JP5088038B2 - Banknote organizer - Google Patents

Description

The present invention relates to a banknote organizing apparatus that counts banknotes, accumulates the counted banknotes in a stacking unit, and bundles and organizes them for each set number of sheets.

Conventionally, for example, four temporary stacking units are provided, and the operator designates sealing for each denomination of banknotes of four denominations or sealing for any two denominations of genuine and non-defect bills from the operation unit, When a banknote is set, the set banknote is conveyed to a discrimination unit to perform discrimination and counting of denominations, and the counted banknotes are divided into, for example, denominations or damages and accumulated in a plurality of temporary stacking units.
And when a fixed number of banknotes are accumulated, the banknotes are transferred to the sealing part by the transfer means, and the banknotes are bound by a tape by the sealing part and discharged. In addition, after the identification and counting of the set banknotes are completed, if there are fractional banknotes that do not reach a certain number in each temporary stacking unit, the banknotes of each fraction are picked up by the transfer body, and the fractional banknote stacking unit They are integrated together (for example, Patent Document 1).
This Patent Document 1 also discloses that the above-mentioned fractional banknotes are bundled by denomination and accumulated in the fractional banknote accumulating unit.

On the other hand, a predetermined number of bundles of bundles of paper sheets are collected and packed in a predetermined number, and then packaged, and the packaging material is removed by severing. There is a paper sheet processing apparatus that inspects one sheet at a time, and bundles the inspected paper sheets again for packaging (for example, Patent Document 2). In this apparatus, when there are less than 10 bundles to be packaged, there is a dummy bundle that is loaded into the package to arrange the appearance of the package, and the dummy bundle is substantially the same as the bundle of paper sheets. It has a shape and also has a loading part for loading from outside the apparatus.

Furthermore, in a paper sheet bundling apparatus applied to a paper sheet processing machine that sorts and accumulates paper sheets such as banknotes according to the type, a bundle of 100 sheets of paper sheets and 100 sheets With a handle sealed with less than that, there is one that prints information on a binding material because it cannot be judged by visual observation (for example, Patent Document 3). When the binding material is wound around a predetermined number of stacked banknotes, the printing means of this apparatus prints so that the previous information is not located on the side of the stacked banknotes, and when the number is less than the predetermined number, a part of the information is stacked. By printing so that it may be located on the side of banknotes, it can be easily discriminated visually.
JP 2007-066249 A (paragraphs 0011 to 0013, 0024 to 0026, 0028 to 0031) JP 2001-357428 A (paragraphs 0014 and 0028) JP 2007-077623 (paragraphs 0022, 0025)

In the conventional technology described above, when the fractional banknotes are accumulated in the fractional banknote stacking unit as they are, the operator can collect the fractional banknotes in a lump, so that it is possible to eliminate the troublesomeness of the operation and prevent forgetting to withdraw. However, the extracted fractional banknotes are then stored, for example, in a cash bus together with the sealed bundle. In that case, the banknotes in a loose state are stored by tying them with rubber bands, etc., so they may be scattered in some cases and stored in a cash bus etc. in the same state as the sealed bundle. Is desired.

On the other hand, in the above-described conventional technology, a technique is disclosed in which fractional banknotes are once transported to a sealing part, denominated or bundled together with a tape, and then accumulated in a fractional banknote accumulating part. In this case, since the fractional banknotes are also bundled, it is assumed that the storage in the cash bus can be properly stored because it has the same shape as the bundle sealed every fixed number of sheets.
However, the number of fractional bills fluctuates during the process. The sealing portion is generally designed and manufactured for the purpose of sealing a predetermined number of predetermined bills, for example, 100 bills. When sealing 100 or less bills or more than 100 bills, There is a problem that the tension may not be sufficiently maintained and the banknotes may fall out of the bundle state, or the tape may not be glued correctly and the creation of the bundle may fail.

Further, in the technique disclosed in Patent Document 3, when the number is less than a predetermined number, printing is performed at a shifted timing so that a part of the information is located on the side surface of the stacked banknotes, but the number of sealed sheets is small. Since the side surface (thickness) is extremely small, there is a concern that the printing timing control is complicated.

In order to solve the above-described problems, the present invention includes a plurality of stacking units and a binding unit that binds banknotes stacked in each stacking unit. , Discriminates and counts for damages, etc., counts the bills that are temporarily accumulated in the stacking unit, and feeds the banknotes that are stacked for each stacking unit to the binding unit and binds them with a tape. A banknote arranging device for discharging, and when the banknotes accumulated in the stacking unit are less than a predetermined number, the simulated medium is inserted and separated and conveyed one by one until reaching the predetermined number, and the banknotes stacked in the stacking unit The mixture of simulated media is sent to the binding unit, bound with tape and released.

Since the present invention adds a simulated medium to a fraction of banknotes stacked in the stacking unit and bundles them with a tape for release, the fraction can always be handled as a bundle of a predetermined number of sheets, For example, the work can be performed efficiently even when stored in a cash bus, and the stability of the sealing operation can be ensured by always sealing a predetermined number of bundles.

Hereinafter, a bill arranging device according to the present invention will be described with reference to the drawings.

FIG. 2 is a perspective view showing the external appearance of the first embodiment of the present invention, and FIG. 3 is a schematic side view showing the internal structure of the banknote arranging apparatus of the first embodiment of the present invention. 4 is an enlarged view of the upper part of FIG. 3, and FIG. 5 is an enlarged plan view of the operation unit of FIG.
In the figure, reference numeral 1 denotes an input portion of a banknote (hereinafter, a symbol M is assigned, and other banknotes are appropriately labeled), and is provided on the front upper portion of a banknote arranging device (hereinafter, referred to as a device) 100. ing. Reference numeral 2 denotes a discrimination unit for performing discrimination and counting of bills M, authenticity, denomination, correctness, front and back, etc., and detecting conveyance abnormality, and is provided in the apparatus 100. Reference numeral 3 denotes a conveyance path of the banknote M. The conveyance path 3 will be described later. Reference numeral 4 denotes a front / back reversing unit for reversing the front and back of the banknote M, and is provided to be positioned downstream (downstream) of the discrimination unit 2 in the apparatus 100.

