JPH04350643A - Method for printing photograph - Google Patents

Abstract

PURPOSE:To automatically discriminate the size of an image frame and to enhance workability and processing efficiency by collating the discriminated result and the image frame of a printing aperture, selecting only the image frame of an identical type and successively printing the processing thereof. CONSTITUTION:There are upper masks 240 for full size and panoramic size and they are exchanged according to the size of the image frame. A notched part 246 is formed on one of them and a limit switch 248 is fitted corresponding to it. Then, the type of the upper mask is discriminated. Two intermediate screen detection sensors are set within the detection range of the image frame of the panoramic size. Then, when base density is detected by two on both ends, it is judged to be the panoramic size. In the case that the mask 240 for the full size is loaded and the image frame of the panoramic size is detected, it is passed and the next image frame of the full size is positioned at a printing position. Thus, the printing processing can be executed under an identical condition and the efficiency of the printing processing is enhanced.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photographic printing method in which an image frame recorded on a photographic film is detected by an image frame detection device and a printing process is performed based on the type of the detected image frame.

0002

2. Description of the Related Art In a photographic printing apparatus, a negative carrier is installed at a printing position in order to sequentially position developed negative films at the printing position. The negative carrier is composed of a base and a lid that can be opened and closed with respect to the base, and the base is formed with a negative film guide path in which printing openings are provided corresponding to image frames. In the guide path, rollers that are rotationally driven by the driving force of a pulse motor are arranged near both ends of the negative film in the width direction. Further, an idle roller is attached to the lid body to form a pair with these rollers and to sandwich the negative film. Therefore, when the lid is closed and the negative film is inserted from the side of the negative carrier, the negative film can be held and conveyed along the guide path.

[0003] A detection device for detecting an image frame edge is provided on the upstream side of the printing opening in the guide path. This image frame edge detection device is
As shown in Publication No. 1329, a cold cathode tube or a halogen lamp is arranged on the back side of the guide path, and a slit hole is formed in the guide path, so that the light rays emitted from the cold cathode tube or halogen lamp are directed onto the guide path. Irradiating negative film.

[0004] Further, a light receiving sensor is provided on the lid body in correspondence with the slit hole, so that the transmitted light transmitted through the negative film is received. Based on the amount of light received by this light receiving sensor, the transmission density of the negative film is calculated. Generally, the base portion of a negative film has a high transmission density, and the transmission density within the image frame range is low. By comparing this transmission density difference with a predetermined transmission density, the boundary between the image frame and the base portion, that is, the image frame edge, is detected and positioned at the printing position.

[0005] As a result, even if the image frame pitch recorded on the negative film fluctuates due to feed error during photographing by the camera, it is possible to automatically and accurately position the image to the printing position, thereby eliminating errors caused by fixed feed. Can be done. Furthermore, since there is no need to detect the notch provided for each image frame, the configuration of the negative carrier itself becomes simple.

By the way, in recent years, it has been thought that the same camera can photograph so-called standard size image frames such as full size and half size, and so-called panoramic size image frames in which the photographic paper size after printing is long in the horizontal direction. It is being A panoramic size image frame is shorter in the negative film width direction than a standard size image frame, and has an elongated shape. For this reason, standard size image frames and panoramic size image frames may coexist on a single negative film.

[0007] The size of such image frames cannot be determined using conventional negative carriers, and therefore must be determined visually by the operator.

[0008] Furthermore, in order to deal with a negative film in which image frames of different sizes coexist, a negative mask suitable for each image frame size is prepared and attached to the printing opening. That is, the negative masks are switched in accordance with the detected and positioned image frames, and the printing process is performed in the order in which they are recorded on the negative film.

[0009]

However, in the above-mentioned conventional printing method, depending on the mixed state, negative masks are frequently switched, which deteriorates processing efficiency. In addition, it takes time to sort the sizes, resulting in poor workability.

In consideration of the above facts, the present invention is capable of automatically determining the size of an image frame, and by comparing this determination result with the image frame frame of the printing aperture, selects only image frames of the same type and sequentially prints them. It is an object of the present invention to provide a photographic printing method that can improve workability and processing efficiency by performing a printing process.

[0011]

[Means for Solving the Problems] The invention as set forth in claim 1 provides a switching means capable of switching an image frame frame arranged in a printing opening provided in a guide path of a photographic film between a standard size and a panoramic size; A photo printing method using a photo printing apparatus including an image frame detection device that detects an image frame edge based on the amount of transmitted light of the photographic film conveyed on the guide path, which is received by a light receiving section on the upstream side of the printing opening. The light-receiving section is composed of a plurality of sensors arranged along the width direction of the photographic film, and at least one sensor is arranged within the detection range of standard-sized image frames and outside the detection range of panoramic-size image frames. The image frame size is selected based on the amount of light received by each sensor, and image frames whose size does not match the size of the image frame frame of the printing aperture are skipped during the printing process.

0012

According to the first aspect of the invention, the switching means places either a standard image frame frame or a panoramic size image frame frame in the printing aperture. On the upstream side of the printing opening, the image frame edge to be positioned is detected by a light receiving section, the image frame edge is positioned at a predetermined position, and the image frame is positioned at the printing position. By the way, at least one of the sensors in the light receiving section is located within the detection range for standard size image frames and outside the detection range for panoramic size image frames, so this sensor does not match the base density of the photographic film. The amount of received light will be detected accordingly. Therefore, it is determined that no image exists at this position, and this image frame is determined to be of panoramic size. Here, if the image frame border of the printing aperture is switched to the standard size by the switching means, the shooting area of the image frame and the image frame border do not match, so this image frame is skipped and the printing process is passed. . In this way, image frames of the same image size can be printed continuously, improving work efficiency. Incidentally, the skipped image frames may be sequentially positioned again after switching the image frame and then subjected to the printing process.

