JPS5825254B2 - image recording device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an image recording apparatus that records an image on a long sheet such as a film and develops the image.

In an image recording device such as a processor camera, it is necessary to carry out processing after development while maintaining a substantially constant film feeding speed to prevent processing unevenness from occurring on the film.

On the other hand, recording work is usually performed intermittently, sometimes with quite long interruptions, so the film is sent intermittently from the recording section to the processing section after development. Feeding will be interrupted for a long time.

In order to adjust for the difference in film feeding characteristics between the recording section and the processing section, a storage device is provided between the recording section and the processing section. The film is sent to the processing section.

However, in conventional processor cameras, a vertically movable roller is provided to form a film loop in the storage device, and the film loop is formed by the movement of this roller, which makes the structure complicated and the storage device difficult to store. The disadvantage of this device was that it could not store a large amount of film due to its size.

In addition, it is necessary to load film from the recording section to at least the storage device before starting the recording operation, which makes loading the film troublesome, and furthermore, it is necessary to cut the sheet near the recording section after shooting. If a cutter is installed and the sheet is cut by this cutter, the sheet must be loaded into the storage device again after the sheet is cut and the recording operation is resumed, which is very inconvenient.

The present invention provides an image recording device that solves the above problems.

The present invention will be explained below using specific examples shown in the drawings.

FIG. 1 shows a processor camera to which the present invention is applied, in which 1 is a camera section for photographing an image of a document on film, and 2 is a processor section for performing photographic processing such as development on the photographed film. .

An automatic document feeder 3 is arranged above the camera section 1.
Documents 5 such as checks, bills, stock certificates, and slips are stacked and placed in a container 6.

Reference numeral 7 designates a rotatable lever that sends the original 5 out of the container, 8 a solenoid for supplying the original that drives the lever 7, and 9 a spring coupled to the end of the lever 7.

When the solenoid 8 of the automatic document feeder is turned on, the lever 7 swings against the force of the spring 9, its tip feeds the edge of the lowest document in the container 6, and one document is delivered to the photographing section. 15.

10 is a document detector for detecting the presence or absence of a document in the container 6;
It consists of a microswitch that turns on when a document is present in the container and outputs a "1" signal.

The original 5 sent out of the container 6 is sent to the photographing section (recording section) 1
The photographic material is sent at a constant speed to a photographing position located between two spaced apart glass flat plates 17 and 18 by a pair of feed rollers 16 disposed at 5, and then discharged onto a tray 20 by a pair of discharge rollers 19. Ru.

The upper roller of the pair of feed rollers 16 is supported so as to be able to move vertically, and when an original is sent between the pair of feed rollers 16, the upper roller moves upward depending on the thickness of the original, and this roller The transition is detected by document advance detector 25.

This detector 25 consists of a microswitch, and if the original is
When it is fed between the pair of feed rollers 16, it turns on.
1'' signal and maintains the on state until the trailing edge of the document passes the photographing position.

21 is a slit placed near the photographing position, and 22 is a lamp that illuminates the original.

The rollers 16 and 19 are connected to a drive source (not shown) of the photographing section, and are driven for a certain period of time when the document supply solenoid 9 is turned on, and feed the documents at the same speed.

30 is a projection lens, 31 is a shutter, and 32 is a slit.

When the original 5 passes through the photographing position, it is reduced and projected onto the microfilm F placed at the exposure position 29 by the projection lens 30.

The microfilm F is wound around a supply reel 33, and is fed at a constant speed by a capstan roller 35, a pinch roller 36, and a pair of feed rollers 37 located at the exposure position 29.

The capstan roller 35 and the feed roller 37 are coupled to a drive source (not shown) of the photographing section, and are driven when the document feed detector 25 is turned on, and feed the film at a speed equal to the moving speed of the document image on the surface of the capstan roller 35. to be sent.

Therefore, during photographing, the film in the photographing section is fed in synchronization with the feeding of the document.

