JP2009042953A - Paper sheet counting machine, selling terminal equipment and counting method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a paper sheet counting machine for quickly and accurately reading RFID tag information by counting paper sheets to which RFID tags are attached one by one, selling terminal equipment in which the paper sheet counting machine is integrated and a counting method suitable for the selling terminal equipment. <P>SOLUTION: First and second accumulation parts 23 and 24 are arranged at a front face 1a side of the body of a paper sheet counting machine 3, and a counting part 33 is arranged in a conveyance path region 29a following a delivery mechanism 26. This paper sheet counting machine 3 is provided with RFID tags R/W 35A and 35B installed on conveyance path regions 29b and 29c following the conveyance path region 29a for communicating with an RFID tags attached to a tickets T to be conveyed in the middle of conveyance; a branching part 34 installed just after the conveyance path region 29c for branching an abnormal ticket T' to be stored in a second integration part 24; and a first integration part 23 for storing the normal ticket T. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a sheet counter for paper sheets, and in particular, a paper sheet with an RFID (Radio Frequency Identification) tag, for example, a sheet counter for banknotes, banknote-type tickets, card-type tickets, and sales including the same The present invention relates to a terminal device and a counting method.

For example, in an event ticket or the like, an RFID tag is attached to or inserted into a ticket in order to record POS (Point of Sales) information for preventing counterfeit tickets or for analyzing the tendency of visitors. It has come to attach. Then, in a dealer who handles such tickets with RFID tags collectively, the number of tickets is reliably counted at high speed, the RFID tag information of the ticket is read, or the POS information is handed over to the ticket handed over to the customer. It is necessary to write.
As a similar counting machine, there is known a desk-mounted banknote counting and sorting machine that identifies and counts banknotes one by one at high speed as described in Patent Document 1.
JP 2003-223661 A

However, the banknote counting and sorting machine is for identifying and counting banknotes at high speed, and does not count the paper sheets with RFID tags by reliably reading or writing RFID tag information.
Also, when RFID tag information is read or written by an RFID tag reader / writer (hereinafter referred to as RFID tag R / W) in a state where tickets or cards with RFID tags are stacked, There was a problem that writing failure occurred, and even if a reading failure or writing failure occurred, it could not be confirmed.

  In order to solve the above-described problems, the object of the present invention is to incorporate a sheet counter that can count RFID sheets with each RFID tag and read RFID tag information quickly and reliably. Another object of the present invention is to provide a sales terminal device and a counting method suitable for it.

  In order to solve the above-mentioned problem, the first invention is a feeding mechanism that feeds paper sheets with RFID tags to be identified and counted one by one, a counting sensor for counting the fed paper sheets, And a tag reader for reading RFID tag information recorded on the RFID tag attached to the fed paper sheet.

According to the first invention, the paper sheets are fed out one by one, and the tag reader reads out the RFID tag information of the RFID tag attached to the single fed paper sheet. RFID tag information can be reliably read without simultaneous reading of a plurality of combined RFID tags.
Incidentally, the number of paper sheets counted by the counting sensor and the number of paper sheets read by the tag reader may be compared and checked.

  According to a second aspect of the present invention, there is provided a loading unit having a feeding mechanism in which sheets with RFID tags to be identified and counted are loaded in a stacked state, and the loaded sheets are separated and fed one by one. , A conveyance path for conveying paper sheets fed out from the loading unit, a counting sensor for counting the paper sheets provided in the conveyance path one by one, and a communication means provided in the conveyance path and communicating with the RFID tag A stacking unit that stacks the paper sheets conveyed in the transport path at a position below the loading unit, and allows the paper sheets to be taken out from the front of the machine body, a display unit that displays a counting result, and a counting process A control unit that controls the number of sheets counted based on a signal from the counting sensor and a result of the number of sheets counted based on a result of communication means communicating with the RFID tag on the display unit. With features That.

According to the second aspect of the invention, the sheets are fed into the transport path one by one and the communication means communicates with the RFID tag attached to the single sheet fed to the transport path. Therefore, the RFID tag information can be reliably read and written without simultaneous reading and writing with other RFID tags.
The present invention relates to an input device for inputting the number of sheets using the sheet counter of the first or second invention, a display device for displaying the type of sheets and the number of sheets input A sales terminal device sales terminal device including a terminal main body that is communicably connected to the single wafer counter and controls the counting process of the single wafer counter, and a counting method used for them.

  ADVANTAGE OF THE INVENTION According to this invention, the sheet counter which can count the sheet | seat with which the RFID tag was attached | subjected one by one, and can read RFID tag information quickly and reliably and a sales terminal device incorporating it can be provided.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
<Overall configuration of sales terminal device>
Here, the ticket sales are entrusted by the ticket seller, and the ticket sales at a sales agent that sells a large number of tickets, or the group travel dealer buys the ticket coupon for the group at the sales agent and sells the ticket An example will be described in which an actual delivery of a ticket for a group is received at the window.

(A) of FIG. 1 is a figure which shows the sales terminal device concerning embodiment of this invention, (b) is a block diagram of the banknote-type ticket with RFID. FIG. 2 is a configuration diagram of the sales terminal device.
A sales terminal device 1 for selling or counting a ticket (paper sheet) T to which an RFID tag 7 is attached, for example, a banknote-type ticket or a card ticket is used. 3, an input device 4 such as a keyboard 4 a and a mouse 4 b, a terminal main body 5, a display device 6 having a main display portion 6 a and a sub display portion 6 b, and a printer 8.
The terminal body 5 is connected to the sheet counter 3, the input device 4, the display device 6, and the printer 8.
The terminal body 5 is communicably connected to a server 9 (see FIG. 2) of the headquarters of the ticket seller via the network 2 (see FIG. 2). In FIG. 1, it is connected to the network 2 by a wireless LAN.

As shown in FIG. 1A, the sheet counter 3 includes a loading unit 22 that loads the operation unit 21 and the ticket T in a stacked state on the front side of the upper panel of the machine body. The loading portion 22 is provided with a guide plate 22a that can move to the left and right to align the longitudinal end positions of the ticket T. Further, a marker 22b is drawn on the surface of the machine body of the loading unit 22, and a conveyance path 29 (see FIG. 4), which is described later, of an antenna that communicates with the RFID tags 7 of the first and second RFID tags R / W 35A and 35B described later. In FIG. 4, it is indicated by conveyance passage areas 29a to 29f, the conveyance passage 29 is a general name of the whole), and indicates the position in the width direction, and the position of the RFID tag 7 attached to the ticket T is aligned with this marker 22b and guided. The position of the plate 22a can be set.
Further, on the front surface of the machine body of the single-wafer counter 3, a first stacking unit 23 that stacks the counted tickets T and a second stacking unit 24 that stacks the abnormal tickets T ′ determined to be abnormal are ticketed. T or abnormal ticket T ′ is provided so that it can be taken out. On the right side of the first stacking unit 23 and the second stacking unit 24, display units 25a and 25b for displaying the counting results are provided.

The display device 6 is used by an operator, for example, a main display unit 6a composed of a liquid crystal display device, and a small display that displays only the content presented to the customer among the information displayed on the main display unit 6a. For example, it is comprised from the subdisplay part 6b comprised with the liquid crystal display device.
The ticket T stacked on the loading unit 22 of the sheet counter 3 is a horizontally long bill-shaped ticket as shown in FIG. 1B, and the RFID tag 7 is attached to the surface of the ticket.
Incidentally, for example, the RFID tag 7 is of an inlet type in which an antenna terminal (not shown) of an IC chip 7a having a size of about 0.4 mm is connected to the antenna 7b. The RFID tag 7 may be affixed from the surface as described above, or the RFID tag 7 may be inserted between the front and back of the ticket and obscure its presence by printing on the ticket surface.

  As shown in FIG. 2, the terminal main body 5 of the sales terminal device 1 is a so-called personal computer, in which a CPU 5a is connected to a bus 5b, and a ROM 5c, RAM 5d, a storage unit 5e, a communication unit 5f, an I / O interface are connected to the bus 5b. 5g and a network communication unit 5h are connected. The ROM 5c stores an application program for realizing the function as the sales terminal device 1 by the CPU 5a. The CPU 5 a is connected to the input device 4, the display device 6, and the printer 8 through the I / O interface 5 g, and the control unit of the sheet counter 3 through the communication unit 5 f and the communication unit 32 of the sheet counter 3. 31 is connected. Further, the CPU 5a can communicate with the server 9 from which the ticket T is released via the network 2 via the network communication unit 5h.

(RFID tag information)
FIG. 3 is a diagram illustrating an example of RFID tag information recorded on an RFID tag attached to a ticket.
The RFID tag information 40 includes RFID tag identification information 41 recorded in a non-rewritable area at the time of manufacture in order to identify the RFID tag 7 individually, and information of a part of the digits is an identification code (authentication identification information). 41a is used for authenticity determination, and the remaining digit information is used as the serial number 41b.

