JP3695847B2 - Photo printing and developing equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a photographic developing apparatus, and in particular, has a function of conveying photographic paper, which has been cut in advance to a desired cut size, to the left and right of the conveyance path so that the processing speed can be increased. The present invention relates to a photographic developing device.
[0002]
[Prior art]
After exposure printing on the emulsion surface of photographic paper (hereinafter referred to as paper) that has been cut to a predetermined size, it is conveyed so that it sequentially passes through a processing tank containing processing liquids for development, bleaching and washing. After that, a photographic developing device configured to be dried and discharged to the outside has been put into practical use.
[0003]
For example, according to the photographic developing apparatus disclosed in US Pat. No. 5,307,114, a continuous roll paper which is blocked by blocking light in a paper magazine is made into a desired cut size by a cutter unit. After cutting in advance, the emulsion surface is transferred to the exposure printing section, then exposed to the desired size with the film set on the scanner, and then transferred to the processing liquid for development, bleaching, and washing. An apparatus has been proposed that is configured to sequentially transport through the processing tanks, and then to dry and discharge to the outside.
[0004]
This device integrates the function of rotating the paper 90 degrees after exposure and then developing the film when it is necessary to rotate the paper in the exposure printing section when exposing to a desired size. On the other hand, the continuous roll paper built in the paper magazine so as to block the light is cut into a desired size by a cutter unit in advance and conveyed to the exposure printing section with the emulsion surface facing up, before the scanner Then, after the exposure printing is performed, the film is transported to an upstream transport unit and passed through a processing tank provided therein, followed by development, fixing, and washing with water, and a completed photograph is obtained after drying.
[0005]
In addition, according to Japanese Utility Model Application No. 6-30765, which is the applicant of the present application, a distribution means for distributing photographic paper cut in advance to a desired cut size to the left and right conveyance paths is provided upstream of the conveyance path. Thus, a “cut sheet sorting device” has been proposed in which photographic paper is conveyed in two rows on the left and right sides so as to improve the processing speed.
[0006]
[Problems to be solved by the invention]
However, according to such a cut sheet sorting device, the conveyance roller is always driven at low speed and high speed, so that it is inherited. However, since there is one roller pair, panoramic photographs ( In the case of a long photograph such as a length of 254 mm along the conveyance direction and a width orthogonal to the conveyance direction of 89 mm, the photograph is skewed and cannot be conveyed in parallel to the conveyance path. In the case of size distribution, there is a problem that noise is increased because the rollers are controlled to stop and drive at low speed.
[0007]
Therefore, the present invention has been made in view of the above-described problems, and even when the photographic paper is distributed to the left and right of the conveyance path, even when the photographic paper has a long length along the conveyance direction including the panoramic photograph. It is an object of the present invention to provide a photographic developing apparatus that can reliably convey in parallel to the conveyance path without skew and can reduce noise.
[0008]
In addition to the above object, another object of the present invention is to provide a photographic developing device capable of normal conveyance downstream.
[0009]
[Means for Solving the Problems]
In order to solve the above-described problems and achieve the object, according to the present invention, the photographic paper that has been preliminarily cut to a desired cut size and then subjected to exposure printing is arranged in two rows on the left and right sides of the conveyance path. In a photographic developing apparatus provided with sorting means for sorting and transporting, the sorting means is driven by an upstream drive roller disposed at a distance equal to or less than the cut size along the transport direction of the transport path. A first pair of rollers, a second pair of downstream drive rollers and driven rollers, A drive shaft having an oval cross section provided on the drive roller of each of the first and second pairs, the drive roller penetrating through the axis so as to be movable in the left-right direction of the transport path; A guide shaft that is provided on each of the driven rollers of each of the first and second pairs and passes through the axis so that the driven roller can move in the left-right direction of the transport path, and rotational driving of the drive shaft And by stopping The first pair and the second pair rotation Drive motor to be driven and stopped, the first pair, the first pair in contact with both ends of the drive roller and the driven roller in the second pair, and in the left-right direction of the transport path And a moving means for reciprocally driving the second pair, a detecting means for detecting an initial position of the moving means, the driving means, the moving means, and a control means connected to the detecting means. It is characterized by that. In addition, in order to determine the size of the photographic paper that has been cut in advance to the desired cut size, a determination means that is arranged in the approximate center of the transport path and is connected to the control means is the first pair. In the state where the moving means is moved to the neutral position, it is determined whether or not the size is arranged on the upstream side of the transfer path, and is distributed to the left and right rows downstream of the conveyance path. The paper is conveyed downstream by driving the drive motor at the neutral position, while the photographic paper is sandwiched between the first pair and the second pair by driving the drive motor at the neutral position during sorting. After the stop, the control means is configured to control the control unit so that the left or right part is distributed and then the sheet is conveyed downstream by driving of the drive motor.
[0010]
In addition, a second drive motor that drives a third pair of a second drive roller and a second driven roller downstream from the second pair is provided, and the transport speed on the downstream side is higher than the transport speed on the upstream side. In order to configure to stop the drive motor after the conveyance by the low-speed drive of the drive motor is completed and take over the conveyance by the high-speed drive of the second drive motor. The drive motor Clutch means for preventing the braking force due to the detent torque after stopping of the second driving roller and the second driven roller from being applied to the second pair is provided between the driving motor and the first pair. It is characterized by providing.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Preferred embodiments of the present invention will be described below with reference to the accompanying drawings.
[0012]
First, FIG. 1 is an external perspective view in which all covers provided detachably with respect to the housing 2 are shown in order to show the main part of the overall configuration of the photographic developing device 1, and is a paper magazine set as an option. The state where the left storage part 2a is added is shown, and the discharge part of the completed photograph is omitted.
[0013]
As is apparent from this figure, the device 1 is configured to be vertically flat so as not to occupy as much area as possible, while taking into account that the main parts can be easily accessed from the front. As a result, even when the apparatus 1 is installed so as to be quite close to the wall surface, especially in a narrow store in Japan, it is easy to replace or replenish the processing liquid, which is a variety of operations to be performed on a daily basis. The access to the back surface of the apparatus 1 is made unnecessary as much as possible.
[0014]
Further, this paper magazine left storage portion 2a is detachably attached from the side surface of the apparatus 1 indicated by an arrow Y in the figure, and can be added together with the cutter unit 4 so that two pieces as shown in the figure. The paper magazine 3 can be loaded simultaneously. In this way, when the usage frequency is higher than the demand, the photo printing and developing apparatus 1 completed with only the paper magazine right storage portion 2b disposed so that the paper magazine 3 can be added as appropriate. Is first introduced into a laboratory, a photo studio, etc., and the paper magazine left storage unit 2a can be added as appropriate based on the usage frequency after introduction and the consumption of paper including panoramic photos.
[0015]
On the other hand, photographic paper (hereinafter referred to as “paper”) preliminarily coated with a color emulsion on the photographic printing side is wound as a continuous long roll paper having a predetermined width dimension (for example, 89 mm width), and light is completely transmitted. The paper magazine 3 is built in such a manner that it can be rotated freely.
[0016]
The paper magazine 3 is configured symmetrically as shown in the figure so that it can be used in common with the paper magazine left storage portion 2a and the paper magazine right storage portion 2b. Are respectively provided with handles 3a for taking out and loading. In addition, a shutter plate 134, which will be described later, for configuring an automatic opening / closing mechanism of the opening when discharging the built-in roll paper to the outside of the magazine 3 is provided in either the paper magazine right storage portion 2b or the paper magazine left storage portion 2a. Even when it is inserted, it is configured to automatically open and close in the same manner, so that the components are shared and the usability is improved.
[0017]
Further, as will be described later, the cutter unit 4 provided in the vicinity of the paper magazine 3 is for cutting the continuously conveyed paper P into a desired size before baking. The paper P cut into the size is first transported to the exposure printing unit 5 provided in the dark box 7 and temporarily sucked and fixed on the table 8, and ready for printing. The film F is sequentially fed to the illustrated scanner 6 and an optical system 6a including a zoom lens is automatically or manually adjusted so that an image of a desired size is formed on the paper P and printed. It is configured.
[0018]
After this printing operation, the paper P is transported toward the sub-transport unit 9 disposed above the cutter unit 4 and then transported to the main transport unit 10. The main transport unit 10 is provided with a greeting unit 11 for printing a greeting or the like on a photograph in the middle of transporting paper so that it can be easily attached and detached. For this reason, it is necessary to access the main transport unit 10 frequently, and the main transport unit 10 is configured to be easily pulled out in front of the housing 2 as described later.
[0019]
Further, on the downstream side of the main conveying unit 10, processing tanks 12 for sequentially performing development, bleaching, and washing with water after baking are provided in a stepped manner as shown in the figure, and provided between the processing tanks 12. The direction is changed by the reversing roll 13 and is sent to the drying unit 17 so as to be finally discharged to the outside of the apparatus 1 after drying.
[0020]
On the other hand, a replenishment tank 15 for replenishing the treatment liquid is provided in the lower part of the middle stage of the treatment tank 12, while the used treatment liquid can be collected through the drain 14 below the tank, By opening only the cover (not shown), consideration is given to performing all the daily tasks.
[0021]
A power supply unit 19 is provided in the housing 2 that occupies the space below the drying unit 17, and processor control for performing various controls related to the processing tank 12 is provided on the power supply unit 19. A unit 18 is provided, and is configured to control the entire apparatus while exchanging various control data with the main control unit 16 that controls paper conveyance fixed to the left side surface of the dark box 7. Has been.
[0022]
Next, FIG. 2 is an external perspective view of an enlarged main part showing a state of paper conveyance in the main conveyance 10 of FIG.
[0023]
In this figure, the same reference numerals are given to the components that have already been described, and the description will be omitted. The paper P cut by the cutter unit 4 is adsorbed by a large number of holes formed on the table 50. Is sucked to the table side without a gap. Below this table 50, a suction part 51 that can be rotated in the direction of the arrow d3 shown in the figure by a turning motor is provided so as to be able to reciprocate in the transport direction, and the paper P is held and printed at the position shown in the figure. ing.
