JP2713575B2 - Copier - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a copying apparatus in which a fax mechanism can be combined, and more particularly to a paper passing counter in a copy mode and a fax mode.

(Prior art)

Conventionally, when a facsimile machine and a copying machine are combined, there is a problem in a paper passing counter of the combined machine. That is, if the user selects a system that pays a certain fee for one copy, the number of received faxes is added to the normal number of copies, which causes inconvenience. In particular, when the key counter is used to count the number of copies for each department, the print data printout of the fax data is not counted, which causes confusion.

〔Purpose〕

SUMMARY OF THE INVENTION The present invention has been made in view of such circumstances, and an object of the present invention is to provide a copying apparatus in which a fax mechanism that does not cause a problem in sheet counting can be combined.

〔Constitution〕

In order to achieve the above object, the present invention provides a scanner unit for optically reading an original, a storage unit for storing data received via a communication line as storage data, and a data from the scanner unit or from the storage unit. It is intended for a copying apparatus having a printing unit for printing stored data.

Determining means for determining whether or not the printing unit can print the storage data; and determining whether or not the number of sheets to be printed when the storage data is printed, Counting means for counting separately from the number of sheets, and when the judgment means judges that the storage data can be printed, the printing section stores the data from a state in which data from the scanner section can be printed. It is configured to automatically switch to a state in which data can be printed, print the stored data, and automatically switch the counting of the number of passed sheets to the counting means to count. Is what you do.

 Next, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram of the entire composite apparatus. As shown in the figure, the multifunction device includes a scanner A and an operation unit B.
, A plotter section C and a fax section D.

The scanner unit A includes a scanner control unit, a CCD, an automatic document feeder (ADF), and the like. Operation unit B
Is provided with an operation panel described later. The plotter section C includes a main control plate for controlling the entire operation, a sequence control plate for controlling the operations from the supply of the transfer paper to the discharge, and a sorter. The fax part D includes:
It has a fax interface and a communication circuit.

Next, a specific configuration of a digital copying machine as a copying apparatus will be described. FIG. 2 is a configuration diagram of the entire digital copying machine, and FIG. 3 is a plan view of a writing unit in the digital copying machine.

First, a schematic configuration of a digital copying machine will be described with reference to FIG. As shown in the figure, the digital copying machine has a copying machine body (I), an automatic document feeder [ADF] (II),
It consists of four units, a sorter (III) and a double-sided reversing unit (IV).

The copying machine body (I) includes a scanner unit, a writing unit,
A photoconductor unit, a developing unit, a paper feeding unit, and the like are provided. Next, the configuration and operation of each unit will be described.

(Scanner part)

A first scanner which is equipped with a reflecting mirror 1, a light source 3 and a first mirror 2 and moves at a constant speed, and is equipped with a second mirror 4 and a third mirror 5 and is a half of the first scanner. A second scanner that moves following the first scanner at a speed. The original (not shown) on the contact glass 9 is optically scanned by the first scanner and the second scanner, and the reflected image is guided to the lens 7 via the color filter 6 to be placed on the one-dimensional solid-state imaging device 8. It is imaged.

A fluorescent lamp, a halogen lamp, or the like is used as the light source 3, and a fluorescent lamp is generally used because the wavelength is stable and the life is long. In this embodiment, the reflecting mirror 1 is attached to one light source 3, but two or more light sources 3 may be used. Since the solid-state imaging device 8 has a fixed sampling clock, the fluorescent lamp has an adverse effect on the image unless it is turned on at a higher frequency.

As the solid-state imaging device 8, a CCD is generally used. Since the image signal read by the solid-state imaging device 8 is an analog value, it is subjected to analog / digital (A / D) conversion, and various image processing (binarization, gradation processing,
(Scaling processing, editing, etc.), and converted into a digital signal as a set of spots.

In this embodiment, in order to obtain color image information, a color filter 6 that transmits only necessary color information is provided in the middle of the optical path guided from the document to the solid-state image sensor 8 so as to be able to enter and exit. The color filter 6 is moved in and out in accordance with the scanning of the original, and functions such as multiple transfer and double-sided copy are operated each time, so that multiple diverse copies can be created.

[Write section]

The image information after the image processing is written on the photosensitive drum 40 in the form of a set of light points by raster scanning of laser light in an optical writing unit.

A He-Ne laser was used as a laser light source. The wavelength of this He-Ne laser is 633 nm, which has been used because it matches well with the sensitivity of conventional photocopiers. However, the laser light source itself is very expensive and the equipment cannot be directly modulated, which makes the equipment complicated. It has problems such as becoming.

In recent years, semiconductor lasers that can be directly modulated at low cost have been used due to the increase in sensitivity in the long wavelength region of photoconductors. This semiconductor laser is also used in this embodiment.

 FIG. 3 is a plan view showing the writing section.

The laser light emitted from the semiconductor laser 20 is converted into a parallel light beam by the collie-met lens 21, and is shaped into a light beam of a predetermined shape by the aperture 32. The shaped laser light is
The light enters the polygon mirror 24 in a form compressed in the sub-scanning direction by the first cylinder lens 22.

The polygon mirror 24 has an accurate polygon and is rotated at a constant speed in a constant direction by a polygon motor 25 (see FIG. 2). This rotation speed is set to
And the writing density and the number of surfaces of the polygon mirror 24.

The reflected light of the laser light incident on the polygon mirror 24 is deflected by the rotation of the mirror 24. The polarized laser light sequentially enters the fθ lenses 26a, 26b, 26c. fθ
The lenses 26a, 26b, and 26c convert the scanning light having a constant angular velocity so as to scan the photosensitive drum 40 at a constant speed.
An image is formed so as to be a minimum light spot on the surface, and a surface tilt correction mechanism is also provided.

The laser light that has passed through the fθ lenses 26a, 26b, and 26c is guided to the synchronization detection sensor 30 by the synchronization detection mirror 29 outside the image area, and after a certain period of time from the generation of the synchronization signal for generating the cue signal in the main scanning direction, the image data is Are output for one line, and thereafter, this is repeated to form one image.

(Photoconductor unit)

A photosensitive layer is formed on the peripheral surface of the photosensitive drum 40. Organic photoconductors (OPC), α-Si, Se-Te, etc. are known as photosensitive layers sensitive to a semiconductor laser (wavelength 780 nm). In this embodiment, the organic photoconductor (OPC) is used. ing.

In general, in the case of laser writing, there are two types of processes: a negative / positive (N / P) process in which light is applied to an image portion, and a positive / positive (P / P) process in which light is applied to a background portion. Adopts N / P process.

