JPS60133472A - Image forming device - Google Patents

Abstract

PURPOSE:To sort recording materials after image formation in different modes according to the modes by controlling a stacking means on the basis of data stored in a memory means. CONSTITUTION:An elevator 210 is lifted up previously and all shelves 202 are mounted on the upper side of a cam 108. When copy paper is ejected from a main body and detected by paper detectors 106 and 107, the elevator is lowered by one stage and the lowermost shelf falls from the cam to stack the copy paper on the shelf. When the next copy paper is detected, the elevator is further lowered to stack the copy paper. When one group is copied completely, a solenoid 105 operates to free the cam 108, and the elevator 210 is lifted up. This operation is repeated until the quantity SET stored in a RAM, then the copying operation is all stopped. For example, when A4, 5, CHANGE, SET, ENT, 10, SET, and ENT are inputted with keys, five groups of ten sheets are copied.

Description

[Detailed description of the invention]

The present invention relates to an image forming apparatus that forms an image on a recording material. Conventional copying machines only make copies of a predetermined number of copies of one original by setting the number of initial copies at one time, or make copies in specific colors such as monochrome or three colors by setting the color mode at one time. It is possible to copy from the same original onto different paper sizes, copy in different color modes, or make different numbers of copies depending on the paper size and color mode, or even different copies depending on different originals. The operator has to set the copy mode such as the paper size and the like every time each copy is made, which is troublesome. In addition, in cases where multiple copies have been made, or when multiple originals are copied in different modes, the operator can sort a large number of copies into the desired classification or classification after a series of copies have been completed.
are divided by number of sheets. As the number of copies increases, this becomes a very troublesome task, and when the copies are to be separated by mode, the task becomes even more troublesome. The present invention has been developed in view of the above points, and includes a storage means capable of storing data related to an image forming operation for a plurality of image forming parts;
An image forming means for forming images on a recording material in mutually different modes based on data stored in the storage means, and a storage means comprising a plurality of storage parts for storing recording materials on which images have been formed by the image forming means. and a control means for controlling the storage means based on the take stored in the storage means. As a result, it is possible to sort recorded months whose images have been formed in different modes using a storage means that operates based on the mode. The present invention also provides an image forming apparatus which automatically makes nine copies one after the other in different copying modes, such as overlapping, from the same original. Another object of the present invention is to provide an image forming device that automatically makes copies one after another in a true copying mode, and another purpose is to make copies from the same original several times in the same copying mode, and also to automatically exchange the original and make copies of other copies. It is an object of the present invention to provide an image-forming apparatus which copies from an original in different copying modes, and another object of the present invention is to provide an image-forming apparatus which automatically makes copies one after another in different copying modes from the same or different originals, and again by introducing the modes one after another. Another object of the present invention is to provide an image forming device that repeats copying multiple times, and another object of the present invention is to provide an image forming device that displays a copying mode currently being executed and a cedar copying mode to be executed next. Another object of the present invention is to provide an image forming apparatus capable of color copying, which makes copies of different combinations of color modes from the same or different originals;
1 Tsukasa - Is it double-sided copying from the original to both sides of the desired paper? (The other purpose is to automatically make copies of the same original one after another in different production modes. The purpose of the present invention is to provide an image forming device that performs copying in the same combination as the copying mode of the first original, and classifies the cobby strings according to the copying mode.See page 1 below. Figure 1 shows a color copy to which the present invention can be applied. Both sides are scanned with 2 beams of light, and a faithful color representation (by mixing three colors) is applied to the filter 4 of Jj''5 and 7j, and the color angle 'C' is applied to the 81k on the photosensitive drum 8. A light image is irradiated onto the photoreceptor, and a latent image is formed on the photoreceptor by applying a light beam to the charge, which has been pre-charged by the band 1l1. Then, this 71'-year-old image was visualized using the yellow developer 17, and it was visualized as:
is transferred to the copy paper wrapped around the transfer drum 9.
a1.9 is the feeding roller 15 from the selected cassette 16.
For example, A4 size paper is fed. The same original image is then scanned again with the filter 4 trimmed to the edge, and an electrostatic latent image is formed on the photoreceptor in the same manner as described above. This latent image is initialized by the magenta developer 18, and the visible image is transformed into the above 1' (
Transfer it to photo paper and superimpose it on the previous yellow image. Next, change the filter 4 to red and operate the cyan developer 19,
A cyan visible image is formed in the same manner as above, and this visible image is superimposed on the two-color image on the copy paper to form a three-color superimposed image. Thereafter, the copy paper is separated by the timing operation of the separation claw 10, and while being transported by the conveyor belt 12, it is melted and fixed by the fixing device 11, and the copy paper is made into a copy with colors faithful to the original, and is discharged from the machine by the roller 20K. be done. Figure 2 shows an example of the operating section of such a photocopier. A combination of a button switch and a display element such as a lamp or a light emitting diode is used to enable selection and display at the same time. The one that lights up when Switch, Ji is pressed and IA+O, and the point 91 at an appropriate interval
f!
It is possible to set the TI beauty punishment separately and show the brightness level of the display element such as a small lamp or light dimade. i'i754'
Distinguished display is also possible by subtracting k. K
2 is the number of copies and the copy thread tlAI. Set 5; “D” is the first numeric keypad, and DISP2 is the outer numeric keypad.