Reference numeral 5 denotes an open pocket for accumulating banknotes M of denominations not to be bound, and is provided on the upper surface of the apparatus 100. The banknotes M accumulated in the open pocket 5 can be directly accessed by an operator. Yes. Reference numeral 6 denotes a stacking mechanism. In the first embodiment, the stacking mechanism 6 includes four stacking units (hereinafter referred to as temporary stacking units) 6a to 6d arranged in one column in the apparatus 100. In the temporary stacking units 6a to 6d, a predetermined number of sheets, for example, in the first embodiment, 100 banknotes M can be stacked. Note that the number of temporary stacking units is not limited to four but may be three or more.

Reference numeral 7 denotes an operation unit provided on one side of the insertion unit 1. The operation unit 7 includes a count start button 7 a for instructing counting of the banknote M, a completion button 7 b for instructing completion of counting and bundling processing, and the apparatus 100. There is provided a reset button 7c for restarting at the time of failure recovery. Reference numeral 7d denotes a status display lamp which emits green light during operation and red light during an alarm.
Reference numeral 8 denotes a discrimination unit 2, which is a reject pocket for collecting reject banknotes Mr. whose denomination has been identified or whose conveyance abnormality has been detected. The reject pocket 8 is provided above the input unit 1, and is accumulated in the reject pocket 8. The operator can directly access the rejected banknote Mr. Reference numeral 9 denotes a transfer mechanism, and reference numeral 10 denotes a banknote binding mechanism as a binding unit, both of which are provided in the apparatus 100, both of which will be described later.

11 is a banknote bundle outlet, and 12 is a door provided in front of the apparatus 100. By opening the door 12, the operator can access the stacking mechanism 6. An operation display unit 13 is provided on the upper surface of the apparatus 100 so as to be positioned behind the open pocket 5, and is configured by an LCD and a touch panel arranged on the surface thereof. The operator operates the operation display unit 13 by operating the operation display unit 13. The mode is specified, and the denomination and stacking order of the banknotes M stacked in the temporary stacking units 6a to 6d are set. The operation display unit 13 also displays the denomination, correctness, and counting result of the banknote M identified by the discrimination unit 2.
A display example of the operation display unit 13 will also be described later.

Here, the conveyance path 3 will be described.
In the upper part of the apparatus 100, the conveyance path 3 is composed of conveyance paths 3 a to 3 d as shown in FIG. 4, and the conveyance path 3 a is provided so as to reach the branch point A from the input part 1 through the discrimination part 2. The path 3b is provided from the branch point A to the reject pocket 8.
Further, the conveyance path 3c is provided so as to reach the branch point B from the branch point A through the front / back inversion portion 4. The conveyance path 3d extends from the branch point B from the arrow G shown in FIG. 4 to the lower part of the apparatus 100 and is provided along the temporary accumulation units 6a to 6d of the accumulation mechanism 6. Further, the conveyance path 3e extends from the branch point B. It is provided to reach the open pocket 5. In addition, a switching blade (not shown) that switches the conveyance direction of the banknote M is provided in the vicinity of each of the branch points A and B, and the operation is controlled by a control unit that will be described later.

FIG. 6 is a side view of the stacking mechanism according to the first embodiment of the present invention. In the stacking mechanism 6, the four temporary stacking units 6a to 6d are arranged in the vertical direction as described above, and these temporary stacking units 6a to 6d have the same structure. The temporary accumulation unit 6a will be described as an example. The banknote M transported by the transport path 3d is taken toward the stacking plate 21 by the sorting gate 27 of the temporary stacking unit 6a, whereby the banknote M that has entered the temporary stacking unit 6a is hit by the tapping wheel 20 at the rear. Are stacked on the stacking plate 21. Moreover, the banknote M which invades after that is integrated | stacked on the banknote M integrated | stacked on the stacking board 21 by the same operation | movement.

FIG. 7 is a perspective view of the temporary stacking unit according to the first embodiment of the present invention. The banknote M (not shown) that has entered the temporary stacking unit 6a is not only struck by the tapping wheel 20, but is also aligned in the longitudinal direction by the longitudinal positioning mechanism 22 provided on one side of the temporary stacking unit 6a. Further, the position in the short direction is aligned by the short positioning mechanism 23 provided on the front end side of the temporary stacking unit 6a.

Here, the longitudinal positioning mechanism 22 includes a motor 22a capable of rotating in both forward and reverse directions, and a positioning member 22c such as a bar or plate connected to the motor 22a via a connecting member 22b. By timing the detection signal of an incoming sensor (not shown) that detects the incoming bill M, the positioning member 22c is rotated by the motor 22a, thereby pressing the bill M against the reference surface 25 installed on the opposite side. Rank.

The short positioning mechanism 23 is composed of a rod-like member biased by a biasing means such as a torsion spring (not shown), and aligns by biasing the accumulated bills M toward the entrance side. It has become. When the banknotes M are stacked on the stacking plate 21, and it is detected that the stacking height exceeds a reference value by a height sensor (not shown), the stacking plate 21 is automatically lowered and the space of the temporary stacking unit 6a. By this operation, stable stacking can be performed even if the stacking height changes depending on the state of the banknote M caused by wrinkles, creases, and the like.

A presser plate 24 is provided above the stacking plate 21 so as to face the presser plate 24. The presser plate 24 stands by above the temporary stacking unit 6a during the stacking of the bills M on the stacking plate 21, and is sequentially taken in. It does not interfere with the entry of the banknote M. When a predetermined number of banknotes M, for example, 100 banknotes M, are stacked on the stacking plate 21 of the temporary stacking unit 6a, the sorting gate 27 is operated so as not to take in the banknotes M. The banknote M is controlled so as to be stacked on any one of the temporary stacking units 6b to 6d.

In the temporary stacking unit 6a where the banknote M has stopped entering, the stacking plate 21 is raised and the presser plate 24 is lowered to hold the banknote M. By this operation, the thickness of the banknotes M having different stacking heights is made constant according to the state of the banknotes M such as bags, and delivery to the transfer mechanism 9 is facilitated. A bill M clamped by the stacking plate 21 and the presser plate 24 is pulled out by a bill clamp portion of the transfer mechanism 9 described later entering the temporary stacking portion 6a from the short positioning mechanism 23 side. At this time, the short positioning mechanism 23 is configured to be retractable so as not to hinder the pulling operation. Although it is not shown in the present invention, it is a retraction structure by rotation in the horizontal direction, but it may be retractable downward.

