WO2005014454A1 - Thread processing system and adaptation method - Google Patents

Abstract

The invention relates to an air-jet loom (W) and a thread processing system comprising at least one weft-thread measuring delivery device (F), in which a loom controller (MC) and a measuring delivery device controller (C) are connected via an information transmission route (A) for at least the cloth width (B, B') and the storage body diameter (D) that is to be set can be defined using the transmitted cloth width information (iB). An optoelectronic thread sensor (S) generates signals from the presence or absence of the weft-thread (Y) in a scanning zone (Z) on the storage body (4). The thread sensor (S) is a reflection-operated sensor, which can be used to generate weft-thread presence and absence signal levels (Hi, Lo, Hi , Lo ). An automatic level threshold selection device (K) is connected to the information transmission route (A), said device having at least two different level thresholds (S1, S2) for signal level evaluation for different cloth widths. Each level threshold value (S1, S2) lies between the respective presence and absence signal levels for the diameter that is correlated with the current cloth width (B, B'). This allows the measuring delivery device to automatically adapt, with regard to the thread scanning operation, to the current cloth width or the defined diameter (D) of the storage body.

Description

 Thread processing system and adjustment method

The invention relates to a thread processing system according to the preamble of claim 1 and a method according to the preamble of claim 6.

Since in an air jet weaving machine every weft thread is entered into the shed with air jets, the weft length must be measured by the measuring device according to the weaving width set in the air jet weaving machine. For this purpose, a stop device with a stop element is provided on the measuring delivery device, which, depending on the weaving cycle, is moved into or withdrawn from the storage body. The indented stop element locks the weft thread against a trigger. The retracted stop element allows a predetermined number of weft threads to be drawn off until it is re-engaged until the respective weft length is reached. In order to adjust the weft length to the respective weaving width in the shed, the diameter of the storage body is set so that an integral multiple (the number of turns to be released) of the storage body circumference corresponds to the weft length or weaving width. Such an adjustment is necessary, for example, with every change in the weaving width, and possibly also as readjustment if weft threads that are too short or too long occur. In order to simplify operation, in modern air-jet weaving machines there is an information transmission path between the weaving machine control, which is informed about the respective weaving width, and the measuring device control for mutual communication, for example in a serial CAN bus system for at least the weft length or the weaving width intended. From the information received in each case, for example, the microprocessor of the measuring control device calculates the number of weft threads to be released per weft and the respectively optimal diameter of the storage body; which is displayed either on the measuring delivery device or on the control panel of the weaving machine control, so that the personnel can carry out the diameter adjustment manually or with an auxiliary device. The measurement delivery device control is also responsible for providing a sufficiently large number of weft thread turns on the storage body, which covers the consumption by the intermittent weft withdrawal and is continuously supplemented. The weft turns are through a winding element is formed on the storage body. The winding element is driven by a motor which is controlled by the measuring device control, in response to signals from an optoelectronic thread sensor which supplies signals to the microprocessor from the presence or absence of the weft thread in a scanning zone on the memory body. If the thread sensor detects the presence of the weft thread in the scanning zone, the motor is decelerated or stopped. If the thread sensor detects the absence of the weft thread in the scanning zone, the motor is accelerated. In practice, there are opto-electronic thread sensors that can be divided into two main categories. The thread sensor of the first category uses a reflective surface from the storage body and monitors the light reflected from the surface, which is shaded as soon as the thread has reached the surface. The thread sensor of the other category scans the weft thread directly, ie it monitors the light reflected from the weft thread when it is present. In a measuring delivery device, especially in a measuring delivery device working with thread separation, the use of the thread sensor of the first category with a reflecting surface in the storage body is impractical for several reasons: the space for elements of the storage body that move during operation hardly allows to accommodate the reflecting surface. The installation space to be provided for the stop device used for thread dimensioning also limits the accommodation of a reflective surface. Since the contact area between the weft thread and the storage body should be as small as possible in order to minimize harmful friction, the large reflective area can hardly be provided in a sufficient size. Finally, the signal evaluation is difficult because, due to inevitable soiling, it can no longer be reliably discriminated whether the reflecting surface is covered by the weft thread or by soiling. All these restrictions do not apply to the thread sensor of the second category, which is therefore preferred for such thread processing systems. Another problem with the thread sensor scanning the reflection light of the weft thread is that it can be difficult to discriminate between the light reflected from the weft thread and light reflected from mechanical parts of the storage body in the background. The light reflected by background components changes, for example, in intensity, depending on whether a large diameter or a small diameter is set that the light path dis dance changes. However, since the measuring device control does not know the actually set diameter, it has not been possible to reliably avoid faulty signals after a diameter adjustment.

