JP2017116479A - Inspection method of transported object - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inspection method of transported objects capable of detecting a positional relationship of inspection objects arranged in sheets being transported.SOLUTION: An inspection method of transported objects comprises: a first light radiation step for radiating a first radiation light L1 to a first sheet 51 and a first inspection object 61 from outside of the first sheet 51 in a state of inserting a reflection plate 21 between first and second sheets 51, 52; a second light radiation step for radiating a second radiation light L2 to the second sheet 52 and a second inspection object 62 from outside of the second sheet 52; a first light detection step for receiving a first reflection light Lr1 obtained by reflection of the first radiation light L1 on the reflection plate 21 and the first sheet 51, for detecting a light amount; a second light detection step for receiving a second reflection light Lr2 obtained by reflection of the second radiation light L2 on the reflection plate 21 and the second sheet 52, for detecting a light amount; and a position detection step for detecting positions of end parts of the first and second inspection objects 61, 62 in a width direction of the respective sheets 51, 52 based on the light amounts of the first and second reflection lights Lr1, Lr2.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a method for inspecting a conveyed object.

  There is an inspection method in which reflected light or transmitted light obtained by irradiating light on an inspection object is received by an optical sensor. In this inspection method, an inspection object is inspected using a light amount obtained by photoelectric conversion with light received by an optical sensor. For example, Patent Document 1 discloses that the first sensor detects both side edges of the web and generates position information indicating how much the web is biased in the width direction (paragraph [1] of Patent Document 1). 0021]).

JP 2003-38566 A

In the inspection apparatus described in Patent Literature 1, it is impossible to detect the mutual positional relationship between the inspection objects arranged opposite to each other in the folded sheet.
The present invention relates to a method for inspecting an object to be conveyed that makes it possible to detect a mutual positional relationship between objects to be inspected that are arranged opposite to each other in a sheet that is conveyed oppositely.

The present invention is a method for inspecting a transported object that detects the positions of first and second inspection objects disposed facing each of the light-transmitting first and second sheets that are transported facing each other. There,
A first light irradiation step of irradiating the first sheet and the first inspection object with first irradiation light from the outside of the first sheet, with a reflector inserted between the first and second sheets;
A second light irradiation step of irradiating the second sheet and the second inspection object with second irradiation light from the outside of the second sheet;
A first light detecting step of receiving the first reflected light obtained by the first irradiation light being reflected by the reflecting plate and the first sheet and detecting the amount of light;
A second light detection step of detecting the amount of light by receiving the second reflected light obtained by the second irradiation light reflected by the reflector and the second sheet;
A position detecting step for determining the positions of the end portions of the first and second inspection objects in the width direction of the sheets from the light amounts of the first and second reflected lights;
There is provided a method for inspecting a conveyed object.

  The method for inspecting an object to be conveyed according to the present invention makes it possible to detect the mutual positional relationship between inspection objects arranged opposite to each other in a sheet conveyed oppositely.

It is the block diagram which showed a preferable example of the inspection apparatus which enforces the to-be-conveyed object inspection method of this invention. (A) is sectional drawing which made the front-back direction of drawing the conveyance direction of a sheet | seat, (b) is a top view. (A) to (c) are partial cross-sectional views for explaining changes in the amount of light received by the sensor. It is the graph which showed an example of the calibration curve which calculates | requires the position of a 1st test target object from the light quantity calculated | required by light-receiving and photoelectrically converting with the 1st sensor part. (A) is the front view which showed an example of the arrangement | positioning state of the test target object with respect to a sheet | seat, (b) is the front view which showed the folded state of the sheet | seat. It is a related figure of the light transmittance of a spunlace nonwoven fabric using a polypropylene fiber, and basic weight. It is the fragmentary sectional view which showed the case where measurement of deviation | shift amount is impossible. In addition, illustration of the sheet | seat 50 which permeate | transmits the irradiation light shown in FIG. 1 etc. is abbreviate | omitted. It is the block diagram which showed the preferable example of the inspection apparatus which enforces the inspection method of another to-be-conveyed object.

  A preferred embodiment of a method for inspecting a conveyed object according to the present invention will be described below with reference to the drawings. First, a preferred example of a non-conveyed object to be inspected using the inspection method of the object to be conveyed and an inspection apparatus that performs the inspection method will be described with reference to FIG.

