JPS6293133A - Paper sheet drawing-out and receiving device - Google Patents

Abstract

PURPOSE:To prevent paper sheets from handling interruption due to the shortage thereof for improving the efficiency of furnishing funds by providing a vertically movable upper plate body and bottom plate body in a paper sheets receiving box to receive and draw out the paper sheets in cooperation of both plate bodies. CONSTITUTION:An upper plate body 39 and a bottom plate body 38 are vertically movably provided in a paper sheets Yen receiving box. Paper sheets Yen, when received, are counted one by one by taking-in rollers 40, 28 and stacked with the bottom being supported by claws 42, 43 included inward. When the paper sheets Yen on a hopper in an inlet are exhausted, the claws 42, 43 are opened outward by solenoids 16, 17. The upper plate body 39 is lowered to compress the paper sheets Yen and pull inside the claw 42, 43 and the upper plate body 39 is elevated to prepare for the next receipt of paper sheets. In drawing out paper sheets the claws 42, 43 are opened to lower the upper plate body 39 and compress the paper sheets Yen, and the upper sheets Yen and plate bodies 38, 39 are raised to draw out one by one the specified number of paper sheets through drawing-out rollers 14a, 16a. Thus, the shortage of drawing-out paper sheets Yen can be prevented to improve the efficiency of furnishing funds.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a paper sheet storage and feeding device that stores and feeds paper sheets such as banknotes.

[Technical background of the invention and its problems] Automatic transaction devices called ATVs are widely used in banks, etc., and automation and speeding up of counter operations have been achieved. However, recently, banks have adopted a two-day week system, and ATVs cannot be used when banks are closed, resulting in a corresponding decline in service to customers, and measures to improve this situation are being considered. One way to solve this problem is to operate automated corners unmanned. but,
Since conventional ATVs are configured with separate units for deposits and withdrawals, the deposit unit only collects money, while the withdrawal unit only allows money to go out.

For this reason, it is necessary to frequently take out banknotes from the depositing unit and replenish money to the dispensing unit, which is a disadvantage of automation. In order to solve such problems, a circulation type (recycling type) depositing and dispensing device has been developed that circulates and uses deposited bills as disbursed bills.

In this circulating deposit/withdrawal device, a bill storage/dispensing unit that stores bills in the storage section and sends out the stored bills one by one accurately and quickly without jamming is particularly needed for unmanned automation. There is.

[Object of the Invention] An object of the present invention is to provide a paper sheet storage and feeding device that can store paper sheets such as banknotes and reliably feed out the stored paper sheets one by one.

[Summary of the Invention] According to the present invention, there is provided a storage box body for storing paper sheets such as banknotes, a feeding section provided at an upper part of the storage box body and feeding the paper sheets into the storage box body, and a storage box body. an upper plate that is vertically movable on the body; a bottom plate that is vertically movable on the storage box body and on which paper sheets to be introduced are loaded; and the upper plate and the bottom plate are driven. a plate driving unit provided at the top of the storage box body to feed a predetermined number of paper sheets lifted upward by the bottom plate; and a feed-back unit that operates in the opposite direction to the feeding direction of the feeding unit. and a plate drive unit for lowering the upper and bottom plates after the feeding unit finishes feeding out the paper sheets, and feeds the paper sheets following the last sheet to be fed into the storage box body. A paper sheet storage/feeding device is provided, which comprises a control section for controlling a feed-back means for returning paper sheets.

[Embodiment of the Invention According to the ATM shown in FIG. 1, a recycling and deposit/withdrawal device 2 of the present invention is provided inside.

In addition, a passbook handling unit 110, a cash card handling unit 111, a CRT unit 112, and a control/power supply unit 113 are provided.

A passbook is delivered to the passbook handling unit 110 via a passbook exit 110a. Cash card handling unit 1
11, a cash card is entered and taken out via a cash card exit 111a. The CRT display unit 112 displays predetermined guidance on the CRT display 112a.

FIG. 2 shows a block circuit of an ATM and its peripheral devices.According to this, a main control unit 6 composed of a computer is provided, and this main control unit 6 has a control unit 2 for depositing and withdrawing money. It is connected via a deposit/withdrawal device control section 3 that controls the device. Further, an internal monitor 5 is coupled to a main control section 6 via an internal monitor control section 4 . Further, a storage section 7 , a group control device input/output control section 8 , and a transmission control section 9 are connected to the main control section 6 . The group control device input/output control section 8 is coupled to a group recycling self-propelled trolley device 11 via a group control device 10 .

The group recycling self-propelled trolley device 11 has a mobile trolley that can be moved to a plurality of ATVs installed in a bank,
This is a banknote handling device that feeds and replenishes banknotes between ATVs. Such a banknote handling device was developed in a patent application filed in 1986-9.
No. 7815.

The transmission control unit 9 is communicably coupled to a host computer 120 installed at a bank's head office or the like.

According to the deposit/withdrawal device 2 shown in FIG.
2 is provided so that it can be opened and closed in the front and back, and is opened and closed by a motor M1 shown in FIG. A deposit/withdrawal hopper 13 is provided below the deposit/withdrawal port 1112 for storing banknotes to be deposited all at once. At the lower outlet of the hopper 13, a bill taking-in roller 14 is disposed, which is provided with a rubber chip as a braking member on a part of its periphery in order to sequentially feed out the bills one by one. An eccentric rubber roller 15 is provided above the take-in roller 14, and a gate roller 16 that rotates in the opposite direction to the roller 14 is provided on the side.

A backup 17 is provided to press the banknote bundle inserted into the hopper 13 against the take-in roller 14 and the feed roller 15 with a substantially constant pressure by a spring force. That is, the lower part of the backup 17 is attached with a hinge so that it can be opened, and the banknotes are deposited and withdrawn from the hopper 1.
3, it is opened by a magnet to form a banknote introduction port.

Magnetic sensors P4 and P5 for detecting the printed magnetic pattern of one banknote are disposed facing each other inside the banknote inspection unit 18, which is provided approximately in the middle of the deposit/withdrawal device housing. A contact image sensor P6 that optically reads the printed pattern on the surface of the banknote through the banknote, and a thickness detector P7 that detects the thickness of the banknote are provided. Thickness detector P
Reference numeral 7 is constituted by a potentiometer type thickness detector which detects the thickness by the angular displacement of the rotation angle of the arm supporting the detection roller.

The banknote inspection section 18 sends a detection signal to a banknote inspection section control unit 20 disposed below. The banknote inspection unit control unit 20 processes signals output from each sensor of the banknote inspection unit, determines the denomination, authenticity, fitness (determining whether it is suitable for withdrawal), and whether the banknote is front or back. The resulting signal is transferred to the deposit/withdrawal control section 3.

The first gate G1 installed in the banknote conveying path provided around the middle between the banknote validating unit 18 and the banknote validating unit control unit 20 is provided to selectively form a banknote replenishment path and a banknote dispensing path, Driven by rotary solenoid S2. The second gate G2 is provided to switch the conveyance path from the 10,000 yen bill storage box 25 and the 1,000 yen bill storage box 26 to the bulk storage box 27 and vice versa, and is driven by a rotary solenoid S3. The first gate G1 has a banknote sensor P8
It operates in response to signals generated when it passes through.

The second gate G2 is activated after a predetermined delay time has passed since the sensor P8 detects the banknote. That is, the operation timing of the first and second gates G1 and G2 is determined by the sensor P8.

In addition to the first and second gates G1 and G2, various gates, ie, third gate G3 to ninth gate G9, and sensors are provided, and these gates will be explained later. In these gates, gates G5, G6, and G7 require high-speed separation, and are activated at the timing of detecting the leading edge of the bill, and unless the next bill receives a command to move in the opposite direction, it will self-hold and move in the same direction. form a conveyance path for banknotes.

A temporary storage section 23 with front and back matching is provided adjacent to the banknote inspection section 18 . The temporary storage section 23 guides the banknotes to the left and right by the operation of the gate G6, thereby reversing the front and back of the banknotes and aligning all the banknotes to the front side. Beating wheels 28 are provided at the meat entrance of the temporary storage section 23, and these beating wheels 28 have a plurality of flexible protrusions and knock off the rear end of the banknotes being carried in. It has the function of preventing collisions with the leading edge of incoming banknotes and preventing jams. Such jam prevention tapping wheels are provided in all of the stacking sections provided in each section. A vertically movable press plate 29 with an idle row 529a attached is attached to the upper part of the temporary storage section 23, and a vertically movable bottom plate 3 is attached to the bottom surface.
0 is set. The upper press plate 29 and the bottom plate 30 are moved up and down by one DC geared motor M4, and the upper press plate 29 is suspended by a spring against the link of the vertical mechanism so as to absorb the thickness of the stacked banknotes. The bottom plate 30 is formed in a comb-teeth shape, and is in a nested relationship with the conveyor belt so that when the bottom plate 30 is lowered, it passes through the conveyor belt.

A reject ticket stacking section 24 is arranged adjacent to the stacking section 23 . The stacking section 24 is formed by an upper belt 24a and a lower belt 24b, and as described later, the upper belt 24a is vertically rotated by a roller 32, and the lower belt 24b is vertically rotated by a roller 33.

A 10,000 yen bill storage box 25 and a 1,000 yen bill storage box 26 are arranged below the stacking portions 23 and 24. These storage boxes 25
．． The operation of 26 will be described later. The bulk storage unit 2), which is detachably attached to the rear of the deposit/withdrawal device 2, includes a loading/scrutinizing bulk storage box 34, a collection box 35, and rejiku 1 to ticket storage boxes 3.
It is divided into 6 categories.

The electrical connections of various members of the deposit/withdrawal device 2 shown in FIG. 2 are shown in FIG. 3. According to this diagram, a timing detector P3, a magnetic bang (front) detector P4, a magnetic bang (back) detector P5, an optical bang (front) detector P6, and a thickness detector P7 are connected to the banknote inspection section control unit 20. be done. The deposit/withdrawal door opening/closing motor M1 to the transport main motor M12 are connected to a motor driver MD. The deposit/withdrawal backup release switch 81 to the bulk storage box hold claw release switch 817 and the electromagnetic clutch C1 are connected to the magnet driver MGD. The person withdrawal port door fence detection switch SW1 to the bulk storage box set detection switch 5W25 are connected to the switch interface SWI. The deposit/withdrawal port height detection switch 11 to the banknote insertion detection switch P14 from outside the machine are connected to the photo sensor interface PH1.

The banknote inspection section control unit 20 is connected to the deposit/withdrawal device control section 3, and includes a motor driver MT[), a magnet driver MGD, a switch interface SW1. Photo sensor interface PHI is connected to deposit/withdrawal device control section 3 via interface I10.

FIG. 5 shows a mechanical circuit showing the state of conveyance of banknotes when operating the deposit/withdrawal device shown in FIGS. 3 and 4. FIG.

The functions of each member shown in this figure are shown in FIGS. 6(a) and 6(b).