38 is a roller that comes into contact with the outer surface of the film wound on the supply reel 33, and 39 is a swingable arm that supports the roller 38. These are used to detect the remaining amount of film wound on the supply reel. , is configured to issue an alarm signal when the amount of film becomes less than a predetermined amount.

45 is a cutter for cutting the film, and is driven by a solenoid (not shown).

Reference numeral 50 denotes a storage chamber in which the film sent from the photographing section is freely stored in a loop shape, and a pair of supply rollers 51 are installed near the entrance of the storage chamber.
, a pair of discharge rollers 52 are arranged near the exit.

The film exposed in the photographing section is fed to a storage chamber by a supply roller 51, and the film stored in the storage chamber is fed to a part of the processor by a discharge roller 52.

A film loop F' is formed in the storage chamber due to the difference in film feeding speed between the supply roller 51 and the discharge roller 52.

The supply roller 51 is connected to the same driving source as the capstan roller 35 and the feed roller 37, and these rollers 35.
The film is fed at the same speed as No. 37.

As shown in FIG. 3, the pair of supply rollers 51 have a diameter larger at the ends than at the center, and the film F is held between the large diameter portions of the supply rollers 51.

The pair of discharge rollers 52 also have the same shape as the supply roller 51.

A film guide member 53 is disposed between the supply roller 51 and the discharge roller 52, and the film guide member 53 has protrusions 53a disposed near the small diameter portions of the rollers 51 and 52 at both ends that engage with the side edges of the film. Vertical wall for movement restriction 5
3b.

This film guide member 53 guides the leading edge of the film from the entrance to the exit of the storage chamber when the leading edge of the film is fed into the entrance of the storage chamber, and also prevents the film from shifting laterally between the rollers 51 and 52. This works to ensure that a film loop is formed.

In FIG. 3, a first pulse generator 55 operates in conjunction with the rotation of the supply roller 51, and generates a pulse every time the roller 51 rotates by a certain angle.

The first pulse generator 55 includes a cam disk 56 fixed to the shaft of the supply roller 51, and a microswitch 57 turned on and off by projections provided at regular intervals on the circumference of the cam disk 560.

A second pulse generator is connected to the discharge roller 52 as well as the supply roller 51, and operates in conjunction with the rotation of the discharge roller 52, generating a pulse every time the roller 52 rotates by a certain angle.

Note that the pulse generator is not limited to the above embodiment, and various known pulse generators can be used.

The first and second pulse generators are configured to generate one pulse when the rollers 51 and 52 each feed the film by the same predetermined length.

FIG. 4 shows the drive mechanism of the discharge roller 52.

The shaft 52a of the discharge roller 52 is drivingly coupled to a first drive shaft 61 via a first electromagnetic clutch 60. Drive shaft 61
is connected to a drive source (motor) of the photographing section that drives the capstan roller 35, the feed roller 37, and the supply roller 51.

Further, a gear 63 is fixed to the shaft 52a, and this gear 63
meshes with gear 64.

The shaft of the gear 64 is drivingly coupled to a second drive shaft 66 via a second electromagnetic clutch 63, and the second drive shaft 66 is coupled to a drive source (motor) of the processor part 2.

When the first electromagnetic clutch 60 is turned on, the shaft 52a and the first.
The drive shaft 61 is disconnected, and the discharge roller 52 is connected to the roller 3.
The film is fed at substantially the same speed as 5,3751.

On the other hand, when the second electromagnetic clutch 65 is turned on, the shaft 52a and the second drive shaft 66 are drivingly coupled, and the ejection roller 52 feeds the film at substantially the same speed as the processor section 2.

When the first and second electromagnetic clutches 60, 65 are respectively off, the discharge roller 52 is not driven and is at rest.

In the above embodiment, the film feeding speed of the rollers 35, 37, and 51 is set to be faster than the film feeding speed of a portion of the processor.