, I) The IRP 3 displays the number of copies completed during the copying process, and I) The ISP 4 then uses a display device pE to display the number of copies to be made in 1-j. (An example is shown in which a two-digit number can be displayed.As the display element 7, for example, a 7-segment diode) can be used. K5 is a switch group for setting the twist of copy paper, for example A3, A4, B4,
Insert a stored cassette such as B5 into the cassette. ! ], and display for each size can be provided. This switch is also recessed and self-illuminated like the switch K1, and is indicated by a lamp, light emitting diode, or the like. K6 is the switch K1, switch K2, switch K
5, a switch for storing the data set by switch K7 and switch K9 in the storage circuit. K7 is a switch for setting the number of copies (repeatedly) to be made, and the required number of copies is determined by switch K2. DISP8 is a display section made up of 7-segment light emitting diodes like 3 to 5, and has an upper part that displays the settings for how many copies to make, and a lower part that displays how many copies have been completed so far. It is divided into two parts. K9 is a switch to be set when the original needs to be replaced, and at the time of setting and at the time when the original should be replaced, an appropriate means is used to display a lighting indication as described above. The operation of the copying machine can be temporarily stopped by the CHANGE signal and restarted by the copy start switch K12. In addition, when using an automatic original supply means called an auto feeder (Fig. 8.9) or a step feeder in conjunction with a copying machine, this signal can be used to automatically exchange originals (described later). . (10 is a switch for temporarily stopping the operation of the copying machine, and K11 is the switch Kl, K2, K5, IC
7. Program to cancel the data set by K9
The switch. K12 is a copy start switch, and several types of booters set by the switch are activated by the ENT switch K6.
After the settings have been transferred and stored in the storage circuit, when the COPY switch K12 is set to 1, the settings are read from the storage circuit in the order in which they were set and the copying operation is started. This switch also includes switch K9CHANGE and switch K
It is also used when restarting a copying machine whose operation has been temporarily stopped by 10PAUSE. If you do not need a memory circuit and want to copy only one type of copy, use switches Kl, K2, and K5 to set the copy switch. By pressing Ki3 (SINGLE), a copy can be obtained in the same way as a conventional color copier. Switch K14 (BOTH) U is for double-sided copying, and is a copying machine equipped with a second copy paper feeding means. The signal from this switch causes the second feeding means to feed copy paper that has been copied on one side again for copying (described later).Generally, when performing copying work, it is necessary to select the necessary color, The number of required copies and the size of the copy paper are selected.The present invention stores a plurality of sets of the above settings in advance in a memory circuit, reads out the settings one song at a time, and An example of the control circuit shown in Figs. 3 and 4 is r<.t.
Press the Color SELECT key to select the 2lM type keys in Figure 2. You can choose at 3 out of 10 years old. Tatashi, TWO
Once (2 colors) and FULL (3 colors) are selected, no further color selections can be made for the copying operation. First, when B-Y or K1 is selected as a color selection code, it is encoded by encoder ENC1 and sent to register RGS.
Enter I as a 5-digit binary signal. Next, when you select the second color (eg G-Y), the B-Y signals of the contents of register RGSI are transferred to register R.
After being transferred to GS2, the second color code is stored in register RGSI. Next, when the third color (example RM) is selected, this signal is 0.
1010 transfers the contents of RGS2 to RGS3 and the contents of RGSI to RGS2, and then enters RGSI. Therefore R
Color selection signals for the third color, second color, and first color are temporarily stored in GSI, RGS2, and RGS3, respectively. Note that the mechanism for sequentially storing data in RGSI, 2.3 is known as shown in Figures 7 (a) and (b). In other words, T
1 to T4 are timers that output the output shown in FIG. 7, and the timed operation is started by pressing any key K1. The first key input is stored in RGSI at ■, and it is transferred to RGS2 at ■.
The second key input is stored in RGSI. The same applies below. That is, if the code signal is +1 in the order of the developing device, each R
The color code stored in GS is oooooi, 0010
It becomes 1,01010. After that, the contents of RGS1 are multiplexer MPX13, decoder DEC3, gate GATEI, driver DRV3.
, and the contents of RGS2 are MPXI4, DEC4,
Following GATEI and DRV3, the signal is also supplied to the display DISPI through the MPX15, DEC5, GATEL and DRV3 contained in RGS3 (7'), and lights up the display (color key) in a yellowed color. Ushida color mode TWO, that is, when B, G, R, R&BK is selected, and when FULL (10101) is selected, the individual squares on the cape do not enter RGSI in succession. 1) 17th to 21st of EC3 (TWO color and FULL
(corresponding to color information) is detected and read to RGSI. It is prohibited to import. Furthermore, DEC3,4,
Converts a 5-digit 5-bit code to 21 line output. I) RV amplifier. K2 is a key switch for setting the number of first five sheets, and the number selected with the key is encoded into four binary digits by an encoder ENC2 and entered into RGS4. The output of RGS4 is MPX8,D
It is supplied to DISP2 through ECI and DRVI and displayed on the right side. If you need a paddle that requires a double-digit number of shots, then two ♀
The signal you press on the eye becomes the lower digit, and the contents of RGS4 become RGS.
