JP2006146536A - Analysis program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain data useful for process control and quality control in the manufacturing process of a fiber assembly from a signal concerning property information on the fiber assembly obtained from a video signal from an imaging means which has imaged the fiber assembly. <P>SOLUTION: An analysis program makes an information processing device execute the undermentioned steps, and analyze a signal related to the property information of the fiber assembly obtained from a video signal from an imaging means which has imaged the fiber assembly running continuously. The steps are: (1) a step which sequentially reads signals related to the property information of the fiber assembly (a signal on width count data, a thickness clamped video signal, a thickness video signal, a signal related to smear count data); (2) a step which associates the sequentially read signals with time data, and sequentially stores them in a recording device of the information processing device; and (3) a step which obtains data on quality information of the fiber assembly by associating them with the time data from signals which have been associated with the time data and sequentially recorded. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an analysis program useful for process control and product quality control in the production process of continuously running fiber aggregates (filter tows and the like).

  In the production process of a fiber assembly (for example, tobacco filter tow), it is necessary to inspect the width, thickness, and dirt of the continuously produced fiber assembly for quality control. The width is required to be constant over time, and the thickness is required to have a uniform thickness distribution in the width direction over time. And when these characteristics exceed a reference value (specified range), it is necessary to prevent the outflow of defective products by excluding them from the product.

  Conventionally, a method has been employed in which a part of a continuously produced fiber assembly is cut and the width is measured, or the width of the running fiber assembly is read. Further, the dirt of the running fiber assembly is visually observed to detect the dirt.

  However, in these methods, the inspection target is only a part of the fiber assembly to be produced. I will continue. Moreover, since the inspection of thickness and dirt is performed by qualitative visual evaluation, it is difficult to make use of it for improving the quality of products.

  Video signals from the image pickup means are used for quality control of products, quality determination, and the like. For example, in Japanese Patent No. 3013903 (Patent Document 1), an edge is chamfered and a glass having a seaming surface is horizontally placed on an apparatus for detecting a defect of the edge portion. A light source that irradiates light from two diagonal directions on the opposite side of the plate glass and a light source side corner between the plate glass surface and the seaming surface that is outside the range of the extended region of the optical path irradiated to the glass edge A glass plate for identifying defects based on the magnitude of the bright signal of the image signal captured by the camera. A defect detection apparatus is disclosed. However, this apparatus requires a plurality of light sources and a plurality of imaging means.

  In Japanese Patent No. 3025833 (Patent Document 2), a signal pattern obtained by offsetting a maximum value of a video signal pattern obtained by imaging by a non-defective imaging means to a larger side by an offset value, and a minimum value of the video signal pattern are offset. A signal pattern generation unit that generates at least one of the signal patterns that are offset by a smaller value, a threshold pattern generation unit that generates a threshold pattern from the offset signal pattern, a video signal obtained by imaging the inspection object, and a threshold An inspection apparatus is disclosed that includes comparison means for comparing the pattern and determining the quality of the inspection object.

  Japanese Patent Application Laid-Open No. 8-122269 (Patent Document 3) discloses an imaging means for imaging an inspection object and outputting a video signal, and an inspection area setting means for setting an inspection area within an imaging field of view by the imaging means. And an abnormal part detecting means for detecting an abnormal part based on a video signal in the examination area, and a good / bad determination signal output means for outputting a good / bad determination signal according to whether or not the abnormal part has been detected. An imaging type inspection apparatus accommodated in the inside is disclosed. This document also describes that a notification means for notifying the result of the quality determination to the outside by light or sound is provided.

However, when these devices are applied to a continuously running fiber assembly, not only does the fiber assembly move continuously, but also the width and thickness of the fiber assembly change as the vehicle travels. It is difficult to accurately detect and analyze defects such as the generation of parts and feed them back to the production process. In particular, when applied to a fiber bundle such as a filter tow that is composed of a plurality of yarns and travels at high speed, not only the degree of adjacent yarns and the degree of overlap of the yarns varies with traveling, but these variations are constantly occurring. Therefore, it is difficult to accurately detect, analyze, and feed back to the production process defects (or non-uniform portions) of the fiber assembly.
Japanese Patent No. 3013903 (Claims) Japanese Patent No. 3025833 (Claims) JP-A-8-122269 (Claims)

  Accordingly, the object of the present invention is to provide the information processing device with the characteristic information (width, thickness, dirt) of the fiber assembly based on the video signal (video signal) from the imaging means that images the continuously running fiber assembly. It is to provide an analysis program for continuously and quantitatively analyzing (information regarding) and outputting (recording, displaying, sending) in a useful form.

  Another object of the present invention is to provide a program for causing an information processing device to analyze a signal related to characteristic information of a fiber assembly, and to provide a program useful for process control and quality control in a fiber assembly production process. It is in.

  Still another object of the present invention is to allow an information processing apparatus to analyze a signal related to characteristic information of a fiber assembly, for example, to grasp a normal state, to immediately notify an abnormality, and to feed back to a production process. Is to provide.

  Another object of the present invention is to provide a program capable of preventing the outflow of defective products due to the inversion phenomenon of fiber aggregates (filter tow, etc.) and / or contamination of the final product due to soiling of the fiber aggregates. is there.

  Still another object of the present invention is to crimp the fiber assembly uniformly throughout the whole by managing the thickness and / or width of the fiber assembly before crimping in the production process of the crimped fiber assembly. To provide a useful program.

  An object of the present invention is to provide a program useful for providing data relating to quality information that can be utilized for quality improvement (or confirmation of the effect of quality improvement) of a fiber assembly by process control.

  As a result of earnest studies to achieve the above-mentioned problems, the present inventors have found that the characteristic information (width, thickness, dirt) of the fiber assembly based on the video signal from the imaging means that captured the continuously running fiber assembly. When the information) is analyzed continuously and quantitatively by the information processing apparatus, it was found that it can be output in a form useful for process control and quality control in the production process of the fiber assembly, and the present invention has been completed.

That is, according to the present invention, the characteristic information of the fiber aggregate obtained from the video signal (for example, the video signal from the line sensor camera and / or the area sensor camera) from the imaging means that images the continuously traveling fiber aggregate. (For example, a signal related to width count data of a fiber assembly, a thickness video signal that may be clamped of the fiber assembly, a signal related to dirt count data of the fiber assembly, etc.) The present invention relates to an analysis program for causing the information processing apparatus to execute the following steps.
(1) Step of sequentially reading a signal related to the characteristic information of the fiber aggregate (2) Data related to the characteristic information of the fiber aggregate obtained from the sequentially read signal is sequentially associated with time data in the recording device of the information processing apparatus. Step of recording (3) Step of obtaining data relating to quality information of fiber aggregate (information that is the basis of value judgment regarding quality) from data recorded in association with time data In step (3) For example, based on width count data recorded in association with time data, data (instantaneous value data) relating to the width of the fiber assembly corresponding to the recorded time data, an average value within a predetermined time, and a maximum within a predetermined time A step of obtaining at least one selected from a value and a minimum value within a predetermined time may be included.

  In the step (2), for example, the thickness data in the width direction of the fiber aggregate obtained from the thickness video signal that may be clamped sequentially read are sequentially recorded in the recording device of the information processing apparatus in association with the time data. The step (3) includes, for example, (i) thickness data in the width direction of the fiber aggregate recorded in association with time data (data on thickness at each point in the width direction). A step of obtaining the travel position data of the fiber assembly corresponding to the recorded time data, (ii) from the thickness data in the width direction of the fiber assembly recorded in association with the time data, to a plurality of reference thickness distribution patterns Based on the step of classifying the thickness distribution state of the fiber assembly, or (iii) the thickness data in the width direction of the fiber assembly recorded in association with the time data, As a profile of the thickness of 維集 coalescence, such as the step of sending to the display device a signal to display it may be included.

  In step (iii), for example, (a) the width direction of the fiber assembly is set as the X axis, the time axis is set as the Y axis, the thickness direction is set as the Z axis, and the thickness profile of the fiber assembly is displayed on the display device. The position is shifted and displayed on the screen in time series, or (b) the width direction of the fiber assembly is taken as the X axis, the thickness direction is taken as the Y axis, and the thickness profile of the fiber assembly is displayed on the display screen of the display device. There may be a step of sending a signal for displaying the images superimposed on each other.

  The step (3) includes, for example, (3a) a step of obtaining data relating to the size of the dirt of the fiber aggregate from the dirt count data of the fiber aggregate recorded in association with the time data, and (3b) the dirt detection. Each time a trigger signal is detected, a step of reading the image signal of the fiber aggregate sent together with the dirt detection trigger signal; (3a) From the fiber aggregate dirt count data recorded in association with the time data, the fiber aggregate (3b) Obtaining data related to the size of the fiber aggregate in a time series from the data related to the size of the fiber aggregate recorded in association with the time data. Step, and (4) sending a signal for displaying data relating to the size of the dirt of the fiber assembly to the display device in time series. Or (3a) obtaining data relating to the quality information of the fiber assembly from the data relating to the property information of the fiber assembly recorded in association with the time data; (3b) data relating to the quality information of the fiber assembly; A step of comparing with a reference value relating to the quality, and (4) if the data relating to the quality information of the fiber assembly deviates from the reference value relating to the quality, (i) sending an alarm command signal to the alarm device, or ( ii) A step of sending a control command signal to the process control device may be included.

  The program of the present invention may cause the information processing apparatus to further execute a step of sending data relating to the characteristic information of the fiber assembly or data relating to the quality information to another information processing apparatus as a signal.

  The fiber assembly may be a filter tow.

  In this specification, “characteristic information of the fiber assembly” means defect information extracted from various signals included in the video signal from the imaging unit that images the continuously running fiber assembly. This means information determined as a defect by the determining means, and includes at least one information selected from the width, thickness and dirt of the fiber assembly. Further, in this specification, “record” may be rephrased as “save”. In this specification, the video signal includes a video signal.

  According to the present invention, the information processing apparatus is caused to analyze a signal related to the characteristic information of the fiber assembly obtained from the video signal from the imaging means that images the continuously traveling fiber assembly. It is possible to analyze a defect portion (non-uniform portion such as width and thickness, dirt, etc.) of the fiber aggregate that could not be determined. In addition, since the information processing apparatus can continuously and quantitatively analyze the signal relating to the characteristic information of the fiber assembly, it is useful for process control and quality control at the production site of the fiber assembly.

  That is, according to the present invention, by causing the information processing apparatus to analyze a signal related to at least one type of characteristic information selected from the width, thickness, and dirt of the fiber assembly, for example, to grasp a normal state, Can be immediately notified and fed back to the production process. According to the present invention, for example, by causing the information processing apparatus to analyze a signal related to the width count data of a fiber assembly (such as a filter tow), the time when the inversion phenomenon of the fiber assembly (such as a filter tow) occurs and a predetermined time Since the number of occurrences of the inversion phenomenon per time (a predetermined length of the fiber assembly) can be sequentially displayed, the outflow of defective products can be efficiently prevented. Further, according to the present invention, it is possible to effectively prevent the contaminated portion from being mixed into the final product by causing the information processing apparatus to analyze the dirt of the fiber assembly.

  According to the present invention, particularly in the production process of the crimped fiber assembly, whether or not the overlapping state (thickness uniformity) of the bands before crimping is the same as the initial setting state, or an allowable range It can be determined whether or not. Therefore, according to the present invention, using the thickness uniformity as an index, the bands can be supplied to the crimping process in a state of being overlapped with a predetermined uniformity, and the fiber aggregate can be crimped uniformly throughout. Furthermore, according to the present invention, it can also be determined whether or not the fiber assembly (tow band) before crimping is displaced with respect to the crimper. Therefore, the fiber assembly can be uniformly crimped over the whole by supplying the crimping machine with the traveling position (center axis or the like) of the fiber assembly (tow band) before crimping as an index.

  In addition, the data relating to the quality information of the fiber aggregate obtained by the present invention can be used as information for improving the quality of the fiber aggregate (or confirming the effect of quality improvement) by process control, for example.

