CH701902A2 - A method for tracking the color homogeneity of the yarn surface and device for its implementation. - Google Patents

Abstract

The invention relates to the method of monitoring the color homogeneity of the yarn surface (2) by means of the tracking and evaluation of the radiation (8) reflected by the yarn (2) which emits to the yarn (2) from the source (3) of the radiation (4) has been. The radiation (8) reflected by the yarn (2) is scanned by the reflected radiation sensor (6) in a common plane with the absolute average of the yarn (2) by means of a digital optical line sensor (1) of the absolute average of the yarn (2) and the scanning of the yarn (2) reflected radiation (8) is made with a mutual temporal synchronization. The invention further relates to the device for monitoring the color homogeneity of the yarn surface (2), which has a source (3) of the radiation (4) arranged next to the space for yarn passage (2) and at least one sensor (6) of the reflected radiation (8) , wherein the device further comprises an evaluation device (10). Against the source (3) of the radiation (4), behind the space for yarn pass (2), there is arranged a digital optical line sensor (1) of the absolute average of the yarn (2) which is in a common plane with the source (3) of the radiation (4) and with the sensor (6) of the reflected radiation (8), wherein source (3) of the radiation (4), digital optical line sensor (1) and sensor (6) of the reflected radiation (8) with the source of Control signals are coupled in detail and these control signals are mutually synchronized.

Description

Description area of engineering

The invention relates to the method for tracking the color homogeneity of the yarn surface by means of the tracking and evaluation of the radiation reflected by the yarn, which was emitted to the yarn from a radiation source.

The invention relates to the device for tracking the color homogeneity of the yarn surface, which has a radiation source which is arranged next to the space for the Garndurchlauf, and at least one sensor of the reflected radiation, wherein the device further comprises an evaluation device.

State of the art

In the preparation of the fiber material for yarn production, attention is paid to the color homogeneity of the fiber material from which the yarn is subsequently produced, as to one of the qualitative parameters. The fibers of a different color are considered from the perspective of textile technology for the impurities.

In the present, the detection of the color blends in the yarn produced is known by means of the scanning of the yarn by the optical means. It uses the irradiation of the yarn with a suitable light source and it is the energy of the reflected radiation from the yarn measured so that when the yarn contains a color mixture, the amount of energy reflected by the yarn changes briefly. As the light source, one usually uses a source that generates the radiation in the visible spectrum or in an infrared spectrum or in a UV spectrum. The radiation source can produce either monochromatic radiation or radiation formed by the spectrum of monochromatic constituents. As the optical scanning element, one uses the element having the defined transmission characteristic - electrical signal. However, the measurement of the amount of energy reflected from the gran is negatively affected by the variability of the average of the yarn and by the parasitic radiation sources that are in the vicinity of the measurement, such as bulbs, sunlight, flashing security and information lights, etc. These parasitic radiation sources then introduce into the measured values of the reflected energy an error which has a negative effect on the accuracy of determining the presence of foreign fibers in the yarn.

In the present there is the possibility of minimizing the influence of the parasitic radiation sources mainly by a suitable design arrangement of the measuring zone with the suitably arranged optical scanning elements for scanning the energy reflected from the yarn, which is emitted by suitably placed the respective yarn irradiating radiation source. To sufficiently eliminate the influence of the parasitic radiation sources, however, it would be necessary to completely close the measuring zone and thus prevent the parasitic radiation from entering the measuring zone, in particular in the case of the yarn tracking device on a textile machine the maintenance of the textile machine, yarn breaks, renewal of the spinning process, etc. is virtually impossible.

The further possibility of suppressing the influence of the parasitic radiation sources consists in the use of the radiation source with a high radiation intensity. The disadvantage of this solution, however, is a high energy demand of such source and thus in a large heat loss. The further disadvantage is that the use of a high power radiation source could adversely affect the scanning capabilities of the optical scanning element, which would then have to operate outside the optimum sensitivity range.

For most parasitic radiation sources, the amount of energy emitted is either not changed so much in time, or it is changed at the slower rate by a few digits than it is at the frequency of sampling the amount of energy reflected from the yarn is. The negative effects of such parasitic radiation sources can then be minimized by means of a "high-pass" filter inserted in the processing path of the signal representing the amount of energy reflected by the yarn. However, this minimizes only the "slow" changes in the amount of energy emitted by the parasitic radiation sources.

However, there are also those parasitic radiation sources in which the amount of emitted energy is changed at a similar frequency as the frequency of sampling the amount of energy reflected from the yarn. In such parasitic radiation sources, the method with the filter of the «high pass» is already completely unusable, because the filter of the type «high pass» with the respective defined cutoff frequency would suppress together with the unwanted parasitic radiation and the signal to a significant extent that the Represents the amount of energy reflected from the yarn from the source that intentionally irradiates the yarn.