In this way, when detecting an image frame edge, the image frame size is determined at the same time and compared with the image frame frame of the printing aperture, so that image frames of the same size are successively processed. It is also possible to efficiently print photographic film containing a mixture of standard size and panoramic size image frames.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIGS. 1 and 2 show a printer processor 10 as a photographic printer to which the present invention is applied. First, the overall configuration of this printer processor 10 will be explained.

The printer processor 10 is covered with a casing 12 on the outside. The printer processor 10 includes a work table 14 protruding from the casing 12 on the left side in FIG. A negative carrier 18 on which a negative film 16 is set is placed on the upper surface of the work table 14. The detailed configuration of the negative carrier 18 will be described later.

A light source section 36 is installed below the work table 14. The light source section 36 includes a light source 38. The light rays emitted from the light source 38 reach the negative film 16 set on the negative carrier 18 via the filter section 40 and the diffusion tube 42. The filter section 40 has three parts: C, M, and Y.
It is composed of two filters, each of which is movable on the optical axis of the light beam.

An optical system 46 is attached to an arm 44 that protrudes from the printer processor 10. Optical system 4
Reference numeral 6 includes a lens 48 and a shutter 50, and is arranged on the optical axis of the light beam. The light beam transmitted through the negative film 16 passes through a lens 48 and a shutter 50, and forms an image of the negative film 16 on a photographic paper 54 set in an exposure chamber 52.

The optical system 46 also includes a density measuring device 56, such as a CCD, for measuring the density of the negative film 16. This density measuring device 56 is connected to a controller 162, and an exposure correction value at the time of exposure is set based on data measured by the density measuring device 56 and data keyed in by the operator.

Here, the light source section 36, the optical system 46, and the exposure chamber 52 enable a printing process, and an exposure section 58 is formed.

A mounting portion 60 is provided above the arm 44. A paper magazine 64 that stores photographic paper 54 wound in layers on a reel 62 is attached to the mounting section 60 .

A roller 66 is disposed near the mounting section 60 and conveys the photographic paper 54 to the exposure chamber 52 while holding the photographic paper 54 therebetween. Further, rollers 68 are disposed near the exposure chamber 52, and the photographic paper 54 on which the image of the negative film 16 has been printed is held in the exposure chamber 52 and conveyed to a reservoir section 70 adjacent to the exposure chamber 52.

The reservoir section 70 stores photographic paper 54 that has been subjected to the printing process, and is connected to an exposing section 58 that performs the printing process, a developing section 58, and a developing section 58.
It absorbs the difference in processing time with the processor unit 72 that performs each process of fixing and washing.

Photographic paper 54 discharged from reservoir section 70
is transported to the color developing section 74 of the processor section 72 adjacent to the reservoir section 70 . The color developing section 74 is a photographic paper 54
is immersed in a developer to perform development processing. The developed photographic paper 54 is conveyed to a bleach-fixing section 76 adjacent to a color developing section 74 . The bleach-fixing section 76 performs a fixing process by immersing the photographic paper 54 in a fixing solution. The fixed photographic paper 54 is conveyed to a rinsing section 78 adjacent to a bleach-fixing section 76 . The rinsing section 78 performs a washing process by immersing the photographic paper 54 in washing water.

The photographic paper 54 that has been washed with water is transferred to a rinsing section 78.
and is transported to the adjacent drying section 80. The drying section 80 wraps the photographic paper 54 around a roller and exposes it to high temperature air to dry it.

The photographic paper 54 is held between a pair of rollers 82A, and the photographic paper 54 that has been dried is discharged from the drying section 80 at a constant speed. A pair of rollers 82B are disposed above the rollers 82A, and are intermittently rotated in response to processing by a cutter section 84 disposed downstream of the drying section 80. As a result, the cutter section 84 cuts the photographic paper 54.
It is composed of a cut mark sensor 86 that detects a cut mark given to a cut mark, and a cutter 88 that cuts the photographic paper 54, cuts the photographic paper 54 image by frame, and discharges the photographic paper 54 to the outside of the casing 12 of the printer processor 10.

As shown in FIG. 3, each control is controlled by a controller 162. The controller 162 is
It is configured to include a microcomputer 164. The microcomputer 164 has a CPU 166 and a RAM 1.
68, ROM 170, input/output port 172, and buses 174 such as data buses and control buses that connect these
It is made up of.

The controller 162 is connected to a conveyance control section 176 that controls the conveyance system of the negative film 16 and photographic paper 54 in the printer processor 10, and also controls the lighting of the light source 38 in the exposure section 58 and the light path of the filter section 40. appearance, frame advance with negative carrier 18, shutter 50
An exposure control section 178 is connected to the exposure control section 178, which controls the exposure system such as opening/closing. In addition, the controller 162 also includes a drying section 80.
Detection of cut marks by the cut mark sensor 86 in the drying control section 182 that controls the drive of the fan and heater in the drying control section 182 and the cut mark sensor 86 in the cutter section 84 downstream thereof;
A cutter control unit 184 that controls cutting of the photographic paper 54 by
is connected.

FIG. 4 shows a negative carrier 18 according to this embodiment.
It is shown. This negative carrier 18 is constructed mainly of a pedestal 200 as a base and an open/close cover 202 as a lid.