In addition, there is an information area writable on the RFID tag 7, and after printing as a ticket T, a ticket recorded on the RFID tag 7 under the management of the ticket release source in order to identify the type of the sales ticket T Ticket type information 42 indicating the type can be registered, and sales management information (hereinafter referred to as POS (Point Of Sales) information) 43 can be recorded at the ticket sales terminal. The POS information 43 includes, for example, store information 43a such as a store code recorded on the RFID tag 7 using the RFID tag R / W at the sales terminal of the ticket T, and sales date / time information 43b.
The RFID tag identification information 41, the ticket type information 42, the store information 43a, and the sales date / time information 43b are each prefixed with an identifier for identifying the type of information, and these are read as the RFID tag information 40. If so, the subsequent processing can be easily performed.

  The area of the ticket type information 42 can be written only by the ticket seller, and the RFID tag identification information 41 and the area of the ticket type information 42 can be read at the sales end window, but writing is not possible. I can't do it.

《Detailed description of single wafer counter》
(Mechanical structure of single wafer counter)
Next, the detailed configuration and operation of the sheet counter 3 will be described with reference to FIGS. 4 and 5 (refer to FIGS. 1 and 2 as appropriate). FIG. 4A is a left side cross-sectional view schematically showing the internal structure of the desk-top type sheet-fed counter according to the present embodiment, and FIG. 4B is a front view thereof. FIG. 5 is a block diagram of the control circuit of the single wafer counter.
A loading unit 22 is provided on the upper part of the sheet counter 3 so that the tickets T to be counted can be placed and loaded in the stacked state from the front surface 3a side. Position of the RFID tag 7 in the width direction in the loading section 22 together with a guide plate 22a (refer to FIG. 1) that can be moved to the left and right to make it easy to stack by aligning both ends, and a note "Align RFID tag to this part" And a marker 22b (see FIG. 1) for designating.

As shown in FIG. 4A, the lowermost ticket T of the ticket T loaded on the mounting table 22c is placed on the lower side of the mounting table 22c of the loading unit 22 on the front surface 3a side of the single wafer counter 3. A feed-out mechanism 26 having a kicker roller 26a and a feed roller 26b that feeds from the rear side toward the back surface 3b is provided. The kicker roller 26a and the feed roller 26b are partly composed of a high friction material such as rubber, and the other circumferential surfaces are metal surfaces that easily slip, both of which are stepping motors M ₁ (see FIG. 5). The counting sensors S1 and S2 of the counting unit 33 that counts the tickets T that are driven in synchronization with each other and are disposed in the middle of the conveyance passage area 29a described later (in FIG. 4A, the counting sensor S1 is the light emitting element S1a). The counting sensor S2 is displayed as a set of the light emitting element S2a and the light receiving element S2b) and is driven and stopped based on detection signals from the detection sensors S5 and S6.

Incidentally, the light emitting element S1a is a light emitting element such as an LED, and the light receiving element S1b is a light receiving element such as a phototransistor. The light receiving element S1b outputs an ON signal to the control unit 31 when detecting light from the light emitting element S1a, and outputs an OFF signal when not detecting light.
Set of light emitting element S2a and light receiving element S2b in other counting sensor S2, set of light emitting element S3a and light receiving element S3b in detection sensors S3, S4, S5, and S6 described later, set of light emitting element S4a and light receiving element S4b, light emission The set of the element S5a and the light receiving element S5b and the set of the light emitting element S6a and the light receiving element S6b have the same configuration as the set of the light emitting element S1a and the light receiving element S1b.

  Above the feed roller 26b, a gate member 27a (reversing roller) constituting a gate portion 27 for separating and feeding the ticket T fed from the loading portion 22 to the feed roller 26b into one sheet is provided. Immediately after the gate portion 27, a transport roller 28 for sending out the ticket T that has passed through the gate portion 27 is provided. Each of these rollers 26a, 26b, 27a, 28 is provided in a pair in the axial direction thereof (in the transport width direction of the ticket T and in the longitudinal direction of the ticket T). In particular, the roller 26 b is wider than the rollers 27 a and 28, and faces both the rollers 27 a and 28.

Subsequent to the loading unit 22, the conveyance path 29 (in FIG. 4 (a), which conveys the ticket T fed from the loading unit 22 is indicated by conveyance path areas 29a to 29f, and the conveyance path 29 is a generic name. ) Is arranged. This conveyance path 29 has a roller structure in which rollers are arranged on two conveyance guide plates having roller windows from both sides of the conveyance guide plate to the positions of the roller windows in the conveyance passage areas 29a to 29d. An RFID tag of the RFID tag 7 attached to the ticket T, which is provided along the inner surface of the back surface 3b of the machine 3 downward and has a conveyance passage area 29a having a counting portion 33 in the middle, and the conveyance passage area 29a. A conveyance path area 29b for reading information and a conveyance path area 29c for writing POS information to the RFID tag 7 are provided. The conveyance path area 29a extends from the position of the rollers 26b and 27 to the rollers 29a ₁ and 29a ₂ , and the conveyance path area 29b extends from the position of the rollers 29a ₁ and 29a ₂ to the rollers 29b ₁ and 29b ₂ , and the conveyance path area 29c is to the branch claw 34a to be described later from the position of the roller _29b 1, _{29b 2.}

  An RFID tag R / W 35A is arranged in the conveyance passage area 29b, and a detection sensor S3 (consisting of a light emitting element S3a and a light receiving element S3b) and a detection sensor S4 (light emitting element S4a and a light receiving element) are arranged on the upstream side and the downstream side thereof. S4b). In addition, an RFID tag R / W 35B is arranged in the transport passage area 29c, and a detection sensor S5 (consisting of a light emitting element S5a and a light receiving element S5b) and a detection sensor S6 (light emitting element S6a) are arranged on the upstream side and the downstream side thereof. A light receiving element S6b). In the transport passage area 29b, a window is opened in the transport guide plate so that the antenna of the RFID tag R / W 35A can communicate with the RFID tag 7 attached to the ticket T. Similarly, a window is opened in the conveyance passage area 29c so that the antenna of the RFID tag R / W 35B can communicate with the RFID tag 7 attached to the ticket T. When the conveyance guide plates constituting the conveyance passage areas 29a to 29f are thin and resin plates, radio waves are transmitted therethrough, so that it is not necessary to provide the antenna windows of the RFID tags R / W 35A and 35B described above on the conveyance guide plates.

Immediately after the transport passage area 29c, a branching section 34 is provided for switching the course between a transport path area 29d that continues to the transport path area 29c and a transport path area 29e that reaches the second stacking section 24. A branch claw 34a is swingably supported by the branch portion 34 by a shaft 34b. Further, a transport passage area 29f for transporting the ticket T to the first stacking unit 23 is provided after the transport passage area 29d. Along the conveying path zone 29d, roller _29c 1, 29c _2, etc. are arranged to that end.

  As shown in FIG. 4A, the first stacking unit 23 stacks the tickets T in a standing posture. That is, an impeller 36 is provided at the terminal position of the transport passage area 29f leading to the first stacking portion 23, and the tickets T are received one by one between the blades of the impeller 36, and the comb of the first stacking portion 23 is received. In a standing position on the bottom 23b between the L-shaped standing wall 23c and the impeller 36, which is urged toward the impeller 36 by a spring (not shown), leaving the ticket T on the tooth-shaped bottom 23b. Tickets T are accumulated.

The bottom 23b is supported by the frame 23d from below, and the standing wall 23c is attached to the bottom 23b so as to be movable in the front-rear direction. The frame body 23d has left and right support walls (not shown). The support wall pivotally supports the impeller 36, and the moving mechanism 37 such as a solenoid causes the impeller 36, the bottom portion 23b, and the standing wall 23c to be integrated with the left and right walls. In the direction, for example, about 1 cm can be moved.
Accordingly, the axial width of the impeller 36 is longer by, for example, 1 cm on both sides than the left and right width of the maximum allowable width of the ticket T, and the first stacking portion 23 is also on both sides of the left and right width of the maximum allowable width of the ticket T. Each is set longer by 1 cm, for example.

  By adopting such a structure, the moving mechanism 37 can be displaced by a predetermined distance to the left and right of the fuselage under the control of the control unit 31. The tickets T sent to can be accumulated by being displaced to the left or right of the aircraft. At this time, since the ticket T is restrained between the blades of the impeller 36 and the standing wall 23c, the right and left of the ticket T by the displacement operation of the moving mechanism 37 to the left and right can be set by appropriately setting the acceleration of the left and right displacement. Deviation in the direction can be prevented.

  The main purpose of the second stacking unit 24 is to use it for ticket stacking rejected as an abnormal ticket T ′. Therefore, the structure of the second stacking unit 24 is a simple tray-like box. A bladed roller 38 is provided on the pulley shaft 38a at the lower end of the conveying passage area 29e to reach the abnormal ticket T ′ smoothly into the second stacking portion 24.

As described above, at the lower position of the loading unit 22, the inside of the front surface 3a side of the body of the single-sheet counter 3 continues without being branched from the transfer path area 29c, and continues to the transfer path area 29d and the transfer path area 29f. The lower first stacking unit 23 that stacks the tickets T transported to the front surface 3a side of the sheet counter 3 and the transport path area 29c branch from the transport path area 29e, followed by the sheet path counter 3 An upper second stacking unit 24 that stacks the tickets T transported to the front surface 3a side is disposed.
The lower first stacking unit 23 is used for the normal ticket T, and the upper second stacking unit 24 is used for the abnormal ticket T ′. The distinction between normal tickets and abnormal tickets will be described in the explanation of control of the counting process.