Returning to FIG. 1, 70 is a film detector, which is composed of an infrared lamp and an infrared detection light-receiving element, and is turned on when a film is detected and outputs a "1" signal.

Note that, in this embodiment, a silver salt film, for example, is used as the microfilm.

Since this silver halide film is not sensitive to infrared rays, it is not affected by the infrared rays of the film detector 70.

80 is a developing device, 81 and 82 are washers, and 83 is a dryer.

The film F sent from the camera device 1 to the processor part 2 is fed by the 1 drive roller 84, developed with a developer in a developing device 80, washed with water in water washers 81 and 82, and then heated with hot air in a dryer 83. After being dried, it is discharged onto a tray 86 by a discharge roller 85.

Feed drums 90, 91, and 82 are arranged in each of the liquid tanks of the developing device 80 and the water washing devices 81 and 82, respectively, and the film F is wound around each drum and automatically fed.

As the developer for the developing device 80, a monobath developing and fixing solution is used.

Note that the development process and the fixing process may be performed separately in separate tanks.

1 drive roller 84, discharge roller 85 and feed drum 90
, 91 and 92 are driven by the same driving source (not shown). Each film is fed at the same speed.

95 is a take-up reel used when winding the film without cutting it.

FIG. 6 shows a control circuit of the processor camera.

In the figure, reference numeral 100 denotes a shutter drive circuit, which operates to open the shutter 31 in response to a detection signal when the document feed detector 25 detects a document.

Reference numeral 101 denotes a film 1 drive circuit that drives the drive source of the photographing section. When a drive signal is input, the film 1 drive circuit drives the drive source 1 to drive the capstan roller 35, feed roller 37, and supply roller 51.
rotate synchronously.

Reference numeral 102 designates the second pulse generator described above, which generates pulses in conjunction with the rotation of the discharge roller 52.

105 is a first counter that adds and counts the signal input to the input terminal E and subtracts the signal input to the input terminal E. When the count reaches the first set value, "1" is output from the output terminal A.
” signal is output, and when the second set value is larger than the first set value, a “1” signal is output from output terminal B, and when the third set value is much smaller than the first set value, a “1” signal is output from output terminal C.
1'' signal and is reset when a reset signal is input to the input terminal R.

106 is an alarm such as a buzzer, 107 is a second counter, which outputs a "1" signal from output terminal F when a predetermined count is reached, and is reset when a reset signal is input to input terminal R.

108 is a monomulti circuit, and 109 is a cutter drive circuit, which operates to drive the cutter 45 and cut the film when a drive signal is input.

Reference numeral 110 denotes a solenoid drive circuit, which operates to drive the solenoid 8 and supply the original 5 to the photographing section 15 when a drive signal is input.

Reference numeral 111 indicates a mode selection switch, and the mode of the apparatus is changed by operating this switch.

Reference numeral 115 indicates a document addition switch for selecting whether or not to add a document, and if you wish to add a document when there are no documents in the container 6, you can switch to select adding a document in advance. When the switch is switched in this way, a "1" signal is generated from the switch.

Reference numeral 116 indicates an initial state setting circuit, which operates when the power switch of the device is turned on and resets each circuit.
” signal is output.

A third counter 118 outputs a "1" signal from the output terminal H when a predetermined count is reached, and is reset when a reset signal is input to the input terminal R.

Reference numeral 119 is a monomulti circuit, and reference numeral 120 is a power switch which is manually operated and instructs to start development and turn on/off the power.

Note that the development start command and the power on/off command may be operated using separate switches.

121 is a processor drive circuit which drives one drive source of the processor part 2 when one drive signal is input thereto.

Gl j G2・・・・・・・・・G is AND gate, G20 j2 G21・・・・・・・・・G is OR gate, v
l, F2...7...F6 is the inverter, Fl, F2...
...F6 indicates a flip-flop, S of the flip-flop is a set input terminal, R is a reset input terminal, and Q
is a set output terminal, and Q is a reset output terminal.