As shown in FIG. 1, the transported object 1 includes a light-transmitting sheet 50 folded in half, and light-impermeable first and second inspection objects 61 and 62 disposed on the sheet 50. . The light transmission means that first and second irradiation lights L1 and L2, which will be described later, pass through the sheet 50, are reflected by the reflecting plate 21, and pass through the sheet 50 again. The light impermeability means that the first and second irradiation objects L1 and L2 irradiated on the first and second inspection objects 61 and 62 have surface reflection, but the remaining irradiation light is absorbed. .
The sheet 50 preferably transmits light having a wavelength of 500 nm or more and 800 nm or less, and has two layers of a top sheet 50A and a back sheet 50B. One of the two-layered sheet 50 that is folded in half is a first sheet 51, and the other is a second sheet 52. The first sheet 51 and the second sheet 52 are conveyed in a state of facing each other. For example, the width direction end portion 51A of the first sheet 51 and the width direction end portion 52A of the second sheet 52 are arranged on the upper end side so that the bi-fold end portion 50C of the sheet 50 is arranged on the lower end side. Has been. The double-folded end portion 50C of the sheet 50 may be conveyed with the up-down direction reversed.
In the first sheet 51, a first inspection object 61 is disposed between the top sheet 50A and the back sheet 50B. A second inspection object 62 is disposed on the second sheet 52 between the top sheet 50A and the back sheet 50B. The first inspection object 61 and the second inspection object 62 are positioned so as to face each other. That is, it is preferable that the upper end portions 61A and 62A of the first and second inspection objects 61 and 62 have the same height in the sheet width direction.

  The transported object inspection apparatus 10 includes a first light irradiation unit 11 that irradiates the first sheet 51 and the first inspection target 61 with the first irradiation light L <b> 1 outside the first sheet 51. Outside the second sheet 52, a second light irradiation unit 12 that irradiates the second sheet 52 and the second inspection object 62 with the second irradiation light L2 is provided. The first irradiation light L1 is irradiated so as to include the upper end portion 61A of the first inspection object 61, and the second irradiation light L2 is included so as to include the upper end portion 62A of the second inspection object 62. Further, outside the first sheet 51, light from the first sheet 51 and the first inspection object 61 illuminated by the first irradiation light L1 is received at a position where the optical path of the first irradiation light L1 is not blocked. A first sensor unit 31 is provided. On the outside of the second sheet 52, a second light that receives light from the second sheet 52 and the second inspection object 62 illuminated by the second irradiation light L2 at a position that does not block the optical path of the second irradiation light L2. A sensor unit 32 is provided. Further, a reflecting plate 21 having both surfaces as reflecting surfaces is provided between the first sheet 51 and the second sheet 52.

Hereinafter, each component will be described in detail.
The first and second light irradiation units 11 and 12 irradiate the first and second irradiation lights L1 and L2 linearly in the width direction of the first and second sheets 51 and 52, respectively. For example, irradiation is performed around the upper end portions 61A and 62A of the first and second inspection objects 61 and 62 including the sheet 50. As the first and second irradiation lights L1 and L2, light having a wavelength of 500 nm or more and 800 nm or less is used from the viewpoint of suppressing the influence of reflection on the surface of the sheet 50 and facilitating transmission.

The first and second light irradiation units 11 and 12 are arranged with a plurality of light emitting elements (not shown) so that the first and second irradiation lights L1 and L2 are evenly irradiated. The arrangement may be a single row, preferably a plurality of rows. Furthermore, in order to obtain illumination light with uniform illuminance without unevenness, it is preferable that a reflecting plate is disposed on the side surface on which the light emitting element is disposed. The illuminance need only be equal to or greater than the illuminance at which reflected light can be obtained, and is preferably equal to or less than the illuminance at which the amount of received light is not reached, depending on the sensitivity of the light receiving element.
The first and second irradiation lights L1 and L2 have a wavelength of 500 nm or more, preferably a wavelength of 600 nm or more, and more preferably a wavelength of 650 nm or more. And a wavelength is 800 nm or less, Preferably a wavelength is 750 nm or less, More preferably, a wavelength is 700 nm or less. Specifically, the wavelength is 500 nm or more and 800 nm or less, preferably the wavelength is 600 nm or more and 750 nm or less, and more preferably the wavelength is 650 nm or more and 700 nm or less. If the wavelength is too short, the irradiated light will not easily pass through the sheet 50. On the other hand, if the wavelength is too long, the irradiation position cannot be seen, and the alignment of the irradiation light cannot be easily performed.
For the first and second light irradiation units 11 and 12, it is preferable to use, for example, semiconductor laser light having a wavelength of 660 nm for the first and second irradiation light L1 and L2. In the present specification, the emission wavelengths of the first and second irradiation lights L1 and L2 are peak wavelengths at which the light intensity is the strongest.

The illuminance of the first and second irradiation lights L1 and L2 is preferably 1 lx or more, and more preferably 4 lx or more. And 7 lx or less is preferable. Specifically, 1 lx or more and 7 lx or less is preferable, and 4 lx or more and 7 lx or less is more preferable. When the illuminance is too strong, the light receiving element exceeds the saturated light receiving amount, and photoelectric conversion cannot be performed in the light receiving element. On the other hand, if the illuminance is too weak, photoelectric conversion does not occur and light cannot be detected. The illuminance is the illuminance at the position where the sheet 50 is first irradiated.
The illuminance is appropriately adjusted by the irradiation distance D of the first and second irradiation lights L1 and L2. When the irradiation distance D is short, the illuminance is lowered, and when the irradiation distance D is long, the illuminance is increased. The irradiation distance D is determined by the first and second light irradiation units 11 and 12 on the optical axes C1 and C2 of the first and second irradiation light L1 and L2 emitted from the first and second light irradiation units 11 and 12, respectively. The distance between the injection end of the sheet and the surface of the sheet 50. Further, it is preferable to irradiate the surface of the sheet 50 so that the optical axes of the first and second irradiation lights L1 and L2 are perpendicular to the irradiation surface, for example. The illuminance was measured using a commercially available illuminometer. Specifically, a digital illuminometer T-1H manufactured by Minolta Co., Ltd. was used.