5, the display is also displayed through MPX9, DEC2, and DRV2. After the transfer was completed, K2's inner tank traced ENC2 and entered RGS4 with Mc, and MPX8, DECI, I
) The signals are displayed on the display device of DISP2 through RVI, and therefore, the signals of the lower digits are temporarily stored in RGS4 and the signals of the upper digits are stored in RGS5. DECI,2 converts 4Nt into a 7 segment signal. K5 is the copy paper size setting key, and the selected signal is encoded with ENC3 (4 digits) and RGS6.
to go into. R ('jS6 contents are MPXI8, DECI3
, DRV9, and is displayed on the DISP5, ie, the self-operated button of K5, for example. Paper size setting is RGS
6 is temporarily stored. K9 is a setting switch for giving a control signal for supplying the next original A to the automatic original supply device to replace the original. When K9 is pressed, the signal is encoded with ENC4 and sent to RGS7. It will be done. The double-sided copying signal when K14 is pressed is encoded with ENC4 to {1, same as the signal of K9, and sent to RGS7. 1701 against K9, K
l. 4 to 10. To “RGS7 Denokawa”jl-
'X2+1, DEC15, l)RV]. 1 [Set DIS6 CHANGE key 9 or BOT
11 meters of the H key will display 76 self-illuminated lamps [7]. CHANGE again. No. or BOTH Shinpei i
:I{. Temporarily recorded on GS7. Write the above ii constant data to the memory RAM ↑17″,・
Use ENT key 6 to do this. Entrusted by Yoshishita 8E3lWl. ENT key K. 6 yoshitai? -Tl is 7'ta', I
RA? A pulse of an appropriate time is generated to input into the if. The signal becomes a WRITE signal that commands 1L writing into the RAM, and is sent to gates G3 to G9, 24, and R
It is also sent to AM. After passing the octopus note through the OR gate OGI, add it to the gate G2 along with the clock pulse of the clock oscillator,
The gate output is counted by counters CT2 and CT3 and converted into an output of 32 via a decoder (not shown). This output causes the memory R. Specify AM's X address O to 31. Also, the output of the OR gate OGI is used as a counter CTI.
Count j7 and specify the Y address of the RAM. In addition, the outputs of counters CT2 and CT3 are decoded into 10 communication signals via decoder DEC12, and a trigger signal (corresponding to the predetermined location of the X address) is generated by matrix MATI.
Make the latch LAI ~ 8. The output pulses of the latches LAI~8 become sub-pulses according to the memory order of the RAM, and when this is applied to the gates G3~9, 24, the outputs of these gates become actual write command signals and are applied to each multiplexer. , the signals temporarily stored in RGS1-7, 23 are transferred to the RAM and stored therein. In the RAM, input data necessary for one type of copying (copy mode) is stored in one line by the ENT signal. X1~Xs is the third color of color selection from RGS1, e.g. B-Y
Then, the signal is 1 and the rest is 0, and RGS is for X6 to X, o.
For example, for B-M, select X. is 1 and the remaining 0
Signal, X1? ~X1, is RGS, the first color of color selection, X16~X1, is RGS, the lower digit of the number of sheets, X
2. ~ x3, to rJ: F, GS, to O tvcb": i: r i, 5, r24"-X27 to RGS, to size I N@X23,
B'OTH{. SET from RGS2B for i, X3o
Shake the servant book with the servant. When inputting ``P1''chiEI-TTJinichishu, the contents of RG reading are P, kuPXIMPX2MI'X3MPX4MPX5
RGS2 via MPX6-MPX22-MIFX23
2 is stored in RjlRAM and gate G3
Output ■ According to Shinichi, the contents of RGS2 are the same as the above for Z, which was created for the operation of MPXI, and also gate G.
4. Kushiro force ■・[Contents of No. 1 and GS3 are the same as above). ．． '[On the route after PX2, the output of gate G5 is also output ◎ By faith, the contents of RGS4 are the same as the above jhJ 8'fP
X3. L:. In his route, the contents of RGS5 are the same as above, and in his route, the output [F] signal of G7 causes RG
The contents of S6 are input to the RAM in the route after MPX5, and the contents of RGS7 are input to the RAM in the route after MPX6 according to the output [F] signal of gate G8. RGS22 is used as a parallel input and a serial output, and sends the data temporarily stored in parallel in RGSI to 7 to the RAM as a sequential signal. Further, after inputting ENT, the next copy mode h in which the copying operation is to be continued is stored in the next f) of the RAM by manually inputting the key after inputting ENT in the same manner as described above, and by inputting ENT again. All registers, counters, flip-flops, and RAM are cleared when the power is turned on and after all copying operations are completed. Next, I will explain the operation of memory RAM. When the Copy key is pressed to start the copying operation, the timer T2 generates a pulse with the required time width to read one row of data from the RAM. This signal is the gate OG7 gate
GI is applied to υ gate G2. Since clock signals from clock oscillators CI and QC are further applied to gate G2, clock pulses are output for only the necessary time. The pulses are counted by the counter CT2.3 to designate the X address. Also counter CT
The outputs of 2 and 3 are passed through decoders DECI and 2 to MA}IJ.
MAT1 and drives latches LAI~8. Also, the W power of timer T2 is a READ signal for reading out the contents of RAM, and is sequentially read by the outputs of latches LA1 to LA7 and the outputs from GIO to GIO16 according to the READ code, respectively. 11, 12, 16, 17, 1
9.21 to read the necessary data from the designated area of the RAM. That is, the contents of one row of RAM are retrieved as follows. Color information X0 to X, is MPX. RGS through?
, X6 to XIo are connected to RGS1 through MPXtt,
, X, 1 to X1s are RGS through MPX+*, 1-digit number information X, 6 to X,, is RGS through MPX,,. G
S14, same 2 digits @X,. To -X, go λiPX1, through RGS, 8, size information X, 4~X,, go MPX
1, through RGSB1, ChangoBoth information X
2m+n is RGS through MPX2s. It is remembered in the glue. After drying, the contents of RGS11 are transferred to DEC through DirXlm.
, to, the contents of RGS12 are DEC by stating M'PX,4.