  In FIG. 4 (a), the transport passage areas 29a to 29f of each part of the transport passage 29 are (1) a belt structure that can sandwich and transport the ticket T, (2) a structure comprising a belt and a roller, and (3) a roller. The two conveyance guide plates having windows have an appropriate form such as a roller structure in which rollers are arranged from both sides of the conveyance guide plate to the position of the roller window. The rollers are provided as at least a pair in the conveyance width direction.

The rollers 29a ₁ , 29a ₂ , 29b ₁ , 29b ₂ , 29c ₁ , 29c ₂ , the branch claw 34a, the impeller 36, and the bladed roller 38 are also provided as at least a pair in the conveyance width direction. In the transport passage areas 29a to 29d, auxiliary rollers may be added in addition to the illustrated rollers. Further, as described above, one pair is not limited to being arranged in the conveyance width direction, and another one may be added at the center in the conveyance width direction.

  As shown in FIG. 4A, a control unit 31 is disposed at the lower part of the single wafer counter 3. As shown in FIG. 4 (b), the open front rectangular openings 23a and 24a are formed on the front surface 3a of the body of the sheet counter 3 corresponding to the positions of the first and second stacking sections 23 and 24. Are formed so that the tickets T and T ′ accumulated in the accumulation units 23 and 24 can be taken out of the sheet counter 3. Display units 25 a and 25 b are provided corresponding to the first and second stacking units 23 and 24.

(Control circuit for single wafer counter)
Next, the configuration of the control unit 31 will be described.
The control unit 31 includes a CPU, a ROM, a RAM, a memory such as a flash memory, an I / O interface circuit, and peripherals for driving a stepping motor M ₁ , a motor M ₂ , a solenoid SD ₁ , and a solenoid SD ₂ to be described later. It consists of a circuit.

As shown in FIG. 5, the control unit 31 includes a communication unit 32 that transmits and receives communication with the communication unit 5 f (see FIG. 2), an operation unit 21, display units 25 a and 25 b, and a sensor that configures the counting unit 33. a group S1, S2, and sensor group S3~S6 provided at an appropriate position of the conveyance path 29, RFID tag R / W35A, and 35B, a moving mechanism 37, the stepping motor _{M 1} of the feeding mechanism 26 for driving the conveying path The rollers 29a ₁ , 29a ₂ , 29b ₁ , 29b ₂ , 29c ₁ , 29c ₂ , the impeller 36 of the first and second stacking units 23, 24, the bladed roller 38, etc. are driven appropriately. a motor _{M 2,} a solenoid SD ₁ which swings driving the branching pawl 34a, a solenoid SD ₂ of the moving mechanism 37 for driving are connected.

The operation unit 21 is provided on the outer surface of the sheet counter 3 and is operated by an operator. The operation unit 21 performs counting by a program stored in a ROM (not shown) of the control unit 31 in addition to turning on and off the power. For example, a start button, a count stop button, or an offline / automatic start setting operation for starting the automatic counting of the ticket T by loading the accumulation ticket T in the loading unit 22 instead of this button, , Offline batch mode that is a mode that stops when 100 tickets T are counted / accumulated, offline / non-batch count mode that accumulates tickets T until the first stacking unit 23 is full, terminal body 5 ( 2), an online mode setting operation for receiving a counting instruction from the terminal body 5 can be performed.
The online mode includes a “count check” mode and a “order” mode based on a control signal from the terminal body 5, details of which will be described later.
Hereinafter, processing in the online mode will be described.

<< Example of first counting process >>
Next, with reference to FIG. 6 to FIG. 9, the first count in the case where the ticket T is received and inspected, for example, at a sales agent or a ticket sales window, using the sheet counter 3 in the present embodiment. An example of processing will be described.
Here, it is assumed that the sales agent and the ticket sales window prepare the tickets T for the current day or the next day in advance before the customer service time.
The operator activates the terminal body 5 and selects the “counting check” mode from the “ordering” mode for accepting purchases at the customer's counter and the “counting check” mode of the ticket acceptance inspection process. The sales terminal device 1 is connected to a server 9 (see FIG. 2) via a network 2.

  FIG. 6 is a main flowchart showing the control flow of the counting process for checking the received ticket in the terminal body. 7A and 7B are diagrams for explaining an operation screen displayed on the main display unit of the display device. FIG. 7A is a diagram showing a setting screen for counting check, and FIG. 7B is a diagram showing a counting result.

In step S <b> 11, the main display unit 6 a of the terminal body 5 displays a count check setting screen 50 as shown in FIG. 7A, and accepts a ticket type input performed by the operator using the input device 4.
The count check setting screen 50 includes a menu column 50a and a setting condition column 50b, and includes scroll buttons 50c, 50d, 50e, and 50f. In the menu column 50a, a button 51 indicating “Order” as a mode selection button and a button 52 displaying “Counting check” are prepared. Here, the button 52 is pressed and displayed with luminance indicating that the “counting check” mode is operating.

The setting condition column 50b includes an icon button 54 for displaying selectable ticket types (major items), a combo box column 53 as a display column thereof, a handler column 55 for accepting manual input of a handler name, and a ticket type ( Subitem) fields 56A, 56B,..., Normal number fields 61A, 61B,..., Abnormal number fields 62A, 62B,..., Counter ID fields 57A, 57B,. A start button 58b and an end button 58c are prepared.
The ticket type (major item) is a column indicating the ticket type of various events registered in the server 9 (see FIG. 2), and is displayed in the combo box column 53 and can be selected.

The icon button 54 is pressed, and the ticket type (major item) to be checked for counting is displayed by communication with the server 9 and selected. Then, a more detailed ticket type (small item) corresponding to the ticket type (large item), for example, “adult ticket” or “dwarf ticket” is entered in the ticket type (small item) column 56A, 56B,. Is displayed. Thereafter, the operator checks the ticket type (small item) column to be subjected to the counting check process from the displayed ticket type (small item) columns 56A, 56B,. The checked ticket type (small item) column changes to the color of the selected state.
In the counter ID column 57A, 57B,..., The ticket T of the relevant ticket type (small item) is stacked on the loading unit 22 (see FIG. 1), and the ID of the sheet counter 3 (hereinafter referred to as “the sheet counter”). This is a field for designating a counter ID.

The data acquisition button 58a is used to set the ticket type (large item) and the ticket type (small item) on the setting screen 50, and to identify the identification code 41a (see FIG. 3) corresponding to the ticket type, the large item, and the small item ticket. This is a button for acquiring ticket type information 42, which is information indicating the type, from the server 9 (see FIG. 2). The start button 58b sets the ticket type (large item) and the ticket type (small item), and further instructs the sheet counter 3 specified by inputting the counter ID column 57A to start counting. Button. Each time this button causes the single sheet counter 3 to perform counting processing for different ticket types, the counter ID is associated with the corresponding ticket type (small item) each time. And a counting instruction can be sent to the set sheet counter 3.
The count results are accumulated in the storage unit 5e (see FIG. 2) each time, and when the end button 58c is pressed, all the count results are displayed. Accordingly, in FIG. 1, the sales terminal apparatus 1 includes two sheet counters 3, but a larger number may be used, and conversely, one.
In the normal number fields 61A, 61B,... And the abnormal number fields 62A, 62B,. FIG. 7B will be described in the description of step S18.

  In the display state of the setting screen 50, a ticket type (major item) combo box field 53, ticket type (small item) fields 56A, 56B,... Are set, and the data acquisition button 58a is set to the mouse 4b (see FIG. 1). ) Automatically communicates with the server 9 (see FIG. 2), and the RFID set for the RFID tag 7 attached to the ticket T of that type based on the ticket type (major item). An identification code 41a (see FIG. 3) in the tag identification information 41, ticket type information including information on ticket types of large items and small items, and information such as sales prices corresponding to the ticket types are acquired (step S12, “Acquire the identification code of the RFID tag identification information, the ticket type information, etc. from the server based on the ticket type”) and store it in the storage unit 5e (see FIG. 2) (step S13).

  Next, the operator inputs the counter ID of the row of the ticket type (small item) to be counted on the setting screen 50 (step S14, “identification of ticket type to be checked by counter”). After that, when the start button 58b is pressed, the terminal main body 5 displays the “counting check” mode signal, the identification code 41a of the RFID tag identification information 41 (see FIG. 3), and the ticket type information 42 (see FIG. 3) as a counter ID. The data is transmitted to the sheet counter 3 designated by the columns 57A and 57B (step S15).

In step S16, the sheet counter 3 performs a counting process. The control in this process will be described in detail later with reference to the flowcharts shown in FIGS.
In step S17, when the counting process in the sheet counter 3 is completed, the counting result from the sheet counter 3 is acquired. When a single sheet counter 3 is used to perform many counting processes for the ticket type (small item), steps S14 to S17 are repeated.
Further, when counting the same number of tickets T of the same ticket type (small item) that can be loaded into the loading unit 22 at a time, the counting is automatically terminated once, and the setting screen 50 is returned to the same loading unit 22. If it is loaded again and a counting start button (not shown) of the operation unit 21 is pressed, counting is resumed.

