CS277434B6 - Holding-down device for a loom controlled by a jacquard machine - Google Patents

Abstract

In the Jacquard harness assembly, the spring forces for the down motion is established solely for the weaving requirements. A spring unit, with release mountings at each end, joins the lifter cord to the range of cords with a sufficient mechanical spring force (F2) to hold down the lifter. - The spring unit is formed by a heddle carrying a blockage with the spring between it and a fixed frame section. The pref. spring is a pressure or coil spring, shrouded by a guide tube, arranged in a number of springs in a matrix with the ends of the guide tubes supported by a common perforated plate. Perforated plates can be assembled vertically, with the springs, to form a component which can be inserted into the machine frame and replaced.

Description

The invention relates to a holding device for a loom controlled by a jacquard machine, wherein each warp thread is movable by means of a shifting line, a pulling device coupled to the machine frame and the shifting line and exerting a spring force, and a control line releasable connected to the other end of the shifting line. of the sinker of the jacquard machine, between two shed positions for controlling the sinkers of the jacquard machine according to the pattern, and is pulled down against the stroke movement of the sinker.

BACKGROUND OF THE INVENTION

In such machines, the individual warp yarns are moved by shifting lines between a lower and an upper position to form a shed. By means of a clamping device which exerts a spring force, the weft thread and the lower end of the shifting line are tensioned with respect to the machine frame to the lower position. Lifting of the weft yarn and the shifting line to the upper shed position is achieved by controlling the sinkers of the jacquard machine according to the pattern, wherein the lower end of the sinkers of the jacquard machine is connected by the control line to the upper end of the shifting cord. In the lower position in the shed, the sinker of the jacquard machine is supported on the attic, in the upper position the sinker is maintained by the upper arresting device. A number of systems exist, for example of the mechanical or electromechanical type, for controlling the sinkers of the jacquard machine exactly according to the pattern.

In general, the lower ends of all sinkers of the jacquard machine have a different geometric spatial form than the engagement points of the warp thread lines, so that lines are required for the lines, resulting in different friction values. Furthermore, it is usual to raise and lower several warp threads with one sinker, i. arrange several control lines for the sinkers and several shifting lines. When weaving in the staple, up to ten shifting lines can be actuated by one sinker, so that a correspondingly high force is applied to the sinker due to the large number of tightening devices. The number of shifting lines in the staple can vary from one woven item to another. As a result, depending on the load case, different forces are applied to the sinkers. If the force exerted by the clamping device is too great, high wear occurs. The required lifetime of the jacquard block, the working time of the loom with a jacquard machine, is thus considerably reduced. Conversely, if the force exerted by the clamping device is too low, functional malfunctions may occur. These disadvantages increase with increasing operating speed, because at higher revolutions of the jacquard machine drive, the sinkers move at a higher speed and must be returned by the spring force applied.

The difficulty is therefore to reconcile the requirements of the weaving technique and the requirements of the machine design so that the lifetime of the jacquard loom is as long as possible.

When the force on the sinker is too small, it is common for the mechanic to clamp an additional spring between the sinker and the machine frame. Due to constructional reasons and due to the inaccessibility of a large amount of sinkers in the jacquard machine, this can rarely be done and, moreover, only at the peripheral sinkers.

SUMMARY OF THE INVENTION It is an object of the present invention to overcome these disadvantages and to provide a holding device so as to meet the conditions of both the weaving technique and the machine design, thereby increasing the service life of the jacquard machine.

SUMMARY OF THE INVENTION

This object is accomplished by a jacquard loom holding device wherein each warp yarn is movable by a drawstring shifter coupled to the machine frame and with this elastic force shifting cord and by a control cord releasably coupled to the other end of the shifting cord and the jacquard sinker between two shed positions in the control of the sinkers of the jacquard machine according to the pattern, and is pulled down against the sinker stroke movement, which consists in that a structural unit consisting of a heald is detachably arranged between the sinker control line and the shifting line and with the sinker control cord and the shift cord, the heald carrying the barrier and a spring force element positioned between the barrier and the perforated plate connected to the machine frame.