In the actual textile companies then occurs a whole mixture of different parasitic radiation sources, so the elimination of the influence of parasitic radiation sources in the yarn tracking is a major problem whose elimination or at least minimization is the aim of this invention.

2 Presentation of the essence of the invention

The object of the invention is achieved by the method of monitoring the color homogeneity of the yarn surface, the essence of which is that the yarn reflected radiation with a sensor of the reflected radiation in a common plane with the sampling of an absolute average of the yarn by means of a scanning the digital optical line sensor, wherein the scanning of the absolute average of the yarn and the scanning of the radiation reflected by the yarn is performed with a mutual time synchronization.

The essence of the apparatus for monitoring the color homogeneity of the yarn surface is that a digital optical line sensor of the absolute average of the yarn is arranged against the radiation source behind the space for Garndurchlauf, with the radiation source and the sensor of the reflected radiation in a common plane, wherein radiation source, digital optical line sensor and sensor of the reflected radiation are coupled in detail with a source of the control signals and these control signals are mutually synchronized. The specific course of the control signals is determined by the construction of individual system components.

The advantageous embodiments of the invention are mentioned in the dependent claims.

By means of the method according to the invention and the device according to the invention, it is possible to compensate both relatively slow and rapid changes in the parasitic radiation reflected by the yarn. The higher the frequency of the control signal for modulating the radiation source, the faster changes in the radiation reflected by the yarn can be compensated, which are caused by the parasitic radiation sources. In practice, such a state is to be reached when the frequency of the control signal for modulating the radiation source is several times higher than the fastest changes in the intensity of the reflected radiation caused by the color impurities in the yarn. The interference caused by the parasitic radiation sources can thus be suppressed to a significant extent and form a signal which is almost the same as if the entire measurement zone were completely separate from the ambient illumination and only the radiation from the radiation source was applied. The further advantage is that this invention makes it possible to integrate the hitherto two measuring systems used, one for measuring the absolute average of the yarn and others for evaluating the color homogeneity of the yarn, ie the presence of foreign fibers, in a device with a common light source.

Overview of the illustrations on the drawing

The invention is illustrated schematically in the drawing, which shows the arrangement of the measuring system in the measuring zone.

Embodiment of the invention

The invention will be explained with reference to the embodiment of an integrated sensor of the average homogeneity of the yarn 2 and the color homogeneity of the yarn 2. The sensor comprises a digital optical line sensor 1 with a series of radiation sensitive elements, e.g. CMOS or CCD sensor, e.g. according to CZ Patent No. 299,647 or 298,929, with the aid of which the absolute average of the yarn 2 is measured in such a way that the yarn 2 is irradiated by a source 3 of the radiation 4 and on the digital optical line sensor 1 by the Number of shaded radiation-sensitive elements, the width of the shadow cast by the yarn 2 5 is measured, the width of the shadow 5 corresponds to the absolute average of the yarn 2. The radiation 4 is a modulated radiation and therefore has a variable intensity over time, the modulation of the source 3 of the radiation 4 being made at a higher frequency than the expected frequency of the sources of parasitic radiation and the frequency of the signals, caused by the passage of the impurities on the yarn through the measuring zone, ie the signals that are reflected by the yarn surface 2. A portion of the light energy emitted by the source 3 of the radiation 4 is reflected by the yarn 2 and scanned by at least one sensor 6 of the reflected radiation 8. The sensor 6 of the reflected radiation transmits the reflected radiation 8 to electrical signal, from the time course of which one can conclude the color homogeneity of the respective yarn 2, because the color homogeneity is influenced by the presence of the foreign fibers, which have a different reflectivity for the radiation 4, eg the fibers having a different color than the yarn 2 or the fibers of another material other than the base material of the yarn 2 is the case. The measurement of the absolute average of the yarn 2 and the tracking of the color homogeneity of the yarn 2 are thus carried out in the same measuring room, in the same measuring plane and using a common source 3 of the radiation 4, the activity of individual elements of the whole apparatus being synchronized and adjusted in time is, as described in more detail in the following text.

Individual elements of the integrated sensor described above are coupled to a control and evaluation device 10, which controls the activity of individual parts of the integrated sensor.

The measurement of the absolute average of the yarn 2 by means of a digital optical line sensor 1 is used to eliminate, or to compensate for that change in the energy reflected from the yarn 2, which causes only by changing the absolute average of the yarn 2 is.