When the operator presses the end button 58c on the setting screen 50, the counting result is displayed (step S18).
On the counting result display screen 60, scroll buttons 50c, 50d, 50e, 50f are prepared, and for each ticket type (small item) and counting machine ID set for counting processing (in FIG. 7B, counting machine ID). Is omitted).
In the ticket type column 60a, a ticket type (large item) and a ticket type (small item) are displayed, a serial number column (indicated as “serial No.” in FIG. 7B), an error code column (in FIG. 7). (B) displays “ERROR code”) 60c, a normal number field 60d, and an abnormal number field 60e.
The RFID tag identification information 41 (see FIG. 3) is displayed in the serial number column 60b, and the error code column 60c indicates “1”, which means that the RFID tag has not been read, and “I does not match the identification code 41a”. “2”, “3” indicating that the ticket type information is different from the input, or no error code indicating normal.
The counting result display screen 60 is displayed and a series of counting checks is completed.

Next, detailed control of step 16 in the flowchart of FIG. 6 will be described with reference to FIGS. 8 and 9.
8 and 9 are flowcharts showing the flow of control of the counting process for checking the received ticket in the single wafer counter. This control is performed in accordance with a control program read from the ROM by a CPU (not shown) in the control unit 31 shown in FIG.

  In step S101, in response to step S15 in the flowchart of FIG. 6 via the communication unit 32, the terminal body 5 sends a “counting check” mode signal and an identification code 41a of the RFID tag identification information 41 (see FIG. 3). The ticket type information 42 (see FIG. 3) is acquired. Accordingly, the control unit 31 controls the sheet counter 3 in the “count check” mode, and temporarily stores the acquired identification code 41a and ticket type information 42 in the flash memory.

In step S102, counting is started in the “counting check” mode, and the initial state is reset. Here, the reset in the initial state is to reset the counted number N _A in the counting unit 33, the counted number N _IS and the abnormal number N _ERROR based on the RFID tag information read by the first RFID tag R / W 35A (= 0) means that the sequence IERROR showing an error code _{(N a)} is reset (= 0). The argument N _A of IERROR (N _A ) is the number of tickets T counted by the counting unit 33, and is N _A = 1 to N _max (N _max : a maximum value set in advance in the program).

Then, a feeding mechanism operation command is issued to the feeding mechanism 26 (see FIG. 4) (step S103). In step S103, in the subsequent repetition, after the operation of step S118 or step S120 described later, a feeding mechanism operation command is output to the feeding mechanism 26. Specifically, the stepping motor M ₁ (see FIG. 5) is controlled to be driven and stopped by the counting sensors S1 and S2 (see FIG. 4) and the detection sensors S5 and S6.
That is, after the feeding mechanism 26 is driven, the counting sensors S1 and S2 stop when the detection signal of the ticket T is output, and when the detection sensors S5 and S6 output the detection signal of the ticket T, they are driven again. On the other hand, the motor M ₂ (see FIG. 5) that drives the rollers and the like of the conveyance path 29 (indicated by the conveyance path areas 29a to 29f in FIG. 4) starts the counting of the rollers and the like of the conveyance path 29 at a constant speed. Are driven continuously.

  In step S104, the flag is reset. Specifically, the flag IBFLAG when the RFID tag information of the RFID tag 7 attached to the ticket T cannot be read, and the flag ICFLAG when the RFID tag information is read but does not match the identification code 41a acquired from the terminal body 5 The RFID tag information is read and matches the identification code 41a, but the flag IDFLAG when the ticket type information 42 does not match is reset (= 0).

In step S105, the counting unit 33 checks whether or not the counting sensor S1 is turned on / off within a predetermined time and the counting sensor S2 is turned on / off within a predetermined time after step S103. This predetermined time is a time set by adding a sufficient margin to the time required for the ticket T to be delivered by the delivery mechanism 26 and reaching the counting unit 33, and the counting sensors S1 and S2 are within the required time. If it is not switched from ON to OFF (No), it means that there is no more ticket T in the loading unit 22, and the process proceeds to S121 according to the reference numeral (B). If the counting sensors S1 and S2 are turned from ON to OFF within the required time (Yes), the process proceeds to step S106, where the counting number N _A = N _A +1, which is the number of tickets T fed by the feeding mechanism 26, is set. It progresses to step S107 after step S106.

  In step S107, after counting the number of sheets to be fed, it is checked whether or not the detection sensor 3 is turned from ON to OFF within the first predetermined time window. In the first predetermined time window, the distance from the counting unit 33 to the position of the detection sensor S3 is set with a slight margin in the time required for the ticket T to be transported. If the detection sensor 3 is turned from ON to OFF within the first predetermined time window (Yes), the process proceeds to step S108, and if not (No), step S107 is repeated.

In step S108, an instruction to read RFID tag information is issued to the first RFID tag R / W 35A, and the RFID tag information is read from the first RFID tag R / W 35A.
In step S109, it is checked whether the RFID tag information has been read. If it can be read (Yes), the process proceeds to step S111. If it cannot be read (No), it is determined that the RFID tag 7 cannot communicate, and the process proceeds to step S110. When it is determined that the RFID tag 7 is incapable of communication, (1) the probability is small but the communication is simply failed, (2) the RFID tag 7 is not attached to the ticket T, (3) the RFID tag 7 is damaged, etc. A failure case can be considered.
In step S110, it flagged as IBFLAG = 1, placed IERROR _(N A) = 1 and the error code, then according to the sign of (A), the process proceeds to step S116.

In step S111, it is checked whether or not the identification code 41a of the RFID tag identification information 41 in the RFID tag information 40 (see FIG. 3) read in step S108 matches the identification code 41a acquired in step S101. To do. If they match (Yes), the process proceeds to step S113. If they do not match (No), it is determined that the RFID tag 7 does not include authentic identification information, and the process proceeds to step S112. When it is determined that the RFID tag 7 does not include the genuine identification information, (1) a probability is small but a simple communication error, and (2) the RFID tag 7 is forged or altered information.
In step S112, it flagged as ICFLAG = 1, placed IERROR _(N A) = 2 and error code, then according to the sign of (A), the process proceeds to step S116.

In step S113, it is checked whether or not the ticket type information 42 read in step S108 matches the ticket type information 42 acquired in step S101. If they match (Yes), the process proceeds to step S115. If they do not match (No), it is determined that the ticket types are different, and the process proceeds to step S114. In step S114, it flagged as IDFLAG = 1, placed IERROR _(N A) = 3 and the error code, then according to the sign of (A), the process proceeds to step S116.
If it does not match the ticket type information 42, a human error is conceivable, for example, when a ticket of another type is mixed in the bundle of tickets T to be counted.

In step S115, N _IS = N _IS +1, the normal number is added, and the process proceeds to step S116. In step S116, it is checked whether or not the detection sensor S6 is turned off and turned on within a predetermined time after the detection sensor S5 is turned off and turned on. If the detection sensor S6 is turned off and then turned on within a predetermined time after the detection sensor S5 is turned on, the process proceeds to step S117. If not (No), step S116 is repeated.
Here, the predetermined time is set with some allowance for the time required for the rear end of the ticket T to pass between the position of the detection sensor S5 and the position of the detection sensor S6.

In step S117, it is checked whether any of the flags IBFLAG, ICFLAG, and IDFLAG is set (= 1). If any of them stands (Yes), the process proceeds to step S119, and if not (No), the process proceeds to step S118.
In step S118, the frame 23d (see FIG. 4) of the first stacking unit 23 is set to the left position and held for a predetermined time. Thereafter, the process returns to step S103 according to the reference numeral (C).
If Yes in step S117, the abnormal number N _ERROR = N _ERROR +1 and one abnormal number are added in step S119, and the frame 23d of the first stacking unit 23 is set to the right position in step S120. Hold for hours. Thereafter, the process returns to step S103 according to the reference numeral (C).

  The holding time of the predetermined time in steps S118 and S120 is a time when a slight allowance is provided for the time until the ticket T reaches the first stacking unit 23 via the transport passage areas 29d and 29f after step S116. . As a result, normal tickets T whose flags IBFLAG, ICFLAG, and IDFLAG are 0 are accumulated on the right side of the first accumulation unit 23, and any of the flags IBFLAG, ICFLAG, and IDFLAG is = 1. 'Is accumulated while being shifted to the left side of the first accumulation unit 23, and the abnormal ticket T' and the normal ticket T are accumulated in a distinguishable manner.

After returning to Step S103 after Step S118 or Step S120, the next new ticket T is paid out from the payout mechanism 26, and a series of control from Step S104 to Step S120 is repeated.
For control, it is not necessary to wait for the holding time for holding the position of the frame 23d before returning to step S103 after step S118 or step S120. In the case of Yes in step S116, the process immediately returns to step S103 to issue a payout mechanism operation command and pay out the next ticket T, so that counting can be performed more quickly.