4, the contents of RGS,a are sent to DEC, through MPX1,
and each signal is sent to a copying device, and
I) The outputs of EC3-5 are applied to DISPI through GATEI and 'DRV3 to display color selection. At the same time, in the color copier shown in FIG. 1, a developer is selected to match the development timing, and a filter is selected to match the exposure timing (described later). Next, for the content of the number of copies in RGS14, the first digit of the number is set in CNTI, and for the content of RGS15, the second digit is set in CNT2. At the same time, this value is displayed on the display device DISP3 through DEC9, 10 and DRV5, 6, respectively. Also RGS14.
The contents of 15 are each switched to MPX8.9 (7)! ) DE
It is displayed on the display device DISP2 through CI,2 and DRV1,2. DISP3 returns to υO by starting copying, and CNT
I, 2 count the supply signal from the greeting card}L, DIS
Display the count value on P3 and compare the count {lα and the set value with COMPI, 2, and if they match,
Generates CTU signal. Then, enter the next mode of copying (described later). The CTU signal clears CNTI,2 and also stops the sheet feeding operation. Also, the paper size answer for RGS18 is MPX18, DECi
3. It is sent to DISP 5 through the DRV 9 string and performed for Shinjibon. At the same time, the output of the DEC 13 is sent to the nuclear printer, which selects the cassette containing the copy paper. In addition, the control system is also returned based on this flaw signal when it differs depending on the sequence production 11 reactor 1 for original scanning. ChangeBoth contents of kGs20 are MPX20
, and sent to the copying machine through the DEC 15. As mentioned above, in order to replace the original, there is a signal that temporarily stops the operation of the mounting unit, but it is also a function that does not allow double-sided copying (described later).The output of the LDEC 15 is DRV]
．． 1 to display a dot illusion on DISP6. When this message appears and the Sokei temporarily stops working, the user should replace the original and then press the Copy key.
By pressing r''} times, the IL will continue copying work.
Do C. The present invention is characterized in that it not only displays the contents of the copying operation currently in progress, but also displays the contents of the copying operation to be performed next. This operation will be explained. The output of the timer T2 started by the Copy signal and the C obtained from the sheet number counter CNTI, GATE3 of 2.
TU signal is applied to gate 25, and this output signal starts timer T3. The output pulse width of timer T3 is the same as the output pulse width of timer T2. This signal is applied to gate OG7 along with the output of timer T2, and the output is counted and decoded in the same manner as described above and passed through the matrix to drive latches LAI-8. Latch LAI~8
The output signal of passes through gate GIO~16 and gate G17.
~Added to 23. Since the second readout signal RFJAD is added to the other inputs of G17 to G23 from the output of timer T3 after the copy button is pressed for the first time or after the CTU signal is output, this signal The contents of the RAM are then read out. On the other hand, the Y address counter at this time is in the RAM because it is the line next to the line in which the contents of the first copy to be performed are currently stored.
The content read and found is the content of the copying operation to be performed next. Therefore, the procedure for reading out the contents of the copying operation to be performed each time is to use a control signal from gate G17 to
Xll is transferred to RGS8, and the process is performed in the same manner as described above until finally, RAMX2 is transferred to RGS21 using the control signal of game G23. The contents of RGS8 are passed through DEC6 and GATE2, and the contents of RGS9 are passed through DEC7 and GATE7.
The contents of GS10 are DRVed through DEC8 and GATE2.
Added to 4. DRV4 is then applied to P and DISPI by adding the output of a signal generator that blinks at an appropriate period. The contents of the copying work to be performed are displayed in a flashing manner. It is also possible to provide another display driven by DRV4. The contents of RGS16 are DEC11;
Through DRV7, and RGS17 (7) contents are DEC1
2. Displays the number of copies to be added to the DISP 4 through the DRV 8. The contents of the RGS 19 are transmitted through the DEC 14 and DRVIO to 1) be added to the ISP 5, and display the paper size of the next copying operation using a blinking signal as described above. The contents of RGS21 are transmitted through DEC16 and DRV12.
It is added to the ISP 6 and displays by blinking whether or not there is a manual pause for original replacement after the next copying operation, an original replacement using the automatic original supply device, or a double-sided copying operation. Furthermore, the contents of the register that stores the next cycle mode are transferred to RGSII through MPXIO when the CTU signal is obtained (after the current copying operation is completed).
Then, the contents of RGS9 are sent to RGS12 through MPX11, and the contents of GSIO are sent to RGS13 through PMX12.
Then, the contents of RGS16 are transferred to RGS14 through MPX16.
The contents of RGS17 are MP. RGS1 through X17
5, the contents of RGS19 are transferred to RGS1 through MPX19.
8, the contents of RGS21 are sent to RGS2 through MPX21.
0 and a new copy cycle continues. The next storage contents of this transfer end U-included RAM are read out to RGS8, 9, 10, 16, 17, 19.21 and displayed as the contents of the next clear photographing operation. Next, I will explain about the SET command. 6th [iyl] is a circuit diagram related to SET, which is a continuation of FIG. 3. SET can easily combine the above cobby modes several times.
．． It is for. Along with changing the original one after another,
This is effective for performing ↑t+copy of a different copy mode to the original. For example, you can get one A3 size copy from a Meridian using a G filter and an M developer, an R filter and a BK developer, and then use an ND filter and a Y developer from another original B to make the same copy. When you perform the two-mode operation 10 times to obtain one A3 size copy and obtain a total of 20 copies,
First, press the SET key, then store the data regarding original A using the FNT key, then store the data regarding original B using the ENT key, and then use the number key K2, SET key K7, and ENT key K6 to select 10. store in memory. Motoi No. 8 i-1, such as color and year change, is stored in each RGS. ENT Kuiichi is 41P, and the -1:1l-b number mentioned in 11 is D"Tsuzugi in a certain RAM strange place, >.tGS's s1v
For the T fortune-telling, the data is stored in 30 boxes of RAM via the MPX 23, which switches the output when the clock pulse reaches 30. Copy mode that adds 1″ζ1 to original B}” {=
After storing $M in the 211th position of the RAM using the ENT key, use the key K2 for setting the number of sheets to store the number of sets in RGS4.5, and then press the SET key to store the number in RGS23.
