JP2004264144A - Detection method and detection device for thickness of nonwoven fabric, etc. - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for accurately detecting the thickness of all the regions of an inspecting object such as a nonwoven fabric without being affected by disturbance light or being affected by peripheral temperature change, and to provide a device optimum for executing this method. <P>SOLUTION: Infrared rays are irradiated to an inspecting object, which is moving, such as a nonwoven fabric, to measure the quantity of light transmitted by the object, the actual measurement of the transmitted light quantity is compared with a reference value previously housed in a storage means for the light quantity transmitted by the object, and the thicknesses of the object at its respective regions are detected from the result of the comparison. This device is equipped with a means for irradiating infrared rays to the moving object, a means for imaging light transmitted by the object, and a means for preparing a multiple-tone area image of the object by storing therein data on a multiple-tone line image successively outputted from the imaging means while calculating the thicknesses of the respective regions of the object by comparing the brightness of the multiple-tone area image of the object with that of a multiple-tone area image of a master image plane prepared from a reference value on the object previously housed in the storage means. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optimal detection method and an optimal detection device for detecting the thickness of all portions of an inspection object such as a nonwoven fabric or a thick paper having a large dynamic range of thickness.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there has been provided an apparatus which irradiates beta rays while moving an inspection object having a large dynamic range such as nonwoven fabric or paper and detects the thickness of the inspection object based on a transmission amount per unit area.
[0003]
However, this device has the drawback that it is not possible to detect the thickness of all parts of the test object because the radiation source must be moved in the direction crossing the running test object. There are drawbacks, such as poor installation and extremely high cost, such as strict installation conditions for use, requiring qualification of the operator, and the like.
[0004]
[Patent Document 1]
Japanese Patent Application Laid-Open No. H11-211647 (0007, FIG. 3)
[0005]
[Problems to be solved by the invention]
As a method for inexpensively and accurately detecting the thickness of an object to be inspected, such as a running nonwoven fabric, as shown in FIG. The inspection object is irradiated with light by a fluorescent lamp, the transmitted light amount of the inspection object is measured by a CCD line sensor or the like, the measured value is stored in a memory, and a reference value of the transmitted light amount of the inspection object stored in a storage means in advance is used. A method of comparing the measured values and detecting the thickness of each part of the inspection object from the comparison result can be considered.
[0006]
In this method, if the amount of transmitted light is measured correctly, as shown in Fig. 1, the thick part is concave because the amount of transmitted light is small, and the thinner part is observed as a convex graph because the amount of transmitted light is larger than it. Although the thickness of all parts of the test object can be accurately detected, as shown in FIG. 2, when a fluorescent lamp is used as a light source, the actual measurement value of the test object greatly fluctuates due to disturbance light. It is extremely difficult to obtain accurate measured values, and it is extremely difficult to obtain accurate measured values because the amount of irradiation changes due to changes in the internal gas pressure due to changes in the temperature of the fluorescent lamp during measurement, resulting in poor reliability. .
[0007]
Therefore, the present invention irradiates an object to be inspected such as a nonwoven fabric with light, measures the amount of transmitted light of the object to be inspected, and compares the measured value with a reference value of the amount of transmitted light of the object to be inspected. The thickness of each part of the test object is detected from the data, and the measured value of the test object is free from the influence of disturbance light. It is a main object of the present invention to provide a method capable of accurately detecting the thickness of all portions of a nonwoven fabric or the like without being affected by the influence, and a device optimal for performing the method.
[0008]
In addition, the present invention provides a method for preventing the object to be inspected such as nonwoven fabric or paper from burning or deteriorating due to heat from a light source when detecting the thickness of the object to be inspected. It is also an object to provide a device.
[0009]
[Means for Solving the Problems]
The technical means of the present invention for achieving the above object is to irradiate the entire width of the object to be inspected such as a running nonwoven fabric with infrared rays, measure the amount of transmitted light of the nonwoven fabric or the like as the object to be inspected, and calculate the measured value. The measured value is stored in the storage means, and the measured value is compared with a reference value of the transmitted light amount of the object stored in the storage means in advance, and the thickness of each part of the object is detected from the comparison result. It is.
[0010]
Further, another technical means of the present invention for achieving the above object is to prevent the temperature of the object to be inspected from rising when the object is irradiated with infrared rays. An infrared irradiation tube in which a space for heat insulation is arranged and an infrared irradiation source is linearly arranged is used to irradiate the entire width of the inspection object with infrared light.
[0011]
Another technical means of the present invention for achieving the above object is to compare the measured value of the transmitted light amount of the inspection object with the reference value of the transmitted light amount of the inspection object. By adding a threshold value to the reference value and comparing it with the measured value of the transmitted light amount of the inspection object, the type and position of defects such as adhesion of hair, insects, metal, and dirt and pinholes can be detected. It was made.