The internal monitor 5 shown in FIG. 7, which is provided on the rear surface of the housing of the deposit/withdrawal device 2, is configured so that it can be operated by an attendant. That is, the internal monitor 5 is provided with a display panel 5a17, a segment display panel 5b1, a keyboard 5C, and a numeric keypad 5d, each including a display panel 5a17, a segment display panel 5b1, a keyboard 5C, and a numeric keypad 5d, each of which includes LEDs corresponding to the status display and call contents. Furthermore,
A power switch 5e and a group circulation/single changeover switch 5'' are provided.A 7-segment display panel 5b is provided.
is a 5-digit display, the code representing the selected transaction type and the machine operation step number are each displayed as a 1-digit number, and when an error occurs in the operation of the machine, an error hood is displayed as a 3-digit number. The keyboard 5C includes keys for inputting various data and processing commands, and for displaying the amount of stored banknotes.

The changeover switch 5r is provided to switch between controlling deposits and withdrawals for a plurality of ATVs as one group or controlling them individually.

FIG. 8 shows the flow of banknotes when depositing money, and this depositing operation will be explained according to the flow shown in FIG. 11. When the button corresponding to the deposit display is pressed in accordance with the guidance on the CRT display 112a, the motor M1 is rotated normally so as to open the cash withdrawal port door 12. When the deposit/withdrawal port fi12 is completely opened, the deposit/withdrawal port door opening switch SW2 is turned on and the motor M1 is stopped.

In this state, when the depositor inserts banknotes into the deposit/withdrawal hopper 13 through the deposit/withdrawal port and then manually closes the deposit/withdrawal 0 door 12, the switch SW1 detects the closing of the deposit/withdrawal port door 12. turns on. Then, the photosensor P2 that detects whether a banknote is inserted is in the banknote inserted state, that is,
Detects dark conditions. Next, it is determined whether the photosensor P1, which detects the height of banknotes at the deposit/withdrawal port, detects darkness. This photosensor P1 is provided to detect whether the banknotes are inserted in the correct position, and is arranged at a position slightly higher than the width of the banknotes and lower than the length of the banknotes. When the banknotes are inserted vertically, the photo sensor P1 detects darkness, that is, it detects that the banknotes have been inserted in the wrong direction.
is displayed on the CRT display 112a. At this time, the cash withdrawal port door 12 is opened again to enable the re-insertion of banknotes. If the banknotes are correctly inserted, the motor M2 that drives the backup 17 of the deposit/withdrawal port hopper 13 rotates normally. When the motor M2 is rotating normally, the one-way clutch connected to the motor M2 is in a released state, and in this state, the banknotes continue to be pressed toward the feed roller by the spring force. At this time, when the main motor M12 that drives the main transport path is rotated, the main transport path starts to move at a low speed. When the electromagnetic clutch C1 is energized and the main conveyance path enters a high-speed conveyance state,
The motor M3, which starts taking in banknotes, rotates normally. As the motor M3 rotates, the intake roller 14 and the rubber roller 1
5 and the gate row 516 rotate, and the banknotes ¥ are fed into the main conveyance path one by one. When each banknote ¥ enters the banknote inspection section 18, the banknote inspection section 18 determines the denomination, authenticity, and front and back sides of the banknote ¥ by a well-known method. The banknote ¥ passed through the banknote inspection unit 18 is guided downward by the first gate G1, and further transferred upward by the roller, and then passed through the gates G2 and G.
3 and G4 to enter gate G5. As a result of the inspection by the banknote inspection section 18, when it is determined that the incoming banknote ¥ is a genuine bill, the amount of the banknote ¥ is sequentially added to the transaction deposit memory, and the gate G5 is switched to the temporary storage section 23 side.

This switching is performed by actuating the rotary solenoid S6, which is actuated at a predetermined time delay from the time when the leading edge of the banknote is detected by the photosensor P9. When the front and back judgment of the banknote ¥ led to the temporary storage section 23 is heads, the gate G6 is tilted to the right and the banknote ¥
is led to the path on the left. If the judgment is wrong,
Gate G6 is pushed to the left, and the banknotes go through the passage on the right.
guided by. Note that the gates 1-G6 are driven by a solenoid S7, and this solenoid S7 is driven by a photo sensor P.
From the time when the tip of the banknote is detected by 9, the solenoid S
It is operated with a delay time somewhat longer than the delay of 6. Gate G
The banknotes ¥ passed through 6 are stored in the temporary storage section 23.

As a result of the inspection by the bill inspection section 18, if the incoming bill ¥ is not a genuine bill, the gate G5 is switched to the reject side. This switching is performed by deenergizing the rotary solenoid S6, and the 0-tally solenoid S6 is deenergized at a predetermined time delay from the time when the leading edge of the banknote is detected by the photosensor P9.

The banknotes guided to the reject side are accumulated in the deposit reject accumulation section 24.

As described above, the banknotes are distributed to the temporary storage section 23 or the deposit reject accumulation section 24, and the deposit/withdrawal port hopper 1
When the last banknote of ¥3 is sent out, the photo sensor P2 detects a "bright" state, that is, there is no remaining banknote, and the motor M2 is reversed so that the backup 17 of the deposit/withdrawal port hopper 13 is raised. At this time, if the final bill fed into the banknote inspection section 18 is determined to be a rejected bill, the gate G4 is rotated upward at the time when this final rejected bill reaches the gate G4, and the rejected bill is sent to the bill inspection section 18. A guiding bypass path is formed between the banknote inspection section 18 and the temporary storage section 23. Therefore, the final pasted ticket passes through the bypass path and is inspected again by the banknote inspection section 18. If the final pasted banknote is a misjudgment by the banknote inspection section 18, it will be judged to be a genuine note by inspection again, and in this case, the gate G4 will be returned to its original position and stored in the temporary storage section 23. By forming the bypass path in this manner, the inspection speed becomes faster than when the final pasted reject ticket is inspected again via the deposit reject accumulation section 24 and the deposit/withdrawal port hopper 13, and the speed of banknote discrimination can be increased.

When the backup 17 activated by the reverse rotation of the motor M2 reaches the upper stop position, the detection switch SW3 detects this. Motor M2 is stopped in response to this detection.

When a detection switch (photo interrupter) SW4 that detects the stop position of the pulse motor that drives the take-in roller 14 detects the stop position, the banknote take-in motor M3 is stopped. At this time, the N magnetic latch C1 is turned off, and the main motor M12 is stopped in order to further stop the main transport path.

Thereafter, it is checked whether there are any rejected tickets, and if there are no rejected tickets, the number of bills for each denomination is stored in the transaction deposit memories a1b, c. The CRT display 112a displays ``The deposit amount is 00 yen.'' If it is correct, press "○", if it is incorrect, press "x"" will be displayed.r
When the OJ button is pressed, banknotes of ¥ are sent out from the temporary deposit storage section 23 to the deposit/withdrawal port hopper 13 in a batch. The operation of the temporary storage section 23 at this time will be explained with reference to FIG.

FIG. 9(a) shows a state in which the banknote bundle is stored in the storage box, and the upper press plate 29 is lowered from this state. When the upper press plate 29 presses the banknote bundle against the bottom plate 30, the bottom plate 30 descends. Since the bottom plate 30 is in a nested relationship with the conveyor belt, the bottom plate 30 passes through the conveyor belt and moves to a position below the conveyor belt. At this time, the front side plate 31 of the bottom plate 30 rotates and falls forward to form a carry-in path. The upper press plate 29 stops halfway depending on the thickness of the banknote bundle due to spring force. As the banknotes are pressed against the conveyor belt and carried out, the upper press plate 29 descends to press the banknotes against the conveyor belt. Upper press plate 29
reaches the lower stop position and the detection switch SW6 is turned on,
As shown in the flowchart of FIG. 11(d), motor M4 is stopped. Here, solenoid S8 is turned on to open gate G10.

Next, the motor M5 is rotated normally in order to lower the upper belt of the deposit reject accumulation section 24. That is, motor M5
As a result of normal rotation of the roller 32, the roller 32 descends from the position shown in FIG. 10(a) to the position shown in FIG. 10(b). As a result, the upper belt moves to the lower belt while pressing the banknote bundle in the stacking section. When the upper and lower belts of the deposit reject accumulation section reach the lower stop position, the detection switch SW9 is turned on and the motor M5 is stopped. At this time, a return path (passage) to the deposit/withdrawal port is formed by the upper and lower belts. Furthermore, Figure 10 (C)
As shown in , the roller 33 rises and the lower belt moves up and down so as to push up the upper belt.

When this stops at the upper stop position, a conveyance path to the back side is formed.

When the solenoid S1 is energized, the backup 11 of the deposit/withdrawal port hopper 13 is rotated, and the backup 17 is opened so that an entrance conveyance path to the deposit/withdrawal port hopper 13 is formed. At this time, in order to drive the main conveyance path at low speed, the main motor M2 is turned on while the clutch c1 is turned off. This is to transport banknotes in bundles, and the transport speed is 1/10 of the speed when transporting banknotes one by one.
will be lowered to FIG. 13 shows the conveyance route for this bundle of banknotes. Photo sensor P10 during conveyance of banknote bundle
detects the remaining banknotes in the temporary deposit storage section 23, and when there are no remaining banknotes, a timer is set in response to the detection output of the photosensor P10, and the motor M12 is stopped after the set time of the timer has elapsed.

After the motor M12 is stopped, the solenoid S1 is turned off as shown in the flowchart of FIG. 11(e), and the tip of the deposit/withdrawal lock-up 17 is returned to its original position. Further, solenoid S8 is turned off and gate G10 is closed. Furthermore, the motor M5 is reversed so that the upper belt of the deposit reject accumulating section 24 returns to its original position, and switch SW8 is turned on during the return operation of the deposit reject accumulating section 24.
Motor M5 is then stopped. At this time, a reject ticket accumulation space is formed between the upper and lower belts.

On the other hand, the upper press plate 29 and the bottom plate 30 of the temporary storage section 23
Motor M4 is reversed to raise to the initial position. When the upper press plate 29 and the bottom plate 30 reach the upper stop position, the photo interrupter SW4 is turned on, and the motor M5 is turned on.
will be stopped. After this, the operation of discriminating the disbursed banknotes is performed according to the route shown in FIG. 14, but before that, as shown in FIG.
Returning to the flow above, the operation when a rejected ticket exists will be explained.

If there is a rejected ticket, it is determined whether the number of times it is used is three times or less. In this limited number of times judgment, if a rejected ticket exists, the rejected ticket is inspected repeatedly, and the limit is three times. If the number of times is less than the limit of 3, the message "Please reinsert the banknote correctly" is displayed and the operation follows the flow shown in FIG. 11(h).

That is, solenoid S8 is energized and gate G10 is opened. The motor M5 is rotated forward, and the deposit reject accumulation section 2
4 upper belt 24a is lowered. Upper belt 24a
When reaches the lower stop position, photo interrupter SW9 turns O.
N, and motor M5 stops. The solenoid S1 is turned on so that the tip of the backup 17 is bent to form a bill receiving space. In this state, the rejected ticket can be transported. By driving the main motor M2, the rejected ticket is returned to the deposit/withdrawal port hopper 13 at low speed. At this time, a timer is set,
Motor M12 is stopped after a predetermined time.