Since the temporary stacking units 6b to 6d have the same structure as the temporary stacking unit 6a, the banknotes M can be aligned, stacked, and sandwiched similarly to the temporary stacking unit 6a.
FIG. 8 is a perspective view of the transfer mechanism according to the first embodiment of the present invention. The transfer mechanism 9 includes a bill clamp unit 30, a clamp unit moving unit 31, and a vertical movement unit 32.
The banknote clamp part 30 has clamp claws 35 a and 35 b that open and close in the vertical direction. The banknote clamp part 30 is mounted on the clamp part moving means 31. When the banknote M is clamped and pulled out by the clamp claws 35a and 35b from the temporary stacking sections 6a to 6b, the clamp moving means 31 pushes the banknote clamp section 30 against the temporary stacking sections 6a to 6b, and 100 banknotes M Can be moved to a position where it can be clamped.

The banknote clamp part 30 and the clamp part moving means 31 are moved up and down by the vertical movement means 32 using a stepping motor (not shown) as a drive source between the temporary stacking parts 6a to 6d, and the temporary stacking part 6a after 100 banknotes have been stacked. It is controlled to stop corresponding to any one of ˜6b. Therefore, position sensors 33a to 33d are arranged in the frame of the vertical movement means 32 corresponding to the positions of the temporary stacking units 6a to 6d. For example, the banknotes M stacked in the temporary stacking unit 6a When extracting, the clamp part moving means 31 is pulled up by the vertical movement means 32 to the position of the position sensor 33a.

Since the clamp part moving means 31 pulled up needs to be fixed at this position while the banknote clamp part 30 pulls out the banknote M from the temporary stacking part 6a, the stopper cam 34 that can be rotated at the position stopped by the position sensor 33a is provided. It is locked to the clamp part moving means 31 to prevent the movement.
A series of operations of the transfer mechanism 9 will be described. For example, when the banknote M accumulated in the temporary stacking unit 6a is pulled out, the banknote clamping unit 30 is first moved to the position of the position sensor 33a together with the clamp unit moving unit 31 by the vertical movement unit 32. The movement is stopped and the movement is stopped at the position where the position sensor 33 a detects the clamp part moving means 31, and at the same time, the stopper cam 34 is rotated and locked to the clamp part moving means 31.

As a result, the clamp part moving means 31 is fixed at a position corresponding to the temporary stacking part 6a. In this state, the clamp claws 35a and 35b of the bill clamp part 30 are opened in the vertical direction by the clamp moving means 31, and 100 banknotes M are opened. Preparation for clamping is performed, and the banknote clamp unit 30 is further pushed out in the direction of the temporary stacking unit 6a by the clamp unit moving means 31.

The clamp claws 35 a and 35 b of the pushed bill clamp part 30 are inserted into an opening provided on the short positioning mechanism 23 side of the temporary stacking part 6 a and are sandwiched between the stacking board 21 and the presser board 24. The banknote M is clamped from above and below. Next, when the stacking plate 21 and the presser plate 24 are opened to release the holding of the banknote M by both, the 100 banknotes M are passed to the banknote clamping unit 30. The bill clamp part 30 that holds the bill M at 35 b is pulled back by the clamp part moving means 31.

At this time, the bill M held by the clamp claws 35a and 35b hits the short positioning mechanism 23 of the temporary stacking portion 6a. However, when the bill clamping portion 30 is pulled back as it is, the short positioning mechanism 23 is attached by the pressing force of the bill M. The banknote M is withdrawn from the temporary stacking portion 6a smoothly by falling in the direction opposite to the orientation direction against the biasing means. And when the banknote clamp part 30 is pulled back to the original position, the stopper cam 34 latched to the clamp part moving means 31 is rotated, and the latching is released. Subsequently, the clamp moving means 31 is moved by the vertical movement means 32 to the banknote binding mechanism 10 located at the lowermost end of the moving path together with the banknote clamp section 30 holding the banknote M, and the clamp claws 35a and 35b of the banknote clamp section 30 are moved. The gripped banknote M is delivered to the banknote binding mechanism 10.

FIG. 9 is a side view of the banknote bundling mechanism according to the first embodiment of the present invention. The banknote bundling mechanism 10 as a bundling unit includes a conveyance unit 40 including rollers and a belt, a tape 41 for bundling with a paper tape, a printing unit 42, a tape supply unit 43 for supplying the tape 41, and a tape 41. And a binding means (not shown). The rollers and belts constituting the conveying means 40 can be moved up and down by means not shown in the direction of the arrow H, and are constructed so as to be able to be conveyed even if the number of banknotes M to be sealed is about 70. .

The banknote binding mechanism 10 binds the banknotes M as follows.
First, the transport means 40 collectively receives 100 banknotes M from the banknote clamp part 30 of the transfer mechanism 9 (arrow I), rotates the roller and the belt in the arrow J direction, and moves the banknote M in the arrow K direction. Then, transport to the binding position.
Continuously, the tape supply means 43 supplies the tape 41 in the arrow L direction. A bundling means (not shown) seals the banknote M. At that time, the printing unit 42 prints the denomination of the banknote M to be bundled by the tape 41, a specific mark (identification mark) in the case of a fractional banknote bundle, and the like via the ink ribbon. The printed tape 41 is cut to a predetermined length by the cutter 44, and the cut tape 41a is wound around the 100 bills M transported to the binding position by the binding means to form a bill bundle. .
The banknote bundle thus created is further conveyed in the direction of arrow N by the conveying means 40 and sent to the discharge port 11.

FIG. 10 is a block diagram illustrating a control system according to the first embodiment of the present invention.
50 is a control unit that controls the operation processing of the entire apparatus 100, 51a to 51d are counters, and the counters 51a to 51d correspond to the temporary accumulating units 6a to 6d on a one-to-one basis, for example, accumulated in the temporary accumulating unit 6a. The number of the banknotes M is counted by the counter 51 a and is counted up every time it is placed on the stacking plate 21. Similarly, the number of banknotes M accumulated in the temporary stacking unit 6b is counter 51b, the number of banknotes M stacked in the temporary stacking unit 6c is counter 51c, and the number of banknotes M stacked in the temporary stacking unit 6d is counter 51d. Be counted.
A storage unit 52 stores the denominations of the banknotes M accumulated in the temporary stacking units 6a to 6d, the number of banknotes M counted for each denomination, and the like, and includes a semiconductor memory or HDD. . Since the storage unit 52 is backed up by a battery or the like, the stored contents are retained even when the power is shut off. In addition, 2 is the discrimination part mentioned above.

