CZ32540U1 - A device on a weaving machine for pulling the linking warp threads from the phase into the gap between the upper and lower outer fabric of the spacing fabric - Google Patents

Description

The Industrial Property Office does not ascertain in the registration procedure whether the subject of the utility model meets the conditions of eligibility for protection pursuant to Section 1 of Act no. No. 478/1992 Coll.

Weaving machine apparatus for pulling out the warp threads from the shed to the gap between the upper and lower outer fabric of the spacer fabric

Technical field

The present invention relates to a weaving machine for pulling out the warp threads from the shed to the gap between the upper outer fabric and the lower outer fabric of the spacer fabric while forming the loops of the threads by means of a manipulation bar coupled with at least two electromagnets arranged above the upper outer fabric. fabric and back.

BACKGROUND OF THE INVENTION

The spacer fabrics comprise two outer fabrics and a plurality of rope threads attached to the outer fabrics and arranged between the outer fabrics.

US 8015999 B2 discloses a method of forming such a spacer fabric in which the spacer fabric is formed on a weaving machine from two warp yarn systems, of which the base warp yarn system serves only to weave both outer fabrics and the warp yarn system serves to weave both outer fabrics and during the interruption of the weaving process to form the rope threads by pulling the rope warp threads from the shed into the gap between the outer fabrics by means of the rope warp thread puller.

Pulling of the warp threads from the shed is done manually when the weaving is interrupted, when, after crossing the warp threads, one operator inserts a pull bar from one side into the shed which the other operator grips on the other and pulls the pull rod together. of warp threads by a third operator.

It is an object of the present invention to provide a weaving machine apparatus for pulling the warp threads out of the shed to the gap between the upper outer fabric and the lower outer fabric of the spacer fabric while forming the loops of the rope threads in the gap.

The essence of the technical solution

The aim of the technical solution is achieved by a weaving machine, which is based on the fact that the manipulation bar is equipped with permanent magnets assembled into Halbach fields, where the electromagnets can be coupled to electromagnets. The electromagnets are equipped with skis of non-magnetic material. are terminated by the pole piece of the respective electromagnet.

Due to the length of the handling bar, it is desirable to be made of a lightweight material and a high stiffness, such as a carbon composite or titanium, or a hard anodized duralumin.

In order to facilitate the manufacture of the handling bar, it is advantageous if the bar comprises, in its central part, a support core made of a lightweight material of high rigidity, to which the terminals are attached at the edges.

The core may be made of a carbon composite or titanium, or a hard anodized duralumin, or other suitable material.

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To strengthen the handling bar and reduce wear, at least a portion of the handling bar is overlapped with high-strength material cover plates selected from the group of stainless steels.

In a preferred embodiment, the entire handling bar is overlapped with the high-strength material.

For cooperation with electromagnets, it is advantageous if the permanent magnets arranged in the Halbach fields are situated at the ends of the handling bar, preferably at the terminals of the handling bar.

The Halbach fields of the permanent magnets are formed by rows of at least five permanent magnets which are arranged perpendicular to the length of the handling bar and the Halbach fields are arranged in the shed with a strong side upwards against the respective electromagnets.

The pole pieces of the electromagnets are terminated with working portions which reach into the electromagnet ski in its front part for optimum forces for catching and transporting the handling bar.

Said working portions of the pole pieces of the electromagnets are arranged in a direction perpendicular to the rows of permanent magnets arranged in the Halbach fields.

In order to increase the reliability of the device, a pick-up sensor is provided in each solenoid.

Clarification of drawings

An exemplary embodiment of a weaving machine apparatus according to the present invention is schematically shown in the drawings, where FIG. 1 shows a diagram of the mechanism of a weaving machine with a manipulation bar in a shed, FIG. Fig. 2 is a diagram of a weaving machine mechanism with a handling bar in the gap between the outer fabrics; 3 shows a view of a handling bar without cover plates, FIG. 4 shows a view of the overlapping cover plate, FIG. 5 is a view of the arrangement of permanent magnets in the Halbach field, FIG. 6 shows a section through an electromagnet, FIG. 7 shows a view of an electromagnet without winding, and FIG. 8 shows a view of the electromagnet without the right side cover.