The charging charger 41 is of a scorotron type having a grid on the photoreceptor side, uniformly (-) charges the surface of the photoreceptor drum 40, and irradiates a laser beam to the image forming unit to lower the potential of the portion. Then, the background portion of the surface of the photoconductor drum 40 has a potential of -750 to -800 V and the image portion has a potential of about -500 V, and an electrostatic latent image is formed on the surface of the photoconductor drum 40.
A bias voltage of -500 to -600 V is applied to the developing roller by the developing units 42a and 42b, and the electrostatic latent image is visualized by attaching the charged toner to (-).

(Development section)

The apparatus of the present embodiment includes two developing units, a main developing unit 42a and a sub developing unit 42b. In the case of solid black, the sub-developing unit
42b and the toner replenisher 43b are detached. In this embodiment having two developing units, black toner is put into the toner supplying unit 43a paired with the main developing unit 42a, and color toner is put into the toner supplying unit 43b paired with the sub developing unit 42b. During the development of a color, the development is selectively performed by changing the position of the main pole of the developing device of another color.

This development can be combined with the reading of color information by switching the color filter 6 of the scanner, the multiple transfer of the paper transport system, and the screen copying function to perform multifunctional color copying and color editing. For development of three or more colors, there is a method of arranging three or more developing devices around the photosensitive drum 40, a revolver method of rotating three or more developing devices, and the like.

The images visualized by the developing units 42a and 42b are
The transfer charger 44 applies a (+) charge to the sheet of paper which has been synchronized to 0 and is transferred from the back of the sheet. The transferred paper is subjected to AC static elimination by a separation charger 45 held integrally with the transfer charger 44, and is separated from the photosensitive drum 40.

The toner remaining on the photosensitive drum 40 without being transferred to paper is
The cleaning blade 47 scrapes off the photosensitive drum 40 and collects it in an attached tank 48. Further, the pattern of the potential remaining on the photosensitive drum 40 is erased by irradiating light with the charge eliminating lamp 49.

A photo sensor 50 is provided immediately after the development. The photo sensor 50 includes a pair of a light emitting element and a light receiving element, and detects the reflection density on the surface of the photosensitive drum 40. In this method, a certain pattern (for example, a pattern of black or halftone dots) is written in a position corresponding to a reading position of a photo sensor by an optical writing section, and after the development, the reflectance of the pattern section and the photoreceptor drum other than the pattern section are developed.
The density of the image is determined from the reflectance ratio of 40. If the image is light, a toner supply signal is output. In addition, the fact that the density does not increase even after replenishment can be used to detect the lack of the remaining amount of toner.

(Paper feeding section)

In this embodiment, a plurality of cassettes 60a, 60b,
The transferred paper is passed through a re-feeding loop 72 to enable double-sided copying or re-feeding.

When a start button is pressed after one cassette 60 is selected from the plurality of cassettes 60a, 60b, 60c, the sheet feed rollers 61 (61a, 61b, 61b) near the selected cassette 60 are pressed.
61c) rotates, and the paper is fed until the leading edge of the paper hits the registration roller 62. Although the registration roller 62 is stopped at this time, it starts rotating at a timing and an image position formed on the photosensitive drum 40, and feeds the paper to the peripheral surface of the photosensitive drum 40. Thereafter, the toner image is transferred at the transfer section, and the paper is suction-conveyed by the separation / conveyance section 63, and the heat roller
The transferred toner image is fixed on the paper by a fixing roller composed of a pair of a pressure roller 64 and a pressure roller 65.

At the time of normal copying, the paper transferred in this manner is guided to the paper discharge port on the sorter (III) side by the switching claw 67. On the other hand, at the time of multiple copying, the sheet passes through the lower sheet re-feeding loop 72 without being changed in direction by the switching claws 68, 69, and is again guided to the registration roller 62.

There are two types of screen copying: a case where only the copying machine body (I) is used and a case where a double-sided reversing unit (IV) is used. Here, the former case will be described. Switching claw 67
The paper guided downward by is further guided downward by the switching claw 68,
With the next switching claw 69, the tray 70 further below the refeed loop 72
Led to. Then, the sheet is fed again in the reverse direction by the reversal of the roller 71, is guided to the sheet re-feeding loop 72 by the switching of the switching claw 69, and is fed to the registration roller 62.

[Automatic Document Feeder (ADF II)]

The ADF automatically guides documents one by one onto the contact glass 9 and discharges them after copying.

The document stack placed on the document feeder table 100 is aligned in the width direction of the document by the side guide 101. The placed documents are separated and fed one by one by the feeding roller 104,
By the rotation of the conveyor belt 102, it is carried to a predetermined position on the contact glass 9 and positioned.

When the predetermined number of copies have been completed, the original is discharged onto the discharge tray 103 by the rotation of the transport belt 102 again. In addition,
The document size can be detected by counting the position of the side guide 101 and the document feeding time.

[Sorter (III)]

The copy paper discharged from the copying machine main body (I) is stored in the bin 111a, for example, in a page order, for each page, or
It is a device to selectively feed to ~ 111x. Copy paper fed by a plurality of rollers rotated by the motor 110 is guided to the selected bin 111 by switching the pawls near the entrance of each bin 111.

[Double-sided reversing unit (IV)]

As described above, the copying machine main unit (I) can perform only double-sided copying for each sheet. However, by attaching the double-sided reversing unit (IV), double-sided copying can be performed collectively.

When making a double-sided copy of a plurality of sheets, the sheet guided downward by the sheet discharging roller 66 is sent to the both-side reversing unit (IV) by the next switching claw 67. The paper that has entered the double-sided reversing unit (IV) is accumulated on the tray 123 by the discharge roller 120. At that time, the length and width of the copy paper are aligned by the feed roller 121 and the side alignment guide 122. The copy sheets stacked on the tray 123 are re-fed by the re-feed roller 124 at the time of back side copying. At this time, the sheet is guided directly to the refeed loop 72 by the switching claw 69.

In FIGS. 1 and 2, reference numeral 23 denotes soundproof glass,
27 is a mirror, 28 is dustproof glass, 31 is a lens holding unit, 46 is a separation claw, 80 is a main motor, and 81 is a fan motor.

(Electric control unit)

FIGS. 4a and 4b are block diagrams of the entire copying machine. Both figures are obtained by dividing one block diagram. A part of the central processing unit CPU (a) has an overlapping portion. When these figures are connected, a single block diagram is obtained.

The control unit of the copier has two CPUs.
(A) controls the sequence, and the CPU (b) controls the operation. CPU (a) and C
PU (b) is connected by a serial interface (RS232C).