Store 1vT A, then press the ENT key to RA
This number of sets and the SET flaw number are stored in the third inertia of M. To further explain this point, since we have confirmed that the SET key has been pressed for the second time by checking the set state of flip-flop FF2, the contents of RGS4 are transferred to MPX27 via Game 1-G30. Also, the contents of RGS5 are output to MPX28 via G31. MPX27.28
The above is the output of FF2 and the third gate number 1 person, snow:
Since the output is cut by the AND output of 7 and minus 1, MP by ENT
ENT after the second SET key including switching of X1
Depending on the key, the number of sets is 1~5, 6~ on the third line of RAIv1
It is stored at address 10. The path of the sweet color information becomes the path of the number of sets. Note that FF'2 is cleared by manual effort using any key of K1. Also, this Xa1a signal is MPX25,2
The signal is output to decoders 17 and 18 via drivers DRV13 and DRV14, and is decoded into a 7-segment signal, which is displayed on a display device DISP7 via drivers DRV13 and DRV14. The Y address (row) at the time of writing is determined by the counter CT1, which increments by one in response to the ENT4n signal. Next, I have a question about reading the SET signal. I will clarify. When the clock 30 is counted after the copy timer and a SET signal from X30% is obtained, it is stored in the RGS 26. We will explain how to print a predetermined number of copies from the Y address row where the signal is located to the Y row size where the next sET signal is obtained. When the first SET'IN number is input to RCS26, it sets F3, clears RGS26, and returns G3.
4, store the Y address at that time in RGS27,
Set it to CNT5. The Y address is the CTI mentioned above.
obtained from. When +=, input the signal of FF3 to 0.38 to stop the increment of the X address, and obtain the Y address of the next SET number stored. Tsu''!!
:． ! CNT5 is advanced by CLOCK until SET is obtained in 2RGsz6, and only the Y address is passed through G36. Seven Y addresses are MPX50, MPX5
1 to CTI. When the second SET number is obtained in RGS26, FFa is reset, G35 is turned on via inverter 1, the Y address at that time is stored in RGS28 via G35, and set in CNT6. CL of 1 ladle (timer T4) from G37 after setting
Scan the X address using OCK to find the number of sets, and then use the second SET signal to set JIRAMX+-X4,Xs.
-The numerical position of Xs is
(upper digit) case ir + sa h. , rt. When the scan of only T4 is completed, the time-up coefficient of timer T4 is signaled and the contents of RGS27 'cP9L.' are sent to CNT5. , +ILMpxso,51 via 1-, to RGS27 +
1 Set the Y address to CTI. By the way, R
D via PX25, 26 of the number of pairs of GS24, 25
There is mud on the top of ISPLAY8 i'1. ．． cNT3,4
is set to CNT 3rd and 4th edition by Coby. This is a counter that counts the number of sets that is cleared with the DIS.
Displayed at the bottom of PLAY8. When the Y address is entered on the next line after the first SET line, the machine waits for the count 1 up CTU signal to be output from the copy machine. Nao X
The address gate G38 is the second SET signal (FF3
reset). In response to the CTU signal, as described above, the next row is scanned by the X address from CLOCK, and the coby mode information is stored in each register from the RAM. Shift the line for each CTU, scan and SE again
When it comes to the row with T, switch MPX51 and RGS2
The first Y address stored in 7 is set in the counter CT1 via the MPX51. Then, the set number counter CNT3 is incremented by 1 in response to the signal COMP7. Again, the copying operation is repeated by reading the mode information from the first SET line to the second SET line. and R.G.S.
When the count values of CNT3 and 4 match both the upper and lower digits with the number of sets stored in 24 and 25, the G40 outputs a number indicating that the copying of the predetermined set has been completed, and that signal increases CNT60 by +1. Then, the row next to the row in which the number of sets is stored is set in eNT6, outputted to CT1 via G41, and a new Y address is set in CT. T4
The timer is started by the second output of the RGS 26, and the X-scan between the DT4s is thereby performed in the number of rows. Also, for MPX51, the Y address after T4 is RG.
When it becomes equal to the address content of S28, RGS27 is output, and otherwise, CNTS is output. The Y address counter CT, increments from the preset point by the output of the gate OG1, but may be O after the program copy is completed. In this explanation, for the sake of simplification, the lines of each register multi-grab, etc. are not clearly shown, but they can be understood with the explanations and examples. By further increasing this capacity, it is possible to increase the number of color combinations by expanding the ma/ko display area.

[It's my own. Regarding RGS, enter numbers 1 to 7 using the key ``-''. I
! ;Transfer to NT-Go1ζA8・I Clear friend, lma+
/ {Valley RGS2-\+ij: Send provisional, now included [11 description (Dplot<T'WO, when FULL signal, read double thread stop 2 and 4 are each internal 1~GS3, RGS5l\After transfer Load. 8, 9, 1 (N, Copy timer number T, and CTU {7 respectively, Rcss is MPX1
0fjM to RGSII, ItGS9 is transferred to RGS12 through MPXII, RGSIO is transferred to RGS13 through Ml)X12, and after 7t, each RAMX, ~X,,X
, ~X, o, X1, -X1, is read. 11, 12, 13, 14.15 are input signals thereto. 16.17 is Copy timer signal Jp, T2 and CT
RGS16 connects RGS through MPXt6 with each U signal.