It is preferable that the reflecting plate 21 has a size that includes the entire irradiation surface on which the first and second irradiation lights L1 and L2 are irradiated to the reflecting plate 21.
The thickness of the reflecting plate 21 is preferably a thickness that allows insertion of the reflecting plate 21 without contacting the first and second sheets 51 and 52 to be conveyed. For example, 2 mm or more is preferable, 4 mm or more is more preferable, and 5 mm or more is more preferable from the viewpoint of ensuring rigidity. And from a viewpoint of avoiding a contact with the 1st, 2nd sheet | seats 51 and 52, 10 mm or less is preferable, 8 mm or less is more preferable, and 6 mm or less is further more preferable. Specifically, 2 mm or more and 10 mm or less are preferable, 4 mm or more and 8 mm or less are more preferable, and 5 mm or more and 6 mm or less are more preferable.
The reflecting plate 21 is preferably a plate material that reflects the first and second irradiation lights L1 and L2 on both sides. Examples of the plate material include resin and metal. Examples of the resin include polyamide resin, fluorine resin, polyacetal resin, and the like. Specific examples include polyamide resins, fluorine resins, and polyacetal resins, such as MC nylon (registered trademark), Teflon (registered trademark), Duracon (registered trademark), and the like.
In the case of a plate material, the surface is preferably mirror-finished. Alternatively, it is also preferable to use a plate material provided with a reflection film coating on both sides to increase the reflectance.

  The 1st, 2nd sensor parts 31 and 32 may be adjoined to the 1st and 2nd irradiation parts 11 and 12 mentioned above, or may be arranged separately. It suffices if it is arranged at a position where it can receive the reflected and transmitted light. The first and second sensor units 31 and 32 are preferably photoelectric conversion elements that can receive light having the wavelengths of the first and second irradiation lights L1 and L2. For example, a photodiode that can receive light with a wavelength of 500 nm to 800 nm can be used as the photoelectric conversion element.

  The first and second sensor units 31 and 32 are preferably connected to a signal processing unit (not shown) that processes an electrical signal obtained by receiving light and performing photoelectric conversion. The signal processing unit receives and stores the electrical signal photoelectrically converted by the first and second sensor units 31 and 32. The signal processing unit preferably has a function of amplifying an electric signal, a function of removing noise, and the like.

In the signal processing unit, the amount of light is obtained from the electrical signals of the inspection areas photoelectrically converted by the first and second sensor units 31 and 32, and the displacement amounts of the first and second inspection objects 61 and 62 are calculated.
For this purpose, a calibration curve for calculating the position of the first inspection object 61 by the amount of light is obtained in advance.
The first reflected light Lr1 received by the first sensor unit 31 is a case where the entire irradiation area of the first irradiation light L1 is an area that does not include the first inspection object 61 of the first sheet 51 (FIG. 2A). )), The reflected light Lr1 reflected by the reflecting plate 21 has the largest amount of light. This state corresponds to the state of the light amount 100 of the calibration curve described later.
As the area of the area of the first sheet 51 that overlaps the first inspection object 61 in the irradiation area of the first irradiation light L1 decreases (see FIG. 2B), the amount of light is proportional to the area reduction. Will increase. In other words, as the area where the first inspection object 61 overlaps the irradiation region of the first irradiation light L1 increases, the amount of the first reflected light Lr1 decreases in proportion to the increase in area. This state corresponds to an intermediate state between the light amounts 50 to 100 of the calibration curve described later.
When the entire irradiation region of the first irradiation light L1 on the first sheet 51 overlaps the region of the first sheet 51 on which the first inspection object 61 is arranged (see FIG. 2C), the first Since it is absorbed by the inspection object 61, the first reflected light Lr1 has the least amount of light. This state corresponds to the state of the light amount 50 of the calibration curve described later. That is, the light amount of the calibration curve is a relative light amount where 100 is the light amount where the reflected light Lr1 is the largest and 50 is the light amount where the reflected light Lr1 is the smallest.

