EP0534132A1 - Process for the weft insertion in an air-jet loom - Google Patents

Abstract

What is described is a process for weft insertion on an air-jet loom with a plurality of yarn bobbins forming a yarn supply, the yarn end of one bobbin being connected to the yarn start of the other bobbin and the transfer of the yarn to the other bobbin being detected. <??>The object is to eliminate adverse influences which take effect during the transfer of the weft yarn from one yarn supply to the next following the weft insertion. <??>For this purpose, the programmed travelling field of the staggered nozzles has temporarily superposed on it before, during or immediately after the detection a transitional travelling field which is maintained until an initial quantity of weft yarns is drawn off from the yarn supply or until the yarn flight time has reached its desired value. The return to the programmed travelling field takes place thereafter.

Description

The invention relates to a method for weft insertion on an air jet loom according to the preamble of patent claim 1.

When operating air jet looms, it is generally known that the transport of the weft thread through the entry channel in the reed and here in particular the entry time or speed required for the weft entry is dependent on several factors.
For example, there are differences in the air effectiveness of the thread from one and the same thread supply and fluctuations in the winding density of the thread supply, i.e. the weft threads of the upper thread layers of a thread supply generally have a surface structure that is less favorable for air attack than the middle and end positions of the thread supply , to be corrected by a corresponding procedure for weft insertion in the weaving machine.
In order to be able to compensate for these shortcomings and to ensure the entry time or the speed of the weft that is fixed in the program control within a weaving cycle, it is known that the entry time or the speed of the weft in the sense of an increase or decrease in the air pulse duration through the main nozzle of an air jet weaving machine influence.
It is not known to do this by including the relay nozzles or by the relay nozzles themselves.

According to DE-OS 38 18 766 it is known to further develop the control of the relay nozzles of an air jet loom so that different yarn qualities can be processed in successive operations. To do this, the Relay nozzles controlled in groups and the duration of the pulse length of the control regulated depending on the air effectiveness of the yarn to be processed.
Influences which have a negative effect on the weaving process when the weft thread is transferred from one thread supply to another supply cannot be eliminated with the known solution.

When processing threads of the same quality, but which are subtracted from two different interconnected thread stores, these shortcomings occur in the same way. In addition there are other influences, namely those which arise when the first thread supply from which the weft thread has just been drawn comes to an end and the next thread supply is transferred. Here the thread end of the outgoing supply is connected to the thread start of the full supply, for example.
Although, as already stated, this is the same weft thread quality, the influences resulting from the thread transition cannot be easily remedied using the known relay nozzle control.
The individual relay nozzles or groups of relay nozzles would in fact be used to set up a new traveling field according to the program and to maintain it with a comparatively higher pressure, that is to say a higher energy requirement, and to allow it to act on the weft thread. The entry parameters for the weft thread, once specified, would have to be changed, which would not have an impact on the productivity of the weaving machine. In addition, this measure would cause an undesirably high consumption of feed fluid, but this can be ruled out.

The invention is therefore based on the object, in addition to the program-oriented traveling field already formed by the relay nozzles for transporting the weft thread through the weft thread entry channel, with the disadvantageous influences which act on the weft thread entry during the transition of the weft thread from one thread supply to the next eliminate.

• daß während oder unmittelbar nach dem Übergang des Schußfadens von dem einen Fadenvorrat auf den nächstfolgenden dem programmgemäß ausgebildeten Wanderfeld zeitweilig ein Übergangswanderfeld überlagert wird,
• daß das Übergangswanderfeld solange aufrechterhalten bleibt, bis eine Anfangsmenge von Schußfäden vom nächstfolgenden Fadenvorrat abgezogen ist oder bis die Fadenflugzeit ihren Soll-Wert erreicht hat und
• daß nachfolgend zu dem programmgemäß ausgebildeten Wanderfeld zurückgekehrt wird.

According to the invention, the object is achieved by

• that a transition hiking field is temporarily superimposed during or immediately after the transition of the weft thread from the one thread supply to the next following one, which is designed according to the program,
• that the transition hiking field is maintained until an initial amount of weft threads has been subtracted from the next thread supply or until the thread flight time has reached its desired value and
• that is subsequently returned to the hiking field trained according to the program.

