KR20040016387A - Warp weaving machine - Google Patents

Abstract

PURPOSE: Provided is a warp weaving machine which controls a characteristic of a spring in a high working speed by using a fiber reinforced plastic, thereby driving a pattern stitch in a high working speed. CONSTITUTION: The warp weaving machine comprises a weaving area, a spun yarn supplying area and a spun yarn stretching part which is between the weaving area and the spun yarn supplying area wherein a stretch spring is disposed to each spun yarn together with a guide part. The stretch spring(15) is formed of a fiber reinforced plastic. The plastic has the conductance. The plastic is reinforced with a carbon fiber. The guide part is formed of an eyelet(17) which has the conductance and is connected to the elastic spring.

Description

Warp Weaving Machine

The present invention relates to a warp weaving machine having a yarn tensioning portion between a weaving area, a yarn feed area, said weaving area, and said yarn feed area where tension springs are disposed with guides for each yarn.

In warp looms, the yarn consumption is not the same during the run time. Based on this loom movement, the yarn demand arises fluctuating in each weaving cycle. At the same time, however, the warp beam from which the yarn is loosened should be rotated as uniformly as possible. In order to suppress such fluctuations in yarn demand, there is an aiming line that can change the length of the path between the yarn feed area and the weaving area. In this way, fluctuations in the yarn consumption are equalized.

In inclined looms that can be patterned, the solution is not necessarily suitable. Here, all yarns are no longer based on the same consumption fluctuations. Thus, all yarns are no longer treated in the same form. For this reason, a single tension spring is disposed with the guide for each yarn, so that each yarn can be handled separately to mitigate variations in yarn consumption. Here, the spring is formed of a leaf spring made of steel. This causes a problem when increasing the speed of the warp loom.

The leaf springs made of steel presently used are provided with a cross section of 0.6 mm 2 having a relatively low natural frequency, which may result in uncontrollable loom motion. For example, when selecting a leaf spring having a relatively large cross section of 0.8 mm 2, the natural frequency of the leaf spring is sufficiently high. Since relatively large forces are required to manipulate this type of spring, the yarn tension in relatively large paths will be very high. This uncontrollable movement and very high yarn tension result in an unclean knit form.

An object of the present invention is to be able to drive an inclined loom capable of pattern knitting at a high operating speed.

1 is a schematic cross-sectional view of a warp loom,

Figure 2 is a side view partially cut in tension spring-segment according to the first embodiment of the present invention,

3 is a perspective view of the tension spring-segment,

4 is a side view of a tension spring segment according to a second embodiment of the present invention;

FIG. 5 is a perspective view of the tension spring segment corresponding to FIG. 4; FIG.

6 is a side view of the tension spring segment according to the third embodiment of the present invention,

FIG. 7 is a perspective view of the tension spring segment corresponding to FIG. 6. FIG.

The object is achieved by an inclined loom of the kind mentioned at the beginning, characterized in that the tension spring is formed of fiber reinforced plastic.

By using the fiber reinforced plastic, it is possible to adjust the properties of the spring to be required for driving the warp loom at high operating speeds. The natural frequency of the spring can be selected sufficiently high. In addition, the spring formed of fiber reinforced plastic has a relatively high damping portion. This works advantageously when the vibration of the spring finally occurs due to a pattern or material. When the spring is formed of fiber reinforced plastic, additional parameters are obtained by selecting plastic and fiber reinforcement to control the natural frequency and damping action of the spring. In addition, there are also dimensional parameters of the spring.

Preferably, the plastic is conductive. The conductivity of the plastic may, among other things, form when the yarn is circulated through the guide or may be used to induce electrostatic charge that flows with the yarn. Thus, there is a possibility of induction even when using plastics.

Here, the plastic is preferably reinforced with carbon fibers. Here, the carbon fiber has two problems. That is, the carbon fiber, on the one hand, acts mechanically on the reinforcement of the spring. On the other hand, the carbon fiber is used as a conductor for inducing electric load. By using tension springs made of carbon fiber reinforced plastic (CFK), tension springs made of CFK in warp looms are well suited for improved pattern weaving.

The guide portion is preferably formed of an eyelet connected to the tension spring while being conductive. Thus, static electricity can be transferred from the yarn through the eyelets to the tension spring. Therefore, the leakage of the static electricity is easily performed.