A negative film transport path 204 is formed in the pedestal 200 as a guide path. A printing opening 206 is provided at the center in the longitudinal direction of the negative film transport path 204, and serves as an irradiation opening for light from a light source 38 provided in the printer processor 10.

The size of the printing opening 206 is the same as that of the full-size image frame 16A of the negative film 16. In the negative film conveyance path 204, conveyance rollers 208, 210, 212, and 213 are provided on the upstream side (to the left in FIG. 4) and the downstream side (to the right in FIG. 4) of the printing opening 206 to convey the back surface (lower surface) of the negative film 16. are arranged accordingly. As shown in FIG. 5, each conveyance roller 208, 21
0, 212, and 213, a sprocket 214 is attached to one end in the axial direction of the rotating shaft, and meshes with teeth formed on an endless timing belt 216.

The timing belt 216 is wound around a sprocket 214 attached to the most upstream conveyance roller 208 and a sprocket 214 attached to the rotating shaft of a pulse motor 218. The pulse motor 218 is connected to a control device 220 (see FIG. 10) via a driver 222, and is driven in steps according to a drive signal from the control device 220. Accordingly, when the pulse motor 218 rotates, each of the conveyance rollers 208, 210, 212, and 213 is driven in the same rotation direction and at the same rotation speed.

The opening/closing cover 202 has a housing-like cover main body 224 whose lower end is pivotally supported by a bar 226 fixed to the pedestal 200, and can be opened and closed relative to the pedestal 200 around this bar 226. ing.

A through hole 228 corresponding to the burning opening 206 is provided at the bottom of the cover body 224. The cover body 224 also has an upper guide base 230 at a position corresponding to the negative film transport path 204 in the closed state.
is attached, and a negative film guide wall 232 is integrally formed so that a gap is created between the tip of the negative film guide wall 232 and the bottom surface of the negative film transport path 204. Further, this gap size is slightly larger than the wall thickness of the negative film 16 to ensure a conveyance path for the ends in the width direction of the negative film.

Further, between the guide walls 232, the conveyance rollers 208, 210, 212 and 21 are provided.
3, idle rollers 234, 236, 238
and 239, and when the opening/closing cover 202 is closed, the idle rollers 234, 23
6, 238 and 239 and conveyance rollers 208, 210, 2
12 and 213 sandwich the negative film 16, so that conveyance force can be transmitted to the negative film 16.

An upper mask 240 is disposed at the center of the upper guide base 230 in the negative film transport direction, and is movable relative to the upper guide base 230 and has an opening at a position corresponding to the through hole 228. . Upper mask 240 is detachably attached to mask base 242. That is, the upper mask 240 includes one with a full-size aperture and another with a panoramic-size aperture, and these are based on the image frame size recorded on the negative film 16 (see FIG. 6) It can be exchanged accordingly.

As shown in FIG. 7, the mask base 242
Both ends in the width direction are bent so that the tip portions face each other and have a substantially U-shaped cross section, thereby forming a rail portion 244. The upper mask 24 is attached to this rail portion 244.
0, the upper mask 240 is supported by the mask base 242. Also, upper mask 24
A notch 246 is formed at the insertion tip of one type (for example, the full-size upper mask 240), and a limit switch 248 is attached to the back side of the rail portion 244 corresponding to this.

The signal line of limit switch 248 is connected to control device 220. Therefore, the contacts of the limit switch 248 are switched only when the panoramic size upper mask 240 is inserted, and the type of upper mask to be inserted can be determined by the on/off state of the limit switch 248.

[0038] The mask base 242 has a cover main body 224.
The solenoid main body 250 is supported via a shaft near the rotation center of the solenoid main body 250 when the cover main body 224 is closed. When the solenoid main body 250 is energized, the mask base 242 is attracted by magnetic force, and the upper mask 240 can be brought into close contact with the printing opening 206 of the negative film transport path 204, thereby sandwiching the negative film 16 positioned on the optical axis P. It is now possible to do so.

As shown in FIG. 8, a rectangular groove 252 is formed in the bottom of the negative film transport path 204 on the upstream side of the printing opening 206, and a transparent glass plate 254 is fitted into the groove 252, which is connected to the surrounding guide surface. It is said to be the same. This groove 252
A slit hole 256 that penetrates to the back surface of the negative film transport path 204 is formed at the bottom of the negative film transport path 204 . Slit hole 25
The longitudinal direction of 6 is provided along the width direction of the negative film transport path 204. On the back side of the negative film transport path 204 corresponding to this slit hole 256, a plurality of LED chips 258 serving as a light projecting section are arranged along the width direction of the negative film transport path 204, that is, the width direction of the negative film 16. has been done.

As shown in FIG. 9, this LED chip 2
58 is 2 that develops R (red) and Y (yellow) colors.
Colored LED chips 258 are arranged on the substrate 260, and the arrangement order is RYYRYYRYY...
The ratio is R:Y=1:2. This makes the luminous efficiency of each color the same.

Each LED chip 258 is connected to a common signal line 2.
62 (see FIG. 10), and a light beam emitted by a signal from the control device 220 passes through the negative film 16 that is transported along the negative film transport path 204.

The slit hole 256 corresponds to the screen detection sensor 264 provided on the upper guide base 230 of the cover body 224 when the cover body 224 is closed. Therefore, the amount of light transmitted through the negative film 16 is detected by the screen detection sensor 264. As shown in FIG. 6, four screen detection sensors 264 are arranged along the width direction of the negative film 16, and each is connected to the control device 220 by an independent signal line. The control device 220 obtains the photographic film transmission density distribution based on the output signal from the screen detection sensor 264, and detects the boundary between the image frame 16A and the base portion, that is, the image frame edge.