At this time, the timer functions in place of a bill remaining sensor for the deposit reject accumulation section 24.

Solenoid S1 turns OFF when the return of the register banknote is completed.
The backup 17 is restored to its original state.

Furthermore, solenoid S8 is turned off and gate G10 is closed. In the flow of Fig. 11(i), motor M
5 is reversed. This is a drive for raising the upper belt 24a of the deposit reject accumulation section 24 to re-form the accumulation space. When the upper belt 24a reaches the middle stop position, the photointerrupter SW8 is turned on, and in response, the motor M5 is stopped. After this, Figure 11 (a
Returning to the flow shown in ), the return banknotes are re-inserted by the depositor by opening the cash withdrawal port door 12, and the banknotes are inspected again according to the same flow. This banknote re-examination is limited to 3 times.
When the number of times is exceeded, as shown in the flow of Fig. 11 (C)
``I will return the unreadable ticket.'' is displayed, and the pre-processing for discriminating the disbursed banknotes described above is executed. This pre-processing is completed by stopping the motor M4 in the flow shown in FIG. 11(e).

Next, a dispensing banknote discrimination process is performed. First, it is determined whether the rOJ button has been pressed. If this determination is YES, the electromagnetic clutch C1 is turned on, and the main motor M12 is turned on to drive the main conveyance path at high speed. is driven. At this time, the motor 2 is rotated normally in order to push down the backup 17 of the deposit/withdrawal port hopper 13. Banknotes ¥ is a backup 1
7, it is pressed against the take-in roller 15. The motor M3 that rotates the take-in roller 15 is driven to rotate in the forward direction, so that banknotes ¥ are sent out one by one to the main conveyance path.

As shown in FIG. 14, this banknote is conveyed to the banknote inspection section 18 by the main conveyance path, and the denomination and fitness are determined. This banknote inspection determines whether the banknote is suitable for withdrawal, and in this determination, banknotes that have been repaired with adhesive tape or the like, and banknotes that are stained or damaged are treated as unsuitable for withdrawal. When 1,000 yen bills suitable for withdrawal are sequentially sent in this judgment as to whether the withdrawal is appropriate or inappropriate, 1,000 yen is sequentially added to the stored amount memory O corresponding to the 1,000 yen storage box 26. At this time, the gate G1 is rotated to the right so that the banknotes are transported to the storage box 26. This gate G
The rotational drive of No. 1 is performed by turning on the solenoid S2. When the 1,000 yen bill is conveyed to the 1,000 yen storage box 26 via the conveyance path and the photo sensor P12 detects passage of the 1,000 yen bill, the solenoid S12 is turned OFF, the gate G8 is rotated to the left, and the passage to the 1,000 yen storage box 26 is carried out. is formed. Therefore, the 1,000 yen bills are sequentially stored in the 1,000 yen bill storage box 26.

If the transported bill is a 10,000 yen bill instead of a 1,000 yen bill, 10,000 yen is sequentially added to the storage amount memory P corresponding to the 10,000 yen bill storage box 25. - The 10,000 yen bill is conveyed to the 10,000 yen storage box 25 via the gate G1. At this time, photosensor P1
1 When the passage of a 10,000 yen bill is detected, solenoid S9 turns O.
N is turned, gate G7 is rotated to the left, and 10,000 yen storage box 2 is opened.
5 is formed. Therefore, -10,000 yen bills are sequentially stored in the 10,000 yen bill storage box 25.

If there are 5 unsuitable withdrawal tickets, the transaction deposit memory a,
The value obtained by subtracting the total number of stored 1,000 yen bills and the number of stored - 10,000 yen bills from the total number of banknotes stored in b and c is added to Q. Next, solenoid S2 is turned off and gate G1 is rotated to the left. Furthermore, solenoid S3
is turned ON, and gate G2 is rotated to the left. As a result, the banknotes that are inappropriate for withdrawal are guided to the reject storage box 3G by the gates Gl and G2 and stored there.

As described above, all the banknotes in the deposit/withdrawal port hopper 13 are sorted into the storage boxes 25, 26, 36, and when the photo sensor P2 detects that there are no bills remaining, the motor is activated to raise the backup 17 of the deposit/withdrawal port hopper 13. M2 rotates in the opposite direction. When the backup 11 reaches the upper stop position, the proximity switch SW3 is turned ON and the motor M2 is stopped. At this time, when the photosensor SW4 is OFF, that is, the motor M3 is stopped when the motor stop position for receiving and sending money to the deposit/withdrawal port is detected.

Subsequently, the main transport path motor M12 is stopped.

At the time of re-fetching, it is determined whether or not there is a rejected bill. If NO, the process moves to the storage operation; if YES, the total number of bills stored in transaction deposit memories a, b, and c is calculated by 1,000,000. The value obtained by subtracting the total number of stored yen bills and the number of stored -10,000 yen bills is added to Q, and then the storage operation is started. The storage operation is performed according to the flow shown in FIG. 12, and this storage operation will be described later. When the storage operation is completed, the values in the transaction memories a, b, and c are added to the values in the current high memories R, S, and T of the deposit/withdrawal device, and are stored. The values of the transaction memories a, b, and c are added to the values of the accumulated deposit memories A, B, and C, and are stored in the memories A, B, and C, respectively. memory a
, b, and c are cleared, thereby ending the deposit and withdrawal banknote discrimination processing.

Next, the storage operation will be explained according to the subroutine shown in FIG. 12, but before that, the configurations of the 1,000 yen bill storage box 26 and the -10,000 yen hole storage box 25 will be explained. However, the structure of the thousand yen bill storage box 26 and the million yen hole storage box 25 is exactly the same as that of the bulk storage box 34 of the bulk storage section 27 shown in FIGS. 16 and 17. The structure of the storage box will be explained based on the following.

A take-in roller 15a and a feed-in roller 16a are provided at the top of the storage box 34. These rollers 14a and 15a are connected by an intermediate gear, rotate one-to-one, and take in or feed one bill per rotation. The rollers 14a and 15a are removably connected to a motor M1 through a swivel coupling and are driven by this motor M10. An elastic belt 4 is coaxially connected to the take-in roller 14a.
1 and an idle roller 54 are installed, and these can freely rotate independently of the take-in roller 14a. The entrance side idle roller 40 is connected to the intake shaft idle roller 54 via a telescopic belt 41, and both are rotated by the travel of the telescopic belt 41 receiving power from the main conveyance path belt. Three rows of beating wheels 28a are provided facing the idle roller 40 on the entrance side. These beating wheels 28a have the same function as the beating wheels 28 of the temporary storage section 23. A horizontally provided back-up plate 38 is supported by a guide rod 48 via a linear ball bearing so as to be vertically movable. Further, the back-up plate 38 is always urged upward by a spring 46. Furthermore, the back-up plate 38 is connected to a drive belt 49, and is connected to a DC motor M11 with a gear reduction gear by a detachable coupling to a pulley 55 with a one-way clutch. When motor M11 is rotated counterclockwise in FIG. 16, the one-way clutch is locked and pulley 5
5 and a belt 49, the back-up plate 38 is lowered against the spring 46.

When the motor M11 rotates clockwise, the one-way clutch slips, and the back-up plate 38 is urged upward by the tensile force of the spring 46, but when the motor M11 is stopped, the self-locking mechanism of the gear reducer forces the one-way clutch upward. The tensile force of the spring 46 causes the back-up plate 38 to
cannot rise and has stopped.

The back-up plate 38 has a micro switch 5 for empty detection.
W2) is attached, and the push-in plate 39 has an escape hole that corresponds in position to the actuator of the microswitch 5W2). Therefore, if there are no banknotes when the back-up plate 38 is raised to the uppermost position, the actuator in the escape hole can detect the crowd and the absence of banknotes.

Push-in plate 3 installed horizontally to correspond to the back-up plate
9 is supported by a guide roller 48 via another linear ball bearing independently of the back-up plate 38 so as to be vertically movable. In addition, the push-in plate 39 is the back-up plate 3.
8 is constantly urged upward by a separate spring 47, and furthermore, a drive belt 50 is connected to the DC motor M11 with a gear reducer via a pulley 56 with a one-way clutch and a removable camp ring. combined.

The operation of the push-in plate 39 is exactly the same as that of the back-up plate 38; when the motor M11 rotates clockwise, the one-way clutch slips, and when the motor M11 rotates counterclockwise, the one-way clutch is locked.

Therefore, when the DC motor M11 rotates counterclockwise, the push plate 39 and the back-up plate 38 descend at the same speed while maintaining the same distance. On the other hand, when the motor M11 rotates clockwise, the back-up plate 38 and the push-in plate 39 are unlocked so as to rise within the range of the circumferential speed of the pulleys 55, 56.

At this time, depending on the load conditions, the back-up plate 38 and the push-in plate 39 can stop, slowly rise, or perform different operations.

The hold claws 42 and 43 are supported by magnets 816 and S17 and return springs 44 and 45, respectively. In FIG. 15, the arm tip of the left holding claw 42 is in contact with the rotating shaft of the beating wheel 28a.

Therefore, when the solenoid S16 attracts the holding claw 42, the striking wheel 28a simultaneously rotates to the left and escapes. In this escape position, the beating wheel 28a does not receive rotational driving force from the external conveyance path, so the beating wheel 28a does not rotate.

Even when the intake pulse motor MIO is stopped, if the main conveyance path is driven, the telescopic belt 41, the entrance side idle roller 40, and the intake shaft idle roller 54 are connected via the belt gear.
, the beating wheel 28a, the reversing roller 16a1, and the feeding roller 57 rotate, so that the banknotes can be conveyed. If the rubber chip of the take-in roller 14a is on the conveyance path during banknote conveyance at this time, there is a risk that it will become an obstacle. Therefore, in order to take in the first bill without skipping when taking out a bill, the rubber chip of the take-in roller 14a is necessary. It is necessary to always correctly stop the stop position between the conveyance path and the intake surface. For this purpose, a switch 5W20 is provided, which detects the stop position from the notch position of the notch disk attached to the intake shaft, and detects the stop position of the motor M.
stop ho.

By configuring the storage box as shown in L, there are the following advantages. That is, since the two upper and lower plates can be moved up and down at any interval during one Tanabata festival, it is possible to accommodate the amount of banknotes stored. At the time of loading, the stacking height is mechanically set by the holding claw so that up to 100 bills can be stacked, so the stacking can be done without being affected by the already stacked banknote bundle. Since the banknotes are moved downward, even if the stacking is slightly disordered, the banknotes can be aligned and pushed in.The fixed force of the spring raises the banknotes and presses them against the holding claws, so when stacking the banknotes, the stacked banknotes will be loose and fluffy. Even if this happens, the banknote bundle is pressed against the banknotes in a single storage operation, so a large amount of banknotes can be stored in a narrow space.