First, the sequence control will be described. The sequence controls the timing of paper transport, such as paper size sensors, paper transport sensors such as paper ejection detection and registration detection, duplex units, high voltage power supply units, relays,
Drivers such as solenoids and motors, sorter units,
A laser unit, a scanner unit and the like are connected.

For sensors, a paper size sensor that detects the size and orientation of the paper loaded in the paper cassette and outputs an electrical signal according to the detection result, a sensor related to paper conveyance such as registration detection and discharge detection, an oil end A signal is input from a sensor that detects the presence or absence of a supply such as toner or toner end, and a sensor that detects a mechanical abnormality such as a door open or a fuse break.

In the duplex unit, a motor for aligning the paper width, a paper feed clutch, a solenoid for changing the transport path, a paper presence / absence sensor, a home position sensor for the side fence for paper width alignment, and a sensor for paper transport are provided. is there.

The high-voltage power supply unit applies a predetermined high-voltage power to the charging charger, the transfer charger, the separation charger, and the developing bias electrode.

The driver relation includes a paper feed clutch, a resist clutch, a counter, a motor, a toner supply solenoid, a power relay, a fixing heater, and the like.

It is connected to the sorter unit by a serial interface, and conveys the paper at a predetermined timing according to a signal from the sequence and discharges the paper to each bin.

The analog input includes a fixing temperature, a photo sensor input, a laser diode monitor input, and a laser diode reference voltage. The fixing temperature is controlled on and off by an input from a thermistor in the fixing unit so that the temperature of the fixing unit is constant. The photo sensor input is
A photosensor pattern formed at a predetermined timing is inputted by a phototransistor, and the density of the pattern is detected, so that the toner supply clutch is turned on and off to control the toner density.

An A / D converter and an analog input of a CPU are used as a mechanism for adjusting the power of the laser diode to be constant. This is controlled so that the monitor voltage when the laser diode is turned on matches a preset reference voltage (this voltage is set so that the laser diode becomes 3 mW).

The image control circuit generates timing signals such as masking, tricking, erasing, and a photo sensor pattern, and sends out a video signal to the laser diode.

The gate array synchronizes a 2-bit parallel image signal from the scanner with a synchronization signal PMSYNC generated by a racer beam scanner unit, and further converts the image signal into a 1-bit serial signal synchronized with an image writing signal RGATE. Output to the image control circuit.

Next, operation-related control will be described. The main CPU controls a plurality of serial ports and a calendar IC. Sequence control CPU for multiple serial ports
In addition, an operation unit, a scanner, a fax, an interface unit, and the like are connected.

The operation unit has a display for displaying the key input of the operator and the status of the copying machine. The key input information is transmitted serially to the main CPU, and the display is turned on by serial reception from the main CPU. The scanner transmits information on image processing and image reading serially, and exchanges preset information contents with the fax and interface unit. The calendar IC stores the date and time, and the machine can be turned on and off based on this information.

FIG. 5 is a block diagram of the image scanner section.
An analog image signal output from the CCD image sensor 407 is amplified by a signal processing circuit 451 and converted into a digital multi-value signal by an A / D converter 452. This signal is subjected to correction processing by a shading correction circuit 453, and is applied to a signal separation circuit 454.

By processing the image information input to the signal separation circuit 454,
It is separated into a binary image component signal such as a character and a halftone image component signal. The binary image component signal is applied to a binarization processing circuit 456, and the halftone image component signal is applied to a dither processing circuit 455. The binarization processing circuit 456 converts the input multi-value data into binary data according to a preset fixed threshold value. The dither processing circuit 455 determines input data based on a preset threshold value for each scanning position and outputs binary data including halftone information.

The signal synthesizing circuit 157 synthesizes the binary signal output from the binarization processing circuit 456 and the binary signal output from the dither processing circuit 455, and outputs a signal DATA1 and a signal DATA2.

The scanner control circuit 460 controls the lamp control circuit 458, the timing control circuit 459, the electric scaling circuit 461, and the scanner drive motor 465 according to an instruction from the printer control unit. The lamp control circuit 458 performs on / off and light amount control of the exposure lamp 402 according to an instruction from the scanner control circuit 460.

A rotary encoder 466 is connected to a drive shaft of the scanner drive motor 465, and a position sensor 462 detects a reference position of the sub-scanning drive mechanism.

The electrical scaling circuit 461 performs electrical scaling processing on dithered image data and binarized image data in accordance with the main-scanning-side magnification data set by the scanner control circuit 460.

The timing control circuit 459 outputs each signal according to an instruction from the scanner control circuit 460. That is, when reading is started, a transfer signal for transferring one line of data to the shift register and a shift clock pulse for outputting the data of the shift register one bit at a time are applied to the CCD image sensor 407. For the image reproduction system control unit,
It outputs a pixel synchronization clock pulse CLK, a main scanning synchronization pulse LSNG, and a main scanning valid period signal LGATE.

The pixel-synchronized clock pulse CLK is substantially the same as the shift clock pulse applied to the CCD image sensor 407. The main scanning synchronization pulse LSYNC is a main scanning synchronization signal PMSYNC output from the beam sensor of the image writing unit.
However, the output is prohibited when the image is not being read. Main scan valid period signal LGATE
Goes high at the timing when the output data DATA1 and DATA2 are considered to be valid data.

In this example, the CCD image sensor 407 outputs valid data of 4800 bits per line. The output data DATA1 is data of each odd-numbered pixel, and the output data DATA is data of each even-numbered pixel.

When the scanner control circuit 460 receives a reading start instruction from the control unit from the printer, the scanner control circuit 460 turns on the exposure lamp 402, starts driving the scanner drive motor 465, and starts the timing control circuit 4.
59, and starts reading the CCD image sensor.
Further, the sub-scanning effective period signal FGATE is set to a high level H. This signal FAGTE goes to a low level L when the time required to scan the maximum reading length (in this example, the size in the A-size longitudinal direction) in the sub-scanning direction after being set to a high level H has passed.

FIG. 6 is a block diagram of the fax section. As shown in the figure, the fax unit is composed of a main board, a SAF unit, an FCU unit, a network control unit (NCU) that can be changed depending on the destination, a communication circuit and a telephone.

This system is based on memory transmission and reception.
Therefore, at the time of transmission, the document information is once stored in the SAF memory and then transmitted. Also, during reception, the data is stored in the SAF memory and then output when the printer is idle. The switching between the copy mode and the fax mode will be described later in detail.