  The program of the present invention is an analysis program for causing an information processing apparatus to analyze a signal related to characteristic information of a fiber assembly obtained from a video signal from an imaging unit that images continuously running fiber assemblies. The program of the present invention causes the information processing apparatus to execute at least (1) a reading step, (2) a recording step, and (3) an analysis step. In the reading step, a signal related to the characteristic information of the fiber assembly is sequentially read by the information processing apparatus. In the recording step, data relating to the characteristic information of the fiber aggregate obtained from the sequentially read signals is sequentially recorded in the recording device of the information processing apparatus in association with the time data. In the analysis step, the information processing apparatus is caused to acquire data related to the quality information of the fiber assembly from the data related to the property information of the fiber assembly.

[Information processing device]
The information processing apparatus (computer) normally has a function of processing the measured data, and can analyze a signal related to the characteristic information of the fiber assembly obtained from the video signal from the imaging means that images the fiber assembly. The information processing apparatus is a recording device that records data related to fiber aggregate characteristic information obtained from signals related to the fiber aggregate characteristic information, image signals of the fiber aggregate, etc. [flexible disk (FD) drive, hard disk (HD) drive Etc.] may be provided inside or outside. The information processing apparatus may be connected to a display device that displays data related to the characteristic information of the fiber assembly or data related to the quality information. The information processing device may be connected to another information processing device or a control device (for example, a device for controlling the production process of the fiber assembly).

  The information processing apparatus is equipped with an OS (Operating System) such as a control program. Usually, the information processing apparatus causes the arithmetic element of the information processing apparatus to function as a predetermined arithmetic circuit according to a program (application program) by the function of the installed OS, and executes a command by the program as predetermined arithmetic processing To do. In addition to arithmetic processing, the information processing apparatus also performs processing such as signal and data control processing, transmission / reception, comparison, discrimination, and instruction.

[Fiber assembly]
The fiber assembly is not particularly limited as long as it is a fiber assembly that can run continuously. For example, the tobacco filter tow is run by pulling fibers (yarns) continuously discharged from the spinning tower in the length direction, and a plurality of [for example, about 100 to 10,000 (particularly about 250 to 5000)], It is manufactured by crimping and drying in the middle of running while being bundled and adjacent. The present invention is useful for quality control (judgment of pass / fail) of continuously manufactured fiber assemblies.

  The fiber aggregate may have a two-dimensionally expanded form (for example, a band shape, a bandage shape, etc.). The fiber assembly is a strip-shaped fiber assembly composed of a plurality of yarns [for example, a strip-shaped fiber assembly composed of a layer composed of a plurality of yarns bundled and arranged adjacent to each other, the plurality Or a belt-like fiber assembly (such as tobacco filter tow) composed of a plurality of layers in which layers composed of yarns are laminated. Adjacent yarns may overlap each other. In the belt-like fiber assembly constituted by a plurality of layers, the yarns may be laminated at the same position in the width direction or at different positions.

  The fiber aggregate may be a fiber aggregate capable of transmitting light. The fiber aggregate that can transmit light (for example, tobacco filter tow) may analyze the width, thickness, dirt, etc. using the transmitted light amount, and analyze the width, dirt, etc. using reflected light. May be. The fiber aggregate that does not transmit light may be analyzed for width, dirt, and the like using reflected light.

  The fiber assembly may be composed of non-crimped yarns or crimped yarns. In the production process of a fiber assembly composed of crimped yarns, the program of the present invention may be used for quality control of the fiber assembly before crimping or after crimping. In a fiber assembly (such as a filter tow before crimping) composed of non-crimped yarns, it is highly necessary to manage at least one of thickness, width, and dirt. In a fiber assembly composed of crimped yarns (such as a filter tow after crimping), it is highly necessary to manage at least one of width and dirt. The fiber assembly may be openable.

  The traveling speed of the fiber assembly is not particularly limited, and may be, for example, about 0.1 to 100 m / second, preferably about 1 to 50 m / second, and more preferably about 5 to 30 m / second. A fiber assembly (particularly a fiber assembly that can be opened) is likely to vary in thickness and fiber density (opened state) due to fluctuations in the proximity and overlap of adjacent yarns as it travels. According to the program of the present invention, it is possible to cause the information processing apparatus to analyze characteristic information such as width, thickness, and dirt with high accuracy even for a fiber assembly traveling at high speed.

  For example, in the production of a fiber assembly (filter tow, etc.) that is made up of a plurality of yarns that are bundled and arranged adjacent to each other and layered together, the proximity of adjacent yarns as the vehicle travels The degree of overlap and the degree of overlap vary, and defective products are likely to be generated due to uneven thickness. In addition, in the production process of crimped fiber aggregates (crimped filter tows, etc.), the judgment result of the overlapping state (thickness uniformity) of yarns (or bands) before and after crimping is used as the quality control of the fiber aggregates. You may use it.

[Video signal]
The video signal from the imaging means that images continuously running fiber aggregates may be a color video signal or a black and white video signal. A color video signal (including a full color video signal) may be used by removing the color signal (or color signal) by a filter circuit. The video signal may be a signal by interlace scanning or non-interlace scanning. You may analyze the signal regarding the characteristic information of the fiber assembly obtained from the luminance signal contained in a video signal.

  As an image pickup means for picking up an image of the fiber aggregate, various means capable of picking up an image of the continuously running fiber aggregate and generating a video signal can be employed. The imaging means may be an area sensor camera or a line sensor camera. Examples of such imaging means include a video camera (monochrome or color), a line sensor camera, and other digital imaging means (such as a digital camera that can capture a moving image).

  When imaging a continuously traveling fiber assembly, for example, an imaging means having a predetermined angle of view is disposed on the front side of the fiber assembly continuously traveling from below to above, and the back surface of the fiber assembly. In addition, a background plate (for example, black) may be provided in order to increase the contrast to the fiber aggregate (usually white). An illuminating device for illuminating the fiber assembly from an oblique direction may be disposed on the back side of the fiber assembly in the non-viewing range of the imaging means. The illuminating device may be disposed from the background plate toward the back surface side of the fiber assembly, or the back surface side of the fiber assembly may be illuminated with light rays (transmission illumination). Taking advantage of the fact that the light transmittance is high in the thin region of the fiber assembly and the light transmittance is small in the thick region, the thickness and thinness of the fiber assembly can be imaged with high contrast, and thickness uniformity or non-uniformity can be achieved. Analysis can be performed with high accuracy. Further, by utilizing the fact that the fiber aggregate is low in light transmittance or light reflectance, the fiber aggregate can be imaged and the state of occurrence of the dirt can be analyzed.

  The video signal from the area sensor camera (CCD, image pickup tube, etc.) is used for the horizontal blanking part (or period) and the video part signal and the vertical blanking part (or period) constituting one scanning line in interlace scanning. It may include a signal [vertical synchronization signal, cut pulse, equalization pulse, etc.] to be configured. The signal constituting the horizontal blanking section (or period) may include a front porch area, a horizontal synchronization signal, a back porch area, and the like.

  The output signal of the line sensor camera may include a video signal and a synchronization signal (scanning signal, line transfer pulse). The video signal from the line sensor camera may include a black level signal, a start-side invalid pixel signal, and an end-side invalid pixel signal.

[Signal related to characteristic information of fiber assembly]
The signal relating to the characteristic information of the fiber assembly obtained from the video signal from the area sensor camera is, for example, an image pickup means (area sensor camera) for picking up a continuously running fiber assembly and the image pickup means. At least selected from the width, thickness and dirt of the fiber assembly based on means for synchronizing and clamping the video signal (such as sync separation circuit and clamping circuit) and the clamped video signal from this means Detection means for detecting characteristic information including defect information relating to one characteristic, extraction means for extracting defect information from characteristic information detected by the detection means, an extraction signal from the extraction means, and the information On the basis of a reference signal related to Can.

  FIG. 1 is a block diagram showing an electrical configuration for obtaining a clamped video signal from a video signal from an area sensor camera. A video signal (particularly a luminance signal included in the video signal) from the area sensor camera 11 may be synchronously separated by the synchronous separation circuit 13. The sync separation circuit 13 separates various sync signals (horizontal sync signal, vertical sync signal, frame sync signal, odd / even signal for odd field and even field, sync clamp signal, etc.) from the video signal. The synchronization signal is given to the timing circuit 14. The timing circuit 14 generates various timing signals for synchronizing with a video signal related to a predetermined scanning line. For example, the trigger signal may be generated by the trigger circuit 15.

  The clamp circuit 12 clamps the video signal in response to the synchronous clamp signal and keeps the reference level constant. Since the amplitude of the AC-coupled video signal varies depending on the size of the video signal portion, the DC level of the synchronizing signal is not constant, and the DC level of the video signal superimposed on the synchronizing signal is not constant. Therefore, the video signal may be clamped by the clamp circuit 12, the DC level may be reproduced, and the reference level may be made constant. The synchronous clamp signal can be generated from the synchronous signal by the synchronous clamp signal generating means.

  The signal relating to the characteristic information of the fiber assembly obtained from the video signal from the line sensor camera is, for example, an imaging unit (line sensor camera) for imaging a continuously traveling fiber assembly, Means for clamping the video signal (such as a clamping circuit) and, based on the clamped video signal from this means, including defect information relating to at least one characteristic selected from the width, thickness and dirt of the fiber assembly Based on a detection means for detecting characteristic information, an extraction means for extracting defect information from the characteristic information detected by the detection means, an extraction signal from the extraction means, and a reference signal related to the information, It can be obtained by an automatic discriminating device provided with discriminating means for discriminating the suitability of the information.

  FIG. 2 is a block diagram showing an electrical configuration for obtaining a clamped video signal from a video signal (and a synchronization signal) from a line sensor camera. A synchronization signal from the line sensor camera 21 is given to the timing circuit 24. The timing circuit 24 generates various timing signals for synchronizing with a video signal related to a predetermined scanning line. For example, the trigger signal may be generated by the trigger circuit 25.

  For example, the video signal from the line sensor camera 21 may be clamped by the clamp circuit 22 to obtain a clamped video signal. The clamp circuit 22 clamps the video signal in response to the synchronous clamp signal and keeps the reference level constant. Usually, since the video signal sent from the line sensor camera is DC-coupled, the clamp is not always necessary. However, since the reference level fluctuates even if DC coupling is used, the reference level may be made constant by clamping the video signal sent from the line sensor camera with the clamping means. By making the reference level constant, a signal relating to the characteristic information of the fiber assembly can be extracted efficiently and accurately. As the synchronization signal, the synchronization signal sent from the line sensor may be used in the case of self-excitation, and in the case of other excitation, the synchronization signal sent from the synchronization signal generation circuit is converted to a clock generation circuit (clock pulse). You may use with the clock pulse sent from the generation circuit.

  The signal relating to the property information of the fiber assembly can be extracted from a clamp video signal or a video signal (especially at least a luminance signal). Examples of the signal related to the characteristic information of the fiber aggregate obtained from the clamped video signal (or video signal) include a signal related to width count data, a thickness clamped video signal (or thickness video signal), and a signal related to dirt count data. Can be mentioned. Extraction of clamped video signals (clamp scanning signals) or signals related to fiber aggregate property information (signals related to width count data, thickness clamped video signals, thickness video signals, signals related to dirt count data, etc.) The extraction means is not particularly limited, and various noise removal means, for example, a differentiation means, an integration means, a threshold comparison means, a waveform shaping means (a low-pass filter for removing high-frequency noise) according to the type of characteristic information In addition to slice means based on thresholds, etc., these means may be combined.

  Hereinafter, referring to FIGS. 3 to 5, a signal related to width count data, a thickness clamped video signal (or thickness video signal), and a signal related to dirt count data are extracted from the clamped video signal (or video signal). The electrical configuration will be described.

[Signal related to width count data]
FIG. 3 is a block diagram for explaining an example of an electrical configuration for extracting a signal related to width count data from the clamped video signal (or video signal) of the fiber assembly.

  The signal related to the width count data is, for example, a clamped video signal or video signal (video signal of a predetermined scanning line, particularly a luminance signal) including characteristic information regarding the width of the fiber assembly, and noise related to the width count data. The signal can be extracted by giving it to an extraction circuit that extracts the signal. Since the signal related to the width count data is often included as a low frequency signal in the clamped video signal (or video signal), the extraction circuit that extracts the signal related to the width count data is, for example, the clamped video signal (or video). A noise removing circuit (low-pass filter circuit) 31 that removes high-frequency noise from the signal) and a slice circuit 32 may be used.