By the way, this screen detection sensor 264 is
As shown in FIG. 6, the arrangement is within the vertical dimension (width direction of the negative film 16) of the full-size image frame 16A, and the middle two are panoramic-size images taken as panoramic images. The image frame 16 is within the vertical dimension of frame 16B, and the two at both ends are panoramic size.
It is outside the range of the vertical dimension of B. For this reason, the 2
The detection value of the screen detection sensor 264 is negative film 1.
If it is detected as a base density of 6, it can be determined that the image frame 16B is of panoramic size.

As shown in FIG. 16, some negative films 16 are provided with a frame mark 265 at the edge of each image frame that slightly protrudes from the edge. The frame mark 265 has a high density because it is exposed to light when photographing with a camera, and therefore has a low transmission density and is easily recognized as part of an image. When one scanning line of the screen detection sensor 264 passes over this frame mark 265, the output value of each sensor becomes different. Furthermore, the density distribution also differs depending on the image capturing state. Therefore, in this embodiment, the screen detection sensor 264 (first sensor) located at the highest density position and the screen detection sensor 264 located at the lowest density position
(second sensor) is selected, and the difference between them is used as a condition for determining whether or not the detected value is appropriate.

The bottom surface of the negative film transport path 204 on the upstream side of the slit hole 256 is slightly deeper in the center so that it does not come into contact with the negative film 16 when the negative film 16 is transported. That is, since only both ends of the negative film 16 in the width direction are in contact with each other, the image surface is not damaged. In this deep bottom surface, two circular holes 266 and 268 are provided along the longitudinal direction at the center in the width direction of the negative film transport path 204, and the LED elements 27
0 and 272 are buried respectively. These LEDs
The elements 270 and 272 are each connected to the control device 220 and emit light in response to a signal from the control device 220.

LED element 270 near slit hole 256
is used to detect the splice tape used for joining when a plurality of negative films 16 are connected to form a roll, or the management tape affixed to each negative film 16, and is used to detect the negative film insertion in the negative film transport path 204. The LED element 272 on the opening side is used to detect the presence or absence of the negative film 16, and corresponds to a tape sensor 274 and a negative presence/absence sensor 276, respectively, which are attached to the upper guide base 230 side. The tape sensor 274 and the negative presence/absence sensor 276 are each connected to the control device 220.

[0047] The LED element 270 and the LED element 272
LED elements 280 are embedded in both widthwise ends of the negative film transport path 204 between the negative film transport path 204 and the negative film transport path 204 . This LE
The D element 280 is connected to the control device 220 and corresponds to barcode sensors 282 provided at both ends of the upper guide base 230 in the width direction. Barcode sensor 282
is connected to the control device 220. Negative film 1
6 is transmitted through an LED element 280, detected by a barcode sensor 282, and decoded by a control device 220.

The barcode sensor 282 is attached to a frame member 284 that is swingable with respect to the upper guide base 230, so that it can follow the meandering movement of the negative film 16 when it is conveyed. Therefore, the barcode attached to the narrow end portion of the negative film 16 in the width direction can be read regardless of the meandering of the negative film 16. As shown in FIG. 11, the distance between each sensor is determined with one side of the burning opening 206 as a reference.

As shown in FIG. 10, the control device 220 includes a CPU 286, a RAM 288, a ROM 290, an input port 292, an output port 294, and a bus 296. The output port 294 is connected to the pulse motor 218 via the driver 222 and the solenoid body 250 via the driver 298, respectively.

[0050] Also, each output port 294 has an L
The LED elements 270, 2 via the ED driver 300
72 , 280 and the substrate 260 of the LED chip 258 .

The tape sensor 27 is connected to the input port 292.
4 and a negative presence/absence sensor 276 are connected via a comparator 302 and an inversion circuit 304. The input port 292 also has two barcode sensors 282 and 4.
screen detection sensors 264 are connected to amplifiers 306 and A, respectively.
/D converter 308. Furthermore, the input port 292 has four key switches 310A, 310B, 3 provided on the pedestal 200 of the negative carrier 18.
10C and 310D are connected. By operating this key, the stop position of the negative film 16 can be forwarded, reversed, and finely adjusted.

This control device 220 is connected to the controller 162 on the printer processor 10 side. Signals are exchanged with the controller 162 when the positioning of an image frame is completed, when the printing process is completed and the positioning of the next image frame is instructed, and when an abnormality occurs in the negative film transport system or screen detection in the negative carrier 18. There may be cases where Here, if an abnormality occurs, the printer processor 10
It is notified by an alarm (not shown) attached to the
Although the processing is stopped, the output of the abnormal signal is limited by controlling the negative carrier 18 manually, automatically, or fully automatically.

[0053] In the case of manual operation, there is no need to notify abnormalities because the operator is near the equipment, and in the case of fully automatic operation, all abnormalities are notified and processing is stopped, which improves work efficiency. It's not appropriate from the point of view. In other words, if there is a super overexposed image, for example, automatic processing will not produce the optimal printing process, but rather than switching to manual processing each time, it is possible to It is more efficient to reheat. Therefore, in this embodiment, the control state (manual, automatic,
(fully automatic), the output form of the abnormal signal is changed accordingly.