[0024]
After this printing, the paper P is transported toward the main transport unit 10 in the direction of the arrow d4, and at the position of the paper P1 in the figure, it is determined whether or not it is large format PL, and then transported in the direction of the arrow d5. The Here, when the paper size is small (127 × 89 mm), the paper is distributed to the left and right so as to be in the positions of P3, P4, P5, and P6 so that the inside of the processing tank 12 is arranged in two rows. Transport. Thus, two rows are conveyed so that the processing speed can be increased. Similarly, in the case of a portrait such as a panoramic photograph (254 × 89 mm), it can be conveyed in two rows in the same manner.
[0025]
On the other hand, when it is desired to perform printing so as to be orthogonal to the conveyance direction of the film loaded in the film scanner 6, the turning motor 52 is driven 90 degrees in the direction of the arrow d3 so that the printing can be performed. With this paper, all kinds of different sizes can be baked.
[0026]
FIG. 3 is an external perspective view showing a state in which the main transfer unit 10 and the processing tank 12 shown in FIG. 1 are taken out. In this figure, the paper magazine 3 is configured so that it can be taken out in the directions of arrows f1 and f2 after opening a cover (not shown). The cutter unit 4 is configured to be taken out in the direction of the arrow f3, and the sub-transport unit 9 is configured to be taken out in the direction of the arrow f4 after removing a fixing screw (not shown).
[0027]
On the other hand, since the main transport unit 10 has a considerable weight, after moving in the direction of the arrow f5 so as to be in the position shown by the broken line and the position shown by the solid line, the main transfer unit 10 can maintain the moving state in the one-supported state. The ink ribbon replacement work of the print head and the work of replacing each unit 11 including the greeting unit can be easily performed. Then, the treatment tank 12 can be taken out in the direction of the arrow f7 in the drawing, and the reverse roll 13 can be taken out in the direction of the arrow f6, respectively, so that the water washing operation can be easily performed. The above is the configuration in which the design philosophy of the device 1 has flourished. The individual configuration will be described below with reference to FIGS. 4 to 26.
[0028]
FIG. 4 is a block diagram of the paper transport unit of the photographic printing and developing apparatus 1, and FIG. 5 is a block diagram of the main part of the lower part of FIG.
[0029]
First, in FIG. 5, a stepping motor which is a roll paper drive source for driving a gear meshing with a gear provided in a core of the roll paper RP in order to drive the roll paper RP of the roll paper magazine 3 is formed. The first motor 20 is fixed to the housing 2. By rotating the first motor 20 in the forward and reverse directions with a predetermined number of pulses, the diameter of the roll paper RP is automatically measured as will be described later, and the slack of the paper is positively generated. The load is reduced so that accurate conveyance can be performed.
[0030]
Further, a drive roller 21 with a clutch that is rotatably provided at a base (not shown) fixed to the housing 2 is rotatably provided in a contact state so that an idle roller 22 rotates simultaneously. Each drive roller described below is rotatably provided at a base (not shown) fixed to the housing 2, while each idle roller is freely rotatable in contact with the drive roller so as to rotate simultaneously. Therefore, only the name will be described.
[0031]
Next, a timing belt 24 stretched around a timing pulley 23a fixed to the output shaft of the second motor 23 of the stepping motor is hung on the drive roller 21 with clutch and the drive roller 25 with clutch. Each drive roller is driven by driving the second motor 23 in response to the pulse from.
[0032]
Further, immediately after the paper magazine is loaded, the leading edge of the paper passes through the first sensor S1 and is conveyed to the portion of the idle roller 26 provided facing the drive roller 25 with the clutch by the driving of the second motor 23. Further, after passing through the second sensor S2, it passes between the fixed blade 29 and the rotary blade 30 of the cutter unit 4.
[0033]
On the other hand, the sub-transport unit 9 is provided to send the paper P after exposure printing to the main transport unit 10 as described above, and a guide plate 32 that is swung by the solenoid 31 is disposed in the vicinity of the rotary blade. When the paper returned by the reverse rotation of the drive roller 35 and the idle roller 36 after exposure printing is conveyed to the main conveyance unit 10 while being retracted when the cutter unit 4 is cut by driving the solenoid 31, the guide plate 32 is moved downward by a spring force (not shown) so that the paper is fed between the idle roller 33 and the drive roller 34.
[0034]
For this purpose, a timing belt 38 meshing with a pulley 40 a provided on the output shaft of the fourth motor 40 of the stepping motor is stretched between the drive roller 35 and the drive roller 34 in the sub-conveying section 9. Yes.
[0035]
The solenoid 37 is configured to move between a state where the drive roller 35 is pressed against the idle roller 36 and a state where the drive roller 35 is separated from the idle roller 36.
[0036]
With the above configuration, the first motor 20, the second motor 23, and the fourth motor 40 are individually driven as will be described later so as to convey the paper, while the table of the exposure printing unit 5 is activated when the apparatus 1 is started up. The paper is transported to the third sensor S3 provided on the back surface of the paper 50.
[0037]
The cutter unit 4 shown by a two-dot chain line in the figure is for cutting by driving the rotary blade 30 by the rotation of a third motor 27 which is a cutter driving motor, and detecting the position of the rotary blade 30 as a dog detection sensor. As will be described later, the sub-conveying unit 9 can be started immediately after cutting, as will be described later.
[0038]
A suction part 51 for holding the cut paper at the exposure printing position is mounted on a turning motor 52. A vacuum valve 53 is connected to the suction portion 51, and further connected to a vacuum pump 55 via a pipe 54. Further, the suction portion 51 and the turning motor 52 are mounted on a carriage (not shown), and the carriage is reciprocated by a timing belt 57 stretched between an output pulley of the fifth motor 56 and a timing pulley 59. It is configured. The fan 58 is provided in an airtight chamber below the table in order to generate a negative pressure at a suction hole formed in the table.
[0039]
Referring to FIG. 4 again, a pair of a drive roller 60 and an idle roller 61 of the main transport unit 10 is provided upstream of the idle roller 33 and the drive roller 34 of the sub transport unit. Further, a fifth sensor S5 is provided upstream of the pair of drive roller 60 and idle roller 61, and the pair of drive roller 62 and idle roller 63 is loaded further upstream, and the above-mentioned greeting unit is loaded. Above the opening, a pair of a drive roller 64 and an idle roller 65 is disposed. The above drive rollers 60, 62, and 64 are configured to obtain a driving force from a sixth motor 80 that is a stepping motor.
[0040]
Next, as described with reference to FIG. 2, when the paper size is small and can be transported in two rows, the sorting operation is performed such that the paper is sorted left and right so as to be positioned at P3, P4, P5, and P6. A pair of a drive roller 66 and an idle roller 67 and a pair of a drive roller 68 and an idle roller 69 are provided.
[0041]
Further, on the downstream side of the pair of the drive roller 66 and the idle roller 67, a sixth sensor S6 for detecting the leading edge and width of the conveyed paper is disposed.
[0042]
A drive roller 70 and idle roller 71 pair is disposed upstream of the drive roller 68 and idle roller 69 pair. Further, a seventh sensor S7 and an eighth sensor S8 are disposed upstream thereof, and the paper transport position is optically detected in a non-contact manner as in the first sensor S1 to the sixth sensor S6. Like to do.
[0043]
At the top of the main transport unit 10, a drive roller 72 that obtains power through a coupling from a motor (not shown) provided to drive the transport rollers of the processing tank 12 is provided with an idle roller 73, It is provided so as to rotate together with the idle roller 74, and the paper is sent to the processing tank 12 through a shutter (not shown) that is opened and closed by a shutter solenoid 75.
[0044]
On the other hand, the eighth motor 82, which is initially positioned by the tenth sensor S10, drives the pair of the drive roller 66 and the idle roller 67 and the pair of the drive roller 68 and the idle roller 69 to perform the left / right sorting operation. Similarly, it is a stepping motor.
[0045]
Each of the motors and sensors described above is connected to the main control unit 16 in which a predetermined motor driver and sensor amplifier are mounted, and the control described later is performed.
[0046]
FIG. 6 is a front view of the main transport unit 10, and FIG. 7 is a schematic diagram showing the roller arrangement of FIG. In both figures, the components already described in FIGS. 5 and 6 are denoted by the same reference numerals and will not be described.
[0047]
The main transport unit 10 is provided with the above motors and rollers between two base plates 79 provided substantially symmetrically on the left and right, and each greeting unit 11 is placed in the opening 79a shown in FIG. It can be loaded. In addition, the sixth motor 80, the seventh motor 81, and the ninth motor 83 are arranged as shown in FIG.
[0048]
First, the timing belt 84 is hung on the timing pulley 80a of the sixth motor 80 so as to push the back with the tension roller 85, and the timing pulleys (not shown) of the drive rollers 60 and 62 are driven by the belt. ing. A timing belt 86 is stretched between a timing pulley (not shown) of the drive roller 62 and a timing pulley (not shown) of the drive roller 64, and transmits the rotational driving force of the sixth motor 80 to each drive roller. It is configured as follows.
[0049]
A one-way clutch 91 is built in the timing pulley 81a fixed to the output shaft of the seventh motor 81 so that the timing pulley 81a can be driven only in the paper transport direction. Then, after the distribution, when the paper is transported by the downstream ninth motor 83 and the energization of the seventh motor 81 is stopped to distribute the next paper, the detent torque load of the seventh motor 81 is stopped. The configuration is such that the influence does not reach the paper transport by the ninth motor 83.
[0050]
A timing belt 87 is stretched between a timing pulley 81 a fixed to the output shaft of the seventh motor 81 and a timing pulley (not shown) of the drive roller 66. A timing belt 88 is stretched between the drive roller 66 and the drive roller 68 so that a predetermined tension is generated by a tension roller 89. A timing belt 90 is stretched between a timing pulley 83 a fixed to the output shaft of the ninth motor 83 and a timing pulley (not shown) of the drive roller 70.
[0051]
Next, in FIG. 7, the same reference numerals are given to the components that have already been described, and the description thereof will be omitted. When the description is not given, a dot matrix head for back printing is provided between the drive rollers 60 and 62. The first print head 95 and the second print head (not shown) are arranged, and are configured to record desired matrix character information via the ink ribbon of the ink ribbon cartridge 96 provided in a replaceable manner. ing.
[0052]
In addition, there is only one print head for models that have only one print head as in the past and models that require more information to be recorded and printed on the back side of the paper, such as the newly developed IX film. Since printing in one row by the head is insufficient, two are provided so as to record in two rows. Further, as shown in FIG. 7, it goes without saying that the inter-axis distances D1 and D2 of each roller are set so as not to hinder the conveyance of the paper of the minimum size.