It has been shown that the disadvantageous influences on the weft thread insertion during the transition of the weft thread from the empty to the full thread supply can essentially only be achieved by temporarily increasing the pulse duration of the groups of relay nozzles which form the traveling field according to the program. Surprisingly, it has also been shown that the extension of the pulse duration can be canceled after only a few weft threads entered by means of the transition hiking field. This ensures that a higher air consumption that is estimated for the establishment and maintenance of the transition hiking field is not recorded.

Further features which advantageously design the solution according to the invention result from the subclaims.

Figur 1

zeigt die Abhängigkeit der Fadenflugzeit (FFZ) und des Energiebedarfs (EB) vom Durchmesser der Fadenspule ohne Schußeintragsregelung,

Figur 2

die Abhängigkeit der Fadenflugzeit (FFZ) und des Energiebedarfs (EB) vom Durchmesser der Fadenspule mit Schußeintragsregelung,

Fig. 3

die Abhänigkeit der Fadenflugzeit (FFZ) und des Energiebedarfs (EB) vom Durchmesser der Fadenspule unter Verwendung eines Spulenüberlaufsensors und mit Schußeintragsregelung.

The invention is explained in more detail below using an exemplary embodiment.

Figure 1

shows the dependence of the thread flight time (FFZ) and the energy requirement (EB) on the diameter of the thread spool without weft insertion control,

Figure 2

the dependence of the thread flight time (FFZ) and the energy requirement (EB) on the diameter of the thread spool with weft insertion control,

Fig. 3

the dependence of the thread flight time (FFZ) and the energy requirement (EB) on the diameter of the thread spool using a spool overflow sensor and with weft insertion control.

In Figures 1 to 3, the influence of the bobbin diameter reduction on an air jet loom, i.e. the weft thread consumption leading to the diameter reduction, on the important parameters, such as thread flight time (time of the weft thread, which it takes from the thread start on the weft thread insertion side to the thread arrival) is shown on the basis of the diagrams on the weft arrival side of the weaving machine) and energy consumption (amount of fluid per unit time for the weft insertion into the shed).
In order to clarify the advantageous effect of the invention, a distinction is made in these representations between a weft insertion without and a weft insertion with weft insertion regulation.

The decrease in the bobbin diameter D to d or the weft thread consumption (SFV) is plotted on the abscissa and the filament flight time (FFZ) and energy requirement (EB) are plotted on the ordinate.

FIG. 1 shows the course of the flight time of the weft thread as a function of the diameter of the thread supply with constant energy input EB for the weft thread insertion into the shed of a weaving machine. A regulation of the weft thread entry is not provided here. It is clear from this that with decreasing diameter of the thread supply from D to d the flight time FFZ of the weft thread through the shed also decreases.
It is also shown that the energy requirement EB in air, an important parameter for the weft insertion Air jet weaving machines, regardless of the thread supply quantity, is constant. The thread flight time FFZ and the energy input for the weft thread insertion are therefore not interdependent. These are serious disadvantages because, on the one hand, different thread flight times have a negative impact on the performance of the weaving machine and, on the other hand, the same energy requirement as is required for the weft thread withdrawal from a full thread supply is also taken into account when the thread supply runs out. This means that a consistently constant energy requirement is not required.