FIG. 11 is an explanatory diagram illustrating an example of an initial setting screen according to the first embodiment of this invention.
The figure shows a mode selection screen 131 in the initial setting screen displayed on the operation display unit 13. In the figure, an input frame 131a is provided with an online key and an offline key in order to set whether the operation of the apparatus 100 is performed offline or connected to the host apparatus, that is, performed online.
The input frame 131b has a deposit key for setting the deposit mode and an organize key for setting the organize mode. The deposit mode is a mode in which a cash deposit transaction is performed, the banknote M is counted, and a result obtained by classifying and counting each transaction number, a specified category, and the like is stored in the storage unit 52. In this mode, the result of classification and aggregation is not stored in the storage unit 52.

The input frame 131c is provided with a count key and a sealing key. When the count key is pressed, the input frame 131c enters the count mode, and the bill M set in the input unit 1 is conveyed to the discrimination unit 2 for denomination discrimination and counting. The counting mode is not related to the present invention and will not be described.
When the sealing key is pressed, the sealing mode is entered, the banknote M set in the input unit 1 is conveyed to the discrimination unit 2, denomination discrimination and counting are performed, and the temporary accumulation units 6 a to 6 d are accumulated. The operation setting automatically seals a predetermined number of banknotes M.

The input frame 131d is provided with a (non-sealing) key and a (sealing) key for setting whether or not to perform fractional sealing, and whether or not there is a fractional sealing operation depending on the selection of this key. Can be set.
The input frame 131e is a part for selectively inputting whether the fraction sealing mode is the full denomination type fraction mode or the mixed denomination mode. When all denomination keys are selected, all denominations are in fraction mode, and each denomination is sealed independently, and when mixed keys are selected, it is in mixed denomination mode, summing the denominations of denominations, The control unit 50 calculates and selects a combination that is equal to or less than the predetermined number, and sealing is performed based on the combination.

For example, if the fraction of a 10,000 yen bill (denoted as Mm) is 30 and the fraction of a thousand yen bill (denoted as Ms) is 50, the total number is within a predetermined number (100). Sealing is performed by combining the fractions of the 10,000 yen bill Mm and the thousand yen bill M together, that is, 80 bundles.
On the other hand, when the fraction of the 10,000 yen bill Mm is 70 and the fraction of the thousand yen bill Ms is 50, the total number exceeds the predetermined number (100), that is, the 10,000 yen bill Mm and the thousand yen bill. Since the total Ms is 120, sealing is not performed with the fractions together, but each is sealed alone.

The input frame 131f is a part where the ticket type to be processed by the apparatus 100 can be designated, and includes a designation key, a correct note key, a damage ticket key, a damage key, and a mixed key.
When the designated key is pressed, the designated denomination bundling mode is set, and all four denominations are organized and tied together at the same time, but from the input screen not shown, 10,000 yen, 1,000 yen, 5,000 yen, 2,000 yen By arbitrarily depressing each of the buttons and specifying the denomination, the banknotes M of the single denomination and the two denominations can be bound.

When the correct ticket key is pressed, the correct ticket classification and binding mode is set, and the correct tickets of all four denominations are arranged and bound. However, although it is basically four denominations, you can specify the denomination by specifying the denomination by arbitrarily pressing the 10,000, 1,000, 5,000, and 2,000 yen buttons from an input screen (not shown). Binding of banknotes M of denomination and two denominations is also possible.
When the non-use key is pressed, the non-use card classification and bundling mode is set, and only the banknotes determined to be non-use by the discrimination unit 2 are collected and bundled.
When the correct / incorrect key is pressed, the correct / invalid ticket classification / bundling mode is entered, and the basic process is to classify and bind the correct / incorrect losses of 10,000 yen bills Mm and 1000 yen bills Ms. By depressing each button of 2,000 yen arbitrarily and specifying the denomination, it is possible to specify a single denomination and two denominations. The banknote M is discriminated against damage, but the level can be designated by a numerical value indicating the degree of contamination set in advance in the range of 0 to 9, and the designated damage level is used as a discrimination reference value, which is less than the reference value. Is identified as a genuine ticket, and a standard value or higher is identified as a non-performing ticket. In the correct / injured ticket classification and binding mode, the banknotes M determined to be correct or damaged by the discriminating unit 2 are accumulated and bound respectively.

When the mixed key is pressed, the mixed bundling mode is set. For example, the designated denominations and the number of the denominations are collected and sealed together. In addition, since there is a limit (for example, 100 sheets), it goes without saying that the number of sealed sheets is arranged as a plurality of small bundles.
The normal sealing mode key 131g registers in advance processing modes that are frequently set, and when this key is pressed, the setting information stored in advance in the storage unit 52 is read out automatically. The operation mode is specified.

The abbreviated registration key 131h can be registered by adding a code (for example, 01, 02,...) To an operation mode pattern having a high setting frequency from among a plurality of operation modes. The characteristic operation mode pattern can be recorded.
The confirmation key 131i is pressed when each input key from the input frames 131a to 131h is pressed or when the displayed initial setting is acceptable, and the control unit 50 detects the signal pressed by the confirmation key 131i. This completes the setting.
Needless to say, the cancel key 131j is pressed when canceling each setting from the input frames 131a to 131h. When the key is pressed once, the control unit 50 controls to return to the previous step.

Next, the effect | action of the structure mentioned above is demonstrated. FIG. 1 is an operation flowchart of the first embodiment of the present invention, and S means an operation step. Also, it is assumed that 10,000 yen banknote Mm and thousand yen banknote Ms are designated as denominations to be bundled, and a bundle of banknotes that does not cause problems in the creation and subsequent handling is referred to as a “predetermined number”. The number of sheets is “80 to 100”. A bundle that is not in the fractional state is referred to as “a certain number”, and the number is “100”.
S1: When the apparatus 100 is turned on, the control unit 50 causes the operation display unit 13 to display a mode selection screen 131 as an initial setting screen. Each mode key on the initial setting screen is pressed to select.
S2: The operator sets the banknote M in which a plurality of denominations are mixed (should be a 10,000 yen banknote Mm and a thousand yen banknote Ms, but has not been identified as the banknote M) in the input unit 1 and operates. When the count start button 7a disposed in the section 7 is pressed, the banknote M starts to be taken into the transport path 3a.