When there are no more tickets T stacked in the loading unit 22, No is determined in step S105, and the process proceeds to step S121 according to the reference numeral (B). In step S121, the counted number N _A , N _IS , N _ERROR is displayed on the display unit 25a. Then, the count result information is transmitted to the terminal body.
If the operator continues the counting process in the “counting check” mode of the ticket T of the same ticket type as before in this state, the ticket T is loaded again into the loading unit 22 and the counting of the operation unit 21 is started. When the button is pressed, the process returns to step S103, and the “counting check” mode is continued. At this time, values such as N _A , N _IS , and N _ERROR are inherited, and the count result information is added as it is as a series.

Thus, the processing of the “counting check” mode for a series of tickets T in the single wafer counter 3 is completed.
When performing a counting process in the “counting check” mode for a ticket T of another ticket type, it is necessary to start from step S101.
Here, the counted number N _A is the number of sheets loaded in the loading unit 22 of the ticket T, and N _ERROR is the number of abnormal tickets (abnormal paper sheets) in the counted number N _A ((b) of FIG. 7). is abnormal number value displayed in the column 60e) in a normal number of the N _iS counting number N _a value displayed in the normal number column 60d in (in FIG. 7 (b)).
Furthermore, by comparing the count number N _A and normal number N _IS, it may be alerting the operator to an alarm display on the display unit 25a or the display unit 25b if there is a difference, not shown in FIG. 5 Buzzer An alarm sound may be emitted by.

  The transport speed of each roller in the transport path 29, in particular the ticket T in the transport path area 29b, is such that the first RFID tag R / W 35A is in the RFID tag 7 while the ticket T passes between the detection sensors S3 and S4. As long as the RFID tag information can be read, the speed should be as high as possible. If this passing time is set to 0.2 seconds, for example, the RFID tag R / W 35A has sufficient communication time to communicate with the RFID tag 7.

  In the present counting process, step S101 in the flowchart constitutes the authentic identification information acquisition means described in the claims.

  As described above, according to the first counting process performed by the single-sheet counter 3 according to the present embodiment, the ticket T with the RFID tag 7 is received and inspected, the ticket T is fed out one by one, and the first RFID tag R / W35A can read the information, so that the RFID tag 7 is attached to the ticket T, the RFID tag 7 is not damaged, or the RFID tag identification information 41 written in the RFID tag 7 is authentic. Etc. can be checked reliably.

In particular, the position of the first RFID tag R / W 35A is determined after only one ticket T is allowed to flow through the transport passage areas 29a to 29c and the number of tickets T sent is checked by the counting sensors S1 and S2 which are optical sensors. The first RFID tag R / W 35A communicates with the TFID tag 7 at the timing when the ticket T is conveyed to the TFID tag 7, so there is no interference with the RFID tags 7 attached to the other tickets T, and one by one reliably. Can be checked based on the communication result.
In addition, a guide plate 22a and a marker 22b are provided in the loading unit 22 so that the antenna position of the first RFID tag R / W 35A matches the position of the RFID tag 7 attached to the ticket T in the horizontal direction in the ticket T. Therefore, reliable communication can be ensured.

Furthermore, compared with the number _{N A} ticket T which is counted by the counting sensor S1, S2, the number _{N IS} based on RFID tag information of the RFID tag 7 which has been read in the first RFID tag R / W35A, abnormal ticket T The presence / absence of an abnormal ticket T 'can be checked without counting the number of'. Then, what is determined to be an abnormal ticket T ′ through communication with the RFID tag 7 is that its contents (communication impossible, does not include the identification code 41a (possibility of fake ticket), and the ticket type information 42 does not match (incorrect ticket type). Error codes “1”, “2”, “3” are displayed in correspondence with distribution, mixing of different ticket types, etc.) Then, it is easy to perform manual sorting of the ticket T ′ thereafter, rereading confirmation by other RFID tags R / W, and the like.
As the counting sensor of claim, the counted number N _A ticket T on the light sensor, off, not limited to the counting sensor S1, S2. The number of operations of the feeding mechanism 26 controlled by the control unit 31 may be detected and counted.

<< Example of Second Counting Process >>
Next, using the sheet counter 3 in the present embodiment, for example, a second case in which a predetermined number of tickets T of a predetermined type are counted and sold to a customer at a sales agent or a ticket sales counter, for example. An example of the counting process will be described.
The operator activates the terminal body 5 and selects the “order” mode from the “order” mode for accepting purchases at the customer's counter and the “count check” mode of the ticket acceptance inspection process. The sales terminal device 1 is connected to the server 9 via the network 2.
FIG. 10 is a main flowchart showing the flow of control of the sales ticket counting process in the terminal body. FIG. 11 is a diagram showing a sales number input screen displayed on the main display unit of the display device, and FIG. 12 is a diagram showing a ticket issue detail screen displayed on the main display unit of the display device.

In step S <b> 21, the terminal body 5 displays a sales number input screen 70 as shown in FIG. 11, and accepts inputs such as a ticket type (paper sheet type) and the number of sheets.
Here, the ticket type (sheet type) and the number information correspond to the count instruction information described in the claims.
The sales quantity input screen 70 includes a menu column 70a and a setting condition column 70b. In the menu column 70a, a button 71 indicating “Order” which is a mode selection button and a button 72 indicating “Counting check” are prepared. Here, the button 72 is pressed and displayed with brightness indicating that the “order” mode is operating.

  The setting condition column 70b includes an icon button 74 for displaying selectable ticket types (major items), a combo box column 73 as a display column thereof, a handler column 75 for accepting manual input of a handler name, and a ticket type ( Small item) column, for example, "adult ticket" 76A, "middle ticket" 76B, "student discount ticket" 76C, "dwarf ticket" 76D, unit price column 77A, 77B corresponding to the ticket type (small item) column, respectively. , 77C, 77D, order quantity fields 78A, 78B, 78C, 78D, subtotal fields 79A, 79B, 79C, 79D, counter ID fields 80A, 80B, 80C, 80D, total field 81, and customer name manually A customer name field 82, a start button 83a, and an end button 83b are prepared.

For the ticket type (large item), ticket type (small item), unit price, etc., the identification code 41a of the RFID tag identification information 41, the ticket type information 42, etc. were previously acquired from the server 9 in the “count check” mode. It is data that is acquired at the same time and stored in the storage unit 5e (see FIG. 2). Then, at the sales counter, inventory management of various tickets is performed by an inventory management program installed in the terminal main body 5 or another personal computer (not shown) connected by a wireless LAN or the like, and the icon button 74 is pressed to store the tickets. It can be read out from the section 5e or from another personal computer and displayed in the combo box column 73 for selection.
Here, description will be made assuming that these data are stored in the storage unit 5e.

The icon button 74 is pressed to select and select the ticket type (major item) to be sold from the inventory data registered in the storage unit 5e. Then, a more detailed ticket type (small item) corresponding to the ticket type (large item), for example, “adult ticket”, “middle ticket” in the ticket type (small item) fields 76A, 76B, 76C, 76D, “Student discount ticket”, “Children ticket”, etc. are displayed. The corresponding unit price is displayed in the unit price columns 77A, 77B, 77C, 77D.
Then, from the displayed ticket type (small item) fields 76A, 76B,..., The order quantity fields 78A, 78B,. The number of orders received is manually input using the input device 4. Then, a subtotal of (unit price) × (number of sheets) is displayed in the subtotal column 79A, 79B,... Corresponding to the corresponding ticket type (subitem), and the total amount is also displayed in the total column in conjunction. The The ticket type (small item) column in which the number of orders is input changes to the color in the state where the color is selected.
The counter ID column 80A, 80B,... Is a column for specifying the ID of the sheet counter 3 by stacking the ticket T of the selected ticket type (small item) on the loading unit 22. is there.

  Incidentally, in the sales number input screen 70 illustrated in FIG. 11, only one ticket type (major item) is displayed, and below it, the ticket type (small item), unit price, order quantity, subtotal, and counter ID are displayed. However, when a plurality of ticket types (major items) icon buttons 74 and combo box fields 73 are displayed and a plurality of ticket types (major items) are set, the ticket type (major item) is always displayed thereunder. A pop-up window that displays (small item), unit price, order quantity, subtotal, and counter ID opens, and the total column 81 may be calculated for the plurality of ticket types (large items).

The start button 83a is a button for setting the ticket type (large item) and the ticket type (small item) and instructing the sheet counter 3 to which the counter ID is set to start counting. This button sets a counter ID corresponding to the ticket type (small item) and sends a count instruction to the set sheet counter 3 each time counting is performed over and over again. be able to.
The count results are accumulated in the storage unit 5e each time, and when the end button 83b is pressed, all the count results are displayed.

In the display state of the sales number input screen 70, the ticket type (large item) combo box field 73, the ticket type (small item) fields 76A, 76B,..., The order number fields 78A, 78B,. When the machine ID fields 80A, 80B,... Are set and the start button 83a is clicked with the mouse 4b (see FIG. 1), the ticket T of that type is changed from the storage unit 5e based on the ticket type (major item). The identification code 41a (see FIG. 3) in the RFID tag identification information 41 set for the attached RFID tag 7, the ticket type information 42 including information on the large item and the small item ticket type, and the storage unit 5e in advance. Is acquired (step S22, “Acquires identification code of RFID tag identification information corresponding to the ticket type, ticket type information and issuing store code from the storage unit based on the ticket type”). Based on the designation of the counter ID, the “order” mode signal, the identification code (authentication identification information) 41a of the RFID tag identification information 41, the ticket type information (the type of paper sheet) ), and transmits a POS information issuing store code and (shop information) date and time information, the number _{N R} (step S23). Here, the ticket type information (paper sheet type) and the number of sheets N _R correspond to the counting instruction information described in the claim, and the issuer code and date / time information as POS information are included in the sales information described in the claim. Correspond.