On the basis of the above-mentioned facts, the person skilled in the art strives to influence the weft insertion speed and thus the weft flight time FFZ in the sense of keeping it constant. For this purpose, the energy requirement EB required for the weft thread transport through the shed via the relay nozzles, not shown, had to be adapted to the changing conditions on the thread supply 1A.
This adjustment was carried out by means of a weft insertion control known per se, the sequence of which is shown in FIG. 2.
According to this, a target value 5 for the thread flight time FFZ of the weft thread is determined by the shed. The energy requirement EB used to ensure a weft flight time FFZ that is to be kept constant from weft insertion to weft insertion over the width of the shed is dependent on the current quantity of the thread supply present on the respective thread spool 1A, 2A, 3A etc. That is to say, the need for transport medium, which is required via the individual relay nozzles or relay nozzle groups, in order to transport the weft thread to be inserted into the shed, increases substantially continuously as the thread supply on the thread spool 1A, 2A etc. decreases to the thread supply "zero" the coils 1B, 2B and so on.
Relative to the duration of the activation of the relay nozzles or groups of relay nozzles in the weaving machine this in that the duration of the activation of the valves upstream of the relay nozzles and thus the blowing duration of the relay nozzles is reduced.
During the transition of the weft thread from an empty thread supply 1B to a filled thread supply 2A, an increase in the thread flight time above the target value 5 to an actual value 6 per weft thread entry can be recorded due to the conditions as they exist at the time of the thread transition. The increase in the filament flight time FFZ to a value above the target value 5 is shown in FIG. 2.
Since the energy requirement specified by the control EB (target value 4.1), as it acts on the start of a weft thread to be withdrawn from a filled thread supply and cannot be exceeded during the thread transition, there is an inevitable extension of the thread flight time Δ FFZ 1 in this time interval . This leads to loose threads in the fabric to be manufactured and thus to inferior woven goods.
The solution according to the invention now also remedies this defect.

In FIG. 3, a bobbin overflow sensor 7 is integrated between the decreasing thread supply 1B and the filled thread supply 2A. This sensor 7 detects the transition of the weft thread from the one thread supply 1B to the other thread supply 2A to the control unit of the air jet weaving machine, not shown here.
Thereupon, the traveling field according to the program, which is formed by successively actuating the relay nozzles or groups of relay nozzles distributed over the weaving width, that is, before, during or immediately after the thread supply 1B has run out, by switching from the target energy requirement 4.2 to the target Energy requirement 4.1, that is, by comparatively increasing the pressure of the medium acting on the weft thread, superimposes the operating interval 8 of a transition hiking field.
As shown in FIG. 3, this leads to the fact that the weft flight time of the weft threads of the expiring supply 1B, 2B temporarily compared to the yarn flight time FFZ predetermined according to the program (Target value 5) is undershot. The weft thread is therefore first carried in the operating interval 8 by the amount of time FFZ - Δ FFZ₂ faster through the shed. After an initial amount of weft threads has been withdrawn from the thread supply 2A, 3A or until the thread flight time has reached its target value 5 again, the program returns to the traveling field designed according to the program.

With these steps according to the invention it is achieved that it does not, as shown in the diagram. Fig. 2 can be seen - as a result of the direct transition from empty stock to full stock - in the transition phase from thread supply to thread supply to extended weft insertion times, to loose threads in the fabric or even to the loom being switched off. With the formation of the transition hiking field, these adverse consequences are completely eliminated.

DRAWING LEGEND

1A

Bobbin / thread supply full

1B

Expiring bobbin / thread supply

2A

Bobbin / thread supply full

2 B

Expiring bobbin / thread supply

3A

Bobbin / thread supply full

4th

Energy requirement - target value

5

Thread flight time - target value

6

Thread flight time - actual value

7

Coil overflow sensor

8th

Operating interval transition hiking field

D

Full bobbin diameter

d

Coil diameter leaking coil

Δ FFZ₁

Differential amount of filament flight time

Δ FFZ₂

Differential amount of filament flight time

Claims (3)

Method for weft insertion on an air jet loom with a plurality of thread bobbins forming a thread supply, according to which the weft end of a thread supply is connected to the weft thread beginning of another thread supply for the continuous provision of a weft thread, after which the transition of the weft thread from one to the other thread supply is detected and then detected Relay nozzles are fed with compressed air in accordance with a weft insertion program specified for a program carrier, and then the relay nozzles, according to the link existing between the program holder and a control unit, set up a traveling field by individual or group control when the weft is inserted into the shed,
characterized in that during or immediately after the transition of the weft thread from the one thread supply to the next following one according to the program, a transition hiking field is temporarily superimposed, that the transition hiking field is maintained until an initial quantity of weft threads has been withdrawn from the thread supply or until the thread flight time has reached its desired value has reached and that is subsequently returned to the hiking field trained according to the program. Method according to Claim 1, characterized in that the transition of the thread is detected and the transition hiking field is activated on the basis of this detection. Method according to Claims 1 and 2, characterized in that the thread is passed through a detection zone in a manner known per se.

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