S3: The control part 50 controls the whole apparatus 100, and first discriminate | determines the banknote M in the discrimination part 2. FIG. The true bills and the bills M discriminated from the thousand yen bill Ms or the 10,000 yen bill Mm are counted and transported to the front / back reversing section 4 by the transport path 3c regardless of the result of discrimination of the damage. Further, the banknote M that has been identified as having an unknown denomination or has been detected to be transported is transported from the branch point A to the transport path 3b reject pocket 8.

S4: After the front and back reversing part 4 is aligned, it is transported to the stacking mechanism 6 by the transport path 3d and stacked on the temporary stacking units 6a to 6d. For example, the temporary stacking unit 6a has a correct bill of 10,000 yen banknote Mm, the temporary stacking unit 6b has a slip of 10,000 yen bill Mm, and the temporary stacking unit 6c has a correct bill of 1000 yen bill Ms temporarily. In the stacking unit 6d, a slip of a thousand yen bill Ms is stacked. The number of 10,000 yen banknotes Mm and thousand yen banknotes Ms accumulated in the temporary stacking units 6a and 6c is counted by the counters 51a and 51c, and the number of banknotes M stacked in the temporary stacking units 6b and 6d is counted by the counters 51b and 51d. Be counted. That is, the value of the counters 51 to 51d is added by “1” by the control unit 50 to the sheets on which one banknote M is stacked on the temporary stacking units 6a to 6d. Further, when the banknote M is taken in and the banknotes M accumulated in the temporary stacking unit 6a reach 100 sheets, if there is a temporary stacking unit having no stacking number, the 101st sheet ( The temporary stacking unit is stacked from the first sheet).

S5: Uptake is performed until a detector (not shown) detects that all the banknotes M present in the insertion unit 1 have disappeared (no banknotes). When the banknote M runs out of the insertion unit 1, the control unit 50 displays on the operation display unit 13 whether or not additional insertion is performed, and accepts additional insertion.
S <b> 6: When the detector (not shown) detects that the bill M has run out in the insertion unit 1, the control unit 50 displays the count result on the operation display unit 13. This display may be changed (counted up) every time the banknote M is accumulated in the temporary accumulation units 6a to 6c.

S7: The control unit 50 monitors the number of stacked 10,000 yen banknotes Mm and 1000 yen banknotes Ms accumulated in the temporary stacking units 6a to 6b in parallel, and when the number reaches a certain number (100 sheets), the next step S8 is performed. If the predetermined number of sheets is not reached, the counting of the banknote M after step S3 is continued as it is.

S8: The banknotes M stacked 100 in the temporary stacking units 6a to 6d are sealed.
This sealing operation will be briefly described by taking as an example the 10,000 yen bill Mm accumulated in the temporary accumulation unit 6a. First, when 100 million yen banknotes Mm are accumulated in the temporary stacking unit 6a, the 100 million yen banknotes Mm are extracted by the transfer mechanism 9, and the banknotes are indicated by thick arrows C to F in FIG. It is transferred to the bundling mechanism 10, sealed to one banknote bundle by the banknote bundling mechanism 10, and discharged from the discharge port 11. That is, when 100 million yen bills Mm are accumulated in the temporary stacking unit 6a, the taking of the bills M from the loading unit 1 is temporarily stopped, the transfer mechanism 9 moves in the direction of arrow C, and 100 million yen bills are collected. After gripping Mm and returning to the direction of arrow D and further descending in the direction of arrow F and being positioned at a position corresponding to the banknote bundling mechanism 10, 100 million yen bills Mm are collectively moved from the moving mechanism 9 to the direction of arrow C. To the banknote bundling mechanism 10.

The control unit 50 resumes taking in the banknotes M from the input unit 1 when the moving mechanism 6 collectively collects the 100 million yen banknotes Mm from the temporary stacking unit 6a.
The delivered ten thousand yen banknotes Mm are bundled into one by a banknote binding mechanism 10 using a paper tape sealing band and discharged as a banknote bundle from the discharge port 11.
In addition, characters such as a financial institution name, a store name, a denomination, the number of sheets, a total amount, a sealing date, and a serial number are displayed on the band for sealing immediately before sealing by the printing means provided in the banknote binding mechanism 10. Information is printed.

S9: When the completion button 7b of the operation unit 7 is pressed, the control unit 50 checks whether or not the money type sealing mode is selected when the fraction sealing mode is selected.
When the denomination sealing mode is selected, the control unit 50 calculates and displays the number of paper sheets (hereinafter also referred to as simulated media) Md necessary for a predetermined number of sheets that can be handled as a bundle from the number of denominations. To do. Here, the simulated medium Md is a paper sheet having a paper quality substantially equivalent to that of the 10,000 yen banknote Mm, but printing is assumed to be a plain color or a character and a picture that cannot assume a banknote.
S10: Next, the control unit 50 checks whether it is allowed to leave a rose as a fraction processing or to seal it. When the money type sealing mode is selected, the process proceeds to step S11. This denomination mode is a mode in which each denomination is sealed independently. In the mixed denomination mode, the denominations of the denominations are summed, and sealing is performed based on a combination that falls within a predetermined number. Become.

S11: The control unit 50 determines whether the denomination fraction mode is the mixed denomination mode.
In the case of the money type fraction mode, the difference from the predetermined number (80) is calculated with respect to the fraction of each money type, that is, the number of banknotes accumulated in the temporary storage units 6a to 6d.
For example, when the fraction of the 10,000 yen bill Mm is 30 and the fraction of the thousand yen bill Ms is 45, the difference between the predetermined number (80) and the accumulated number (30) of the 10,000 yen bill Mm is 50. It becomes a sheet. Similarly, in the case of the fraction (45 sheets) of the thousand yen bill Ms, the difference is 35 sheets. This difference number is calculated as the number of simulated media Md to be added (50 + 35 = 85 sheets). If the fraction is within a predetermined number (80 to 100), the number of simulated media Md to be added is 0 (zero).
Further, in the mixed denomination mode, the control unit 50 selects a combination that adds up the fractions of the denominations and falls within a predetermined number. (Described in step S13)

S12: The control unit 50 displays the calculated quantity of the simulated medium Md on the operation display unit 13. For example, in the above example, “Please insert 85 or more simulated banknotes” is displayed as the total number of simulated media Md50 on the 10,000 yen banknote Mm side and 35 simulated media Md on the 1000 yen banknote Ms side.
S13: The control unit 50 in the mixed denomination mode selects a combination that adds up the fractions of the denominations and falls within a predetermined number, and performs sealing based on the combination. For example, when the fraction of a million yen bill Mm is 30 and the fraction of a thousand yen bill Ms is 45, since the total number is within a predetermined number (80 to 100), the 10,000 yen bill Mm and the thousand yen The bills Ms are rounded together (75 in total), and five sheets of simulated media Md are further added for sealing. Detailed description will be given later.
Further, when the fraction of the 10,000 yen bill Mm is 70 and the fraction of the thousand yen bill Ms is 50, the total number exceeds the predetermined number (100), so the 10,000 yen bill Mm and the thousand yen bill Ms. Are not sealed together, and 10 and 30 simulated media Md are added to each of them and sealed individually. The above number information is stored in the storage unit 52 for each of the temporary accumulation units 6a to 6d.

