JPS613159A - image editing copier - Google Patents

Abstract

PURPOSE:To improve the function for editing an image, and to improve the operability of an image editing area input part by constituting a copying machine so that plural editing contents can be inputted simultaneously, also these editing contents are brought to a continuous copying processing, and thereafter, a transfer paper is stocked in each separate part in a containing device at every editing contents. CONSTITUTION:When display parts are turned on, a display appears, and in case of copying, the operation is executed from a key of the left side. A composite copy key 48 is used when originals of the first sheet and the second sheet are superposed and copied, and an inversion paper discharge key 47 is used when a transfer paper is discharged to a paper discharge tray 19 by reversing the surface and the rear side, and copying is executed from the original of the first sheet, and when the discharged transfer paper is turned inside out as it is the page is arranged in order from the first sheet. In this operating flow, first of all, editing ranges of originals A-C are inputted successively, (three kinds), and subsequently, the contents of editings 1-3 are copied, respectively, and stocked successively in a store tray. Next, a copy of the editing 1 is fed from the store tray, and the contents of the editing 1 of the original B are superposed and copied, and the copy is fed to the store tray again. Such an operation is executed successively and each editing contents are led to each separate stocker, by which the subsequent classifying work becomes unnecessary.

Description

[Detailed description of the invention]

TECHNICAL FIELD The present invention relates to an analog image editing copying machine that extracts necessary portions of a plurality of original documents in an analog manner and edits them onto a single sheet (transfer paper). BACKGROUND OF THE INVENTION Various copying machines are known which have a so-called analog image editing function, in which required portions of a plurality of manuscripts are extracted in an analog manner and edited or synthesized onto a single sheet (transfer paper). Conventionally, this type of copying machine uses a first document with a hole in the area where the second document should be inserted, and overlaps this and the second document and copies them as one document, or copies the first document. There is a known method in which the sheet is stored in a sheet storage section inside the machine, and when the second document is copied, this sheet is sent again to the transfer position, and the necessary portion of the second document is copied on the same surface as the copy surface of the first document. It is being In the latter copying machine, a one-exposure relative position adjustment means and an erase means are used to align each document. As described above, although the concept of image editing in composite copying apparatuses has been known, there has been no concrete disclosure of techniques for improving operability or various functions related to image editing. Furthermore, in the past, when trying to set an image area, many switches were required, which had the disadvantage of being expensive and tedious. OBJECTS The present invention was made against the background of such conventional examples, and it is an object of the present invention to improve the image editing function and the operability of the human-powered section in the image editing area. Configuration The configuration of the present invention will be explained below based on the drawings. First, the functions of a copying machine, which is the premise of the present invention, will be explained based on FIGS. 1, 2, and 3, and then the present invention will be explained with reference to FIGS. In FIG. 1, a first document set at a predetermined position by the document exchanger [IK] is illuminated by a well-known illumination and exposure optical device 8 including a light source 2, mirrors 3 to 6, and a lens 7, and is illuminated on a photoreceptor 9. image is exposed. The surface of the photoreceptor 9 is uniformly charged by a charter 10 and exposed by an illumination exposure optical device 8 to form an electrostatic latent image. While the photoreceptor 9, for example a photoreceptor drum, is moving, the electrostatic latent image is developed and visualized by the developing device 11. The developed image on the photoreceptor 9 is transferred to a transfer paper 14 serving as a copy paper fed from a paper feed section 12.13 at a transfer position. In FIG. 1, a transfer drum 15 is used as a means for conveying the transfer paper 14 to the transfer position. After the transfer, the photoreceptor 9 is neutralized and cleaned by a cleaning device 16, and the process from charging is repeated again. The transfer paper 14 on which the image of the first original document has been transferred is sent to a storage device. In FIG. 1, the transfer drum 15 is also used as a storage device. For this purpose, the transfer M14 fed from the paper feed section 12.13 is first shifted by a clamp 17 provided on the transfer drum 15. The transfer paper 14 is the transfer drum 1