Next, the operation of the above-mentioned processor camera will be explained.

First, before starting photography, the microfilm F is passed between the capstan roller 35 and the pinch roller 360, and the film is set in such a state that the leading edge of the film is sandwiched between a pair of feed rollers 37.

It is assumed that the mode selection switch 111 is switched to a mode in which contact a is connected, and the document addition switch 115 is switched to add a document.

Next, when the power switch 120 is turned on by manual operation, power is supplied to the entire apparatus, the lamp 22 is turned on, and the developer is heated.

Furthermore, the flip-flop F6 is set by the ON signal of the power switch, which causes the processor drive circuit 1
A drive source for the processor part 2 is driven via 21.

Further, each counter and each flip-flop are reset by a reset signal from the initial state setting circuit 1116.

After the developing solution reaches a predetermined temperature, when a large number of originals 5 are put into the container 6 of the automatic original feeder, the original detector 10 is turned on, and the on signal of the original detector turns on the antgame.
2 opens, the solenoid 8 is driven via the solenoid and drive circuit 110, and one document 5 is supplied to the photographing section 15.

When the document feed detector 25 in the photographing department detects this document,
The document feed rollers 16 and 19 are driven by the document detection signal from the document feed detector.

Further, the document detection signal from this detector opens the shutter 31 via the shutter drive circuit 100, and the capstan roller 35, feed roller 37, and supply roller 51 rotate via the film drive circuit 101, and the film F is fed.・Ru.

Therefore, the film F is fed in synchronization with the feeding of the original 5,
The image of the original is projected onto the film and exposed.

Furthermore, the flip-flop F1 is set by a signal of document detection from the document feed detector 25.

In addition, the document detection signal of the document feed detector 25 is
It is input to AND gate G1 via gate G2o.

At this time, since there is no film at the film detection position of the film detector 70, the AND gate G1 is opened, and the output signal of this AND gate G causes the first electromagnetic clutch 60 to open.
is turned on, and the discharge roller 52 rotates.

Therefore, like the rollers 35, 37, and 51, the discharge roller 52 rotates in conjunction with the photographing operation of the photographing section.

On the other hand, the drive source of the processor part 2 is driven via the processor drive circuit 121 by the set side output signal of the flip-flop F6, which is set by turning on the power switch 120, and thereby the rollers 84.8 of the processor part
5. The drum 90°91.92 rotates continuously.

The originals 5 are sent to the imaging unit 15 one after another by the automatic original feeder 3.
and are sequentially recorded on film.

As photography progresses, the leading edge of the film sent by the feed roller 37 advances, passes through the cutter 45, is captured by the supply roller 51, is then sent to the storage chamber by the supply roller 51, and is guided by the film guide member 53 in the storage chamber. After traveling along the line, it is caught by the discharge roller 52 and discharged out of the storage chamber by the discharge roller 52.

When the leading edge of the film reaches the film detector 70, the film detector is turned on, and as the film detector is turned on, the output of the inverter V3 becomes "0", so the AND gate G1 is closed and the first electromagnetic clutch 60 is turned off. , and the discharge roller 52 stops.

Therefore, since the supply roller 51 and the discharge roller 52 are driven in conjunction with the photographing operation of the photographing section, the amount of film in the storage chamber 50 is at the lowest limit with the leading edge of the film being captured by the discharge roller. Also, the film located upstream of the discharge roller will not be stretched and damaged, and the film will not be damaged due to slipping between the discharge roller and the film.

Furthermore, since the ejecting roller rotates in conjunction with the photographing operation, the film in the photographing section is not unnecessarily drawn out by the driving force of the ejecting roller.

On the other hand, when the film detector 70 is turned on, the supply roller 5
The AND gate G4 opens every time the first pulse generator 55, which is interlocked with the rotation of the first
The counter 105 adds and counts.