Here, the eyelet and the tension spring are particularly preferably injected into the cavity and the plastic. Here, the plastic is mainly used to fix the eyelet to the tension spring. Thus, it is possible to avoid the eyelets being secured to the tension spring in another way, for example by adhering. Of course, the plastic is so thin that it has no effect or no significant effect on the mechanical properties of the tension spring. Thus, the tension spring can be placed back and forth by dimensions and materials used in relation to the desired natural frequency and the desired damping action.

The tension spring preferably has a natural frequency corresponding to at least 1.8 times the driving frequency of the warp loom. For warp looms with an operating speed of 1200 rpm (r.p.m.), this corresponds to a frequency of 20 Hz. Of course, when the central axis of rotation of the inclined loom rotates, different speeds occur in the loom, and different speeds occur in the spun yarn motion and the spun spring. In the above example, the driving frequency of the warp loom at 20 Hz is based on the condition that the natural frequency of the tension spring must match. If the natural frequency of the tension spring corresponds to at least 1.8 times the drive frequency, the tension spring will obtain satisfactory properties. In the above example, this would be at least 36 Hz.

Here, the tension spring preferably has a damping portion that generates 10% less damping than the vibration within 5 seconds after the 100% vibration is activated. Thus, there is a relatively weak residual vibration after 5 seconds. When the tension spring is vibrated, the tension spring is relatively strongly attenuated. In tension springs made of steel used so far, under the same conditions other than, generally, 30% or more of residual vibration occurs.

The tension spring is preferably capable of using a storage path of at least 30 mm. Therefore, the yarns are sufficiently supplied so that the yarns are uniformly released from the warp beam when the yarns are consumed at different times. The storage path is preferably much larger, in particular 40 mm.

Here, the tension spring preferably has a movable force for a storage path of 35 cN or less. In other words, in order to manipulate the spring via the storage path of at least 30 mm, the movable force must not be greater than 35 cN. This force depends on the magnitude arrangement of the force of the steel spring with a cross section of 0.6 mm 2 and is approximately half of the same spring force in the steel spring with a cross section of 0.8 mm 2. Thus, the sufficiently high natural frequency of the tension spring is combined with the weak moving force.

Multiple tension springs are preferably integrated into segments. In warp looms, in general, thousands of tension springs are provided. Thus, the integration of the plurality of tension springs into the segments makes it easy to perform the operation.

Here, in particular, the segment preferably has two tension jaws into which the plurality of tension springs are fitted side by side. Thus, the segment has a mount that can replace a single tension spring. If the tension spring breaks, the state of the entire segment is not defective. Rather, the segment can be repaired at a relatively low cost.

Preferably, the tension spring has a cushion in the end region sandwiched between the tension jaws. While the clamping force of each single tension spring does not negatively affect the segment, the cushion affects certain tolerance compensation in multiple tension springs arranged side by side in the segment. In addition, due to the fixing force, each tension spring can be easily fixed to the segment. The risk of breakage of the tension spring, which may occur when transferring to a fixed position between the tension jaws, is reduced.

Preferably, the cushion ends inside the tension jaw. Thus, the spring vibrates freely without contacting the tension jaw in both directions. This contact must be carried out on the side from which the tension spring does not work.

It is preferable that the said tension spring is provided with the protrusion inserted in the protrusion part in a tension jaw. Thus, the fixing force for fixing the tension spring to the tension jaw is improved. The fixation force is not limited to pure fixation force. Rather, a shaped end is formed between the tension spring and the at least one securing jaw.

The tension jaw preferably has side-by-side insertion features with at least one protrusion and at least one protrusion. The two tension jaws are not only positioned against each other by means of fastening forces but also relatively protected from movement by the shape ends.

In another embodiment, the segment has a fixture made of a mold with the tension spring. In this embodiment, different materials can be used on the one hand for the tension spring and on the other hand for the fixture.

As a third alternative, the segment is integrally formed with the base body and the plurality of tension springs. For example, first, the cross section of the base body region can produce a larger plate than in the tension spring region to be formed later. The tension spring can then be formed mechanically, for example by sawing.

The present invention will now be described with reference to the accompanying drawings and the description of the embodiments of the present invention.

