EP0464417A1 - Method of monitoring the regularity of slivers - Google Patents

Abstract

What is described is a method of monitoring or measuring the regularity of spinning slivers by means of mechanical feeler members during production on the sliver line, in which the mechanical tension of the running sliver is measured in front of a transport-roller arrangement and serves as a measure of the regularity of the sliver.

Description

The present invention relates to a method for monitoring or measuring the uniformity of spun fiber cables by mechanical probes in the course of cable production on the belt line.

In the production of synthetic fibers, it is necessary to give the spun filaments the desired textile properties through a series of post-treatment steps. Post-treatment steps that are usually required include e.g. in stretching, fixing, crimping and, if necessary, cutting the continuous filaments into staple fibers. In the art, these post-treatment steps are usually carried out on so-called belt mills by first combining the filament array of many spinnerets into a spinning cable and placing it in cans and then in turn folding a large group of these spinning cables and jointly carrying out the above on a belt mill. Subsequent treatment steps such as fixing, curling, etc. subject. The spun fiber cables which have been simultaneously treated in this way contain a very large number, usually a few hundred thousand to a few million individual filaments.

A uniform cable quality, in particular a constant number of filaments, is crucial, in particular for the production of spun fiber cables which are then to be further processed as so-called converter cables, tear cables or filling fiber cables. Every change in the cable thickness leads to an irregularity in the end product, which amounts to a loss of quality.

For technical reasons, e.g. Because the cables of the freshly spun filaments stored in cans are not infinitely long, disruptions due to the leakage of delivery cans and the subsequent tightening of replacement spun cables are inevitable. Disruptions in the spinning process, which can lead to tearing of individual filaments and to clumping and drop formation, result in so-called hard spots in the spun fiber cable and reduce its quality. It is therefore necessary to monitor the spun fiber cables for irregularities in order to be able to remove the parts of the end products which have suffered a loss in quality due to the irregularity from the production process. The spun fiber cables are usually monitored visually by the operating personnel. Automatic devices which minimize the effects of cable irregularities on the end product have also already been described for special fields of application.

Devices that serve this purpose are known for example from DE-AS-21 44 104, DE-OS-24 00 293 or German Patent No. 11 208. The devices known from DE-AS-21 44 104 and DE-OS-24 00 293 work with tracer rollers which scan the thickness of the fiber cable. In the device of DE-PS 11 208, a so-called feeler saddle is used for this purpose, which is to be thrown up by thick points of the cable.

DE-OS 33 06 687 describes a device for bringing together a plurality of partial cables of a synthetic fiber cable in front of the crimping chamber by means of pivotable deflecting rollers which has cable tension measuring and regulating units. This measurement of the cable tension is used here exclusively for the automatic regulation of the discharge rollers, so that the joining of the partial cables is optimized. The device is not used to record the quality of the partial cables.

In contrast, the present invention provides a method with which the quality of a synthetic fiber cable can be monitored and, if necessary, evaluated.

It has been found that, surprisingly, this problem can be solved by continuously monitoring the mechanical tension of the synthetic fiber cable.

An object of the present invention is therefore a method for monitoring or measuring the uniformity of synthetic fiber cables by means of mechanical probes, during production on the belt line, in which the mechanical tension of the running cable is measured in front of a roller arrangement transporting the cable at a defined speed and as a measure for the uniformity of the fiber cable serves.

Roller assemblies, which are used to transport cables at a defined transport speed on conveyor belts, are designed so that the cable running over the rollers practically assumes the peripheral speed of the transport rollers due to friction on the roller surface.

Individual rolls are generally not sufficient to convey a defined transport speed to a cable, since the friction between the cable and the roll surface is not large enough and therefore a certain amount of slippage usually occurs.

Roller arrangements that can give a cable a defined speed therefore contain two or more - common are e.g. up to seven rollers (so-called septets) - rollers which are either arranged so that they pass the cable one after the other with the greatest possible wrap angle or they are designed as pairs of squeeze rollers.

Pinch roller pairs consist of a fixed roller and a movable roller that presses on the fixed roller with great pressure. The cable to be transported is in the nip of the Quet pair of rollers pulled in and transported at the peripheral speed of the nip rollers. This results in a cable tension resulting from the overall construction of the cable route upstream of the squeeze rollers, ie upstream thereof, which statistically fluctuates around a normal value in normal operation. Roller arrangements that can convey a defined transport speed to a cable are referred to below as transport roller arrangements. Transport roller arrangements can be found on many cable treatment devices as feed rollers, for example on dryers, crimping chambers, tear lines, cutting machines, etc.

The measurement of the mechanical cable tension is therefore preferably carried out in front of the feed rollers of a cable treatment unit e.g. a tear zone or a stuffer box measuring area, which is equipped with a voltage measuring device of known type. If there is a fault in the synthetic fiber cable in the form of a thicker or weaker cable piece in the feed rollers (transport roller arrangement) of the monitored unit, this fault shows up as a change in the cable tension in front of the feed rollers, which can be measured well with tension sensors known per se. If the transport roller arrangement consists of a roller multiplet, a fault in the form of a thickening of the cable leads to an increase in voltage, and a thinned portion of the cable leads to a decrease in voltage. If the transport roller arrangement consists of a pair of squeeze rollers, a thickening of the fiber cable as it passes through the nip leads to an increase in tension, a thin point of the cable leads to a decrease in tension if the cable is also under tension downstream of the pair of squeeze rollers. If the cable is no longer under tension downstream of the squeeze roller, e.g. behind the feed rollers of a stuffer box (crimping chamber), the effects are reversed: a cable thickening leads to a voltage drop, a thin point provokes a voltage increase. So-called "hard spots", which arise, for example, from an accumulation of torn filaments (called so-called specks) that have run together to form a knot-like polymer drop, lead to the passage of the feed rollers of a monitored unit, which are designed as squeeze rollers, e.g. in a stuffer box, to a sharp increase in tension of the cable in the area in front of the feed rollers when the cable is no longer under tension behind the pinch rollers (as in a stuffer box).