FIG. 7 is a block diagram of the power supply unit. Power cord 80
Is supplied to the main power supply unit and the scanner power supply unit through the main switch (SW2) or the sub switch (SW1). The main power supply unit supplies DC power to a main control board, a sorter control board, a fax control board, and the like. On the other hand, the scanner power supply unit supplies DC power to a scanner controller, an ADF controller, an operation unit, and the like.

8 and 9 are a component arrangement view as viewed from the front and a component arrangement as viewed from the back of the multifunction peripheral. In FIG. 8, 82 is an operation unit, 83 is a power relay, 84 is an SSR of a heater, a transport fan, a motor, etc., 85 is a relay unit, 86 is a safety switch, 87 is a door switch, 88 is a total counter, and 89 is fax reception. A counter, 90 is a communication circuit board, 91 is a receiver, and SW2 is a main switch. As shown in the figure, the main switch SW2 is provided on the front side of the apparatus as in a normal copying machine.

In FIG. 9, 92 is a main control board, 93 is a noise filter, 94 is a circuit breaker, 95 is a cleaning power pack, 96 is a bias roller power pack, 97 is a blade solenoid, 98 is a charging / bias power pack,
99 is a toner supply solenoid, 105 is a resist detector, 106
Is a color detector, 107 is a manual feed detector, 108 is a network control unit, 109 is a first paper feed micro clutch, 112 is a paper end detector, 113 is a second paper feed micro clutch, and 114 is a third relay micro clutch. Reference numeral 115 denotes a resist micro clutch, 116 denotes a paper feed control plate, 117 denotes a modem, 118 denotes a fax interface plate, and SW1 denotes a sub-switch. As shown in FIG.
1 is provided at a position different from the main switch SW2, that is, on the rear surface of the multifunction device.

FIG. 10 is a power supply circuit diagram, and FIG. 11 is a DC power supply circuit diagram. As shown in FIG. 10, if any one of the sub-switches SW1 and the main switch SW2 is turned on, AC power is supplied to the main body. Main switch
The switch SW2 is provided with AC1 and AC2 for detecting whether the switch SW2 is ON or OFF. This AC
1, AC2 has a DC power supply circuit in which a circuit as shown in FIG. 11 is incorporated.

Therefore, when the main switch SW2 is off, AC is supplied, the photocoupler is turned on, and the input of the CPU goes low "L". On the other hand, when the main switch SW2 is on, the photocoupler is turned off, and the input of the CPU goes high "H".

Next, how to use the main switch SW2 and the sub switch SW1 will be described.

(A). In the case of using the copier alone without using the fax function In this case, the sub switch SW1 is turned off, and the main switch SW2 supplies 100V power to use as a normal copier.

(B) ・ When used as a composite device of fax and copier a. Sub-switch SW1 is on and main switch SW2 is off A software reset signal is sent to each system, and each CPU that receives this signal resets the RAM clear and port. Turn off, etc., and are in the same state as the power-on reset (however,
The CPU does not reset by this signal). At this time, the main relay connected to the sequence CPU is naturally turned off, and all the AC systems in the apparatus are turned off.

However, as apparent from FIG. 7, since 100 V AC is supplied to each of the main power supply unit and the scanner power supply unit, DC power is supplied to each CPU. In this state, for example, there is a state in which the main switch SW2 is turned off and the fax is in the night reception mode because it is not used as a copying machine at night.

At this time, when the sub-switch SW1 is turned off, 100 V AC is not supplied to the apparatus main body when the main switch SW2 is turned off, and all the power supply units are also turned off, so that night reception of the fax cannot be performed. Therefore, if there is no sub switch SW1 and only the main switch SW2, the main switch SW2 is not always turned on even at night (of course, in this state the power relay is also turned on, and the AC fan, preheating heater, etc. are also turned on. Power consumption is increased), and night reception cannot be performed.

In this respect, as in the present invention, the main switch SW2 and the sub-switch SW1 are separately provided so that the sub-switch SW1 is turned on and the main switch SW2 is turned off at night when the copying machine is not used. , The sequence, the output ports of the operation unit, and the power relay can all be turned off, which saves considerable power. The DC is supplied to the fax control unit (5 V, ± 12 V), so that the fax is in the reception mode.

b. A state in which the sub switch SW1 is on and the main switch SW2 is on By turning on the main switch SW2 from off, a program start signal is sent to each CPU, and each CPU starts operating.

When using a copier, if a copy error (for example, an error such as a paper jam or a serviceman call) occurs, the main switch is usually used to reset the error.
Turn SW2 off → on. In the case of a multifunction device with a facsimile device, the same switch is performed. At this time, if there is no sub-switch SW1, all the fax data being received or being transmitted will be cleared. However, at this time, if the sub-switch SW1 is turned on, even if the main switch SW2 is turned off to on, the transmission and reception of the fax is not affected.

FIG. 12 is a flowchart for selecting a fax and copy mode using keys. One key is provided for selecting the fax mode and the copy mode.
When this key is pressed, a buzzer sounds, and if the fax mode is already set, the fax mode is turned off, the user select flag is turned off, and the copy state before entering the fax mode is returned.

When the key is pressed, in the copy mode, the fax mode is turned on, the user select mode is turned on, and if the ADF return display is displayed, it is turned off. Feeds out, saves the copy mode at that time, and moves to fax mode.
At this time, a pad for switching the copy / fax display panel (which will be described later) in which the input surface for copy and the input surface for fax can be slidably changed is confirmed. For example, a warning message such as “Fax-no-panel” is issued.

FIG. 13 is a flowchart for selecting a mode of facsimile and copy by pad. When the pad is changed from the fax mode to the copy mode, if it is already in the copy mode, return as it is.If it is in the fax mode, the fax mode is turned off, the user select flag is turned off, the copy mode is set, and the copy status is set. Return to

When the pad is changed from the copy mode to the fax mode, the warning display is turned off if the pad mode is already in the fax mode.
Turn user select on. In the copy mode, the fax mode is turned on, the user select is turned on, the ADF is processed, the copy mode is saved, and the mode is shifted to the fax mode.

FIG. 14 is a flowchart of the mode reset of copy and fax. The default of copying and faxing can be switched by a dip switch or the like according to the user's request. At the time of auto reset, the mode is determined by this dip switch.

If the apparatus is not operated for a certain period of time (for example, one minute), an automatic reset is performed.

At the time of the initial state, the copy mode is set, and when the initial state is set to the fax mode, the copy mode is set. When the fax mode is set by user selection, the copy mode is set.
If it is not a user select, the copy mode returns to the initial state.

Switching by the fax / copy switching switch or pad is performed by a key counter (for example, a key card).
It can be done even without any. This is because the key counter is just a copy counter and has nothing to do with sending faxes.