[0053]
Further, the right edge portion of the base plate 79 is formed with a concave portion at the top and bottom, and in these concave portions, an upper slide rail 200 having a function of supporting a load when pulled out and a function of sliding in the front-rear direction, The slide rail 201 is configured to infiltrate. The sixth sensor S6 includes the tip detection S6-1 and the width detection S6-2 as described above.
[0054]
Next, FIG. 8 is a block diagram showing a state after the optional paper magazine left storage 2a is added. In this figure, the table 50 is basically symmetric and the guide plate 32 is omitted from the configuration described in FIG. 5, and includes the paper magazine 3 as described above and is as common as possible. It consists of parts.
[0055]
Further, in this figure, the same reference numerals are given to the components that have already been described, and the description will be omitted and limited to the characteristic portions. The roll paper of the roll paper magazine 3 loaded in the paper magazine left storage portion 2a will be described. An eleventh motor 320 that drives a gear meshing with a gear provided in the core of the roll paper is fixed to the housing 2. As will be described later, the roll paper diameter is automatically measured by the rotational drive in the forward and reverse directions corresponding to the predetermined number of pulses from the control circuit of the first motor 320, and the slack of the paper is positively generated. The load during paper conveyance is reduced so that accurate conveyance can be performed. A drive roller 321 with a clutch that is rotatably provided at a base (not shown) fixed to the housing 2 is rotatably provided in a contact state so that the idle roller 322 rotates simultaneously.
[0056]
Next, a timing belt 324 stretched around a timing pulley fixed to the output shaft of the twelfth motor 323 of the stepping motor is hung on the drive roller 321 with clutch and the drive roller 325 with clutch. Each drive roller is driven by driving the motor 323 with a predetermined number of pulses.
[0057]
Immediately after loading the paper magazine, the second motor 323 is driven so that the leading edge of the paper passes through the eleventh sensor S301 and is conveyed to a portion of the idle roller 326 provided facing the drive roller 325 with the clutch, Further, after passing through the twelfth sensor S302, it passes between the fixed blade 329 and the rotary blade 330 of the cutter unit.
[0058]
On the other hand, the sub-conveying unit 309 is provided to send the cut paper to the exposure printing unit 5, and for this purpose, the sub-conveying unit 309 includes a pulley provided on the output shaft of the fourteenth motor 340 of the stepping motor. The timing belt 338 meshing with the drive roller 335 is stretched.
[0059]
The solenoid 337 is for moving between a state in which the idle roller 336 is pressed against the drive roller 335 and a state in which the idle roller 335 is separated from the drive roller 335. With the above configuration, the eleventh motor 320, the twelfth motor 323, and the fourteenth motor 340 are individually driven to perform the paper transport, while the apparatus 1 is activated on the back surface of the table 50 of the exposure printing unit 5. In this way, the roll diameter of the roll paper and the distance between the sensor S302 and the sensor S4 are measured.
[0060]
Further, the cutter unit shown by a two-dot chain line in the figure is for cutting by driving the rotary blade 330 by rotation of a thirteenth motor 327 which is a cutter driving motor, and detecting the position of the rotary blade 330 for dog detection. As will be described later, the speed of the sub-conveying unit 9 can be activated immediately after cutting, as described later.
[0061]
With the configuration set as an option as described above, the paper after cutting is sucked in the suction hole formed in the table while being transported to the suction portion 51 by the transport mechanism and subjected to exposure printing. In this manner, roll paper having a width that cannot be conveyed from the magazine loaded in the paper left storage portion 2b can be supplied.
[0062]
Next, FIG. 9 is an AA arrow view of FIG. 6, in which the main transport unit 10 is pulled out from the front surface 2 f of the housing 2 and supported by the upper slide rail 200 and the lower slide rail 201. FIG. In this figure, the same reference numerals are given to the components that have already been described, and the description will be omitted, and only the features will be described. The seventh motor 81 and the ninth motor 83 are connected to the base plate 79 on the front side. Each timing belt 87, 88, 90 is fixed to the timing pulley of each drive roller as shown in the figure so that it can be easily exchanged even if it is in the supported state as shown. I have to. Further, as described above, the eighth motor 82 for reciprocating the main carriage 100 to the left and right and the drive rollers 60, 62, and 64 are driven to drive the drive rollers 66 and 68 to the left and right to distribute the left and right. The sixth motor 80 is fixed on one base plate 79 as shown.
[0063]
Further, a drive sprocket 72a is interlocked with the drive roller 72, which is adapted to obtain a driving force from a driving motor (not shown) provided in the processing tank, and the main transport unit 10 is inserted and set to the back side of the housing 2. In a state, it is configured to automatically engage to obtain a driving force. On the other hand, the first print head 95 and the second print head 97 below the drawing are provided side by side as described above.
[0064]
As described above, a large number of components can be attached to each other's base plate 79, and an upper plate 105 that also serves as a reinforcing member that connects each other and a lower plate 106 are provided between the base plates 79. The upper plate 105 is completely fixed by screws or the like so as to connect the two base plates 79. The upper plate 105 is provided with locking holes 105a and 105b which are formed in a substantially house shape as shown in the figure, and at the apex of the roof, on the side portion on the upper slide rail 200 side. The fixed flanged pins 200a and 200b are inserted so as to support the load on the upper portion of the main transport unit 10.
[0065]
Further, when separating the main transport unit 10 from the slide rail 200, the pins 200a and 200b are moved downward from the roof portions of the locking holes 105a and 105b by lifting the main transport unit 10 upward, It is configured to pass through the pin flange and remove.
[0066]
On the other hand, the lower plate 106 is provided so as to be movable in the vertical direction between the two base plates 79. For this purpose, both edge portions of the lower plate 106 are bent so as to be substantially parallel to the base plate 79, and a pair of left and right pins 110, 111 are implanted in the bent portion, and these pins 110, 111 is guided so that it can move up and down in the vertical groove of the base plate. Similarly to the upper plate 105, the lower plate 106 is provided with locking holes 106a and 106b that are formed in a substantially house shape as shown in the figure. The flanged pins 201a and 201b fixed to the side surface portion on the rail 201 side are inserted into the lower portion of the main conveyance portion 10 so as to support the load through the pair of left and right coil springs 113.
[0067]
With this configuration, when separating the main transport unit 10 from the lower slide rail 201, the pins 201a and 201b are moved downward from the roof of the locking holes 106a and 106b by lifting the main transport unit 10 upward. After moving to, the flange portions of the pins 201a and 201b are passed through and removed.
[0068]
As described above, the upper and lower slide rails 200 and 201 support the load W of the main transport unit 10 in the vertical direction while supporting the load W downward via the pair of left and right coil springs 113. , 201 can reliably share a load of about 30 kg, which is the total weight of the unit.
[0069]
That is, for example, when a relatively small load rail with a load resistance of 20 kg per slide rail is used, if the lower plate 106 is completely fixed between the base plates 79 like the upper plate 105, Unless the vertical distance of the upper and lower slide rails 200, 201 and the vertical distance of the lower plate 106 or the upper plate 105 are set strictly, the upper plate 105 is supported by the flanged pins 200a, 200b of the upper slide rail 200, The lower plate 106 cannot be supported by the pins 201a and 201b of the lower slide rail 201.
[0070]
Therefore, the upper slide rail 200 is securely supported by the pins 200a and 200b so that the upper plate 105 is supported by 20 kg, which is the performance of the slide rail, and the remaining 10 kg is lowered via a pair of left and right coil springs 113. So that the load of about 30 kg can be surely shared by both of the two slide rails 200 and 201, the small slide rail can be used, and the concave portion can be made small. 10 can be configured compactly. By the way, when a higher-order slide rail with a load capacity of 40 kg is used, the concave portion is increased about four times.
[0071]
FIG. 10A is an enlarged front view of the left part of the lower plate 106 of FIG. FIG. 10B is a cross-sectional view taken along the line AA in FIG. In both figures, since the schematic configuration has been described with reference to FIG. 9, the components that have already been described are denoted by the same reference numerals and description thereof is omitted. A groove 79a is formed by machining, and the pin 110 and the pin 111 are prevented from falling off the vertical groove 79a by the flange portion, and are provided so as to be vertically movable. Further, the pin 110 and the pin 111 are provided on the side surface portion of the lower plate 106.
[0072]
On the other hand, the upper and lower coil springs 113 provided on the left and right are respectively hung on the spring hooks 112 fixed to the lower plate 106, and the lower end 113 b of the coil spring is fixed to the inner surface of the base plate 79. The lower plate 106 is urged to move downward in a state where the main conveying unit 10 is attached to the housing. Further, the flange portion of the flanged pin 201a fixed to the side surface portion on the lower slide rail 201 side at the apex portion of the roof of the locking hole 106a-1 drilled so as to have a substantially house shape as illustrated. 201a infiltrates with a stroke L, and supports the pin 201a on the upper inner surface of the locking hole 106a-1, and supports the load at the lower part of the main transport unit 10 via the left and right coil springs 113, respectively. I am doing so.
[0073]
Note that the main transport unit 10 is not limited to the configuration in which the main transport unit 10 is supported by the upper and lower slide rails as described above, and various configurations are possible, and the load of the main transport unit 10 that is relatively heavy is essential. In the case where the load can be supported in a single-supported state by at least a plurality of slide rails, it is possible to use as small a slide rail as possible.
[0074]
Next, FIG. 11 is an external perspective view showing a state in which the paper magazine 3 is stored in the paper magazine right storage portion 2b. Although not shown, the paper magazine 3 can be commonly used for the left and right storage portions. Therefore, it is configured in substantially the same manner when stored in the paper magazine left storage portion 2a.
[0075]
Therefore, as representatively described in the description made with reference to FIG. 11, the paper magazine is configured to be bilaterally symmetric and is provided with handles 3a (the back side is omitted) on both the front and back surfaces. Further, a shutter plate 134, which will be described later, which constitutes an automatic opening / closing mechanism of the opening when discharging the built-in roll paper to the outside, is inserted into either the paper magazine right storage portion 2b or the paper magazine left storage portion 2a. However, it is configured to open and close automatically in the same way.