By obtaining the light quantity of the first reflected light Lr1 in each of the above cases, the relationship between the reflected light quantity and the distance from the reference position as shown in FIG. 3 is obtained by the first calibration curve. The distance from the reference position refers to the distance P1 from the position of the upper end P0 of the irradiation light L1 to the upper end 61A of the first inspection object 61. In addition, when the measurement value of light quantity has a dispersion | variation, it is preferable to approximate to a linear function by the least squares method etc.
Here, the distance from the minimum light amount to the maximum light amount is the width W in the sheet width direction of the irradiation region when the first irradiation light L1 is irradiated onto the surface of the sheet 50. The unit of the width W is, for example, mm. For example, the optical axis C (C1) of the first irradiation light L1 is set to be perpendicular to the surface of the reflecting plate 21. In addition, the irradiation angle of the first irradiation light L1 may be inclined so that the first sensor unit 31 can receive more reflected light. That is, you may arrange | position the 1st light irradiation part 11 so that the optical axis C may incline. The same applies to the second light irradiation unit 12 as in the first light irradiation unit 11.

A second calibration curve (not shown) for calculating the position of the second inspection object 62 based on the amount of the second reflected light Lr2 can also be obtained in the same manner as the first calibration curve. That is, the relationship between the amount of reflected light and the distance from the reference position is obtained by the second calibration curve. The distance from the reference position refers to the distance P2 from the upper end P0 position of the irradiation light L2 to the upper end 62A of the first inspection object 62. In addition, when the measurement value of light quantity has a dispersion | variation, it is preferable to approximate to a linear function by the least squares method etc.
Thus, by obtaining a calibration curve for each of the first and second sensor units 31 and 32, a calibration curve corresponding to each of the first and second sensor units 31 and 32 is obtained. Thereby, the distances P1 and P2 indicating the positions of the upper ends 61A and 62A of the first and second inspection objects 61 and 62 can be obtained more accurately. The unit of P1 and P2 is, for example, mm.

Next, a preferable example of the method for inspecting a conveyed object according to the present invention will be described.
The inspection method of the conveyed object is performed using the inspection apparatus 10 described with reference to FIG.
As shown in FIG. 4A, the conveyed object 1 includes a light-transmitting sheet 50 and first and second inspection objects 61 and 62 arranged in the width direction thereof. A plurality of first and second inspection objects 61 and 62 are arranged in the longitudinal direction (conveying direction) of the sheet 50. As shown in FIG. 4B, the width direction of such a sheet 50 is folded in half along the longitudinal direction.

For example, the sheet 50 is made of a light-transmitting nonwoven fabric made of fibers such as polyethylene, polyethylene terephthalate, and polypropylene. Specifically, a nonwoven fabric that transmits light having a wavelength of 500 nm to 800 nm is used.
Usually, when visible light is irradiated to a nonwoven fabric, the light which permeate | transmits a nonwoven fabric by repeating the reflection on the fiber surface which comprises a nonwoven fabric, and the passage of the clearance gap between fibers, and a part of light which permeate | transmits the nonwoven fabric inside a fiber. There is light that passes through the nonwoven. In short, the light irradiated to the nonwoven fabric is a complex combination of light that passes through the fiber, light that is reflected from the fiber surface, and light that travels between the fibers. Transparent in the direction. Other light is reflected and scattered by the fiber surface and absorbed into the fiber. Further, when the basis weight of the nonwoven fabric is small, there is light that passes straight through between the fibers. Therefore, the nonwoven fabric normally transmits visible light unless the basis weight becomes too large. When the basis weight becomes too large, reflection on the fiber surface increases, the amount of transmitted light decreases, and the light transmittance decreases extremely. Even if the light transmission amount decreases, it is possible to carry out the inspection method of the conveyed object, but the inspection accuracy may be reduced due to noise or the like. Therefore, the basis weight of the sheet 50 made of nonwoven fabric preferably has an upper limit. The basis weight of the sheet 50 will be described later.

Moreover, it is preferable that the fiber used for a nonwoven fabric has transparency. The transparent fiber transmits visible light having a wavelength of 380 nm to 800 nm. “Having transparency” means translucent, and that some of the visible light irradiated from the front side is reflected on the surface and has internal absorption, but part of it is transmitted to the back side. For example, the light transmission property of polyethylene in the visible light region is described on page 3 of the technical document GX-27e “Neofluon Film” of Daikin Industries, Ltd. In this graph of light transmission characteristics, light transmittance from a wavelength of 200 nm to 800 nm is described as the light transmission characteristics of a polyethylene film having a thickness of 25 μm. In this case, the light transmittance in the visible light region is 85% or more. The technical document GX-27e can be searched on the Internet at www.daikin.co.jp/chm/products/pdf/catalog/GX-27e.pdf (search date: December 21, 2015).
In addition, the light transmission characteristics of polyethylene terephthalate in the visible light region are described in, for example, a graph searched on the Internet http://www.zeon.co.jp/business/enterprise/speplast/optes2_1.html (search Sun: December 21, 2015). According to the graph of the light transmission characteristics, the light transmittance from a wavelength of 300 nm to 800 nm is described in the graph as the light transmission characteristics of a polyethylene terephthalate film having a thickness of 100 μm. In this case, the light transmittance in the visible light region is 80% or more.

