1. Field of the Invention
The present invention relates to an apparatus for detecting a light-transmissive sheet-like body having a high transmittance or an edge thereof highly accurately.
2. Description of the Related Art
One known apparatus for detecting minute defects in a light-transmissive substrate made of glass or the like is shown in
While the conventional apparatus is capable of effectively detecting the defect in the light-transmissive substrate 12, it is difficult for the apparatus to detect, with high accuracy, an edge 14 of the light-transmissive substrate 12 or the light-transmissive substrate 12 itself.
Specifically, if the transmittance of the light-transmissive substrate 12 is large, then any difference between shadow and highlight areas of the image of the light-transmissive substrate 12 is very small. When the light-transmissive substrate 12 vibrates while it is being detected or if the light-transmissive substrate 12 has transmittance variations, the accuracy with which to detect the light-transmissive substrate 12 is greatly reduced.
It is therefore a general object of the present invention to provide an apparatus for detecting a light-transmissive sheet-like body or an edge thereof stably with high accuracy.
An object of the present invention is to provide an apparatus for detecting a light-transmissive sheet-like body whose edge can be detected in emphasis.
Another object of the present invention is to provide an apparatus for detecting a light-transmissive sheet-like body whose edge can be detected with high accuracy without being adversely affected by positional displacements of the light-transmissive sheet-like body.
Still another object of the present invention is to provide an apparatus for detecting a light-transmissive sheet-like body whose length can be detected with high accuracy.
The above and other objects, features, and advantages of the present invention will become more apparent from the following description when taken in conjunction with the accompanying drawings in which preferred embodiments of the present invention are shown by way of illustrative example.
The light source unit 22 comprises a light source 34 for emitting the illuminating light L and a condenser lens 36 for converging the illuminating light L onto an end of the optical fiber 24.
The optical unit 26 comprises a half-silvered mirror 38 for reflecting the illuminating light L outputted from the other end of the optical fiber 24, a condenser lens 40 for converging the illuminating light L reflected by the half-silvered mirror 38 into parallel-beam light-transmissive light L and leading the parallel-beam light-transmissive light L to the reflector 28, and an aperture member 42 disposed at an image-side focal point of the condenser lens 40. The optical unit 26 comprises a telecentric optical system.
The apparatus 20 according to the first embodiment is basically constructed as described above. Operation and advantages of the apparatus 20 will be described below.
The illuminating light L emitted from the light source 34 of the light source unit 22 is converged by the condenser lens 36, and led through the optical fiber 24 to the optical unit 26. In the optical unit 26, the illuminating light L is reflected by the half-silvered mirror 38, converged by the condenser lens 40 into parallel-beam light-transmissive light L, which is led to the light-transmissive sheet-like body 32. The light-transmissive light L then passes through the light-transmissive sheet-like body 32, is reflected by the reflector 28, passes again through the light-transmissive sheet-like body 32, and reenters the optical unit 26. In the optical unit 26, the light-transmissive sheet-like body 32 travels through the half-silvered mirror 38 and the aperture member 42 and is applied to the CCD device 29 of the CCD camera 30, which detects the applied amount of illuminating light L and outputs an electric signal representing the detected amount of illuminating light L.
The illuminating light L which travels from the optical unit 26 to the reflector 28 and then back from the reflector 28 to the optical unit 26 includes light transmitted through the light-transmissive sheet-like body 32 and light bypassing the light-transmissive sheet-like body 32. Since the illuminating light L transmitted through the light-transmissive sheet-like body 32 passes through the light-transmissive sheet-like body 32 twice, the amount of the illuminating light L that falls on the CCD device 29 is greatly reduced. If any reflection by the surfaces of the light-transmissive sheet-like body 32 is ignored, then the amount of illuminating light L which falls on the CCD device 29 is reduced at a rate of the square of the transmittance of the light-transmissive sheet-like body 32. However, the illuminating light L bypassing the light-transmissive sheet-like body 32 and falling on the CCD device 29 is not reduced in amount. Therefore, it is possible to determine whether the light-transmissive sheet-like body 32 is placed between the optical unit 26 and the reflector 28 or not from the amount of illuminating light L detected by the CCD device 29.
Since the apparatus 20 according to the first embodiment employs a telecentric optical system, the amount of illuminating light L which is detected by the CCD device 29 differs greatly depending on whether the light-transmissive sheet-like body 32 is placed between the optical unit 26 and the reflector 28 or not, as shown in Table 1 below. Table 1 shows, for comparison, detected levels of illuminating light L which is applied directly to the CCD camera 20 after having passed through and bypassed the light-transmissive sheet-like body 32 whose transmittance is 70% (general optical system+transmissive illumination: optical condition 1), detected levels of illuminating light L which is applied to the CCD camera 20 via a telecentric optical system after having passed through and bypassed the light-transmissive sheet-like body 32 (telecentric optical system+transmissive illumination: optical condition 2, see
In the optical condition 1 (general optical system+transmissive illumination), the difference between detected signals produced when the illuminating light L passes through and bypasses the light-transmissive sheet-like body 32, i.e., the difference between shadow and highlight areas, has a level of 25. In the optical condition 2 (telecentric optical system+transmissive illumination), the difference between the detected signals has a level of 42. Accordingly, the telecentric optical system is effective in making the resultant image clear. In the optical condition 3 (telecentric optical system+coaxial epi-illumination) according to the second embodiment, the difference between the detected signals has a much higher level of 115 due to a large amount of illuminating light L which is reduced by the coaxial epi-illumination arrangement. Consequently, the arrangement based on the telecentric optical system+coaxial epi-illumination is capable of reliably detecting whether the light-transmissive sheet-like body 32 is present or not even through the light-transmissive sheet-like body 32 has a large transmittance.