Next, the storage operation of the storage boxes 25, 26, and 34 will be commonly explained according to the flow shown in FIG. 12 and the steps shown in FIG. 15.

In FIG. 15(a), when taking in banknotes, solenoids 810, S11, 813, 814, S16, S17
has not been turned off, and the hold claws 42 and 43 have entered the storage box. In this state (4), the bundle of banknotes already stored is regulated by the hold claw 12.43. Also, the hold claw 42.43 and the stored banknote form a bottom for the M banknotes to be newly taken in. The distance to the bottom is set to a value that is optimal for stacking up to 100 banknotes and prevents the banknotes from standing up or turning over. The distance is set so that the banknotes do not become jammed in the upright position.Therefore, the banknotes taken in are entered diagonally and stacked one after another as shown in FIG. 15<a). All banknotes that can be withdrawn from the deposit/withdrawal hopper 13 are held by the hold claw 42.4
If it piles up on top of 3, the capture will stop. At this time, the motors M7, M9, and Mll rotate normally (rotate counterclockwise in the figure), and the back-up plate 38 and push-in plate 39 descend, but since the one-way clutch is locked, the back-up plate 38 and push-in plate 39 Both descend at circumferential speed.

Solenoid S10.811 after a predetermined time by a timer
．． 313, 314, 816, and Si7 are turned on, and the hold claws 42, 43 are opened (FIG. 15b). When the back-up plate 38 support push-in root 29 is lowered to the push-in position c'J3'5i;a shown in FIG. 15(C), the switch S
W14, SW'l 9.5W24 is ON〉2 At this time, motor M7. M9, Mll are stopped, and solenoids Sl 0,811, Sl 3, S14, S16 .
817 is turned off and the holding claws 42, 43 enter the storage box again (FIG. 15d).

After this, motors M7, M9, Mll reverse, ie, rotate clockwise in the figure. In the reverse rotation, the one-way clutch becomes free, so the back-up plate 38 and the push-in plate 39 are raised separately by the spring force. The push-in plate 39 is constructed in a nested relationship with the Honild claws 42, 43, so that the holding claws 42). 13. However, the upper part of the banknote bundle placed on the back-up plate 38 collides with the holding pawl, and the back-up plate 38 stops. At this time, the banknotes are pressed together by the lifting force of the back-up plate 38 and packed together. That is, since the banknotes taken into the storage box are packed together, more banknotes can be stored in a small space.

When the push plate 39 reaches the infeed ticket guide position, switch yf.
sW1.3, 5W18, SW 23 are ON ”Fj
,6.

In response to turning on this switch, motors M7 and M are used to stop the lifting of the backup plate 38 and the push-in plate 39.
9. Ml 1 is stopped and the storage operation is completed.

If "○" is not pressed in the flow of FIG. 11(e), the process moves to the flow of FIG. 11(j). That is, in order to open the deposit/withdrawal 0 door 12, the motor M1 is rotated normally. When the cash withdrawal port door 12 reaches the open stop position, the switch SW
2 is ONL, motor M1 stops. Here, when the depositor removes the banknotes from the deposit/withdrawal bank 13 and there are no remaining banknotes, the photo sensor P2 turns ONL and the motor M
1 is reversed and the cash withdrawal port door 12 is closed. Deposit/withdrawal port fi
! 12 reaches the closed position, switch SW1 turns ONb,
Motor M1 stops. This will bring you to the initial state,
The following deposit operations are possible.

Next, withdrawal will be explained with reference to the flows shown in FIGS. 18 and 19. When the button corresponding to the deposit is pressed according to the guidance on the CRT display 112a and the withdrawal amount is keyed in, the main motor M12 that drives the main conveyance path is rotated in the normal direction.

Due to the forward rotation of only the main motor M12, the main conveyance path begins to run at a low speed. When the electromagnetic clutch C1 is turned on, the main conveyance path rotates at high speed. If the withdrawal is specified as a 10,000 yen bill or a 1,000 yen bill, the 10,000 yen bill storage box 25 is selected first, and -
The operation of dispensing money from the 1,000-yen hole is started, and then the 1,000-yen bill storage box 26 is selected, and the operation of dispensing 1,000-yen bills is started. If the withdrawal is specified as a 1,000 yen bill, the 1,000 yen bill storage box 26 is selected from the beginning,
The operation of dispensing 1,000 yen bills begins.

The withdrawal operation operates according to the flow shown in Figure 20.
) As shown in Figure (a), the motor M7 (M9) is rotated forward in order to lower the back-up plate 38 and the push-in plate 39 slightly. This is to release the stored banknotes from being pressed against the holding claws 42, 43 by the pushing up force of the back-up plate 38, and to make it easier to remove the hold claws from the stored banknote bundle. This descending layer is set by a timer, and when this timer time elapses, motor M7 (M9)
is stopped and solenoid 5IO1811 (813,51
4) is turned on, and the hold claws 42 and 43 are opened.

In this state, the motor M7 (M9) is reversely rotated, and the back-up plate 38 and push-in plate 39 are raised. When the banknotes are raised to a predetermined position, a timer is activated, and motors M6 (M8) rotate normally to start taking in and feeding out banknotes. The forward rotation of the motor M6 (M8) causes the take-in roller 14a to rotate and feed out the banknotes one by one.

At this time, the photosensor P11 (P12) detects the passage of banknotes, and the number of bills passed is counted based on the detection signal. The banknotes dispensed from the storage box 2526 are conveyed to the banknote inspection section 18 by the main conveyance path.

The transported banknotes are inspected by the banknote inspection section 18 for denomination, authenticity, and stacking. If it is determined through these inspections that the bill to be dispensed is a genuine bill, the gate G2 is moved to the right and the solenoid S3 is turned off to form a passage to the temporary storage section 23.
be made into If the bill is not a valid bill, the solenoid S3 is energized so that the gate G2 moves to the left in order to guide the bill to the reject storage box 36 as a reject ticket. This gate switching timing is determined by the detection of bill passage by the photosensor P8. When a valid bill is detected by the photosensor P9, the rotary solenoid S6 is biased to rotate to the left in order to switch the gate G5 to the temporary storage section side. Furthermore, the gate G6 is switched to the right by spring force and the left passage (
The rotary solenoid S7 is deenergized to form a bus). In this state, banknotes are sequentially stored in the temporary storage section 23. When the number of banknotes sent out from the storage box reaches the specified number, it is checked whether or not there is a direct ticket.

If there is a rejected ticket, the number of rejected tickets is added to the designated number, and the process returns to the flow of counting the number of dispensed tickets shown in FIG. 20(a). If there is no rejected ticket, the photo sensor swi detects the stop position of the intake motor.

It is checked whether (SW15) has detected the stop position (dark detection). If YES, the intake motor M6 (M8) is stopped. In this state, the designated number of banknotes has been fed out from the storage box, but at the end of this banknote feeding, after the last banknote has been fed out,
The next banknote is slightly fed out by the take-in roller 14a,
A situation occurs in which the leading edge of the banknote protrudes between the take-in roller 14a and the reversing gate row 516a. When this gradual withdrawal occurs, the gradually dispensed banknotes will not return correctly, causing a malfunction in the next withdrawal. Therefore, in order to eliminate this uneven delivery, the back-up plate 38 is lowered while the conveyor belt continues to run even if the take-in motor M6 (M8) is stopped after a predetermined number of banknotes have been sent out. As a result, when the banknote bundle becomes loose, the reversing roller 16a
The issued banknotes are pulled back into the storage box. To eliminate this unevenness, the back-up plate 38 and the push-in plate 39 start to descend simultaneously, but since the push-in plate 39 is retracted by an amount α from the take-in roller surface, when the back-up plate 38 is lowered by α, this α The bill bundle is loosened by that amount, and by taking advantage of this loosening, the gradual coming out is eliminated, and by lowering the push plate 39, the gradually coming out bills, that is, the uppermost banknotes are returned to the normal position.

The forward rotation of the motor M7 (M9) lowers the back-up plate 38 and the push-in plate 39 as shown in FIG.
9) turns on. Motor M7 responds to the push position detection.
(M9) is stopped, and the lowering of the backup plate 38 and the push-in plate 39 is stopped.

At this time, solenoid 51o1S11 (S13.514
) is turned OFF, and the hold claw is returned to the storage box (e). Again, the motor M7 (M9) is reversed, and the back-up plate 38 and push-in plate 39 are raised (f). When the stored banknote hits the holding pawl, the back-up board 38 stops. The push-up plate 39 reaches the guide position. When it rises, the switch 5W13 (SW18) is turned on.As a result, the motor M7 (M9) that drives the back-up plate 38 and the push-in plate 39 to rise stops, and the dispensing operation is completed.

According to the above-mentioned withdrawal operation, the holding claw is retracted from the stored ticket after the bank-up board 38 lowers the back-up board 38 slightly to reduce the pressure between the bills, so that the banknote is not damaged. The magnetic force of the solenoid required for retracting the holding claw can be reduced. In addition, if the motor Mli continues to rotate clockwise during the withdrawal process, the back-up plate will gradually rise due to the force of the pressing spring 46 as banknotes are received, eliminating the need for pressure detection or complicated control. Stable capture is possible even when Furthermore, even though the rotation of only the take-in roller is stopped, the bill continues to travel on the conveyance path and the reversing roller continues to rotate, and the bill that is being pressed becomes loose, and then the pushing plate pulls the bill downward. By pushing down, the protrusion is corrected and stored. Furthermore, since the push-in plate is lowered below the holder claw and then returned to its original position, a space for accumulating the next deposited banknote can be reliably created.

When the dispensing operation is completed, the electromagnetic clutch c1 is turned off, the main motor M12 is further stopped, and the main conveyance path is accordingly stopped. Thereafter, as shown in the flowchart of FIG. 19(b), the motor M4 is rotated forward, and the bottom plate 3o of the temporary storage section 23 is lowered below the conveyor belt, and the upper press plate 29 is also lowered. When the bottom plate 30 and the upper press plate 29 are lowered to the lower stop position, the switch SW6 is turned on and the motor M4 is stopped. At this time, solenoid S8
is turned on, and gate G10 is opened. Motor M5
is rotated in the forward direction, and the upper belt 2 of the deposit reject accumulation section 24
4a descends. When the upper belt 24a reaches the lower stop position and the detection switch SW9 is turned on, the motor M5 stops. The solenoid S1 is turned on, and the tip of the deposit/withdrawal robust up 17 rotates to be in the open state. In this state, when the motor M12 is driven and the main conveyance path runs at a low speed, the banknote bundles in the temporary storage section 23 are conveyed all at once and enter the deposit/withdrawal port hopper 13 via the deposit reject accumulation section 24. The conveyance process at this time is shown in FIGS. 9 and 10.

When the food sensor P10 for detecting residual banknotes in the temporary storage section detects a bright state, that is, there is no residual banknote, the motor M12 is stopped after a set time of the timer from the detection, and the traveling of the main conveyance path is accordingly stopped. Thereafter, the solenoid S1 is turned off to restore the backup 17, and the solenoid S8 is further turned off to close the gate G10. In addition, the upper belt 2 of the deposit reject accumulation section 24
Motor M5 is reversed to return 4a to its original position.