FIG. 15 is a flowchart showing a key counter display. The key counter display is turned off when the key counter is on, or when the mode shifts to the fax mode even when the key counter is off.

FIG. 16 is a flowchart of the counter control.
The copier is provided with a counter for counting specific sheets other than the total counter. When the fax is online, when the copy feed signal comes, the counter is counted up in the fax mode, and is not counted up in the copy mode.

If the fax is not online, use it as a copy counter (A3 counter in this case) and count up when feeding A3 size paper. In this case, the A3 counter is used as an example, but the counter may be used as a jam counter or the like.

As a result, the total number of sheets passed is counted by the total counter, and the number of sheets passed by fax can be known by the fax counter, which is very effective in service to the user.

Also, here, the number of sheets passed at the time of fax is counted, but when the fax is connected, only the number of copies passed is counted.
It is the same principle.

FIG. 17 is a flowchart of sorter control. A sorter of a copying machine has a tray that is normally discharged and an interrupt tray that is discharged when a mode error or an interruption occurs. In the fax mode, the printed paper is discharged to an interrupt tray without being output to a tray normally used in a copying machine. This eliminates the inconvenience of copying a piece of paper sent by fax.

When a sorter is not used, a two-bin discharge tray is provided, one for a copying machine, one for a fax, and a tray for each mode. By using the two-bin tray, paper printed out by fax and paper printed out by copying can be separated.

FIG. 18 is a flowchart of control of fax reception in the copy mode. When the reception of the fax is completed in the copy mode, a print request signal is sent from the fax. If the printer is in the ready state and has not been operated for a certain period of time (for example, 30 seconds), a print OK signal is output and the mode automatically shifts to the fax mode. When the printer is not in operation or when a predetermined time has not elapsed even in the ready mode, a print NG signal is output.

In other words, the printer is not shifted to the fax mode in a state in which the printer is not ready, for example, a door open, a jam, a serviceman call, and the like, and there is a possibility that the copying operation may be continuously performed. As a result, the fax printout is performed only during the time when the device is open,
Downtime as a copying machine can be extremely reduced.

If an operation is performed by the operator during the print output, the user select flag is turned on.

FIG. 19 is a flowchart showing control of fax reception during the preheating mode. When the reception of the fax is completed during the preheating mode, a print request signal is sent from the fax. At this time, since the printer is in the ready state and is not used as a copy, the printer is automatically switched to the fax mode immediately. At this time, a print okay is output and the preheating flag is turned on.

If an operation is performed by the operator during this print output, the preheating flag is turned off and the user select flag is turned on.

FIG. 20 is a flowchart at the end of fax printing. When all the data received in the fax is output, the end of fax printing is sent when the last sheet is discharged. At this time, if the user select mode is on (the user turns on the fax mode and turns it on), the fax mode is continued, and the mode reset (FIG. 14) or the fax / copy switching switch or Do not enter copy mode until pad is operated.

When the user select mode is off, the fax mode is turned off. When the preheating flag is on, the mode returns to the preheating mode. When the preheating flag is off, the mode returns to the copy mode.

If there is a print request from the fax, the printer can shift to the fax mode and print out even if there is no key counter. This is because the key counter is just a copy counter and has nothing to do with fax printing.

Even if the number of copies is managed by the key counter, there is no mistake because there is a total counter and a fax counter.

When the mode is changed to the fax mode, the key counter display turns off.

All of these systems are connected by a serial interface, and a signal is sent to each system in the order of initial set → program start, and when each system (sequence, operation unit, scanner, fax) receives the program start, Perform normal operation. If only the initial set signal is used, it is waiting in each system initial state (RAM clear, out port off, etc.).

FIG. 21 is a flowchart showing a power control method, and this flow is incorporated in one part of a main routine. First, the timer checks whether a certain time has elapsed. This is because each system takes time to complete the initial reset at the time of reset.

Next, the main switch SW2 ON flag is checked. When this flag is ON, it is checked whether the main switch SW2 is ON (that is, AC detection is checked). When the main switch SW2 is on, the return is performed as it is. When the main switch SW2 is off, the check is performed again after 100 msec. (This is done for a certain period of time to prevent malfunction due to noise.) If it is on, return is turned off, if it is off, the flag is turned off, and the initial set signal is output to each system.

When each system receives this signal, it clears the RAM, turns off all ports, and creates a pseudo power off state. At this time, naturally, the sequence is also initialized and the relay is turned off, so that no AC is supplied into the apparatus. This state continues until the main switch SW2 is turned on.

If the main switch SW2 on flag is off, it is checked whether the main switch SW2 is on. If it is off, it returns. If it is on, it checks again after 100 msec. If it is off, it returns, if it is on, it turns on the flag,
Output the program start signal to each system. Upon receiving this signal, each system starts operating.

When using the switches SW1 and SW2 as a single copier without using the fax function, the subswitch SW1 is always turned off, and the main switch SW2 is turned on and off. On the other hand, when used as a copier-fax composite apparatus, the sub-switch SW1 is always turned on, and the main switch SW2 is used as a pseudo main switch. Usually, the time period during which the copier is operated is, for example, from 8:00 am to 8:00 pm, during which time the main switch SW2 is operated.
Is turned on, and at other times, the main switch SW2 is off. However, the fax must be available 24 hours a day.

Therefore, the DC power supply always operates by always turning on the sub-switch SW1. This DC
Since the power is supplied to the fax, the fax operates even when the main switch SW2 is turned off, and can receive.

Also, in this state, reception of the fax is completed,
When a print request signal comes, the system is started up (a program start signal is issued) and printed out. In this case, the system is started up, but only the printer may be started up.

After the printout is completed, an initial set signal is output again to turn off the system. When the initial set signal enters the fax, the fax only detects power-off and does not perform operations such as RAM clear and port off.

FIG. 22 is a flowchart of the fax print.

FIG. 23 is a plan view of an operation panel when used as a single copier that does not use the fax function, and FIG. 24 is a plan view of an operation panel when used as a multifunction device that also has the fax function.

In FIG. 23, 301 is a sorter key that is pressed when using a sorter, 302 is a double-sided key that is pressed when performing double-sided copying, and 303 is when automatically copying a two-sided original one by one, or automatically when two-sided originals are copied. A page continuous key 304 to be pressed when copying one side at a time; a liquid crystal display 304 for explaining the operation method and displaying the operation state of the apparatus;
Is a blank key that is pressed when cutting out the entire copy, 306 is a black-and-white reverse key that is pressed to reverse the black and white parts of the entire copy, and 307 erases the area outside the area specified by the line marker. Marker area erase key that is pressed when deleting, 308 is the marker area erase key that is pressed when deleting the area specified by the line marker, and 309 is the marker area that is pressed when the area that is specified by the line marker is cut out. A blank during processing key 310 is a marker area processing black and white reversing key that is pressed when reversing a white portion and a black portion within the range specified by the line marker.