[0076]
For this purpose, as shown in the figure, the first cam member 140 and the second cam member 141 are provided symmetrically, and the opening 133 formed in the magazine case 131 is opened by the action of these cam members. It is configured.
[0077]
The configuration of the magazine case 131 will be described below. First, the magazine case 131 is formed of an injection resin from a resin material that completely blocks light, and is configured so that roll paper can be loaded and replaced by opening the lid appropriately in a dark room. It is fixed to the four corners of the bottom surface of the magazine case 131 by two guide rails 130 arranged on the bottom surface of the right storage portion 2b of the housing 2, and four sliders 132 that also serve as legs are provided. By sliding in the facing surfaces of these guide rails 130 and pushing them in the direction of the arrow g1 in the figure, a normal loading position is obtained.
[0078]
Further, at the final position where the paper magazine 3 does not move any more, a locking member 151 is provided on the housing 2 side so that the paper magazine 3 does not move and is pushed substantially horizontally from the wall surface 2t. In this final stop position, the first cam member 140 and the second cam member 140 are inserted into the magazine case 131 from the opening 131f or the opening 131g so as to block the respective openings 131f and 131g. The cam member 141 is moved in the arrow g2 direction, and the columnar member 135 fixed to the shirter plate 134 is moved in the arrow g3 direction.
[0079]
Next, referring further to the external perspective view before loading the paper magazine 3 in FIG. 12, the shutter plate 134 is moved by the pair of coil springs 137 so as to always close the opening 133 shown by the solid line.
[0080]
FIG. 13 is a front view of the paper magazine 3 in the state after loading shown in FIG. 11 as viewed from the opening 133 side. In this figure, the shutter plate 134 is guided to move in the vertical direction. The cylindrical member 135 is fixed at the lower central portion. Further, the upper ends of the pair of coil springs 137 are hung on a spring hooking portion 136 installed in the magazine case 131, while the lower ends are hung on hook portions 134 a of the shutter plate 134. It always moves so as to block the opening 133.
[0081]
Further, the first cam member 140 and the second cam member 141 that integrally form a slope contacting the outer peripheral surface of the columnar member 135 are movable by a guide block 138 and a guide block 139 fixed to the magazine case 131, respectively. While being held, the first cam member 140 and the second cam member 141 completely block the openings 131f and 131g by the action of the coil spring 144 shown in FIG. 12, so that no light enters inside. I have to. For this reason, the first cam member 140 and the second cam member 141 are formed with steps as shown in the drawing.
[0082]
With the above configuration, as shown in FIG. 14, in the state before loading, the shutter plate 134 is moved upward by the urging force of the coil spring 137 so that the opening 133 is closed. After loading, as shown in FIGS. 11 and 13, the push pin 145 enters the magazine case 131 through the opening 131f and presses the second cam member 141 in the arrow g2 direction. A component force is generated to move the member 135 downward, and the shutter plate 134 is moved downward to open the opening 133.
[0083]
Similarly, when a magazine is loaded into the paper magazine left storage portion 2a, the push pin 145 enters the magazine case 131 through the opening 131g and presses the first cam member 141. Is generated, and the shutter plate 134 is moved downward to open the opening 133.
[0084]
After being loaded into the paper magazine right storage portion 2b as described above, the pair of pins 150 fixed to the upper surface of the magazine case 131 is locked by the locking member 151 provided on the housing 2 side. So that it does not move from the loading position unless the lever is operated.
[0085]
15 is an external perspective view of a magazine fixing mechanism fixed to the ceiling surface of the paper magazine left and right storage portions 2a and 2b. FIG. 15 (a) shows a fixed state, and FIG. 15 (b) shows a released state. Is illustrated.
[0086]
In this figure, a mounting plate 152 processed from a metal plate is fixed to the ceiling surface of the paper magazine left and right storage portions 2a, 2b, and a horizontal groove formed so that one end of the mounting plate 152 is open. The pins 150 fixed to the upper surface of the magazine cover intrude into 152 g, respectively, and guide the pins 150 to the roots of the lateral grooves 152 g to guide the upper surface side of the paper magazine without backlash.
[0087]
On the other hand, a lever 153 that can be operated in the direction of the arrow a1 in the drawing in the paper magazine left and right storage portions 2a and 2b of the apparatus 1 is provided so as to be rotatable around the rotation fulcrum 152a of the mounting plate 152. Yes. Further, the other end of the lever 153 supports the locking member 151 so as to be movable in the direction of the arrow, and the claw portion of the locking member 151 is locked to each pin 150 as shown in FIG. It is configured to be able to move to a state to be released and to a state to be released as shown in FIG.
[0088]
Further, a sub-lever 154 is provided on the locking member 151 so as to be moved forward by a coil spring 155. One of the pins 150 is constrained from the front and rear direction, so that the magazine is not fixed. It is in a state.
[0089]
Then, as shown in FIG. 15B, when the lever 153 is moved in the direction of the arrow a1 in order to enter the released state, the sub lever 154 moves in the direction of the arrow a2, and the sub lever 154 is moved in the direction of the arrow a3 by the pulling force of the coil spring 155. And the restraint state with respect to the pin 150 is released.
[0090]
Next, FIG. 16 is a schematic configuration diagram of each component provided in the paper magazine 3. The components already described are denoted by the same reference numerals, description thereof is omitted, and only the characteristic portions are described.
[0091]
First, a timing belt 160 is interposed between a pulley of a first motor fixed to the housing 2 side for driving the roll paper RP and a large pulley 161 of a timing pulley pivotally supported on the housing 2 side. The small pulley 162 provided integrally with the large pulley 161 is driven. Between this small pulley 162 and a timing pulley 165 that is pivotally supported in the housing 2, a timing belt 163 that prevents the occurrence of tarmi by a tension roller 164 is stretched.
[0092]
Further, a gear coupling 176 made of an inner gear is fixed to the timing pulley 165, and when the paper magazine 3 is loaded in the direction of the arrow g1 as described in FIG. 11, it is integrated with the core of the roll paper RP. The outer gear side of the gear coupling 176 is meshed with the gear 166 (illustrated by a one-dot chain line) previously meshed with the gear 167 fixed to the gear 167 in the forward / reverse direction of the first motor 20. The driving force can be transmitted in such a way as to completely prevent light from entering.
[0093]
A timing belt 168 (shown by a one-dot chain line) is stretched between the timing pulley 23 a of the second motor 23, the pulley 170 with clutch, and the pulley 171 so as to prevent tarmi by tension rollers 169 and 174. ing. In addition, a timing belt 173 (shown by a one-dot chain line) is stretched between the pulley 172 integrally fixed with the pulley 171 and the pulley 175 with a clutch so as to prevent a tarmi by a tension roller 174. Yes.
[0094]
By arranging as described above, the components shown in FIGS. 5 to 8 can be arranged in a very limited space. The left storage portion 2a side shown in FIG. 8 is substantially the same as FIG.
[0095]
Next, the cutter unit will be described with reference to the side view of FIG. In the figure, components that have already been described are denoted by the same reference numerals, description thereof is omitted, and description is limited to characteristic portions.
[0096]
First, the rotary blade 30 and the fixed blade 29 shown in a broken line constitute a so-called rotary cutter, and its pivotal support portion 30a so that the rotary blade 30 rotates counterclockwise in the cutter base shown by a two-dot chain line. Is supported on both sides of the base. Further, the fixed blade 29 is provided with an urging means (not shown) so that the cutting blade tip of the fixed blade 29 abuts against the outer peripheral surface of the rotary blade 30 without any gap so as to cut the paper. It is configured.
[0097]
The auxiliary dog 180 is fixed to the shaft support 30 a of the rotary blade 30 by the set screw together with the arm member 183, and the auxiliary dog 180 passes through the dog detection switch 28 mounted on the circuit board 181. Thus, the state immediately after cutting by the rotary blade 30 can be detected. The arm member 183 is provided with a link 185 having one end pivotably supported by a bearing 184 and the other end pivotally supported by a motor disk 187 by a bearing 186. On the other hand, a main dog 188 is fixed to the motor disk 187, and the cutter sensor 182 mounted on the substrate 181 is configured to detect the rotational position of the third motor 27.
[0098]
In the above configuration, the paper continuously conveyed from the direction of the arrow d in the figure is cut into a cut size as the third motor 27 is driven and conveyed in the direction of the arrow d1, while FIG. The secondary dog 180 at the position shown in a) is detected prior to the cutter sensor 182 by the dog detection switch 28, and a signal is output to the downstream transport unit to start the motor and the like to Prepare to accept.
[0099]
According to the cutter unit 4 including the crank mechanism configured as described above, when the motor is driven only in one direction and the main dog 188 of the motor disk 187 is detected as shown in FIG. A reliable cutter control can be performed by outputting a rotation stop signal of the three motors 27. The control of the cutter unit will be described later.
[0100]
Next, a characteristic configuration of the sub-transport unit 9 will be described with reference to an enlarged view of a main part in FIG. 18 and a plan view in FIG. In both figures, the same reference numerals are given to the components that have already been described, and description thereof is omitted.
[0101]
First, in order to transport the paper transported in the direction of the arrow d1 after being cut by the cutter unit 4 to the table 50, a guide plate 32 that is swung to a position illustrated by a solid line and a broken line in the drawing is indicated by a broken line. Driven to position. For this purpose, rotation shafts 192 are provided at both ends of the guide plate 32 and are held so as to be able to swing on the base plate 191 of the sub-conveying unit 9. In addition, a spring hook 193 is integrally formed on the guide plate 32, and the guide plate 32 is formed by a pulling action of a coil spring 194 stretched between the spring hook 195 and the spring hook 195 planted on the base plate 191. It is urged to move to the position indicated by the solid line in the figure.
[0102]
The electromagnetic solenoid 31 fixed to the base plate 191 generates a suction force that overcomes the urging force that moves in the direction shown by the solid line as described above, and moves the guide plate 32 to the position shown by the broken line.
[0103]
For this purpose, a pin 196 is press-fitted or inserted into the plunger 198 of the solenoid 31, and the connecting plate 197 is rotatably held while the connecting plate 197 is rotated with respect to the guide plate 32 by the pin 199. Hold freely. In FIG. 19, pulleys 190 are fixed to the rotation shafts 33a and 34a of the drive roller 34 and the idle roller 33, and spring rings are stretched around the respective pulleys. To ensure that it is communicated.