  The noise removal circuit 31 generates noise (that is, a noise signal outside the video signal, a noise signal at the rise and fall of the video signal, a noise signal within the video signal) included in the clamped video signal (or video signal). A video signal from which noise has been removed can be generated. A clamped video signal (or video signal) is supplied to a slice circuit (or comparison circuit) 32 in which a predetermined threshold is set in order to extract a signal related to the characteristic information of the width of the fiber assembly with higher accuracy. The slice circuit 32 may generate a rectangular signal corresponding to the width of the fiber assembly and sliced at a predetermined level. The noise-removed and sliced rectangular signal is supplied to the AND circuit 34 together with the reference clock signal (pulse signal) from the clock generation circuit 33, and the AND circuit 34 generates a clock signal corresponding to the sliced rectangular wave region. (Pulse signal) may be generated. A signal from the AND circuit 34 may be supplied to the counter circuit 35 and the number of clocks (number of pulses) corresponding to the width of the sliced rectangular wave may be counted to obtain a signal related to the width count data.

  A timing signal may be given from the timing circuit to the reset circuit, and the width count data by the counter circuit may be reset for each screen scan (every field scan). The reset circuit resets the accumulated count data by the counter circuit in response to the timing signal from the timing circuit.

[Thickness clamped video signal and thickness video signal]
FIG. 4 is a block diagram for explaining an example of an electrical configuration for extracting the thickness clamped video signal (or thickness video signal) from the clamped video signal (or video signal) of the fiber assembly.

  The clamped video signal (or video signal) of the fiber assembly contains noise within an acceptable thickness due to, for example, fine non-uniformity of the fibers (yarns) that make up the fiber assembly. In many cases. Therefore, in order to extract the thickness clamped video signal (or thickness video signal) from the clamped video signal (or video signal) of the fiber assembly, the clamped video signal (or video signal) of the predetermined scanning line [video signal A predetermined scanning line (for example, a scanning signal of the Xth scanning line crossing the imaging region) may be supplied to the extraction circuit. The thickness clamped video signal (or thickness video signal) is usually included in the clamped video signal (or video signal) as a low frequency signal. Therefore, the noise removal circuit (low-pass filter circuit) 41 may remove high-frequency noise from the clamped video signal (or video signal) to extract the thickness clamped video signal (or thickness video signal).

[Signal related to dirt count data]
FIG. 5 is a block diagram for explaining an example of an electrical configuration for extracting a signal related to dirt count data from the clamped video signal (or video signal) of the fiber assembly.

  The signal related to the dirt count data is usually included as a high frequency signal in the clamped video signal (or video signal). In order to extract a signal related to the dirt count data, the clamped video signal (or video signal) may be supplied to an extraction circuit including, for example, a differentiation circuit 51, comparison circuits 52a and 52b, and AND circuits 54a and 54b. . The differentiation circuit 51 performs a differentiation process on the clamped video signal (or video signal) to remove low-frequency noise, and converts a signal related to dirt characteristic information into a peak waveform. A high level dirt comparison circuit (first comparison circuit) for slicing or comparing the differential signal generated from the differentiation circuit 51 with, for example, a slice level (or threshold value, first reference value) corresponding to high level dirt. 52a and a low-level dirt comparison circuit (second comparison circuit) 52b for slicing or comparing at a slice level (or threshold value, second reference value) corresponding to low-level dirt to detect dirt The binarized signal may be generated. The binarized signal generated by the high level dirt comparison circuit 52a can correspond to the original dirt of the fiber assembly. The binarized signal generated by the low level dirt comparison circuit 52b can correspond to a potential dirt of the fiber assembly.

  The differential signal from the differentiation circuit 51 may include a noise signal corresponding to the shadows on both sides of the traveling fiber assembly, and binarization from the first and second comparison circuits 52a and 52b. The signal may include a binarized noise signal corresponding to shadows on both sides of the fiber assembly. A binarized signal from the first comparison circuit 52a and a width window gate signal from the dirt window gate circuit 53 (a gate signal slightly narrower than the width of the continuously running fiber assembly) as information on the imaging width. Provided to the first AND circuit 54a, the binarized signal from the second comparator circuit 52b and the width window gate signal to the second AND circuit 54b, and from the binarized signal according to the background plate You may remove the noise signal corresponding to shadows, such as the both sides of a fiber assembly.

  In the dirty window gate circuit 53, a width reference value regarding a window (a window width not including noise corresponding to a shadow by the background plate) slightly narrower than a predetermined window width (observation width) of the fiber assembly may be set. The window gate signal from the dirty window gate circuit 53 is in response to a synchronization signal given at a predetermined timing from a timing circuit that generates a synchronization signal (timing signal) related to the scanning line of the video signal. This is given to the second AND circuit 54b.

  The binarized signal from the first AND circuit 54a is given to the first dirt counter circuit 55a, and among the binarized signals, the number of pulses or rectangular peaks corresponding to dirt is counted. A signal relating to dirt count data is provided. The binarized signal from the second AND circuit 54b is given to the second dirt counter circuit 55b, and a signal relating to the second dirt count data is given. The signal relating to the second dirt count data may be used to manage potential dirt of the fiber assembly.

  The signals related to the first and second dirt count data may be reset every scan of one screen (that is, every field scan). For example, a synchronization signal (timing signal) is given from the timing circuit to the reset circuit 56, and in response to the synchronization signal (timing signal), the reset circuit 56 performs the first dirt counter circuit 55a and the second dirt counter circuit 55b. The signals relating to the first and second dirt count data accumulated in step (1) may be reset to zero.

[Analysis program]
The signal source related to the fiber assembly property information such as the automatic discriminator is usually a signal related to the fiber assembly property information (eg, signal related to width count data, thickness clamped video signal, thickness video signal, dirt count). An interface (interface circuit) for sending a signal related to data) to the information processing apparatus, and a trigger means (trigger circuit) for generating a trigger signal for causing the information processing apparatus to read the signal related to the characteristic information. In order to increase the accuracy of processing by the information processing device, noise related to the fiber assembly characteristic information may be removed from these signals before being read by the information processing device, or may be amplified by an amplifier circuit. Good. The trigger signal notifies the information processing device of the timing at which a signal related to the characteristic information is transmitted from the automatic determination device or the like. Therefore, in response to the trigger signal, a signal related to the characteristic information can be read by the information processing apparatus.

  In the present invention, first, a signal related to the characteristic information of the fiber assembly is read by an information processing apparatus. For example, a trigger that is sent to the information processing apparatus at a predetermined cycle together with signals related to the characteristic information of the fiber assembly (signals related to width count data, thickness clamped video signals, thickness video signals, dirt count data, etc.) Each time a signal (width trigger signal, thickness trigger signal, dirt detection trigger signal, etc.) is detected, the fiber assembly is passed through a digital signal input / output board (DIO board), an analog / digital conversion (A / D conversion) board, etc. A signal related to body characteristic information may be read.

  When the signal related to the property information of the fiber assembly is a digital signal (a signal related to the width count data, a signal related to the dirt count data, etc.) The information may be read via a DIO board (a device that converts a digital signal into a format that can be read by the information processing device) installed in the information processing device. When the signal relating to the characteristic information of the fiber assembly is an analog signal (thickness clamped video signal, thickness video signal, etc.) A device for converting the signal into a signal). In this case, the signal regarding the characteristic information of the fiber assembly may be A / D converted by the information processing apparatus and read as a digital signal.

  In addition, the information processing apparatus may include peripheral devices such as a capture board (a device that converts a video signal sent from a CCD camera or the like into a format that can be read by the information processing apparatus).

  According to the present invention, based on signals relating to the property information of the fiber assembly (signals relating to width count data, thickness clamped video signals, thickness video signals, signals relating to dirt count data, etc.) Characteristic information such as dirt can be analyzed.

  In the present invention, a program can be selected according to what is measured (analyzed) as the characteristic information of the fiber assembly. That is, among the measurement of the width of the fiber assembly (signal related to the width count data), the measurement of thickness (thickness clamped video signal or thickness video signal), the measurement of dirt (signal related to the dirt count data), etc. Measurement (width measurement, thickness measurement, dirt measurement) or a plurality of measurements is selected, and corresponding programs (width measurement program, thickness measurement program, dirt measurement program) are started.

  According to the program for width measurement, the information processing device is configured to, for example, data on the width of the fiber assembly, an average value on the width of the fiber assembly within a predetermined time, a maximum Values, minimum values, etc. can be analyzed.

  According to the thickness measurement program, the information processing apparatus can, for example, run position data of the fiber assembly, data on the thickness distribution state of the fiber assembly based on the thickness clamped video signal or the thickness video signal of the fiber assembly. Further, the thickness data in the width direction of the fiber assembly (data regarding the thickness on the scanning line) can be displayed on the display device as a profile of the thickness of the fiber assembly.

  According to the dirt measurement program, the information processing apparatus can, based on a signal relating to the dirt count data of the fiber aggregate, for example, data relating to the presence or absence of dirt in the fiber aggregate, data relating to the size of the dirt in the fiber aggregate, fiber Data on the number of dirt on the aggregate can be analyzed, the size of the dirt on the fiber aggregate can be displayed on the display device over time, and the fibers sent along with the dirt detection trigger signal The video signal of the aggregate can be read.

  At least a part of the characteristic information of the fiber assembly is obtained from the information processing apparatus via another information such as a DIO board, a digital / analog conversion (D / A conversion) board, or a local area network (LAN) board. You may make it send to a processing apparatus or a control apparatus.

[Width measurement program]
FIG. 6 is a flowchart illustrating an example of an operation of reading a signal related to width count data of the information processing apparatus by the width measurement program. As shown in FIG. 6, when the width measurement program is activated, the information processing apparatus starts a step of reading a signal related to width count data. That is, each time the information processing device detects a width trigger signal sent in a predetermined cycle together with a signal related to the width count data (S11), the information processing device temporarily stores the width count data from the DIO board. And a step (S13) of recording at a predetermined address on the hard disk (HD) of the information processing apparatus in association with the time data. The information processing apparatus executes a step of sending the width count data recorded at a predetermined address of the HD to the display device together with the display command signal, and the width count data is displayed on the display device (S14). For example, the width count data may be displayed on the display device in the form of a list in correspondence with the associated time data. For example, even if a finite number (for example, 10) of data is displayed from the latest data and the latest width count data is added, the earliest display data among the displayed data may be deleted. Good. Alternatively, only the latest width count data may be displayed one by one sequentially. Hereinafter, various data may be displayed in the same manner as the width count data.

  According to the width measurement program, it is possible to cause the information processing apparatus to analyze the data regarding the width of the fiber assembly corresponding to the time data, the average value, the maximum value, the minimum value, etc. regarding the width of the fiber assembly within a predetermined time. it can. In the width measurement program, it is possible to select the type of analysis (for example, analysis of data relating to the width corresponding to time data, analysis of the average value relating to the width within a predetermined time, analysis of the maximum value, analysis of the minimum value, etc.) It may be.

  FIG. 7 is a flowchart illustrating an example of the operation of the information processing apparatus according to the width measurement program when analysis of data related to the width is selected. The flowchart of FIG. 7 shows a state in which the width of the fiber assembly is too wide (a state where there is a risk of adversely affecting the quality of the product: a wide state) and a state in which the fiber assembly is too narrow (a state where the width is too narrow). If the condition that may adversely affect the quality (narrow state) continues for a long time or occurs frequently, but not for a long time, the fiber assembly production process is used to readjust the production conditions. The process of discharging the aggregate is shown.

  When the analysis of the data related to the width is selected, as shown in FIG. 7, the information processing apparatus executes the step (S110) of calling the width count data recorded at a predetermined address of the HD of the information processing apparatus. A step (S111) of calculating data related to the width of the fiber assembly based on the width count data is executed. The information processing apparatus executes a step (S112) of recording data relating to the calculated width at a predetermined address of HD, and a step of sending the data relating to the width together with a display command signal to the display device Then, data relating to the width is displayed on the display screen in correspondence with the time data (S113).

