WO2009096006A1

WO2009096006A1 - Bar-code ticket processing machine, bar-code ticket processing method, paper note processing machine, and paper note processing method

Info

Publication number: WO2009096006A1
Application number: PCT/JP2008/051366
Authority: WO
Inventors: Toshio Numata; Tomoyasu Sato; Tatsuya Sugano
Original assignee: Glory Ltd.
Priority date: 2008-01-30
Filing date: 2008-01-30
Publication date: 2009-08-06

Abstract

A bar-code ticket processing machine includes a holding section (30) having a bottom face (31) to hold bar-code tickets B in a bundle state, a delivery-out section (15) to deliver out a bar-code ticket B located at the undermost side among the bar-code tickets B held in a bundle state at the holding section (30), and a carriage mechanism (60) to carry the bar-code tickets B delivered out of the delivery-out section (15). To the carriage mechanism (60), pile-up sections (7, 8) are linked which pile up the bar-code tickets B carried by the carriage mechanism (60). At the lower side of the bottom face (31) on the holding section (30), a bar-code detector section (10) is provided to read out the bar-code information of the bar-code tickets B held in a bundle state at the holding section (30).

Description

Barcode ticket processing apparatus, barcode ticket processing method, paper sheet processing apparatus, and paper sheet processing method

The present invention relates to a barcode ticket processing apparatus, a barcode ticket processing method, a paper sheet processing apparatus, and a paper sheet processing method for reading barcode information of a barcode ticket.

Conventionally, the barcode information of the barcode ticket has been read by an identification unit provided in the conveyance path.

For example, in US Pat. No. 7,040,476, an apparatus for sorting and stacking banknotes and barcode tickets in which an identification unit for identifying banknotes or barcode tickets passing through the transport path is arranged in the transport path (paper sheet processing apparatus) ) Is disclosed. US Pat. No. 7,201,320 also includes a medium detector (barcode detector) for determining whether or not the currency substitute medium is valid based on at least one barcode mark of the currency substitute medium in the transport mechanism. An evaluation system (paper sheet processing apparatus) for evaluating a document is disclosed.

However, in such a paper sheet processing apparatus, the barcode information of the barcode ticket is read during conveyance. For this reason, since the barcode ticket is read in an unstable arrangement state in a short time, the reading accuracy of the barcode information of the barcode ticket is insufficient.

In general, since the barcode ticket is made of thermal paper, the barcode portion printed on the barcode ticket may be damaged when the barcode ticket is fed out. For this reason, in such a case, the barcode information may be erroneously read by the identification unit or the medium detector described above.

Furthermore, in such a paper sheet processing apparatus, since it is necessary to provide a detection unit for reading the bar code information of the bar code ticket in the transport path, the size of the paper sheet processing apparatus has become large.

By the way, Japanese Patent Application Laid-Open No. 3-30912 is provided with a detection unit that is provided in the banknote loading unit and detects the characteristic part of the frontmost banknote of the loaded banknote while the banknote is stationary. Is disclosed. However, the detection unit in Japanese Patent Laid-Open No. 3-30912 is used for predicting the denomination of the banknote, and does not read the barcode information of the barcode ticket. And since the detection part in Unexamined-Japanese-Patent No. 3-30912 reads the color tone of the whole banknote surface, it is thought that the thing like a camera is used.

The present invention has been made in consideration of the above points, and can read barcode information of a barcode ticket with high accuracy and can be reduced in size, and the barcode ticket processing apparatus and paper sheets can be reduced in size. It is an object of the present invention to provide a processing apparatus, a barcode ticket processing method using such a barcode ticket processing apparatus, and a paper sheet processing method using a paper sheet processing apparatus.

The barcode ticket processing apparatus according to the present invention
An accommodating portion for accommodating a barcode ticket having a bottom surface in a bundle;
A payout unit for feeding out the barcode ticket located at the lowest position among the barcode tickets stored in a bundled state in the storage unit;
A transport mechanism for transporting the barcode ticket fed out by the feeding unit;
A stacking unit connected to the transport mechanism and configured to stack the barcode ticket transported by the transport mechanism;
A barcode detection unit that is arranged below the bottom surface of the storage unit and reads barcode information of a barcode ticket stored in a bundled state in the storage unit;
It has.

In the barcode ticket processing apparatus according to the present invention,
It is preferable that the bar code detection unit includes a laser sensor.

In the barcode ticket processing apparatus according to the present invention,
It is preferable that the bar code detection unit includes a line sensor.