Schematic loom, partly shown in FIG. 1, has a weaving-operating region 1. In the weaving-operating region 1, yarns 2 and 3 are supplied from warp beams 4 and 5, and the finished knitted fabric 6 is calculated from the weaving-operating region 1. The warp loom has a bar 7 with a needle 8 and a bar 9 with a needle 10. Between the warp beam 4 and the needle 8, the yarn 2 is guided past the fixed deflection rod 11 and past the yarn 12 tension portion 12 in which the yarn is likewise deflected. In a similar manner, a fixed deflection rod 13 is arranged between the warp beam 5 and the bar 10, and the deflection rod 13 is accompanied by a yarn tensioning portion 14. The two yarn tension portions are formed substantially the same. Therefore, only the yarn tensioning portion 12 will be described in detail below.

The yarn tensioning portion 12 has a tension spring 15 for each of the yarns 2. The tension spring 15 is fixed to the rod 16, which extends the width of the warp loom. As a mechanical condition, a number of rods on which the tension springs can be fixed can be nested.

At the apex of each of the yarns, eyelets 17 used as guides are disposed. The yarn of the yarn bundle (2) is guided by the eyelet (17).

The eyelet 17 is formed in the eyelet part 18. The eyelet portion 18 is fixed to the spring 15 by adhesion. The eyelet portion 18 and the tension spring 15 may have a common plastic cover, such that the eyelet portion 18 is firmly secured to the tension spring 15.

Since the eyelet part 18 is formed of a metal material, the eyelet part 18 is conductive. The connection between the eyelet portion 18 and the tension spring 15 is also conductive.

The tension spring 15 is formed of carbon fiber reinforced plastic (CFK). The tension spring 15 is correspondingly conductive as well.

As indicated by the arrow 19, the eyelets 17 disposed on the tension springs 12, 14 can restore a partially elevated path. At this time, the tension spring 15 is deformed. The path characterized by the "storage path" must have a length of 40 mm.

By using the carbon fiber reinforced plastic as a material for forming the tension spring 15, the movable force can be kept relatively small. In the cross section of 0.96 mm 2 of the tension spring 15, the force necessary to move the eyelet 17 via the storage path of 40 mm is approximately 30 cN.

The tension spring 15, made of carbon fiber reinforced plastic, has a relatively high natural frequency. In the example where the tension spring 15 has a cross section of 0.96 mm 2, the natural frequency is approximately 41 Hz. The tension spring 15 also has a relatively large inherent damping portion. When the damping part of the activated vibration is used during the operation time, 6.5% residual vibration occurs within 5 seconds after the activation of 100% (± 4 mm in the above-mentioned case). In other words, the tension spring 15 stops oscillating relatively quickly after activation.

When comparing this value with a tension spring made of steel, a tension spring made of steel with a cross section of 0.6 mm 2 has a very low natural frequency. The natural frequency is approximately 23 Hz. After 5 seconds this kind of spring still has 40% residual vibration. Thus, the movable force is relatively weak beyond the tension path. The movable force is less than or equal to the movable force of a spring made of carbon fiber reinforced plastic and is approximately 27 cN. For example, when selecting a steel spring with a relatively large cross section of 0.8 mm 2, the natural frequency will be relatively high, ie 33 Hz. The damping portion will also be stronger. After 5 seconds, only 31% residual vibration occurs. Of course, the movable force via the storage path is very high. The movable force is approximately 60 cN. This can cause very high yarn tension and at the same time spun yarn delay.

By selecting carbon fiber reinforced plastic as the material of the tension spring 15, a very high natural frequency occurs and a very strong damping action leading to very weak residual vibrations. The movable force via the storage path depends on the size arrangement of the steel spring with a cross section of 0.6 mm 2 as used so far.

A slightly faster loom operates at an operating speed of 1200 rpm (r.p.m.). This corresponds to a frequency of 20 Hz. Of course, at the time of rotation of the central axis of rotation of the loom, different speeds of loom and spinning yarn motion occur, which is led to different motions of the tension spring 15. Thus, the frequency of the tension spring 15 is higher than 20 Hz. When the natural frequency of the tension spring 15 is determined to be at least 1.8 times the operating frequency of the loom, satisfactory results can be obtained. In the above-described case, the natural frequency corresponds to two or more times the operating frequency.

The warp loom is provided with thousands of tension springs 15. Thus, as shown in FIGS. 2 and 7, multiple tension springs 15 have the advantage that they can be integrated into segments.

A first embodiment of this segment is shown in FIGS. 2 and 3.

