WO2010028642A1

WO2010028642A1 - Contactless method for controlling the thickness of a preparation layer applied to a yarn and circuit arrangement for carrying out said method

Info

Publication number: WO2010028642A1
Application number: PCT/DE2009/001302
Authority: WO
Inventors: Wolfgang Schäfer; Frank Jenke; Jan Posvic
Original assignee: Neumann Elektronik Gmbh
Priority date: 2008-09-15
Filing date: 2009-09-14
Publication date: 2010-03-18
Also published as: EP2331906A1; DE102008047336B4; DE102008047336A1

Abstract

The aim of the invention is to devise a contactless method for controlling the thickness of a preparation layer applied to a yarn and a circuit arrangement for carrying out said method which allow the monitoring and optionally the control of the preparation application online and continuously during the production process of the filament yarn spinning on every spinning nozzle and which also allows already existing textile machines to be retrofitted. According to the invention, the field effect is directly detected via the induction effect caused by it and without first compensating it. As a result of the induction effect, an electrical voltage which is proportional to the induction is generated and the electrical voltage is evaluated in terms of its level and curve. The invention also relates to a contactless method for controlling the thickness of a preparation layer applied to a yarn and to a circuit arrangement for carrying out said method.

Description

Method for the contactless control of the thickness of a preparation layer applied to a yarn and circuit arrangement for carrying out the method

The invention relates to a method for non-contact control of the thickness of a spin finish applied to a yarn and a circuit arrangement for carrying out the method.

For the production of woven, knitted, knitted, embroidered or the like yarns are needed, which consist of filament yarns with infinitely long fibers that hold together undiluted. Depending on the application, these yarns consist of a different number of filaments, up to yarns of only one filament, the monofilaments. In order to allow further processing of the yarns or to improve the processability, they are immediately after leaving the spinneret with liquid chemical substances called preparation, coated. Preparations consist of various chemical components, such as lubricants, emulsifiers, antistatic agents, etc. The application is carried out with the aid of preparation fingers or rollers. If the coating quality achieved is insufficient, disruptions of the further processing process, in particular due to thread breaks, for example because of insufficient sliding properties, are the result.

The state of the art is to perform a random check of the preparation order outside the technological process in the laboratory as part of quality assurance. Any defects usually affect the entire production batch. Intensity and uniformity of the preparation application are only inadequately determined, the result being only statements on the applied amount on the relevant thread section. The disadvantage of conventional quality control is that it only takes place when the production process is complete and the product is no longer to be changed. In order to reduce the reject rate, an over-preparation could be made. But this is costly and uneconomical and does not avoid production process disturbances.

It is known that an electrostatic field effect, which emanates from the thread, is modified by the preparation depending on the layer thickness. It would be possible to capture the field effect by means of a conventional method on the detour of the field compensation. (Vosteen, William E., A Review of Current Electrostatic Measurement Techniques and their Limitations, Lecture on the "ELECTRICAL OVERSTRESS EXPOSITION, 24.-26. April 1984, San Jose, Calif.) Field strength information is obtained indirectly via a compensatory supplementary field in this method. The devices used for this purpose have large dimensions and are complicated and cost-intensive, so that they have also found application only in the laboratory. Moreover, the method is only able to detect long-wave components from the charge progression of the yarn which permit only a low-frequency signal with a narrow-band spectrum. As a result, the course of the preparation layer thickness along the thread can only be reflected with a low spatial resolution.

The object of the invention is to develop a method for the contactless control of the thickness of a preparation layer applied to a yarn and a circuit arrangement for carrying out the method, which both monitors and optionally controls the preparation application online and continuously in the production process of filament yarn spinning at each spinneret. as well as retrofitting existing textile machines allowed.

The advantage of the method according to the invention is that it allows a cost-effective continuous detection of the quality of the applied preparation during the production process and can be installed by its compactness even in difficult and tight machine positions.

The invention will be explained in more detail below using an exemplary embodiment. In the accompanying drawing shows

Fig. 1 shows a circuit arrangement for carrying out the method and

2 shows an electrode arrangement of the circuit arrangement.