Thereafter, as the shooting progresses, since the discharge roller 52 is stopped, a loop of film is formed in the storage chamber 50, the amount of film in the storage chamber increases, and the count value of the first counter 105 increases accordingly. .

FIG. 5 shows the change in the amount of film in the storage chamber over time, at time t.

indicates the time point when the leading edge of the film is detected by the film detector 70, and time t indicates the time point when the leading edge of the film is detected by the film detector 70.

Thereafter, the amount of film in the storage chamber increases.

The amount of film stored in the storage room at time t1 is the first
When the set amount A' is reached, the output terminal A of the first counter 105
A "1" signal is output from the circuit, and this signal activates the alarm 106 and sets the flip-flop F2.

Therefore, the user is notified by the buzzer of the alarm 106 or the like that a large amount of film is stored in the storage chamber.

By setting flip-flop F2, or gate G2
, the second electromagnetic clutch 65 is turned on, and the discharge roller 52 is drivingly coupled to the drive source of the processor part 2.

Therefore, the discharge roller 52 feeds the film in the storage chamber to the processor part 2 at the same speed as the rollers of the processor part 2.

A pulse is generated from the second pulse generator 102 in conjunction with the rotation of the discharge roller 52.

At this time, since the film detector 70 is in the on state, the second
The pulses from the pulse generator are sent to the first counter 105 through the AND gate G, and are subtracted and counted by the first counter.

The film discharged from the storage chamber is developed, fixed, washed with water, and dried in the processor section 2, and then discharged to the tray 86.

After this, when the shooting operation continues, the amount of film discharged from the storage chamber is smaller than the amount of film supplied to the storage chamber i, so at time t2, the amount of film in the storage chamber becomes less than the first set amount A/. The second set amount B/(If the amount of film in the storage chamber is larger than this, problems such as damage to the film will occur), and the output terminal B of the first counter 105 is
A “1” signal is output from the flip-flop F.
3 is set.

AND gate G2 by setting flip-flop F5
is closed, the solenoid 8 is turned off via the solenoid drive circuit 110, and the feeding of the document 5 is thereby stopped.
Photography work is prohibited.

After this ban on photography, the amount of film in the storage room gradually decreased.
At time t5, when the first set amount A' is reached again, a "1" signal is output from the output terminal A of the first counter 105, and the flip-flop F3 is reset by this signal.
As a result, the AND gate G2 opens, the supply of originals starts again, and the photographing operation is restarted.

Thereafter, the operation between times t1 and t3 is repeated.

When there are no originals in the container 6 at time t4 (original detector 10 is turned off), the rollers 35°i37, 51 stop.

However, since the discharge roller 52 continues to rotate, the amount of film in the storage chamber gradually decreases thereafter.

Then, at time t5, when a document is added to the container 6, the photographing operation is restarted, the amount of film in the storage chamber increases, and from then on,
The same operations as described above are repeated.

However, the additional document must be placed in the container 6 before the amount of film in the storage chamber becomes less than the third set amount C'.

If there is no original to be added after this (or even before restarting the photographing), the original adding switch 115 is switched so as not to add an original.

Then, after the document in the container 6 is exhausted again and the document detector 10 is turned off, at time t7, the amount of film in the storage chamber becomes a third set amount σ(
If the amount of film is less than this, the film will be stretched between the rollers 51 and 52, causing problems such as damage to the film.
1” signal is output, and this signal opens AND gate G7,
Flip-flop F4 is set via OR gate G24.

On the other hand, at time t7, a "0" signal is output from the document addition switch 115, and a "1" signal is output when the document feed detector 25 detects the document sent to the photographing position for the first time. is set and the AND gate G3 is open when the document detector 10 is turned off, so when the flip-flop F4 is set, the AND gate G8 is opened and the OR gate G is opened.
The film drive circuit 101 is operated via the film drive circuit 2o, and the capstan roller 35, feed roller 37, and supply roller 51 are rotated, and the film F in the photographing section is idly fed.