An example of the relationship between the basis weight of the nonwoven fabric and the light transmittance was examined. For the measurement of the light transmittance, a spunlace nonwoven fabric made of polypropylene fibers having a basis weight of 80 g / cm ² was used. In addition, nonwoven fabrics having various basis weights were obtained by overlapping the nonwoven fabrics. Therefore, when the nonwoven fabric is not present, the basis weight is 0 g / cm ^2. By increasing the number of nonwoven fabrics, the nonwoven fabric has various basis weights ranging from 80 g / cm ² to 800 g / cm ² . And the light transmittance was measured about the nonwoven fabric of each basic weight. As the measurement light, a semiconductor laser light having a wavelength of 660 nm was used. Details of the light transmittance measurement method will be described later.
The results will be described with reference to FIG. FIG. 5 shows light transmittance on the vertical axis and basis weight on the horizontal axis.
As shown in FIG. 5, the basis weight increased and the light transmittance decreased rapidly, but light transmission was recognized even when the basis weight was 800 g / cm ² . From this, it was found that the measurement light is at least transmitted through the nonwoven fabric.

The basis weight of the nonwoven fabric, as the strength of the sheet is maintained, preferably 10 g / ^{m 2} or more, 30 g / ^{m 2} or more preferably, 50 g / ^{m 2} or more is more preferable. Then, 200 g / m ² or less is preferable, 150 g / m ² or less is more preferable, and 100 g / m ² or less is preferable so that light having a wavelength of 500 nm to 800 nm is transmitted and reflected light of the transmitted light is transmitted again. Further preferred. For example, the basis weight of the sheet 50 is set to 70 g / m ² to 80 g / m ² .
Specifically, as an example, a polypropylene spunlace nonwoven fabric having a basis weight of 80 g / m ² is used for the topsheet 50A. Further, a polypropylene spunlace nonwoven fabric having a basis weight of 70 g / m ² is used for the back sheet 50B. In addition, as a nonwoven fabric, you may use nonwoven fabrics other than a spunlace nonwoven fabric. For example, an air-through nonwoven fabric, a needle punched nonwoven fabric, a spunbond nonwoven fabric, a melt blown nonwoven fabric and the like can be preferably used.
The transmittance of light having a wavelength of 660 nm of the topsheet 50A made of a spunlace nonwoven fabric of polypropylene having a basis weight of 80 g / m ² and a thickness of 0.66 mm was 9.0%. Moreover, the transmittance | permeability of the light of wavelength 660nm of the back surface sheet 50B which consists of a spunlace nonwoven fabric of the said basis weight 70g / m < ² >, thickness 0.59mm was 20.0%. Thus, even if it is a nonwoven fabric state, it turns out that the sheet | seat 50 fully permeate | transmits said light.

The thickness of the nonwoven fabric was measured as follows.
It measured using the thickness measuring device in the state which applied the load so that the pressure of 0.05 kPa might be applied. A laser displacement meter manufactured by OMRON Corporation was used as the thickness measuring instrument. The thickness was measured at 10 points, and the average value was calculated as the thickness.

The light transmittance was measured as follows.
A transmission sensor manufactured by Keyence Corporation, model: LV-NH110 was used for the measuring instrument. The oscillation wavelength of the semiconductor laser light of this transmission sensor is 660 nm. Moreover, the model: LV-N11N made from Keyence Corporation was used for the amplifier. The distance between the light emitting head and the light receiving head of the sensor is set to 200 mm, and the light transmittance is measured so that the distance from the light emitting portion, which is the intermediate portion, is 100 mm and is perpendicular to the optical axis. A non-woven fabric was arranged. The transmittance was measured by irradiating a 0.2 mW laser beam having a wavelength of 660 nm and measuring the amount of transmitted light. Moreover, the irradiation light quantity was measured in the state which does not distribute a nonwoven fabric. The transmittance was determined using the formula [transmitted light amount] / [irradiated light amount] × 100 (%).

  The inspection objects 61 and 62 are light-impermeable. Light impermeability means that light is not transmitted at all, and irradiation light other than surface reflection is absorbed. Examples of such inspection objects 61 and 62 include a heating element packaged using a polyethylene (PE) stretched film containing calcium carbonate or a polyethylene paper laminate film. The heating element absorbs the first and second irradiation lights L1 and L2, but does not transmit it. The heating element includes a metal compound having a black color or a color close to black, such as iron chloride or iron oxide.

  As shown in FIG. 1, the 1st, 2nd light irradiation parts 11 and 12 are distribute | arranged so that it may mutually correspond on the line | wire which extended each optical axis C1 and C2. For the first and second light irradiation units 11 and 12, for example, light having a wavelength of 660 nm is used as the first and second irradiation lights L1 and L2. As the first and second irradiation lights L1 and L2, it is also possible to use light having other wavelengths described above having a wavelength of 500 nm to 800 nm. The first and second irradiation lights L <b> 1 and L <b> 2 have a vertically long irradiation region that is long in the width direction of the sheet 50. For example, the width W of the irradiation region (the length of the irradiation region in the vertical direction of the drawing) is 30 mm, and the length of the irradiation region in the direction orthogonal to the width direction of the irradiation region (the length of the irradiation region in the depth direction of the drawing) is 2 mm. is there. The longitudinal direction is a direction parallel to the width direction of the sheet 50. The irradiation distance D (D1, D2) between the first and second light irradiation units 11, 12 and the sheet 50 is 60 mm. The irradiation distance D is appropriately selected according to the areas of the irradiation regions of the first and second irradiation lights L1 and L2 and the light amounts of the first and second irradiation lights L1 and L2.