Table 1 shows whether or not an abnormality signal is output in each control state with respect to abnormality contents. Note that a circle in the control status column indicates that an abnormal signal is output, and an x mark indicates that an abnormal signal is not output.

[0055]

[Table 1]

The ROM 290 stores a program for correcting the mounting position of each sensor and the deviation of the detected value by each sensor, and is set as a correction coefficient when the negative carrier 18 is shipped. In the installation position correction, the distance from one side of the burning opening 206 to each sensor is measured by the number of pulses of the pulse motor 218, and the error with the number of pulses stored in advance in design is corrected. In addition, the deviation of the detected values of each sensor is particularly important for the LED chip 2.
A correction coefficient is determined for each image detection sensor 264 so that the four screen detection sensors 264 detect the same amount of light of the light beam emitted from the image sensor 58 .

When the negative carrier 18 is shipped, an A/D converter 30 is installed to convert the values detected by the screen detection sensor 264 and the barcode sensor 282 into digital values.
The amount of light emitted by the corresponding LED element and LED chip is determined to match the 8 ranges.

The RAM 288 includes a screen detection sensor 264.
A map is stored that determines the transmission density of the negative film based on the data detected by. This results in
One conveyance by the pulse motor 218 (in this example,
It is possible to obtain the transmission density distribution during one transport from the center of the image frame 16A or 16B to the center of the adjacent image frame. The edges of the image frames are determined based on this transmission density distribution, and the edges of each image frame are stored in correspondence with the number of sending pulses of the pulse motor 218.

The operation of this embodiment will be explained below. first,
The normal printing process procedure will be explained.

[0060] When the process is started, the light source 38 is turned on,
The negative carrier 18 is driven to position the negative film 16. The L of the negative film 16 is determined by the density measuring device 56.
The ATD (average transmission density) is measured, an exposure correction value is set from this measurement data and data manually input by key, and the exposure amount (exposure time) is calculated to obtain optimal printing conditions.

Incidentally, the negative film 16 may contain a mixture of full-size image frames 16A and panoramic-size image frames 16B. These printing processes differ in the negative mask area, printing magnification, photographic paper mask area, and photographic paper transport amount, so pass one of them and print the same size first, then print the other size continuously. Chie-baking is more efficient. Therefore, in this embodiment, the respective baking conditions are set depending on the upper mask 240 currently loaded on the mask base 242. The type of upper mask 240 can be determined by checking the on/off state of the limit switch 248 by loading it onto the mask base 242. Therefore, control is performed so that only the type of image frame detected by the limit switch 248 is positioned, and other types of image frames are passed.

A routine for comparing an image frame and an upper mask will be described below with reference to FIG.

First, in step 650, it is determined whether or not the limit switch 248 is on. If the determination is affirmative, it is determined that the panoramic size upper mask 242 is attached, and the process proceeds to step 652, where flag F is set. It is reset (0) and the process moves to step 654. Also,
If a negative determination is made in step 652, it is determined that the full-size upper mask 242 is being worn, and the process proceeds to step 656, where flag F is set (1), and the process proceeds to step 654.

In step 654, the size of the image frame is determined. That is, of the four screen detection sensors 264 of the negative carrier 18, the two at both ends are outside the range of the vertical dimension of the panoramic size image frame 16B and within the range of the vertical dimension of the full size image frame 16A. Therefore, when these two screen detection sensors 264 detect the base density of the negative film 16, it can be determined that it is a panoramic size image frame 16B, and when the image density is detected, it can be determined that it is a full size image frame. It can be identified as 16A.

If it is determined in step 654 that the image frame 16B is of panoramic size, the process moves to step 658.
If it is determined that the image frame 16A is full size, the process moves to step 660.

In step 658, it is determined whether or not flag F has been reset. If the determination is negative, it is determined that the image frame size and the upper mask size do not match, and the process advances to step 662, where this A signal passing the image frame is output to the controller 162 and the process returns. Further, if an affirmative determination is made in step 658, it is determined that the image frame size and the upper mask size match, and the printing process can be performed, so the process returns as is.

On the other hand, in step 660, it is determined whether flag F is set, and if the determination is negative, it is determined that the image frame size and the upper mask size do not match, and the process proceeds to step 662. , outputs a signal passing this image frame to the controller 162, and returns. Further, if an affirmative determination is made in step 660, it is determined that the image frame size and the upper mask size match, and the printing process is possible, so the process returns as is.

Therefore, for example, when the full-size upper mask 240 is loaded and the screen detection sensor 264 detects a panoramic-size image frame 16B, this is passed and the next full-size image frame 16A is printed. Position to position. Thereby, the baking process can be performed under the same conditions, and the efficiency of the baking process is improved.

Next, the photographic paper 54 is transported to the exposure chamber 52 and positioned, and the shutter 50 is opened. This results in
The light beam emitted by the light source 38 passes through the filter unit 40 and the negative film 16 and reaches the exposure chamber 52, and the photographic paper 54 positioned in the exposure chamber 52 starts printing an image on the negative film 16 according to the exposure conditions. The C, M, and Y filters located on the optical axis of the light beam are moved. After the predetermined exposure time has elapsed, the shutter 50 is closed. With this, the printing process for one frame of the negative film 16 is completed. By repeating this, the printed portions of the photographic paper 54 are sequentially conveyed to the reservoir section 18.

The photographic paper 54 conveyed to the reservoir section 70 is conveyed to the color developing section 74, where it is immersed in a developer and subjected to development processing. The developed photographic paper 54 is transferred to a bleach-fixing section 76.
The image is transported to and subjected to fixing processing. Photographic paper 54 that has been fixed
is transported to the rinsing section 78 and washed with water. The photographic paper 54 that has been washed with water is conveyed to a drying section 80 and is dried.