  In order to determine whether or not the fiber assembly is in the wide state, the information processing apparatus executes steps (S121 and S122) of comparing data relating to the width recorded on the HD with a reference value (upper limit). When the data regarding the width is equal to or less than the upper limit, it is determined that the wide state is not established. Therefore, in order to determine whether or not the fiber assembly is in a narrow state, steps (S131 and S132) are performed in which data relating to the width is compared with a reference value (lower limit). When the data regarding the width is equal to or greater than the lower limit, it is determined as normal. Therefore, returning to step S110, the information processing apparatus executes a step of calling the next width count data recorded in the HD, and executes a step of calculating data relating to the width of the fiber assembly from the called data (S111). The same steps are repeated until the analysis is completed.

  In step S122, when the data regarding the width corresponding to the time data is larger than the upper limit (in the wide state), the information processing apparatus enters the wide state in order to determine whether or not the wide state continues for a long time. The step (S141) which calculates the elapsed time after becoming (the 1st elapsed time regarding a width | variety: the elapsed time of a wide state) is performed. The information processing apparatus executes a step of sending the display command signal to the display device together with a step of recording the elapsed time of the wide state at a predetermined address of HD (S142), and the elapsed time of the wide state is displayed on the display screen. (S143). Further, the information processing apparatus executes a step (S152) of comparing the elapsed time in the wide state with the reference time A (first reference time: long time reference) in order to determine whether the wide state is appropriate. When the elapsed time of the state exceeds the reference time A (long time reference), it is determined that the wide state has continued for a long time. Therefore, a step (S185) of sending a fiber assembly discharge command signal to the fiber assembly discharge device is executed. The elapsed time in the wide state can be calculated based on time data associated with the width count data.

  When the elapsed time in the wide state is less than or equal to the reference time A (long time reference), the information processing apparatus uses the elapsed time in the wide state as a reference to determine whether or not the elapsed time in the wide state is a short time. Steps (S161, S162) for comparison with time B (short-time reference) are executed. If the elapsed time in the wide state is less than the reference time B (a short time reference) (if the wide state has occurred but was in a short time), the process returns to step S110, and the information processing apparatus performs the next recording in the HD. The step of calling the width count data (S110) is executed, the step of calculating the data relating to the width of the fiber assembly from the called data (S111) is executed, and the same steps are repeated until the analysis is completed.

  When the elapsed time in the wide state is equal to or greater than the reference time B (short time reference), the information processing apparatus determines that the elapsed time is the reference time A (long time) in order to determine the occurrence frequency of the wide state of the fiber assembly. The step (S171) of calculating the number of occurrences within a predetermined period of the wide state (semi-wide time wide state) that is equal to or less than the reference time and equal to or longer than the reference time B (short time reference) is executed (S171). The number of occurrences of the semi-long wide state can be performed by using, for example, a counting unit that counts when the semi-long wide state occurs and a reset unit that resets when a predetermined time elapses. The information processing apparatus records the number of occurrences in the predetermined period of the semi-long wide state in a predetermined address of the HD (S172), and also includes data on the number of occurrences in the predetermined period of the semi-long wide state in the data A step of sending to the display device is executed in conjunction with the display command signal, and the number of occurrences within a predetermined period of the semi-long wide state is displayed on the display screen (S173). Even if a wide state occurs for a quasi-long time, the frequency of occurrence is actually low, and there is a possibility that the quality of the product is not adversely affected. Therefore, the information processing apparatus compares the number of occurrences of the semi-long-time wide state within a predetermined period with the reference number (upper limit) in order to determine whether the semi-long-time wide state is appropriate (S181, S182). If it is executed and the number of occurrences exceeds the upper limit, it is determined that a wide state of a semi-long time has occurred frequently, and in step S185, a fiber assembly discharge command signal is sent to the fiber assembly discharge device.

  When the number of occurrences is less than or equal to the upper limit, it is determined that the occurrence frequency is low, although a wide state of semi-long time has occurred. Returning to step S110, the information processing apparatus calls the next width count data recorded in the HD in step S110, and calculates data relating to the width of the fiber assembly based on the called width count data in step S111. . Such an operation is repeated until the analysis is completed.

  In step S132, when the data on the width of the fiber assembly is less than the lower limit (in the case of the narrow state), the information processing apparatus determines whether the narrow state has continued for a long time. The step (S144) of calculating the elapsed time (second elapsed time related to the width: the elapsed time in the narrow state) since the narrow state is entered is executed based on the time data associated with. The information processing apparatus performs a step (S145) of recording the elapsed time in the narrow state at a predetermined address in HD (S145), and sends the elapsed time in the narrow state with the display command signal to the display device. The step is executed, and the elapsed time in the narrow state is displayed on the display screen (S146). The information processing apparatus executes a step (S153) of comparing the elapsed time in the narrow state with the reference time C (long time reference). When the elapsed time in the narrow state exceeds the reference time C (the long time reference), it is determined that the narrow state has continued for a long time. Therefore, the information processing apparatus executes a step (S185) of sending a fiber assembly discharge command signal to the fiber assembly discharge device.

  When the elapsed time in the narrow state is equal to or shorter than the reference time C (long time reference), the information processing apparatus uses the elapsed time in the narrow state as a reference in order to determine whether or not the narrow state is a short time. Steps (S163, S164) for comparison with time D (short-time reference) are executed. When the elapsed time in the narrow state is less than the reference time D (short time reference), it is determined that the narrow state has occurred but is in a short time, the process returns to step S110, and the information processing apparatus is recorded in the HD. The step of calling data is executed, the step of calculating data relating to the width of the fiber assembly from the called data (S111) is executed, and the same steps are repeated until the analysis is completed.

  When the elapsed time in the narrow state is equal to or longer than the reference time D (short time reference), the information processing apparatus determines that the elapsed time is the reference time C (long time reference) in order to determine the occurrence frequency of the narrow state. Thereafter, a step (S174) of calculating the number of occurrences within a predetermined period of a narrow state (quasi-long-time narrow state) that is equal to or longer than a reference time D (a short time reference) is executed (S174). The information processing apparatus records the number of occurrences in the predetermined period of the narrow period of the quasi-long time at a predetermined address of the HD (S175), and data on the number of occurrences in the predetermined period of the quasi-long period of the narrow state. In addition, a step of sending it to the display device together with the display command signal is executed, and the number of occurrences data within a predetermined period of the narrow period of the quasi-long time is displayed on the display screen (S176). Then, the information processing apparatus executes steps (S183, S184) for comparing the number of occurrences within a predetermined period with the reference number (upper limit). When the number of occurrences exceeds the reference number (upper limit), a narrow state of semi-long time frequently occurs. Therefore, the information processing apparatus executes a step (S185) of sending a fiber assembly discharge command signal to the fiber assembly discharge device.

  When the number of occurrences within the predetermined period is equal to or less than the reference number (upper limit), a narrow state for a quasi-long time has occurred, but it is determined that the occurrence frequency is low and there is no possibility of adversely affecting the quality of the product. Therefore, returning to step S110, the information processing apparatus executes a step of calling data recorded on the HD, executes a step of calculating data on the width of the fiber assembly from the called data (S111), and performs analysis. Similar steps are repeated until finished.

  Steps for “display on display device” [data related to width (S113), time after data related to width exceeds upper limit (S143), time after data related to width becomes lower than lower limit (S146), standard In the display of the number of occurrences (S173) greater than or equal to time B (short-term reference) and the number of occurrences (S176) greater than or equal to the reference time D (short-term reference)], for example, one display screen of one display device A column for displaying the data of each item may be provided above and displayed simultaneously. For example, the data related to the width may be displayed by sequentially displaying only the latest data, or a finite number (for example, 10) of data from the latest is displayed in a list form, and the latest data is added. You may display so that the first display data may be deleted every time. For the elapsed time in the wide state (or narrow state), for example, “0 (seconds)” is displayed in the normal state, and after the wide state (or narrow state) is entered, the data relating to the width is displayed. You may count up based on the associated time data.

  In the step of “recording on HD” (S112, S142, S145, S172, S175), for example, at least the time data associated with the corresponding width count data and the data type [data on width, data on width] Time after the data exceeds the upper limit, time after the data related to the width becomes less than the lower limit, number of occurrences within a predetermined period of time equal to or greater than the reference time B (short time reference), reference time D (short time reference) It may be recorded at a predetermined address so that it can be called based on the above occurrence count]. Hereinafter, various types of data may be recorded at a predetermined address so that they can be called based on at least the corresponding time data and the type of data.

  In FIG. 7, the data relating to the width is compared with the reference value (lower limit) after being compared with the reference value (upper limit), but is compared with the reference value (upper limit) after being compared with the reference value (lower limit). May be.

  In step S132, when the data regarding the width is less than the reference value (lower limit), it may be determined that the inversion phenomenon of the fiber assembly has occurred, and the number of occurrences of the inversion phenomenon (display) may be counted up. The inversion phenomenon refers to a phenomenon in which the fiber assembly is instantaneously twisted within a short time of less than about 1 second and the front surface and the back surface are switched in the production process of the fiber assembly (such as filter tow). Since the width of the portion where the inversion phenomenon of the fiber assembly occurs is extremely narrow, the occurrence of the inversion phenomenon can be detected by comparing the data relating to the width with a predetermined reference value (lower limit). The inversion phenomenon adversely affects the quality when the fiber assembly is processed into a tobacco filter or the like. Therefore, a step of calculating the number of occurrences of the reversal phenomenon within a predetermined time may be provided, and when the number of occurrences exceeds a reference value (upper limit), the outside may be notified.

  FIG. 8 is a graph for explaining an operation when an alarm command signal is transmitted when the reference value of the number of occurrences of inversion within a predetermined time is set to three. In the example of FIG. 8, the counter means for counting when a reversal phenomenon is detected and the reset means for resetting when a predetermined time has elapsed, the number of occurrences of the reversal phenomenon is counted, and when the count reaches 3, the alarm command A signal is sent out.

  FIG. 9 is a flowchart illustrating an example of the operation of the information processing apparatus according to the width measurement program when the average value analysis regarding the width is selected. If the width of the fiber assembly (average value within a predetermined time) is too wide (when it is wider than this, the product quality may be adversely affected) or too narrow (when it is too narrow, the product quality will be adversely affected) If there is an instruction to reduce or widen the width of the fiber assembly, but the effect is not recognized, the fiber assembly is discharged from the production process to readjust the production conditions. The process of making is shown in FIG.

  When the analysis of the average value is selected, as shown in FIG. 9, the information processing apparatus within a predetermined time (for example, predetermined 2 seconds) out of the width count data recorded at a predetermined address of the HD of the information processing apparatus. After executing the step (S210) of calling the width count data, a step (S211) of calculating an average value related to the width of the fiber assembly within a predetermined time from the called data is executed. The information processing apparatus executes a step of recording average value data relating to the width at a predetermined address of HD (S212) and a step of sending the average value data relating to the width together with a display command signal to the display device. The average value for the width is displayed on the display screen (S213).

  In order to determine whether the fiber assembly is in the wide state, the information processing apparatus executes steps (S221, S222) of comparing the average value data regarding the width with the reference value (upper limit), and the average value data is If it is less than or equal to the upper limit, steps (S223, S224) of comparing the average value data with the reference value (lower limit) are executed in order to determine whether or not the fiber assembly is in a narrow state. When the average value data is equal to or higher than the lower limit, it is determined as normal. Therefore, returning to step S210, the information processing apparatus executes a step of calling data recorded at a predetermined address of the HD, and calculating average value data regarding a width within a predetermined time from the called data (S211). ) And the same steps are repeated until the analysis is finished.

  If the average value data regarding the width of the fiber assembly exceeds the upper limit in step S222, the information processing apparatus adjusts the width of the operation instruction signal for narrowing the width by a predetermined control amount (minimum unit) in step S231. Send to device. In order to confirm the operation of narrowing the width, the information processing apparatus executes a step (S241) of calling width count data within a predetermined time after the operation recorded in a predetermined address of the HD, and performs a predetermined operation after the operation. A step (S242) of calculating average value data relating to the width within the time is executed. The information processing apparatus executes a step (S243) of recording the average value data relating to the width after the operation at a predetermined address of HD (S243) and causing the display command signal to accompany the average value data relating to the width after the operation. Then, the sending step to the display device is executed, and the average value regarding the width after the operation is displayed on the display screen (S244).