[0104]
With the above configuration, the plunger suction operation can be reliably transmitted to the guide plate 32 via the connecting plate 197 as the electromagnetic solenoid 31 is energized without loss. That is, conventionally, the plunger attracting operation by energizing the electromagnetic solenoid 31 is directly applied to the guide plate without going through the connecting plate 197, so that the component force not involved in the swinging of the guide plate is the guide force. Although it acted on the plate and caused wear, the conventional problem was solved by the rotational operation of the pin by providing the connecting plate in the middle in this way.
[0105]
Next, FIG. 20A is an external perspective view in which the main part is cut away to show the arrangement of the first print head and the second print head. In this drawing, the same reference numerals are given to the components that have already been described, and the description will be omitted, and the description will be limited to the characteristic portion. A guide section on the emulsion surface side when the paper P is conveyed to the arrow d5 side between the drive roller 60 and the drive roller 62 driven in the direction of the arrow r1 in the drawing is configured.
[0106]
In addition, the paper guide plate 220 has a platen plate 235 (shown in FIG. 20B) that can be adjusted with respect to the print head by screws, while the illustrated guide portion 220a that prevents paper jam is formed. The platen in the first print head 95 or the second print head 97 is configured to receive the printing pressure during the printing operation.
[0107]
A paper guide plate 221 is fixed to face the paper guide plate 220 so as to guide the back side of the paper. A printer base 222 is fixed above the paper guide plate 221. The print heads 95 and 97, which are fixed so that the dot rows 95a and 97a are arranged side by side as shown in the figure, are attached to the printer base 222. It is fixed.
[0108]
Next, FIG. 21 is an external perspective view seen from the printer base 222 side, and as shown in FIG. 9, the main transport unit 10 is pulled out from the housing 2 to the first print. A state in which the head 95 is pulled out is shown. FIG. 22 is a plan view for explaining the operation. 21 and 22, the printer base 222 is formed by processing spcc having a thickness of 1.6 mm, for example. The printer base 222 relays and integrates the base plate 79 and the first and second print heads 95. , 97 has sufficient mechanical strength to support the reaction force when energized.
[0109]
Two guide grooves 222a are formed in the printer base 222, and the printer base 222 is fixed to the head base plate 223 that fixes the printer base 224 in which the ribbon feed motor of the second print head 97 is built. The pin 225 fixed to the bent portion that is bent at a right angle along the guide groove 222a is guided along the guide groove 222a. An ink ribbon cartridge 96 is detachably provided on the printer base 224. The head base plate 223 has a guide groove 223a and an arcuate guide groove 223b. The guide groove 223a and the arcuate guide groove 223b are guided by a second pin 226 fixed to the printer base 222. It is comprised so that.
[0110]
The head base plate 227 fixing the printer base 228 incorporating the ribbon feeding motor of the first print head 95 is fixed to a bent portion that is bent at a right angle along the printer base 222. The first pin 229 is guided along the guide groove 222a so that it can be pulled out as shown. An ink ribbon cartridge 96 is detachably provided on the printer base 228. The head base plate 227 has a guide groove 227a and an arcuate guide groove 227b (shown by a broken line) continuous to the guide groove 227a. The guide groove 227a and the arcuate guide groove 227b are formed on the printer base. It is configured to be guided by a second pin 230 fixed to 222. In addition, when the first pin 229 on the head base plate 227 is pulled out to the maximum as shown in the drawing, the first pin 229 comes to a stop by hitting the front side of the guide groove 222a, so that no further drawing can be performed. It is configured.
[0111]
Further, by disposing the ink ribbon cartridges 96 so as to face each other as shown in the drawing, the first print head 95 and the second print head 97 can be provided close to each other, as described above. When performing two-line printing, care is taken so that the line spacing of the two-line print record does not become too wide.
[0112]
As the print head, an ink jet recording type, which uses special ink that is not affected by the processing liquid, or a thermal transfer type, can be used. Needless to say, it is not limited to.
[0113]
Next, FIG. 22 is a plan view showing a procedure for replacing the ink ribbon cartridge 96 of the first print head, and the second print head side is also replaced in substantially the same manner. A description will be given representatively with respect to the cartridge, and the components already described in FIG.
[0114]
First, in FIG. 22A, a screw hole 231 is provided in the printer base 222, and a screw 232 indicated by a broken line is turned in the opposite direction to the arrow h1 with respect to the screw hole 231 to thereby turn the screw. The head base plate 227 can be fixed to the printer base 222 so as to be screwed into the hole portion 231. Here, the gripping portion of the fixing screw 232 is knurled so as to prevent slipping. Print recording is performed in the state shown in FIG. 22A, and the ink ribbon cartridge 96 is replaced when the printing becomes blurred due to the use of the ink ribbon.
[0115]
At the time of this replacement, as shown in FIG. 21, the first print head 95 and the second print head 97 are quite close to each other so as to be substantially back-to-back. After the ink ribbon cartridge 96 has been pulled out of the base 222, the ink ribbon cartridge 96 faces the front side, and then replaced. For this purpose, in the state shown in FIG. 22A, the fixing screw 232 is turned in the direction of the arrow h1 so that only the screw portion of the fixing screw 231 is removed from the screw hole portion 231.
[0116]
Subsequently, as shown in FIG. 22B, the first pin 229 fixed to the head base plate 227 is guided by the guide groove 222 a and is fixed by the second pin 230 fixed to the printer base 222. The guide groove 227a of the head base plate 227 is guided, and the head base plate 227 is pulled out from the printer base 222 in the direction of the arrow h2 by being guided at two points and moving straight.
[0117]
In this way, the second pin 230 abuts against the guide groove 227a and the first pin 229 abuts against the front side of the guide groove 222a. Subsequently, the head base plate 227 is rotated in the direction of the arrow h3 with the first pin 229 as the rotation center. At this time, the pin 230 of the printer base 222 is formed with the first pin 229 as the center. 22 is guided in the arcuate guide groove 227b of 227, and the state shown in FIG.
[0118]
That is, the state shown in the external perspective view of FIG. At this time, the side surface portion of the head base plate 227 made of spcc is attracted and held by the magnet catch 233 fixed to the printer base 222. Thus, since the ink ribbon cartridge 96 is held in the front direction, the ink ribbon cartridge 96 is removed in the direction of the arrow h5 (FIG. 27C) and replaced with a new one.
[0119]
Further, the operation for replacing the ink ribbon cartridge is completed in the state shown in FIG. Thereafter, the main transport unit 10 is slid by the slide rails 200 and 201 and returned to the housing 2 to complete the ink ribbon cartridge replacement operation. On the other hand, the ink ribbon cartridge of the second print head 97 is replaced in substantially the same manner as described above.
[0120]
Next, FIG. 24 is an external perspective view of a sorting unit that moves the paper to the positions of the papers P3 and P4 after sorting the paper to the left and right as briefly described in FIG. In the figure, the same reference numerals are given to the components that have already been described, the description will be omitted, and the following description will be limited to the components that have not been described.
[0121]
First, the left and right base plates 79 are provided with bearings (not shown), respectively, and a drive shaft 250 and a guide shaft 252 having a cross-section machined as shown in FIG. I support. A pulley 254 is fixed to each of the drive shaft 250 and the guide shaft 252, and a drive roller 66 provided slidably on the drive shaft 250 by tensioning a spring ring 253 between the pulleys 254. Thus, the idle roller 67 is surely brought into contact with the belt to prevent slipping during conveyance. For this reason, the bearing on the guide shaft 252 side has a clearance that can move in the vertical direction shown in the figure.
[0122]
Similarly to the drive shaft 250, a drive shaft whose cross section is processed in an oval shape and a guide shaft 258 are further arranged on the downstream side, and a drive roller (non-removable) provided slidably on the drive shaft. And the idle roller 69 is guided.
[0123]
As shown in the figure, the main carriage 100 has four thrust bushings 260 fixed at four corners. The main carriage 100 is driven in the directions of the arrows d6-1 and d6-2 shown in the drawing by guiding both side surfaces of the idle rollers 67 and 69 as sliding contact surfaces on the inner wall surfaces of the thrust bushings 260. Accordingly, the idle rollers 67 and 69 are similarly moved in the directions of arrows d6-1 and d6-2.
[0124]
Further, four thrust bushings 260 are fixed at four corners of the sub-carriage 101 provided to face the main carriage 100, and the drive roller 66 and the above-mentioned drive roller 66 are not shown on the inner wall surfaces of the thrust bushings 260. Both side surfaces of the drive roller are guided as slidable contact surfaces, and the oval hole portions 66a and 68a (not shown) of the drive rollers 66 and 68 are formed by the opposed flat surfaces 250a of the oval drive shaft 250. The drive rollers 66 and 68 are driven so as to transmit the rotational force, and the idle roller 67 is driven as the sub carriage 101 is driven together with the main carriage 100 in the directions indicated by the arrows d6-1 and d6-2. , 69 and move in the direction of arrows d6-1 and d6-2 in complete synchronization with That.
[0125]
As described above, in order to drive the main carriage 100 and the sub-carriage 101, the eighth motor 82 fixed to the side surface of the base plate 79 is a so-called double-shaft type, and the timing pulleys 82a and 82b are provided on both shafts. Two timing belts 255 are stretched between these pulleys and two tension pulleys 256 fixed to the inside of one base plate 79 so as to be rotatable. The part is fixed to the main / sub-carriage 100, 101 using the fixing bracket 257, and is completely synchronized with the forward / reverse driving of the eighth motor 82 in the directions of arrows d6-1, d6-2. I try to move.
[0126]
The pulley 251 for driving the drive shaft 250 is a double type, and the timing belts 87 and 88 are hung as shown in the figure. In the sixth sensor S6, a sensor S6-1 for detecting the leading edge of the paper and a sensor S6-2 for detecting the paper width are arranged by a guide plate (not shown) upstream of the drive roller 66 as shown by a broken line. Yes.
[0127]
Next, FIG. 25 is an external perspective view of the sorting unit showing a state where it has moved to the position of the paper P4 in FIG. In this figure and FIG. 24, the same reference numerals are given to the components that have already been described, and the description will be omitted, and the following description will be limited to the components that have not been described.