S14: When the operator sets the simulated medium Md of the quantity displayed on the operation display unit 13 in the input unit 1 and presses the count start button 7a disposed on the operation unit 7, the intake of the simulated medium Md is started.
It should be noted that the number of simulated media Md to be input does not have to be accurately counted and can be additionally input. Accordingly, the approximate thickness of the simulated medium Md to be inserted may be, for example, “40 simulated banknotes, approximately total thickness of about 5 mm inserted”.
S15: The control unit 50 separates the simulated medium Md set in the loading unit 1 and conveys it inside. At this time, every time it passes through the discrimination unit 2, it detects true / false, denomination, front / back, correct / injury, double feed, etc., as with the banknote M. Without being transferred to the reject pocket 8, it is transferred to the temporary accumulating units 6a to 6d. Even if it is determined to be “double feeding”, it may be managed as “one sheet” for counting and may be conveyed to the temporary stacking units 6a to 6d.

S16: The control unit 50 accumulates the simulation medium Md in the temporary accumulation units 6a to 6d until it matches the number information of the simulation medium Md stored in the storage unit 52. For example, when the fraction of the 10,000 yen bill Mm is 30 and the fraction of the thousand yen bill Ms is 45, the temporary stacking unit 6a in which 30 million yen bills Mm are stacked has 50 sheets. The simulated medium Md is accumulated. In addition, 35 simulation media Md are accumulated in the temporary accumulation unit 6c in which 45 thousand yen bills Ms are accumulated. This order of accumulation may be from either the 10,000 yen banknote Mm side or the thousand yen banknote Ms side.

The control unit 50 calculates the total number of sheets each time the simulated medium Md is accumulated in the temporary accumulation units 6a to 6d, and operates until the predetermined number (80 sheets) is reached. Here, when there is no simulated medium Md in the input unit 1, the operation display unit 13 displays to prompt additional input. Here, when the operator additionally inputs the simulated medium Md and presses the count start button 7a disposed on the operation unit 7, the taking-in of the simulated medium Md is started again.

S17: The banknote M of the temporary stacking unit 6 that has reached a predetermined number (80 sheets) is pulled out of the temporary stacking units 6a to 6d by the transfer mechanism 9 and sent to the banknote binding mechanism 10 and sealed as described above. Thereby, for example, since the temporary stacking unit 6a is in an empty state, when the stacking number of bills M of the temporary stacking unit 6c or 6d newly reaches 100, switching to the empty temporary stacking unit 6a is performed. Is possible. At this time, the value of the counter 51a is cleared (zero) (the value of the counters 51b to 51d is also cleared when the banknote M of the temporary stacking units 6b to 6d is extracted).

The control unit 50 immediately before sealing by the printing means, character information such as financial institution name, store name, denomination, number of sheets, total amount, sealing date and serial number, and a mark that means a fractional banknote bundle P is printed. This printing is controlled so as to be positioned on the side end face of the bundle in a sealed state as shown in FIG.
At this time, the bundle of the 10,000 yen bill Mm and the thousand yen bill Ms is sealed in a state where the simulated medium Md is combined into 80 sheets, so that it can be properly sealed.
The banknote binding mechanism 10 receives a bundle of 80 sheets (the banknote M and the simulated medium Md) from the transfer mechanism 9, binds the received bundle with tape as described above, and discharges it from the discharge port 11 as a mixture Mz. In this way, the fraction sealing process is completed.

S18: If it is determined in step S10 that the fractional banknote is in an operation mode that the roses may remain loose, the removal is instructed by opening the doors 12 of the temporary stacking units 6a to 6d. By the above sealing operation, the mixture Mz becomes a state as shown in FIG. In FIG. 12A, the simulated medium Md is overlaid on the upper layer of the thousand-yen banknote Ms and bound by a tape. As illustrated, the mark P is located on the side surface of the mixture Mz. In FIG. 12B, a thousand yen bill Ms is placed on the 10,000 yen bill Mm, and the simulated medium Md is further superimposed on the upper layer and bound by a tape.

Next, the operation as the mixed sealing mode will be described. Here, the fraction of the 10,000 yen bill Mm is 30 in the temporary stacking unit 6a, the fraction of the thousand yen bill Ms is 45 in the temporary stacking unit 6c, and the total number is within a predetermined number (80 to 100). For this reason, the process of mixing and sealing shown in FIG. 13 is taken as an example of sealing by adding five simulated media Md together with the fractions of the 10,000 yen banknote Mm and the thousand yen banknote Ms together (total 75 sheets). This will be described in combination with the explanatory diagram.

FIG. 13 is an explanatory diagram of an operation process of mixed sealing according to the first embodiment of the present invention. The control unit 50 takes in the simulated medium Md set in the input unit 1 for the 10,000 yen bill Mm (at this time, 30 sheets) accumulated in the temporary accumulation unit 6a, and the count value “35” of the counter 51a. It works until it becomes. That is, the five simulation media Md are stacked so as to be stacked on the 10,000 yen bill Mm of the temporary stacking unit 6a.
This integration operation itself is the same as a normal integration operation. The controller 50 stops the operation at the count value “35” of the counter 51a.