The invention has for its object to provide a thread processing system and a method of the type mentioned, with which the aforementioned disadvantage of a thread sensor of the second category in the measuring delivery device is eliminated in a structurally simple manner, and changing light reflections from background parts of the memory body have no influence on the precision take the weft feel.

The object is achieved with the features in claim 1.

According to the invention, the knowledge is taken into account that the signal levels of the presence and absence signals decrease as the diameter of the storage body decreases in the case of an optoelectronic thread sensor which responds to the reflection light of the weft thread and make it more difficult, in each case regardless of the diameter set between the presence and absence signal levels discriminate. The level threshold value selection device provided provides a level threshold value for the evaluation of the signal levels for a specific diameter setting range or a specific diameter of the memory body, which lies between the presence and absence signal levels generated at this diameter. The selected level threshold value is, so to speak, a reference plane, with the aid of which the microprocessor is informed exactly whether the thread sensor has detected the presence or absence of the weft thread. The level threshold value selection device uses the weft length or weave width information that is available in any case and outputs that level threshold value for signal evaluation that matches the set weave width or the diameter set with regard to the weave width. In this way, a falsifying influence is automatically prevented with the background reflection light changing in diameter because the selected level threshold value is matched to the diameter-dependent distance between the thread sensor and the weft thread in such a way that it varies between the values resulting from this diameter - and absence signal levels. In order to select the appropriate level threshold in each case, the weave width information is transmitted to the level threshold value selection device via the information transmission path. Based on this information, the level threshold selection device knows which of the various level threshold values is used. The information can be transmitted directly from the weaving machine control, or indirectly via the microprocessor, which either processes the information if necessary and issues a corresponding selection command to the level threshold value selection device or then uses the appropriate level for signal level evaluation. Procured threshold. The selection device uses the weaving width or diameter information which is present in any case in order to adapt the response behavior of the thread sensor accordingly and, above all, automatically, so that after the diameter setting has been carried out, the microprocessor is able to control the motor.

According to the method, the measuring delivery device is automatically adapted to the current weaving width by means of the weaving width information with regard to the weft thread scanning, without the staff needing to do more than set the specified diameter of the storage body.

In the event that a display for the diameter of the storage body calculated on the basis of the weaving width information is provided, either on the measuring delivery device or in the control panel of the weaving machine, which is activated or fed by the microprocessor in order to inform the staff accordingly, then one Transmission path can be provided either from the microprocessor or from the display to the level threshold selection device, which provides the correct level threshold for the signal level evaluation based on the calculated diameter.

Since the thread quality or thread color processed in each case also has an influence on the reflection behavior of the weft thread, it is expedient to provide an adjusting device for the thread quality or color parameters and to connect it to the microprocessor and / or the level threshold value selection device. The staff takes the setting of the appropriate parameter on the adjusting device. ters before. Either the microprocessor and / or the level threshold value selection device then takes this parameter into account when selecting the appropriate level threshold value for this thread quality or thread color and the calculated and / or set diameter of the storage body.

The level threshold value selection device is expediently integrated in the microprocessor, which anyway carries out the signal level evaluation and receives the weaving width information from the weaving machine control. In the case of a smart thread sensor of this second category, which carries out at least part of the signal level evaluation or signal processing itself and delivers signals that have already been processed to the microprocessor, the level threshold value selection device could, however, also be integrated into the thread sensor or its electronics.

The level threshold value selection device expediently contains at least two different level threshold values, which are assigned, for example, the maximum diameter and the minimum diameter or diameter adjustment ranges close to the maximum and minimum diameters. The level threshold values can be recorded in a table. It is conceivable not only to call up the threshold values in stages, but to provide the threshold values continuously. In the table, the level threshold values are correspondingly assigned to different weaving widths or different diameters of the memory body, so that the correct level threshold value is called up or set depending on the content of the weaving width information or the value of the calculated diameter.