[0128]
First, at the neutral position shown in FIG. 24, when the sensor S6-2 detects that the paper can be sorted after the paper is conveyed in the direction of the arrow d5, the paper is first fed at the neutral position to the drive roller 66. And the idle roller 67 pair, and a drive roller (not shown) and idle roller 69 pair. Thereafter, the eighth motor 82 that has been initialized in advance (described later with reference to a flowchart) is driven in the direction of the arrow r5, and power is transmitted via the timing belt 255 so that the main / sub carriage 100 is driven. , 101 are driven in the direction of arrow d6-1 as shown in the figure to move the paper P to the left column. After that, the seventh motor 81 is driven to feed the paper P in the direction of the arrow d7, so that it is inherited by the downstream ninth motor. Although not shown, when the paper P is moved to the right row, the eighth motor 82 and the seventh motor 81 are driven to send out the paper P in a similar manner, and the paper P is transported by the downstream ninth motor. It is configured as follows.
[0129]
Here, in FIG. 25, when a large gap G is generated between the roller that is guided by the shaft and moved to the left and right while being sandwiched between the thrust bushings 260 and the sliding contact surface of the thrust bushing 260, as shown in FIG. Cause skewing of the paper. That is, when holding between the pair of the downstream drive roller 66 and the idle roller 67 and the pair of the upstream drive roller 68 and the idle roller 69, both pairs are brought into contact with the sliding surface of the thrust bush 260. On the other hand, when there is no gap and the same is not applied by one side, and there is a gap G on the upstream side, for example, the skew is performed obliquely in the left direction. As a result, in the downstream processing tank 12, the paper is conveyed while being inclined, and normal conveyance cannot be performed thereafter. Therefore, control is performed so that the gap G is not formed.
[0130]
In this way, the paper P conveyed downstream is sent to the conveyance unit composed of the pair of the drive roller 70 and the idle roller 71 driven by the ninth motor 83 via the timing belt 90, and finally driven. It is conveyed by a pair of roller 72 and idle rollers 73 and 74. At this time, after the leading end of the paper P is conveyed between the pair of the drive roller 70 and the idle roller 71 driven by the upstream ninth motor 83 by the driving force of the seventh motor 81 of the distributing unit, The power supply to the motor 81 is cut off and the ninth motor 83 is used for conveyance, and the upstream conveyance force that is no longer necessary at this time is cut.
[0131]
When the energization of the seventh motor 81 is cut in this way, the detent torque of the seventh motor 81, which is a stepping motor, acts on each of the drive rollers described above. In particular, in the drive roller 68, the rear end side of the paper is idled. The pair of rollers sandwiched with the roller 69 becomes an extra load.
[0132]
Therefore, the timing pulley 81a of the seventh motor 81 has a built-in one-way clutch that transmits the driving force in only one direction coaxially.
[0133]
In this way, as shown in the schematic diagram of FIG. 26, the motor driving force is transmitted via the timing belt 88 only when the timing pulley 81a of the seventh motor 81 is driven in the direction indicated by the white arrow. Is transmitted to the drive roller 68, and when the energization to the seventh motor 81 is cut and rotated, the detent torque of the seventh motor 81 does not act on the drive roller 68 when it rotates. . As described above, the detent torque of the seventh motor 81 that is stopped after the conveyance to the predetermined position is prevented from acting as an extra rotational load on the drive roller 68 that is being conveyed. Can be done.
[0134]
The above is the schematic configuration relating to the mechanical part of the photographic developing device 1, and the feature thereof is that the continuous roll paper RP built in the paper magazine 3 so as to block light is turned into a rotary cutter. After cutting into a desired cut size by the unit 4, the paper P is transported to the exposure printing unit with the emulsion surface facing up, and then transported to the upstream main transport unit 10 in the sub transport unit 9. In step 10, the back print unit prints the desired data on the back side as necessary, and exposes the paper P to the left and right after exposure to a desired photo finished product desired by the customer using a greeting unit or the like. Judge whether it is a size that can be distributed, distribute it to the left or right, or transport it downstream as it is, processing liquid for predetermined development, bleaching and washing After sequentially transported a processing layer 12 that is built in to enable use of the rigidity possessed by the paper P itself is for discharging to the outside and dried.
[0135]
Further, as a further feature, the paper magazine 3 can be used in the left and right direction, and can be used in common for the optional magazine magazine right storage portion 2a. For example, almost all operations can be performed, and the paper can be exposed to a desired size vertically and horizontally by appropriately reversing the paper in the exposure printing section.
[0136]
Since the apparatus is configured as described above, control in the main controller 16 as described below is required. First, FIG. 27 is a control flowchart for preliminarily measuring the winding diameter of the roll paper RP incorporated in the paper magazine 3, and is included in a so-called initialization program executed when the apparatus is started.
[0137]
Thus, the reason for preliminary measurement of the winding diameter of the roll paper RP is that, as described with reference to FIG. 16, the roll paper RP is integrally provided with the roll paper wound around the core. This is because the feed is made by driving the gear 166 meshing with the roll paper gear 167.
[0138]
In other words, when the outer diameter of the roll paper RP is large, the gear 166 with a small amount of rotation is driven, while the rotation of the gear 166 increases as the diameter of the roll paper RP gradually decreases with consumption of the paper. In order to drive the first motor 20 so as to increase the driving amount, by measuring the winding diameter of the roll paper RP, it is possible to control the feeding amount obtained from the feeding amount = radius × circumference × rotation angle. To do.
[0139]
Therefore, in FIGS. 27 and 5, when the presence of the paper magazine 3 and the presence or absence of the roll paper are measured and determined to be present after the apparatus is turned on, in step S1, the roll paper RP is wound without sagging. The first motor 20 which is a stepping motor is started on the premise of step S2, and the process proceeds to step S2. When the first motor 20 corresponding to the occurrence of 125 mm of tarmi is driven in step S2, the first motor 20 is stopped in step S3.
[0140]
Next, the electromagnetic clutch 170 of the drive roller 25 with the clutch is energized, the second motor 23 is driven before and after this, and the tip of the paper is conveyed toward the second sensor S2, and this second The second motor 23, which is a stepping motor, is energized so as to carry 25 mm after passing the sensor S2. When the transport for 25 mm is completed, in step S6, the energization of the electromagnetic clutch 170 of the drive roller 25 with the clutch is stopped, and subsequently, in step S7, the first motor 20 is driven in the reverse rotation so as to return the paper (rewind). Is done.
[0141]
At this time, in step S8, the number of driving pulses of the first motor 20 from when the tip of the paper passes through the second sensor S2 until it passes through the first sensor S1 is counted, and mounted in the control unit 16 in step S9. Stored in the RAM of the temporary storage unit. Based on the number of drive pulses counted in this way, the winding diameter is calculated from the above formula. Thereafter, the process proceeds to step S10, where it is confirmed that the tip of the paper has passed through the first sensor S1, and the first motor 20 is stopped. On the other hand, even if rewind driving of the first motor 20 is continuously executed for 30 seconds in step S7, if the tip of the paper does not pass through the second sensor S2, a very large amount of tarmi is generated on the roll paper. In step S1, the process returns to step S1, and the operations from S1 to S9 are repeated.
[0142]
Next, FIG. 28 is a flowchart for measuring the distance between the second sensor S2 and the third sensor S3 required in steps S45 and S49. This control does not need to be included in the initialization program as described above, and is stored as it is first performed at the time of product shipment, so that it is difficult to avoid the mechanical occurrence. This automatically corrects the variation in the distance between the three sensors S3.
[0143]
28 and 16, first, the first motor 20 is driven to generate 400 mm of tarmi on the basis of the roll paper winding diameter obtained in step S9 of the flowchart of FIG. Next, in step S21, the electromagnetic clutch 175 is energized to prepare for driving the clutch-equipped drive roller 21, and in step S22, the electromagnetic clutch 170 is similarly energized to drive the clutch-equipped drive roller 25. Prepare for.
[0144]
In step S23, the solenoid 37 shown in FIG. 5 is energized so that the drive roller 35 and the idle roller 36 come into contact with each other. In step S24, the second motor 23 and the fourth motor 40 are started, and in step S25, the third sensor S3 is fed by 25 mm after the tip of the paper has passed.
[0145]
Subsequently, in step S26, the energization of the solenoid 37 is stopped, the drive roller 35 is released, and in step S27, the second motor 23 is started to be conveyed in the return direction. Subsequently, in step S28, the number of pulses of the second motor 23 until the tip of the paper reaches the third sensor S3 to the second sensor S2 is measured. Then, when the leading edge of the paper has passed the second sensor S2 in step S29, the second motor 23 is turned off. In step S30, the distance between the second sensor S2 and the third sensor S3 is calculated based on the number of pulses measured in step S28 and stored in the main control unit 16.
[0146]
As described above, the winding diameter of the roll paper RP is preliminarily measured, and subsequently, the operation shown in the control flowchart for the main measurement of the winding diameter of the roll paper RP shown in FIG. 28 is performed. At this time, the rotary blade 30 of the cutter unit 4 is in a position where the paper can pass between the fixed blade and the drive roller 35 and the idle roller 36 are turned on by energizing the solenoid 37 in step S40. After making contact and allowing the paper to be transported, the process proceeds to step S41, where the second motor 23 and the fourth motor 40 of the sub transport unit 9 are energized, and the leading edge of the paper passes through the third sensor S3. Then, step driving is performed so as to further convey 100 mm.
[0147]
In this way, when 100 mm has passed through the third sensor S3, the process proceeds to step S43 where the energization of the solenoid 37 is cut and the drive roller 35 is separated from the idle roller 36. With the above, the tarp of the roll paper is completely eliminated, and then the process proceeds to step S44, where the leading edge of the paper is conveyed reversely by the activation of the first motor 20, and the leading edge of the paper passes through the third sensor S3, and the second The number of pulses until it passes through the sensor S2 is measured. In step S46, the first motor 20 is driven so as to be rewinded by another 30 mm after passing through the first sensor S1, and then in step S47, the first motor 20 is driven so as to be conveyed. In step S48, the first motor 20 is driven. The 1,000 pulses are fed to generate the tarmi so that the load on the feeding operation by the drive rollers 21 and 25 is eliminated. In step S49, since the distance between the second sensor S2 and the third sensor S3 is accurately measured in advance, the winding diameter of the roll paper can be accurately calculated by dividing the distance by the number of measurement pulses. Become.
