DE3821224C1 - Air-jet weaving machine for multi-web weaving - Google Patents

Abstract

What is described is an air-jet weaving machine for multi-web weaving for large weaving widths, a single weft-insertion apparatus and a weft-insertion channel being provided in conjunction with a shedding device and a warp let-off device. The air-jet weaving machine for multi-web weaving is to be developed in such a way that a reliable weft insertion is guaranteed, relatively irrespective of the yarn quality, so that, even in the case of large weaving widths, an excellent fabric quality is achieved. For this purpose, provision is made for arranging respectively in the interspace between two weaving webs an intermediate nozzle which connects in alignment one weft-insertion channel of one weaving web to the other weft-insertion channel of the other weaving web, the intermediate nozzle being designed as an accelerating nozzle.

Description

The invention relates to an air weaving machine for multi-lane weaving for large weaving widths according to the preamble of claim 1.

Such air weaving machines are characterized in that two or multiple webs can be woven, only one Weft insertion device is present. Above all, multi-lane weaving used with large weaving widths and has the advantage that one Saves machine effort because with a single air intake device two webs can be woven simultaneously.

Also the shedding devices, the warp let-off devices and the fabric winding is only available.

So you have high weft insertion rates despite low weaving frequencies achieved.

However, there are such air weaving machines for multi-lane weaving Difficulties with large web widths. You use big ones Weaving widths, then there is an instability of the weft entry. With as the weaving width increases, the spread of the thread speed increases; d. H. the arrival time of the weft thread on the catch side cannot can be determined more exactly, but is subject to a specific one Scattering, the greater the width of the weave, the greater.

This spread depends on the type of thread, namely the air-effective yarn surface.  

Therefore, in the previously known multi-loom weaving machines, the Disadvantage that you could not exceed certain weaving widths. At large weaving widths were therefore too low in quality count because the weft could not be stretched quickly enough and by spreading the arrival time a uniform stretch of the Weft could not be guaranteed. It even happened Shot stops, with which the production speed is essential was affected.

Larger weaving widths even prevented the use of certain yarns due to their air-effective surface such scattering did not cause use of these yarns with large weaving widths was more possible.

The invention is therefore based on the object of a weaving machine to develop multi-lane weaving in such a way that it is relatively independent of the Yarn quality ensures a safe weft insertion, so that Excellent quality of goods achieved even with large weaving widths becomes.

To achieve the object, the invention is thereby characterized in that each in the space between two webs Arranged between the nozzle, which is in alignment with the one weft insertion channel one weave with the other weft insertion channel of the other weave connects and that this intermediate nozzle is designed as an acceleration nozzle is.

With the use of an intermediate nozzle according to the invention between two a completely new effect is achieved because of neighboring weaving lanes in the intermediate nozzle is the thread that comes from the weft insertion channel a web comes in, sucked in, accelerated in this intermediate nozzle,  i.e. So give it a certain boost and increase it with this The weft thread is thrust into the weft insertion channel of the neighboring one Web lane shot in.

This is the main advantage that it is centering and Stabilization of the weft thread comes, so that the scatter of the thread tightness speed becomes smaller, and thus almost even with large webs uniform thread arrival can be guaranteed.

With the intermediate nozzle used according to the invention, it is thus possible far exceed the previously known weaving widths; for example it is now possible with the use of the intermediate nozzle according to the invention, an air weaving machine with two webs and a total weaving width of 4 m to realize, even processing unfavorable yarn qualities can be, so that such a novel air weaving machine has a wide range of applications.

In a preferred embodiment of the invention, the intermediate nozzle is designed as a Venturi nozzle, which consists of a conical inlet funnel 21 , on the outer circumference of which radial bores are arranged on the circumference and the outer circumference of which is flowed by a longitudinal air flow, so that in the inlet opening of the inlet funnel a suction effect on the incoming weft thread is achieved and at the outlet of the Venturi nozzle even the speed of sound or a multiple of the speed of sound is achieved, so that the thread in this intermediate nozzle is accelerated many times faster than it could be accelerated by the relay nozzles arranged in the weft insertion channel.

So this is an extraordinary stabilization and Acceleration effect achieved by the intermediate nozzle according to the invention,  so that the large weave widths described can be reached.

In a development of the invention it is provided that several intermediate nozzles can be connected in series to possibly with certain very difficult yarn qualities Acceleration and stabilization effect still to be improved.

There is for the separation of the weft thread between the weaving lanes several options.

First of all, the weft can be separated in the intermediate nozzle itself be made, with a slot in the intermediate nozzle, the blades of a pair of cutting scissors engage in the airtight and Blade stop the separation of the weft thread between the webs to reach.