The photographic paper 54 that has been dried is transferred to the cutter section 8.
A cut mark is detected in step 4, and each image is cut.

By the way, in the negative carrier 18, image frame positioning can be performed not only automatically but also manually.Furthermore, in automatic mode, there is so-called automatic control in which an operator is nearby and the operator operates the printing start button. The timing of starting this printing is also determined by the control device 220 of the negative carrier 18.
There are so-called fully automatic control performed by exchanging signals with the controller 162 of the printer processor 10.
It is possible to switch between stages (manual, automatic, fully automatic).

Here, in this embodiment, depending on each control,
The output of the abnormality signal from the negative carrier 18 is restricted to prohibit unnecessary alarm notification even though the operator is nearby.

That is, as shown in Table 1, in the case of manual control, negative size abnormality (code No. 8), unexposed negative (code No. 10), fogging negative (code No.
．． 11), an abnormal signal is output only when there is a negative end abnormality (code No. 12).

In the case of fully automatic control, if there is only an abnormality in the finish, and the printing process can be controlled without any problems, there will be an abnormal frame interval (code No. 3), an abnormal frame length (code No.
o. 4), negative size abnormality (Code No. 8), leading edge abnormality (Code No. 9), unexposed negative (Code No.
．． 10) Outputs an abnormal signal when fogging negative (code No. 11) or negative end abnormality (code No. 12) occurs.

Furthermore, in the case of automatic control, an abnormality signal is output in the event of any abnormality. In this way, by changing the output of the abnormality signal according to the control mode, it is possible to take advantage of the fully automatic feature without issuing unnecessary alarms even if the operator is nearby.

Furthermore, the printer processor itself stops its processing each time an unnecessary abnormality signal is output, and the work for error handling can be omitted, improving work efficiency.

In this embodiment, the negative carrier 18 automatically positions each image frame 16A (16B) of the negative film 16 to the printing position (fully automatic).
The edge of each image frame is detected by the screen detection sensor 264, and conveyance control is performed by making the edge of each image frame correspond to the number of sending pulses of the pulse motor 218.

The image frame positioning procedure will be explained below with reference to the flowchart shown in FIG. First, step 400
In step 401, the flag F is reset (to 0), and then in step 401, it is determined by the negative presence/absence sensor 276 whether or not the negative film 16 is inserted into the negative carrier 18. If the negative determination is negative, the process moves to step 402. Then, the LED chip 258 is turned off. Furthermore, if the determination is affirmative, the process moves to step 404 and the LED chip 2 is
58 is lit. In this way, the light source is the LED chip 25
8 is used, it is easy to turn on and off, and the lifespan will not be shortened.

In the next step 406, the negative film 1
When it is determined that the conveyance for positioning the slit hole 2 to the printing position has started, the process moves to step 408 and the slit hole 2 is moved to the printing position.
56 and the amount of transmitted light transmitted through the negative film 16 is detected, and then A/D conversion is performed in step 410.
Each piece of data is stored in correspondence with the number of sending pulses (step 411).

[0081] The steps 408, 410, and 41 are repeated until it is determined in the next step 412 that the conveyance has been stopped.
1 is repeated, and when it is determined in step 412 that the conveyance has been stopped, the process proceeds to step 413, where the transmitted density distributions of each of the four sensors in one conveyance are created based on the stored data.

In the next step 414, it is determined whether or not there is an abnormality in the transmission density distribution. In other words, image frame 1
If 6A (16B) is half-fogged, transparent, or super under or super over, the transmission density distribution will be abnormal. If there is an abnormality, it is determined that the frame edge cannot be detected, and the process moves to step 415, where flag F is set (1), and then the process moves to step 426, which will be described later.

If it is determined in step 414 that the distribution is normal, it is determined that a frame edge can be detected, and the process proceeds to step 416.

In step 416, the pulse number PMAX (H) of the maximum point DMAX of the sensor at the highest concentration position among the four sensors (first sensor) is selected, and then in step 417, the number of pulses PMAX (H) of the maximum point DMAX of the sensor at the highest concentration position (first sensor) is selected. Maximum point DMIN of the sensor (second sensor) located at the lowest concentration position of
The number of pulses PMAX (L) is selected. In the next step 418, the number of sending pulses PA'(H) and PA'(L) for the density value that is 92% of these maximum points is determined,
This is set as a temporary edge, and then in step 419, a minimum point within a predetermined pulse (12 pulses in this embodiment) is selected from this temporary edge PA', and the number of sending pulses PMIN (H), PMIN ( Set L). In the next step 420, the maximum point sending pulse PMAX (H) and the minimum point sending pulse PMIN (H)
, i.e., (PMAX (H) + P
MIN (H))/2 is calculated, and image frame 16A (16
A pulse PA (H) corresponding to the edge of B) is determined. Next, in step 421, the maximum point feed pulse PMAX (L) and the minimum point feed pulse PMIN (L
), i.e., (PMAX (L)+
PMIN (L))/2 is calculated and image frame 16A (1
A pulse PA (L) corresponding to the edge of 6B) is determined.

In the next step 422, the pulse PA (
Find the difference ΔPA between H) and PA(L). This can be obtained at two locations, the right end of N frames (image frames from which edges are obtained) and the left end of N-1 frames, with the maximum point in the center. Here, in step 423, the one with the smaller difference ΔPA between the right end ΔPA of the Nth frame detected last time and the left end ΔPA of the Nth frame detected this time is selected (steps 424 and 425), and the selected one is selected. Use the edge detection point at PMAX (H) as the reference point (if they are the same, select the right end of N frames).

