CZ299647B6 - Device for contactless measurement of a linear textile formation, such as a yarn, thread, textile fiber, sliver and the like - Google Patents

Abstract

The present invention relates to a device for contactless measurement of a linear textile formation such as yarn (1), thread, textile fiber, sliver, etc. containing a radiation source (6) and a radiation sensor (reader) (7) consisting of a system of radiation sensitive elements (700). The radiation sensor (7) consists of a CMOS optical sensor (70) wherein the invention is characterized in that the CMOS optical sensor (70) contains at least one row of radiation-sensitive elements (700) situated next to each other.

Description

The invention relates to a device for contactless measurement of a linear textile formation, e.g. yarn, thread, textile fiber, fiber sliver, etc., comprising a radiation source and a radiation sensor formed by an array of radiation-sensitive elements.

BACKGROUND OF THE INVENTION

Devices for contactless measurement of a linear textile formation, such as yarn, thread, textile fiber, fiber sliver, etc., are known which comprise a light source and light sensor comprising a CCD sensor containing a plurality of radiation-sensitive elements in a row adjacent to each other. or in a matrix arrangement.

Despite the advantages of using CCD sensors in these devices, the disadvantage of these 20 devices remains the relatively high cost of the CCD sensors and the limited scanning speed, which is due to the principle of their operation, which is based on the accumulation and transfer of electric charge.

It is an object of the present invention to reduce the cost of a device for contactless measurement of a linear textile formation, e.g., yarn, thread, textile fiber, fiber sliver, etc., and to enable improvement of the parameters of contactless measurement of a linear textile formation such as yarn, thread, textile fiber, fiber sliver.

SUMMARY OF THE INVENTION The object of the invention is achieved by a device for contactless measurement of a linear textile formation, such as yarn, thread, textile fiber, fiber sliver, etc., characterized in that the radiation sensor consists of a CMOS optical sensor containing at least one order of magnitude. radiation of sensitive elements situated side by side.

The advantage of this device is lower price of CMOS optical sensors compared to the price of CCD sensors. A further advantage of this device is that the CMOS optical sensor allows for a faster scanning speed than the CCD sensor, and the CMOS output signal of the optical sensor is better and easier to process than the CCD sensor output signal. The apparatus of the present invention can be used, as well as devices using CCD radiation sensors, to both determine the thickness of a moving linear textile formation by evaluating the irradiation status of CMOS optical sensor elements and to determine the homogeneity of the moving linear textile formation by evaluating the irradiation degree of CMOS optical sensor elements. arbitrarily combined to achieve more accurate results for monitoring the thickness and / or homogeneity of the moving linear textile formation, and their use depends in particular on the type and properties of the linear textile formation being monitored and the technological needs and capabilities of the monitoring device. The device is designed for serial use on textile machines, especially spinning machines and winding machines. Another advantage of CMOS optical sensors over CCD sensors, which operate on the principle of electric charge coupling, is that the CMOS optical sensors are significantly more resistant to the interaction of adjacent radiation-sensitive elements than CCD sensors. In fact, in the case of CCD sensors, electrical charge penetrates between adjacent radiation-sensitive elements, which negatively affects the accuracy of the measurement, because if one of the two adjacent radiation-sensitive elements is fully illuminated and the other is lightly illuminated or not illuminated at all a portion of the electrical charge from a fully illuminated radiation-sensitive element to an adjacent low-illuminated or non-illuminated radiation-sensitive element,

This is manifested by indicating a higher illumination of the low-illumination or not at all illumination of the radiation-sensitive element than its actual illumination. For evaluating the parameters of a linear textile formation while maintaining a favorable price and sufficient measurement accuracy, it is advantageous if the CMOS optical sensor comprises at least one row of side-by-side radiation-sensitive elements.

Due to easier processing of the CMOS output signal of the optical sensor and the factual measurement of most of the total length of the measured linear textile formation, it is advantageous if the radiation-sensitive elements have a dimension in the length direction of radiation-sensitive elements smaller than their dimension in a direction perpendicular the direction of the length of the row of radiation-sensitive elements.

BRIEF DESCRIPTION OF THE DRAWINGS

1 shows an axonometric view of an embodiment of a device with a CMOS optical radiation sensor, FIG. 2 is a sectional view of the scanning plane of the apparatus of FIG. 1; FIG. and FIG. 4 is a cross-sectional view of the scanning plane of an embodiment in which the plane intersected by the axis of the linear textile formation and the radiation source is inclined to the display plane at an acute angle.

DETAILED DESCRIPTION OF THE INVENTION

A device for contactless measurement of a linear textile formation, such as yarn, thread, textile fiber, fiber sliver, etc., will be described in more detail by way of examples of a device for detecting the thickness and / or homogeneity of a yarn. The homogeneity of the moving linear textile formation is understood throughout this application to mean mass uniformity. The homogeneity of the yarn 1 is monitored in the peripheral part of the yarn, since the core of the yarn 1 is opaque. The thickness of the moving linear textile formation is understood throughout the application to mean uniformity.

In the embodiment shown, the moving linear textile formation is formed by a yarn 1 which is discharged in a known manner from a known spinning device 2. The yarn I is disposed by a known discharge device which, in the illustrated embodiment, also constitutes the first yarn path stabilizing means 3 formed in the illustrated of the embodiment with guide rollers. In the illustrated embodiment, the second stabilizing means 4, which in the illustrated embodiment also includes guide rollers, is inserted into the yarn path 1, from which the yarn f is discharged in the direction of arrow 10 to known yarn winding means (i). The stabilizing means may also be formed by other suitable yarn guiding means or may not be used at all.