The reflection plate 21 described above is inserted between the first and second sheets 51 and 52. First and second light irradiation steps of irradiating the first and second light irradiation portions L1 and L2 from the first and second light irradiation portions 11 and 12, respectively, are performed.
In the first light irradiation step, the first irradiation light L <b> 1 emitted from the first irradiation unit 31 is irradiated to the first sheet 51 and the first inspection object 61 from the outside of the first sheet 51. The outer side of the first sheet 51 refers to the side opposite to the second sheet 52 side.
Subsequently, a first light detection step is performed. In this light detection step, a part of the irradiated first irradiation light L1 is reflected on the surface of the first sheet 51 and the surface of the first inspection object 61. The remaining first irradiation light L1 passes through the first sheet 51 excluding the portion where the first inspection object 61 is disposed, and is applied to the reflecting plate 21. On the reflecting plate 21, the irradiated first irradiation light L <b> 1 is reflected and passes through the first sheet 51 again. These reflected lights are received by the first sensor unit 31 as the first reflected light Lr1.
Note that, in the drawings, the arrows indicating light indicate that the reflected light passes on the same optical path with respect to the vertically incident irradiation light, but is slightly shifted for easy understanding.

On the other hand, in the second light irradiation step, the second sheet 52 and the second inspection object 62 are irradiated from the outside of the second sheet 52 with the second irradiation light L <b> 2 emitted from the second irradiation unit 32. The outside of the second sheet 52 refers to the side opposite to the first sheet 51 side.
The second light irradiation step is preferably performed simultaneously with the first light irradiation step. By carrying out simultaneously, the position of the 1st, 2nd test object 61 and 62 which opposes on both sides of the reflecting plate 21 can be detected more correctly.
Subsequently, a second light detection step is performed. In this light detection step, a part of the irradiated second irradiation light L2 is reflected on the surface of the second sheet 52 and the surface of the second inspection object 62. The remaining second irradiation light L2 passes through the second sheet 52 excluding the portion where the second inspection object 62 is disposed, and is applied to the reflecting plate 21. The reflected second irradiation light L <b> 2 is reflected on the reflection plate 21 and passes through the second sheet 52 again. These reflected lights are received by the second sensor unit 32 as the second reflected light Lr2.
Note that the first and second inspection objects 61 and 62 are absorbed by the first and second inspection objects 61 and 62 except that the first and second irradiation lights L1 and L2 irradiated on the first and second inspection objects 61 and 62 are reflected on the surfaces thereof. Is done. The light absorption of the first and second sheets 51 and 52 is omitted because it is slight.

Subsequently, in the position detection step, the first and second reflected light Lr1 and Lr2 are photoelectrically converted by the first and second sensor units 31 and 32, and the respective current values obtained by photoelectric conversion in the signal processing unit are used. Find the amount of light. Further, distances P1 and P2 indicating the positions of the first and second inspection objects 61 and 62 are obtained from the respective light amounts based on the calibration curve obtained in advance. If P1 = P2, there is no displacement of the first and second inspection objects 61 and 62. If P1> P2, the first inspection object 61 is positioned lower than the second inspection object 62. Conversely, if P1 <P2, the first inspection object 61 is at a higher position than the second inspection object 62. It can be seen that the first and second inspection objects 61 and 62 are displaced in both cases of P1> P2 and P1 <P2. The unit of P1 and P2 is, for example, mm.
The upper ends of the first and second irradiation lights L1 and L2 are set as a position 0, and the lower ends of the first and second irradiation lights L1 and L2 are set as a position PW. Therefore, the width W of the irradiation light is from position 0 to PW. The distances P1 and P2 are distances from the reference position P0 (position 0) to the upper ends 61A and 62A of the first and second inspection objects 61 and 62.