In the barcode ticket processing apparatus according to the present invention,
When the bar code ticket cannot be identified based on the bar code information of the bar code ticket read by the bar code detecting unit, the feeding unit rewinds the bar code ticket, and the bar code detecting unit It is preferable that the barcode information of the barcode ticket fed back by the feeding unit is read again.

In the barcode ticket processing apparatus according to the present invention,
The feeding unit preferably feeds the barcode ticket when the barcode ticket can be identified based on the barcode information of the barcode ticket read by the barcode detection unit.

In the barcode ticket processing apparatus according to the present invention,
A reject unit coupled to the transport mechanism and configured to stack the barcode ticket that is not stacked on the stacking unit; and the feeding unit is configured to receive the barcode ticket when a reading time by the barcode detection unit has exceeded a predetermined time. It is preferable that the transport mechanism guides the barcode ticket to the reject unit.

In the barcode ticket processing apparatus according to the present invention,
It is preferable that the apparatus further includes a conveyance abnormality detection unit that is provided in the conveyance mechanism and detects a conveyance abnormality of the barcode ticket conveyed by the conveyance mechanism.

In the barcode ticket processing apparatus according to the present invention,
Preferably, the barcode detection unit reads barcode information of a barcode ticket located at the lowest position among barcode tickets stored in a bundled state in the storage unit.

The barcode ticket processing method according to the present invention includes:
An accommodating portion having a bottom surface, a feeding portion for feeding out the barcode ticket, a conveying mechanism for conveying the barcode ticket, a stacking portion connected to the conveying mechanism, and a barcode disposed below the bottom surface of the accommodating portion. In a barcode ticket processing method using a barcode ticket processing apparatus including a detection unit,
A housing step of housing the barcode ticket in a bundled state by the housing portion;
A barcode detection step of reading barcode information of barcode tickets stored in a bundled state in the storage unit by the barcode detection unit;
A feeding step of feeding out the barcode ticket located at the lowest position among the barcode tickets stored in a bundled state in the storage unit by the feeding unit;
A transporting step of transporting the barcode ticket fed out by the feeding unit by the transporting mechanism;
A stacking step of stacking the barcode ticket transported by the transport mechanism by the stacking unit;
It has.

In the paper sheet processing method according to the present invention,
In the feeding process, when the reading time by the barcode detection unit has passed a predetermined time or more, a barcode ticket is fed out by the feeding unit,
In the transporting process, it is preferable that the barcode ticket is guided to a reject unit by the transport mechanism.

In the paper sheet processing method according to the present invention,
It is preferable to further include a conveyance abnormality detection step in which a conveyance abnormality detection unit provided in the conveyance mechanism detects a conveyance abnormality of the barcode ticket conveyed by the conveyance mechanism.

The paper sheet processing apparatus according to the present invention comprises:
In a paper sheet processing apparatus for processing paper sheets including banknotes and barcode tickets,
A storage portion having a bottom surface for storing paper sheets in a bundle;
A feeding unit that feeds out a paper sheet positioned at a lowermost position among the paper sheets stored in a bundled state in the storage unit;
A transport mechanism for transporting the paper sheet fed by the feeding section;
A stacking unit connected to the transport mechanism and configured to stack paper sheets transported by the transport mechanism;
A barcode detection unit that is disposed below the bottom surface of the storage unit and reads barcode information of a barcode ticket included in a paper sheet stored in a bundle in the storage unit;
A banknote detector provided in the transport mechanism and for reading banknotes transported by the transport mechanism;
It is preferable to have provided.

In the paper sheet processing apparatus according to the present invention,
It is preferable that the apparatus further includes a reject unit that is connected to the transport mechanism and stacks paper sheets that are not stacked on the stacking unit.

In the paper sheet processing apparatus according to the present invention,
The stacking unit preferably includes a banknote stacking unit that stacks banknotes and a barcode ticket stacking unit that stacks barcode tickets.

In the paper sheet processing apparatus according to the present invention,
It is preferable that the apparatus further includes a conveyance abnormality detection unit that is provided in the conveyance mechanism and detects a conveyance abnormality of paper sheets conveyed by the conveyance mechanism.

In the paper sheet processing apparatus according to the present invention,
The barcode detection unit preferably reads the barcode information of the barcode ticket when the barcode ticket is positioned at the lowest position among the bundled paper sheets stored in the storage unit.