After the image of the first document is transferred from the photoreceptor 9 through one rotation by being clamped by the photoreceptor 9, the transfer drum 15 is temporarily stored while being fixed to the transfer drum 15 at a position where it does not contact the photoreceptor 9. There is a method of changing the distance between the transfer drum 15 and the photoreceptor 9 in order to keep it in a non-contact state with the photoreceptor 9 during storage, and a method of providing a recess in the part of the transfer drum 15 where there is no transfer paper and placing the recess in the photoreceptor 9. A variety of methods can be used, including a method of facing each other. In the above process, the image of the first original is transferred to the transfer paper, and while the transfer paper is stored in the storage device, the original replacement device 1
At , the first original is taken out and the second original is set at a predetermined position. Below is the 1st W. The photoreceptor 9 is charged, exposed and developed in the same process as for originals, and the image of the second original formed on the photoreceptor 9 is rotated again on a transfer paper, such as a transfer drum 15, which is fed from a storage device. As a result, the image is transferred onto the transfer paper 14 sent to the transfer position on the same surface as the image of the first original. In this way the third
When a predetermined number of original images are transferred and combined on the same side of one transfer paper, the 14 transfer paper clamps are released.
The image is fixed by the fixing device fl18 and discharged onto the paper discharge tray 19. The original replacing device 1 is simply the original placing glass 20 of a copying machine.
Alternatively, a semi-automatic document handling device or a fully automatic document handling device that has a feed belt 21 and feeds and sets manually inserted documents to a predetermined position can be used. . In FIGS. 1 and 2, the transfer drum 15 is also used as a storage device for transfer paper after the image of the first original is transferred until the image of the second original is transferred. Therefore, when transferring the image of the second original, when adjusting the deviation in the transfer paper feeding direction between the composite position of the first original and the information position of the second original by the feeding timing of the transfer paper, it is necessary to The photoreceptor 9 is rotated with a timing shift of . At this time, in order to avoid gaps between the photoreceptor 9 and the transfer drum 15, the portion of the transfer drum 15 facing the photoreceptor is formed as a recess at the stop position of the transfer drum 15 to avoid direct contact; A structure may be adopted in which the transfer drum 15 moves away from the photoreceptor 9 when stopped. The storage device can be provided separately instead of being shared by the transfer drum 15. For example, as shown in FIG. 2, the transfer paper is sent from the paper feed section 12.13 to the transfer position by the photoreceptor 9 by a transfer paper conveying means 27 having a roller 22 and a guide 23. After the transfer paper is fused by the fixing device 18, the first ? -G2
8 to the storage tray 30 through a storage path 29 which is switchably provided. When feeding the paper into the storage tray 30, it is always turned upside down so that the leading end is fed as the leading edge, and in the illustrated example, the paper is fed and stored with the copy side facing down. After one sheet or a predetermined number of transfer sheets on which the first original is copied is stored in the storage tray 30, a second original is copied. In the figure, a document exchange device 1, an illumination exposure device 8,
The related parts of the photoreceptor 9 are the same as those in FIG. 1, so their explanation will be omitted. When copying the 2nd yX document, the paper feed roller in the storage tray 30 or the registration roller in the case where the registration roller is sent out from the storage tray 30 in advance according to the exposure timing and is provided in the middle of the transfer paper conveying means 27 and does not stop. The rotational drive is performed under timing adjustment according to the positional deviation calculated from the composite position signal and the information position signal. When the combination position of the transfer paper carrying gII of the first original reaches the transfer position of the photoreceptor 6, the photoreceptor 9
Adjustments are made so that the information of the second document formed thereon is located at the transfer position. The transfer paper is stored in the storage tray 30 in a number corresponding to the number of originals to be combined, and is sent again to the transfer position of the photoreceptor 9, so that the transfer paper is repeatedly fed in a circular manner. When the composite copying using the final original is completed, the transfer paper is discharged to the paper discharge tray 19 by switching the first gate 28. In FIG. 2, from the fixing device 18 to the first /rk-)2
8, another second dart 31 is provided until the transfer paper is sent to the storage tray 30 through the first gate 28. In this case, the switching path 321 feeds the paper into the storage tray with the copied side facing up and the leading end becoming the trailing end.