Embodiments of the subject matter of the invention are explained with the aid of the drawing. Show it:

1 schematically shows a side view of a thread processing system,

Fig. 2 shows a schematic detail of Fig. 1, and

3 shows a diagram of signal levels over the storage body diameter. A thread processing system shown schematically in FIG. 1 has an air jet weaving machine W and in the one of possibly several thread channels a weft measuring delivery device F, from which an insertion device E intermittently enters weft threads Y of a predetermined weft length into a shed 5.

The air nozzle weaving machine W contains controlled air nozzles in the insertion device E and has a weaving width B shown in solid lines with a predetermined dimension. The weaving width B can be changed, as indicated at B '. A control panel 6 of the weaving machine is connected to a weaving machine control MC, which in turn is connected, for example, via a communication bus system BS (e.g. CAN system) and / or at least one information transmission path A to a measurement delivery device control C.

The measuring delivery device F has a drive motor M for a winding element 2 in a housing. A storage body 3 is mounted stationarily on the housing, which is designed, for example, as a rod cage with thin fingers and is used to carry a thread supply formed by the winding element 2 and consisting of turns. Feed elements (not shown) driven by the winding element 2 can work in the storage body 3 in order to produce a separation between the turns.

A stop device P with a stop element, which is adjustable between a stop position and a pull-off position, is mounted in a housing bracket. Furthermore, an optoelectronic thread sensor S is provided, which responds to the reflection light from the windings and gives signals to the delivery device control C, the signal level of which depends on whether a thread winding is present or absent in a scanning zone. The measuring delivery device control unit C evaluates the signals and drives the drive motor M in order to set the thread supply in a specific size (with a specific number of turns, for example up to the scanning zone). A manual or mechanical, possibly even remotely controllable, diameter setting device 4 is provided for the storage body 3. The diameter is marked with D. The stop device P is, as usual, from the measuring device control C, possibly taking into account information transmitted via the transmission path A or in some other way, controlled as a function of the weaving cycle in order to release the weft thread Y for withdrawal or to block the withdrawal.

The weaving machine control MC is informed about the set weaving width B, B 'and supplies information i _B on the weaving width B, B' to the measuring delivery device control C permanently or clocked. With this information, the measuring delivery control unit calculates how many turns per weft released for take-off and what diameter D is considered to be optimal and corresponds to the weaving width B as an integral multiple of the storage body circumference.

2 schematically illustrates equipment components of the measuring delivery device F. The optoelectronic thread sensor S is placed in the housing 1 or a housing extension so that it scans the weft thread Y in a predetermined scanning zone Z on the storage body 3. Since 3 components form a reflective background in the storage body, the thread sensor S picks up the reflection light from the weft thread, vary depending on the set diameter (the minimum and maximum diameters D _max and D _{min are} indicated in FIG. 2) because of the distance of the thread sensor S. the level of the signals emitted from the reflective background and the reflective weft. This will be explained with reference to FIG. 3.

3 shows, for example, the signal level of the thread sensor S on the vertical axis in volts (V), and the diameter D in millimeters on the horizontal axis. The first vertical line in the diagram corresponds to the maximum set diameter D _m ax. The vertical line shown on the right further represents the minimum set diameter D _m i _n. For example, for a black weft, the signal level changes from Hj when the weft is absent to L ₀ when the weft is present in the scanning zone Z. (Y = weft present, N = weft absent), between 5V (when absent) and 4V (if present). With a minimum diameter, the absence signal level Hj 'is 3V and the presence signal level L ₀ ' is only 2V for the same weft. Because the measuring device control does not have the actually set diameter D. is informed, it could no longer make a reliable statement about the control of the motor M from the signal levels which become weaker as the diameter decreases.

According to the invention, different level threshold values S1, S2 are provided for the signal level evaluation for different diameter settings or at least for one diameter setting range. The level threshold value S1, which is used at maximum diameter or a diameter adjustment range lying at maximum diameter, is approximately 4.5 V in the example Hj, 5V, L ₀ 4V. The other level threshold value S2 is at a minimum diameter setting or one Diameter range used for the minimum diameter and in the example Hi'3V,, LO'3V is about 2.5 V. In the signal level evaluation, it is then only determined whether the signal level is above or below the level threshold value S1 or S2 used. If the signal level is above the threshold value, it is decided that no weft thread is present. If it is below the threshold value, then it is decided that the weft thread is present. Since the respective threshold value is assigned to the set diameter or a specific diameter range and lies between the presence and absence signal levels then obtained, a clear and error-free statement is obtained in any case, with which the measuring device controller C correctly controls the motor M. can drive.