The image frame edge pulse PA determined in this manner applies not only to the normally exposed negative film 16 but also to the normal exposure negative film 16.
Even with respect to underexposed or overexposed negative film 16, the position is approximately constant, and detection errors can be suppressed within a range that does not impede positioning.

Furthermore, even if the negative film 16 has frame marks, image frame edges can be detected reliably.

In the next step 426, it is determined whether or not there is a positioning instruction from the controller 262 of the printer processor 10, and if it is determined that there is an instruction,
The process moves to step 428 to read the current number of sending pulses PX, and then, in step 429, it is determined whether flag F has been reset. If the determination is affirmative here, in order to perform positioning based on the detected edge, the process moves to step 430 and calculates the feed amount PDRIVE from the current feed pulse PX and the number of image frame edge pulses PA. (PDRIVE=PA-
PX), the process moves to step 432.

If a negative determination is made in step 429, in order to position the image frame by constant feed, the process moves to step 431, and the current value is sent from PCONST to the constant feed amount from the previous positioning position, and the pulse PX is Assign the subtracted amount to PDRIVE and proceed to step 432.
Move to. In the next step 432, the negative film is transported by the calculated feed amount PDRIVE. This conveyance is determined to be the conveyance in step 406. That is, during conveyance for positioning, the edge of the image frame 16A (16B) two frames before is detected on the upstream side.

When the predetermined image frame 16A (16B) is positioned at the printing position, a positioning completion signal is output to the controller 162 of the printer processor 10 in step 434, and in response, the printer processor 10 performs the above-mentioned process. A baking process is performed.

In the next step 436, it is determined whether or not there has been an instruction to end the burning process. If the determination is negative, the process proceeds to step 400 to continue the process, and if the determination is affirmative, the process proceeds to step 438. LED chip 258
Turn off the light and exit.

In this way, in this embodiment, two types of edges (the front side of the Nth image frame) at the boundary between two image frames (Nth and N-1st) and the base part between these frames are used. , the rear side of the N-1th image frame) and selects the optimal one as the positioning reference, so even negative film 16 with frame marks 265 etc. as shown in FIG. 16 can be accurately detected. Image frame edges can be detected and positioning can be performed with high precision.

The above is the image frame positioning control, and in order to perform such positioning control, the screen detection sensor 2
It is required that the detection accuracy of 64 and the mounting position accuracy from the burning position be accurate. Therefore, in this example,
Accuracy correction is performed when the negative carrier 18 is shipped and every time the power is turned on.

First, the procedure for adjusting the amount of light emitted from the LED chip 258 will be explained with reference to the flowchart shown in FIG. LED
The amount of light emitted by the chip 258 is determined by the screen detection sensor 26
4 will be detected and A/D converted, but the A/D
A convertible range for the converter 308 is determined. Therefore, in step 450, the negative film 16
In the state where it is determined that there is no screen detection sensor 26, the LED chip 258 is made to emit light in step 452, and each screen detection sensor 26
4 (step 454), then step 456
, the largest value of the maximum amount of light detected is selected.

The maximum value LMAX of the selected light amount is compared with the maximum range A/DMAX of the A/D converter 308 (step 458), and in step 460, L
The drive voltage by the LED driver 300 is controlled so that MAX = A/DMAX. As a result, the value detected by the screen detection sensor 264 is transferred to the A/D converter 30.
Data can be reliably read without departing from the dynamic range of 8. Also, LED as a light source
Since the chip 258 is used, the amount of light can be easily adjusted and the amount of light can be easily controlled.

Next, even if the four screen detection sensors 264 detect the same amount of light, a slight error (deviation) occurs due to their accuracy and the influence of temperature changes. If the same amount of light is detected, it is preferable that the output be the same, so it is necessary to correct this deviation. The sensor output deviation setting control procedure will be described below according to the flowchart of FIG.

First, in step 500, when it is determined that there is no negative film 16, the LED chips 258 are caused to emit light in step 502, and each screen detection sensor 264 detects the light (step 504), and then in step 506, Each detected screen detection sensor 264
Find the maximum value of each. The control up to this point is the same as the LED chip light amount control, so it may be stored at the stage of selecting the maximum value.

In the next step 508, the deviation of the output maximum values of the other three sensors is determined based on the maximum output value of one sensor, and in step 510, each screen detection sensor 264 is
is stored as a correction coefficient α.

For example, if the screen detection sensors 264 are SA, SB, SC, and SD, and the amount of light is expressed with sensor SA as a reference (SA = 1.0),
On the other hand, the output of other sensors is SB = 0.9
, SC = 0.8, SD = 0.9, the correction coefficients for each sensor are αSA = 1.00, αS
B=1.11, αSC=1.25, and αSD=1.11. That is, the correction coefficient α stored in step 510 is multiplied at the time when data is input from each screen detection sensor 264. According to this, an appropriate value can be applied at the time of A/D conversion, and a highly accurate transmission density distribution can be created.

Next, each sensor (screen detection sensor 264,
The mounting positions of the barcode sensor 282, tape sensor 274, and negative presence/absence sensor 276) are determined based on the distance from one side of the printing opening 206 at the printing position of the image frame as the number of feed pulses of the pulse motor 218. If there is a deviation at the assembly stage, the number of feed pulses will differ from the predetermined number. Therefore, it is necessary to correct the number of sending pulses, which is predetermined in design, according to the mounting accuracy. Hereinafter, sensor attachment accuracy correction will be explained according to the flowchart of FIG. 15.