Also, by opening the AND gate G8, the AND gate G11 is opened.
This AND gate G1 is opened every time a pulse from the first pulse generator 55 is input to the second counter 107, and this pulse is counted by the second counter 107.

Immediately after the film is skipped forward and the trailing edge of the final exposure area of the film passes the cutting position of the cutter 45, when the count value of the second counter 107 reaches a predetermined value, a "1" signal is output from its output terminal F. This signal activates the mono multi circuit 108, and the output signal of the mono multi circuit 108 drives the cutter 45 through the cutter drive circuit 109.
is driven and the film is cut.

The exposed areas of the film are thus separated from the unexposed areas of the film, and all relevant original information is recorded on a single piece of film.

The second counter 107 is set to output a "1" signal after the trailing edge of the final photographic area of the film passes the cutting position of the cutter 45.

On the other hand, the output signal of the monomulti circuit 108 opens the OR gate G26 and resets the flip-flop F4.

Therefore, the AND gate G8 is closed, the capstan roller 35, the feed roller 37, and the supply roller 51 are stopped, and the film is no longer idly fed.

The cut film pieces are continuously fed to the processor section 2 by the discharge roller 52, and when the trailing edge of the film pieces, i.e. the cut portion of the film pieces, passes the film detector 70, the film detector 70 is turned off. .

When the detector 70 is turned off, the AND gate G6 opens every time a pulse from the second pulse generator 102 is input to the AND gate G6, and this pulse is counted by the third counter 118.

The cut film piece fed into a part of the processor is fed by a drive roller of the processor part, and when the rear end of this film piece passes the discharge roller 85, the count value of the third counter 118 reaches a predetermined value. , a “1” signal is output from the output terminal H, and this signal causes the mono multi circuit 1
19 is activated, the output signal of the monomulti circuit 119 opens the OR gate G25, and each circuit is set to the state before the start of photographing.

Thereafter, when another unit of original is placed in the container 6, photography is automatically performed in the same manner as described above, and one unit of information is recorded on another piece of film.

The third counter 118 is set to output a "1" signal after the rear end of the cut film passes the discharge roller 85.

Next, a case will be described in which the mode selection switch 111 is connected to the contact point and a mode is selected in which photographing is performed while the photographing operation is interrupted for a long time.

After the start of shooting, storage room 5 is
When the film amount within 0 increases and the film amount reaches the first set amount A', a "1" signal is output from the output terminal A of the first counter 105, and the alarm 106 is activated.
The electromagnetic clutch 65 is not activated and the discharge roller 52 remains stopped.

Therefore, film feeding to a portion of the processor is not performed.

After this, when shooting continues, when the amount of film in the storage chamber reaches the second set value B', a "1" signal is output from the output terminal B of the first counter 105, and this signal stops the supply of originals. and photography is prohibited.

After that, the amount of film in the room remains constant without increasing or decreasing.

Therefore, from the start of photography until the amount of film in the storage chamber reaches the second set amount B', the document can be photographed at arbitrary time intervals, and photography can be performed intermittently at long intervals. Even so, there is no problem.

After that, when the mode selection switch is connected to contact a and a mode is selected in which shooting is performed without interrupting the shooting operation for a long time, as is clear from the above explanation, the amount of film in the storage chamber 50 becomes the first set amount A. ', the discharge roller 52 rotates and the film in the storage chamber is fed to a part of the processor.

The subsequent operations are the same as those described above, so the explanation will be omitted.

Therefore, when you start shooting, if you need to interrupt the shooting process to collect or organize documents, etc., you can operate the mode selection switch to select the mode and continue shooting without any problems. It can be performed.

Next, a case will be described in which the power switch 120 is switched from on to off.