Examples of technical solutions

Weaving machine apparatus for pulling warp threads 2 from shed P into the TO gap between the upper outer fabric T1 and the lower outer fabric T2 of the spacer fabric T in forming loops of the rope threads 200 by a handling bar 4 coupled with at least two electromagnets 5 arranged above the upper outer fabric T1 reversibly adjustable in the direction of withdrawal of the spacer fabric T and back will be briefly described in the diagrams of the weaving machine mechanisms in the handling bar 4 inserted into shed P (Fig. 1) and captured by electromagnets 5 and in the next step between the outer fabrics T1 and T2 (Fig. 2). The number of electromagnets 5 may be even higher, for example three or four, two being located at the edges and remaining in the central part, the handling bar 4 being provided with permanent magnets 44 arranged in the Halbach fields 440 at respective locations.

The spacer fabric T is formed from two warp systems, of which the base warp thread system 1 serves only to weave the two outer fabrics T1, T2 and the warp thread warp system 2 serves to weave the two outer fabrics T1, T2, and by pulling the warp threads 2 from the shed P into the gap TO between the outer fabrics T1, T2. The two warp thread systems 1, 2 pass in a known manner through the heald blades L and the beam 31 of the punch mechanism 3.

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In FIG. 1 shows the manipulation strip 4 in the shed P captured by the electromagnets 5 after the weft warp threads 2 have been crossed before inserting the strip 4 into the shed. Here, a part of the upper outer fabric T1 is clamped between the electromagnet 5 and the strip 4. In the next step, the handling bar 4 still held by the electromagnets 5 is displaced in the direction of withdrawal of the spacer fabric T by a specified distance, while pulling loops for the tie warp threads 2 into the gap between the outer fabrics T1, T2. of the warp war.

In the exemplary embodiment of FIG. 3 and 4, the handling bar 4 comprises a support core 41 made of a lightweight material of high rigidity, in an exemplary carbon composite design, which provides sufficient rigidity even at lengths greater than 1500 mm. The core 41 may also be made of another suitable material, such as titanium or hard anodized duralumin. To the core 41 are attached at the ends endings 42, 43, which receive permanent magnets 44, which are arranged in Halbach fields 440. Endings 42, 43 are different, the handling end 42 on the side facing the insertion mechanism of the handling bar 4 into and pulling out of shed P, and sliding end 43 on the opposite side. Locking holes 45 are provided in the handling bar 4, which serve to secure the precise position of the bar 4 when handling the weave, in particular after returning the bar to the shed before being pulled out of the shed P and retracting the bar into the shed P before capturing the electromagnets. .

The Halbach fields 440 of the permanent magnets 44 are formed by rows of at least five cubic magnets, as in the illustrated embodiment, the rows oriented in a direction perpendicular to the length of the handling bar 4 and the Halbach fields are arranged with a strong side up against the electromagnets. In the illustrated embodiment, nine Halbach fields 440 of five permanent magnets 44 are used. The permanent magnets 44 in the individual Halbach fields are glued together and the individual rows of Halbach fields are glued into the holes formed in the respective terminal 42, 43 of the handling bar 4.

The handling end 42 of the handling bar 4 comprises at the free end 420 a recess 421 for engagement with the handling tweezers of the insertion mechanism, the leading edge 4211 of which serves as a tracking edge for the loss bar sensor 56 disposed on the respective electromagnet 5.

The sliding end 43 is rounded at the edges to reduce the risk of thread entrapment, and at its free end 430 is formed an aperture 431 therein whose front edge 4311 serves as a tracking edge for the pickup sensor 56 disposed on the respective electromagnet 5.

The handling bar 4 can be made in one piece (not shown) in which the permanent magnets 44 are mounted on the ends of the bar 4. Again, in this embodiment the ends at the free ends of the handling bar 4 are the same or similar to the free ends 420. 430 of the terminals 42, 43.

In order to increase the strength and durability, the handling bar 4 is overlapped by cover plates 40 of high-strength material, for example of high-strength stainless steel, at least over a portion of its length coming into contact with the warp threads 2. In the embodiment of FIG. 4, the handling bar 4 is lapped over its entire length up to the free ends 420, 430. Thus, a smooth, firm and durable coating is formed on the surface of the handling bar 4 which comes into contact with the threads.