Then, the clamp part moving means 31 is controlled, and the banknote clamp part 30 is positioned by the detection signal of the position sensor 33a in the temporary stacking part 6a. That is, the bill clamp part 30 is moved up and down in the direction of arrow E or F shown in FIG. When positioned in the temporary stacking unit 6a, the short positioning mechanism 23 is rotated and retracted to the right, and the banknote clamp unit 30 is moved in the direction of arrow C (FIG. 3) to clamp the banknotes on the temporary stacking unit 6a. To do.
The banknote clamp part 30 which hold | gripped the banknote bundle is moved to the arrow D direction. The gripping operation itself of the banknote clamp unit 30 so far is the same as the normal gripping operation except for the rotation and retraction of the short hand positioning mechanism 23.
The reason why the short positioning mechanism 23 is rotated and retracted is to prevent the stacking position deviation or the like from occurring when the number of banknotes M to be pulled out is small.

The control unit 50 changes the operation amount of the clamp unit moving means 31 so as to reduce the lowering operation amount from the detection of the position sensor 33a in the lowering operation of the banknote clamp unit 30. That is, in the normal lowering operation, if the position sensor 33c stops at the detection position, the stop corresponding to the temporary stacking unit 6c is performed, but the upper part of the thousand yen bill Ms already stacked on the temporary stacking unit 6c. In order to put it on, the stop is above the normal position.
When stopped, the stopper cam 34 is rotated and, as shown in FIG. 13A, the presser plate 24 of the temporary stacking portion 6c is opened in the direction of the arrow U, and a space is secured on the thousand yen bill Ms. At the same time, the short positioning mechanism 23 is rotated and retracted to the right (arrow W direction).

The control unit 50 moves the banknote clamp unit 30 in the direction of arrow C shown in FIG. 13B while holding the banknote bundle, and holds the simulated medium Md and the 10,000 yen banknote Mm on the stacked 1000 yen banknote Ms. Position it as it is.
Once positioned, the short positioning mechanism 23 is rotated in the direction of the arrow X as shown in FIG.
Subsequently, when the bill clamp part 30 is moved in the arrow D direction, the clamp claws 35a and 35b are pulled out from the thousand yen bill Ms on the stacking plate 21. At this time, the short positioning mechanism 23 becomes a wall surface that prevents the movement of the banknote bundle in the direction of arrow D as described above, so that the simulated medium Md and the 10,000 yen banknote Mm are as shown in FIG. It is piled up on the thousand yen bill Ms.

The control unit 50 raises the stacking plate 21 and lowers the presser plate 24 to grip the mixture Mz of the simulated medium Md, the 10,000 yen bill Mm, and the thousand yen bill Ms. On the other hand, the stopper cam 34 is opened, and the clamp part moving means 31 is moved (lowered) to the proper stop position corresponding to the temporary accumulating part 6c by the position sensor 33c.
Thereafter, the banknote clamp part 30 is moved in the direction of arrow C to clamp the mixture Mz on the temporary stacking part 6a and deliver it to the banknote binding mechanism 10. The control unit 50 immediately before sealing by the printing means, character information such as financial institution name, store name, denomination, number of sheets, total amount, sealing date and serial number, and a mark that means a fractional banknote bundle P is printed as described above.
In the above description, the simulated medium Md is accumulated on the 10,000 yen banknote Mm on the temporary stacking unit 6a and then placed on the thousand yen banknote Ms on the temporary stacking unit 6c. However, the present invention is not limited to this. . That is, after transferring the 10,000 yen banknote Mm from the temporary stacking unit 6a onto the thousand yen banknote Ms on the temporary stacking unit 6c, the simulated medium Md may be stacked in the temporary stacking unit 6c. Further, the thousand yen banknote Ms on the lower temporary stacking unit 6c side may be placed on the 10,000 yen banknote Mm of the upper temporary stacking unit 6a although the stacking position is changed.

As described above, since the banknote mixture is bundled in the order of the simulated medium / 10,000 yen banknotes / thousand yen banknotes from the top layer, the banknotes can be easily visually recognized and classified later when the banknotes are removed from the band. It has become.
In addition, when bundling fractional banknotes of multiple denominations, the simulation medium is aligned and sealed on the upper side of the multiple denominations. This makes it possible to prevent misclassification and improve workability.

Next, a modified example of the present invention will be described.
In the above-described embodiment, “80 to 100 sheets” is described as a predetermined number as the number of banknotes in a bundle that does not cause problems in the creation and handling thereafter. This “predetermined number” is experimentally obtained and set in advance, but there is a difference depending on the bill type to be processed by this apparatus. That is, it can be changed depending on the paper quality and thickness like banknote damage and overseas banknotes. In this modification, the predetermined number value is determined based on the result of the discrimination by the discrimination unit, and the predetermined number value information as shown in FIG. 14 is stored in the storage unit.

The control unit 50 determines the degree of distribution every time it passes through the discrimination unit 2. For example, unused banknotes issued by banknote issuers (the Bank of Japan in the case of Japan) (hereinafter referred to as new tickets) have high rigidity and can be sealed even with a relatively small number. In addition, there are banknotes (hereinafter referred to as circulation tickets) in which the rigidity of the banknotes themselves is lowered by folding or folding as they circulate in the market.
In this modified example, whether the ticket is a new ticket or a circulation ticket is counted, and when the fraction sealing is instructed, the predetermined number value stored in the storage unit 52 is read out, and the simulated medium This is used to calculate the additional number of Md.

Furthermore, as shown in the right column column of FIG. 14, by setting the mixing ratio of the new ticket and the circulation ticket, it becomes possible to make more detailed settings. However, assuming temperature / humidity and the performance error of the sealing arrangement mechanism, it is practically complicated to determine the predetermined number of experiments.
In this way, the number of simulated media used can be reduced as much as possible, and an apparatus for organizing various banknotes can be provided.

Next, as a second embodiment, a description will be given of an embodiment in which a simulation medium storage unit is provided in the apparatus, and a simulation medium corresponding to the additional number of sheets is fed from the storage unit to the conveyance path. FIG. 15 is a perspective view showing the external appearance of the second embodiment of the present invention, and FIG. 16 is a schematic side view showing the internal structure of the second embodiment of the present invention. In the figure, the same parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

15 is a small door provided on the side surface of the banknote sorting apparatus 101. By opening the small door 15, the operator can access the simulated medium storage unit 16, and the simulated medium storage unit 16 is the input unit 1. The bill M and the simulated medium Md can be set in a stacked state in the same manner as described above. And the banknote M and the simulation medium Md can be sent out to the conveyance path 3e by the delivery means which is not shown in figure. Note that the replenishment of the simulated medium Md to the simulated medium storage unit 16 can also be transported from the loading unit 1, and therefore temporarily suspended by loading and taking in the simulated medium Md described in the first embodiment. After the additional stacking on the unit 6, when the surplus number remains in the input unit 1, it can be taken into the simulated medium storage unit 16 and stored.