Between the two stabilizing means 3, 4, the yarn 1 passes through a radiation flux 5, which is emitted by a radiation source 6, which in the embodiment according to FIG. 1 is a point radiation source 60. Opposed to the radiation source 6 is a radiation sensor 7, which is formed by a CMOS optical sensor 70 with a row.

radiation-sensitive elements 700 arranged side by side substantially perpendicular to the direction of movement of the measured linear textile formation. Each of the plurality of radiation sensitive elements 700 of the CMOS optical sensor 70 is coupled to an evaluation device 8 of the state and / or degree of its irradiation. Said evaluation device 8 may also be an integrated part of the CMOS optical sensor 70. The evaluation device 8 is capable of evaluating the operation of the CMOS optical sensor 70 and is provided with an output 80 of the information measured by the CMOS optical sensor 70 about the yarn parameters monitored. yarn hairiness, etc. Devices for further processing the CMOS optical sensor 70 information may be connected to the output 80 of the evaluating device as required, which may consist, for example, of a machine or workstation control system and / or a display device and / or recorder and / or work station control means and / or work station control means for interrupting the moving yarn and / or for stopping at least some of the work station nodes, and the like.

In a non-illustrated embodiment, the device for contactless measurement of the linear textile formation may be provided with a suitable control device and / or a feedback circuit for controlling the intensity of the radiation emitted by the radiation source 6.

The point radiation source 60 emits radiation and produces a radiation flux 5 that impinges on the individual radiation-sensitive elements 700 of the CMOS optical sensor 70. The yarn path I intersects the radiation flux 5. A scanning plane 50 passes through the radiation source 60 and all radiation sensitive elements 700 of the CMOS optical sensor 70.

The yarn 1, located in the radiation flux 5 and moving in the direction of its longitudinal axis, overshadows some of the CMOS elements 700 of the optical sensor 70, the radiation state of the individual radiation-sensitive elements 700 and / or their degree of irradiation. are suitably calculated and / or evaluated for the yarn parameters of interest i, e.g., yarn thickness, yarn hairiness, fiber strand homogeneity, core dimension of the moving core yarn, and the like.

The device for contactless measurement of a linear textile formation, such as yarn, thread, textile fiber, fiber sliver, etc. according to the drawing, can be further modified to meet the specific requirements of some technological processes, while aligning the elements 700 in a straight line lying in the scanning plane 50; 1 is shown in FIG. 2 as shown in FIG. 2.

The radiation 60 is positioned in a plane passing through the longitudinal axis of the yarn X and perpendicular to a line in which the CMOS elements of the optical sensor 70 are arranged and the radiation of the point radiation source 60 impinges on the CMOS optical sensor 70 in the beams 600 diverging from the point radiation source 60.

Fig. 3 shows a further modification of the device of Fig. 1 in cross-section through the scanning plane 50; In this modification, the point radiation source 60 is replaced by a linear radiation source. The radiation flux 5 is formed by parallel spokes 600, so this embodiment is particularly suitable for large thicknesses of yarn 1 or other linear textile formations, since the image of yarn I on the radiation receiver 7 formed by a plurality of radiation sensitive elements 700 is equal to the thickness of the linear form. in the radiation flow 5. For technological reasons, it is sometimes desirable that the point radiation source 60 is located outside a plane perpendicular to the radiation receiver 7 and extending along the longitudinal axis of the linear textile formation as shown in FIG. 4.

Since the yarn 1 or other linear textile formation is mostly moving at a known speed and the evaluation of the state and / or the degree of irradiation of the radiation-sensitive elements 700 takes a certain period of time, monitoring the thickness and / or homogeneity of the yarn 1 is discontinuous, when allowing a higher sampling rate of the linear textile formation of interest. Nevertheless, it provides accurate information on the actual thickness and / or homogeneity of the yarn X or other linear textile formation in the successive scanning planes.

The distance between the scanning planes 50 is generally constant at steady state, but may vary, for example, when a sudden change in the thickness and / or homogeneity of the yarn X is detected, the distance between the scanning planes 50 may be reduced.

The CMOS optical sensor 70 may be formed from rectangular radiation-sensitive elements 700 to simplify signal processing when measuring the parameters of a linear textile formation and to actually measure most of the total length of the linear textile formation being measured. a direction perpendicular to the direction of movement of the measured linear textile formation, i.e. in the direction of the length of the row of radiation-sensitive elements 700, and by their larger dimension are situated in the direction of movement of the measured linear textile formation,

Thus, the radiation-sensitive elements 700, when measuring the linear textile formation, are situated by their smaller dimension in the thickness direction of the measured linear textile formation and by their larger dimension are situated in the direction of the length of the row of radiation-sensitive elements 700. the length of the measured linear textile formation.

A device for contactless measurement of a linear textile formation, such as yarn, thread, textile fiber, fiber sliver, etc., can be controlled at each workstation of the textile machine by a workstation control unit which can also evaluate and process measured values of the measured linear textile formation. Similarly, at each workstation of the textile machine, the evaluation device 8 of the device for contactless measurement of the linear textile formation can, in addition to its own operation, measure the linear textile formation and the operation of the control unit of the textile machine workstation.

Claims (2)

20 1. Apparatus for contactless measurement of a linear textile formation, eg yarn, thread, textile fiber, fiber sliver, comprising a radiation source and a radiation sensor consisting of a radiation-sensitive element system, characterized in that the radiation sensor (7) is a CMOS optical a sensor (70) comprising at least one row of radiation sensitive elements (700) located side by side. Device according to claim 1, characterized in that the radiation-sensitive elements (700) have a dimension in the length direction of the array of radiation-sensitive elements (700) smaller than their dimension in a direction perpendicular to the length direction of the array of radiation-sensitive elements (700). 700).