  In order to determine the control operation by the operation for narrowing the width, the information processing apparatus compares the average value data regarding the width after the operation with the average value data regarding the width before the operation (S251, S252). Execute. When the average value data regarding the width after the operation is equal to or greater than the average value data regarding the width before the operation, the control operation is not recognized. Therefore, the information processing apparatus executes a step (S260) of sending a fiber assembly discharge command signal to the fiber assembly discharge device. On the other hand, when the average value regarding the width after the operation is less than the average value regarding the width before the operation, the control operation is recognized. Therefore, the process returns to step S210, and the information processing apparatus executes a step (S245) of calling the width count data within a predetermined time out of the width count data of the fiber aggregate recorded on the HD. The same step is repeated until the step (S246) of calculating the average value data regarding the width within the time is executed and the analysis is finished.

  In step S224, when the average value data regarding the width of the fiber assembly is less than the lower limit, the information processing apparatus, in step 232, sends a predetermined control amount (minimum unit) ) Sends an operation instruction signal to widen the width. In order to confirm the effect of the operation of expanding the width, the information processing apparatus is called after executing the step (S245) of calling the width count data within the predetermined time after the operation recorded in the predetermined address of the HD. The step (S246) of calculating the average value data regarding the width within a predetermined time of the fiber assembly after the operation is executed from the obtained data. The information processing apparatus executes a step (S247) of recording the average value data relating to the width after the operation at a predetermined address of the HD (S247) and causing the average value data relating to the width after the operation to be accompanied by a display command signal. Then, the step of sending to the display device is executed, and the average value regarding the width after the operation is displayed on the display screen (S248). In order to discriminate the control operation to increase the width, the information processing apparatus executes steps (S253, S254) of comparing the average value data regarding the width after the operation with the average value data regarding the width before the operation. When the average value data regarding the width after the operation is equal to or less than the average value regarding the width before the operation, it is determined that an appropriate control operation has been performed. Therefore, the information processing apparatus executes a step (S260) of sending a fiber assembly discharge command signal to the fiber assembly discharge device. On the other hand, when the average value data regarding the width after the operation exceeds the average value data regarding the width before the operation, it is determined that an appropriate control operation has been performed. Therefore, returning to step S210, the information processing apparatus executes a step of calling data recorded at a predetermined address of HD, and calculates average value data relating to the width of the fiber assembly within a predetermined time from the called data. The same steps are repeated until step (S211) is executed and the analysis is completed.

  In the display of the average value regarding the width in steps S213, S244, and S248, the data of each average value is represented by time data associated with the corresponding width count data (time data corresponding to the beginning of the predetermined time and time data corresponding to the end. Etc.), for example, it may be displayed in a list form.

  In FIG. 9, the average value data relating to the width is compared with the reference value (upper limit) and then compared with the reference value (lower limit). May be.

  FIG. 10 is a flowchart showing an example of the operation of the information processing apparatus by the width measurement program when the analysis of the maximum value and the minimum value related to the width is selected. The flowchart of FIG. 10 shows a state where the width (maximum value within a predetermined time) of the fiber assembly is too wide (a state where there is a possibility of adversely affecting the quality of the product if it is wider than this) or (Minimum value) is too narrow (a condition that may adversely affect product quality if it is narrower than this), and even if an operation to narrow or widen the fiber assembly is instructed, the control operation is permitted. If not, a process for discharging the fiber assembly from the production process in order to readjust the production conditions is shown.

  When the analysis of the maximum value and the minimum value is selected, as shown in FIG. 10, in order to determine whether or not the fiber assembly is in the wide state, the information processing apparatus records at a predetermined address on the HD of the information processing apparatus. After executing the step (S311) of calling the width count data within a predetermined time (for example, predetermined 2 seconds) out of the obtained width count data, the maximum of the width within the predetermined time of the fiber assembly from the called data A step of extracting value data (S312) is executed. The information processing apparatus executes a step (S313) of recording the maximum value data related to the extracted width at a predetermined address of HD (S313), along with the display command signal to the maximum value data related to the extracted width, The step of sending to the display device is executed, and the maximum value related to the width is displayed on the display screen (S314). In order to determine whether or not the fiber assembly is in the wide state, the information processing apparatus executes steps (S321 and S322) of comparing the maximum value data regarding the width with a reference value (upper limit).

  When the maximum value data is less than or equal to the upper limit, in order to determine whether or not the fiber assembly is in a narrow state, the information processing apparatus uses the width count data within a predetermined time among the width count data recorded on the HD. After executing the step of calling (S315), the step of extracting the minimum value data relating to the width of the fiber assembly within a predetermined time from the called data (S316) is executed. The information processing apparatus executes a step (S317) of recording the minimum value data relating to the width at a predetermined address of HD, and sending the minimum value data relating to the width together with a display command signal to the display device And the minimum value related to the width is displayed on the display screen (S318). In order to determine whether or not the fiber assembly is in a narrow state, the information processing apparatus executes steps (S323 and S324) of comparing the minimum value related to the width recorded on the HD with a reference value (lower limit). To do. When the minimum value is not less than the lower limit, it is determined as normal. Therefore, the process returns to step S311, and the information processing apparatus executes a step of calling the width count data within a predetermined time among the width count data of the fiber aggregate recorded on the HD. The same step is repeated until the step (S312) of extracting the maximum value data regarding the width is executed and the analysis is finished.

  In step S322, when the maximum value data regarding the width exceeds the upper limit, the information processing apparatus operates to reduce the width of the fiber assembly by a predetermined control amount (minimum unit) in order to reduce the width of the fiber assembly. A step (S331) of sending the instruction signal to the width adjusting device is executed. In order to confirm the control operation by the operation for narrowing the width, the information processing apparatus executes the step (S341) of calling the width count data within the predetermined time after the operation recorded in the predetermined address of the HD Then, a step (S342) of extracting maximum value data relating to the width of the fiber assembly within a predetermined time after the operation is executed from the called data. The information processing apparatus executes a step (S343) of recording the maximum value data related to the width after the operation at a predetermined address of the HD (S343), and associates the display command signal with the maximum value data related to the width after the operation. The step of sending to the display device is executed, and the maximum value related to the width after the operation is displayed on the display screen (S344). In order to determine the control operation by the operation for narrowing the width, the information processing apparatus compares the maximum value data related to the width after the operation with the maximum value data related to the width before the operation (S351, S352). Execute. If the maximum value data regarding the width after the operation is not less than the maximum value data regarding the width before the operation, it is determined that an appropriate control operation has been performed. Therefore, the information processing apparatus executes a step (S360) of sending a fiber assembly discharge command signal to the fiber assembly discharge device. When the maximum value data regarding the width after the operation is less than the maximum value data regarding the width before the operation, it is determined that an appropriate control operation has been performed. Therefore, returning to step S311, the information processing apparatus executes a step (S311) of calling the width count data within a predetermined time of the fiber aggregate recorded at the predetermined address of the HD, and the maximum width-related data is called from the called data. The same step is repeated until the value is calculated (S312) and the analysis is completed.

  In step S324, when the minimum value data is less than the lower limit, the information processing apparatus sends an operation instruction signal for expanding the width by a predetermined control amount (minimum unit) to increase the width of the fiber assembly. The step of sending to (S332) is executed. In order to confirm the control operation, the information processing apparatus executes the step (S345) of calling the width count data within the predetermined time after the operation recorded in the predetermined address of the HD (S345), and from the called data, A step of extracting a minimum value related to the width of the fiber assembly within a predetermined time after the operation (S346) is executed. The information processing apparatus executes a step (S347) of recording the minimum value related to the width after the operation at a predetermined address of HD (S347), and displays the minimum value data regarding the width after the operation together with a display command signal. The step of sending to the apparatus is executed, and the minimum value related to the width after the operation is displayed on the display screen (S348). In order to determine the control operation, the information processing apparatus executes steps (S353, S354) of comparing the minimum value data regarding the width after the operation with the minimum value data regarding the width before the operation. If the minimum value data regarding the width after the operation is equal to or less than the minimum value data regarding the width before the operation, it is determined that an appropriate control operation has been performed. Therefore, a step (S360) of sending a fiber assembly discharge command signal to the fiber assembly discharge device is executed. On the other hand, when the minimum value data regarding the width after the operation exceeds the minimum value data regarding the width before the operation, it is determined that an appropriate control operation has been performed. Therefore, returning to step S311, the information processing apparatus executes a step of calling the width count data associated with the time data corresponding to the predetermined time within the width count data recorded on the HD, and the next of the fiber assembly The same step is repeated until the step (S312) of extracting the maximum value regarding the width within the predetermined time is executed and the analysis is finished.

  In the steps (S314 and S344) for “displaying the maximum value regarding the width” and the steps (S318 and S348) for “displaying the minimum value regarding the width”, for example, the maximum value is displayed on one display screen of the display device. For displaying the minimum value and the time data associated with the corresponding width count data (the time data corresponding to the beginning of the predetermined time and the time data corresponding to the end ), For example, it may be displayed in a list form.

  In FIG. 10, the information processing apparatus analyzes the maximum value and then analyzes the minimum value. However, after the minimum value is analyzed, the maximum value may be analyzed. In FIG. 10, the information processing apparatus analyzes the maximum value and the minimum value in combination, but the maximum value and the minimum value may be analyzed separately.

  When at least one selected from the average value, maximum value, and minimum value regarding the width of the fiber assembly is out of the reference value (range), the information processing device is caused to execute a step of sending an alarm command signal to the alarm device. May be. FIG. 11 is a graph for explaining an operation when the average value related to the width of the fiber assembly deviates from a reference value (upper limit) and causes the information processing apparatus to execute a step of sending an alarm command signal. When continuing the width measurement, the information processing apparatus repeatedly executes the same operation every time the width trigger signal is detected. By repeating this, the width of the fiber assembly is constantly monitored, the width abnormality and the reversal phenomenon are immediately notified, and promptly fed back to the production process, for example, for quality improvement and confirmation of its effect.

[Thickness measurement program]
When the thickness measurement is started, the information processing apparatus executes a step of reading the thickness clamped video signal. FIG. 12 is a flowchart showing an example of an operation of reading a thickness clamped video signal that operates in response to the activation of the thickness measurement program. As shown in FIG. 12, when the thickness measurement program is activated, the information processing apparatus executes a step of reading the thickness clamped video signal. That is, the information processing apparatus samples the thickness clamped video signal with the A / D conversion board (S22) each time it detects the thickness trigger signal sent in a predetermined cycle together with the thickness clamped video signal (S21). ), Converting the sampled thickness clamped video signal into an aggregate of digital data (S23), temporarily recording the digital data of the thickness clamped video signal in the memory of the A / D conversion board (S24), Temporarily storing the digital data of the thickness clamped video signal in the memory of the information processing apparatus (S25), associating the digital data of the thickness clamped video signal with the time data, and a predetermined address of the HD of the information processing apparatus Recording step (S26) and the thickness clan The digital data Dobideo signals, while accompanied by the display command signal, and performing the step of sending to the display device, the digital data is, as the thickness profile, are displayed on the display screen (S27).

  Note that a thickness video signal (a DC-coupled video signal from a line sensor camera or the like) may be used instead of the thickness clamped video signal.

  According to the thickness measurement program, it is possible to cause the information processing apparatus to continuously and sequentially analyze the traveling position of the fiber assembly, the form of the thickness of the fiber assembly, and the like. When the thickness measurement program is activated, the type of analysis (for example, analysis of the travel position of the fiber assembly, analysis of the form of the fiber assembly, etc.) is selected.