311 is a double copy key that is used to simultaneously copy two small documents such as A5 and B6 sizes on double size paper, and 312 is used to copy at a magnification that matches the specified paper size and original size. Paper designation scaling key,
313 is the independent dimension scaling key pressed to specify the vertical and horizontal dimensions of the original: Original, 314 is the independent dimension scaling key pressed to specify the vertical and horizontal dimensions of the copy: Copy, 315 is the copy Independent scaling keys to be pressed to specify the vertical and horizontal magnification,
A zoom variable key 316 is pressed to specify the copy magnification in increments of 1%.

Reference numeral 317 denotes a copy / fax switching lever. When the lever 317 is switched to the copy side as shown in the figure, editing copy such as marker area processing and independent zooming is possible. When the lever 317 is switched to the fax side as shown in FIG. 24, the key operation of each function of the fax as described later becomes possible.

In the figure, 318 is a set number display area, 319 is a copy number display area, 320 is a reduction key, 321 is an enlargement key, 322 is an equal size key, 323 is a paper selection key, 324 is an automatic paper selection key, 325
Is a document type key, 326 is a density adjustment key, 327 is an automatic density key, 328 is a removable top cover (seal), and the top cover 328 is attached when used only as a copying machine. , 329 in the figure is an interrupt key, 330 is a program key pressed when storing or recalling a program, 331 is a preheat / mode clear key, 333 is an independent variable magnification mode, data and liquid crystal in the independent dimension variable mode A # key 334 pressed when answering a question on the display unit 304 is a start key.

When the copy / fax switching lever 317 is switched to the fax side, a part of the operation panel is automatically changed with the switching operation as shown in FIG. In the figure, 335 is a multi-mode key that is pressed when registering a one-touch dial destination, 336 is a telephone mode key that is pressed when manual reception is set, and 337 is a mini-fax 1 key that is pressed when the transmission destination is the mini-fax 1. , 388 is a normal character key pressed when the size of the original is larger than the normal size, 34
0 is a lowercase key pressed when the text of the document is small, 340 is a transmission key pressed to start transmission, and 341 is a one-touch dial key pressed to register a telephone number in onetouch or to make a onetouch call. .

When used as a composite device, the upper lid (seal) 328 shown in FIG. 23 is removed. Then, below the upper cover (seal) 328, as shown in FIG. 24, a shortening key 342, a pause key 343, a number key 344, a copy / fax changeover switch 345 and the like necessary for the multifunction device are arranged.

FIG. 25 to FIG. 27 are diagrams for explaining a switching mechanism (pad) of the operation panel display accompanying the switching of the copy / fax switching lever 317. As shown in these figures, a copy display panel 347 is fixed to the inner bottom of the rectangular frame 346. Above the copy display panel 347, a fax display panel 348 is slidably disposed.

As shown in FIG. 23, the copy display panel 347 has keys 305 and 306 for processing the entire surface and a key 307 for processing the marker area.
~ 310, double copy key 311, paper specification scaling key 312,
Keys necessary for the copying machine, such as independent size scaling keys 313 and 314, an independent scaling key 315, and a zoom scaling key 316, are provided.

On the other hand, as shown in FIG. 24, the fax display panel 348 has a multi-mode key 335, a telephone mode key 336,
Minifax 1 key 337, ordinary character key 338, small character key 33
9. Keys required as a fax, such as the transmission key 340 and the one-touch dial key 341 are provided.

At the rear end of the fax display panel 348, a filler 349 is provided.
Are provided integrally. In addition, the fax display panel 34
A switching lever 317 is connected to the front end of 8 so as not to interfere with the copy display panel 347. The switching lever 317 is connected to the upper end of a rotating lever 351 supported by a support shaft 350. A transmission type photo sensor 351 is provided at a position facing the filler 349, and is a panel cover 352 in the figure.

FIG. 25 shows a case where the copying machine is used as a copying machine, in which the switching lever 317 is tilted to the copy side, and the copy display panel 347 is exposed in the frame body 346, and various keys provided on the copy display panel 347 can be operated. It has become. In this state, the fax display panel 348 is hidden below the cover 342. By moving the switching lever 317 to the hook side (left side as viewed in the drawing), the hook display panel is accordingly moved.
348 are all pulled out from under the cover 352, and FIG. 26 shows a state in which the fax display panel 348 is being pulled out. FIG. 27 shows a state in which the fax display panel 348 is set in the frame 346. When the filler 349 is inserted into the photo sensor 351, a set signal for detecting the set state is output from the photo sensor 351. .

FIG. 28 is a control block diagram of the display panel unit. 351 in the figure is a photo sensor shown in FIGS. 32 to 34, 353 is an operation part key matrix, 354 is an operation part LED matrix, 35
5 is a display microprocessor, 356 is a latch, 357 is a decoder, 358 is a ROM for storing fixed display data as well as a control program, and 359 is an RA for storing arbitrary display data.
M and 360 are LCD controllers, 361 is a RAM for storing screen display data, and 362 is an LCD unit.

This operation unit is handled as one unit, and is connected to the copier controller via a serial interface to exchange data. The state of the input keys, the check and the LE are controlled by the display microprocessor 355.
D. Controls the contents displayed on the LCD while performing data communication with the copier controller.

The LCD consists of full dots and a dedicated LCD controller
360 displays the data stored in RAM 361. L
Fixed character data is ROM358 as CD display data.
These are stored in the RAM 361 corresponding to the ASCII codes sent from the copier controller. Also, depending on each system configuration, any necessary display data is displayed after being stored in the RAM 359.

The operation unit key matrix 353 includes input of each key of the operation unit, input of the depth switch, and input from the digitizer connected to the switching lever 317 shown in FIG.

FIG. 30 is a flow chart showing the flow of a transmission image signal,
FIG. 31 is a flowchart showing the flow of a received image signal. In these figures, 3 is the light source described above, 24 is a polygon mirror, and 40 is a photosensitive drum.

FIG. 32 is a block diagram showing a signal flow in the hook interface board.

In this fax interface board, the following control and processing are performed. As the CPU, 8085A × 2 is used, which has a frame memory for image processing of 0.78 MB and a SAF memory of 1 MB.