The paper sheet processing method according to the present invention comprises:
In a paper sheet processing method for processing paper sheets including banknotes and barcode tickets,
A storage unit having a bottom surface, a feeding unit for feeding out paper sheets, a transport mechanism for transporting paper sheets, a stacking unit connected to the transport mechanism, and a barcode disposed below the bottom surface of the storage unit A paper sheet processing method using a paper sheet processing apparatus including a detection unit and a banknote detection unit provided in the transport mechanism,
A storage step of storing the paper sheets in a bundled state by the storage unit;
A barcode detection step of reading barcode information of a barcode ticket contained in a paper sheet stored in a bundled state in the storage unit by the barcode detection unit;
A feeding step of feeding out a paper sheet positioned at a lowermost position among the paper sheets stored in a bundled state in the storage unit by the feeding unit;
A conveying step of conveying the paper sheet fed by the feeding unit by the conveying mechanism;
A stacking step of stacking paper sheets transported by the transport mechanism by the stacking unit;
It has.

In the paper sheet processing method according to the present invention,
It is preferable to further include a rejecting step for guiding the paper sheets that are not stacked on the stacking unit to the rejecting unit by the transport mechanism.

According to the present invention, the barcode information of the barcode ticket is arranged below the bottom surface of the storage unit, because the barcode detection unit that reads the barcode information of the barcode ticket stored in the storage unit in a bundle state is arranged. Can be read accurately. In addition, the size of the barcode ticket processing apparatus and the paper sheet processing apparatus can be reduced.

1 is a perspective view of a barcode ticket processing apparatus according to a first embodiment of the present invention. 1 is a side sectional view of a barcode ticket processing apparatus according to a first embodiment of the present invention. Schematic which showed the inside of the identification part of the barcode ticket processing apparatus by the 1st Embodiment of this invention. The flowchart of the barcode ticket processing method by the 1st Embodiment of this invention. Schematic which showed the inside of the identification part of the paper sheet processing apparatus by the 2nd Embodiment of this invention. The flowchart of the paper sheet processing method by the 2nd Embodiment of this invention.

First Embodiment Hereinafter, a first embodiment relating to a barcode ticket processing apparatus and a barcode ticket processing method according to the present invention will be described with reference to the drawings. Here, FIG. 1 to FIG. 4 are diagrams showing a first embodiment of the present invention.

As shown in FIGS. 1 and 2, the barcode ticket processing apparatus includes a casing 1, a bottom surface 31, and side surfaces 32 and 33, and a hopper (accommodating unit) that accommodates a barcode ticket B in a bundled state. ) 30 and a feeding unit 15 that feeds out the barcode ticket B located at the lowermost position among the barcode tickets B accommodated in a bundled state in the hopper 30.

Of these, the feeding unit 15 is disposed on the hopper 30 and rotates to provide a kicker roller that applies a driving force to the lowest barcode ticket B among the barcode tickets B accommodated in the hopper 30 in a bundle. 2 and a gate mechanism 5 that pinches and feeds the barcode ticket B to which a driving force is given by the kicker roller 2.

As shown in FIGS. 1 and 2, the gate mechanism 5 includes a feed roller 3 disposed on the bottom surface 31 of the hopper 30 and a gate roller disposed on the side surface 32 of the hopper 30 so as to face the feed roller 3. 4.

As shown in FIG. 2, below the bottom surface 31 of the hopper 30, there is a laser sensor (barcode detection unit) 10 that reads a barcode printed on a barcode ticket B accommodated in a bundled state in the hopper 30. Is provided. The bottom surface 31 of the hopper 30 is provided with a gap (not shown) such as a window through which the laser light emitted from the laser sensor 10 can pass.

Further, as shown in FIG. 2, a transport mechanism 60 that transports the barcode ticket B fed out by the gate mechanism 5 is provided in the housing 1 on the downstream side of the gate mechanism 5. The stacker (stacking unit) 7 and 8 for stacking the barcode ticket B transported by the transport mechanism 60 is connected to the housing 1 on the downstream side. Further, on the downstream side of the transport mechanism 60, a reject unit 9 on which the barcode ticket B that has not been stacked on the

stackers

7 and 8 is stacked is also connected.

As shown in FIG. 2, the transport mechanism 60 includes a transport path 61 that transports the barcode ticket B and a transport roller (not shown) that applies a driving force to the barcode ticket B. .

Further, as shown in FIG. 2, the

stackers

7 and 8 are provided with

integrated detection sensors

85 and 86 for detecting whether or not the barcode ticket B is integrated. Similarly, the reject unit 9 is provided with an accumulation detection sensor 79 for detecting whether the barcode ticket B that has not been conveyed to the

stackers

7 and 8 is accumulated.