In the above inspection method, there are cases where the positions of the first and second inspection objects 61 and 62 cannot be detected. For example, as shown in FIG. 6A, the entire irradiation area of the first and second irradiation lights L1 and L2 does not extend over the upper ends 61A and 62A of the first and second inspection objects 61 and 62, This is a case where the first and second inspection objects 61 and 62 are obtained. As shown in FIG. 6B, the entire area of one of the first and second irradiation lights L1 and L2 becomes the first and second inspection objects 61 and 62 to be inspected by the irradiation light. is there. In the illustrated example, the entire irradiation region of the first irradiation light L <b> 1 is the first inspection object 61. Further, as shown in FIG. 6C, the first and second inspection objects 61 and 62 are not irradiated over the entire irradiation area of the first and second irradiation lights L1 and L2. Further, as shown in FIG. 6D, the first and second inspection objects 61 and 62 in which the entire irradiation area of one of the first and second irradiation lights L1 and L2 is inspected by the irradiation light are irradiated. If not. In the illustrated example, the entire irradiation region of the first irradiation light L1 is not irradiated to the first inspection object 61.
In such a case, the position detection of the first and second inspection objects 61 and 62 becomes impossible. Therefore, the first and second irradiation lights L1 and L2 need to be irradiated to the boundary portion between the sheet 50 and the first and second inspection objects 61 and 62.

In the inspection method for the object to be conveyed, the positions of the first and second inspection objects 61 and 62 arranged opposite to each other in the first and second sheets 51 and 52 conveyed opposite to each other. It becomes possible to detect the relationship. Accordingly, the positions of the first and second inspection objects 61 and 62 can be inspected while the sheet 50 is being conveyed, so that efficient inspection can be performed without stopping the production line.
The first and second irradiation lights L1 and L2 are light having a long length in the width direction of the sheet 50, but may be light having a long length in the conveyance direction of the sheet 50. In this case, the first and second irradiation lights L1 and L2 are irradiated so as to cross the boundary between the sheet 50 and the first and second inspection objects 61 and 62. Thus, the positional relationship between the first and second inspection objects 61 and 62 and the other first and second inspection objects 61 and 62 adjacent to each other in the sheet conveyance direction can be detected.

Moreover, the inclination of each inspection object can be calculated | required by calculating | requiring the position of each 2 points | pieces of the 1st inspection object 61 and the 2nd inspection object 62. For example, a position P1 from the reference point in the sheet width direction of point A on the upper side of the first inspection object 61 and a position P3 (not shown) from the reference point in the sheet width direction of point B are set. If P1-P3 = 0, the first inspection object 61 is not tilted. However, it is assumed that any of the above reference points is on one line parallel to the horizontal line, and the upper side of the inspection object is parallel to the horizontal line. If P1-P2 ≠ 0, it is tilted. The tilt angle can be easily calculated from the difference Dp between P1 and P2 and the difference Dp between the distances P1 and P2. The inclination angle starting from point A is tan ⁻¹ {(P1−P2) / Dp}.

  In the above inspection method, the case where the folded sheet 50 is conveyed in the vertical direction has been described. In this inspection method, it is possible to inspect in the same manner as described above even when the folded sheet 50 is transported in the horizontal direction. In this case, the entire inspection apparatus 10 is inspected in a state rotated by 90 degrees.

Next, another inspection method of the present invention will be described below.
As shown in FIG. 7, the sheet 50 preferably transmits light having a wavelength of 500 nm or more and 800 nm or less, and has two layers, a top sheet 50A and a back sheet 50B. The first sheet 51 on one side and the second sheet 52 on the other side of the folded sheet 50 are conveyed while maintaining an opposed state. For example, the width direction end portion 51A of the first sheet 51 and the width direction end portion 52A of the second sheet 52 are arranged on the upper end side so that the bi-fold end portion 50C of the sheet 50 is arranged on the lower end side. Has been. The folded sheet 50 to be conveyed may have the up and down direction reversed in the width direction.
In the first sheet 51, a first inspection object 61 is disposed between the top sheet 50A and the back sheet 50B. A second inspection object 62 is disposed on the second sheet 52 between the top sheet 50A and the back sheet 50B. The first inspection object 61 and the second inspection object 62 are positioned so as to face each other.

A light emitting unit 25 that emits light in a symmetrical direction from both sides is inserted between the first and second sheets 51 and 52. The light emitting unit 25 may be in the same direction as the width direction of the sheet 50 and may emit light linearly. First, the 1st light irradiation process which irradiates the 1st irradiation light L1 to the 1st sheet | seat 51 and the 1st test object 61 from one surface of the light emission part 25 is performed. At the same time, a second light irradiation step of irradiating the second irradiation light L2 to the second sheet 52 and the second inspection object 62 from the other surface of the light emitting unit 25 is performed.
Then, the 1st light detection process which light-receives the 1st transmitted light Lt1 which the 1st irradiation light L1 permeate | transmitted the 1st sheet | seat 51 by the 1st sensor part 31, and detects a light quantity is performed. At the same time, a second light detection step of detecting the amount of light by receiving the second transmitted light Lt2 transmitted through the second sheet 52 by the second sensor light 32 is performed.
Next, a position detection process is performed for determining the positions of the end portions 61A and 62A of the first and second inspection objects 61 and 62 in the width direction of each sheet from the light amounts of the first and second transmitted lights Lt1 and Lt2. The position detection process is the same as the above-described position detection process.

  The other inspection method is a method for detecting the positions of the first and second inspection objects 61 and 62 by detecting the transmitted light of the first and second irradiation lights L1 and L2, and the inspection method is simple. is there.