In step S24, the sheet counter 3 performs a counting process. The control in this process will be described in detail later with reference to the flowcharts shown in FIGS.
In step S25, when the counting process in the sheet counter 3 is completed, the counting result from the sheet counter 3 is acquired. When performing a lot of counting with respect to the ticket type (small item) using a single sheet counter 3, steps S <b> 23 to S <b> 25 are repeated.
In addition, when counting the number of tickets T of the same ticket type (small item) that can be loaded into the loading unit 22 at a time, the counting is automatically paused, loaded again into the same loading unit 22 and operated. If a counting start button (not shown) of the unit 21 is pressed, the counting is continued.

When the operator presses the end button 83b on the sales number input screen 70, ticket issue information and error information are displayed (step S26). The contents of ticketing information and error information will be described later.
The operator of the sales counter takes out the normal ticket T for which the counting has been completed from the first stacking unit 23 (see FIG. 1) of the sheet counting machine 3, and issues the ticket issue details appearing on the main display unit 6a (see FIG. 1). While confirming the order with the customer while viewing the screen 85 (see FIG. 12) and receiving money, hand over the ticket T.

At this time, first, a ticket issue detail screen 85 shown in FIG. 12 is displayed on the main display portion 6a. The ticket detailing screen 85 includes a customer name column 86, a ticket issuer name column 87a which is a name column of a store, a handler name column 87b, a ticket type (large item) column 88, and a ticket type (small item) column 89. (Displayed as 89A and 89B in the figure), unit price column 90 (displayed as 90A and 90B in the figure), number of sheets 91 (displayed as 91A and 91B in the figure), subtotal field 92 (in the figure, 92A and 92B), a total column 93, and an icon button 85a displaying "receipt print" are prepared.
The customer name field 86, the handler name field 87b, the ticket type (small item) field 89 (displayed as 89A and 89B in the figure), the unit price field 90 (displayed as 90A and 90B in the figure), The subtotal column 92 (displayed as 92A and 92B in the figure) and the total column 93 were inherited from the sales number input screen 70 by confirming input on the sales number input screen 70 (corresponding to pressing the end button 83b). The ticket issuer name column 87a is data stored in the storage unit 5e in advance.

In the sub-display unit 6b with the display screen facing the customer, the ticket type (major item) on the ticketing detail screen 85, (unit price) for each ticket type (small item) × (number of sheets) = (subtotal), ( Total) is displayed, and you can confirm the order with the customer and confirm the amount.
Thereafter, when the operator presses the button 85a displayed as “Print Receipt” on the ticketing details screen 85, the terminal body 5 transmits the contents of the ticketing details to the printer 8 and prints them (Step S27, Receipt Issue). Thereafter, the operator transmits ticket issue information and error information to the server 9 (step S28), and a series of counting processes in the “order” mode is completed.

  By the way, in the ticketing details screen 85 illustrated in FIG. 12, only one ticket type (major item) is displayed, and below it, the ticket type (small item), unit price, number of sheets, and subtotal are displayed. When multiple ticket types (major items) are set, a pop-up window that displays the ticket type (small item), unit price, number of orders, and subtotal is opened at any time. It may be calculated for each ticket type (large item).

Next, detailed control of step 24 in the flowchart of FIG. 10 will be described with reference to FIGS.
FIGS. 13 to 15 are flowcharts showing the control flow of the sales ticket counting process in the single wafer counter. This control is performed by a CPU (not shown) in the control unit 31 shown in FIG. 5 according to a control program read from the ROM.

In step S201, in response to step S23 in the flowchart of FIG. 10, the “main order” mode signal and the identification code (authentication identification information) 41a of the RFID tag identification information 41 are received from the terminal body 5 via the communication unit 32. (See FIG. 3), ticket type information (paper sheet type) 42 (see FIG. 3), issue store code (store information), date information, and number N _R are acquired. Thereby, the control unit 31 controls the sheet counter 3 in the “order” mode, and temporarily stores the acquired identification code 41a, ticket type information 42, issuing store code, and date / time information in the flash memory.
Here, the ticket type information 42 and the number of sheets N _R correspond to the count instruction information described in the claims, and the issue store code and date / time information as the POS information correspond to the sales information described in the claims.

In step S202, counting is started in the “order” mode, and the initial state is reset. Here, the reset in the initial state is determined as a normal ticket based on the counted number N _A in the counting unit 33, and reading and writing of RFID tag information by the first RFID tag R / W 35A and the second RFID tag R / W 35B. When the determined number N _IS and the abnormal number N _ERROR are respectively reset (= 0), the normal ticket T is set to a predetermined number, for example, a work argument I = 0 for making every 100 blocks, and it is determined as an abnormal ticket each flag IBFLAG to stand in, ICFLAG, IDFLAG, the reset respectively (= 0) IEFLAG, means that the sequence IERROR showing an error code _{(N a)} is reset (= 0).
The argument N _A of IERROR (N _A ) is the number of tickets T counted by the counting unit 33 and is up to N _A = 1 to N _max (N _max : the maximum value set in advance in the program).

For example, in order to control the sales ticket T in units of 100 in an easy-to-understand manner, in step S203, Imax = [N _R / 100] is calculated. Here, [X] is a mathematical operator and is the maximum integer not exceeding X of the real number X. Then, it is checked whether Imax is larger than 0, that is, whether _NR is a number of 100 or more (step S204). If Imax is greater than 0 (Yes), the process proceeds to step S205, and if not (No), the process proceeds to step S206.
In step S205, I = I + 1 and N _B = 100 × I + 1. Here, _{N B} denotes the first new hundred first ticket T to be stacked in the stacking unit 23 for containing the separated every 100 sheets, i.e., 101, 201 and 301, the ....

Then, a feeding mechanism operation command is issued to the feeding mechanism 26 (step S206). In this subsequent step S206, the feeding mechanism operation command is output to the feeding mechanism 26 after step S231 described later. Specifically, the motor _{M 1} is driven and stopped are controlled by the counting sensors S1, S2 and the detection sensor S5, S6.
That is, after the feeding mechanism 26 is driven, the counting sensors S1 and S2 stop when the detection signal of the ticket T is output, and when the detection sensors S5 and S6 output the detection signal of the ticket T, they are driven again. In contrast, the motor M ₂ for driving the rollers of the conveying path 29 continuously driving the rollers of the conveyance path 29 to count at the start after a certain speed.

In step S207, the counting unit 33 sets the counted number N _A = N _A +1, which is the number of tickets T fed by the feeding mechanism 26. Control of the count number N _A, since detailed description with respect to step S105, S106 of the flowchart shown in FIG. 8, a detailed description thereof will be omitted.

  In step S208, after counting the number of sheets to be fed, it is checked whether or not the detection sensor 3 is turned from ON to OFF within the first predetermined time window. If the detection sensor 3 is switched from ON to OFF within the first predetermined time window (Yes), the process proceeds to step S209, and if not (No), step S208 is repeated.

In step S209, an instruction to read RFID tag information is issued to the first RFID tag R / W 35A, and the RFID tag information is read from the first RFID tag R / W 35A.
In step S210, it is checked whether the RFID tag information has been read. If it can be read (Yes), the process proceeds to step S212. If it cannot be read (No), it is determined that the RFID tag 7 cannot communicate, and the process proceeds to step S211. If it is determined that the RFID tag 7 is incapable of communication, (1) the probability is small but the communication is simply failed, (2) the RFID tag 7 is not attached, (3) the RFID tag 7 is damaged, etc. Cases are considered.
In step S211, a flag is set as IBFLAG = 1, the number of abnormal sheets is added (N _ERROR = N _ERROR +1), an error code is entered with IERROR (N _ERROR ) = 1, and then step S222 is performed according to the sign of (3). Proceed to

In step S212, it is checked whether or not the identification code 41a of the RFID tag identification information 41 in the RFID tag information 40 (see FIG. 3) read in step S209 matches the identification code 41a acquired in step S201. To do. If they match (Yes), the process proceeds to step S214. If they do not match (No), it is determined that the RFID tag 7 does not include authentic identification information, and the process proceeds to step S213. When it is determined that the RFID tag 7 does not include the genuine identification information, (1) a probability is small but a simple communication error, and (2) the RFID tag 7 is forged or altered information.
In step S213, the flag is set as ICFLAG = 1, the abnormal number is added (N _ERROR = N _ERROR +1), an error code is entered with IERROR (N _ERROR ) = 2, and then in accordance with the sign of (3), step S222 is performed. Proceed to

In step S214, it is checked whether or not the ticket type information 42 read in step S209 matches the ticket type information 42 acquired in step S201. If they match (Yes), the process proceeds to step S216 according to the reference numeral (1). If they do not match (No), it is determined that the ticket types are different, and the process proceeds to step S215. If it does not match the ticket type information 42, a human error is conceivable, for example, when a ticket of another type is mixed in the bundle of tickets T to be counted.
In step S215, a flag is set as IDFLAG = 1, the number of abnormal sheets is added (N _ERROR = N _ERROR +1), an error code is entered with IERROR (N _ERROR ) = 3, and then in accordance with the sign of (3), step S222. Proceed to

  In step S216, after the detection sensor S4 is turned off to on, it is checked whether or not the detection sensor S5 is turned on to off within the second predetermined time window. Within this second predetermined time window, the distance from the position of the detection sensor S4 to the position of the detection sensor S5 minus the width of the ticket T is taken into account in the time required for the ticket T to be transported. Is set. If the detection sensor S5 is switched from ON to OFF within the second predetermined time window (Yes), the process proceeds to step S217, and if not (No), step S216 is repeated.