As shown in FIG. 2,

sensors

74, 75, 76, 81, 82 for detecting whether the barcode ticket B has passed through the transport path 61 are provided at a plurality of locations on the transport path 61. Further, in the conveyance path 61, a branching claw 91 is provided between the identification unit 50 described later and the stacker 7, and a branching claw 92 is provided between the branching claw 91 and the stacker 8.

Further, as shown in FIG. 2, an identification unit 50 is provided in the housing 1. As shown in FIGS. 2 and 3, the identification unit 50 is connected to the identification CPU 55 for identifying the barcode information of the barcode ticket B read by the laser sensor 10, and the bar to be conveyed by being connected to the identification CPU 55. A thickness sensor 52 that reads the thickness of the code ticket B. The thickness sensor 52 can detect whether or not a plurality of barcode tickets B are overlapped and conveyed (multi-feed).

Further, as shown in FIG. 2, on the downstream side of the feed roller 3 and the gate roller 4, a feeding detection sensor 72 that detects whether the bar code ticket B is reliably fed by the feed roller 3 and the gate roller 4. Is provided. The feeding detection sensor 72 can also detect whether the barcode ticket B is skewed out. As shown in FIG. 2, a transmissive sensor 71 that detects whether the barcode ticket B is accommodated in the hopper 30 is provided in the side surface 32 and the bottom surface 31 of the hopper 30.

In FIG. 3, when the identification CPU 55 can identify the barcode information of the barcode ticket B read by the laser sensor 10, the control CPU 56 drives the feeding unit 15 to feed out the barcode ticket B. (See FIGS. 1 and 2).

It should be noted that the control CPU 56 determines that the barcode to be read by the feeding unit 15 when the reading time by the laser sensor 10 has exceeded a predetermined time without the identification CPU 55 identifying the barcode information of the barcode ticket B. It is configured to control the transport rollers, branching

claws

91 and 92 and the like so that the ticket B is fed out and the barcode ticket B is guided to the reject unit 9 by the transport mechanism 60.

By the way, as described above, the feeding sensor 72 can detect whether the barcode ticket B is skewed and fed, and the thickness sensor 52 conveys (multi-feeds) a plurality of barcode tickets B overlapping. ) Can be detected. The feeding detection sensor 72 and the thickness sensor 52 constitute a conveyance abnormality detection unit that detects a conveyance abnormality of the barcode ticket B conveyed by the conveyance mechanism 60.

Next, the operation of the present embodiment having such a configuration will be described.

First, the bar code tickets B in a bundled state are arranged and accommodated in the hopper 30 (accommodating step 101) (see FIGS. 1, 2 and 4).

Next, the barcode printed on the lowest barcode ticket B among the barcode tickets B accommodated in the hopper 30 in a bundled state is read by the laser sensor 10 (barcode detection step 102) (FIG. 2 and FIG. 4). That is, the barcode printed on the barcode ticket B is started to be read after the barcode ticket B positioned at the lowermost position (the previous one) is completely paid out.

At this time, according to the present embodiment, the barcode information of the barcode ticket B accommodated in the hopper 30 and in a stationary state can be read, and the time for reading the barcode information of the barcode ticket B is sufficient. Can be secured. For this reason, the barcode information of the barcode ticket B can be read with high accuracy.

Here, the point that a sufficient time for reading the barcode information of the barcode ticket B can be secured will be specifically described.

It should be noted that the scanning speed of the laser sensor 10 used as the barcode detection unit is 1000 scan / second, the conveyance speed of the barcode ticket B conveyed on the conveyance path 61 is 2000 mm / second, and the bar fed from the feeding unit 15 The feeding speed of the code ticket B is 720 sheets / minute (12 sheets / second), the height of the barcode ticket B (width in the short direction) is 66 mm, and the barcode ticket printed on the barcode ticket B Consider the case where the height (the length of the barcode ticket B in the short direction) is 10 mm.

First, as in the prior art, when the barcode detection unit is arranged in the conveyance path 61 and the barcode information of the barcode ticket B is read,
10mm ÷ (2000mm / sec ÷ 1000scan / sec) = 5scan
Thus, the barcode printed on the barcode ticket B can be scanned five times.

On the other hand, according to the present embodiment, the barcode sensor B can be scanned by the laser sensor 10 during the time when the barcode ticket B is accommodated in the hopper 30 in a stationary state. That is, during the time obtained by subtracting the time for moving the barcode ticket B (66 mm / 2000 mm / second) from the time for processing one barcode ticket B (1 / (12 sheets / second)), the laser sensor 10. Can be scanned. Therefore,
(1 / (12 sheets / sec))-(66mm ÷ 2000mm / sec) = 50ms
Therefore, the laser sensor 10 can scan for 50 ms. For this reason,
1000 scan / second x 50 ms = 50 scan
Thus, the barcode printed on the barcode ticket B can be scanned 50 times. As is clear from this result, according to the present embodiment, it is possible to secure a sufficient time for reading the barcode information of the barcode ticket B. In the above, the transport speed of the bar code ticket B is uniformly 2000 mm / sec. However, the transport speed does not suddenly become 2000 mm / sec at the start of transport (it is a little slower). The barcode printed on the code ticket B can be scanned 50 times or more.