  FIG. 13 is a flowchart showing an example of the operation of the information processing apparatus according to the thickness measurement program when analysis of the traveling position of the fiber assembly is selected. The flowchart of FIG. 13 shows a state where the fiber assembly traveling position (left end) is unevenly distributed to the left side, or the fiber assembly traveling position (right end) is excessively unevenly distributed to the right side. There was a possibility of adversely affecting the process and adversely affecting the quality of the product. The operation of correcting the uneven distribution of the fiber assembly traveling position (moving to the right or left) was instructed, but the effect of the instruction was not recognized. In this case, a step of sending an alarm output command signal to the alarm device is shown.

  When the analysis of the traveling position of the fiber assembly is selected, as shown in FIG. 13, the information processing apparatus starts the traveling position analysis program and determines whether the traveling position (left end position) of the fiber assembly is appropriate. Then, a step (S411) of calling data recorded at a predetermined address of the HD of the information processing apparatus is executed. The information processing apparatus executes a step (S412) of extracting the left end position LP1 of the fiber assembly from the called data and a step of sending the data related to the left end position LP1 together with a display command signal to the display apparatus. And the left end position LP1 is displayed on the display screen (S413). In order to determine whether or not the traveling position of the fiber assembly is unevenly distributed on the left side, the information processing apparatus executes steps (S421 and S422) of comparing the left end position LP1 with a reference value (left limit). For example, among the positions where the thickness profile intersects a predetermined slice line, the leftmost position can be extracted as the left end position LP1, and the rightmost position can be extracted as the right end position RP1.

  If the left end position LP1 is not to the left of the left limit, the information processing apparatus calls the data recorded at a predetermined address of the HD in order to determine whether the traveling position (right end position) of the fiber assembly is appropriate (S414). Execute. The information processing apparatus executes a step (S415) of extracting the right end position RP1 of the fiber assembly from the called data and a step of sending the data relating to the right end position RP1 to the display apparatus together with a display command signal. The right end position RP1 is displayed on the display screen (S416). In order to determine whether or not the traveling position of the fiber assembly is unevenly distributed on the right side, the information processing apparatus executes steps (S423 and S424) of comparing the right end position RP1 with a reference value (right limit). When the right end position RP1 is not right from the right limit, it is determined to be normal. Therefore, returning to step S411, the information processing apparatus executes a step of calling the data recorded at a predetermined address of the HD, and executes a step of extracting the left end position of the fiber assembly from the called data (S412). The same steps are repeated until the analysis is completed.

  In step S422, when the left end position LP1 is to the left of the left limit, in order to move the traveling position of the fiber assembly to the right, the information processing apparatus sends a signal instructing the rightward movement (minimum unit) to the traveling position. A step (S431) of sending to the adjusting device is executed. In order to confirm the suitability of movement, the information processing apparatus executes a step (S441) of calling the data after the instruction recorded at a predetermined address of the HD, and then the left end position LP2 of the fiber assembly after the instruction. Is extracted (S442), the display command signal is added to the data relating to the left end position LP2 and sent to the display device, and the left end position LP2 is displayed on the display screen (S443). In order to determine the presence or absence of the effect of the movement instruction, the information processing apparatus executes steps (S451, S452) of comparing the left end position LP2 with the left end position LP1. If the left end position LP2 is not to the right of the left end position LP1, it is determined that the effect of the movement instruction has not been recognized. Therefore, the information processing apparatus executes a step (S460) of sending an alarm command signal to the alarm apparatus. On the other hand, when the left end position LP2 is to the right of the left end position LP1, it is determined that the effect of the movement instruction has been recognized. Therefore, returning to step S411, the information processing apparatus executes a step of calling data recorded at a predetermined address of HD, and executes a step of extracting the left end position of the fiber assembly from the called data (S412). The same steps are repeated until the analysis is finished.

  In step S424, when the right end position RP1 is right from the right limit, in order to move the traveling position of the fiber assembly to the left, the information processing apparatus sends a signal for instructing leftward movement (minimum unit) to the traveling position. A step (S432) of sending to the adjusting device is executed. In order to confirm the suitability of the movement, the information processing apparatus executes a step (S444) of calling the data after the instruction recorded at a predetermined address of the HD. The information processing apparatus executes a step (S445) of extracting the right end position RP2 of the fiber assembly after the instruction from the called data, and then displays the data related to the right end position RP2 together with the display command signal. The step of sending to the apparatus is executed, and the right end position RP2 is displayed on the display screen (S446). In order to determine the presence or absence of the effect of the movement instruction, the information processing apparatus executes steps (S453, S454) for comparing the right end position RP2 with the right end position RP1. If the right end position RP2 is not to the left of the right end position RP1, the effect of the movement instruction has not been recognized. Therefore, a step (S460) of sending an alarm command signal to the alarm device is executed. When the right end position RP2 is to the left of the right end position RP1, the effect of the movement instruction is recognized. Therefore, returning to step S411, the information processing apparatus executes a step of calling data recorded at a predetermined address of HD (S411), executes a step of extracting the right end position of the fiber assembly (S412), and performs analysis. The same steps are repeated until ending.

  In the “display on display device” step [LP1 display (S413), LP2 display (S443), RP1 display (S416), RP2 display (S446)], for example, one display screen of the display device is displayed. A column for displaying the right end position (LP1, LP2) and a column for displaying the left end position (RP1, RP2) are provided, and a corresponding thickness clamped video signal (or thickness video signal) is provided. It may be displayed in a list form corresponding to the associated time data. Note that the left end position (LP1, LP2) and the right end position (RP1, RP2) of the fiber assembly are, for example, from a predetermined reference line [for example, the left end, right end, center line, etc. of the captured image (screen)] You may represent by the data regarding a relative distance.

  In FIG. 13, the information processing apparatus is caused to execute the step of analyzing the right end position after executing the step of analyzing the left end position. However, after the step of analyzing the right end position is executed, The step of analyzing may be executed.

  FIG. 14 is a flowchart illustrating an example of the operation of the information processing apparatus according to the thickness measurement program when analysis of the shape of the fiber assembly is selected. The flow chart of FIG. 14 divides the thickness profile into a plurality of regions [in this example, three regions (left region, central region, right region)] in order to eliminate variations in thickness in the width direction of the fiber assembly. Identify the thickest and thinnest areas and calculate the ratio of the “thickest area thickness” to the “thinnest area thickness”. If the ratio is too large, the product quality will be adversely affected. The process of reducing the thick region yarns and increasing the thin region yarns to eliminate thickness variations when a condition that can be applied occurs.

  When morphological analysis is selected, as shown in FIG. 14, the morphological analysis program is started, and the information processing apparatus sets a predetermined address on the HD of the information processing apparatus to divide the thickness profile into three regions. After executing the step of calling recorded data (S511), the step of extracting the left end position LP and the right end position RP of the fiber assembly from the called data (S512, S513), between the left end position LP and the right end position PR. Step (S514) of calculating a position to be divided into three equal parts (center left CL, center right CR), area L of the left region (between left end position LP and center left CL), center region (between center left CL and center right CR) The area C and the area R of the right region (between the center right side CR and the right end position RP) are calculated (S515, S517, S519), and the obtained data is Step of recording at a predetermined address in the respectively HD (S516, S518, S520) is executed.

  Then, the information processing apparatus executes a step for identifying the thickest region (region having a large area) and the thinnest region (region having a small area) for the three regions (left region, central region, and right region). Then, a step for calculating a ratio of “thickness (area) of the thickest region” to “thickness (area) of the thinnest region” is executed.

  That is, the information processing apparatus executes the step (S521) of comparing the left region area L and the central region area C. When left region area L> central region area C, the central region area C and the right region area are compared. A step of comparing with R (S522) is executed. When the central area C> the right area R, the left area is the thickest and the right area is the thinnest. Therefore, a step (S531) of calculating the left region area L / right region area R is executed. If the central region area C> the right region area R is not satisfied in step S522, the information processing apparatus executes a step (S524) of comparing the left region area L with the right region area R. When the left region area L> the right region area R, the left region is the thickest and the central region is the thinnest. Therefore, in order to quantify the degree of thickness variation, the information processing apparatus executes a step (S532) of calculating left region area L / center region area C. If the left region area L> the right region area R is not satisfied in step S524, the right region is the thickest and the central region is the thinnest. Therefore, in order to quantify the degree of thickness variation, the information processing apparatus executes a step (S533) of calculating the right region area R / the central region area C.

  If the left region area L> the central region area C is not satisfied in step S521, the information processing apparatus executes a step (S523) of comparing the central region area C with the right region area R. When the central area C <the right area R, the right area is the thickest and the left area is the thinnest. Therefore, in order to quantify the degree of thickness variation, the information processing apparatus executes a step of calculating the right region area R / left region area L (S534). When the central region area C <the right region area R is not satisfied in step S523, the information processing apparatus executes a step of comparing the left region area L with the right region area R. When the left region area L <the right region area R, the central region is the thickest and the left region is the thinnest. Therefore, in order to quantify the degree of thickness variation, the information processing apparatus executes a step (S535) of calculating the central region area C / the left region area L. When the left region area L <the right region area R is not satisfied, the central region is the thickest and the right region is the thinnest. Therefore, in order to quantify the degree of thickness variation, the information processing apparatus executes a step of calculating the central region area C / the right region area R (S536).

  The information processing apparatus compares the ratio of “thickness of the thinnest region (area)” with respect to “thickness of the thinnest region (area)” calculated in steps S531 to S536 with a reference value (upper limit) regarding thickness variation. Steps (S541 to S546, S551 to S556) are executed. When the ratio is less than or equal to the upper limit, the thickness variation is small. Therefore, the process returns to step S511, and the information processing apparatus executes a step of calling data recorded at a predetermined address of the HD to extract the next left end position and right end position of the fiber assembly (S512, S513). Similar steps are repeated until run and finish the analysis.

  In steps S551 to S556, when the ratio is not less than or equal to the upper limit, the thickness variation is large. Therefore, in order to adjust the thickness variation, the information processing apparatus executes a step of sending a signal instructing movement of the yarn to the thickness adjusting apparatus. For example, when the left region area L / the right region area R exceeds the upper limit in step S551, the information processing apparatus is used to thin the left region (thickest region) and thicken the right region (thinnest region). Sending a signal instructing to move a part of the yarn constituting the central region to the right region and moving a part of the yarn constituting the left region to the central region (S561). Execute. In step S552, when the left region area L / the central region area C exceeds the upper limit, in order to make the left region (thickest region) thin and the central region (thinnest region) thick, the information processing apparatus A step (S562) of sending a signal instructing to move a part of the yarn constituting the left region to the central region to the thickness adjusting device is executed. In step S553, when the right area R / the central area C exceeds the upper limit, the information processing apparatus is configured to thin the right area (thickest area) and thicken the central area (thinnest area). A step (S563) of sending a signal instructing to move a part of the yarn constituting the right region to the central region to the thickness adjusting device is executed.

  In step S554, when the right region area R / left region area L exceeds the upper limit, the information processing device is used to thin the right region (thickest region) and thicken the left region (thinnest region). A step of sending a signal instructing to move a part of the yarn constituting the central region to the left region and a part of the yarn constituting the right region to the central region (S564). Execute. In step S555, when the central region area C / left region area L exceeds the upper limit, the information processing apparatus is configured to thin the central region (thickest region) and thicken the left region (thinnest region). A step (S565) of sending a signal instructing to move a part of the yarn constituting the central region to the left region to the thickness adjusting device is executed. In step S556, when the central region area C / the right region area R exceeds the upper limit, in order to make the central region (thickest region) thin and the right region (thinnest region) thick, the information processing apparatus A step (S566) of sending a signal instructing to move a part of the yarn constituting the central region to the right region to the thickness adjusting device is executed.