In the method according to the invention for the contactless control of the thickness of a preparation layer applied to a yarn, the electrostatic field effect emanating from the yarn is detected directly, without detours by field compensation, via the effect of influence caused by the field effect, as a shift of charges in an electrode subsequently generates an electrical voltage proportional to the charge in accordance with the influence effect. This electrical voltage is evaluated according to their height and their course. The evaluation can be carried out in such a way that, when it exceeds or falls short of a stored Default value an error signal is generated, but it is also possible to use the voltage generated to control the preparation layer thickness.

In order to carry out the method, FIG. 1 shows a circuit arrangement for evaluating the irregularly distributed charge accumulations, which are located on a material to be measured, for example a yarn or a thread. during the production process of yarn production or through friction points in the yarn production process. An electrode arrangement 1, for example a latticed electrode arrangement according to FIG. 2 consisting of two intermeshing combs, is connected with its terminals to a charge amplifier, namely the first terminal 16 to a first charge amplifier 2 and the second terminal 17 to a second charge amplifier 3. The outputs of the first charge amplifier 2 and of the second charge amplifier 3 are connected to the input of a differential amplifier 4. The output of the differential amplifier 4 is connected via a converter 5 both to an AD converter 6 and to an analog signal tap 7. The AD converter 6 is connected via a microcontroller 8 both to a serial interface 9 and to an operating and display unit 10.

The converter 5 can be, for example, an RMS converter, another averaging device, optionally with an adjustable averaging time, a peak rectifier with adjustable discharge time or a low-pass filter with adjustable cutoff frequency.

It is also possible to shift the converter 5 into the microcontroller 8 and replace it there by a digital filter, but in particular also by a non-linear calculation rule, such as, for example, the line integral known from mathematics. This simplifies the analog circuit part, but raises the requirements for the AD converter 6, the microcontroller 8 and its firmware. From the AC voltage signal of the differential amplifier 4, the RMS converter generates a DC voltage signal whose residual ripple and thus the local resolution of the signal on the measurement item are determined inter alia by the averaging time of the RMS converter. At this point in the signal chain, it is possible to pick up the analog output signal of the RMS converter and supply it to an external display or controller for further processing in a machine control. Thus, the construction of a control loop is possible, which online and autonomously change the order quantity of the preparation and thus contributes to quality assurance. At the same time, the analog Output signal of the converter 5 digitized by means of the AD converter 6 and supplied to the microcontroller 8. After a parameterizable digital low-pass filtering or averaging, the display of the measured value in the operating and display unit 10 and the output via the serial interface 9 are controlled by this microcontroller 8. This allows logging by reading directly or by a PC. This digital data can also be used as the analog output signal of the converter 5 to build a control loop. The microcontroller 8 also allows the parameterization of the system parameters, for example the averaging time, by the operator.

2 shows a grid-like electrode arrangement according to the invention, in the exemplary embodiment an electrode arrangement 1 comprising a combination of at least one signal electrode 11 interrupted in the yarn movement direction and at least one reference electrode 12 also interrupted in the yarn movement direction. Both electrodes 11 and 12 have grid webs of different widths and spaces of different widths. Thus, the signal electrode 11, for example, the different widths webs 14a and 14b and the reference electrode 12, the different widths interruptions 15a and 15b. The longitudinal direction of both the signal electrode 11 and the reference electrode 12 is aligned parallel to the yarn 13. The reference electrode 12 is disposed between the yarn 13 and the signal electrode 11 such that the lands 14a and 14b of the signal electrode 11 are associated with the interruption area 15a and 15b of the reference electrode 12. According to an embodiment of the invention, the signal electrode 11 has at least two webs 14a and 14b and the reference electrode at least two interruptions 15a and 15b.

The yarn 13 is moved past the electrode assembly 1 and thus, due to the above-described shape and geometry of the grating, induces signals having a broadband spectrum according to the invention, which reflects the course of the preparation layer thickness along the yarn with high local resolution.