The apparatus 20 according to the first embodiment is also capable of detecting an edge 44 of the light-transmissive sheet-like body 32 with high accuracy as well as the light-transmissive sheet-like body 32 itself.
Since the edge 44 refracts and diffuses the illuminating light L, the edge 44 is greatly effective to reduce the amount of illuminating light L passing therethrough. Since the optical unit 26 comprises a telecentric optical system, the illuminating light L applied to the CCD device 29 is limited to principal light rays. Therefore, the image 49 representing the edge 44 is lower in intensity than the image 46, allowing the edge 44 to be detected with high accuracy.
As shown in
The apparatus 50 thus constructed is capable of measuring, with high accuracy, the length of a light-transmissive sheet-like body 32 which is placed between the reflector 28 and the optical units 54a, 54b and fed in the direction indicated by the arrow.
The CCD cameras 56a, 56b capture respective images of an edge 44 of the light-transmissive sheet-like body 32 and an opposite edge 62 thereof, and supply the captured images to the image processor 58. The image processor 58 displays the captured images on the display monitor 60. The image processor 58 also calculates the positions of the edges 44, 62 from the images, and determines the length of the light-transmissive sheet-like body 32 from the calculated positions of the edges 44, 62. A process of determining the length of the light-transmissive sheet-like body 32 will be described below with reference to
First, the light-transmissive sheet-like body 32 is introduced into a predetermined length measurement range. If a length measurement trigger signal is generated in step S1 shown in
Thereafter, the image processor 58 calculates the coordinates of the edges 44, 62 in step S3. The coordinates are calculated by setting the coordinates of the upstream ends of the CCD cameras 56a, 56b to “0” and determining coordinates from the coordinates “0” up to pixels where the edges 44, 62 are detected, as coordinates W1, W2 of the edges 44, 62.
Using the coordinates W1, W2 of the edges 44, 62 thus determined, the image processor 58 calculates the length X of the light-transmissive sheet-like body 32 in step S4. Specifically, if the distance between the images captured respectively by the cameras 56a, 56b is indicated by X0 and the coordinates of the downstream ends of the images are indicated by W0, then the length X of the light-transmissive sheet-like body 32 is determined as follows:
X=W0−W1+W2+X0
If the values W0, W1, W2, X0 represent the numbers of pixels, then the value X is multiplied by the size of each pixel to determine the length X.
After the length X of the light-transmissive sheet-like body 32 is determined, the image processor 58 determines whether the length X is acceptable or not in step S5. Thereafter, the process is put to an end.
Since each of the optical units 54a, 54b comprises a telecentric optical system which is telecentric on the object side, even if the position of the light-transmissive sheet-like body 32 varies in the direction of the optical axis of the telecentric optical system, the position of the edge 44 can be detected highly accurately without being adversely affected by the positional variation. Therefore, the length X of the light-transmissive sheet-like body 32 can also be detected highly accurately.
In the film production system 70, a roll film 72 of a rolled photosensitive material is unwound and supplied from a film supply unit 74, and cut into a succession of films F of given length by a film cutting unit 76. The cut films F are then fed along a film feed line 78, sorted to an upper feed line 80a and a lower feed line 80b, and then supplied to film stack producing devices 82a, 82b.
In each of the film stack producing devices 82a, 82b, films F are stacked on a protective cover 88 which is supplied from a protective cover supply device 84 through a protective cover feed mechanism 86. The produced stack of films F is supplied to a stack reversing device 90 in which the stack is vertically reversed, i.e., turned upside down. The stack of films F is then placed in a light-shielding package 94 in a packaged product manufacturing device 92, thus producing a packaged product 96. Packaged products 96 thus manufactured are stacked in a packaged product stacking device 98, and then shipped from the film production system 70.
In the film production system 70 thus constructed, the apparatus 50 is disposed on the film feed line 78. The film feed line 78 functions as the reflector 28. The illuminating light L emitted from the light source unit 22 has a wavelength of 850 nm or higher because the films F are of a photosensitive material sensitive to visible light.
The length of each of the films F supplied to the film feed line 78 is determined by the apparatus 50. If the determined length is not acceptable, then the film F is rejected as a defective film from the film feed line 78. Based on the determined length, the film F may be sorted and supplied to the upper feed line 80a or the lower feed line 80b.
Although certain preferred embodiments of the present invention have been shown and described in detail, it should be understood that various changes and modifications may be made therein without departing from the scope of the appended claims.
Number | Date | Country | Kind |
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2001-027150 | Feb 2001 | JP | national |
Number | Date | Country | |
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Parent | 10060148 | Feb 2002 | US |
Child | 11199194 | Aug 2005 | US |