After being transferred to 14, RGS17 transfers MPX17 to 51
0 and transferred to rtGs15/After that, each Ry'w'
Incorporate MX+s~X,,,X2o-X, into R'2. 18 is the input signal input l7, 19 is the copy timer signal T2 and CTIT signal RGS19). iPX1
9 to RGSI. After being transferred to Ti. AMX
, 4 to X27. 20 is input code, 2
RG with 1 copy timer signal T2 and CTU signal
After S21 is transferred to RGS20 through MPX21, RAMX28 is loaded. 23 is inputted by input signal, transferred to RAM and cleared by ENT. 24, 25 FF3 Nori+1・te stares at RA 8q. About MPX MPX1 is RGSI when controller number ■ is L.
When , is H, RGS2 is transferred to MPX2. Similarly, 2 is ■L to MPXI, I{ is RGS3 to MPX3, 3 is ■L to MPX2, H is RGS4 to MPX4, 4 is 0L
In MPX3, ■ in 1 y aS5 to MPX5, 5 is [F]
MPX4 with L, RGS6 with TI MPX. f3, 6d
■) ■MPX5 with ■7, RGS7 with ■{~IPX22
Transfer to 1. 8 and 9 are 1tGsl4, Rcsl5 during CopyM
Otherwise, i”.i:lζGS4, i%GS5 are output. 10, 11, and 12 are each RAMX1 by Copy Gogo.
~X5,X,~X,. ,X1? ~X, , otherwise RGS8, 9.10 is output. 13, 14.15 is C
opyM Taketaka Makanaka RGS11, 12, l3i, others output RGSI, 2, a. 16.17 are RAMX and 6-X respectively by the Copy signal
,,,X,. ~X2, and the rest are RGS? ．． ,RG
Output S17. Similarly, RGS18 is used during the x8idCopy period, RGS6 is used at other times, and 19 is Co
pRAMX24 to Xgy for the pyli issue, RGS19 for the others, RGS20 for 20 during the copy period,
Others are RGS7, 21 is RA by Copy signal.
MX,8 is output, and RGS21 is output for the others. 23 is MPX22 when the control signal is 0L, and RGS2 when it is H.
3 to RGS22. 25 is RG during the copy period
S24, then G30 for DEC17-, 26
Same as GS25, otherwise G31 is DEC
Transfer to 18. 27.28 are the same as above. Next, an example in which two original autofeed devices f, i, and : are provided will be explained. 2+>, 8] It;j: The CHNGE signal drives the original feed rollers 52 and 53, and this causes the original 50' sent after being divided into one sheet out of the originals 50 to be detected as the original. When detected by the device (lung, light receiving element), the rollers 53 and 54 stop, and in synchronization with the exposure scan start signal (drum predetermined position signal, etc.), the rollers are driven again and the original is moved and υ exposed by the lamp. It is something that The original is stopped on the exposure surface, and scanning exposure is performed by moving the lamp 2 and optical system back and forth. Eject the original after exposure. Add the original sheet to the repeat drum 66.
The process is the same as above until the original is detected by the rung and the light receiving element 42 and the transfer is stopped. Start copying with the copy button {E by ffl issue
i ni m}, i11L cam circle oμ (1 of photosensitive drum
1.] Just the same Ju! ) by A'{i;. (When the Shaoren number is fired, the repeat drum 66 starts rotating by the same number, and at a predetermined position of 11), the sheet jυ41. , 50' are conveyed by the drawer '1-ra 54.55 and the feed-9 roller 52, and
1;i50', the guide crow 43 is carried by the reheat drum 6 in its gripper 71 in synchronization with the L drum 1,
Slit sushi light. For one copy, repeat 1゛ram 6G, then D1
Rotate with the fixed {x>:Ity;-t to release the grip and push the tip 1 of the sheet original 50' into the flap of the guide plate 72. -La73
, 74, and made a U-turn at F2, where J-so was placed on the sieve tray 92. At this time, the grip is released and sheet 1/original 50' is fed by presser rollers 45 and 46. If the key K2 is set to several pieces of pine, the sheet that was illuminated by the slit will appear. The tip of the name is repeat drum 6
While being held in the grip 71 of No. 6, it passes under the guide plate 72 and is again illuminated by the slit M at the guide glass 43. the same number of times p for the required copies
, be'k. JJJ'. 'FS is concave-like discharge lJ1 as described above. The drop was detected by the second pump 41 and the light receiver 42, and stopped temporarily.
Shocho {Unfortunately, Otaka Shitohara in the first photo had a grip of 7.
1, the repeat drum 6G is rotated to a predetermined position, and then conveyed. The addition and release of the grip 71 is performed according to the AND condition of the number-of-sheets count-up signal and the aforementioned CHANGE signal. Therefore, the same original can be copied again in different copy modes, such as in different sizes. 9 and 10 are time charts and circuit examples of the auto 7 eid in FIG. 8. When the power is turned on, the clutch CUi is turned on and the repeat drum rotates, and when the repeat drum comes to the home position (near the position where the gripper 71 adds the original), the cam switch MS3 is turned on, so the CLI is turned off and the rotation is stopped. Next, when the copy button is turned on (start), the clutch C. Turn on L2 to drive rollers 54 and 55 to feed the original. With the original tip detection signals from the detectors 41 and 42, c- is turned off 1 to stop feeding +1-. do. Next, the feed lambda signal is sent to the photocopier. Boat feeding roller 3 rotates to '14' when it is joined from the side.