In general, since the barcode ticket B is made of thermal paper, the barcode portion printed on the barcode ticket B is damaged when the barcode ticket B is fed out by the feeding section 15. Sometimes. For this reason, when the barcode information of the barcode ticket B is read by the barcode detection unit provided in the transport path 61 as in the prior art, the barcode information of the barcode ticket B may be read erroneously. .

On the other hand, according to the present embodiment, the barcode information of the barcode ticket B accommodated in the hopper 30 is read. For this reason, the barcode printed on the barcode ticket B before being fed out by the feeding unit 15 can be read, and the barcode portion printed on the barcode ticket B is damaged when fed out by the feeding unit 15. Even if this happens, the barcode information can be read without being affected by this. As a result, the barcode information of the barcode ticket B can be read with higher accuracy.

In the prior art, since the barcode detection unit is provided in the conveyance path 61, the size of the barcode ticket processing apparatus is increased. On the other hand, according to the present embodiment, the laser scanner as the barcode detection unit is disposed below the bottom surface 31 of the hopper 30 and is not provided in the conveyance path 61. For this reason, the size of the barcode ticket processing apparatus can be reduced.

Further, in the present embodiment, since the barcode information of the barcode ticket B accommodated in the hopper 30 in a bundle state is read, the lowest barcode ticket B to be read is located above. It is pressed down by receiving the weight of another barcode ticket B. Therefore, the barcode ticket B can be read while being pressed against the bottom surface 31 of the hopper 30, and the barcode information of the barcode ticket B can be read in a stable state.

By the way, in the present embodiment, the laser sensor 10 is used as a bar code detection unit, and light having high directivity called laser light is used as sensor light. For this reason, the laser sensor 10 can be disposed at a position a certain distance away from the bottom surface 31 of the hopper 30. As a result, the laser sensor 10 can be disposed at a position avoiding the members such as the kicker roller 2 and the feed roller 3.

Further, since the laser light emitted from the laser sensor 10 has a strong characteristic against focal vibration, even if the bar code ticket B is fluttered, the bar code information of the bar code ticket B is displayed. Can be read reliably.

When the barcode information of the barcode ticket B is read by the laser sensor 10 as described above and the barcode information of the barcode ticket B can be identified by the identification CPU 55, the control CPU 56 drives the feeding unit 15. Then, the bar code ticket B is fed out (see FIGS. 1, 2 and 4).

On the other hand, the barcode information of the barcode ticket B read by the laser sensor 10 cannot be identified by the identification CPU 55, and even when the reading time by the laser sensor 10 exceeds a predetermined time, the control CPU 56 The feeding unit 15 is driven to feed out the barcode ticket B (see FIGS. 1, 2 and 4). At this time, the control CPU 56 determines that the identification abnormality has occurred, and controls the transport rollers and the branching

claws

91 and 92 so as to guide the barcode ticket B to the reject unit 9 as will be described later.

Thus, when the barcode ticket B is fed out by the feeding unit 15, the barcode ticket B is transported by the transport mechanism 60 (transport step 106) (see FIGS. 2 and 4). Note that when the barcode ticket B is fed from the feeding unit 15 toward the transport path 61, the barcode ticket B is reliably fed by the feeding detection sensor 72, or the barcode ticket B is skewed. It is detected whether there is any (see FIG. 2).

As described above, the barcode ticket B conveyed by the conveyance mechanism 60 passes through the thickness sensor 52 of the identification unit 50, and the barcode ticket B conveyed by the thickness sensor 52 is overlapped and conveyed (multifeed). Whether it is not detected is detected (see FIG. 2).

Then, when the identification CPU 55 does not determine that there is an identification abnormality based on information from the laser sensor 10, and when no conveyance abnormality is detected in the conveyance abnormality detection (conveyance abnormality detection step) by the conveyance abnormality detection unit. The barcode ticket B transported by the transport mechanism 60 is branched by the branching

claws

91 and 92 and transported to the stackers 7 and 8 (stacking step 108) (see FIGS. 2 and 4). ).