  Hereinafter, the present invention will be described in more detail with reference to an example in which a transported object is inspected by the above-described inspection method of a transported object. The present invention is not limited to the following examples.

(Example)
Based on the calibration curve, the end positions of the first and second inspection objects 61 and 62 (for example, heating elements) are calculated from the reference positions from the reflected light amounts on the first sheet 51 side and the second sheet 52 side, respectively. The deviation (mm) of the heating element is calculated from the calculated difference | P1-P2 | of each position.

<Inspection device>
The inspection was performed using the inspection apparatus 10 shown in FIG. For the first and second light irradiating units 11 and 12 and the first and second sensor units 31 and 32, a model of a reflection feedback sensor manufactured by Keyence Corporation: LV-NH42 was used. The oscillation wavelength of this semiconductor laser light is 660 nm.
For the signal processing unit, model LV-N11MN manufactured by Keyence Corporation was used.

<Inspection conditions>
The optical axes of the first and second irradiation lights L1 and L2 were set in a direction perpendicular to the irradiation surface, and the irradiation distance D was set to 60 mm.

  As a result of the inspection, in the example, the positions of the first and second inspection objects 61 and 62 could be accurately detected. As a result, the shift amount of the first and second inspection objects 61 and 62 could be accurately measured.

DESCRIPTION OF SYMBOLS 1 Conveyed object 10 Inspection apparatus 11 1st light irradiation part 12 2nd light irradiation part 21 Reflector plate 25 Light emission part 31 1st sensor part 32 2nd sensor part 50 Sheet 50A Top sheet 50B Back surface sheet 50C Folded end part of sheet 51 1st sheet 51A The width direction edge part of the 1st sheet 52 2nd sheet 52A The width direction edge part of the 2nd sheet 61 1st inspection object 61A The upper end part of the 1st inspection object 62 2nd inspection object 62A 2nd Upper end portion of inspection object C, C1, C2 Optical axis D, D1, D2 Irradiation distance L1 First irradiation light L2 Second irradiation light Lr1 First reflected light Lr2 Second reflected light Lt1 First transmitted light Lt2 Second transmitted light W Width of irradiation area P1, P2 Distance from reference position

Claims (7)

A method for inspecting an object to be conveyed that detects the positions of first and second inspection objects arranged opposite to each of the first and second light-transmitting sheets conveyed oppositely,
A first light irradiation step of irradiating the first sheet and the first inspection object with first irradiation light from the outside of the first sheet, with a reflector inserted between the first and second sheets;
A second light irradiation step of irradiating the second sheet and the second inspection object with second irradiation light from the outside of the second sheet;
A first light detecting step of receiving the first reflected light obtained by the first irradiation light being reflected by the reflecting plate and the first sheet and detecting the amount of light;
A second light detection step of detecting the amount of light by receiving the second reflected light obtained by the second irradiation light reflected by the reflector and the second sheet;
A position detecting step for determining the positions of the end portions of the first and second inspection objects in the width direction of the sheets from the light amounts of the first and second reflected lights;
A method for inspecting an object to be conveyed.   The inspection method of the conveyed object according to claim 1, wherein wavelengths of the first irradiation light and the second irradiation light are 500 nm or more and 800 nm or less.   The first sheet and the second sheet are composed of one sheet, the one sheet is folded at the center in the width direction, one folded sheet is the first sheet, and the other folded sheet is the above-described sheet. The method for inspecting a conveyed object according to claim 1, wherein the second sheet is a second sheet.   The inspection method of the conveyed object of any one of Claim 1 to 3 which performs the said 1st light irradiation process and the said 2nd light irradiation process simultaneously.   The said inspection target object is light-impermeable, The inspection method of the conveyed product of any one of Claim 1 to 4.   In the position detection step, a calibration curve is obtained in advance from the relationship between the position of the inspection object with respect to the width direction of the sheet and the amount of reflected light at the position, and the light amount of the measured reflected light is used to determine the calibration curve. The method for inspecting a conveyed object according to claim 1, wherein the position of the inspection object is obtained based on a calibration curve. Inspection of the object to be conveyed for detecting the positions of the light-impermeable first and second inspection objects arranged opposite to each of the light-transmitting first sheet and the second sheet conveyed opposite to each other A method,
A first light irradiating step of irradiating the first sheet and the first object to be inspected with the first irradiation light in a state where a light emitting part emitting both sides of light is inserted between the first and second sheets;
A second light irradiation step of irradiating the second sheet and the second inspection object with second irradiation light from the light emitting unit;
A first light detecting step for detecting the amount of light by receiving the first transmitted light transmitted through the first sheet by the first irradiation light;
A second light detecting step of detecting the amount of light by receiving the second transmitted light transmitted through the second sheet by the second irradiation light; and
A position detecting step for determining the position of the end of the inspection object in the width direction of each sheet from the light amounts of the first and second transmitted light;
A method for inspecting an object to be conveyed.

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