[0148]
Next, control of the main transport unit 10 will be described based on the flowchart of FIG. 30 and the block diagram of FIG. Here, as a premise for carrying out this control flowchart, the roll paper RP is cut into a desired cut size in advance by the rotary cutter unit 4 and then conveyed to the exposure printing section with the emulsion surface of the paper P as the light source side. Then, it is assumed that the guide plate 32 is moved downward in the sub-transport unit 9 and is transported to the upstream main transport unit 10.
[0149]
In FIGS. 30 and 4, first, in step S50, energization is performed to the shutter solenoid 75 that has blocked the light disposed at the uppermost portion of the main transport unit 10, and the current is retracted from the transport path. Then, it is brought into a state in which it can be conveyed to the downstream processing tank 12.
[0150]
Subsequently, the process proceeds to step S51, where the downstream drive roller 60 and idle roller 61 pair, drive roller 62 and idle roller 63 pair, and drive roller 64 and idle roller 65 pair are driven to the sixth motor 80. Energization is performed so that the paper transport is performed in the directions of arrows d4 and d5 in FIG. In step S53, the seventh motor 81 is energized to prepare for introduction to the distribution unit.
[0151]
In the subsequent step S54, after the leading edge of the paper conveyed by the fifth sensor S5 is detected, a specified amount that should be a printing margin is conveyed in step S55, and then the process proceeds to step S56, where the first print head 95 or One or both of the second print heads 97 are driven to print and record desired data on the back side of the paper.
[0152]
Thereafter, the paper is further transported and the leading edge of the paper is detected by the sixth sensor S6-1 in step S57, while the paper width dimension is detected by the sixth sensor S6-2, and the process proceeds to step S58, where the leading edge of the paper is detected. The sheet is conveyed until it comes to the front of the pair of the drive roller 66 and the idle roller 67 on the downstream side of the distributing unit. After this, when the energization of the sixth motor 80 and the seventh motor 81 is cut off in step S59 and it is determined in step S57 that the size can be distributed, the distribution routine described later is performed in step S60. move on. On the other hand, if it is determined in step S57 that the large size cannot be sorted, the process proceeds to step S62. In this step S62, two-phase excitation drive (high speed) of the seventh motor 81 and the ninth motor 83 located further downstream of the distributing unit is performed, and in step S63, the leading edge of the paper is sensed by the eighth sensor S8. After that, carry the specified amount further.
[0153]
As described above, the conveyance by the seventh motor 81 of the sorting unit is not necessary, and the rear end of the paper is removed, so the seventh motor 81 is stopped (step S64). At this time, the detent torque of the stopped seventh motor 81 does not reach the pair of the drive roller 70 and the idle roller 71 by the action of the one-way clutch 261 built in the timing pulley 81 a of the seventh motor 81. In order not to become a brake.
[0154]
Next, in step S65, 1-2 phase excitation drive (low speed) of the ninth motor 83 is performed so that the paper conveyance speed becomes equal to the conveyance speed in the processing tank 12 on the downstream side, and then the process proceeds to step S66. The process waits for the rear end of the paper P to pass through the seventh sensor S7, and the ninth motor 83 is stopped.
[0155]
The series of transport operations in the main transport unit 10 is completed as described above, and transported downstream by the drive roller 72 and idle rollers 73 and 74 that obtain the power source from the driving motor on the processing tank side. The above-described series of conveyance is repeated, and continuous conveyance is performed. However, the characteristic is that the conveyance is performed at a high speed until at least the distribution is performed, and the distribution speed is the same as the conveyance speed of the processing tank after the two columns are distributed to the left and right. It is in the point which carries out conveyance control.
[0156]
Next, FIG. 31 is a control flowchart of the cutter unit. In FIG. 5 and FIG. 5 and FIG. 17 illustrating the operation of the cutter, when the preparation for accurately transporting the paper is completed as described above, the front end of the paper is first positioned closer to the magazine 3 than the second sensor S2. . Further, the rotary blade 30 is configured such that the third motor 27 is stopped by the detection of the cutter sensor 182 and is rotated to the retracted position so that the paper can pass between the fixed blade 30 and the rotary blade 30. Yes.
[0157]
Accordingly, in step S70, the electromagnetic clutch 175 of the drive roller 21 with the clutch shown in FIG. 16 is energized, and the electromagnetic clutch 170 of the drive roller 25 with the clutch is energized before and after this. The second motor 23 is driven until the tip is detected by the second sensor S2. Next, proceeding to step S71, when the leading edge of the paper is detected by the second sensor S2, a distance obtained by adding a desired paper cut size (for example, 127 mm, 254 mm) to the distance between the fixed blade 29 and the second sensor S2. Then, the process proceeds to step S73, the third motor 27 for driving the rotary blade 30 is driven, and when the auxiliary dog 180 turns on the dog detection sensor 28 in step S73, the process proceeds to step S74. In this step S74, it is determined that the detection by the dog detection sensor 28 has been performed because the cutting of the paper has been reliably performed in step S73, and the fourth operation is performed so as to start the transport operation of the sub transport unit 9. The motor 40 is started.
[0158]
At this time, the third motor 27 is still rotating, and when the main dog 188 fixed to the motor disk 187 is detected by the cutter sensor 182, the power supply to the third motor 27 is stopped in step S76. Then, the rotary blade 30 is stopped at the cutting evacuation position, and the next paper conveyance is awaited.
[0159]
As described above, when the secondary dog 180 that rotates integrally with the rotary blade turns on the sensor 28 that is a dog detection switch, it is determined that the cutting of the paper has been reliably performed, and the transport of the secondary transport unit 9 is performed. By starting operation, a time lag is prevented and smooth paper conveyance is enabled.
[0160]
Finally, FIG. 32 is a schematic flowchart showing the distribution routine in step S60 of the flowchart of FIG. Referring to this figure and FIGS. 24 and 25, steps S80 to S82 included in the above initialization program in order to initialize the distribution unit are executed substantially simultaneously with the power-on of the apparatus.
[0161]
That is, in step S80, power is supplied to the eighth motor 82 for driving the main / sub-carrying carriages 100, 101 to drive the main / sub-carrying carriages 100, 101 in the direction of the arrow d6-1 in FIG. Thereafter, an actuator (not shown) fixed to the main / sub-carrying carriages 100 and 101 is detected by the tenth sensor S10, the driving of the motor 82 is stopped, and the motor driving for the number of steps previously grasped in the reverse direction is performed. To return to the center position (step S82). Thus, the initialization operation is completed, and the end surfaces of each pair of drive rollers 66 and 68 (shown in FIG. 7) and idle rollers 67 and 69 are the sliding contact surfaces of the four thrust bushings 260 on the left side in the drawing. It will be in the state which contacts with no gap. In this way, the gap G as shown in FIG. 25 can be completely prevented, and the skew feeding of the paper transport can be prevented.
[0162]
After the above initialization, the paper conveyed from upstream is held between the rollers by driving the seventh motor 81, and then the driving of the seventh motor 81 is stopped. Next, in step S84, the main and sub carriages 100 and 101 are driven in the direction of the arrow d6-2 by energization of the eighth motor 82 and stopped.
[0163]
As described above, since the paper P can be moved to the position to be conveyed to the right row, the driving of the seventh motor 81 is restarted in step S85, the downstream ninth motor 83 is started, and the first sheet is started. Ends the paper transport to the right row.
[0164]
Next, proceeding to step S86, the eighth motor 82 is driven, the motor is driven for the number of steps grasped in advance, and returned to the center position. Further, after the paper is held between the rollers by driving the seventh motor 81, the driving of the seventh motor is stopped.
[0165]
Thereafter, the main and sub carriages 100 and 101 are driven in the direction of the arrow d6-1 and stopped before the tenth sensor S10. Thereafter, the ninth motor 83 is driven in order to carry the left row of paper in step S88. Thereafter, a series of operations from step S81 to step S88 are repeatedly executed to perform drive position correction by error accumulation accompanying motor drive.
[0166]
As described above, in FIG. 24 and FIG. 32, the paper P that has been preliminarily cut to a desired cut size and then subjected to exposure printing is transported in order to distribute the paper P in two rows on the left and right sides of the transport path. A first pair of upstream drive roller 66 and driven roller 67, respectively, and a second pair of downstream drive roller and driven roller 69, which are disposed along the direction at a distance equal to or smaller than the cut size, The first pair, the drive motor 81 that drives and stops the second pair, the first pair, and the thrust bush 260 that comes into contact with both ends of the drive roller and the driven roller in the second pair are transport paths. The moving means is driven by the drive motor 82 so that the carriage reciprocates in the left and right directions d6-1 and d6-2, and the initial position is detected by the tenth sensor S10. And to be able to stop.
[0167]
【The invention's effect】
As described above, according to the present invention, when photographic paper is distributed to the left and right of the conveyance path, even if the photographic paper is long in the conveyance direction including a so-called panoramic photograph, it is not skewed. In addition, it is possible to provide a photographic developing apparatus capable of reliably transporting in parallel with the transport path and reducing noise.
[0168]
In addition to the above effects, a photographic developing apparatus capable of normal conveyance downstream can be provided.
[0169]
[Brief description of the drawings]
FIG. 1 shows a paper magazine left storage portion 2a set as an option, with all covers detachably provided to a housing 2 removed to show the main part of the overall configuration of the photographic developing device 1. It is the external appearance perspective view which showed a mode that it extended.
2 is an external perspective view of an enlarged main portion showing a state of paper conveyance in the main conveyance 10 of FIG.
FIG. 3 is an external perspective view showing a state in which the main transfer unit 10, the processing tank 12 and others shown in FIG. 1 are taken out.
4 is a block diagram of a paper transport unit of the photographic developing device 1. FIG.
5 is a block diagram of the main part of the lower part of FIG. 4. FIG.
FIG. 6 is a front view of the main transport unit 10;
7 is a schematic diagram showing the roller arrangement of FIG. 6; FIG.
FIG. 8 is a block diagram showing a state after an optional paper magazine left storage portion 2a is added.
9 is an AA arrow view of FIG. 6 and shows a state in which the main transport unit 10 is pulled out from the front surface 2f of the housing 2 and supported by the upper slide rail 200 and the lower slide rail 201. FIG. FIG.
10A is an enlarged front view showing a left side portion of the lower plate 106 of FIG. 9; FIG. 10B is a cross-sectional view taken along the line AA in FIG.