In FIG. 2, the measuring delivery device control C contains a microprocessor MP which is connected to the information transmission path A and which receives the weaving width information ß from the weaving machine control MC. Like the stop device P, the thread sensor S and the motor M are connected to the microprocessor MP. In solid lines in Fig. 2, the maximum diameter D _max and the minimum diameter D _{mm are shown} in dashed lines. As an additional equipment, a display R can be provided, for example in the measurement delivery device control C, in which the microprocessor MP displays the optimal diameter D calculated on the basis of the weaving width information i _B , and also the number G of the weft threads to be released for the weaving width per weft. Furthermore, an adjusting device T for thread quality or thread color parameters can be provided, which is connected to the microprocessor MP. The microprocessor MP feeds the display R with diameter information i _D, for example.

For the thread sensor S, which is aligned with the scanning zone Z of the storage body 3 and whose scanning distance varies depending on the respectively set diameter D or the microprocessor MP evaluating the signals, a level threshold value selection device K is provided, which is even directly in the microprocessor MP , for example, could be arranged in its signal evaluation circuits. The at least two different level threshold values S1, S2, for example in the form of voltage values in volts, are stored in a table Q in the level threshold value selection device K. The level threshold value selection device K is connected via an information transmission link (which could be embodied in the microprocessor MP) either directly (indicated by dashed lines) to the information transmission link A for the web width information i _B , or, as shown, to the Information transmission path connected between the microprocessor MP and the display R so that the level threshold selector K either eats the weave width information or receives the diameter information i _D , which is also fed into the display R. Alternatively, as indicated, the information intended for the level threshold value selection device K could also come directly from the microprocessor MP, possibly in processed form as selection commands. As a further alternative, it is conceivable that the microprocessor MP itself procures the level threshold value S1 or S2 that corresponds to the calculated diameter D.

In addition, a parameter for thread quality or thread color set in the adjusting device T can be given as color information i _c to the microprocessor MP and / or the level threshold value selection device K in order to take into account the reflection property of the respectively processed weft material in the signal level evaluation via a suitable level threshold value to be able to. The information transmission path A 'for the diameter information i _D either runs from the microprocessor MP or from the display R to the level threshold selector K, while the information transmission path A "can run from the adjusting device T to the selector K, either separately or likewise the microprocessor MP. Before the thread processing system is put into operation or after a change in the weaving width B, B ', the weaving width information i _{B is} transmitted to the measuring control device C, which calculates the diameter D to be set and the number G of the weft thread turns to be released and, if necessary, shows it in the display R (the display R could also be accommodated in the control panel 6 of the weaving machine W). If necessary, a thread parameter is also set on the setting device T and output as color information. From experience, or by means of the adjusting device 4, the calculated diameter D is then set by the personnel. At the same time, a suitable level threshold value S1 or S2 is set or called up either on the basis of the weave width information i _B or the diameter information i _D , and if appropriate with the color information i _c . In this way, the measuring delivery device F is also automatically adapted to the current weaving width B, B 'with regard to the weft thread scanning.

Incidentally, more than two different level threshold values can be stored, or one threshold value analogous to the diameter, i.e. infinitely variable, called up or set.

After the start of operation, the stop device P is placed in the release position and the weft thread Y is entered in the shed 5. Shortly before the set number G is reached, the stop device is put back into the stop position and the shot is ended. During this time, or possibly only afterwards, the motor M runs in order to replenish the thread supply on the storage body 3. When the thread sensor S detects the absence of the weft thread in the scanning zone Z, the motor is driven or accelerated. If the presence of the weft thread in the scanning zone Z is determined, the motor M is slowed down or stopped. The thread sensor S delivers a signal, for example with a higher absence signal level and, in the presence of the weft thread, with a lower presence signal level. The level threshold value S1 or S2 assigned to the diameter D or the weaving width B, B 'lies between the absence and presence signal levels Hj and L ₀ (Hj ¹ , L ₀ ') and is taken into account in the signal level evaluation. That is, the microprocessor MP makes the determination that the weft is absent when the signal level is above the level threshold and that the weft is present when the signal level is below the level threshold. With these findings, the control of the motor M is carried out.