[0012]
Another technical means of the present invention for achieving the above object is to compare the measured value of the transmitted light amount of the object to be inspected with the reference value of the transmitted light amount of the inspected object to determine the density value. By additionally setting and comparing the measured value of the transmitted light amount of the object to be inspected, both the thickness and the density of each part of the object to be inspected are detected.
[0013]
Another technical means of the present invention for achieving the above object is to provide a thickness detecting device such as a nonwoven fabric with a means for irradiating infrared rays over the entire width of a running nonwoven fabric or the like, Means for imaging transmitted light, and storing multi-gradation line image data sequentially output from the imaging means to create a multi-gradation area image of the inspection object and multi-gradation of the inspection object Means for calculating the thickness of each part of the inspection object by comparing with the brightness of the multi-tone area image of the master screen created from the reference value of the inspection object stored in advance in the storage means, It is in.
[0014]
Further, another technical means of the present invention for achieving the above object is that in the above-mentioned thickness detecting device, a space for heat shielding is arranged in the tubular casing and the infrared irradiation source is linearly arranged. The infrared irradiation tube is arranged in the entire width direction of the inspection object.
[0015]
The term "reference value" used in this specification refers to not only the amount of transmitted light that can be known in advance by basis weight (weight per unit area of nonwoven fabric) and basis weight (weight per unit number of paper), but also It also includes the amount of transmitted light estimated when the amount of light is unknown. In other words, the estimated transmitted light amount is set as a temporary reference value, and the reference value is obtained by obtaining an actual measurement value and correcting and setting the temporary reference value.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an example of an embodiment of the present invention will be described with reference to FIG.
[0017]
As shown in FIG. 4, the non-woven fabric 1 to be inspected is wound on a reel 2. The nonwoven fabric 1 is fed and travels via a plurality of guide rollers 3, wound on a reel 4, or supplied to a slitter process. The nonwoven fabric 1 is adapted to pass through a pair of inspection rollers 5 at an appropriate position in the course of traveling. A CCD line sensor 6 is arranged so as to face one surface of the nonwoven fabric 1, and the other side of the nonwoven fabric 1 A light source 7 for transmitted illumination is arranged facing the CCD line sensor 6. Infrared light is used for transmitted illumination. The CCD line sensor 6 is a linear sensor, and an appropriate number of CCD line sensors 6 are installed along the width direction of the running nonwoven fabric 1, and the entire width of the running nonwoven fabric 1 is sequentially imaged. An infrared pass filter (not shown) is attached to the CCD line sensor 6, and detects only a wavelength of 700 nm or more.
[0018]
As shown in FIG. 6, the transmitted light source 7 is provided with a space for heat shielding in a frosted glass tubular casing 7a formed to have a length substantially coincident with the length of the woven fabric 1 in the width direction. The halogen lamps 7b are linearly arranged. The wavelength of the infrared light emitted from the transmitted illumination light source 7 can be appropriately set according to the material of the inspection object.
[0019]
A rotary encoder 8 is provided coaxially with the inspection roller 5 on the downstream side of the position of the CCD line sensor 6 in the running direction of the nonwoven fabric 1, and a labeling device 9 is provided on the downstream side thereof. The labeling device 9 attaches a label for indicating a defective portion to a side edge of a portion of the nonwoven fabric 1 where a defective portion such as adhesion of hair, insects, metal, etc., dirt, and pinholes exists on the guide roller 3. It is configured to be able to. The rotary encoder 8 generates a pulse each time the nonwoven fabric 1 travels for a predetermined length in order to detect the traveling amount of the nonwoven fabric 1. The processing unit 10 stores the multi-tone line image data sent from the CCD line sensor 6 in a memory and creates a multi-tone area image of the nonwoven fabric in this memory. It is used as a line feed signal when converting to multi-gradation line image data, and by counting the number of pulses, the timing at which a defective portion of the nonwoven fabric 1 imaged by the CCD line sensor 6 reaches the labeling device 9 is detected. The labeling device 9 is driven by the detection signal so that the label can be accurately attached to the side edge portion of the nonwoven fabric 1 where the defective portion exists.
[0020]
The data obtained by the processing unit 10 is transmitted to a personal computer, and the personal computer performs statistical processing, and records a history. A monitor TV (CRT) 11 is connected to the processing unit 10, and the multi-tone area image data of the defective portion of the nonwoven fabric 1 created by the processing unit 10 is displayed on the monitor TV 11 so that the processing of the defective portion of the nonwoven fabric 1 is performed. The final judgment can be made visually. In addition, by storing the image displayed on the monitor TV 11 in an appropriate storage medium, the defective portion can be specified again at a desired time such as when the nonwoven fabric 1 is wound.