When the first belt 24a reaches the return position and the switch SW8 is turned on, the motor M5 stops. Similarly, the motor M4 is reversed in order to raise the bottom plate 30 of the temporary storage section 23 together with the upper press plate 29 to the return position.

When the bottom plate 30 and the upper press plate 29 are detected by the lower stop position detection switch SW5, the motor M5 is stopped.

Thereafter, the process returns to the flow shown in FIG. 11(j), and the withdrawal person can now take out banknotes from the deposit/withdrawal hopper 13, and the process returns to the initial state.

FIG. 22 shows a route for collecting forgotten banknotes.

This forgotten banknote collection is an operation to collect the banknotes left behind when the customer sometimes forgets to take out the banknotes even though the customer performs a withdrawal operation. In this collection operation, if the cash deposit/withdrawal hopper 13 remains in the deposit/withdrawal hopper 13 after a predetermined period of time has elapsed after the cash deposit/withdrawal port door 12 is opened to enable withdrawal of the deposit/withdrawal banknotes, the deposit/withdrawal hopper 13 The left banknotes inside are transported to the collection box 35 by the main transport path. At this time, the banknote passes through the banknote inspection section 18.
8, it may be transported to the collection box 35 as it is without being inspected. The amount of collected banknotes is recorded together with the account number of the customer who forgot to collect the banknotes, and will be used for later inquiries.

Next, the operation of the external replenishment route shown in FIG. 23 will be explained with reference to the flowcharts in FIGS. 25(a) to 25(f).

When performing external replenishment, the rear door of the ATMI is opened and the keyboards 5C and 5d of the internal monitor 5 shown in FIG. 7 are operated. First, it is checked whether the changeover switch 5f is in the standalone mode. YE
If it is S, the mode switching (normal transaction mode and clerk operation mode switching) key on the keyboard 5C is pressed. The attendant operation mode lamp on the display panel 5a lights up. Next, the replenishment key is pressed, and then the 10,000 yen or 1,000 yen key is pressed to specify the denomination. The banknote number key is pressed and the number of replenishment banknotes is input from the ten-key keyboard 5d. The number of sheets is displayed on the segment display 5b. If the denomination and number of coins are correct, the confirmation key is pressed. At this time, it is checked whether the designated denomination storage box is full. If it is full, all input data is cleared and the flow returns to the replenishment key press flow. If it is not full, a check is made to see if the number of sheets is within the replenishment limit (for example, 1100 sheets) per refill. If it is within the limit, the replenishment pinch roller is opened, and if it is outside the limit, all the input f-numbers are cleared and the process returns to the replenishment key press flow. When the replenishment pinch roller is opened, banknotes can be inserted, and a bundle of 100 banknotes is inserted into the replenishment pinch roller. The insertion of the banknote bundle is detected by the photo sensor P14,
In response to this detection, gate G10 is opened by energizing solenoid S8.

Next, as shown in the flowchart of FIG. 25(b), the motor M5 is reversed in order to raise the lower belt 24a of the deposit reject accumulation section 24. When the upper and lower belt stop position detection switch SW7 is turned on, the motor M5 is stopped. The solenoid S1 is turned on in order to rotate and open the tip of the backup 17 of the deposit/withdrawal hopper 13 to create an entry conveyance path. Here, the motor M12 is driven and the main transport path is driven at a low speed.4 The above low speed drive will be explained based on the switching mechanism shown in FIG. 24. When main motor M12 is rotating forward, III clutch C1 is turned off and electromagnetic clutch C2 is turned on, the rotational force of motor M12 is transmitted to reduction gear 63 via the upper gear in the figure and clutch C2. be done. The rotational force of this reduction gear 63 is directly transmitted to the output shaft 59 and rotationally drives the conveyance drive shaft 62 via the belt 61. At this time, the conveyance drive shaft 62 is decelerated by three gears from the motor M12, and is approximately 1/1/1 of the rotation speed of the motor M12.
Rotates at a speed of 10. This low speed rotation of the transport drive shaft 62 causes the transport belt to run at a low speed. During this low-speed travel, banknotes are conveyed as a bundle.

When motor M12 rotates forward, electromagnetic clutch C1 is turned on.
When the electromagnetic clutch C2 is turned off, the motor M
12 is transmitted substantially directly to the output shaft 59 via the lower gear and clutch C1. Therefore, the output shaft 59 rotates at high speed, and accordingly, the conveyance drive shaft 62 rotates at high speed. That is, the main conveyor belt runs at high speed. At this time, banknotes are transported one by one.

The bill bundles conveyed by the main conveyance path running at low speed pass through the gates G3, G4, G5, G6, the deposit reject accumulation section 24,
When the bill enters the deposit/withdrawal port hopper 13 via the gate GIO and the backup 17 and is stored in the deposit/withdrawal port hopper 13, the photosensor P2 detects the banknote bundle. In response to this detection, motor M12 is turned off, and travel on the main conveyance path is stopped. Thereafter, by turning off the solenoids S1 and G8, the deposit/withdrawal robust up 17 is returned to its original position and the gate G10 is closed. Furthermore, motor M
5 is rotated in the forward direction, and the lower belt 24b of the deposit reject accumulation section 24 is returned to its original position. When the intermediate stop position detection switch SW8 is turned on, the motor M5 is stopped.

Next, the electromagnetic clutch C1 and motor M12 are turned on, and the main transport path is driven at high speed. In order to push down the backup 17 of the deposit/withdrawal port hopper 13, the motor M2 is rotated normally. In this state, the motor M3 is rotated in the normal direction to feed the banknotes one by one into the main conveyance path. At this time,
If it is not the inspection mode for inspecting replenishment banknotes, the solenoid S2 is turned on and the gate G1 is rotated to the right in order to form a passage to the thousand yen bill and million yen hole storage boxes 25 and 26. Since the designated denomination is 10,000 yen as described above, solenoid S9 is turned on to switch gate G7 to the left. At this time, the gate 8 is switched to the right with the solenoid 312 to 0FFt so as not to form a passage to the thousand yen bill storage box 26. The transported ten thousand yen banknotes are sequentially stored in the ten thousand yen hole storage box 25. When the photosensor P2 for detecting the remaining banknotes in the deposit/withdrawal hopper detects a bright state, when it detects that there are no bills remaining, the process moves to 70- in FIG.
Motor M2 is reversed to raise backup 17 of . Backup upper stop position detection switch SW3
When turned on, motor M2 stops. When the deposit/withdrawal port intake/feed motor stop position detection switch SW4 detects the stop position, the motor M3 is turned off and the bill intake is stopped. 'RF! 1 clutch C1 is turned off and main motor M12 is stopped. At this point, the conveyance of the replenishment banknotes to the storage box 25 is completed, and the number of replenishment banknotes, that is, the number of denomination designated input sheets, is added to the remaining amount of the designated storage box (10,000 yen hole storage box 25), The total number of sheets is stored.

After this, the storage operation shown in the flowchart of FIG. 12 is executed. When the storing operation is completed, the mode switching button on the keyboard 5C of the internal monitor 5'' in FIG. 5 is pressed to return to the normal transaction mode. This return to mode can be confirmed by the lighting of the normal transaction mode LED on the display panel 5a.

When returning to the flow of FIG. 25(C) and inspecting the replenishment banknotes, the replenishment banknotes are inspected in the banknote inspection section 18. In the inspection results, the supplementary banknotes are of the designated denomination,
It is confirmed whether the banknote is suitable for withdrawal, and if it passes, the solenoid S2 is turned on and the gate G1 is rotated to the right to form a passage to the thousand yen bill and ten thousand yen hole storage box 25,26. . Since the designated denomination is 10,000 yen as mentioned above, Gate G
7 to the left, solenoid S9 is turned on. At this time, the gate 8 is switched to the right by turning off the solenoid 812 so as not to form a passage to the thousand yen bill storage box 26. Thereafter, as shown in FIG. 25(e), the transported ten thousand yen banknotes are sequentially stored in the ten thousand yen hole storage box 25.

In order to form a passage to the eject ticket storage box 36 when there are banknotes that have failed the supplementary banknote inspection, the solenoid S1 is turned OFF and the gate G1 is rotated to the left.
Furthermore, solenoid S3 is turned on and gate G2 is rotated to the left. Therefore, the rejected ticket is stored in the reject ticket storage box 36.

When all the supplementary banknotes in the deposit/withdrawal port hopper 13 are sent out and the photosensor P2 for detecting remaining banknotes in the deposit/withdrawal hopper detects a bright state, the backup 17 of the deposit/withdrawal port hopper 13 is activated.
Motor M2 is reversed to raise . When the backup upper stop position detection switch SW3 is turned on, the motor M2 is stopped. When the deposit/withdrawal port intake/feed motor stop position detection switch SW4 detects the stop position, the motor M
3 is turned OFF and the taking in of banknotes is stopped. The electromagnetic clutch C1 is turned off and the main motor M12 is stopped. Moving to the flow in FIG. 25 (f>), it is checked whether there is a rejected ticket. If there is no rejected ticket, the amount stored in the storage box by denomination, that is, the 10,000-yen hole storage box 25, from the specified input amount. This calculated value is added to the remaining amount in the eject ticket storage box.Then, the specified denomination input amount is added to the remaining amount in the specified storage box (10,000 yen hole storage box 25), and the total value is is stored. If there is no rejected ticket, the input amount of the designated denomination is directly added to the remaining amount of money in the designated storage box (10,000 yen bill storage foil 25), and the total value is stored. After this, the 12th The storage operation shown in the flowchart in the figure is executed. When the storage operation is completed, the mode switching button on the keyboard 5c of the internal monitor 5 in FIG. 5 is pressed to return to the normal transaction mode.

This return to mode can be confirmed by lighting the normal transaction mode lamp on the display panel 5a.

In the above-mentioned external replenishment of banknotes, there are cases in which the replenishment banknotes are inspected and cases in which they are not inspected, which will be explained below. In the case where inspection is not performed, for example, in a conventional dispensing unit, the banknotes bundled in 100 sheets are withdrawn by a teller, and the 100 banknotes bundled with the savings image are handled as they are without being inspected.

This is because it is based on the trust that the sealed banknotes are absolutely error-free. If you follow the same idea, there will be no need for inspection. On the other hand, in the case of inspection, the ATV always recognizes the part that relies on manual labor and only accepts banknotes that pass the test, thereby completely eliminating mistakes.

The above idea of refilling is based on the fact that when recycling is used for a single ATV, the 1,000 yen bill storage box is often empty and is almost never full. It is based on establishing and making it possible to replenish when a shortage occurs. Therefore, in the following embodiment, when a local imbalance occurs between multiple ATVs in terms of timing, time, or location, banknotes are sucked up in units of 100 from excessive deposit/withdrawal devices and transferred to other ATVs. The function of replenishing the deposit/withdrawal device is explained. This embodiment will be explained with reference to the flowcharts of FIG. 26 and FIGS. 27(a) to (f).