[0101] Since the position correction of each sensor is performed separately and in the same manner, here, the negative presence/absence sensor 276 is
This will be explained using an example. At step 550, it is determined whether the reference lith film 312 has been detected. This reference lithographic film 312 is a substitute for the negative film 16, and has a high density (almost transparent) part in the middle of a low density (almost transparent) part.
It is a type of photolithographic film with clear edges and opaque areas.

[0102] If it is determined that the transparent portion is not detected, and if the boundary with the high density is detected, an affirmative determination is made in step 550.
In step 552, a predetermined amount of reference lith film 312 is conveyed. This predetermined amount burns a predetermined detection point into the opening 2.
This is the conveyance amount for positioning to the right end of 06.

[0103] When the predetermined amount of the film has been conveyed, the operator determines whether the high and low density edges match the right edge of the printing opening, and if it is determined in step 554 that they match, the reference lith film is discharged. Operate the feed key. By operating this feed key, the process moves from step 554 to step 556, and the reference lith film 312 is
is discharged, and the process ends.

If the feed key is not operated in step 554, the process moves to step 558, where it is determined whether or not the fine adjustment key for fine adjustment has been operated.If the determination is negative, steps 554 and 558 are executed. repeat. here,
When the fine adjustment keys 310B and 310C are operated in step 558, the reference squirrel film 31 is adjusted in accordance with the key operation.
2 moves slightly, and the edge of high and low density is positioned to the right end of the printing opening 206.

In the next step 558, after the fine adjustment (after one operation), the process moves to step 560, where the predetermined values after the adjustment at that time are newly updated and stored, and the process moves to step 554.

By repeating the above steps until the edge of high and low density is reliably positioned at the right end of the printing opening 206 by conveying a predetermined amount in step 552, the attachment position accuracy correction is completed.

[0107] The same processing procedure as described above can be performed for other sensors by selecting which sensor is used to perform the detection in step 550. As a result, the accurate position can be stored as the feed amount regardless of errors during sensor assembly, so the assembly work can be made rough and work efficiency is improved.

[0108] In particular, in the case of the screen detection sensors 264, if the four screen detection sensors 264 are not parallel to each other along the image frame edge, the image frame edge may shift significantly. However, by performing the above correction, since the four screen detection sensors 264 are arranged in parallel along the apparent image frame edge, reliable image frame edge detection is possible.

[0109]

Effects of the Invention As explained above, the photographic printing method according to the present invention can automatically determine the size of an image frame, and also compares the result of this determination with the image frame frame of the printing aperture to identify only image frames of the same type. By selecting and sequentially performing the baking treatment, it is possible to improve workability and processing efficiency, which is an excellent effect.

[Brief explanation of drawings]

FIG. 1 is a perspective view showing the appearance of a printer processor.

FIG. 2 is a schematic diagram showing the internal configuration of a printer processor.

FIG. 3 is a block diagram of a controller of a printer processor.

FIG. 4 is a perspective view showing the appearance of the negative carrier.

FIG. 5 is a perspective view showing a negative carrier conveyance system.

FIG. 6 is a plan view showing the size of image frames recorded on a negative film.

FIG. 7 is a perspective view of the mask base portion.

FIG. 8 is a side sectional view of the guide path of the negative carrier.

FIG. 9 is a perspective view of an LED chip.

FIG. 10 is a block diagram of a negative carrier control device.

FIG. 11 is a plan view showing the positional relationship between the burning opening and the sensor position.

FIG. 12 is an image frame positioning control flowchart.

FIG. 13 is a flowchart of LED chip light emission adjustment control.

FIG. 14 is a sensor output deviation correction control flowchart.

FIG. 15 is a sensor mounting accuracy correction control flowchart.

FIG. 16 is a characteristic diagram showing an image frame with a frame mark and a transmission density distribution of this image frame.

FIG. 17 is a control flowchart showing a routine for comparing an image frame and an upper mask.

[Explanation of symbols]

16 Negative film 18 Negative carrier 206 Printing opening 218 Pulse motor 220 Control device 240 Upper mask 242 Mask base 246 Notch 248 Limit switch 254 Transparent glass plate 256 Slit hole 258 LED chip 264 Screen detection sensor 270 LED element (for tape sensor) 272
LED element (for negative presence/absence sensor) 274
Tape sensor 276 Negative presence/absence sensor 280 LED element (for barcode sensor) 28
2 Barcode sensor

Claims (1)

[Claims] Claim 1: A switching means capable of switching an image frame frame arranged in a printing aperture provided in a guide path of a photographic film between standard size and panoramic size, and a switching means capable of switching an image frame frame placed in a printing aperture provided in a guide path of a photographic film, and a photoreceiving section that receives light on the upstream side of the printing aperture. A photographic printing method using a photographic printing apparatus comprising an image frame detection device for detecting an image frame edge based on the amount of transmitted light of the photographic film conveyed on the guide path, the photographic printing apparatus comprising: a plurality of photographic films arranged along the width direction; The light receiving part is composed of a sensor
By placing at least one sensor within the detection range for standard-sized image frames and outside the detection range for panoramic-size image frames, the size of image frames is sorted based on the amount of light received by each sensor, and the printing aperture is A photo printing method characterized in that image frames whose size does not match the size of an image frame frame are skipped during printing processing.