  The left region area L data (left region thickness data) and the central region area C data (central region thickness data) recorded at predetermined addresses of the HD of the information processing apparatus in each of steps S516, S518, and S520 in FIG. And from the value of the right region area R data (right region thickness data), the information processing apparatus determines to which of the reference thickness distribution patterns the thickness distribution state in the width direction of the fiber assembly is classified. be able to. FIG. 15 shows an example of the type of thickness distribution pattern. In FIG. 15, when the thickness distribution pattern is left region area L> center region area C <right region area R, the center region is thin and the outside is thick (class A), and left region area L <center region area C. > When the right region area R, the pattern in which the central region is thick and the outside is thin (class B), the left region area L = the central region area C = the right region area R, uniform (class C), the left region area L > Central region area C> Right region area R or left region area L <Central region area C <Right region area R, it is set as one thin (classification D). When the thickness distribution state is classified into the classification A, the classification B, or the classification D, the information processing apparatus may execute a step of sending an alarm command signal to the alarm apparatus in order to notify the necessity of the improvement action. Good. If necessary, the information processing apparatus may execute a step of recording the determination result at a predetermined address of HD. Based on this result, it is possible to combine with changes to the form according to the purpose, adjustment work (for example, change or correction of the yarn arrangement constituting the fiber assembly, etc.).

  For example, after causing the information processing apparatus to execute a step of specifying a thin region (left region, central region, or right region) with respect to the target form, (i) when the left region is thin, the right region is configured. Sending to the thickness adjusting device a signal instructing to move a part of the yarn and a part of the yarn constituting the central region to the left region; (ii) when the central region is thin, the yarn constituting the left region Sending to the thickness adjusting device a signal instructing to move a part of the yarn and a part of the yarn constituting the right region to the central region, (iii) when the right region is thin, the yarn constituting the left region You may perform the step which sends out the signal which instruct | indicates moving a part and part of yarn which comprises a center area | region to a right area | region to a thickness adjustment apparatus.

  When continuing the thickness measurement, the information processing apparatus repeatedly executes the same operation (step) every time the thickness trigger signal is detected. By repeating this process, the thickness of the fiber assembly is constantly monitored, the thickness abnormality is immediately notified, and promptly fed back to the production process. For example, it is utilized as information useful for quality improvement and confirmation of the effect. When the target form (thickness) is not achieved, the information processing apparatus may be caused to execute a step of sending an instruction signal for adjusting the form (thickness) to the thickness adjusting apparatus. Thereafter, the information processing device may be caused to execute a step of determining whether or not the form (thickness) of the fiber assembly has been improved, and if not improved, a step of sending an alarm command signal to the alarm device may be executed. Good.

  FIG. 16 shows an example of a profile relating to the thickness based on the transmitted light amount. FIG. 17 shows a state in which the profile relating to the thickness in FIG. 16 is divided into three regions and displayed by color coding (hatching). Further, FIG. 18 shows a form of thickness obtained by dividing the profile relating to the thickness of FIG.

  The profile (thickness data in the width direction) relating to the thickness displayed on the display device in step S27 in FIG. 12 is a graph of the distribution of the thickness (transmitted light amount) data in the cross section in the width direction of the fiber assembly as shown in FIG. It may be a display. When evaluating the thickness by the transmitted light amount, the larger the numerical value of the transmitted light amount, the thinner the thickness. For example, as shown in FIGS. 17 and 18, the thickness state may be displayed in a form that is visually easy to understand. In FIG. 16, the left end position LP, right end position RP, and left end position LP-right end position RP that are extracted and calculated in steps S512 to S514 in FIG. 14 are divided into three equal parts (center left CL, center right CR). A profile relating to the thickness is displayed in three equal parts [left region (L), central region (C), right region (R)] in the width direction. In FIG. 17, each area divided into three equal parts in FIG. 16 is color-coded (hatched). In FIG. 18, a representative value indicating the thickness of each region [data total (area), average value, etc.] is used for graphing.

  19 to 21 are displays of changes over time in the profile relating to the thickness of the fiber assembly. For example, FIG. 19 is a graph in which the obtained thickness profile is three-dimensionally displayed (time series display of a single series) in time series. The profile relating to the thickness in FIG. 19 is displayed as follows. That is, in step S26 in FIG. 12, the data recorded on the HD of the information processing apparatus represents a distribution regarding the thickness on the scanning line in the width direction of the fiber assembly. Specifically, in step S26, the data recorded on the HD of the information processing apparatus corresponds to the brightness of the image at one point on the scanning line in the width direction of the fiber assembly (= transmitted light amount inversely proportional to the thickness). It is a collection of data to be processed.

  For example, the width direction of the fiber assembly is the X axis, the time axis is the Y axis, the thickness direction is the Z axis, and the thickness profile of the fiber assembly is positioned on the display screen of the display device in time series. The display may be shifted. In other words, three-dimensional graph display coordinates having the X, Y, and Z axes are prepared on the display screen of the display device, the X axis corresponds to the width direction (fiber assembly width), and the Y axis corresponds to the time data. The Z axis is assigned to the amount of transmitted light [thinness inversely proportional to the thickness of the fiber assembly], and for example, a profile relating to the thickness obtained from the data associated with the first time data is displayed on the display device. And plots the profile regarding the thickness obtained from the data sequentially associated with the later time data in the Y-axis in association with the elapsed time on the Y axis. The display screen may be cleared after every specified number of plots. After clearing, all of the nth profile may be re-plotted at the position of the (n-1) th profile, and the newest profile may always be plotted at a specific position (Nth position).

  The time lapse display of the profile relating to the thickness may be a three-dimensional display (time lapse display) of a graph (FIG. 18) using the area of the three-divided regions as shown in FIG. In this display, the determination result based on the thickness distribution pattern of FIG. 15 can be displayed in the same manner as the time lapse display of the thickness profile (FIG. 19) for the form of thickness (thickness distribution state). In this display, it is possible to easily observe the change over time in the form of thickness (thickness distribution state). For example, it is possible to determine at a glance a situation in which a fiber aggregate that has a thin central region and a thick pattern on the outside changes to a pattern with a thick central region and a thin pattern with time.

  As shown in FIG. 21, by simultaneously displaying the data measured in a plurality of series on the display device, the thickness states between the series can be easily compared. In FIG. 22, the time-variable region (variation range) of the thickness of the fiber assembly can be displayed on the display device. Specifically, by causing the display device to overwrite the profile relating to the thickness of the fiber assembly, it is possible to determine at a glance that the dense portion of the line is a region with many fluctuations. For example, the width direction of the fiber assembly may be set as the X axis, the thickness direction may be set as the Y axis, and the thickness profile of the fiber assembly may be superimposed and displayed on the display screen of the display device. That is, instead of the three-dimensional graph (FIG. 19) having the X-axis, Y-axis, and Z-axis on the display screen, a two-dimensional graph (FIG. 22) with only the X-axis and Y-axis is prepared. The thickness profile may be displayed in an overwritten state. FIG. 22 is a schematic diagram illustrating an example of a display for monitoring a temporal variation region (variation range) of the thickness of the fiber assembly. In this display, it is possible to easily determine a region (position in the width direction) where the thickness varies greatly. According to such a two-dimensional graph display of the thickness profile, it is also possible to know the variation in the running position of the fiber assembly from the variation in the left end and right end positions of each thickness profile.

[Stain measurement program]
In the information processing apparatus, (1) each time a stain detection trigger signal is detected, a step of sequentially reading the stain count data of the fiber assembly; and (2) information processing by associating the sequentially read stain count data with time data. A step of sequentially recording on the recording device of the apparatus; (3a) a step of obtaining data on the size of the fiber aggregate from the dirt count data of the fiber aggregate associated with the time data; and (3b) a dirt detection trigger. Each time the signal is detected, a step of reading the image signal of the fiber assembly sent together with the dirt detection trigger signal may be executed. (4) a step of obtaining, in a time series, data relating to the size of the dirt of the fiber assembly from the data relating to the size of the dirt obtained in the step (3a), (5) a fiber aggregate; The step of sending a signal for displaying the state of occurrence of dirt (the magnitude of dirt, the number of occurrences within a predetermined time, etc.) in time series to the display device may be executed. When the dirt measurement program causes the occurrence of dirt exceeding a predetermined size or frequency, it can be eliminated as a defective tow at that time and prevented from flowing out as a product. In addition, the cause can be investigated from the state of occurrence of dirt and linked to improvement work.

  FIG. 23 is a flowchart illustrating an example of the operation of the information processing apparatus according to the dirt measurement program. As shown in FIG. 23, when the dirt measurement program is activated, the information processing apparatus starts reading a signal related to dirt count data.

  That is, each time the information processing apparatus detects a dirt detection trigger signal sent together with a signal related to dirt count data (S610), it captures an image of the fiber assembly at that moment via the capture board (S611). ). The information processing apparatus executes a step (S612) of recording the image of the fiber assembly at a predetermined address of the HD of the information processing apparatus, and displays the image signal of the fiber assembly together with a display command signal. A step of sending to the apparatus is executed, and an image of the fiber assembly is displayed on the display screen (S613).

  On the other hand, the information processing apparatus executes a step (S621) of temporarily storing the dirt count data from the DIO board in the memory of the information processing apparatus, and associates the dirt count data with the time data to determine a predetermined value of the HD of the information processing apparatus. The step of recording in the address (S622) is executed, and the step of sending the display command signal to the dirt count data together with the display command signal is executed, and the dirt count data is displayed on the display screen (S623).

  In step S622, the information processing apparatus executes a step (S631) of calling the dirt count data recorded at a predetermined address of the HD, and then determines the size of the dirt based on the called dirt count data. In the following manner, a step (S632) of calculating data (dirt size value data) related to the size of the stain is executed. In order to determine whether or not the size of the dirt is appropriate, the information processing apparatus executes a step (S633) of comparing the dirt size value data with a reference value (upper limit).

  The dirt size value corresponds to, for example, the number of consecutive scanning lines in the width direction of the fiber assembly in which dirt is counted at the same position in the width direction, and the length of the dirt in the running direction of the fiber assembly. Corresponding to Therefore, it can be evaluated that the greater the dirt size value, the greater the dirt. In other words, since the fiber aggregate is normally contaminated across a plurality of scanning lines, the contamination extracted from each clamped video signal (or video signal) in a plurality of scanning lines (especially adjacent or adjacent scanning lines). Based on the signal related to the count data, it is determined whether or not the detection position of the dirt signal in each clamped video signal (or video signal) is the same position in the horizontal direction of the scanning line (width direction of the fiber assembly). If they are at the same position, it may be determined that they are caused by a single stain, and if they are at different positions, it may be determined that they are caused by separate stains.

  For example, the information processing apparatus sequentially compares the dirt count data for adjacent scanning lines, and the scanning lines corresponding to the dirt count data in which dirt is counted at the same position in the horizontal direction of the scanning lines are adjacent to each other. The dirt size value can be calculated by executing the step of counting the number to be performed.

  When the dirt size value is below the upper limit, the dirt is small. Therefore, returning to step S610, every time the information processing apparatus detects a dirt detection trigger signal, a step (S611) of capturing an image of the fiber assembly at that moment is executed, and the dirt count data is stored in the information processing apparatus. The same step is repeated until the step of storing in the memory (S621) is executed and the analysis is completed.

  When the dirt size value exceeds the upper limit, it is determined that the dirt is large. Therefore, based on the image of the fiber assembly displayed on the display screen in step S613, the cause of the occurrence of the dirt detection trigger signal is confirmed, and it is confirmed that nothing other than dirt is detected (S635, S636). When the cause of occurrence is not dirty, false detection occurs. Therefore, the process returns to step S610, and the same steps are repeated each time the information processing apparatus detects a dirt detection trigger signal until the analysis is completed. When the cause of occurrence is dirt, in order to determine the frequency of occurrence of dirt, the information processing apparatus calculates the number of occurrences of the dirt detection trigger signal within a predetermined time (for example, a predetermined two minutes) (S637). After the execution, steps (S638, S639) for comparing the number of occurrences of the dirt trigger signal with the reference number (upper limit) are executed. When the number of occurrences of the dirt detection trigger signal is equal to or less than the reference number, it is determined that a large degree of dirt has occurred but the occurrence frequency is low. Therefore, returning to step S610, every time the information processing apparatus detects the dirt detection trigger signal, the same steps are repeated until the analysis ends. If the number of occurrences is greater than the reference number, it is determined that large dirt has frequently occurred, and the information processing apparatus executes a step (S640) of sending a fiber assembly discharge command signal (operation command signal) to the fiber assembly discharge device. To do.

  In the steps of “display on display device” (S623, S613), for example, one display screen of the display device is divided into two, and captured images are sequentially displayed on one side, and the above-mentioned display is displayed on the other side. The dirt count data corresponding to the existing images may be displayed sequentially.