(1) System sequence control of the fax function (2) Protocol sequence control (3) Processing of image information Convert video signals from the scanner (2-bit serial signal to 8-bit parallel signal) Data compression and reproduction (MH, MR) , EFC) Reduction (B4 size → A4 size) Input / output of data to / from SAF memory and compression / reproduction during input / output (MH, raw data) (4) Multi mode, function selection by internal switch, and code selection (5) Control of Network Control Unit Next, the flow of signals when transmitting and receiving data will be described with reference to FIG.

(1) When sending data from the scanner unit to the line After converting the video signal (2-bit serial signal) from the scanner unit to an 8-bit parallel signal, the DR of 256K
Stored in frame memory composed of AM.

In fax, since the transmission density is 7.7 lines / mm and 3.85 lines / mm, it is contracted by 50% with a scanner, and the density is converted and stored in the memory.

For image processing gate arrays, A3 size → B4 size,
Only the conversion from B4 size to A4 size is possible, and when sent to the other party as fax, there is a possibility that the size of the document is reduced to A4 size. It is B4 size and then stored in frame memory.

After that, the data is sequentially taken out from the frame memory to the FCP1, and the data is sent to the FPC2 via the serial port.

At this time, the original is B4 size and the destination fax paper is
In the case of A4 size, FPC2 reduces the size by 84%, and reduces one frame data to the work RAM.

Data compression for one frame uses FCP2 and work RA
M2, and the result is transmitted via IOP2 to the modem (MODE
M), and sends out the modulated data to the line via the network control unit (NCU).

(2) When transmitting after storing in a memory by broadcasting or the like, the video signal from the scanner unit is temporarily stored in the frame memory, and then one frame of data is stored in the work RAM 1 via the FCP1. Then, the data is compressed between the FCP1 and the work RAM1, and the result is stored in the SAF memory.

When transmitting from the SAF memory, the compressed data in the SAF memory is read, the data is expanded between the FCP1 and the work RAM and converted to the original data, and then sent to the FCP2 serially. Send data to the line.

(3) When sending data from the line to the main control board The signal from the line is input to the modem (MODEM) via the network control unit (NCU), demodulated, and
Send to FOP2 via P2.

FCP2 decompresses the transmitted signal, restores the original data, and sends it to FCP1.

In FCP1, the data is compressed again and stored in the SAF memory. The compression method used in the above-mentioned compression differs depending on the model of the fax, etc., so when storing the data in the SAF memory, the data must be restored and compressed again in order to use the most efficient method. ing.

When a series of reception is completed, the compressed data in the SAF memory is decompressed by FCP1 and transferred to the frame memory.

When one page has been moved, a print command is sent to the main CPU to prepare for printout.

Sends out data in synchronization with LSYNC, LGATE, FGATE, WCLK, etc. of Imagio 320F.

At this time, since the data in the Fourem memory is 7.7 lines / mm, the data is enlarged to double (16 lines / mm), and the parallel signal is converted into a serial signal (PS conversion) and sent out.

When shifting from the copy mode to the fax mode, there are the following various cases.

(1) When the operator wants to transmit using fax (a) Switching to fax mode by copy / fax switching lever 317.

A case in which the operator operates the copy / fax switching lever 317, pulls out the fax display panel, and switches the mode.

(B) Switching to fax mode by the copy / fax switch 345.

 In this case, there are the following two cases.

. When the display panel is not attached to the fax display panel 348. In this case, since the settings required for transmission (for example, ordinary characters, lowercase letters, multi-mode, etc.) cannot be made, “Fax no panel” is displayed on the liquid crystal display 304.

. When the display panel is connected to the fax display panel 348. In this case, there is no problem.

At this time, if there is an original on the platen, the original when the automatic document feeder (ADF) is used is ejected, and if there is an original in the pressure plate mode, a warning is displayed. This is due to the following: a. Prevention of incorrect fax due to incorrect operation (If you intend to insert a document, enter a fax phone number, and then start the scanner, the wrong document will be sent). B. In most cases, fax documents are sent using the ADF, so if the original is cut in the platen mode during copying, sending the fax document using the ADF will damage both documents. It is because.

In this embodiment, the detection of the presence or absence of a document is not performed by inputting a CCD, but when the print switch is pressed to perform a press scan for detecting the size of the document. When the print switch is pressed to perform the operation, 3.When the start switch (print switch) is pressed to feed the original during faxing, it is determined that there is an original under the pressure plate at, and the document is positioned under the pressure plate with the ADF lift-up. There is no.

(2) When the fax control board completes reception and prints out.

In this case, since the mode is switched to the fax mode for printing out, when the printing of the fax is completed, the mode is immediately returned to the original mode.

(A) Standby mode (no operation for more than 30 seconds) → fax mode (printout) → standby mode.

(B) Preheating mode → fax mode (printout) → preheating mode.

(C) Main switch off mode → fax mode (printout) → main switch off mode.

Normally, when used as a copy, input mode and display from the operation unit are performed, image data read by the scanner is given to the LD as a signal through the main control board, and
Copying is performed under the control of the CPU. The fax portion at this time has no effect on the copy operation.
However, since fax control (system control, protocol, image processing, etc.) can operate independently, if data is sent from the telephone line, it can be received even during copying, and the received data is stored in the frame memory. I do. The received data is output from the fax control board to the main control board when the copying operation is not performed for a fixed time or more (for 30 seconds or more in this embodiment), and the received data is printed out.

FIG. 29 is a circuit diagram for changing the input of image data from the scanner to the fax interface board when printing out from the fax interface.

This means that the FPRI signal is turned on when a print start signal is sent from the fax interface, and turned off when a print stop signal is received from the sequence control CPU. /
When the operation section is switched to the fax mode by the facsimile switch, the sequence control in the operation section, the scanner section and the plotter section is performed by the facsimile section. The main control CPU at this time is: Setting of fax initial display (operation section) when switching from copy mode to fax mode. Checks for abnormalities in the entire system (serial errors, serviceman calls, etc.), and switches image data input so that printout is performed by putting image data from the fax interface into the main control when receiving faxes. . All the serial data from the operation unit, the scanner unit, and the sequence unit are given to the fax system control CPU through the main control CPU.

As described above, since the main control in the copy mode has nothing to do with the fax control, the copy / fax switching lever 317 and the copy / fax switching switch 345 in the operation unit are removed, and the fax control unit (the eighth control) is removed.
By removing the communication circuit board 90, the receiver 91, the network control unit 108, the modem 117, the fax interface board 118, etc. shown in FIG. 9 and FIG. If a single copy machine is delivered to a user and the user subsequently requests that a fax function be added, simply add the switching lever 317, switching switch 345, and fax control unit to copy and fax. It can be a composite device.