Depending on the extent of the defect in the synthetic fiber cable, there are shorter or longer changes in tension in front of the feed rollers. The frequency and extent of the voltage deviations thus represent a reliable measure of the quality of the monitored synthetic fiber cable.

The measurement results can be evaluated in various ways, depending on which information about the cable quality is desired. Should e.g. In principle, defects in the cable can be excluded before further processing, so a positive or negative voltage change, e.g. be used immediately to switch off cable transport. If the faulty point is to be removed from the product stream at a suitable point, it can be e.g. be signed. The voltage signal can also e.g. start a timer that controls the discharge of the defective product depending on the cable speed.

For example, an alarm signal triggered by the change in voltage can be used for this purpose, a signal lamp in the area of the cable treatment device downstream of the pair of rollers, e.g. turn on the crimping machine which indicates to the operator that an intolerable cable fault has occurred. At the same time, for example, a signal can be triggered in the area of the cable stapler and, after the fault has passed through the fixer, a signal can be triggered in front of the cutting machine, which enables the can filling to be interrupted in good time and the non-conforming production parts resulting from the cable irregularity to be discharged. As already mentioned above, the signal generated by the change in voltage can also be used to mark the point of failure of the spun fiber cable with a marking dye. The non-conforming production parts can then be removed by hand or automatically, for example in front of the cable tray or on the cutting machine.

So that minor statistical voltage changes in the synthetic fiber cable do not trigger the measures that are necessary in the event of a fault, only those positive and / or negative voltage changes of the cable that are above a predetermined positive and / or negative trigger threshold, i.e. are outside a predetermined threshold value window. The level of the threshold is determined so that it lies above the statistical voltage changes occurring during normal operation.

However, the method according to the invention is not only suitable for triggering certain alarm devices or malfunction measures in the event of malfunctions in the spun fiber cable, but rather the Changes in tension can also be counted or integrated according to frequency and / or extent. The measured value obtained in this way can be standardized to the unit of the running time or running length of the cable and then represents a measure of the average cable quality in the measuring interval.

If an analog signal is derived from the voltage measuring device, any change in the strength of the spun fiber cable can be continuously monitored on a recorder. Here, too, a limit value of the analog signal can be set at which the above-described accident measures are triggered.

Cable tension measurement can be continuous, i.e. be carried out without interruption, whereby a voltage signal is obtained which can be used for constant control of the cable quality. However, the measurement can also be carried out intermittently at short intervals. This embodiment is advantageous when e.g. a single evaluation and control device is provided for several measuring points. The evaluation computer then works as it were in the time sharing process.

The evaluation of the signal sequence for determining the cable quality is expediently carried out by a computer which can output the results in real time and thus enables process control if desired.

All known measuring devices for mechanical tension of spun fiber cables are suitable for carrying out the method according to the invention. Devices that work with a dancer roller, i.e. a movable roller arranged under pressure on the cable and arranged between two fixed rollers. The dancer roller can be controlled in different ways, for example it is possible to have the dancer roller form a relatively long loop of the cable so that the cable loops around the dancer roller at approximately 180 °. The dancer roller is held in this position by spring force, so that every change in tension of the cable leads to a change in position of the dancer roller. The change in position of the dancer roller is then converted in a manner known per se into an electrical analog or digital signal and further processed in the manner described above. However, a dancer roller can also be operated, for example, in such a way that it is held in a position by a constantly measured force in which it deflects the running synthetic fiber cable only relatively slightly, for example by an angle between 20 and 45 °. The force required in each case to maintain this position is continuously measured and converted in a manner known per se, for example by an electronic tensiometer, into an electrical signal which is evaluated as described above.

Claims (5)

1. A method for monitoring or measuring the uniformity of spun fiber cables by mechanical feelers during manufacture on the belt line, characterized in that the mechanical tension of the running cable is measured in front of a transport roller arrangement and serves as a measure of the uniformity of the fiber cable. 2. The method according to claim 1, characterized in that the tension is measured in front of the feed rollers of a cable treatment device. 3. The method according to at least one of claims 1 and 2, characterized in that a positive or negative threshold value is specified for the cable voltage, if exceeded, fault measures are triggered. 4. The method according to at least one of claims 1 to 3, characterized in that the voltage changes, preferably those which are outside the threshold window, are counted or integrated according to frequency and / or extent and this value, if necessary after scaling to the unit of time or cable run length in the measuring interval, is output as a quality feature of the cable. 5. The method according to at least one of claims 1 to 4, characterized in that the signal emitted by the measuring head after usual, sufficient amplification is used to switch on a signal lamp in the region of the cable treatment device downstream of the pair of rollers, and / or in the region of the cable tapper, and , after the corresponding runtime of the malfunction by the fixer, trigger a signal in front of the cutting machine, which makes it possible to discharge the production parts that are not appropriate for the type.