[0021]
Next, the present invention will be described together with the operation of the above device.
[0022]
As shown in FIG. 4, the nonwoven fabric 1 to be inspected is unreeled from the reel 2, is run by the guide rollers 3, and is wound on the reel 4. During this traveling, the non-woven fabric 1 is irradiated by the light source 7 for transmitted illumination, and the transmitted light is sequentially imaged by the CCD line sensor 6 over the entire length in the width direction of the inspection object. The processing unit 10 stores data of a 256-gradation multi-gradation line image sequentially output from the CCD line sensor 6 and creates a multi-gradation area image using a pulse sent from the rotary encoder 8 as a line feed signal. I do. The brightness of each part of the multi-tone area image of the nonwoven fabric 1 is determined by using a reference value of the amount of transmitted light corresponding to the thickness of each part of the nonwoven fabric 1 stored in advance in a memory, and a master image created from this reference value. This is compared with the brightness of each corresponding part of the 256-tone multi-tone area image. In this way, by comparing the measured value of the transmitted light amount of the non-woven fabric 1 to be inspected with the reference value, it is determined whether each part of the non-woven fabric 1 to be inspected has a predetermined thickness, Detect deviation.
[0023]
As described above, since the amount of transmitted light is also related to the density of the nonwoven fabric 1, in this apparatus, a reference value of the density is added in advance in addition to the reference value of the thickness. The multi-tone area image is compared with the 256-tone multi-tone area image of the master image created from the thickness reference value and the density reference value, and the thickness detection and the density detection of the nonwoven fabric 1 are combined. I'm going. In general, the nonwoven fabric 1 and the paper are impregnated with a chemical or a fragrance, and the density of each nonwoven fabric 1 is extremely important. Therefore, it is advantageous to perform the density detection together.
[0024]
If metal adheres to the nonwoven fabric 1 to be inspected, the adhered portion does not transmit light, and if hair or insects adhere, the amount of transmitted light becomes lower than the reference value, and there are pinholes and cuts. And the amount of transmitted light is greater than the reference value. In this device, using this phenomenon, various threshold values are added to the reference value and compared with the measured value of the amount of transmitted light of the inspection object, so that hair, insects, metal, etc. The presence / absence, type, and location of defects such as pinholes, pinholes, and cuts are also detected. Further, in this apparatus, information on the XY dimensions of the defect is also detected.
[0025]
As described above, in the apparatus shown in the figure, the processing unit 10 replaces the data of the thickness of the nonwoven fabric 1 having the thickness determined for each lot with the brightness beforehand and stores the data, and uses this as a reference. Then, the actual thickness of the nonwoven fabric is detected by measuring the fluctuation of the thickness of each part of the nonwoven fabric 1 detected as the fluctuation of the amount of transmitted light, replacing this with the fluctuation of the lightness, and comparing the measured data with the reference. At the same time, the detection of density, the presence / absence and type and location of defects such as adhesion of hair, insects, metal, dirt, pinholes and cuts, and the XY dimensions of the defects are performed.
[0026]
The apparatus shown in the figure uses an infrared pass filter attached to the CCD line sensor 6 in addition to using infrared rays for transmitted illumination, thereby reducing the influence of disturbance light when actually measuring the thickness of the nonwoven fabric 1 to be inspected. In addition to eliminating the influence of temperature changes around the light source and the light source in the actual measurement of the nonwoven fabric 1 as the object to be inspected, the temperature rise around the infrared irradiation source, which is itself a heat source, is measured by infrared irradiation. By adopting a double tube structure of the source and the casing 7a, the temperature is prevented from rising above 100 ° C or more, so that the inspection object such as non-woven fabric or paper is not burned or deteriorated by the heat from the light source. It was made.
[0027]
In implementing the present invention, a method of comparing the reference value of the transmitted light amount with the actually measured value can be arbitrarily selected, whether it is a comparison in pixel units or a comparison of the area average of the area image.
[0028]
The embodiment of the present invention is not limited to the nonwoven fabric. As a preferred embodiment of the present invention, the detection of the thickness of a thick sheet of paper or the like having a large thickness dynamic range can be exemplified.
[0029]
【The invention's effect】
As described above, according to the present invention, an object to be inspected such as a nonwoven fabric is irradiated with infrared rays to measure the amount of transmitted light of the object to be inspected, and this measured value is compared with a reference value of the amount of transmitted light of the object to be inspected. The thickness of each part of the test object is detected based on the comparison result. The measured value of the test object is not affected by disturbance light, and the measured value of the test object is It is possible to accurately detect the thickness of all parts of the inspection object such as a nonwoven fabric without being affected by a temperature change around the light source.