It can be provided in When the second dart is sent to the storage tray 30 through the switching path 32 by switching the second dart, the surface opposite to the curve is in contact with the photoreceptor and transferred to the transfer paper in the next copying process. In other words, double-sided copying becomes possible. Composite copying, double-sided copying, and even double-sided composite copying can be made possible by providing 28.31 and switching the method of feeding the transfer to the storage tray. . That is, double-sided composite copying is possible by performing the above-mentioned composite copying operation on one side, then sending it to the storage tray 30 from the second gate 31 through the switching path 32, and then performing the above-mentioned composite copying operation on the back side again. . In FIG. 3, numeral 33 is a sorter, which can be connected to the copying machine instead of the paper discharge tray 19 in FIG. Next, FIG. 4 shows the operation section of the copying machine according to the present invention, and the operation mechanism will be explained with reference to this figure. Operation keys FiIO key (1 to 9.0) 34, interrupt key 35, clear/stop key 36, cylinder key 37, density adjustment key 38,
Standard mode setting key 39, paper feed selection key 40, magnification setting key 41, 1 for double-sided originals 1 double-sided copy key 4 for single-sided originals
2. There are a stack key 43, a sort key 44, a left blank key 45, a right blank key 46, a reverse paper ejection key 47, and a composite copy key 48, which are not normally visible on the display section 49.50, but are shown in the figure when lit. A message similar to that shown below will appear. When copying, it is best to use the keys on the left side of the operation unit, and the functions will be explained starting with the keys on the left side. The left blank and right blank keys 45 and 46 are keys for adjusting the binding margin, and set the binding margin to the left side of the copied transfer paper by 1.
If you want to make 5 m, press the left blank key 45 and input 15 using the 10 key 34, and the 7-segment display at the top of the display 49 lights up as "15". This may be blinking, and when you release the left plank key L45, "15# disappears and returns to 1". The same applies to the right blank key 46. The composite copy key 48 is used when it is desired to copy the first original and the second original in an overlapping manner. The reverse paper ejection key 47 is used when you want to turn the copy paper upside down and output it to the paper ejection tray 19. When copying from the first original, the ejected transfer paper will have one sheet on the bottom side. Since it is a double copy, if you turn it upside down and turn over the many ejected transfer sheets, you can align the pages in order starting from the first sheet. The stack key 43 and sort key 44 are well known and need no explanation. The double-sided copy key 42 for double-sided originals and single-sided originals is used when double-sided copying is desired, and there are two cases: double-sided copying from a double-sided original, and double-sided copying from a single-sided original. The paper feed selection key 40 is used to select the paper feed tray r12, 13), and the display section 49 shows the A4 paper feed tray for the first stage paper feed tray.
However, the second and third paper feed trays each have B4. A3
is set, and when the first row is selected, the A4 display area is surrounded by a frame. If the user wishes to select the second row, press the paper feed selection key 40 to move the frame to the second row and select the second row. In order to set the magnification, there are an enlargement key and a reduction key (magnification setting key 41), and when these keys are pressed, % is displayed on the display section 49 in steps of, for example, 1 tick. And for example 7
When "1%" is displayed, "A3→A4" is also displayed to notify that the magnification is to reduce A3 to A4. The 10 keys 34 from 1 to 9.0 are used to set the number of sheets, and are displayed in the upper seven segments of the display section 49. The lower 7-segment display is for displaying the number of copies. Further, as described above, it is also used when setting the binding bar width using the 10 key 34 while pressing the left and right blank keys 45 and 46 for adjusting the binding margin. In the figure, there are keys for enlarging and reducing, but this can be used as a magnification key and L. While pressing this magnification key, a desired value can also be input using the 10 key 34. The interrupt key 35 is used when urgent copying is required during copying.Pressing the interrupt key 35 interrupts copying, and pressing it again after performing emergency copying causes
You can return to the previous mode and resume copying. The explanation of the clear/storp key 36, density adjustment key 38, and print key 37 will be omitted. The standard mode setting key 39 is used to change to a preset mode by pressing it, for example, A4.
If you set a magnification of 100% (actual size) in the size, the mode used by the previous person will be A3 size with a reduction rate of 71-,
If you are in sort mode for double-sided copying, press the 1 standard mode setting key 39tl to save the trouble of canceling these settings.
- You can change the magnification to 100% on A4 size paper just by pressing the button. The above is the explanation of the key, and in the case of the figure, it is blank on the left. This shows an example in which the right blank keys 45, 46, composite copy key 48, and reverse paper ejection key 47 are covered because they are not keys that are always placed on the side. Next, display functions that have not yet been explained regarding the display sections 49 and 50 will be explained. The "Paper Check" display lights up when the original and the transfer paper do not match, and of course the judgment is made including the magnification. Display 4902 lights up when there is no paper in the paper feed tray. Display 4903 lights up when copying the back side of a double-sided copy.Display 4903 lights up when there is transfer paper in the sorter pin.
When the stack or sort key i is pressed, it lights up to warn you not to mix it with the previously copied transfer paper. A table 4904 is a display warning that a document has been forgotten. Display 4905 lights up when interrupt key 35 is pressed. Display 5001 lights up during warm-up mode. The display 5002 lights up when warm-up is completed and copying is started when the print key 37 is pressed. Display 5003 is displayed numerically when there is an abnormality in the machine, and at this time display 5004 also lights up to indicate a serviceman call. This number allows you to identify abnormalities,
It has the meaning of self-diagnosis. It can also be used to display the waiting time in minutes during the aforementioned warm-up. Display 5005 lights up when the door is open. When the door on the sorter side is open, display 5005.5006
．． 5007 lights up. Displays 5008 and 5009 light up when there is a jam.
If there is a jam in the sorter, please use the front or 5009.5006
lights up. Display 5010 lights up when the key counter is not set. Display 5011 lights up when there is a shortage of toner. The operation section of the ADF is shown in FIG. 5, and will be briefly explained below.
is used when sending originals automatically, and 5ADF
The key 52 is used when manually inserting a document, and is well known in the art. The size unification key 53 is a mode in which the size of the original is detected and the magnification is automatically set to match the size of the transfer paper in the selected paper feed tray. This is used when you want to unify. The automatic paper feed selection (A, P, S, ) keys 54 are used to detect the size of the original and automatically select the transfer paper in the paper feed tray to match the set magnification. be. The counter key 55 is used when you want to display the number of original sheets, and the number of sheets is displayed using a 7-segment LED.
It is done by 56K. The display panel shown in FIG.
, Set confirmation display 58, which lights up when the original is not fully set.59, Original feed display 59, which lights up when the original is set in the ADF mode, when the copy is about to start, indicates the direction in which the original should be inserted. , and a document insertion display 60 that turns off when the document is inserted. Next, the display unit according to the present invention will be explained. The display is C
I'm using RT. Figures 6(a) to (g> show the contents of the RT screen. In the figure (&), 61 indicates the size of the transfer paper, and scales 62 and 63 indicate the size value of the transfer paper. 64 indicates the size value of the transfer paper. It is a part of the first manuscript. 65 is a part of the second manuscript. [66 is a part of the third manuscript. The character display below the scale 62° and 63 is as follows: The mode contents and transfer paper size of each part of the original are shown. In Figure (b), 64 is one part of the first original, 6
5 is a portion of the second original. The first original is copied at the same size as indicated by the character display. The second original 65 is copied with a reduction of 93 inches as indicated by the character display. In Figure (c), 64m and 64b are part of the first document (same document). In figure (d), 64 is a part of the first manuscript, a frame is created on the transfer paper, and a part 65 of the second manuscript is copied in a 93% reduction mode to the part shown in the figure.
A portion 66 of the third document is zoomed in at 115% magnification mode. In factor (e), 64 is a portion of the first manuscript. 65 is a portion of the second manuscript. 66 is a portion of the third manuscript. 65 and 66 are
Although they partially overlap, it shows that 65 is copied with priority. Reference numeral 64 indicates the position of the copy at the same size, 65 at the reduced size of 93 inches, and 66 at the reduced size of 87 inches. In the figure, 64a and 64b are parts of the first manuscript. 65 is a part of the second N manuscript e6
4b and 65 have partial types as in Figure (s), but 65 is copied preferentially. (2) In (g), 64x and 64b are part of the first original. 65 is a portion of the second manuscript. 64b and 65 partially overlap 9, but 64m,
This is a case where it is necessary to copy both depending on the content to be copied to 64b (this is a case where no priority order is given). Examples of CRT screens have been shown above in FIGS. 6(a) to 6(g). If the CRT is a color type, for example, the figure (
In a), displaying 64 in green, 65 in yellow, and 66 in red makes it easier to see. If the CRT is not a color type, 64
They can also be distinguished by a solid line, 65 by a broken line, and 66 by a dashed line. When there is a priority order as shown in figures (-) and (f), it is also possible to predetermine the color from the highest priority to red, yellow, blue, etc., or to a solid line, a broken line, a dashed-dotted line, etc. It is. The numbers in 64, 65, and 66 shown in factor (a) indicate one order of the manuscript. For a color CRT, if you predetermine that the first document is red, the second document is yellow, and the third document is blue, the numbers in 64, 65, and 66 are no longer needed. Next, the operation section for image editing is shown in the block diagram of FIG. The pressure-sensitive sheet 67, which uses a pressure-sensitive sheet to detect the position of the original, has signal lines for inputting and outputting each matrix signal on the This allows you to enter location information. The I10 controller 68 is connected to the host 7zcpuK data bus, which will be described later. The original S editing area is detected based on matrix information of the scan timing signal and scan return signal of the pressed pressure sensitive sheet 67. A group of keys 69 connected to the area operation section include an edit start key, an edit end key, a priority key, an area shift key, and (
It consists of keys (left, right, up, down), zoom keys (a, zo, down), and color specification keys (black, red, blue). Determination of whether a key has been pressed is based on a matrix signal of a scan signal for detecting a key code and a return signal from which the scan signal is returned to the I10 controller 681C when a key is pressed. The keys of the operation section will be explained as follows: (1) The editing start key is a key that notifies the start of editing the document, and unless this key is pressed, the position information of the pressure sensitive sheet 67 is canceled. ■ The editing end key is a key that notifies the end of editing the manuscript. When this key is pressed, all area designations are completed. If the editing end key is not pressed, multiple areas within the document can be arbitrarily specified. ■ The priority key is pressed when specifying an area for a multi-page document and if there is overlap in the area, the priority key should be given to securing the area for the document. When this key is pressed before, after, or during area designation, a priority flag is set in the RAM that stores the number of originals. ■ The area shift key shifts the frame length of the specified area to the left, right, top, and bottom without changing the frame length. The data in the y-axis direction of the data contents of the area RAM and l1LAP shown in FIG. 8 is changed, and the updated position data is stored when the shift key is released. With the 691 and 692 keys, the data of the X-axis position in the RAM is updated. With the 693 and 694 keys, the data of the X-axis position in the RAM is updated. ■ The zoom key is the key you press to change the size of the image within the area frame, and you can steplessly instruct the image to be enlarged or reduced. ■ The color specification key is a key that is pressed when creating multiple colors on copy paper. ■ The pressure-sensitive sheet key determines the positional information of the editing area, and is valid while the PWA collection start key and collection end key are pressed, and the scan signal of the X and y axes,
Judgment is made based on the matrix signal of the scan return signal. Scan timing TxI and return signal Ty1 port signal as XIYI position information Txn r Tyn
Scan all areas and determine the location. FIG. 9 is a diagram showing the pressure-sensitive sheet showing the X-axis and the y-axis, and FIG. 10 is a diagram showing a state in which transfer paper is placed on the pressure-sensitive sheet 67. The area surrounded by four corners inside the transfer paper is an image editing area. Furthermore, FIGS. 11(a) and 11(b) are diagrams showing the region shift state, and FIG. 12 is a diagram showing the R at that time.
AM Ma, 76. In FIG. 7, 70 and 71 are drivers, and 72 is a controller. Next, the optical illumination section will be explained. One element for image editing is conversion of the image size and image position on the copy screen. In the analog image editing and copying apparatus to which this application pertains, this is achieved by an optical image projection device (optical system). In the copying apparatus shown in FIG. 1, an original placed on an original placing glass 20 is illuminated by a light source 2, and an image of the original is projected onto a photoreceptor 9 in a T-shape by a group of mirrors 3 to 6 and a lens 7. be done. Further, the image of the original is continuously projected onto the photoreceptor 9 by scanning the first mirror 3 (velocity ν) and the second mirror 4, which are integrated with the light source 2, relative to the original. To convert my size, variable magnification projection is performed.Ol) The magnification conversion in the mirror scanning direction is determined by the relative relationship between the surface speed v6 of the photoreceptor 9 and the first mirror scanning speed υ. If the magnification is m, then m = -4 τ (This does not apply to full-exposure copiers that use flash exposure, etc.) 11) The magnification conversion in the direction perpendicular to i) above (the axial direction of the photoreceptor drum) is performed by so-called zooming. . In the example of FIG. 1, a fixed focus lens is used. Move lens 7 in the optical path direction by an amount (Δ8) that matches the magnification m, and move mirror 5,
To correct the total path by Δt by displacing K
more achieved. If the focal length of the lens is f, Δm=(-1) f ΔL=(m+-2) f When a zoom lens is used, correction of the total path can be omitted. Image position transformation is achieved by the following means. 1) Position conversion in the mirror scanning direction is achieved by changing the relative positional relationship between the image and the transfer paper, that is, the timing of contact of the transfer paper 10 with the photoconductor when transferring the developed toner image formed on the photoconductor. . (The timing relationship between the photoreceptor and the transfer paper may be kept constant and the mirror scanning start timing may be changed.) II) Image position conversion in the direction perpendicular to i) above is image projection by moving the lens in the direction perpendicular to the optical path. Achieved by position transformation. FIG. 13 is a plan view of the lens optical path. In FIG. 13, when exposing information in a partial range a of a document range A, an image is normally formed on a partial range A of a range B of the photoreceptor. The photoreceptor corresponds to copy paper or transfer paper. If the lens 7 is now moved by 7 in the direction perpendicular to the optical axis, the partial area on the photoreceptor will be moved a distance t in the direction in which the lens 4 has moved.
It moves to the partial area b' that has moved by the same amount. That is, by selecting the amount of movement of the lens in the direction perpendicular to the optical path, it is possible to arbitrarily select the image forming position on the photoreceptor and on the copy paper in the direction perpendicular to the direction of movement of the copy paper. If used in conjunction with magnification conversion by moving the lens 7 along the optical axis, variable magnification copying and composite copying can be performed at the same time. The amount of movement of the lens in the direction perpendicular to the optical axis is set by calculating the deviation L between the information position and the specified copying position using the control device, and controlling the lens moving device using the signal obtained. For example, the structure for moving the lens is shown in Fig. 14 and Fig. 1.
As shown in FIG. 5, a lens stand 73 to which the lens 7 is fixed is supported by a lens bracket 74, and the lens bracket 7
4 is screwed onto a screw shaft 76 which is rotatably supported by the optical system frame 75, and the screw shaft 76t is connected directly to the motor 77 via a shaft or a belt force.