1 place, lowers and feeds the copy paper, and also lifts the
- Rotate the drum. Kamui σ rotates in synchronization with the drum J:! ) Turn on/off MSI, MS2 and C again
Turn on L2, turn on solenoid sL1y, close the gripper, and add the original. By the copy button! ) If I got 2' of Ranono, I changed Nyoshi's original to NbuC, and optical thread 30+'? Ra25'r"simultaneously via 1k'
The original l1 () is projected onto the photosensitive surface of l'bt7i7.
4ltsu1) }ifil#:l: I'm pushing out coby mode from the RAM, but if in the meantime cITANG
When the E coefficient is input, the flip-flop 551 is set. Then, when the count-up CTU {i number 3 is obtained from the copy}, the cam plate driving the gripper is turned on and the original is removed from the drum. Then, send the new original to MS in synchronization. ! ? i
51&-. 1: Reset after a slight delay from the occurrence of CTU. Then, the CTU makes it possible to latch the CHANGE{N number again by the memory scan during the timer T3. On the other hand, the electrostatic latent image formed on the photoreceptor 8 is formed into a toner image by the developing device 35 in the same manner as the cobia shown in FIG. The image is fixed by the fixing roller 40 and discharged onto the tray 30 by the roller 222. On the other hand, the drum surface is cleaned of residual toner by a blade cleaner 21, and after cleaning the original exposed image by the second rotation of the repeat drum 66, the photoreceptor surface charged by the positive charger 6 is subsequently exposed to light in the same manner as described above. . Also, the Cobia shown in Fig. 8 can be copied on both sides of copy paper by pressing the BOTH key on the operation panel. When the BOTH signal in the RAM is read out and the trailing edge of the fixed copy paper is detected by the paper detector K using the lamp and the light receiving element 24, the drive of the roller 22 is stopped every odd number of times and the claw 47 is raised. The trailing edge of the copy paper is directed toward the second feeding path 48. Then, the roller 22 is reversed, and the copy paper collected at the halfway point of the tray 30 is sent to the roller 27 of the second feeding path 48.
The same paper feed timing signal PF used to drive the paper feed roller 15 drives the roller 27 and sends the paper to the transfer section. Furthermore, roller 2
The rotation of 7 is turned off by the 240th light receiving element, and the claw 47 is turned off by the PF.
Lower it at the signal. Then, the even-numbered toner images formed on the photoreceptor in the same manner as described above are transferred onto this copy paper, and this time it is discharged onto the tray 3o. In this case, the paper feed roller operates every odd number of times of the PF signal. In the case of this double-sided copying, use the key K as shown in Fig. 2, for example, in order of A4, 1, BOTH,
CHNGF. ,ENT,CHANGE,ENT,A4,
2, CHANGE, ENT, SET, 50, l':NT
By pressing , the first and second originals can be double-sided copied for the first sheet, and after the second sheet, 50 sets of 2 & 50 single-sided copies can be made in order starting from the third original. The paper feed signal for counting the number of sheets is the signal when the row 215 is actually activated. Also, for the cobia of ζ, a book can be copied by moving the lamp 2' and the mirror 25' to positions 2 and 25 and emitting slit N light in the E direction. For example, set the BOTH key to BOOK, set the departure signal BOTH to BOOK, and set the B
The lamp 2' and mirror 25' are moved to the above position by the OOK signal, and the lamp 2' is turned on to make a reciprocating operation 1)). For example, A4, 10, ENT, A4, 2, 'BOOK,
When you key in in the order of ENT, when the sheet mode (indication 0) is read by COPY start, 10 copies of the original sheet are made at the 25', 2' position, and when the count up CTU code appears, the next mode is activated. Give out a total of 1 information symbol. When the BOOK code is detected, it immediately switches to book mode 2
A copy is made and the CTU signal returns to the original position 25', 2'. The register for reading 1 is cleared with the CTU{@ number, and then the third line is scanned, and if there is nothing, the rotation of the dome 8 is stopped after a predetermined period of time, and the copying operation is stopped. After that, the power is turned off after a predetermined period of time. In Figure 9, 550 is a comparator, OG50
3,517 is an or gate, 501,513 is an inverk, other gates are and or nand gates, 507,
518 and 524 are drivers. Next, color selection will be explained. 11M is a color I selection circuit, which is a decoder DEC in FIG.
3, 4.5, 1 to 16 of the 21 wires are connected to each resistor RGS113 to RGS111 through a diode D115i. Then, the combination of the filter, filter, and imager required for the first h-light scan is stored in RGSIII, and those required for the second and third scans are stored in RGS112 and RGS113. In addition, RGS111 to 113 are DEC3 and 4.5 respectively.
Input when there is an output. Two-color, full-color selection signals 17-21 are connected to terminals 1-16 of each resistor via a diode D114. A, B of multiplexer MPXIII, 112, 113
, C, the first color combination of RGS111 is output from MPX113 and B,G
, R, and N, and one developer for Y, M, and C are specified. If A is given high11 level and others are given L, it will output the second color, and if B, h1gh level, C or L level, it will output the third color, and if C is level H, it will output O. The signals to A, B, and C drive different processing modes depending on the color mode. FIG. 12 is a time chart for the case of three colors of the color copier shown in FIG. In other words, the transfer drum is rotated twice from the start of copying, that is, the photosensitive drum is rotated once, and then the above-mentioned color processing process is performed with one rotation of the transfer drum for each color, which is half a rotation. This is because two images are created in one rotation of the photosensitive drum. If it is full color, the Y, M, and C modes are sequentially processed, the photoconductor is rotated once, and the post-rotation mode is entered (transfer drum rotates twice), and the drum motor IM1 is turned off to stop the cobia. be. DI{O based on one rotation of the drum that transfers these modes. It is called ~. Of course, the photosensitive drum and the transfer drum rotate in synchronization with the motor IM. In these modes K, the copy paper feed solenoid SOL
The operation timing of No. 1 and the operation timings of the developer and filter are limited to one of the modes. Furthermore, in the case of two-color copying, the process mode is forward rotation l, 2, color processing, Y, M,
There will be seven, backward rotation 1 and 2, and in the case of one color, there will be three, color processing Y and backward rotation 1.2. Furthermore, in the case of continuous copying, the Full Duffler repeats Y, M, C, Y, M, C in order and finally enters backward rotation modes 1 and 2. Therefore, it is necessary to selectively operate the developing device, filter, etc. in an appropriate process mode, regardless of whether it is three colors, two colors, or one day. The circuit for this purpose is shown in Fig. 13, where three colors, two colors, and a single color are set at gates G134 to G136, and the number of rotations of the transfer drum is set at gates Gioi, 132, 133, 139, and 1.