Next, a counter dedicated to fax will be described. When used as a composite device for copying and faxing,
A fax reception counter 89 is provided at the position shown in the figure.

The copy output after receiving the fax is output regardless of the necessity or unnecessary of the user who owns the device. Therefore, if only a copy counter is provided, when the user selects a system (performance charge system) that pays a certain fee for one copy, the number of received faxes is added to the normal number of copies. This causes inconvenience. In particular, when a key counter (including a key card) is used to count the number of copies for each department, if the fax reception counter 89 is not provided, the count will not match for the printout of the fax, resulting in confusion.

For this reason, providing the fax reception counter 89 separately from the total counter 88 eliminates the above-described inconvenience.

As described above, the present invention has the following various features.

(1) In the copying machine / fax composite apparatus, when no operation is performed in the copy mode for a predetermined time, the fax is printed out when the reception of the fax is completed. If no operation is performed during printout, the mode is shifted to the copy mode at the end of printing.

(2) If the reception of the fax is completed during the preheating, the fax mode is set and the printout is performed.
If no operation is performed during the printout, the mode is shifted to the preheating mode at the end of printing.

(3) Even when the key counter (key card or the like) is not set, the mode can be shifted to the fax mode and the printout can be performed. When shifting to the fax mode, the key counter display disappears.

(4) In the apparatus using the sorter, the paper printed in the fax mode is discharged to the interruption tray. The used tray is used at the time of interruption in the copy mode.

If the sorter has two bins, one of the two bins is a copy-only tray and the other is a fax-only tray.

(5) It has a counter in addition to the total counter, and this counter only works as a paper passing counter in fax mode when combined with fax. If the counter is a copying machine alone, it operates as a copy-only counter.

(6) An input mechanism that switches the input pad surface by using a sliding panel to display the keys for fax and copy. A switch mechanism is built in the input mechanism, and copying is performed by switching either the fax / copy switching switch or one of the above panels. And the mode of fax can be changed.

When switching with the switching switch, a warning is displayed if the sliding panel is not in fax. Further, the copy mode is saved when the copy mode is changed to the fax mode, and the saved copy mode is displayed when the copy mode is changed to the fax mode.

(7) When shifting from the copy mode to the fax mode, if there is a document on the platen when using the ADF, the document is discharged. If the ADF is not used, a warning message will be displayed.

You can select the copy mode or fax mode at the time of initialization. If the device is not operated for a certain period of time, the initial mode is set.

(8) Even when the key counter (key card) is not set, the mode can be shifted to the fax mode by the switch or the panel. Further, in the fax mode, the key counter display disappears and transmission becomes possible.

As described above, by appropriately setting the operation mode of the multifunction peripheral, the user can easily operate a complicated multifunction peripheral.

〔effect〕

As described above, the present invention provides a scanner unit that optically reads a document, a storage unit that stores data received via a communication line as storage data, and prints data from the scanner unit or storage data from the storage unit. In a copying apparatus having a printing unit, a determination unit that determines whether the printing unit can print the storage data, and a number of sheets passed when the storage data is printed, Counting means for counting separately from the number of sheets passed when data is printed, and when the determining means determines that the stored data can be printed, the printing section sends data from the scanner section. Automatically switching from a state in which printing can be performed to a state in which the stored data can be printed,
The storage data is printed, and the counting of the number of passed sheets is automatically switched to the counting means for counting.

For this reason, even when a fax is received, there is no inconvenience in counting the paper passing, and a highly reliable copying apparatus can be provided.

[Brief description of the drawings]

1 is a block diagram of a multifunction device according to an embodiment, FIG. 2 is a schematic configuration diagram of a copying machine in the multifunction device, FIG. 4A and 4B are block diagrams of a printer unit, FIG. 5 is a block diagram of an image scanner unit, and FIG. 6 is a block diagram of a fax unit. 7 is a block diagram of the power supply unit, FIG. 8 is a component arrangement view from the front of the multifunction peripheral, FIG. 9 is a component arrangement view from the rear of the multifunction peripheral, and FIG. Supply circuit diagram, Fig. 11 is a DC power supply circuit diagram, Fig. 12 is a flowchart for selecting the mode of fax and copy by key, Fig. 13 is a flowchart of selecting the mode of fax and copy by pad, Fig. 14 is , Copy and fax mode reset float FIG. 15 is a flow chart of a key counter display, FIG. 16 is a flow chart of a counter control, FIG. 17 is a flow chart of a sorter control, and FIG. 18 is a flow of fax reception control in a copy mode. FIG. 19 is a flow chart of the fax reception control during the preheating mode, FIG. 20 is a flow chart after the completion of the fax print, FIG. 21 is a flow chart of the power supply control method, and FIG. 22 is a flow chart of the power control method. FIG. 23 is a plan view of an operation panel when used as a copying machine, FIG. 24 is a plan view of an operation section when used as a multifunction device, and FIG. 25 is a switching lever. FIG. 26 is a cross-sectional view of the display panel switching mechanism showing a state in which is on the copy side, FIG. 26 is a cross-sectional view of the display panel switching mechanism showing a state in the middle of switching, and FIG. FIG. 28 is a control block diagram of the display panel unit, and FIG. 29 is a circuit for changing the input of image data from a scanner to a fax interface board. FIG. 30, FIG. 30 is a flow chart showing a flow of a transmission image signal, FIG. 31 is a flow chart showing a flow of a reception image signal, and FIG. 32 is a signal flow in a fax interface board. It is a block diagram. 81 Power supply unit, 82 Operation unit 87 Door switch 88 Total counter 89 Fax reception counter 90 Communication circuit board 91 Handset 92 Main control board 111 Bin 117 … Modem, 118… Fax interface board 317… Copy / fax switching lever 345… Copy / fax switching switch 347… Copy display panel 348… Fax display panel A… Scanner section, B… Operation section C: Prototype part, D: Fax part SW1: Sub switch SW2: Main switch.

Claims (1)

(57) [Claims] 1. A scanner section for optically reading a document, a storage section for storing data received via a communication line as storage data, and a printing section for printing data from the scanner section or storage data from the storage section. A determination unit for determining whether or not the printing unit can print the storage data, and printing the data from the scanner unit based on the number of sheets passed when printing the storage data. Counting means for counting separately from the number of sheets passed when the determination is made, and when the determination means determines that the stored data can be printed, the printing section prints data from the scanner section. Is automatically switched from a state in which the stored data can be printed to a state in which the stored data can be printed, and the stored data is printed. Copying apparatus characterized by being configured to count automatically switched to several means.