With the above configuration, for example, the control unit 50 can set “85 simulated banknotes” as the total number of simulated media Md on the 10,000 yen banknote Mm side and 35 simulated media Md on the 1000 yen banknote Ms side in the first embodiment. Instead of displaying “Please insert the above”, in the second embodiment, 85 simulated banknotes are automatically sent out from the simulated medium storage unit 16 and conveyed in the direction of arrow Q to the designated temporary storage unit 6. Accumulate. In addition, since the simulation banknote Md does not pass the discrimination part 2 as shown in the figure, even if double feeding occurs, it is conveyed to the temporary stacking part 6 as it is and is added to the banknote M. Thus, since the simulated medium storage unit 16 is provided in the apparatus 101, there is an effect that it is possible to eliminate the troublesomeness of the operator inserting the simulated banknote Md.

As described above, since the tape of the bundle of fractional banknotes is printed differently from the tape of the fixed number (100 sheets), the bundle of fractional banknotes is fixed when taken out from the cash bus, for example. It is also possible to prevent mistakes with a bundle of sheets. Needless to say, a breakdown or the like may be printed on the uppermost simulated medium as a bundling portion capable of printing on the simulated medium instead of printing on a bundle of tapes.
Furthermore, since a simulated medium is used to make a predetermined number of fractional banknotes, if a fractional banknote is pulled out of the bundle, the remaining simulated media can be used again with this device, so that efficient operation of resources is possible. Is possible.

In the present embodiment, the simulation medium has been described as an example of a simulation medium whose outer shape approximates to a 10,000 yen bill, but the present invention is not limited to this. For example, if you prepare two types of simulated media that approximate the shape of a 10,000-yen bill and a thousand-yen bill, and if you want to set the 10,000 yen fraction to a predetermined number, use the simulated media that approximates a thousand-yen bill, and specify the thousand-yen fraction When using a simulated medium that approximates a 10,000 yen banknote, the outer shape is clearly different from that of the simulated medium when pulling out fractional bills from a bundle. .

In this embodiment, an example of printing a “●” mark on the tape as a mark that can recognize a small bundle of fractional media has been described. However, the present invention is not limited to this, and various identifiable marks can be used. is there. If the ink ribbon is a multicolor ribbon, the print color can be switched to provide an identification mark having a different hue.
In addition, if the bundling tape is a bundling portion where two types of bundling tapes can be used, it is possible to replace the identification mark by changing the color of the tape and switching its use. Furthermore, it goes without saying that sticker-like labeling may be used.

It is an operation | movement flowchart of Example 1 of this invention. It is a perspective view which shows the external appearance of Example 1 of this invention. It is a schematic side view which shows the internal structure of Example 1 of this invention. It is an enlarged view of the upper part of FIG. FIG. 3 is an enlarged plan view of an operation unit in FIG. 2. It is a side view of the accumulation | storage mechanism of Example 1 of this invention. It is a perspective view of the temporary accumulation part of Example 1 of the present invention. It is a perspective view of the transfer mechanism of Example 1 of the present invention. It is a side view of the banknote binding mechanism of Example 1 of the present invention. It is a block diagram which shows the control system of Example 1 of this invention. It is explanatory drawing which shows an example of the initial setting screen of Example 1 of this invention. It is a printing example of the identification mark of Example 1 of this invention. It is explanatory drawing of the operation | movement process of the mixing sealing of Example 1 of this invention. It is a table | surface which shows the modification of Example 1 of this invention. It is a perspective view which shows the external appearance of Example 2 of this invention. It is a schematic side view which shows the internal structure of Example 2 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Input part 2 Discrimination part 3 Conveyance path 6 Stacking mechanism 6a-6d Temporary stacking part 9 Transfer mechanism 10 Binding part (banknote binding mechanism)
13 Operation Display Unit 50 Control Units 51a to 51d Counter 52 Storage Unit 100 Banknote Arrangement Device M Banknote Ms Thousand-yen Bill Mm Ten-Yen Bill Md Simulated Medium Mz Mixture

Claims (6)

A plurality of stacking units, and a binding unit for binding the banknotes stacked in each stacking unit with a tape,
The banknotes inserted from the input unit are separated and conveyed, and the discrimination unit discriminates the authenticity, denomination, correctness, etc. and counts, and the counted banknotes are respectively accumulated in the stacking unit. A banknote organizing device for sending and bundling banknotes accumulated every predetermined number to the bundling unit,
When banknotes stacked in the stacking unit is less than the predetermined number, the less than the predetermined number count was calculated as the number of the required simulated medium, the charged to the required simulating medium simulated medium to the insertion portion The paper is separated and conveyed one by one until reaching the number of sheets, and is identified by the identification unit. The necessary number of simulation media is added to the banknotes accumulated in the accumulation unit, and the predetermined number of the mixture is added to the binding unit. A banknote arranging device characterized by feeding and binding. The banknote organizing apparatus according to claim 1, wherein the simulation medium is determined as a fake ticket by the discrimination unit and added to the banknotes accumulated in the accumulation unit. When the number of banknotes accumulated in the plurality of stacking units is less than a predetermined number and the total number of the plurality of stacking units is less than the predetermined number, one sheet is inserted until the total number reaches the predetermined number The banknote organizing apparatus according to claim 1 , wherein the banknote organizing apparatus separates and conveys each of the paper sheets, and sends and bundles a mixture of banknotes and simulated media accumulated in the plurality of stacking units to the binding unit. The banknote arrangement device according to claim 2 or 3, wherein the mixed medium of the mixed body is stacked on an upper stage of banknotes stacked in a plurality of stacking units. 2. A printing means is provided in the bundling portion, and when the mixture of the fractional banknote and the simulated medium is bundled with a tape, printing capable of explicitly recognizing the bundle of the fractional medium on the tape is performed. Or the banknote arrangement apparatus of Claim 3. The banknote arranging device is provided with an operation display unit,
When the banknotes stacked in the stacking unit are less than the predetermined number, the simulated medium is inserted and separated and conveyed one by one until reaching the predetermined number of sheets, and the bundle of banknotes and simulated medium stacked in the stacking unit The bill organizing apparatus according to claim 3 or 4, wherein the banknotes can be selectively implemented by being fed to the tape, bound with a tape, and discharged.

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