4011C is set, and the pulse DHP generated at the home position by the rotation of the transfer drum is sent to the flip-flop FF.
At 141 and 142, titt is set, logical performance 1-L and process mode number P1-1~P14+"2-1~P!-3
G124-129 from F'-1, F-2 from G104,
105, b-1 and b-2 are output from G130 and 131. Incidentally, FUBIE EN'D is a stop signal or a count-up CTU signal from the operation panel, which allows the process to be shifted to the post-rotation mode. Also a
The llend signal is used to turn off the main motor IMI after a predetermined number of post-rotations. Initial reset is performed at power-on. Figure 14 further shows the classification of color process modes into 3 colors, 2 colors, and single color. When the combination of process mode signals is input to A, B, and C in FIG. 11, set and set signals for the filter and developer are output at desired mode timings. Further, the combined signal of B, G, R, N, Y, M, C, B, K is gated by a precise actuation timing signal by the drum pulse DPS according to FIG. 15(a).
(b)(8), output. The fiDPs generates a predetermined timing signal using the counter CtTT150 and the decoder DEC150, and the DH-P resets the count. For example, blue filter B is set with DPSO and 1) PS
It is reset at 2. During this time, the filter B is held in the exposure path by the amplifier 150. FIG. 16 shows the copier shown in FIG. 8 provided with a sorter, and the present invention can separate multiple sets of copies using the SET signal from the RAM and this printer. 161 is a sorter, 162 is a copy paper conveyance belt, 202
210 is a storage dana, and 210 is a sorter elevator. The elevator 210 has been raised in advance, and all the tapers 202 are on the upper side of the cam 108. Copy paper is ejected from the main body and sent by belt 162, and when the paper is detected by paper detection 2: ÷ 106, 107 (lamp and light receiving element), the elevator goes down one stage and the bottom tongue falls from above the cam. Therefore, copy paper is stored in the container. When the next copy paper is detected at 106, 107, the elevator lowers again and stores the copy paper. When one set of copies is completed (on the CTU second train), the solenoid 105 is actuated to release the cam 108 and then raise the elevator 210. When the apex is detected with the switch 210, the rise of 210 is entered, the copy of the same & 6(a) Game shown in figure}G40
signal) stops all copying operations. For example, manually input the keys A4, 5, C} LANGE, SET, ENT.
, 10, SET, ENT, you can make 5 copies of 10 sheets per copy. Further, the size command signal can be a well-known one that selects the necessary one from a large number of cassettes. Also, copying with a different magnification can be done by changing the same way as in the case of BOOK copying. fil, create a RED key, store RED, and release it. When the lens system 30 (FIG. 9) is taken out, the lens system 30 (FIG. 9) is zoomed and the exposure scanning speed is changed. It is. In each of the above examples, the copy button and the CTU signal are used to retrieve the image from the RAM very quickly, and the exposure can be completed before the start of exposure.As described above, the present invention is capable of copying by programming the handling mode in advance. Therefore, there is no need to wait for the next copy, and unattended operation becomes possible. Therefore, it is a good idea to sound a buzzer to let others know when all the copies have been completed. For example, CT
Timer T with a longer time limit than timer T2+T3 every month,
. Activate to end the time period (in color, the after rotation time is 9
long) to turn on the buzzer. Also, the present invention is called -? It is also extremely easy to achieve the above objectives using software using a microcomputer.

[Brief explanation of drawings]

FIG. 1 is a schematic sectional view of a copying machine to which the present invention is applicable, and FIG. 2 is a diagram of a sweeping board of the copying machine according to the present invention. ．． 67ztA7 Figure 1 shows an example of a program control circuit according to the present invention, Figure 5 shows an example of memory contents according to the present invention, Figure 8 shows a double-sided diagram to which the present invention can be applied, and the original auto-feed copying machine is shown with a cutaway side. Figure, Figure 10 Figure 9 shows an example of a time chart and autofeed circuit, Figure 11 shows an example of a color selection circuit, Figure 12 shows a color] Chart diagrams, Figures 13 and A14 are diagrams showing an example of the color process mode setting path, Figure 15 is a diagram showing an example of an operation timing circuit, and Figure 16 is a sectional view of the sorter. is a color selection key, K2 is a sheet number setting key, K5 is a size key, K6 is a storage command *-, K7 is a set key, and DISP2-6Fi display. 463 464 465 466 467 468 469

Claims (1)

[Claims] a storage means capable of storing data relating to an image forming operation for a plurality of image forming parts; an image forming means capable of performing image formation in different modes based on the data stored in the storage means; A storage means comprising a plurality of storage parts for storing recording systems formed into images by the image forming means, and a control means for controlling the storage means based on data stored in the storage means. An image forming apparatus comprising: