wider than the thickness of the spring. This allows the heald to hang up after a very _{short stroke:} beyond the dead center and thus a maintenance of the hitting of the heald on the spring, which in turn guarantees high speeds. . · ... '..

The device described has the advantage over the known control devices that they enables high working speeds. This is primarily due to the internal stress the leaf spring has a very high reactivity, which increases the speed of the and reciprocation of the strands is superior and therefore an immediate engagement of the leaf spring in the Latching of the strand part allows. The speed of the back and forth movement of the strand is therefore decisive for the arbcitsuang of the jacquard machine. and this can be driven higher than before. The fact that the strand movement controls the movement of the leaf spring is crucial for the Work cycle of the whole machine.

As an electromagnet, which causes the holding or releasing of the leaf spring, a common one can be known Electromagnet can be used. In this case, the coil 37 must then be energized when the no 36 is to be magnetized. around the leaf spring 4 (1 in its lower position keep. But this requires a longer exposure of the current to the coil 37, namely from the contact torque of the leaf spring 40 to the fall of the strand, and this is due to the large number of Magnets require a considerable amount of energy.

The use of the permanent magnets described has the further advantage that only a short one Current surge through coil 37 is required. namely in the event that the leaf spring 40 is released should be and should take their locking claw due to their internal tension, while holding on the leaf spring on the core 36 takes place without additional expenditure of energy by the permanent magnet. In this case, the energy consumption is only a fraction of that when it is used of normal electromagnets, what with the large number of lit / s with associated magnets of is of crucial economic importance.

Furthermore, there is still the advantage when using permanent magnets that a single Assign a plurality (group) of cores 36 with coils 37 to wide permanent magnets can.

Claims (9)

Patent claims: 1. Jacqardmaschinc, especially for high-speed looms with individually electromagnetic controlled strands that are moved between two end positions by two forces, of which one is stronger intermittently in the backward movement, the other is weaker and constant constantly acts in the forward movement, and in which further the strands for the purpose Pattern in the final position. into which it has been brought by the intermittent force can be temporarily held by an electromagnetically controllable locking device. characterized.' that everybody Litz wire part (24) has a detent (47) and that a magnet system is assigned to each litz wire part (24) is. which has an armature designed as a leaf spring (40), which leaf spring (40) is in its Normal position as a result of their internal stress miL.-hers free end (41) iri the trajectory of the * Latch (47) of the associated heddle part (24) protrudes and when the heddle moves backwards partly (24) is pressed by this to the magnetic core (36) and during its forward movement Depending on the excitation of the magnet system, either the core (36) is held so that the Strand movement is released. or "is released from the core (36) and in die.Rast (47) des Litzcnteils (24) engages so that the strand is held in its end position. 2. Jacquard machine according to claim 1, characterized in that the detent (47) having Strand part (24) guided in a stationary guide part (34) in a groove (35); whose free end of a contact surface (43) fiif tins bent up Forms the end (41) of the leaf spring (40). 3. Jacquard machine according to claim 2, characterized in that the effective end of the Core (36) of the magnet system is in the immediate vicinity of the Anlagcfläc (43) and that the Guide groove (35) in the guide part (34) like this. arranged is.t. that they from the end (41) of in their Normal position standing leaf spring (40) is covered on the support surface (43) and that the Support surface (43) and the leaf spring endc (41) beveled to the front and down are, so that the part of the stranded wire (24) lying in front of the detent (47) during its backward movement the leaf spring (40) moves as far as it will go against the core (36). 4. Jacquard machine according to claim 1, characterized in that the detent (47) having Part of the strand (24) is arranged at the end of the strand and that it is open to the front Catch (46) for a bolt (28) of the movement mechanism generating the intermittent movement of the strand (26) which moves the heald part (24) into its end position. . 5. Jacquard machine according to Claim 4. through this characterized in that the heddle part (24) is wedge-shaped on its part located to the rear of the detent (47) is formed and that the lower edge (24 "') of the wedge (24 ") opposite that which is guided in the guide groove (35) and is located in front of the detent (47) Edge of the LitzenteUs (24) is reset. 6. Jacquard machine according to claim 2, characterized in that the guide part (34) with a support arm (42) is connected, which serves as a support for the magnet system. -a ^ L. · ■ · ■. 7. Jacquard machine according to Ansprucn f, characterized in that the leading edge (45) of the Latch (47) in the heald part (24) is rounded at its lower end. 8. Jacquard machine according to claim 1, characterized characterized in that the magnet system one Has permanent magnets (38), the magnetic flux of which via a bracket (39), the core (36) and the leaf spring (40) is closed in the applied state and its core (36) is closed by a coil (37) is surrounded, the magnetization sense of the magnetic flux of the permanent magnet (38) counteracts, so that when the coil (37) flows through it, the core (36) does not attract any force owns. 9. Jacquard machine according to claim 8, characterized in that the permanent magnet (38) a plurality of cores (36) with coils (37) are assigned. 1 sheet of drawings 009 637/96