A structure may be used in which the lens 7 is moved in a direction perpendicular to the optical axis by being reversibly rotated by a motor 77. If the movement of the lens bracket 74 is guided by a guide bar 78 fixed to the optical system frame 75, the lens can be smoothly reciprocated without tilting. If the optical system frame 75 itself is screwed onto a threaded rod or the like in the same manner as shown in FIGS. 14 and 15 so as to be movable in the optical axis direction, magnification can be changed. To convert the image position, control the feeding timing of the copy paper and control the movement of the lens as described above. It is also possible to use a method of adjusting the control unit. Next, the control unit will be described. Fig. 16 is a control diagram of this copying machine. 600 is a microprocessor, and 1601 is a key
602 is a display interface, 602 is a key and optical display element in the operating section, 603 is a ROM that stores control fI: 1 gram, fixed data, 604U is a ROM that can write and read control flags, copy data, etc., and 605 is a CRT 2. A video RAM 606 that stores display data is a CRT controller that extracts data from the video RAM and controls the display position and timing. 607 is a character generator that converts display data into a dot pattern. 608 converts the dot data into a video signal, takes the timing and outputs the signal iC'RT 609
A video control unit 609 outputs to a CRT, 610
input/output CIA) interface, 611 is a buffer for each input in the copying machine, 612 is an editing image area operation unit, 613
is an input/output (Ilo) interface, 6]4 is a driver, 615 is an erase unit, 616 is an optical axis moving motor, 617 is a development drive clutch, 618 is a registration roller clutch, 619 is a storage tray paper feeder, and each It's a load. The entire copying machine is controlled by a control program stored in the R0M 603.The control program is roughly divided into two parts; one is a program that processes image editing input, copy mode input, etc. (standby routine); One is a timing control program (copy routine) for the copying process load.The image editing inputs processed in the standby routine are the image area input from the area operation unit and the area layout input from the keyboard.Example of load The erase unit, optical axis movement motor, development drive clutch, registration roller clutch, and storage tray paper feed clutch shown in FIG. 16 are based on the data input above.
'F timing etc. are controlled. Image area data Xl 12 Fl 'I
Area data after t layout α1 α2 β1
β2 Normal copy temporary erase data Xt
y, y. If the initially input area data, area data after layout, and temporary erase data during copying are set to the above values (
(See Figures 17(a) and (b)) Erase unit:
Area data after layout and normal erase data Optical axis movement motor: Image area data (yx) and data after layout (βl) Registration o-rough latch: Image area data (xl') and data after layout (α1) It is controlled by the calculation. The operation of erase data will be explained based on FIGS. 18(a) to (cl).
) shows how the image area data for each Mlia inputted from the area operation unit 612 is stored at a specific address in the RAM 604. The number of image areas for one document is not limited to two. The figure (b) shows how normal copy temporary Haylace data is stored at specific addresses of the ROM 603 for each size. Here, X5rX*Vi is the clock number indicating the blinking timing of the erase unit, and Y 1 + Y z indicates each half of the selection data of the light emitting elements in the erase unit. FIG. 4C shows the calculated erase data for each document. Here a
is the number of clocks per unit length of α1, YI(β
1. β1). Y2 (β1.β2) is half data of the erase element selection data changed by βl and β2. The amount of movement of the optical axis is represented by R(β1F+), and the value of R changes depending on the zoom magnification when copying the image area. The reso roller clutch ON timing is a(αr
t) + Z. a is the number of clocks per unit length of α1, and 2 is the number of clocks for the registration roller during normal copying. When there are developing units of multiple colors, the OFF timing of the developing drive clutch is changed depending on which unit is selected, and the unit corresponding to the input color is selected. The storage tray paper feed clutch is timed and driven so as to feed the transfer paper stored in the tray when an even-numbered image area is copied. 620 to 622 are photosensitive drums; These are a resistor and a photo interrogator that detect the notch of a circular bread having radial notches that rotate in synchronization and emit a clock pulse.The timing of the copying machine is controlled by the number of pulses.Next, the present invention Regarding operation 70- of FIG. 19 (al~(c