It would also be possible to arrange a pair of cutting shears either in front the intermediate nozzle or is arranged behind the intermediate nozzle.

In a third embodiment is a non-contact severing the weft possible by z. B. in the intermediate nozzle Laser optics is arranged and severing with a laser beam he follows.

Instead of laser optics, you can also use an ultrasound beam separate or with a heat beam that corresponds to a corresponding Heating source is heated.

It is also possible to use the separation devices described to be arranged on one side of the intermediate nozzle outside the intermediate nozzle,  e.g. B. at the outlet of the intermediate nozzle.

In the following, the invention is based on only one Execution path illustrating drawings explained in more detail. Here go further from the drawings and their description essential features and advantages of the invention.

Here shows:

Fig. 1 shows schematically in side view an air weaving machine for multi-lane weaving and

Fig. 2 enlarged in section an intermediate nozzle according to the invention.

The air weaving machine for multi-lane weaving consists of the weft insertion apparatus, which consists of a package 1 , from which the weft thread 2 is drawn off and fed to a weft thread store 4 via a thread guide 3 .

The weft thread 2 is introduced from the weft thread store 4 into a main nozzle 5 which, with a corresponding air pulse control, shoots the weft thread 2 into the weft insertion channel 13 of a first weaving web 7 .

The weaving machine 6 in this case has two weaving webs 7 , 8 which are arranged parallel and at a distance from one another, each weaving web being associated with the corresponding shedding devices. such as B. the Profilriete 9 , 10 , the dobby and eccentric.

The second weaving web 8 has a weft insertion channel 14 of the same type, the weft thread 2 being transported in the weft insertion channels 13 , 14 through corresponding relay nozzles 11 , 12 .

According to the invention, the intermediate nozzle 15 according to the invention is now arranged in the space between the two webs 7 , 8 . The intermediate nozzle 15 here consists of a nozzle body 18 to which an air supply 16 is connected. The nozzle tube 17 connects to the nozzle body 18 . It is important that the intermediate nozzle 15 connects the weft insertion channel 13 of the web 7 in alignment with the weft insertion channel 14 of the weaving web 8 .

Going from FIG. 2, further details out of the intermediate 15 according to the invention.

It can be seen here that the intermediate nozzle 15 contains a Venturi nozzle 28 , which forms an inlet funnel 21 on its inlet side, into which the air flows in the direction of the arrow 25 and has negative pressure there.

The weft thread coming from the weft insertion channel 13 is thus sucked in in the direction of the arrow 25 and introduced into the Venturi nozzle 28 with negative pressure.

At the mouth 29 of the Venturi nozzle 28 , the weft thread enters an air flow of higher speed, which can be the speed of sound or a multiple of the speed of sound, so that the thread is strongly accelerated, tightened and centered in this area in the direction of arrow 26 .

This is achieved in that the nozzle body 18 is arranged on the outer circumference around the Venturi nozzle 28 and has a circumferential annular channel 22 , from which radially inward bores 23 are evenly distributed over the circumference. These bores open into an air chamber 24 , which tapers in the area on the outer circumference of the Venturi nozzle 28 and then widens in the vicinity of the mouth 29 of the Venturi nozzle 28 , so that 30 sonic speed is reached in the area of the narrowest cross section and by the following expansion in cross section 31 the air flow expands and thereby a supersonic speed is reached, so that the thread is torn away in the direction of arrow 26 and then flows accelerated through the nozzle tube 17 .

So when the thread leaves the nozzle mouth 27 of the nozzle tube 17 it is strongly accelerated, centered and stabilized.

The thread thus receives a strong thrust through this intermediate nozzle 15 according to the invention and is fed with this thrust into the weft insertion channel 14 of the two weaving webs 8 .

This results in a relatively precisely determinable thread arrival time on the catch side of the second weaving web 8 and thus high quality fabrics with large weaving widths can be woven even with difficult yarn qualities.

It is provided here that the air supply 16 takes place in pulses to the intermediate nozzle 15 , namely until the thread has reached the catching side of the second weaving web 8 .

The following is a preferred embodiment of a separation device described.

In this case, slots 20 are arranged in the nozzle tube 17 of the intermediate nozzle 15 , into which a cutting shear 19 engages. The separating scissors can be driven in the radial direction, so that the separating scissors 19 come into action at the sheet stop and cut off the weft thread.

In a further development of the invention it is provided that further stabilizing tube cross sections are arranged in the interior of the nozzle tube 17 , such as, for. B. conical air ducts.