This partial siphoning operation is also designated by the internal monitor 5. That is, it is checked whether the changeover switch 5f is in the standalone mode. If YES, keyboard 5C
The mode switching (normal transaction mode and attendant operation mode switching) key is pressed. The attendant operation mode lamp on the display panel 5a lights up. Next, the partial copying key is pressed, and then the ten thousand yen or thousand yen key is pressed to specify the denomination. The user presses the banknote number input key and inputs the number of banknotes to be drawn from the ten-key keyboard 5d. The number of sheets is displayed on the segment display 5b. If the denomination and number of coins are correct, the confirmation key is pressed. At this time, it is checked whether the designated denomination storage box is empty. If it is empty, all the input data will be cleared, and the process will return to the partial download key press screen. If it is not empty, a check is made to see if the number of copies is within the limit (for example, 100 copies) per copy. If it is not within the limit, all input data is cleared and the process returns to the partial key press flow. If it is within the limit, the motor M12 is rotated forward and the main conveyance path is driven. The electromagnetic clutch C1 is turned on and the main transport path is driven at high speed.

A storage box of the designated denomination, for example, the 1,000 yen bill storage box 26 (or the 10,000 yen hole storage box 25) is selected. In order to slightly lower the back-up plate 38 and push-in plate 39 of the storage box 26, the motor M7 (M9) is rotated forward for the time set by the timer. When the timer setting time elapses, motor M7 (M9)
is stopped and solenoid 5101811 (813,51
4) is turned on, and the hold claws 42 and 43 are opened. In this state, the motor M7 (M9) is reversely rotated, and the back-up plate 38 and push-in plate 39 are raised. When it rises to a predetermined position, a timer is activated, and motor M6 (M8) rotates normally to start taking in and feeding out banknotes. The forward rotation of the motor M6 (M8) rotates the take-in roller 14a and feeds out the banknotes one by one. At this time, the photosensor P11 (Pi 2) detects the passage of banknotes, and the number of bills passed is counted based on the detection signal. Storage box 2625
The banknotes withdrawn from the main conveyance path are transferred to the banknote inspection section 18.
transported to. The transported banknotes are inspected by the banknote inspection section 18 for denomination and stacking. If it is determined by this inspection that the bill to be dispensed is a valid bill, the gate G2 is turned to the right and the solenoid S3 is turned off to form a passage to the temporary storage section 23. If the bill is not a valid bill, the solenoid S3 is energized so that the gate G2 moves to the left in order to guide the bill to the reject storage box 36 as a reject ticket. This gate switching timing is determined by the detection of bill passage by the photosensor P8. When a valid bill is detected by the photosensor P9, the rotary solenoid S6 is biased to rotate to the left in order to switch the gate G5 to the temporary storage section side. Therefore, the banknotes are sequentially transferred to the deposit reject accumulation section 24.
transported to.

When the number of banknotes sent out from the storage box reaches the specified number, it is checked whether or not there is a direct ticket. If there are any rejected tickets, add the number of rejected tickets to the specified number, and
Returning to the flow of counting the number of dispensed sheets in FIG. 7(b). If there is no rejected ticket, it is checked whether the photosensor 5W10 (SW15) for detecting the stop position of the take-in motor has detected the stop position (dark detection). If YES, take-in motor M
6 (M8) is stopped. The forward rotation of the motor M7 (M9) causes the back-up plate 38 and the push-in plate 39 to descend.
When it descends to the push-in position, switch 5W14 (SW19
) turns ON. Motor M7 responds to the push position detection.
(M9) is stopped, and the backup plate 38
Then, the lowering of the push plate 39 is stopped. At this time, solenoid S10.511 (S13.514) is turned off and the hold claw is returned to the storage box. Once again, the motor M7 (M9) is reversed, and the backup plate 38 and push-in plate 39 are raised. When the stored banknotes collide with the holding pawl, the back-up plate 38 stops. The push plate 39 rises to the guide position, and the switch SWI3 (SW18
) is turned on, the back-up plate 38 and push-in plate 39
The motor M7 (M9) driving the motor upward stops.

The electromagnetic clutch C1 and motor M12 are sequentially turned off, and the main conveyance path is stopped. In order to raise the lower belt 24a of the deposit reject accumulation section 24, the motor M5 is reversed. Photo interrupter S for detecting stop position on belt
When W7 is turned on, motor M5 is stopped. In this state, motor M12 is reversed. In this case, in the switching mechanism shown in FIG. 24, the electromagnetic clutch C1 is turned off and the electromagnetic clutch C2 is turned on. Therefore, the reverse rotational force of the main motor M12 is applied to the upper gear and the clutch C.
2 to the reduction gear 63, and the drive shaft 62
is rotated in reverse at low speed. Therefore, the main conveyance path runs in the reverse direction at a low speed, and the banknotes in the deposit reject accumulation section 24 are collectively conveyed outward as shown by the broken line. When the photosensor P14 provided close to the replenishment port 12a detects a banknote bundle to be conveyed (dark detection), the motor M is activated after the set time of the timer.
12 is turned off, and traveling of the main conveyance path is stopped. If a rejected note does not exist in banknote inspection, the input amount of the specified denomination (thousand yen bill) is subtracted from the amount remaining in the storage box (thousand yen bill storage box) and is stored. If a rejected ticket exists, the designated denomination (thousand yen bill) amount corresponding to the number of rejections is calculated. The calculation result value is added to the remaining amount of money in the reject storage box, and the added value is stored. The added value of the calculated value and the specified number of coins is subtracted from the remaining amount of money in the denomination-specific storage box, and the result is stored.

When the balance is determined by the storage box balance calculation described above, the specified amount is subtracted from the current amount memory of the deposit/withdrawal device, and the result, that is, the total amount held by the ATV is stored. When this process is completed, the key on the internal monitor 5 will be displayed.

- The mode switching button on board 5C is pressed to return to normal trading mode. At this time, the normal transaction mode lamp is lit and the deposit/withdrawal device 2 returns to its initial state.

Figure 28 shows the flow of banknotes in the inspection mode in which deposits and withdrawals are settled and the bills in the 10,000 yen hole storage box 25 and the 1,000 yen bill storage box 26 are transferred to the bulk storage box. The explanation is shown in the boxes ○-- in FIGS. 29(a) to 29(C). According to this flow, first, the mode switching (normal transaction mode and clerk operation mode switching) key on the fifth internal monitor keyboard 5C is pressed. The attendant operation mode lamp on the display panel 5a lights up. Next, the review key is pressed, and then the confirmation key is pressed. At this time, the motor M12 is rotated in the normal direction, and the main conveyance path is driven. The electromagnetic clutch C1 is turned on and the main transport path is driven at high speed. It is checked whether banknotes of ¥ are present in the million yen hole storage box 25. If a million-yen hole exists, the million-yen hole storage box 25 is selected. Thereafter, an inspection operation for the million-yen hole is performed according to the flowcharts shown in FIGS. 30(a) to (C), and this inspection operation will be described later.

After checking the million yen hole, it is checked whether or not banknotes ¥ exist in the 1,000 yen bill storage box, and if YES, the 1,000 yen storage box is selected. Next, a scrutiny operation is performed on the 1,000 yen bill.

In the above-mentioned inspection operation of 10,000 yen and 1,000 yen, Figure 30 (a
), first, the motor M7 (M9) is rotated in the normal direction in order to lower the back-up plate 38 and the push-in plate 39 slightly. This is to release the stored banknotes from being pressed against the holding claws 42 and 43 by the pushing up force of the back-up plate 38, and to easily separate the holding claws from the stack of stored banknotes without damaging the banknotes. . The amount of descent of the back-up plate 38 is set by a timer, and when the timer elapses, the motor M7 (M9) is stopped and the solenoid 810. Sl 1 ('S13.514)
is turned on, and the hold claws 42 and 43 are opened. In this state, the motor M7 (M9) is reversely rotated, and the back-up plate 38 and push-in plate 39 are raised. When the banknotes are raised to a predetermined position, a timer is activated, and motors M6 (M8) are rotated in the normal direction to start taking in and feeding out banknotes. The forward rotation of the motor M6 (M8) causes the take-in roller 14a to rotate and feed out the banknotes one by one. At this time, photosensor P1
1 (P12) detects the passage of bills, and the number of bills passed is counted based on the detection signal. The banknotes dispensed from the storage box 2526 are conveyed to the banknote inspection section 18 by the main conveyance path. The banknote inspection unit 18 determines the denomination and stacking of the conveyed banknotes. If the disbursed banknote is determined to be genuine by these inspections, the solenoid $3 is turned on to tilt the gate G2 to the right in order to form a passage toward the gate G3.
Becomes FF. If the bill is not a valid bill, the solenoid S3 is energized so that the gate G2 moves to the left in order to guide the bill to the reject storage box 36 as a reject ticket. This gate switching timing is determined by the detection of bill passage by the photosensor P8.

The gate G3 is tilted to the left in order to guide banknotes to the bulk storage box 34. This gate G3 is plunger solenoid S4
It is driven by being energized.

In this state, the genuine bills are sequentially stored in the bulk storage box 34.

When a rejected ticket is conveyed to the rejected ticket storage box 36 via gate G2, it passes through gate G9.
9 is activated only during the collection operation, the rejected ticket is carried into the reject ticket storage box 36 as it is.

It is checked whether the storage boxes 25 and 26 are empty. For this sky detection, the sky detection switch SW115W16 is ON.
It will be judged whether or not it has become. If the storage box is not empty, it is determined whether the number of bills sent out from the storage box matches a predetermined number. If YES, it is checked whether the photosensor 5W10 (SW15) for detecting the stop position of the intake motor has detected the stop position (dark detection). If YES, the intake motor M6 (M8) is stopped. At this time, the bulk storage box 34 is selected and the storage operation is started. This storage operation is performed in the same manner as the flow shown in FIG.

When the designated storage box is empty, the gate G3 is returned to the right by turning off the solenoid S4.

If it is not empty, the flow returns to the flow for counting the number of sheets fed out in FIG. 30(a).

In the flow shown in FIG. 30(C), the back-up plate 38 and the push-in plate 39 are lowered by normal rotation of the motor M7 (M9). When these are lowered to the push-in position, switch 5
W14 (SW19) is turned on.

Motor M7 (M9) turns OFF in response to push position detection
Then, the lowering of the back-up plate 38 and the push-in plate 39 is stopped. At this time, solenoid S10.811 (
S13.514) is turned OFF and the hold claw is returned to the storage box. Once again, the motor M7 (M9) is reversed, and the back-up plate 38 and push-in plate 39 are raised. When the stored banknotes collide with the holding claw, the back-up plate 3
8 stops. When the push plate 39 rises to the guide position, the switch SWi3 (SW18) is turned on. As a result, the motor M7 (M9) that drives the backup plate 38 and the push plate 39 upward stops, and the inspection operation is completed. .