The thread sensor S could be designed such that it delivers a higher signal level when the weft thread is present than when it is absent. The thread sensor S could be adjustable in the axial direction of the storage body 3 in the housing bracket. The stop device P is expediently adjustable, for example in the radial direction, in order to be set to an optimal position when the diameter is changed.

In an alternative, not shown, the level threshold value selection device K could also be accommodated in the weaving machine control MC or in the control panel 6, in order to then transmit the level threshold value S1 or S2, which is assigned to a specific weaving width B, B ', to the measurement control device control via the transmission link A. C to be transferred so that it is automatically adjusted during the operation of the measuring delivery device F and can work without errors regardless of the set diameter D. In the case of a smart thread sensor S with its own evaluation circuit, the level threshold value S1, S2, which is respectively adapted to the weaving width, could already be processed in the thread sensor S ', which then possibly delivers the presence and absence signals to the microprocessor MP.

Claims

claims

1. Thread processing system, comprising an air jet weaving machine (W) and at least one weft thread measuring delivery device (F) with a storage body (3) with an adjustable diameter (D) and a diameter adjustment device (4), with a weaving machine control (MC) and a measuring delivery device control (C) containing a microprocessor (MP), which is connected to the weaving machine control (MC) via an information transmission path (A) for at least the weft length or the weaving width (B, B '), with one in the Measuring control unit (C) contain evaluation circuit for calculating at least the storage body diameter (D) to be set on the basis of a transmitted weft length or weave width information (i _B ), and with at least one optoelectronic thread sensor (MP) connected to the microprocessor (MP) S), which generates signals from the presence or absence of the weft thread (Y) in a scanning zone (Z) on the storage body (3), characterized thereby t that the thread sensor (S) is a thread reflection sensor that responds to thread reflection light differences between the weft thread (Y) present or absent in the scanning zone (Z), taking into account a level threshold value (S1, S2), with which decreasing diameter (D) weaker presence and absence signal levels (Hi, L ₀ , Hj ', L ₀ ') can be generated, that an automatic level threshold value selection device (K) is provided and directly or indirectly to the information Transmission path (A) is connected, and that the level threshold value selection device (K) for different weft length or weave width information (iB) has at least two different level threshold values (S1, S2) for the signal level evaluation, each of which for the the weaving width (B, B ') correlated diameter setting range or diameter of the storage body (3) between the respective presence and absence signal levels (Hi, L ₀ ; Hi ', Lo').

2. Thread processing system according to claim 1, characterized in that a connected to the microprocessor (MP), which can be activated by the microprocessor (MP) with a diameter information (i _D ) display (R) for the on the basis of the transmitted weft length or weaving width ( B) calculated storage body diameter (D) is provided, and that a transmission path (A ') for the diameter Information (i _D ) is also provided by the microprocessor (MP) to the level threshold selector (K).

3. Thread processing system according to claim 1, characterized in that an adjusting device (T) is provided for thread quality or color parameters and is connected to the microprocessor (MP) and / or to the level threshold value selection device (K).

4. Thread processing system according to claim 1, characterized in that the level threshold value selection device (K) in the microprocessor (MP) or in the thread sensor (S) is integrated.

5. Thread processing system according to claim 1, characterized in that the at least two different level threshold values (S1, S2) in a different weave widths (B) or different diameters (D) associated with the table can be retrieved or outputted, preferably for retrieval or output in steps or continuously.

6. Method for adapting a weft measuring device (F) with a variable storage body diameter (D) in a thread processing system comprising an air-jet weaving machine (W) with a variable weaving width (B, B ') to the current weaving width, whereby a weaving machine control ( MC) and a measuring device controller (C) communicate via an information transmission path (A) at least with information (i _B ) on the current weaving width and a storage body diameter setting value is determined on the basis of the weaving width information (i _B ), and wherein at least one optoelectronic thread sensor (S) in the measuring delivery device scans the supply of weft threads on the storage body (3) and generates weft thread presence and absence signal levels (Hi, L ₀ , Hj ', L ₀ ') for the measuring delivery device control (C), characterized in that the thread sensor (S) generates the presence and absence signal levels (Hj, Lo, Hj ', L ₀ ') from light reflected by the weft thread (Y), and there ss at least two different level threshold values (S1, S2) are provided for evaluating and for discriminating between the respective presence and absence signal levels, among which the weaving width (B, B ') or level threshold values (S1 or S2) correlating to the defined diameter (D) is selected and used automatically at least by means of the weave width information (i _B ).