). Enter the editing range for manuscript A (3 types). →Enter the editing range for manuscript B (3 types). →Enter the editing range for manuscript C (3 types). →Fj, copy the contents of Edit 1 of draft A and store it in the storage tray. →Copy the contents of Edit 2 of manuscript A and stock it in the storage tray. →Manuscript A
Copy the contents of Edit 3 and stock it in the storage tray. →A copy of Edit 1 is sent from the storage tray, and the content of Edit 1 of manuscript B is overlaid and sent to the storage tray again. →A copy of Edit 2 is sent from the storage tray, the content of Edit 2 of manuscript B is overlaid, and the copy is sent to the storage tray again. →A copy of Edit 3 is sent from the storage tray, and the content of Edit 3 of manuscript B is superimposed on the copy and sent to the storage tray again. →A copy of Edit 1 is sent from the storage tray, and the content of Edit 1 of document C is further copied, ejected, and stored in the first bin of the sorter. →A copy of Edit 2 is sent from the storage tray, and the contents of Edit 2 of document C are further copied, ejected, and stored in the second bin of the sorter. →A copy of Edit 3 is sent from the storage tray, and the content of Edit 3 of document C is further copied, ejected, and stored in the third bin of the sorter. Effects The present invention is as described above, and according to the present invention, by guiding each edited content to a separate stocker, there is an effect that subsequent classification work is not necessary.

[Brief explanation of drawings]

Figures 1 and 2 are diagrams showing the internal configuration of a copying machine, which is the premise of the present invention, Figure 3 is a diagram showing a state in which a sorter is connected to the copying machine shown in Figure pR2, and Figure 4 is a diagram showing the operation unit. 5(a) and 5(b) are plan views showing the display and operation section of the tri ADF. FIGS. 6(a) to 6(g) are views showing various states of the display section. The figure is a block diagram of the image editing area input section, Figure 8 is a diagram showing the RAM Matsu f, Figure 9 is an explanatory diagram of the pressure-sensitive sheet, and Figure 10 is a state in which a document is placed on the pressure-sensitive sheet. Figure 11(a). (b) is a diagram showing the image area shift pattern wAt-, FIG. 12 is a diagram showing the RAM MA and Z at that time, and FIGS. 13 and 14. FIG. 15 is a diagram showing the positional relationship of lenses for image editing, FIG. 16 is a control block diagram of the copying machine according to the present invention, and FIGS. 17(i) and (b) are diagrams showing image area data and image area. Figure 18 (a3 r (b), (c) is i
Figures 19 (a), (b), (c) showing RAM maps related to 1-image area data and erase data.
is an explanatory diagram showing how to edit 1.2.3 for manuscripts A, B, and C'. 9... Photoreceptor, lO... Charging device fil (charger), 8... Illumination exposure optical system device, 11... Presentation device, 615... Erase device (erase unit), 3
0... Storage device (storage tray), 28... Switching device #
(1st r-t), 33... sorter. Figure 7 Figure 3 Figure 77, (a) Figure 18 (a)
(b)(c)

Claims (1)

[Claims] A charging device that uniformly charges the photoreceptor, an illumination exposure optical device that projects a light image of the original onto the photoreceptor, a developing device that develops the image formed on the surface of the photoreceptor, and a charging device that uniformly charges the photoreceptor. An erase device that selectively erases the formed image, a paper feed device that feeds the transfer paper, a storage device that temporarily stores the transferred copy paper, a discharge device that discharges the transferred copy paper, and a discharge device that discharges the transferred copy paper. A storage device that stores transfer paper, a discharge path that connects the transfer position and the discharge device, and a passage that connects the transfer position and the storage device;
In a copying machine that has a switching device that selects these two paths, an operation input device that inputs the desired editing of the original image, and a display device that displays the input status, it is possible to input multiple editing contents at the same time. An image editing copying machine characterized in that after continuous copying of a plurality of edited contents, transfer paper is stocked in separate locations in a storage device for each edited contents.