The basic idea of the invention is that an additional spring force element is inserted into the length of the shifting lines, that a conventional tightening device only has to meet the conditions given by the weaving technique, while the additional spring force element meets the conditions given by the machine design. The invention furthermore allows a simple construction of such a holding device by means of which already existing looms with a jacquard machine can be equipped.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows a schematic representation of an embodiment of a holding device according to the invention; FIG. 2 shows a partial section through the arrangement of spring force elements disposed in a structural unit; FIG. 5 shows a second embodiment of a holding device arranged in a machine frame, where additional bias may still be provided.

DETAILED DESCRIPTION OF THE INVENTION

Giant. 1 schematically illustrates the construction and connection of the jacquard machine J and the weaving loom W. The warp threads 1 in the weaving loom W may be moved by the shifting line 2 between the lower position shown by the solid line and the upper position shown by the broken line to form a shed. In order to ensure the lower position of the warp threads 1 in the shed, the elastic force F1, caused by the clamping device 3 shown schematically as a spring, acts on the shifting line 2 in the region where it raises or contracts the warp thread 1. This resilient force F1 acts downward to the machine frame. When the shifting cord 2 and the warp thread 1 are pulled to the upper position shown by the broken lines, the pulling device 2 exerts a restoring force to return the warp thread 1 to the lower position, drawn by the solid line.

The jacquard machine J controls the movement of the warp threads 1. In the jacquard machine J, the sinkers 4, in a conventional manner, move up and down between the upper and lower shed positions and are retained in one of these positions. Each sinker 4 is fixed, but releasably, by the control cord 5, to at least one shifting cord 2 of the loom. This connection is effected, for example, by engaging a carabiner and a loop each located at the end of the control line 5 or the shifting line 2. The control whether the sinker 4 is to be locked in the upper shed position or left in the lower shed position can be carried out in a known manner. eg through a mechanical needle mechanism or an electromagnetically controlled retention mechanism, etc. A number of systems of this kind are known.

In the lower shed position, the lower end of the sinker 4 generally rests on the soil 6 of the jacquard machine J, which is located in the machine frame. In FIG. 1, it is merely indicated that a plurality of shifting cords 2 can be connected to a single sinker 4. Such an arrangement is also customary.

It is also schematically illustrated that the shifting line 2 extends through guides which are also fixedly connected to the machine frame. These lines need not be vertical in any case, but rather exceptional.

The restoring force which acts on the sinker 4a on the warp thread 1 must meet both the conditions given by the weaving technique and the conditions given by the machine design. If this elastic force is too high, excessive wear occurs, but if it is too low, functional failures may occur. This is the more serious the more the number of shifting lines in the duty cycle changes.

This problem is solved according to the invention by the arrangement of the structural unit F with a spring force element. According to FIG. 1, this assembly unit F consists of a cable 8 which is firmly but releasably connected to both the sinker control cable 5 and the shift cable 2. The cable 8 carries a barrier 9. Between the barrier 9 and the perforated plate 10 connected to By means of a machine frame, a resilient element 11 is provided, which exerts an elastic force F2. The resilient force F2 of the resilient force element 11 is selected to be sufficient to retract the sinker 4. The resilient force FI of the retraction device 3 is opposite the needle to be sufficient to retract the warp thread 1 to the lower shed position when the respective sinker 4 is in its lower position.

As a result, the elastic force FI required for the clamping device 2 is determined exclusively by the weaving process and the elastic force F2. The force exerted by the spring force element 11 is determined solely by the construction of the machine, irrespective of how many shifting lines 2 are in the loom of the weaving loom W, and thus how many of them are lifted or contracted by one sinker 4.