To eliminate or compensate for the negative effects of parasitic radiation using the already mentioned modulated radiation 4 with a higher modulation frequency, as the expected frequency of the sources of parasitic radiation and frequency of reflected from the yarn surface 2 signals amount.

With the modulation frequency of the radiation 4, the measurement of the absolute average of the yarn 2 is synchronized in such a way that in the time of the higher intensities of the radiation 4, e.g. at full power of the source 3, the size of the shadow 5 of the respective yarn 2 on the digital optical line sensor 1 is measured, i. the absolute average of the yarn 2 is measured, and at the same time at least one sensor 6 of the reflected radiation measures the amount of light energy reflected by the yarn 2, it being known that this quantity of reflected energy is represented by the sum of the reflected values from the Source 3 of the radiation 4 coming energy and the energy coming from the sources of parasitic radiation is formed. In the time of the lower intensity of the radiation 4, e.g. in the complete extinction of the source 3, the absolute average of the yarn 2 is not measured and with the sensor 6 of the reflected radiation only the amount of light energy reflected by the yarn 2 is measured, which at this time is the low power or zero power of the source 3 in FIG Basically, only by the energy coming from the sources of parasitic radiation, ie an incident in the measuring zone arbitrary ambient light, is formed. By comparing the values of the reflected light energy measured in this way at the different intensities of the radiation 4 of the radiation source, the influence of the parasitic radiation is compensated. The information on the absolute average of the yarn 2 and information about the amount of reflected light from the yarn 2 are processed by means of a control and evaluation device 10, which is equipped with the communication means, not shown, with a higher-level control system, the setting of individual sensors and their calibration and storage of the constants to verify the accuracy or elimination of the aging process, etc. allows.

To further improve the tracking of the color homogeneity of the yarn 2, the yarn 2 undergoes a specially prepared measuring zone, the essence being that the yarn 2 to be traced passes in the measuring zone opposite the sensor 6 of the reflected radiation 8 against a background whose reflectivity of the light radiation corresponds to the expected reflectivity of the radiation of the color homogeneous yarn 2. For example, such special background may have the same or sufficiently close color to the expected color of the color homogeneous yarn 2. Such special background may e.g. by an exchangeable suitably colored material, an LCD display with the controllable luminance and color parameters, an illuminated by its back by an additional radiation source screen, etc., are formed.

In the drawing, the coupling of the elements of the integrated sensor according to this invention is shown schematically. All active elements are connected in addition to the function coupling described below to the source of their working voltage in order to be able to perform the respective activity at all. The integrated sensor has a control and evaluation device 10, which has in the illustrated embodiment, a microprocessor 101 and a generator 100 of the control signals, which is coupled to the microprocessor 101. In the embodiment not shown, the generator 100 of the control signals is a direct part of the microprocessor 101, wherein it also supplies the control signal for its own microprocessor 101. With the generator 100 of the control signals, an optical digital line sensor 1 is coupled, which is also coupled to the microprocessor 101. The above control signals need not be the same for the individual device elements, but they are always periodically synchronized with each other in time. The concrete chronological courses of individual periodic signals are adapted to the tax needs of all system elements.

The yarn 2 is irradiated by the source 3 of the radiation 4, which is also coupled to the generator 100 of the control signals, by which the radiation 4 is modulated.

In the path of the radiation reflected by the yarn 2 at least one sensor 6 of the reflected radiation 8 is arranged, which is coupled with its output to the first input of the pair of switches S1, S2, each of which is connected to the generator through its other input 100 of the control signals is coupled. The output of each switch S1, S2 is coupled to the input of the memory D1, D2. The outputs of both memories D1, D2 are connected to the inputs of the comparator E. The output of the comparator E is connected to the input of the microprocessor 101.

In the embodiment not shown, switches S1, S2, memories D1, D2 and comparator E are the components of the microprocessor 101, i. these are either formed directly by the internal means of the microprocessor 101 or their activity is determined by the action of the internal means of the microprocessor 101, e.g. according to the control software, simulated.