The electromagnets 5 are formed by a core 51 around which a coil 52 is arranged. The lower pole piece 53 and the upper pole piece 54 are mounted on the core 51. The lower pole piece 53 is embedded in a non-magnetic material ski 55 that is provided with a smooth coating allowing the ski 55 to slide easily over the upper outer fabric T1 and warp threads 1. In the front of the ski 55, the lower pole piece 53 is terminated by a working portion

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531. Attached to the upper pole piece 54 is the front portion 540 of the upper pole piece 54 terminated in the ski 55 by the work piece 541, which is disposed near and parallel to the rear work piece 531 of the lower pole piece 53, 531 and 541 of the pole pieces 53, 54 are adapted to achieve the shortest loop of the rope warp yarns 2 as they are pulled out of the shed P and at the same time to exert maximum work force on the handling bar 4. In the electromagnet 5 directions of movement, which is interconnected with the means of the weaving machine control system. In a particular embodiment, the sensor is an inductive sensor with optical signaling, and the right electromagnet 5 sensor 56 tracks the front edge position 4211 of the tweezer recess 421 in the free end 420 of the handling bar 42 and the left electromagnet 5 sensor follows the front edge position 4311 431 in the free end 430 of the sliding end 43 of the handling rail 4. On the rear and side sides, the electromagnets 5 are provided with covers 57.

The dimensions and distance of the working portion 531 of the lower pole piece 53 and the working portion 541 of the top pole piece 54 are bound to the dimensions of the permanent magnets 44 in the handling bar 4 arranged in the Halbach fields 440. In an exemplary embodiment, the width of the working parts 531, 541 is equal to the length of the permanent magnet side. 44 and the distance between the working portions 531 and 541 is also equal to the length of the side of the permanent magnet 44. The length of the working portions 531 and 541 of the pole pieces 53, 54 is equal to or less than the length of the Halbach array 440. to Halbach fields.

The number of electromagnets 5 may be even higher, for example three or four, two being located at the edges and remaining in the central part, the handling bar 4 being provided with permanent magnets 44 arranged in the Halbach fields 440 at respective locations.

The number of permanent magnets 44 in the Halbach field is given by 4n + 1, so the minimum number is five.

Industrial applicability

The technical solution is intended for weaving machines for forming a spacer fabric, on which it creates a system for pulling the warp threads out of the shed to the gap between the upper outer fabric and the lower outer fabric in forming the loops of the rope threads.

PROTECTION REQUIREMENTS

Claims (11)

A weaving machine apparatus for pulling out the warp threads (2) from the shed to a gap (TO) between the upper outer fabric (T1) and the lower outer fabric (T2) of the spacer fabric in forming the loops of the threads (200) by means of a handling bar (4) coupled with at least two electromagnets (5) arranged above the upper outer fabric (T1) reversibly adjustable in the direction of withdrawal of the spacer fabric (T) and back, characterized in that the handling bar (4) is at locations where it is coupled with the electromagnets (5). 5), provided with permanent magnets (44) assembled into Halbach fields (440), the electromagnets (5) being provided with a ski (55) of non-magnetic material at the bottom, terminating the pole pieces (53, 54) of the respective electromagnet (5) ). Device according to claim 1, characterized in that the handling bar (4) is made of a light material of high stiffness selected from the group of carbon composite or titanium or hard anodized duralumin. -4GB 32540 U1 Device according to claim 1, characterized in that the handling bar (4) comprises a support core (41) made of a lightweight material of high rigidity to which the end pieces (42, 43) are attached at the edges, the support core (41) is made of carbon composite, or titanium, or hard anodized duralumin. Device according to any one of the preceding claims, characterized in that at least a part of the handling bar (4) is overlapped by cover plates (40) of high-strength material selected from the group of stainless steels. Device according to claim 4, characterized in that the entire handling strip (4) is overlapped with the high-strength material. Device according to any one of the preceding claims, characterized in that the permanent magnets (44) arranged in the Halbach fields (440) are situated at the ends of the handling bar (4). Device according to claim 6, characterized in that the permanent magnets (44) are situated in the terminals (42, 43) of the handling bar (4). Device according to any one of the preceding claims, characterized in that the Halbach fields (440) of the permanent magnets (44) are formed by rows of at least five permanent magnets (44), the rows being arranged perpendicular to the length of the handling bar (4) and the Halbach the fields (440) are arranged in the shed with their strong side upward against the respective electromagnets. Device according to any one of the preceding claims, characterized in that the pole pieces (53, 54) of the electromagnet (5) are terminated by working portions (531, 541) which extend into the ski (55) at the front thereof. Device according to claim 9, characterized in that the working portions (531, 541) of the pole pieces (53, 54) are arranged in a direction perpendicular to the rows of permanent magnets (44) arranged in the Halbach fields (440). Device according to any one of the preceding claims, characterized in that a sensor (56) for the loss of the handling bar (4) is arranged in the electromagnet (5).