Since in the jacquard machine J and the weaving loom W a large number of such spring force elements 11 have to be arranged in a nut similar to the sinkers 4, it is expedient, as shown in schematic Fig. 2, to arrange the guide tubes 12 in the same nut. The guide tubes 12 are fastened between the top perforated plate 10 and the bottom perforated plate 13. The guide tube 12 may be relatively thin-walled when both perforated plates 10, 13 fixed in the machine frame to a predetermined distance. Giant. 2 shows an embodiment wherein the holes 14 in the top perforated plate 10 and the corresponding holes in the bottom perforated plate 13 necessary for the passage of the cable 8 are arranged in a square grid. Depending on the arrangement of the sinkers 4 in the jacquard machine J, the apertures 14 of adjacent rows may be offset. The adjacent guide tubes 12 may optionally contact each other. The cable 8 according to FIG. 2 has a loop 16 at the upper end of the carabiner and at the lower end; however, the arrangement can also be reversed, depending on how the shifting line 2 and the control line 5 are equipped.

Giant. 3 shows an arrangement in which the helical spring 17 constituting the spring force element is supported on the perforated plate 10. The opening 14 for the passage of the cable 8 is substantially only slightly larger in diameter than the cable itself. A recess 18 is formed around the guide tube 12 in the perforated plate 10, the diameter of which corresponds to the outer diameter of the guide tube 12. The last thread of the helical spring 17 is clamped between the end of the guide tube 12 and the bottom 19 of the recess 18 so that it cannot slip. Figure 4 shows the arrangement of the spring force element in the guide tube 12 and, in addition, a different embodiment with respect to its support on the apertured plate 10. The apertures 14 in the apertured plate 10 have a dimension such that a loop 16 or carabiner 15 passes therethrough. arrangement. A recess 18 is also formed in the underside of the perforated plate 10 to receive the end of the guide tube 12. However, a perforated plate 20 is inserted between the guide tube 12 and the bottom 19 of the recess 18, the opening of which is intended only for the passage of the cable.

8. The perforated plate 20 thus serves to support a spring force element, also formed as a helical spring 17.

Referring to FIG. 4, in the cable 8 inside the guide tube 12 a disk-shaped barrier 21 is mounted, the diameter of which substantially corresponds to the inner diameter of the guide tube 12, and in addition the disk 21 may have openings for the passage of air. Thus, the disc 21 may also have a star shape or the like. It is only essential that the disc 21 is guided inside the guide tube 12 and can serve to support the helical spring 17.

At the lower end, the guide tube 12 is inserted in a similar manner into the lower perforated plate 13. However, at this point there is no need to support the spring force element, so it is sufficient that an opening 22 corresponding to the opening 14 is formed in the lower plate 13. depressions 18.

In order to prevent the guide tube 12, the helical spring 17 and the disc 12 from buckling under a buckling load, especially when the helical spring 17 is compressed in the thin-walled guide tube 12, it is expedient to arrange a support perforated plate 24 between the perforated plates 10, 25, corresponding to the diameter of the guide tube 12. In the example shown, the support perforated plate 24 is located approximately where the center of the compressed coil spring 17 is located, i.e. in the upper third of the distance between the two perforated plates 10, 13. a bottom perforated plate 13 by a screw connection 26, which is schematically indicated in FIG. 5.

As noted, the sinker 4 of FIG. 1 is displaced between the lower and upper positions, with the lower end abutting on the attic 6 and thereby also determining the lower position of the cable 8. FIG. 4 shows that in this lower position u the loop 16 bears virtually tension-free on the perforated plate 20, or according to FIG. 3, on the perforated plate 10. In the upper position o the cables 8 corresponding to the top dead center of the sinker 4 F2. The stroke h between the lower position u and the upper position of the drawbar is a quantity given by the machine design.

Giant. 5 shows essentially the same arrangement as FIG. 4, wherein the structural unit F, consisting of the two perforated plates 10, 13 and the spring force elements disposed therebetween, is fixed in the machine frame. The upper frame part 27 according to FIG. 5 is assigned to the jacquard machine J according to FIG. 1 and the lower frame part 28 to a weaving loom W. Between them, the structural unit F is fastened with the screw connection 29 indicated. retrofit also into existing looms with jacquard machine.