Here, it is detected that the barcode ticket B transported to the

stackers

7 and 8 is transported into the

stackers

7 and 8 through the sensors 81-84 (see FIG. 2).

On the other hand, when the identification CPU 55 determines that there is an identification abnormality based on information from the laser sensor 10 or when a conveyance abnormality is detected in the conveyance abnormality detection (conveyance abnormality detection step) by the conveyance abnormality detection unit, The target paper sheet (which may be mixed with paper sheets other than the barcode ticket B) is conveyed to the reject unit 9 without being branched by the branching

claws

91 and 92 and accumulated. (Reject Step 109) (See FIGS. 2 and 4).

Here, the identification abnormality means a case where the information identified by the identification unit 50 does not match the information recorded in advance. Examples of such an abnormal identification include when the identified barcode information does not match the information recorded in advance. By the way, the information stored in advance in the identification unit 50 in this way can be changed as appropriate, for example, when the type of the barcode ticket B is changed.

Further, the conveyance abnormality means an abnormality when the barcode ticket B is conveyed by the conveyance mechanism 60. Examples of such a transport abnormality include a case where the barcode ticket B is transported obliquely (skew), a case where a plurality of barcode tickets B are transported in an overlapping manner (multifeed), and a plurality of A case where the barcode ticket B is transported without a predetermined interval (chain) is exemplified.

By the way, although it demonstrated by the aspect using the laser sensor 10 as a barcode detection part above, it is not restricted to this, A line sensor etc. can also be used as a barcode detection part.

In the above description, when the identification CPU 55 can identify the barcode information of the barcode ticket B read by the laser sensor 10, the control CPU 56 drives the feeding unit 15 to feed out the barcode ticket B. Even when the identification CPU 55 cannot identify the barcode information of the barcode ticket B read by the laser sensor 10, if the reading time by the laser sensor 10 has exceeded a predetermined time, the control CPU 56 determines that the identification abnormality has occurred. In the above description, the feeding unit 15 is driven to feed out the barcode ticket B (see FIG. 4).

However, the present invention is not limited to this. When the feeding unit 15 uniformly feeds the barcode ticket B and the barcode information of the barcode ticket B read by the laser sensor 10 cannot be identified by the identification CPU 55, The control CPU 56 may cause the barcode ticket B to be fed back by the feeding unit 15 and cause the laser sensor 10 to read the barcode printed on the barcode ticket B again.

In the above description, the barcode printed on the barcode ticket B has been described using an aspect in which reading is started after the barcode ticket B positioned at the lowermost position (the previous one) is completely fed out. . However, the barcode printed on the barcode ticket B is not limited to this, and the barcode ticket B located at the lowermost position (the previous one) moves in the feeding direction, so that Reading may be started when the barcode printed on the barcode ticket B located at the second position reaches a state where the laser beam from the laser sensor 10 can be irradiated.

Second Embodiment Next, referring to FIGS. 5 and 6, a second embodiment of the present invention will be described. The second embodiment shown in FIGS. 5 and 6 relates to a paper sheet processing apparatus that processes paper sheets including banknotes and barcode tickets B. The laser sensor 10 and the barcode ticket B are hoppers. The barcode information of the barcode ticket B is read when it is located at the lowermost position among the bundled paper sheets accommodated in 30. The identification unit 50 provided in the transport path 61 further includes a line sensor (banknote detection unit) 51 connected to the identification CPU 55 and a magnetic sensor 53 connected to the identification CPU 55. One of the

stackers

7 and 8 functions as a banknote stacker (banknote stacking unit) 8 for stacking banknotes, and the other one is a barcode ticket stacker (barcode ticket) for stacking barcode tickets B. It functions as a stacking unit 7 (see FIG. 1). Other configurations are substantially the same as those of the first embodiment shown in FIGS.

In the second embodiment shown in FIG. 5 and FIG. 6, the same parts as those in the first embodiment shown in FIG. 1 to FIG.

Hereinafter, the operation of this embodiment will be described.

First, paper sheets in a bundled state including banknotes and barcode ticket B are placed in hopper 30 and stored (accommodating step 101) (see FIGS. 1, 2 and 6).

Next, the laser beam is irradiated by the laser sensor 10 onto the paper sheet positioned at the lowest position among the barcode tickets B accommodated in the hopper 30 in a bundle (see FIGS. 2 and 6). When the barcode information can be identified by the identification CPU 55, it is determined that the target paper sheet is the barcode ticket B. On the other hand, the barcode information is identified by the identification CPU 55. If it is not possible, it is determined that the target paper sheet is not the barcode ticket B (barcode detection step 102) (see FIG. 6).