[0030]
In addition, when detecting the thickness of the inspection object, a space for heat insulation is arranged in a casing formed to have a length substantially matching the width direction of the inspection object as a light source for transmitted illumination. If an appropriate number of double-tube structures with linearly arranged irradiation sources are used, the rise in the ambient temperature of the inspection object can be suppressed. Even if it is flammable, the test object can be prevented from burning or deteriorating. Even if the test object stops running due to interruption of detection work, etc., Does not burn.
[0031]
In addition, if a threshold value is added to the reference value of the thickness in advance, it is possible to determine not only the thickness of the inspection object but also the presence and type of defects such as adhesion of hair, insects, metal, etc. of the inspection object, dirt, and pinholes. The position can also be detected.
[0032]
Furthermore, if a density reference value is set in advance in addition to the thickness reference value, not only the thickness of the inspection object but also the density of the inspection object can be detected.
[Brief description of the drawings]
FIG. 1 is an explanatory view of a thickness detection state using a fluorescent lamp as a light source when there is no disturbance light, where a concave portion indicates a thick portion and a convex portion indicates a thin portion.
FIG. 2 is an explanatory diagram of a detection state when the same inspection object as in FIG. 1 is subjected to thickness detection in a state where disturbance light enters.
FIG. 3 is an explanatory diagram showing the relationship between the thickness of a nonwoven fabric and the amount of transmitted light in relation to the density of the nonwoven fabric. The solid line indicates high density, the dotted line indicates medium density, and the dashed line indicates low density.
FIG. 4 is an explanatory view showing an outline of an embodiment of the apparatus of the present invention.
FIG. 5 is a diagram illustrating the relationship between the wavelength of infrared rays and the sensitivity of a CCD line sensor. 1 indicates the sensitivity of the CCD line sensor, and 2 indicates the wavelength of the incident light of infrared rays.
FIG. 6 is a perspective view of a state in which a casing of an infrared irradiation source most suitable for carrying out the present invention is cut away.
FIG. 7 is an explanatory diagram of a change in irradiation light rate due to a change in ambient temperature in comparison with the infrared irradiation source and the fluorescent lamp in FIG. 6; The dotted line indicates the case of a fluorescent lamp, and the solid line indicates the case of the infrared irradiation source shown in FIG.
FIG. 8 is an explanatory diagram of a thickness detection state using the infrared irradiation source of FIG. 6, where a concave portion indicates a thick portion and a convex portion indicates a thin portion. As the inspection object, the one shown in FIG. 1 was also used.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Nonwoven fabric 2 Reel 3 Guide roller 4 Reel 5 Inspection roller 6 CCD line sensor 7 Transmitted illumination light source 7a Casing 7b Halogen lamp 8 Rotary encoder 9 Labeling device 10 Processing unit 11 Monitor TV

Claims (6)

The entire width of the object to be inspected such as a running non-woven fabric is irradiated with infrared rays, the transmitted light amount of the non-woven fabric or the like to be inspected is measured, and the measured value is stored in the storage means, and the measured value is stored in the storage means in advance. A thickness of each part of the inspection object is detected from the comparison result with a reference value of the amount of transmitted light of the inspection object. 2. The thickness of a nonwoven fabric or the like according to claim 1, wherein infrared rays are radiated to the entire width of the object to be inspected by an infrared irradiating tube in which a space for heat shielding is arranged in a tubular casing and an infrared irradiating source is linearly arranged. Detection method. A threshold value is added to the reference value of the transmitted light amount, and the measured value of the transmitted light amount of the inspection object is compared with the actual measured value of the transmitted light amount to detect defects such as adhesion of hair, insects, metal, etc., dirt, pinholes, and the position thereof. A method for detecting the thickness of a nonwoven fabric or the like according to claim 1 or 2. The thickness and density of each part of the object to be inspected are detected by adding a density value to the reference value of the amount of transmitted light and comparing the measured value with the measured value of the amount of transmitted light of the object. Item 3. The method for detecting a thickness of a nonwoven fabric or the like according to Item 3. A means for irradiating infrared light over the entire width of the object to be inspected such as a running nonwoven fabric, a means for imaging transmitted light of the object to be inspected, and storing multi-gradation line image data sequentially output from the imaging means. The multi-tone area image of the inspection object is created, and the multi-tone area image of the master screen created from the reference value of the inspection object stored in advance in the storage means. Means for calculating the thickness of each part of the inspection object in comparison with the brightness. 6. A means for irradiating infrared rays, wherein a suitable number of infrared ray irradiating tubes in which a space for heat shielding is arranged in a tubular casing and infrared ray irradiating sources are linearly arranged are arranged in the entire width direction of the inspection object. Detector for non-woven fabrics.

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