Giant. 5 shows, in addition to FIG. 4, another spatial position, whereby the structural unit F is offset by a distance t relative to FIG. 4, by placing a spacer 10 of thickness t between the upper frame piece 27 and the perforated plate 10. by selecting the thickness of this spacer 30, an additional bias can be created in the lower position and in the upper position o, which means that the spring force F2 can be different for the same helical spring 17. Fig. 5 shows the position where the loops 16 of the cable 8 are connected by the control lines 5 to the corresponding sinker 4.

According to the invention, an embodiment is also possible in which the position of the structural unit F with the spring force element is adjustable between the two frame parts 27, 28.

The invention has been described for an exemplary embodiment in which the helical spring 17 is compressed in the up position and exerts a downward force on the cable 8 via a perforated plate 20 on the cable 8. The arrangement can also be opposite, in that in the upper position o the elastic force element is expanded so that the elastic force F2 acts downwardly as a traction force. Other types of springs can be used instead of helical springs.

According to the invention, each of the sinkers 4 is subjected to an elastic force F2 which pulls it to the lower position u and is conditioned by the machine design. In contrast, the elastic force F1, caused by the weaving technique, acts exclusively on the warp thread 1 and moves it to the lower shed position. In this way, the function of the whole arrangement is ensured and, at the same time, the wear is reduced even at high speeds, i.e. high revolutions of the jacquard machine drive J. This is even independent of whether the duty cycle is being operated. This implies that the lifetime of the jacquard as a whole is increased by the simple construction of the entire device, which can be built into existing weaving looms.

Claims (12)

1. A holding device for a loom controlled by a jacquard machine, wherein each warp thread is movable by a drawstring shifting line coupled to the machine frame and with this elastic-force shifting line, and by a release line connected to the other end of the shifting line and two shed positions in the control of the sinkers of the jacquard machine according to the pattern, and is pulled down against the stroke movement of the sinker, characterized in that a structural unit (F) consisting of a detachably arranged unit (F) is detachably arranged between the sinker control line (5) a cable (8) which is firmly but releasably connected to both the control cord (5) of the sinkers (4) and the shifting cord (2), the cable (8) supporting the barrier (9) and between the barrier (9) and a spring force element (11) is provided by a perforated plate (10) connected to the machine frame. Holding device according to Claim 1, characterized in that the spring force element is formed by a compression spring, in particular a helical spring (17). Holding device according to either of Claims 1 and 2, characterized in that the spring force element (11) is surrounded by a guide tube (12). Holding device according to one of Claims 1 to 3, characterized in that the spring force elements are arranged in a plurality of nuts. Holding device according to claim 3 and 4, characterized in that the ends of the guide tubes (12) are fixed in common perforated plates (10, 13). Holding device according to claim 5, characterized in that the perforated plates (10, 13) are connected to each other and form a separate structural unit (F) with the spring force elements, which can be installed in the machine frame. Holding device according to claim 6, characterized in that the guide tubes (12) are thin-walled and a support perforated plate (24) is arranged between the perforated plates (10, 13) and is connected to one of them. Holding device according to one of Claims 3 to 7, characterized in that the guide tube (12) has, at one end, a closing perforated plate (20), the opening of which allows the cable (8) to pass through, the spring force element (11) acting between the barrier and the perforated plate (20). Holding device according to one of Claims 3 to 7, characterized in that the guide tube (12) is supported at least at one end against a fixed frame part, in particular against a perforated plate (10), the spring force element being fixed at one end between a perforated plate (10) and a guide tube (12). Holding device according to one of Claims 1 to 9, characterized in that the barrier is formed by a disc (21) fixedly connected to the cable (8). Holding device according to claim 10, characterized in that the disc (21) has openings for the passage of air. Holding device according to one of Claims 1 to 11, characterized in that the cable (8) has a carabiner (15) or a loop (16) at one end, which is releasably connected to the respective shifting line (2) or the control cord (5)