The device operates to control and synchronize the action of the optical digital line sensor 1, the radiation source 3 and the switches S1 and S2 by the generator of the control signals 100. For each measurement of the reflected radiation, two values of the reflected energy are detected by means of the reflected radiation sensor 6, i. when the yarn 2 is basically irradiated only by the parasitic radiation sources, and when the yarn 2 is irradiated by both parasitic radiation sources and by the source 3 of the radiation 4. The signal representing the amount of energy reflected by the yarn 2, which is irradiated only by the parasitic radiation sources, is separated by the switch S2 and is integrated and stored in the memory D2. The signal representing the amount of energy reflected by the yarn 2, that of the parasitic radiation sources and of the

4

Claims (8)

Source 3 of the radiation 4 is separated by the switch S1 and integrated in the memory D1 and stored. The comparator E makes a mutual comparison of both stored in the memories D1 and D2 values and on the output of the comparator E is the value of the reflected radiation from the yarn 2 with the eliminated influence of the parasitic radiation sources. This output value of the comparison element E and its changes are subsequently used in the microprocessor 101 for the evaluation of a possible occurrence of a foreign fiber in the yarn 2, specifically as a function of the absolute average of the yarn 2 measured by the digital optical line sensor 1, possibly with the correction In this way, besides the elimination of the influences of the parasitic radiation sources, it is also possible to evaluate whether the change in the radiation reflected by the yarn 2 is actually due to the appearance of the color inhomogeneity of the respective yarn 2, ie the presence of a foreign fiber in the yarn 2 or whether this is caused only by an immediate change in the average of the yarn 2 and so on. Industrial applicability The invention is applicable in the textile industry for determining the quality of the yarn produced. List of reference numbers [0027] 1 optical digital line sensor 2 yarn 3 radiation source 4 radiation 5 shadows 6 Sensor of reflected radiation 8 reflected radiation 9 optical link 10 control and evaluation device 100 generator of control signals 101 microprocessor D1, D2 memory E comparison element S1, S2 switch claims A method of monitoring the color homogeneity of the yarn surface by means of tracking and evaluating the radiation reflected by the yarn emitted to the yarn from a radiation source, characterized in that the radiation (8) reflected by the yarn (2) is detected by the sensor (6 ) of the reflected radiation is scanned in a common plane with the scan of the absolute average of the yarn (2) by means of a digital optical line sensor (1), the scan of the absolute average of the yarn (2) and the scanning of the yarn (2 ) reflected radiation (8) is made with a mutual temporal synchronization. 2. The method according to claim 1, characterized in that the yarn (2) is irradiated by a modulated radiation, wherein in dependence on the time course of the modulation of the radiation (4), the reflected radiation (8) is measured cyclically and the Amount of energy of the reflected radiation (8) is compared in at least two times with a different intensity of the modulated radiation, wherein the measurement result of the reflected radiation (8) with the temporally corresponding measurement result of the absolute average of the yarn (2) by means of a digital optical Line sensor (1) is compared and the information about the disturbance of the color homogeneity of the yarn surface is issued only in such a case, when the change of the reflected radiation (8) by the change of the absolute average of the yarn (2) was not caused. 5 3. The method according to any one of claims 1 or 2, characterized in that the yarn (2) is irradiated in its passage around a colored background whose reflectivity of the radiation (4) of the expected reflectivity of the radiation (4) of the color homogeneous yarn ( 2) corresponds. 4. The method according to claim 3, characterized in that in the irradiation of the yarn (2) the color and / or the reflection capabilities of the colored background is set in dependence on the yarn color. 5. The device for monitoring the color homogeneity of the yarn surface, which has a radiation source arranged next to the space for yarn passage and at least one sensor of the reflected radiation, wherein the device further comprises an evaluation device, characterized in that against the source (3) of the radiation ( 4) behind the space for passage of the yarn (2) a digital optical line sensor (1) of the absolute average of the yarn (2) is arranged, in a common plane with the source (3) of the radiation (4) and with the sensor (6) of the reflected radiation (8), wherein source (3) of the radiation (4), digital optical line sensor (1) and sensor (6) of the reflected radiation (8) are coupled in detail to the source of the control signals and these Control signals are mutually synchronized. 6. Device according to claim 5, characterized in that the optical line sensor (1) is coupled to the generator (100) of the control signals and to the microprocessor (101), with the generator (100) of the control signals further the source (3 ) of the radiation (4), wherein the sensor (6) of the reflected radiation (8) is coupled with its output to the first input of the pair of switches (S1, S2), each with its other input to the generator (100) is coupled to the control signals, the output of each switch (S1, S2) is coupled to the input of one of the memories (D1, D2), the outputs of both memories (D1, D2) connected to the inputs of the comparator (E) whose output is connected to the input of the microprocessor (101). 7. Device according to claim 6, characterized in that the generator (100) of the control signals, switches (S1, S2), memory (D1, D2) and comparator (E) are the components of the microprocessor (101). 8. Device according to claim 6, characterized in that generator (100) of the control signals, switches (S1, S2), memory (D1, D2) and comparator (E) are formed by the function simulation by the internal means of the microprocessor. 6