When the inspection operation is completed, the electromagnetic clutch C1 is turned off, and the main motor M12 is further turned off. This causes the conveyance path to stop. Next, based on the memory contents of the storage unit (7) (Fig. 31), as shown in Fig. 29 (b), the number P of sheets sucked from the million-yen hole storage box is the number of sheets stored in the million-yen hole storage box with the current high memory. is set to Furthermore, the number O that has been sucked up from the 1,000 yen bill storage box is set to the number of 1,000 yen bill storage boxes that are currently in high memory. The cumulative number of million yen coins deposited into the device is added (B-A+E+F).

Additionally, the cumulative number of thousand yen bills deposited into the device is added (LA+D+F). Furthermore, the cumulative number of 5,000 yen bills deposited into the device is set (NC). The number of million yen holes that should be in the reject ticket storage 1136 is counted (V-L-P). In addition, the reject ticket storage box 36
The number of thousand yen bills that should be in is calculated (LJ-L-0)
. A-N, ■, and U in the cumulative memory area are dumped to the printing device, and the storage section is cleared. The number P of stored thousand yen bills in the loading box and the number 0 of stored thousand yen bills are compared (verification).

The number of coins of each denomination stored in the reject box is compared with N, ■, and U. If the verification is successful, a new bulk storage unit is set in the deposit/withdrawal device 2.

That is, the bulk storage unit 27 is replaced with a new bulk storage unit. The mode switching button is pressed to return to normal trading mode. The normal transaction mode lamp lights up and the deposit/withdrawal device returns to its initial state and stands by.

FIG. 32 shows the flow of banknotes when the banknotes stored in the bulk storage box 34 of the bulk storage section 27 are loaded into the denomination-specific storage boxes, that is, the 10,000-yen hole storage box 25 and the 1,000-yen bill storage box 26. It is shown. In this loading, if there are no banknotes to be replenished in the bulk storage box 34 of the bulk storage unit 27 that has already been loaded, the empty bulk storage unit 27 is used as a deposit/withdrawal device! 2) and replaced with a bulk storage unit 2) having a bulk storage box 34 that stores banknotes in bulk.

In loading, mode switching is first performed as in replenishment, inspection, etc. That is, as shown in the flowchart of FIG. 33 <a>, the mode switching key on the keyboard 5C of the internal monitor 5 is pressed, and the attendant operation mode is set. At this time, the attendant operation mode lamp on the display panel 5a lights up. Next, the loading key is pressed to set the loading mode. To set the number of sheets to be loaded into the ten thousand yen hole, the number of sheets input key is pressed, the number of sheets is input using the numeric keypad, and when the ten thousand yen key is further pressed, the number of ten thousand yen sheets is displayed on the segment display 5b of the internal monitor 5, Further, the input number of sheets is added to the cumulative total memory G.

To set the number of loaded 1,000 yen bills, the number input key is pressed, the number is input using the numeric keypad, and when the 1,000 yen key is further pressed, the number of 1,000 yen bills is displayed on the segment display 5b of the internal monitor 5.
is displayed, and the input number is further added to the cumulative memory F. When the confirmation key is pressed, the motor M12 is rotated in the normal direction, and the main transport path is driven. Electromagnetic clutch C1 is turned on,
The main transport path is run at high speed. In order to slightly lower the back-up plate '38 and the push-in plate 39, the motor M11 is rotated forward for the timer period. When this timer time has elapsed, motor M11 is stopped and solenoid 816.8 is stopped.
17 is turned on, and the hold claws 42 and 43 are opened. In this state, the motor M11 is reversely rotated, and the back-up plate 38 and the push-in plate 39 are raised. When the banknotes are raised to a predetermined position, a timer is activated, and the motor MIO is rotated in the normal direction to start taking in and feeding out banknotes. The forward rotation of the motor MIO causes the take-in roller 14a to rotate, and bills are sent out one by one from the bulk storage box 34. At this time, the photosensor P13 detects the passage of banknotes, and the number of passed banknotes is counted based on the detection signal. Solenoid S5 is turned on,
Gate G4 is pushed to the left. Therefore, the banknote ¥ is conveyed in the direction of the banknote inspection section 18.

The denomination and stacking of the transported banknotes are determined by the banknote validator 18. If the disbursed banknote is determined to be a genuine note through these inspections, the 10000 yen hole storage box 25 and the 1000 yen bill storage box 26 are opened.
Solenoid S2 is turned on to tilt gate G1 to the right in order to form a passage in the direction of. If the bill is not a legitimate bill, the solenoid S2 is turned OFF and the solenoid S3 is turned ON so that the gates G1 and G2 are tilted to the left in order to guide the bill to the reject storage 936 as a reject ticket. The switching timing of the gate G1 is determined by the detection of passage of banknotes by the photosensor P8.

It is determined whether the denomination of the banknote ¥ to be conveyed toward the denomination storage box is a 1,000 yen note or a 10,000 yen note. If it is a 10,000 yen note, solenoid S9 is turned on so that gate G7 falls to the left in order to guide the 10,000 yen note to the 10,000 yen hole storage box 25. The switching timing of this gate G7 is determined by the timing of detecting the banknote ¥ by the photosensor P11. If it is a 1,000 yen bill, the solenoid S12 is turned on so that the gate G8 falls to the left in order to guide the 1,000 yen bill to the 1,000 yen bill storage box 26. The switching timing of this gate G8 is determined by the timing of detecting the banknote ¥ by the photosensor P12. Photo sensors P11 and P
The number of stored ten thousand yen bills and the number of thousand yen bills stored are counted by the banknote detection signal of I3.

The banknotes sorted as above are placed in the ten thousand yen hole storage box 25.
, are stored in the 1,000 yen bill storage box 26 and the rejected ticket storage box 36, respectively. Each time banknotes are stored, it is determined whether the bulk storage box 34 is empty or whether the stored banknote count value matches a predetermined number of banknotes. If either of them is determined as YES, it is determined whether the photosensor 5W20 has detected the darkness, that is, has detected the stop position of the batch storage box take-in and feed motor. This judgment is Y
If it is ES, the batch storage box take-in motor M10 is stopped.

At this time, the deposit reject accumulation unit 24
Alternatively, the million-yen storage box 25 is selected, and the storage operation is started for the selected storage box. Incidentally, when the bulk storage box 34 becomes empty, the storage operation is simultaneously started for the re-storage boxes of the million yen hole storage box 25 and the thousand yen bill storage box 26. This storage operation is performed according to the flow shown in FIG.

When the bulk storage box 34 becomes empty, the drainoid S3 is turned off and the gate G2 is returned to its original state. 33rd if not empty
Returning to the flow in Figure (b). Furthermore, solenoid S5 is turned off in order to restore gate G4. The electromagnetic clutch C1 is turned off, the motor M12 is turned off, and the main conveyance path is stopped. Next, the motor M11 is rotated forward,
The back-up plate 38 and the push-in plate 39 are lowered. When the push-in plate 39 descends to the push-in position, the switch 5W2
4 turns on. Motor M11 responds to the detection of the pushing position.
is stopped, and the lowering of the back-up plate 38 and the push-in plate 39 is stopped. At this time, solenoid 816, S17
is turned off, and the hold claw is returned to the storage box.

The motor M11 is reversed again, and the back-up plate 38 and the push-in plate 39 are raised. When the stored banknotes collide with the holding pawl, the back-up plate 38 stops. Push plate 3
9 is raised to the guide position and the switch 5W23 is turned on, the motor M11 driving the back-up plate 38 and the push-in plate 39 upward stops.

The number of ten thousand yen bills stored in the ten thousand yen bill storage box is added to the number P of ten thousand yen bills stored in the current high memory, and the result is stored. The number of 1,000 yen bills stored in the thousand yen bill storage box is added to the number of 1,000 yen bills stored in the current high memory, 0, and the result is stored. The number of bills stored in the reject ticket storage box is calculated as the sum of the subtracted values of the number of input 10,000 yen bills q, the number f of input 1,000 yen bills, and the number of bills stored in the 10,000 yen hole storage box 25 and the 1,000 yen bill storage box 26. The value is added to Q and stored. Deposit/withdrawal current high memory R and S values Q and f
are added to obtain a new current ^, and this amount is stored. After this process is completed, the mode switching button is pressed and the deposit/withdrawal device is returned to the normal transaction mode.

FIG. 34 shows the flow of banknotes when they are replenished leaf by leaf (one banknote at a time) from the group recycling device 11 using solid arrows. According to this embodiment, the group recycling device 11 that runs behind the ATM 1 is connected to the deposit/withdrawal device 2, and replenishment in units of leaves is started. As this group recycling device 11, for example,
9-97915 is used for replenishing banknotes in units of leaves. That is, group recycling device 1
1, for example, when the ten thousand yen hole is refilled in the deposit/withdrawal device 2, the banknotes are sent to the gates G3 and G4 as shown by solid line arrows.
The banknotes are guided to the banknote inspection section 18 via the banknote inspection section 18. The banknotes passed through this banknote inspection section 18 are sent to the ten thousand yen hole storage box 2 through the gate G1.
5, and is stored in the million-yen storage box 25 through the gate G7.

In the embodiment shown in FIG. 34, group recycling is performed leaf by leaf, but supplementary banknotes can be brought in as a bundle. In this case, a bundle of banknotes is carried in through the same route as in the embodiment shown in FIG. 23, and banknotes are replenished. in this case,
As the group recycling device 11, a banknote bundle automatic replenishment device shown in FIG. 35 is used. This device has motor 13
2, and an upper unit 1.3 placed on top of the lower unit 130a.
06 is provided. The upper unit 130b can be moved up and down with respect to the lower unit 130a by a lifting motor 139, a pinion gear 140 and a rack gear 41 that are interlocked with the lifting motor 139. Further, the upper unit 30b includes a recycling control device 136, an operation keyboard 143, and a liquid crystal display 144.
is built-in. Further, an optical communication type transceiver 150 is provided, which performs optical communication with the transceiver provided in each ATV, and is connected to the movable trolley 1 of the group recycling device 11.
14, transmits and receives control signals for self-running, stopping, etc.

A movable safe unit 100 that can be moved back and forth by an advance/retreat drive motor 142 is provided on the upper unit 130a. This mobile safe unit 100 includes a motor 10.
A conveyor belt 101 that is rotated in forward and reverse directions by 2 is provided. A banknote bundle is fed to this conveyor belt 101 by a bending rubber roller 105 . A cutter 104 driven by a rotary solenoid 103 is disposed between the conveyor belt 101 and the rubber roller 104. This cutter 1
04 is provided for cutting the band of the banknote bundle.

When the band is cut, the banknote bundle is bent by the pushing force of the rubber roller 105, and the band is cut by the cutter 10'4 using this bending. For this purpose, the conveyor belt 101 and the rubber roller 105 are configured to be driven independently. Banknote bundle with band (100 banknotes or 100 banknotes for replenishment) 106 is back 710
It is placed on top of 8. The backup 108 is urged upward by a rising spring 109, and can place eight bundles of 100 sheets. The banknote bundle extrusion claw 107 pushes out the banknote bundle 1
06 one by one to the rubber roller 105.