FIG. 11 is an external perspective view showing a state where the paper magazine 3 is stored in the paper magazine right storage portion 2b.
12 is an external perspective view of the paper magazine 3 before loading. FIG.
13 is a front view of the paper magazine 3 in a state after loading shown in FIG. 11 as viewed from the opening 133 side.
FIG. 14 is a front view of the paper magazine 3 before loading as viewed from the opening 133 side.
FIGS. 15A and 15B are external perspective views of a magazine fixing mechanism fixed to a ceiling surface of the paper magazine left and right storage portions 2a and 2b, where FIG. 15A is a fixed state, and FIG. 15B is an external perspective view illustrating a released state. It is.
16 is a schematic configuration diagram of each configuration provided in the paper magazine 3. FIG.
FIG. 17 is a side view for explaining the operation of the cutter unit.
FIG. 18 is an enlarged view of a main part of the sub-transport unit 9;
FIG. 19 is a plan view of FIG. 18;
FIG. 20A is an external perspective view in which the main part is cut away to show the arrangement of the first print head and the second print head, and FIG. 20B is a cutaway view of the main part.
FIG. 21 is an external perspective view seen from the printer base 222 side.
FIG. 22 is a plan view for explaining the operation of replacing the ink ribbon cartridge.
FIG. 23 is an external perspective view when replacing the ink ribbon cartridge.
24 is an external perspective view of a sorting unit that moves to the positions of the papers P3 and P4 described in FIG. 2;
25 is an external perspective view illustrating the operation of FIG. 24. FIG.
FIG. 26 is a plan view for explaining the operation of the seventh motor and the ninth motor.
FIG. 27 is a control flowchart for preliminarily measuring the winding diameter of the roll paper RP built in the paper magazine 3;
FIG. 28 is a flowchart for measuring the distance between the second sensor S2 and the third sensor S3.
FIG. 29 is a control flowchart for measuring the winding diameter of the roll paper RP built in the paper magazine 3;
30 is a control flowchart of the main transport unit 10. FIG.
FIG. 31 is a control flowchart of the cutter unit 4;
FIG. 32 is a control flowchart of a sorting operation.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Photo printing developing apparatus, 2 ... Housing, 2a ... Paper magazine right storage part, 2b ... Paper magazine left storage part, 3 ... Paper magazine, 4 ... Cutter unit, 5 ... Exposure printing part, 6 ... Film scanner, 7 DESCRIPTION OF SYMBOLS ... Dark box, 8 ... Table, 9 ... Sub conveyance part, 10 ... Main conveyance part, 11 ... Greeting unit, 12 ... Processing tank, 13 ... Inversion roll, 14 ... Drain, 15 ... Replenishment tank, 16 ... Main control part, 17 DESCRIPTION OF SYMBOLS ... Drying unit, 18 ... Processor control part, 19 ... Power supply part, 20 ... 1st motor (motor for roll paper drive), 21 ... Drive roller with clutch, 22 ... Idle roller, 23 ... 2nd motor, 23a ... Timing pulley , 24 ... timing belt, 25 ... drive roller with clutch, 26 ... idle roller, 27 ... third motor (cutter drive) Motor), 28 ... Dog detection switch (sensor), 29 ... Fixed blade, 30 ... Rotary blade, 31 ... Solenoid, 32 ... Guide plate, 33 ... Idle roller, 34 ... Drive roller, 35 ... Drive roller, 36 ... Idle Roller, 37 ... Solenoid, 38 ... Timing belt, 40 ... Fourth motor, 50 ... Table, 51 ... Suction unit, 52 ... Swivel motor, 53 ... Vacuum valve, 54 ... Piping, 55 ... Vacuum pump, 56 ... Fifth motor 57 ... Timing belt, 58 ... Fan, 59 ... Timing pulley, 60 ... Drive roller, 61 ... Idle roller, 62 ... Drive roller, 63 ... Idle roller, 64 ... Drive roller, 65 ... Idle roller, 66 ... Drive roller, 67 ... Idle roller, 68 ... Drive roller, 69 ... Idle roller, 70 ... Live roller 71 ... Idle roller 72 ... Drive roller 73 ... Idle roller 74 ... Idle roller 75 ... Shutter solenoid 79 ... Base plate 79a ... Opening 80 ... Sixth motor 81 ... Seventh motor 82 8th motor (for carriage), 83 ... 9th motor, 84 ... timing belt, 85 ... tension roller, 86 ... timing belt, 87 ... timing belt, 88 ... timing belt, 89 ... tension roller, 90 ... timing belt, 91 ... One-way clutch, 92 ... Paper guide, 95 ... First print head, 96 ... Ink ribbon cartridge, 97 ... Second print head, 100 ... Main carriage, 101 ... Sub-carriage, 105 ... Upper plate, 106 ... Lower plate, 110 ... pin, 111 ... pin, 112 DESCRIPTION OF SYMBOLS ... Spring hook part, 113 ... Coil spring, 113a ... Upper end part, 113b ... Lower end part, 114 ... Spring hook part, 130 ... Guide rail, 131 ... Magazine case, 132 ... Slider, 133 ... Opening part, 134 ... Shutter plate, 135 ... Cylinder member, 136 ... Spring hook portion, 137 ... Coil spring, 138 ... Guide block, 139 ... Guide block, 140 ... First cam member, 141 ... Second cam member, 144 ... (Compression) coil spring, 145 ... Push pin, DESCRIPTION OF SYMBOLS 150 ... Pin, 151 ... Locking member, 152 ... Mounting plate, 153 ... Lever, 154 ... Sub lever, 155 ... Coil spring, 160 ... Timing belt, 161 ... Large pulley, 162 ... Small pulley, 163 ... Timing belt, 164 ... Tension Roller, 165 ... Timing pulley, 166 ... Gear, 167 ... Roll paper -Gear, 168 ... Timing belt, 169 ... Tension roller, 170 ... Timing pulley, 171 ... Timing pulley, 172 ... Electromagnetic clutch, 173 ... Timing belt, 174 ... Tension roller, 175 ... Electromagnetic clutch, 176 ... Gear coupling, 180 ... Sub-dog, 181 ... Board, 182 ... Cutter sensor, 183 ... Arm member, 184 ... Bearing, 185 ... Link, 186 ... Bearing, 187 ... Motor disk, 188 ... Main dog, 189 ... Set screw, 190 ... Timing pulley, 191 ... Base, 192 ... Rotating shaft, 193 ... Spring hook, 194 ... Coil spring, 195 ... Spring hook, 196 ... Pin, 197 ... Connecting plate, 198 ... Solenoid plunger, 199 ... Pin, 200 ... Upper slide rail, 200a ... locking pin, 2 DESCRIPTION OF SYMBOLS 0b ... Locking pin, 220 ... Paper guide plate, 220a ... Guide part, 221 ... Paper guide plate, 222 ... Printer base, 222a ... Guide groove, 223 ... Head base plate, 223a ... Guide groove, 224 ... Printer base part, 225 ... 1st pin, 226 ... 2nd pin, 227 ... Head base plate, 227a ... Guide groove, 228 ... Printer base, 229 ... 1st pin, 230 ... 2nd pin, 231 ... Screw hole, 232 ... Fixing screw 233: Magnet catch, 235: Platen plate, 250: Drive shaft, 251: Timing pulley, 252 ... Guide shaft, 253 ... Spring ring, 254 ... Pulley, 255 ... Carriage drive timing belt, 256 ... Tension pulley, 257 ... Fixed Bracket, 258 ... guide shaft, 258 ... guy Shaft, 260 ... thrust bush, 261 ... one-way clutch, S1 ... first sensor, S2 ... second sensor, S3 ... third sensor, S4 ... fourth sensor, S5 ... fifth sensor, S6 ... sixth sensor, S7 ... 7th sensor, S8 ... 8th sensor, S9 ... 9th sensor, S10 ... 10th sensor, P ... Paper (printing paper), RP ... Roll paper

Claims (3)

In a photographic developing apparatus provided with a sorting means for sorting and transporting the photographic paper that has been preliminarily cut into a desired cut size and then exposed and baked into two rows on the left and right sides of the transport path,
A first pair of an upstream drive roller and a driven roller, a downstream drive roller and a driven roller, which are arranged along the transport direction of the transport path and separated by a distance equal to or less than the cut size. A second pair of rollers,
A drive shaft having an oval cross section provided on the drive roller of each of the first and second pairs, the drive roller penetrating through an axis thereof so that the drive roller can move in the left-right direction of the transport path;
A guide shaft that is provided on each of the driven rollers of each of the first and second pairs, and that passes through the axis so that the driven rollers can move in the left-right direction of the transport path;
By the rotation and stopping of said drive shaft, said first pair, a drive motor for the rotary drive and stop the second pair,
The first pair and the second pair are in contact with both ends of the driving roller and the driven roller, and the first pair and the second pair are arranged in the left-right direction of the transport path. Moving means for reciprocating driving;
A photographic developing apparatus comprising: a detecting means for detecting an initial position of the moving means; the driving means; the moving means; and a control means connected to the detecting means. In order to determine the size of the photographic paper that has been cut in advance to the desired cut size, a determination means that is disposed substantially at the center of the transport path and is connected to the control means is provided upstream of the first pair. Determining whether or not the size is allocated to the left and right two rows downstream of the conveyance path,
In the state in which the moving means is moved to the neutral position, the first transfer is carried downstream by driving the drive motor at the neutral position during the non-assignment, while the first drive is driven by the drive motor at the neutral position during the assignment. The photographic paper is sandwiched between the second pair and the second pair, stopped, then left or right, and then transported downstream by driving the drive motor. The photographic developing apparatus according to claim 1, wherein the photographic developing apparatus is configured. A second drive motor that drives a third pair of a second drive roller and a second driven roller on the downstream side of the second pair, so that the transport speed on the downstream side is higher than the transport speed on the upstream side; After the conveyance by the low-speed drive of the drive motor is finished, the drive motor is stopped and is configured to take over the conveyance by the high-speed drive of the second drive motor.
Clutch means for preventing a braking force due to a detent torque after the drive motor from being stopped from being applied to the second pair of the second drive roller and the second driven roller is provided as the clutch motor. The photographic developing apparatus according to claim 2, which is provided between the two.

Images