The tension spring 15 with the eyelet portion 18 at its end is coupled to another end between two tension jaws 20, 21. The two tension jaws 20 and 21 are connected to each other by a set screw 22. The upper tension jaw 20 has a protrusion 23 inserted into the recess 33 from the lower tension jaw. The two tension jaws 20, 21 have shaped ends facing each other. The protrusion 23 is used as a fixing part of the tension spring (15).

By using a cushion 24, it is possible to compensate for relatively small tolerance variations that may occur between adjacent tension springs 15. The cushion 24 can be compressed to a lesser extent.

The cushion 24 has two projections 25 inserted into the boring 26 from the tension jaw 20. As such, the cushion 24 is connected to the tension jaw 20.

As can be seen in FIG. 3, the two tension jaws 20, 21 are provided with a continuous opening 27 through which screws can be guided in order to secure the segment shown in FIG. 3 to the square rod 16. Equipped.

2 and 3 have the advantage that the tension spring 15 can be replaced in case of breakage of the tension spring 15. The entire segment should not be overlooked. It should be possible to dismantle the two tension jaws 20, 21 and to replace the defective tension spring 15 with a new tension spring 15.

Since the transfer between the tension spring 15 and the tension jaw 21 is similarly conductive, an electrostatic charge transferred to the eyelets 17 and the eyelets 18 through the yarns 2 and 3 can be induced. Can be.

4 and 5 show a modified embodiment, wherein the same and corresponding members use the same reference numerals. Here, the tension spring 15 has a fixture 29 into which the spun yarn tension spring 15 of the segment is inserted. The fixture 29 is then made into a mold together with the tension spring 15, for example made of aluminum or lead. Conductive plastics can be used in the molds, so that the path of the continuous, conductive eyelets 17 can be used to make looms.

6 and 7 show the third embodiment, in which the same members use the same reference numerals. In schematic illustration, the eyelet 17 near the eyelet portion 18 is not shown in FIG. 6. This cannot be confirmed later. In the embodiment of FIGS. 6 and 7, the tension springs 15 of the segments are formed of plates. In other words, the tension spring 15 is integrally connected with the base body 30. As can be seen in Figure 6, the plate end is provided with a hardened portion 31 to form the basic body 30 later. The tension spring 15 is cut from the thin area 32, for example by splitting the body of water.

As described above, according to the present invention, it is possible to drive a warp loom capable of pattern knitting at a high operating speed.

Claims (17)

In a warp loom having a weaving zone, a yarn feed zone, a yarn tension section between the weave zone and the yarn feed zone where tension springs are disposed with guides for each yarn. The tension spring 15 is inclined loom, characterized in that formed of fiber reinforced plastic. The warp loom according to claim 1, wherein the plastic is conductive. The warp loom according to claim 1, wherein the plastic is reinforced with carbon fiber. The warp loom according to claim 1, wherein the guide part is formed of an eyelet (17) connected to the tension spring (15) while being conductive. 5. The warp loom according to claim 4, wherein the eyelet (18) and the tension spring (15) are sprayed into the cavity with the plastic. The warp loom according to claim 1, wherein the tension spring (15) has a natural frequency corresponding to at least 1.8 times the driving frequency of the warp loom. 7. The warp loom according to claim 6, wherein the tension spring (15) has a damping portion which generates 10% less damping than the vibration within 5 seconds after the activation of 100% vibration. The warp loom according to claim 1, wherein the tension spring (15) can use a storage path of at least 30 mm. 9. The warp loom according to claim 8, wherein the tension spring (15) has a movable force for a storage path of 35 cN or less. The warp loom according to claim 1, wherein the plurality of tension springs (15) are integrated into segments. 11. The warp loom according to claim 10, wherein said segment has two tension jaws (20, 21) into which said plurality of tension springs (15) are fitted side by side. 12. The warp loom according to claim 11, wherein said tension spring (15) has a cushion (24) in the end region sandwiched between said tension jaws (20, 21). 13. The warp loom according to claim 12, wherein said cushion (24) ends inside said tension jaw (20, 21). 12. The warp loom according to claim 11, wherein said tension spring (15) has a projection (25) inserted into a protrusion (26) in said tension jaw (20). 12. The warp loom according to claim 11, wherein said tension jaw (20, 21) has side-by-side insertion features having at least one protrusion (23) and at least one protrusion (33). 11. The warp loom according to claim 10, characterized in that the segment has a fixture (29) that is made into a mold together with the tension spring (15). 11. The warp loom according to claim 10, wherein the segment is formed integrally with the base body (30) and the plurality of tension springs (15).