Here, when the barcode sheet B located at the lowest position among the barcode tickets B accommodated in the hopper 30 in a bundled state is the barcode ticket B, the same effects as those of the first embodiment can be obtained. Can do.

That is, it is possible to read the barcode information of the barcode ticket B in a stationary state, and to sufficiently secure the time for reading the barcode information of the barcode ticket B. For this reason, the barcode information of the barcode ticket B can be read with high accuracy.

Further, the barcode printed on the barcode ticket B before being fed out by the feeding unit 15 can be read, and the barcode portion printed on the barcode ticket B is scratched when the barcode is fed out by the feeding unit 15. Even if this happens, the barcode information can be read without being affected by this. For this reason, the barcode information of the barcode ticket B can be read more accurately.

Furthermore, the bar code ticket B located at the lowermost position to be read is pressed by receiving the weight of other paper sheets located at the upper side. Therefore, the barcode ticket B can be read while being pressed against the bottom surface 31 of the hopper 30, and the barcode information of the barcode ticket B can be read in a stable state.

After the laser beam is irradiated from the laser sensor 10 as described above and the barcode information identification result is obtained, the paper sheet is fed out to the conveyance path 61 by the feeding unit 15 (feeding step 105) (FIG. 1). FIG. 2 and FIG. 6). Then, the paper sheets fed out in this way are transported by the transport mechanism 60 and reach the line sensor 51 of the identification unit (transport process 106) (see FIGS. 5 and 6).

The barcode information read by the laser sensor 10 by the identification CPU 55 can be identified, and the paper sheet that is determined to be the barcode ticket B uses the line sensor 51 without being read by the line sensor 51. It passes (see FIG. 5), passes through the

sensors

74, 81, 83 (see FIG. 2), and is conveyed to the barcode ticket stacker 7 (see FIGS. 1 and 6). At this time, the barcode ticket B is branched by the branching claw 91.

On the other hand, the sheet information that cannot be identified by the identification CPU 55 by the laser sensor 10 and is determined not to be the barcode ticket B is read by the line sensor 51 to generate image data. (See FIG. 5).

Then, the identification CPU 55 identifies the target paper sheet based on the image data, identifies whether the target paper sheet is a banknote, and the paper sheet is a banknote. In this case, it is determined whether the bill is new or old, correct / incorrect, true / false, denomination, direction, front and back (see FIGS. 5 and 6). Note that the identification CPU 55 determines the authenticity of the banknote based on information from the magnetic sensor 53.

As described above, the paper sheets determined to be banknotes by the identification CPU 55 are transported to the banknote stacker 8 and accumulated through the

sensors

74, 75, 82, and 84 (see FIG. 2) (stacking step 108). (See FIGS. 1 and 6). At this time, the banknote is branched by the branching claw 92.

If the identification unit 50 determines that there is an identification abnormality, or if a conveyance abnormality occurs while being conveyed by the conveyance mechanism 60, the target paper sheet is the branching claw 91, It is conveyed to the reject unit 9 without being branched by 92 and accumulated (rejecting step 109). (See FIGS. 2 and 6)