If the electrode assembly 1 in addition to the outgoing from the yarn 13 influence also electrical Störfeldem an industrial environment (for example, caused by thyristor machine controls) is exposed, arise signals with Nutzanteil (starting from the yarn) and noise component (starting from the interference field), the latter in the control the preparation thickness causes errors. The formation of the difference of the two signals, which were once removed from the signal electrode 11 and the other of the reference electrode 12, in the differential amplifier 4, causes the compensation or at least attenuation of the noise due to the remote interference source approximately equally precipitating noise components. By contrast, the two due to the proximity to the yarn differently failing useful signal components are not mutually attenuated. This serves to achieve a high signal-to-noise ratio (SNR).

When the reference electrode 12 is disposed between the yarn 13 and the signal electrode 11 and in such a manner that the lands 14a and 14b of the signal electrode 11 are associated with the junction area 15a and 15b of the reference electrode 12, the reference electrode 12 can serve also to the target a high SNR to shield interference fields with respect to the signal electrode 11. For this purpose, in another embodiment of the invention, the reference electrode 12 is connected via its terminal 16 not only to the input of the charge amplifier 2, but, as shown in Figure 2, additionally connected to ground potential.

LIST OF REFERENCE NUMBERS

1 electrode arrangement

2 first charge amplifier

3 second charge amplifier

4 differential amplifiers

5 transducers

6 AD converter

7 analog signal tap

8 microcontrollers

9 serial interface

10 operating and display unit

11 signal electrode

12 reference electrode

13 yarn

14a, 14b footbridges

15a, 15b interruptions

16 first connection

17 second connection

Claims

claims

1. A method for non-contact control of the thickness of a spin finish applied to a yarn, wherein the yarn emanating from the electrostatic field effect is exploited, characterized in that the field effect is detected directly, without detours by their compensation, on the influential effect caused by it that due the influence effect is generated by an electrical voltage proportional to the influence, that this electrical voltage is evaluated according to its magnitude and its course.

2. The method according to claim 1, characterized in that the evaluation is performed such that when exceeding or falling below a stored default value, an error signal is generated.

3. The method according to claim 1, characterized in that the voltage generated is used to control the preparation layer thickness.

4. Circuit arrangement for detecting and evaluating the influence of charges of a yarn, characterized in that for detecting the yarn (13) outgoing influence parallel to the yarn, an electrode assembly (1) is arranged, the first terminal (16) for evaluating the output signal Electrode arrangement (1) with a first charge amplifier (2) and the second terminal (17) are connected to a second charge amplifier (3), which is a differential amplifier (4) connected downstream, that the output of the differential amplifier (4) via a converter (5 ) is connected to both an AD converter (6) and an analog signal tap (7) and that the AD converter (6) via a microcontroller (8) both with a serial interface (9) and with a control unit (10 ) connected is.

5. Circuit arrangement according to claim 4, characterized in that the electrode arrangement (1) is lattice-shaped.

6. Circuit arrangement according to Claim 4 or 5, characterized in that the electrode arrangement (1) consists of a combination of at least one signal electrode (11) interrupted in the yarn movement direction and at least one reference electrode (12) also interrupted in the direction of yarn movement, the longitudinal direction of both electrodes ( 11, 12) is aligned parallel to the yarn (13) and the reference electrode (12) is arranged between the yarn (13) and the signal electrode (11) such that the webs (14a, 14b) of the signal electrode (11) 15a, 15b) are associated with the reference electrode (12).

7. Circuit arrangement according to claim 6, characterized by webs of different widths (14a, 14b) and interruptions of different widths (15a, 15b).

8. Circuit arrangement according to claim 6 or 7, characterized in that the reference electrode (12) has at least two interruptions (15a, 15b).

9. Circuit arrangement according to one of claims 6 to 8, characterized in that the signal electrode (11) has at least two webs (14a, 14b).

10. Circuit arrangement according to one of claims 6 to 9, characterized in that the reference electrode (12) is connected both to the charge amplifier (2) and to ground potential.