The group recycling device 11 requires replenishment A
When the TV is moved, a bundle of banknotes, for example, a bundle of -10,000 yen banknotes, is removed from the movable safe unit and refilled from the rear replenishment port 2a of Jindekin@2. The banknote bundle replenished from the replenishment port 2a is conveyed to the deposit/withdrawal port hopper 13 by a conveyance path belt running at low speed, as shown in FIG. The banknote bundles in the deposit/withdrawal port hopper 13 are fed out one by one and conveyed to the million yen hole storage box 25 via the banknote inspection section 18, and the storage box 25 is replenished.

In the case of partial ejection, inspection, or loading, banknotes are delivered to the mobile safe unit in units of 100 banknotes.

In this case, 100 banknotes can be pulled into the mobile safe in a bundle when receiving the banknotes.

In the above-described deposit/withdrawal system, banknotes may jam in the conveyance path during conveyance of the banknotes. In this case, unmanned automation cannot be achieved by opening the inside of the deposit/withdrawal device to clear the jam. However, according to this invention, jams can also be automatically cleared.

This is because, according to the present invention, the transport system has the following three features. That is, 1. Banknotes can be transported in bundles, and 20 bundles can be transported at low speed; 3. Low-speed conveyance can be performed in both forward and reverse directions. By utilizing these features, jams can be automatically cleared.

Jams generally occur near the gate, but in front of this gate there is a banknote detector (banknote sensor) consisting of a photosensor, etc., to detect the passage of banknotes and determine the gate activation timing. . This sensor is used to detect jamming of banknotes at the gate. In other words, the banknotes being conveyed pass the sensor in a predetermined time, but when the banknotes become jammed at the gate and stay at the sensor position, the sensor takes a long time to detect the banknotes, and the occurrence of a jam is determined based on this detection time length. Ru. Another method is a jam detection method called shift control. This is a method of confirming that banknotes are being conveyed between two adjacent sensors for a predetermined period of time. In this method, a jam is not detected when the photosensor detects darkness, but a jam is determined to occur when a banknote that has passed through a previous sensor does not reach the next sensor within a predetermined time. Therefore, this jam detection is a bright detection.

FIG. 36 to FIG. 39 show the occurrence of a jam and its release. FIG. 36 shows a state in which the banknotes being conveyed while being sandwiched between the upper and lower conveyor belts B1 and B2 collide with the gate G, and two or three banknotes are jammed at the gate. At this time,
The occurrence of a jam is detected by the sensor described above. In response to this jam detection, the conveyor belts B1 and B2 are run in opposite directions for a predetermined period of time, and the banknotes are evacuated from the gate G (FIG. 37). In this case, the reversal time is determined to be the minimum necessary. Next, the gate G is moved below the conveyor belt (FIG. 38). Once again, the conveyor belts 81, 82 are run in the banknote conveyance direction (FIG. 39). At this time, the jammed banknotes are conveyed through the gate, and the jam is automatically cleared.

Regarding this jam, in the case of a deposit transaction, if a jam occurs before the depositor completes the deposit transaction, the gate is directed toward the deposit/withdrawal port. On the other hand, in a withdrawal transaction, if a jam occurs before the transaction is completed, the gate operates to collect the banknotes into the reject storage box.

However, after the state shown in FIG. 37, in case 1 where you want to transport the jammed bill in the direction where gate G is located, that is, in the downward direction in FIG. Since it is configured to allow a bundle of 100 bills to pass through, jammed banknotes can easily pass through the gate G.

In the above embodiment, sensors are provided at various locations to detect the conveyance state of banknotes, but one sensor is used to detect timings from G1 to G6 for gates that are close to each other, for example, gates G4, G5, and G6. I try to take it. Although it is preferable to use a common sensor in this way because it helps to reduce costs, it is also possible to provide individual sensors for these approach gates.

[Effects of the Invention] According to this invention, a storage box for storing paper sheets such as banknotes is provided with an upper plate and a bottom plate that are movable up and down, and the paper sheets are fed one by one by a paper sheet feeding roller. Paper sheets to be stored are stacked on the bottom plate. The paper sheets loaded on the bottom plate are lifted up as the bottom plate rises, and are fed out one by one by a predetermined number of sheets by the tip feeding means. After the paper sheets have been fed out by the feeding means, the upper and bottom plates are lowered, and at this time,
The paper sheet following the last paper sheet fed out is returned to the storage box body by the feeding back means which is operated in the opposite direction to the feeding direction. Therefore, even if the next sheet after the last sheet to be fed out is caught at the feeding port, it will be immediately returned to the storage box, and there will be no hindrance to feeding out the next sheet. Allows for smooth delivery.

[Brief explanation of drawings]

FIG. 1 is a perspective view of an automatic transaction device using a paper sheet storage/dispensing device according to an embodiment of the present invention, FIG. 2 is a block circuit diagram of the automatic transaction device of FIG. 1, and FIG. A diagram schematically showing the internal configuration of the deposit/withdrawal device, FIG. 4 is a block circuit diagram of the deposit/withdrawal device, FIG. 5 is a mechanical circuit diagram of the deposit/withdrawal device of FIG. 3, and FIG. 6(a) and (b) is a diagram explaining the functions and operations of various parts shown in Figure 5, Figure 7 is a perspective view of the internal monitor, and Figure 8 is a diagram showing the flow of banknotes during depositing operation of the deposit/withdrawal device. 9(a) to 9(d) are schematic structural diagrams of the temporary storage unit in the banknote bundle discharging operation; 11(a) to (j) are flowcharts for explaining the deposit operation, FIG. 72 is a flowchart for explaining the storage operation of the storage group, and FIG. 13 is for transporting banknote bundles from the temporary storage section to the deposit/withdrawal hopper. A schematic structural diagram of the depositing and dispensing device showing the flow, FIG. 14 is a schematic structural diagram of the depositing and dispensing device showing the flow of banknotes during storage operation, FIG. 15 (a)
~(e) is an operational diagram of the storage box during storage operation, FIG. 16 is a schematic structural diagram of the side surface of the bulk storage section, FIG. 17 is a schematic structural diagram of the bulk storage section from a plane, and FIG. Schematic structural diagram of the deposit/withdrawal device showing the flow of banknotes, Figure 19 (
a) to (C) are flowchart diagrams of withdrawal mode, No. 20
Figures (a) to (C) are diagrams showing the withdrawal operation subroutine in the withdrawal mode, Figure 2) (a) to (f) are operation diagrams of the storage box in the withdrawal operation, and Figure 822 is a banknote withdrawal operation subroutine. 23 is a schematic structural diagram of the depositing and dispensing device showing the flow of banknotes in external replenishment mode, FIG. 24 is a diagram of the main conveyance path drive mechanism, and FIG. 25 (a) ) to (f) are flowcharts of external replenishment mode,
The 26th cause is a schematic structural diagram of the deposit/withdrawal device showing the flow of banknotes in the partial suction mode, Figure 27 (a>-(f) is a flow chart diagram of the partial suction mode, and Figure 28 is the scrutiny mode) 29(a) to 29(C) are flowcharts of the inspection mode, FIGS. 30(a) to 30(C) are inspection operation subroutine diagrams, and FIG. 31 32 is a schematic structural diagram of the depositing and dispensing device showing the flow of banknotes in the loading mode; FIGS. 33(a) to 33(e) are flowcharts of the inspection mode; FIG. 35 is a schematic structural diagram of the deposit/withdrawal device showing the flow of banknotes during external replenishment, FIG. 35 is a schematic structural diagram of the group recycling device, and FIGS. 36 to 39
The cause is a diagram of a conveyance path for explaining automatic jam release. 1...ATM, 2...Deposit/withdrawal device, 5...Internal monitor, 11...Self-propelled trolley device for group recycling,
12...Payment/withdrawal port vinegar, 13...Deposit/withdrawal hopper, 1
4.14a... Take-in roller, 17... Backup plate, 18... Banknote inspection section, 23... Temporary storage section,
24... Deposit rejection collection section, 25... Thousand yen hole storage box, 26... Thousand yen bill storage box, 27... Bulk storage section, 34... Bulk storage box, 35... Collection Storage box, 3G
...Reject ticket storage box, G1-G9...Gate,
P1-P14...Sensor, SW1-5W25...Detection switch, 81-517...Solenoid, M1-M
12...Motor, C1, C2...Electromagnetic clutch. Applicant's Representative Patent Attorney Takehiko Suzue Figure 1 Figure 2 (a) Figure 6 Figure 11 Figure 11 Figure 11 Figure 12 (a) (b) Figure 16 Figure 17 (C) Figure 19 Figure 20 (c) Figure 20 (a) (b) (c) Figure 2) (f) - Rowing 1: Kat+- Figure 24 Figure 27 Figure 27 Figure 27 (d) Figure 27 Figure 27 (f) Figure 27 (a) Figure 29 (b) Figure 29 Figure 30 Figure 30 Figure 33 (b) Figure 33! ,,4 Article 33 Country (d) Figure 33 (e) Figure 33 Figure 35 Procedure Kan 1 Official Book (Method) 1. Display of the case Japanese Patent Application No. 60-125694 No. 3, Person making the amendment Relationship with the case Patent applicant (307) Toshiba Corporation 4, Agent UBE Building 7, 3-7-2 Kasumigaseki, Chiyoda-ku, Tokyo,
Contents of the amendment (1) In the 4th line of page 80 of the specification, "Figure 32" is corrected to "Figure 34."

Claims (3)

[Claims] (1) A storage box body for storing paper sheets, a means provided on the upper part of the storage box body for feeding paper sheets into the storage box body, and an upper plate provided on the storage box body so as to be movable up and down. a bottom plate that is vertically movable in the storage box body and on which paper sheets to be introduced are loaded; a plate driving means for driving the upper plate and the bottom plate; and the storage box. means for feeding out a predetermined number of paper sheets that are provided at the top of the box and lifted upward by the bottom plate; a feeding-back means that operates in a direction opposite to the feeding direction of the feeding means; and the feeding means. controlling the plate drive means to lower the upper and bottom plates after the paper sheets have been fed out, and feeding the paper sheets subsequent to the final sheet to be fed back to the storage box body. A paper sheet storage/feeding device comprising means for controlling a feed-back means. (2) The sheet storage/feeding device according to claim 1, wherein the feed-back means is a roller means provided close to the feed-out means and rotated in a direction opposite to the feeding direction. (3) The plate driving means includes a lowering driving means for driving the bottom plate and the upper plate in a downward direction, a rising driving means for driving the bottom plate and the upper plate in an upward direction, and a lowering driving means for driving the bottom plate and the upper plate in an upward direction. Claim 1 comprising a one-way clutch means that is in a coupled state that simultaneously transmits driving force to both the bottom plate and the top plate in the upward direction, and is in a free state in the upward direction. Or the paper sheet storage and feeding device according to item 2.