Now, after starting the photographing operation, when the photographed film has not yet been fed into a part of the processor, there is no original in the container 6, and the photographing operation is completed, and when the power switch 120 is turned off, the output of the inverter v6 is turned off. Since it becomes "1",
The AND gate G1o is opened, the No. 2 clutch 65 is turned on, the discharge roller 52 is rotated, and the film in the storage chamber is sent to a part of the processor.

On the other hand, when the AND gate G1o is opened, the flip-flop F4 is set, which opens the AND gate G8, and the film is then cut by a predetermined length in the same way as described above.

When the rear end of the cut film piece passes the discharge roller 85, the power supply to all the devices is cut off, and the power to all the devices is cut off.

Therefore, the switch 120 is used not only as a power supply/stop/command switch but also as a development start command switch.

Incidentally, the film may be fed immediately when the power switch is turned off.

A mechanism for maintaining power supply to the entire device for a certain period of time after the power switch is turned off is known, for example, using a timer that is linked to the power switch and causing the timer to maintain the power supply for a certain period of time.

With the above configuration, when information is recorded on a single film by switching the mode selection switch 111 to connect to the contact, the user operates the switch 120 even if there is a part that has already been recorded. Unless otherwise specified, there is no problem even if the part is interrupted for a long time, and all the information can be stored on a single film of any length.

Therefore, since mutually related information can be recorded on a single film, there is no need for editing later.

Further, it is possible to obtain a film piece of any length on which all information is recorded within the amount of film that can be stored in the storage chamber, and it is possible to record one unit of desired information on the same film.

In the present invention, the long sheet is not limited to microfilm, and various known recording sheets can be used, and the developing method is not limited to the embodiments, and any known developing method can be applied. .

As described above, according to the present invention, a long sheet can be automatically loaded into the storage chamber, and the recording operation can be restarted after hanging the sheet on the rollers in the storage chamber or cutting the sheet as in the conventional case. The work becomes extremely simple as there is no need to reload the sheets into the storage room, and unlike conventional methods, the sheets are exposed to external light every time they are loaded, resulting in wasted sheets. There's nothing left to do.

In addition, the structure of the device is simple and small, and
Since there is no need to provide movable rollers in the storage chamber, a large amount of sheets can be stored.

[Brief explanation of drawings]

FIG. 1 is a configuration diagram of a processor camera to which the present invention is applied;
Figure 2 is a sectional view of the main parts of the storage chamber, Figure 3 is a perspective view of the supply roller and film guide member, Figure 4 is a configuration diagram showing the drive mechanism of the discharge roller, and Figure 5 is a diagram showing the amount of film in the storage chamber. FIG. 6, which shows the changes, is a diagram showing the control circuit of the processor camera. 2...Part of processor, 3...Automatic document feeder, 15...Photographing section, 50...
Storage room, 80...Developer, 81, 82...
...Water, 83...Dryer.

Claims (1)

[Claims] 1. A recording means for recording an image on a long sheet; a sheet storage chamber having a sheet feeding port and a sheet feeding port, and storing sheets sent from the feeding port in a loop shape;
a sheet guide member extending from the sheet feeding port to the feeding port and guiding the sheet sent to the feeding port through the storage chamber to the feeding port; and a sheet guiding member extending from the sheet feeding port to the feeding port; processing means for developing the sheet; and a first processing means for feeding the sheet on which an image has been recorded by the recording means to the feeding port of the storage chamber. a driving roller means, a second driving roller means for feeding sheets in the storage chamber to the processing means, and a sheet cutting means disposed between the first driving roller means and an inlet of the storage chamber. and when the unrecorded sheet is fed to the storage chamber by the rotation of the first drive roller means after the sheet is cut by the sheet cutting means, the leading edge of the unrecorded sheet is guided by the sheet guide member and the sheet is cut by the sheet guide member. An image recording device characterized in that the image recording device is configured to automatically advance to the second drive roller means.