Claims

An accommodating portion for accommodating a barcode ticket having a bottom surface in a bundle;
A payout unit for feeding out the barcode ticket located at the lowest position among the barcode tickets stored in a bundled state in the storage unit;
A transport mechanism for transporting the barcode ticket fed out by the feeding unit;
A stacking unit connected to the transport mechanism and configured to stack the barcode ticket transported by the transport mechanism;
A barcode detection unit that is arranged below the bottom surface of the storage unit and reads barcode information of a barcode ticket stored in a bundled state in the storage unit;
A bar code ticket processing apparatus comprising:
2. The barcode ticket processing apparatus according to claim 1, wherein the barcode detection unit includes a laser sensor.
2. The barcode ticket processing apparatus according to claim 1, wherein the barcode detection unit includes a line sensor.
When the barcode ticket cannot be identified based on the barcode information of the barcode ticket read by the barcode detection unit, the feeding unit rewinds the barcode ticket,
The barcode ticket processing apparatus according to claim 1, wherein the barcode detection unit reads again barcode information of the barcode ticket fed back by the feeding unit.
The bar code ticket is fed out when the bar code ticket can be identified based on bar code information of the bar code ticket read by the bar code detector. The barcode ticket processing apparatus according to 1.
A reject unit coupled to the transport mechanism and configured to stack barcode tickets not stacked on the stacking unit;
When the reading time by the barcode detection unit has passed a predetermined time or more, the feeding unit delivers the barcode ticket,
6. The barcode ticket processing apparatus according to claim 5, wherein the transport mechanism guides the barcode ticket to the reject unit.
The barcode ticket processing apparatus according to claim 1, further comprising a conveyance abnormality detection unit that is provided in the conveyance mechanism and detects a conveyance abnormality of the barcode ticket conveyed by the conveyance mechanism.
2. The barcode ticket according to claim 1, wherein the barcode detection unit reads barcode information of a barcode ticket positioned at a lowermost position among barcode tickets stored in a bundled state in the storage unit. Processing equipment.
An accommodating portion having a bottom surface, a feeding portion for feeding out the barcode ticket, a conveying mechanism for conveying the barcode ticket, a stacking portion connected to the conveying mechanism, and a barcode disposed below the bottom surface of the accommodating portion. In a barcode ticket processing method using a barcode ticket processing apparatus including a detection unit,
A housing step of housing the barcode ticket in a bundled state by the housing portion;
A barcode detection step of reading barcode information of barcode tickets stored in a bundled state in the storage unit by the barcode detection unit;
A feeding step of feeding out the barcode ticket located at the lowest position among the barcode tickets stored in a bundled state in the storage unit by the feeding unit;
A transporting step of transporting the barcode ticket fed out by the feeding unit by the transporting mechanism;
A stacking step of stacking the barcode ticket transported by the transport mechanism by the stacking unit;
A barcode ticket processing method comprising:
In the feeding process, when the reading time by the barcode detection unit has passed a predetermined time or more, a barcode ticket is fed out by the feeding unit,
The barcode ticket processing method according to claim 9, wherein the barcode ticket is guided to a reject unit by the conveyance mechanism in the conveyance step.
10. The bar according to claim 9, further comprising a conveyance abnormality detection step in which a conveyance abnormality detection unit provided in the conveyance mechanism detects a conveyance abnormality of the barcode ticket conveyed by the conveyance mechanism. Code ticket processing method.
In a paper sheet processing apparatus for processing paper sheets including banknotes and barcode tickets,
A storage portion having a bottom surface for storing paper sheets in a bundle;
A feeding unit that feeds out a paper sheet positioned at a lowermost position among the paper sheets stored in a bundled state in the storage unit;
A transport mechanism for transporting the paper sheet fed by the feeding section;
A stacking unit connected to the transport mechanism and configured to stack paper sheets transported by the transport mechanism;
A barcode detection unit that is disposed below the bottom surface of the storage unit and reads barcode information of a barcode ticket included in a paper sheet stored in a bundle in the storage unit;
A banknote detector provided in the transport mechanism and for reading banknotes transported by the transport mechanism;
A paper sheet processing apparatus comprising:
13. The barcode ticket processing apparatus according to claim 12, further comprising a reject unit that is coupled to the transport mechanism and accumulates paper sheets that are not accumulated in the accumulation unit.
The paper sheet processing apparatus according to claim 12, wherein the stacking unit includes a banknote stacking unit that stacks banknotes and a barcode ticket stacking unit that stacks barcode tickets.
13. The paper sheet processing apparatus according to claim 12, further comprising a transport abnormality detection unit that is provided in the transport mechanism and detects a transport abnormality of the paper sheet transported by the transport mechanism.
The barcode detection unit reads barcode information of the barcode ticket when the barcode ticket is positioned at the lowest position among the bundled paper sheets stored in the storage unit. Item 13. A paper sheet processing apparatus according to Item 12.
In a paper sheet processing method for processing paper sheets including banknotes and barcode tickets,
A storage unit having a bottom surface, a feeding unit for feeding out paper sheets, a transport mechanism for transporting paper sheets, a stacking unit connected to the transport mechanism, and a barcode disposed below the bottom surface of the storage unit A paper sheet processing method using a paper sheet processing apparatus including a detection unit and a banknote detection unit provided in the transport mechanism,
A storage step of storing the paper sheets in a bundled state by the storage unit;
A barcode detection step of reading barcode information of a barcode ticket contained in a paper sheet stored in a bundled state in the storage unit by the barcode detection unit;
A feeding step of feeding out a paper sheet positioned at a lowermost position among the paper sheets stored in a bundled state in the storage unit by the feeding unit;
A conveying step of conveying the paper sheet fed by the feeding unit by the conveying mechanism;
A stacking step of stacking paper sheets transported by the transport mechanism by the stacking unit;
A paper sheet processing method characterized by comprising:
18. The barcode ticket processing method according to claim 17, further comprising a rejecting step of guiding paper sheets that are not stacked in the stacking unit to the rejecting unit by the transport mechanism.