In a further embodiment of the invention, it is provided that the nozzle tube 17 widens conically outward in the region of the nozzle mouth 27 in order to achieve air acceleration.

The inventive intermediate nozzle 15 there is the further advantage that an improved yarn guide in the channel is ensured because without this intermediate nozzle (as only known so far) lacks this yarn guide; the weft therefore tends to drop or fall in the weft insertion channel and there are therefore difficulties in centering the weft in the weft insertion channel 14 of the second weaving web 8 .

With the use of the intermediate nozzle 15 according to the invention there is the further advantage that now not so high air capacity is necessary for the relay nozzles 12 of the second woven cloth 8, as was required previously without using an intermediate nozzle 15 according to the invention. So you can save air and the yarn quality is better because the thread is not so roughened by the smaller amount of air.

Here, for example, two air stores 32 , 33 are shown in FIG. 1, each air store being associated with a weaving web 7 , 8 , respectively. Valves 34 , 36 attach to each air reservoir 32 , 33 , with several lines 35 , 37 emanating from each valve, which are connected to the relay nozzles 11 , 12 in an air-tight manner.

With the use of two air reservoirs 32 , 33 it is therefore possible to specifically adapt the amount of air specifically for each weaving web 7 , 8 and thus obtain a significantly lower air consumption.

Claims (11)

1. Air weaving machine for multi-lane weaving for large weaving widths, a single weft insertion apparatus and a weft insertion channel being provided in connection with a shedding device and a warp let-off device, characterized in that an intermediate nozzle is provided in each case in the space between two weaving webs ( 7 , 8 ) ( 15 ) is arranged, which connects one weft insertion channel ( 13 ) of one weaving web ( 7 ) in alignment with the other weft insertion channel ( 14 ) of the other weaving web ( 8 ), and that this intermediate nozzle ( 15 ) is designed as an acceleration nozzle. 2. Air weaving machine according to claim 1, characterized in that the intermediate nozzle ( 15 ) is designed as a Venturi nozzle ( 28 ) and consists of a conical inlet funnel ( 21 ), on the outer circumference distributed around the circumference in a nozzle body ( 18 ) with a circumferential annular channel ( 22 ) radial bores ( 23 ) are arranged, the outer circumference being flushed through by a longitudinal air flow from an air supply ( 16 ). 3. Air weaving machine according to claim 2, characterized in that the bores ( 23 ) open into an air chamber ( 24 ) in the manner of a further nozzle, the air chamber ( 24 ) tapering in the area on the outer circumference of the Venturi nozzle ( 28 ) and then in The vicinity of the mouth ( 29 ) of the Venturi nozzle ( 28 ) is expanded to a cross section ( 31 ) in such a way that the speed of sound is reached in the area of the narrowest cross section ( 30 ) in the air chamber ( 24 ). 4. Air weaving machine according to claim 2, characterized in that the air supply ( 16 ) is provided in a pulsed manner to the intermediate nozzle ( 15 ) until the thread ( 2 ) has reached the catching side of the second weaving web ( 8 ). 5. Air weaving machine according to claim 1, characterized in that the intermediate nozzle ( 15 ) at the outlet has a nozzle tube ( 17 ) in which stabilizing tube cross sections are arranged in the manner of conical air guide tubes. 6. Air weaving machine according to claim 5, characterized in that the nozzle tube ( 17 ) in the region of the nozzle mouth ( 27 ) widens conically towards the outside. 7. Air weaving machine according to claim 1, characterized in that several intermediate nozzles ( 15 ) are arranged in series one behind the other. 8. Air weaving machine according to claim 1, characterized in that the weft thread ( 2 ) in the region of the intermediate nozzle ( 15 ) is separated, wherein in the intermediate nozzle ( 15 ) a slot ( 20 ) is provided, in which the blades of a pair of cutting scissors ( 19 ) intervene and cut off the weft thread ( 2 ) at the leaf stop. 9. Air weaving machine according to claim 8, characterized in that two shears ( 19 ) are provided, one in front of the intermediate nozzle ( 15 ) and the other after the intermediate nozzle ( 15 ) is arranged. 10. Air weaving machine according to claim 8, characterized in that the weft thread ( 2 ) is cut without contact by arranging a laser optics or an ultrasonic device or a heat beam in the region of the intermediate nozzle ( 15 ). 11. Air weaving machine according to claim 8, characterized in that the separating devices for the weft thread ( 2 ) are arranged on one side outside the intermediate nozzle ( 15 ) at the outlet of the intermediate nozzle ( 15 ).