  In step S217, an instruction to write an RFID tag is issued to the second RFID tag R / W 35B, and POS information, for example, an issuer code and date / time information is written in the second RFID tag R / W 35B (second RFID tag). Tag R / W writes issuer code and date / time information).

In step S218, an instruction to read RFID tag information is issued to the second RFID tag R / W 35B, and whether or not the second RFID tag R / W 35B has read the POS information written in step S217 in the RFID tag information. (Issuance store code, date / time information can be read?). If it can be read (Yes), the process proceeds to step S220. If it cannot be read (No), the process proceeds to step S219. In step S219, IEFLAG = 1 is set as a flag, the number of abnormal sheets is added (N _ERROR = N _ERROR +1), an error code of IERROR (N _ERROR ) = 4 is input, and then the process proceeds to step S223.

In step S220, the branching claw 34a (see FIG. 4) is moved to the first stacking unit 23 side. That is, the ticket T that has passed through the transport passage area 29c is determined to be a normal ticket T, and is accumulated in the first stacking unit 23 via the transport path areas 29d and 29f. In step S221, the number of normal tickets is added (N _IS = N _IS +1).

When the process proceeds from step S211, S213, S215 to step S222, it is checked whether or not the detection sensor S6 is turned off and on within a predetermined time after the detection sensor S5 is turned off and turned on. If the detection sensor S6 is turned off and turned on within a predetermined time after the detection sensor S5 is turned off, the process proceeds to step S223. If not (No), step S222 is repeated.
Here, the predetermined time is set with some allowance for the time required for the rear end of the ticket T to pass between the position of the detection sensor S5 and the position of the detection sensor S6.

  In step S223, it is checked whether any one of the flags IBFLAG, ICFLAG, IDFLAG, and IEFLAG is set (= 1). If any of them stands (Yes), the process proceeds to step S224. If not (No), the process proceeds to step S226 according to the reference numeral (4).

  In step S224, the branch claw 34a is moved to the second stacking unit 24 side. That is, the ticket T that has passed through the transport passage area 29c is determined to be an abnormal ticket T 'and is stacked in the second stacking unit 24 via the transport path area 29e. In step S225, the flag is reset. Specifically, the flag IBFLAG when the RFID tag information of the RFID tag 7 attached to the ticket T cannot be read, and the RFID tag information can be read, but are included in the identification code 41a and the RFID tag information acquired from the terminal body 5. The flag ICFLAG when the identification code 41a does not match and the RFID tag information are read and the identification code 41a matches, but the ticket type information 42 acquired from the terminal body 5 and the ticket type information 42 included in the RFID tag information do not match. Flag FLAG in the case where the POS information was written in step S217, but the flag IEFLAG in the case where the POS information which should have been written in the subsequent step S218 could not be read (POS information writing failure) is reset ( = 0).

In step S226, it is checked whether Imax is greater than zero. If it is greater than 0 (Yes), the process proceeds to step S227, and if not (No), the process proceeds to step S231. In step _S227, checks whether or not _N IS = N _B. For _{N IS} = N _B (Yes), the process proceeds to step S228, otherwise (No), the processing proceeds to step S231.
In step S228, the frame body 23d of the first stacking unit 23 is moved to a side different from the current position. That is, if the current position is the left position, the position is moved to the right position. If the current position is the right position, the position is moved to the left position.

As a result, the normal tickets T accumulated in the first accumulation unit 23 are accumulated with a deviation of left and right in units of 100 sheets. In step S229, I = I + 1 and then N _B = 100 × I + 1 (step S230). In step S231 after step S230, the normal ticket number _{N IS} checks whether a number _{N R} above. If normal ticket number _{N IS} is more than the number _{N R} (Yes), the process proceeds to step S232, otherwise (No), (2) code according Returning to step S226 of feeding the next new ticket T The system 26 is fed out from the mechanism 26, and a series of control from step S226 to step S231 is repeated.

In step S232, the display unit 25a counts the number _{N IS} based on RFID tag information, the display unit 25b displays an abnormal number _{N ERROR} (ticketing number _{N IS} and abnormal number _{N ERROR} display). And count result information is transmitted to the terminal main body 5 (step S233).

Next, ticket issue information and error information displayed on the main display unit 6a by the terminal body 5 based on the count result information transmitted from the sheet counter 3 to the terminal body 5 in step S233 will be described.
FIG. 16 is a diagram for explaining a ticket issuing information screen. The ticket issue information screen 95 includes, for example, a ticket type (large item) column 96, a ticket type (small item) column 97 (indicated as 97A and 97B in the figure), and a serial number column 98 (in the figure, “Serial No.”). ”And 98A and 98B) and a number field 99 (displayed as 99A and 99B in the figure).
FIG. 17 is a diagram for explaining an error information screen. The error information screen 100 includes, for example, a ticket type (large item) column 101, a ticket type (small item) column 102A, and a tabular error code information column 104A. The error code information column 104A includes an abnormal number serial number column 104Aa, a code column 104Ab, and a serial number column 104Ac (indicated as “Serial No.” in the drawing), and an error code is displayed for each abnormal ticket T ′. The serial number can be read in association with it.

Thus, a series of counting processes in the “order” mode is completed.
When the counting process in the “order” mode is performed for a ticket T of another ticket type, it is necessary to start from step S201.
The transport speed of each roller in the transport path 29, particularly the ticket T in the transport path areas 29b and 29c, is determined so that the first RFID tag R / W 35A is the RFID tag while the ticket T passes between the detection sensors S3 and S4. The RFID tag information of the RFID tag 7 is written and read by the second RFID tag R / W 35B while the ticket T passes between the detection sensors S5 and S6. If it is possible, it should be as fast as possible. If this passing time is set to 0.2 seconds, for example, the RFID tag R / W 35A, 35B is sufficient for communication with the RFID tag 7.

In this counting process, step S21 in the flowchart corresponds to the input unit for counting instruction information recited in the claims, and step S23 corresponds to the counting instruction information output unit recited in the claims.
The portion of the "acquisition of the identification sign of the RFID tag identification information" in step S201 of the flowchart corresponds to the authentic identification information acquiring means according to claim, part of the "note denomination information, acquisition of the number N _R" is claimed Corresponding to the counting instruction acquisition means described in the section, the “acquisition of issuer code and date / time information” portion constitutes the sales information acquisition means described in the claims.

  As described above, according to the second counting process by the single-sheet counter 3 according to the present embodiment, the ticket T is fed out one by one in the counter sales of the ticket T with the RFID tag 7, and the first RFID tag R / W35A can read the information, so that the RFID tag 7 is attached to the ticket T, the RFID tag 7 is not damaged, or the RFID tag identification information 41 written in the RFID tag 7 is authentic. Etc. can be checked reliably.

  Further, the writing of the POS information to the RFID tag 7 is made to the second RFID tag R / W 35B, and the function of the POS information is separated from the check of the RFID tag identification information 41 by the first RFID tag R / W 35A. The RFID tag 7 can be written and confirmed with certainty.

In particular, the position of the first RFID tag R / W 35A is determined after only one ticket T is allowed to flow through the transport passage areas 29a to 29c and the number of tickets T sent is checked by the counting sensors S1 and S2 which are optical sensors. The first RFID tag R / W 35A communicates with the TFID tag 7 at the timing when the ticket T is conveyed to the TFID tag 7, so there is no interference with the RFID tags 7 attached to the other tickets T, and one by one reliably. Can be checked based on the communication result.
The second RFID tag R / W 35B communicates with the TFID tag 7 at the timing when the ticket T is transported to the position of the second RFID tag R / W 35B after the position of the ticket T is checked by the detection sensors S4 and S5. Therefore, there is no interference with the RFID tags 7 attached to the other tickets T, and the check can be made reliably based on the communication result with each one.
In addition, the loading plate 22 is provided with a guide plate 22a and a marker 22b so that the antenna positions of the first and second RFID tags R / W 35A and 35B and the position of the RFID tag 7 attached to the ticket T are matched. Reliable communication can be secured.