  When the dirt count data exceeds the reference value (for example, when the size value or the number of occurrences of the dirt detection trigger signal exceeds the reference value), the information processing device is determined to be abnormal and an external device (alarm device) , A step of sending an alarm command signal or an operation command signal to the control device, for example, a step of sending an operation command signal to the fiber assembly discharging device in the fiber assembly production process.

  When the measurement of dirt is continued, the information processing apparatus repeatedly executes the same operation (step) every time it detects a dirt detection trigger signal. As a result, the contamination of the fiber assembly is constantly monitored, the abnormality is immediately notified, and is quickly fed back to the production process, thereby preventing the outflow of the abnormal product. The criterion for determining that the dirt count data exceeds the reference value is, for example, when the dirt count data (size value, number of occurrences) exceeds (1) the reference value A (gradual reference value) even once. (2) Although the reference value A (slow reference value) is not reached, the number of times that the reference value B (strict reference value) is exceeded during the predetermined period T reaches the reference N times. Good.

  FIG. 24 is a graph in which dirt is detected on the horizontal axis and the dirt size value detected at each time is displayed on the vertical axis. According to the graph as shown in FIG. 24, it is possible to grasp the situation in which significant dirt frequently occurs from the initial state of the occurrence of dirt, which is useful information for elucidating the cause of dirt and implementing countermeasures.

[Sending step]
The information processing apparatus sequentially transmits the signal related to the characteristic information on the width, thickness, dirt, etc. of the fiber assembly to the display apparatus together with the display command signal along with the characteristic information. Steps may be executed to display the characteristic information on a display screen. In addition, while causing the information processing apparatus to perform a step of analyzing a signal related to the characteristic information of the fiber assembly, a step of sequentially recording data related to the quality information obtained is performed, and data or analysis related to the recorded characteristic information is performed. After the analysis is completed as the signal regarding the obtained quality information, a step of sending the data to another information processing apparatus may be executed to cause the other information processing apparatus to perform post-analysis.

  For example, in order to analyze the width of the fiber assembly in detail, the information processing apparatus may execute a step of post-analyzing the width count data recorded at a predetermined address of the information processing apparatus HD, The information processing apparatus may be caused to execute a step of sending the width count data as a signal to another information processing apparatus, and cause another information processing apparatus to perform post-analysis.

  If another information processing device is an information processing device that has a high-capacity storage device and can perform advanced processing, it can be manufactured from accumulated data using annual fluctuations, monthly fluctuations, daily fluctuations, and other series. The stability of quality can be examined by comparing the same varieties that have been manufactured or manufactured in the past. It is also useful for investigating the cause and relationship with quality items that gradually deviate from the center value over a long period of time. Even if the information processing apparatus does not perform such high-level processing, it can be used for issuing an alarm or prompting an action with reference to a standard obtained from accumulated data.

  The present invention allows an information processing apparatus to analyze a signal related to characteristic information of a continuously running fiber assembly (for example, a filter tow in a production process), and is useful for quality control of a fiber assembly, for example. Can be used for output (as data related to quality information). According to the program of the present invention, for example, data relating to temporal variation information of the width and thickness of the fiber assembly can be managed by the information processing apparatus, and can be used for process control and quality control in the production process of the fiber assembly. . For example, based on the strength or size of defect information, statistical data processing [temporal fluctuation tendency, frequency of generation of defect information (including strength and size), etc.] Available.

FIG. 1 is a block diagram showing an electrical configuration for obtaining a clamped video signal from a video signal from an area sensor camera. FIG. 2 is a block diagram showing an electrical configuration for obtaining a clamped video signal from a video signal (and a synchronization signal) from a line sensor camera. FIG. 3 is a block diagram for explaining an example of an electrical configuration for extracting width count data from the clamped video signal. FIG. 4 is a block diagram for explaining an example of an electrical configuration for extracting the thickness clamped video signal from the clamped video signal. FIG. 5 is a block diagram for explaining an example of an electrical configuration for extracting dirt count data from the clamped video signal. FIG. 6 is a flowchart showing an example of the operation [reading of width count data] of the information processing apparatus when the width measurement program according to the embodiment of the present invention is started. FIG. 7 is a flowchart showing an example of the operation of the information processing apparatus (analysis of data relating to width) by the width measurement program according to an embodiment of the present invention. FIG. 8 is a graph for explaining the operation when the information processing device is caused to execute a step of sending an alarm command signal to the alarm device according to the number of occurrences of the inversion phenomenon. FIG. 9 is a flowchart showing an example of the operation [analysis of width count data (average value)] of the information processing apparatus by the width measurement program according to the embodiment of the present invention. FIG. 10 is a flowchart showing an example of the operation (maximum value and minimum value analysis) of the information processing apparatus by the width measurement program according to the embodiment of the present invention. FIG. 11 illustrates an operation when the information processing device causes the analysis result (average value, maximum value, minimum value) of the width count data to deviate from the reference value and executes a step of sending an alarm command signal to the alarm device. It is a graph for. FIG. 12 is a flowchart showing an example of the operation of the information processing apparatus (reading of a thickness clamped video signal, display of a thickness profile) when starting a thickness measurement program according to an embodiment of the present invention. FIG. 13 is a flowchart showing the operation [analysis of travel position (operation of travel position analysis program)] of the information processing apparatus by the thickness measurement program according to one embodiment of the present invention. FIG. 14 is a flowchart showing the operation [morphological analysis (morphological analysis program operation)] of the information processing apparatus according to the thickness measurement program according to the embodiment of the present invention. FIG. 15 is a schematic diagram for explaining types of thickness distribution patterns. FIG. 16 is a graph showing an example of a profile relating to the thickness based on the transmitted light amount. FIG. 17 is a graph showing a state in which the profile relating to the thickness of FIG. 16 is divided into three regions and displayed in color (hatched). FIG. 18 is a graph showing a form of thickness obtained by dividing the profile relating to the thickness of FIG. 16 into three regions. FIG. 19 is a three-dimensional graph showing an example of a time series display of a single series of profiles relating to thickness. FIG. 20 is a graph showing an example of a time lapse display of three areas of a profile relating to thickness. FIG. 21 is a graph showing an example of a comparative display of a plurality of series of profiles relating to thickness. FIG. 22 is a schematic diagram illustrating an example of a display for monitoring a temporal variation region (variation range) of the thickness of the fiber assembly. FIG. 23 is a flowchart showing the operation of the information processing apparatus according to the dirt measurement program according to the embodiment of the present invention. FIG. 24 is a graph in which the horizontal axis represents the time when dirt is detected, and the vertical axis represents the dirt size value of dirt detected at each time.

Claims (12)

An analysis program for causing an information processing device to analyze a signal related to characteristic information of a fiber assembly obtained from a video signal from an imaging unit that images continuously running fiber assemblies, the information processing device Program to execute the following steps.
(1) Step of sequentially reading a signal related to the characteristic information of the fiber aggregate (2) Data related to the characteristic information of the fiber aggregate obtained from the sequentially read signal is sequentially associated with time data in the recording device of the information processing apparatus. Step of recording (3) Step of obtaining data relating to quality information of the fiber assembly in association with time data from data recorded in association with time data   The program according to claim 1, wherein the imaging means is a line sensor camera and / or an area sensor camera.   The signal related to the property information of the fiber assembly is at least one selected from the signal related to the width count data of the fiber assembly, the thickness video signal that may be clamped of the fiber assembly, and the signal related to the dirt count data of the fiber assembly. The program according to claim 1. The program according to claim 3, which causes the information processing apparatus to execute the following steps.
(1) Step of sequentially reading a signal related to the width count data of the fiber assembly (2) A width count data obtained from the signal related to the width count data read in sequence is sequentially recorded in the recording device of the information processing apparatus in association with the time data. Step (3) Based on the width count data recorded in association with the time data, the data relating to the width corresponding to the recorded time data of the fiber assembly, the average value within the predetermined time, the maximum value within the predetermined time, and the predetermined Obtaining at least one selected from the smallest values in time The program according to claim 3, which causes the information processing apparatus to execute the following steps.
(1) Step of sequentially reading the thickness video signal of the fiber assembly that may be clamped (2) Thickness data in the width direction of the fiber assembly obtained from the thickness video signal that may be sequentially read of the clamped thickness Step (3) at least one step selected from the following steps (i) to (iii) (i) a fiber aggregate recorded in association with time data A step of obtaining the travel position data of the fiber assembly corresponding to the recorded time data from the thickness data in the width direction of (ii) serving as a reference from the thickness data in the width direction of the fiber assembly recorded in association with the time data A step of classifying the thickness distribution state of the fiber assembly based on a plurality of thickness distribution patterns. (Iii) The width of the fiber assembly recorded in association with time data. The step of sending the thickness data, to the display device a signal for displaying a profile of the thickness of the fiber aggregate   In step (iii), (a) the width direction of the fiber assembly is the X axis, the time axis is the Y axis, the thickness direction is the Z axis, and the profile of the fiber assembly thickness is displayed on the display screen of the display device. , Displayed in a time-series manner, or (b) the width direction of the fiber assembly as the X axis, the thickness direction as the Y axis, and the profile of the thickness of the fiber assembly on the display screen of the display device, 6. The program according to claim 5, wherein the program is a step of sending a signal for displaying the images in a superimposed manner. The program according to claim 3, which causes the information processing apparatus to execute the following steps.
(1) A step of sequentially reading a signal relating to the dirt count data of the fiber aggregate every time a dirt detection trigger signal sent together with a signal relating to the dirt count data of the fiber aggregate is detected. (2) The dirt count sequentially read. Step of sequentially recording the dirt count data obtained from the data-related signal in association with the time data in the recording device of the information processing apparatus. (3) From the dirt count data of the fiber aggregate recorded in association with the time data, (4) The step of reading the image signal of the fiber assembly sent together with the dirt detection trigger signal every time the dirt detection trigger signal is detected The program according to claim 3, which causes the information processing apparatus to execute the following steps.
(1) A step of sequentially reading a signal relating to the dirt count data of the fiber aggregate every time a dirt detection trigger signal sent together with a signal relating to the dirt count data of the fiber aggregate is detected. (2) A dirt count sequentially read. A step of sequentially recording the dirt count data obtained from the data-related signal in association with the time data in the recording device of the information processing apparatus (3a) From the dirt count data of the fiber aggregate recorded in association with the time data, the dirt of the fiber aggregate is recorded. Obtaining data relating to the size of the fiber assembly (3b) obtaining data relating to the soil size of the fiber assembly in a time series from the data relating to the soil size of the fiber assembly recorded in association with the time data (4) ) Displays a signal for displaying data related to the size of dirt in the fiber assembly in time series. Step to be sent to the location The program according to claim 3, which causes the information processing apparatus to execute the following steps.
(1) A step of sequentially reading a signal relating to the dirt count data of the fiber aggregate every time a dirt detection trigger signal sent together with a signal relating to the dirt count data of the fiber aggregate is detected. (2) A dirt count sequentially read. Step of sequentially recording the dirt count data obtained from the data-related signal in association with the time data in the recording device of the information processing device (3) From the dirt count data of the fiber aggregate recorded in association with the time data, Calculating the number of stains within a given time The program according to claim 1, which causes the information processing apparatus to execute the following steps.
(1) Step of sequentially reading a signal related to the characteristic information of the fiber aggregate (2) Data related to the characteristic information of the fiber aggregate obtained from the sequentially read signal is sequentially associated with time data in the recording device of the information processing apparatus. Recording step (3) obtaining data relating to quality information of the fiber assembly from data relating to the property information of the fiber assembly recorded in association with the time data (4) data relating to the quality information of the fiber assembly (5) When the data relating to the quality information of the fiber assembly deviates from the reference value relating to the quality, (i) sending an alarm command signal to the alarm device, or (ii) a control command Sending the signal to the process controller   The program according to claim 1, further causing the information processing apparatus to execute a step of sending data relating to the characteristic information of the fiber assembly or data relating to the quality information to another information processing apparatus as a signal.   The program according to any one of claims 1 to 11, wherein the fiber assembly is a filter tow.

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