  Further, what is determined as an abnormal ticket T ′ through communication with the RFID tag 7 is that the contents (communication is impossible, does not include the identification code 41a (possibility of fake ticket), and the ticket type information 42 does not match (incorrect ticket type). The error codes “1”, “2”, “3”, “4” are displayed in correspondence with the distribution, mixing of different ticket types, etc.), the POS information writing failure), and the second stacking unit 24 Therefore, not only the subsequent manual sorting of the ticket T ′ and the rereading confirmation by another RFID tag R / W but also the first stacking unit in which only the normal ticket T is stacked is facilitated. 23 tickets T can be quickly handed to customers.

  In addition, since the ticket T ′ in which the POS information has failed to be written is not issued, when the customer returns the ticket after purchase, the ticket T issued without fail from the POS information recorded on the RFID tag 7 is surely issued. It is easy to avoid troubles when the ticket T is returned and cleared. Furthermore, since the POS information is reliably recorded in the analysis using the POS information of the ticket T collected after the customer uses the ticket T, the used ticket sampling efficiency is improved.

  In the present embodiment, the bill-type ticket T has been described as an example, but it can also be applied to a card-type ticket.

<Modification>
(Another usage of the second counting example)
Furthermore, using the example of the second counting process, the single wafer counter 3 can be easily used as a function of the sorter. That is, the concept of distinguishing between a normal ticket T and an abnormal ticket T ′ is based on the RFID tag-added ticket T in which specific ticket type information 42 is recorded and the RFID tag-added ticket T ′ in which other ticket type information 42 is recorded. It is sufficient to re-read and perform counting processing.
At this time, the communication radio waves between the RFID tags R / W 35A, 35B and the 35 RFID tag 7 easily pass through the ticket T, so there is no need to align the front and back of the ticket T.
(First modification)
If the antennas of the RFID tags R / W 35A and 35B are provided so as to cover two or two places in the width direction of the transport passage 29, the position of the RFID tag 7 of the ticket T loaded in the loading unit 22 can be determined. There is no need to align the left and right directions of the tickets T on either side.

(Second modification)
In the present embodiment, the identification code 41a, which is authentic identification information, is the digit above the RFID tag identification information 41 recorded on the IC chip 7a when the RFID tag 7 is manufactured, but is not limited thereto. When the entire RFID tag identification information 41 is a serial number, the whole RFID tag identification information 41 is used as the genuine identification information, and whether or not it is authentic depending on whether the serial number is a predetermined assigned number or not. You may make a judgment. Further, the ticket type information 42 itself may be used as an identification code 41a which is authentic identification information.

(Third Modification)
Incidentally, although the counting sensors S1 and S2 and the detection sensors S3 to S6 are optical sensors in combination of a light emitting element and a light receiving element in the present embodiment, the present invention is not limited thereto. A sensor using a microswitch may be used.
Further, instead of configuring the counting unit 33 of the single wafer counter 3 with the counting sensors S1 and S2, it may be configured with the detection sensors S3 and S4 by deleting it. In that case, the sheet counter 3 can be shortened by the conveyance passage area 29a.
Further, the first RFID tag R / W 35A and the twenty-first RFID tag R / W 35B may be used together. At that time, it is necessary to consider the communication time between the RFID tag 7 and the RFID tag R / W. As a means, as a stepping motor is also the motor M ₂ for driving the rollers to place the transport passage 29, at the location of the RFID tag R / W, it may be a drive control of the roller, such as to stop short time ticket T time.
If it does in that way, the conveyance channel | path 29 can be shortened further and the sheet | seat counter 3 can be reduced in size.

(Fourth modification)
Further, a sheet count for classifying a bundle of tickets T in which three or more types of tickets are mixed into two types of tickets T1 and T2 specified at a time and tickets T 'of other types of tickets. It is also easy to make a machine.
In that case, it is sufficient to provide not only the first and second stacking units 23 and 24 but also a third stacking unit having the same configuration as the first. At this time, the second branch claw is added to the downstream side of the conveyance passage 29 of the branch claw 34a, and a conveyance passage for conveying the ticket T from the second branch claw to the third stacking unit is added. This can be realized by preparing a detection sensor immediately before the branch claw and controlling the timing of driving the branch claw by the detection signal from the detection sensor.

(Fifth modification)
In addition, in order to confirm that the number of each ticket type of the ticket T is correct, the sales staff manually prepares one or more types of ticket T ordered by the customer. 11 are stacked on the loading unit 22 and read, and then the result of reading the ticket type is displayed in the order quantity fields 78A, 78B,. .. etc., and the subtotal columns 79A, 79B,... And the total column 81 can be easily calculated. Then, the sales amount can be presented to the customer on the sub-display unit 6b, and the customer can be confirmed that it is definitely in accordance with the breakdown of the order quantity of the customer.

If the above-described configuration is combined with the first modification, the ticket type of the collected ticket can be easily read by reading the RFID tag information without arranging the front, back, left and right, and whether it is authentic or not. Can be classified.
Therefore, it is necessary to store the identification determination information for the front and back sides in the control unit of the single-sheet counter in order to determine whether or not it is authentic by the print pattern, color, etc., as in the case of banknote identification, and to determine the type of banknote. This makes it easy to control identification determination. It can also be applied to banknotes with RFID tags 7 attached.

(A) is a figure which shows the sales terminal device concerning embodiment of this invention, (b) is a block diagram of the banknote-type ticket with RFID. It is a block diagram of a sales terminal device. It is a figure explaining the example of the RFID tag information recorded on the RFID tag attached to the ticket. (A) is a schematic left cross-sectional view showing the internal structure of the tabletop type sheet-fed counter in the present embodiment, and (b) is a front view of the same. FIG. 5 is a block diagram of the control circuit. It is a block diagram of the control circuit of a single wafer counter. It is a main flowchart which shows the flow of control of the counting process of the check of the receipt ticket in a terminal main body. It is a figure explaining the operation screen displayed on the main display part of a display apparatus, (a) is a figure which shows the setting screen of a count check, (b) is a figure which shows a count result. It is a flowchart which shows the flow of control of the counting process of the check of the receipt ticket in a single wafer counter. It is a flowchart which shows the flow of control of the counting process of the check of the receipt ticket in a single wafer counter. It is a main flowchart which shows the flow of control of the count process of the sales ticket in a terminal main body. It is a figure which shows the sales number input screen displayed on the main display part of a display apparatus. It is a figure which shows the ticketing detail screen displayed on the main display part of a display apparatus. It is a flowchart which shows the flow of control of the count process of the sales ticket in a single wafer counter. It is a flowchart which shows the flow of control of the count process of the sales ticket in a single wafer counter. It is a flowchart which shows the flow of control of the count process of the sales ticket in a single wafer counter. It is a figure explaining a ticket issue information screen. It is a figure explaining an error information screen.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Sales terminal device 2 Network 3 Single wafer counter 3a Front surface 3b Back surface 4 Input device 5 Terminal main body 5a CPU
5b bus 5c ROM
5d RAM
5e storage unit 5f communication unit 5h network communication unit 6 display device 6a main display unit 6b sub display unit 7 RFID tag 8 printer 9 server 21 operation unit 22 loading unit 22a guide plate 22b marker 23 first stacking unit 23d frame 24 second 2 stacking sections 25a, 25b Display section (display section)
26 Feeding mechanism 27 Gate portion 28 Transport rollers 29a to 29f Transport passage area (transport passage)
31 control unit 32 communication unit 33 counting unit 34 branching unit 34a branching claw 35A first RFID tag R / W (tag reader, communication means)
35B Second RFID tag R / W (tag reader, communication means)
37 Moving mechanism 40 RFID tag information 41 RFID tag identification information 41a Identification code (authentication identification information)
41b Serial Number 42 ticket type information 43 POS information 43a store information 43b sales date and time information 50 setting screen 60 counted result display screen 70 of sheets sold input screen 95 ticketing information screen 100 error information screen M ₁ stepping motor M ₂ motor S1a, S2a emission Element (counting sensor)
S1b, S2b Light receiving element (counting sensor)
S3a, S4a, S5a, S6a Light emitting element (detection sensor)
S3b, S4b, S5b, S6b Light receiving element (detection sensor)
SD ₁ and SD ₂ solenoid T ticket (paper sheets)
T 'Abnormal ticket (abnormal paper sheet)

Claims (8)

A feed-out mechanism that feeds out paper sheets with RFID tags to be identified and counted one by one;
A counting sensor for counting the paper sheets fed out;
A tag reader for reading RFID tag information recorded on the RFID tag attached to the paper sheet to be fed;
A sheet counter. Loading sheets having RFID tags to be identified and counted are loaded in a stacked state, and having a feeding mechanism for separating and feeding the loaded sheets one by one;
A transport path for transporting the paper sheet fed from the loading unit;
A counting sensor for counting the paper sheets provided in the conveyance path one by one;
A communication means provided in the transfer passage and communicating with the RFID tag;
A stacking unit configured to stack the paper sheets conveyed in the conveyance path at a position below the loading unit and to remove the paper sheets from the front surface of the machine body;
A display for displaying the counting results;
A control unit for controlling the counting process,
The controller is
A sheet-fed counter which displays on the display unit a result of a counted number based on a signal from the counting sensor and a result of a counted number based on a result of the communication means communicating with the RFID tag. The controller is
Furthermore, it has authentic identification information acquisition means for acquiring authentic identification information indicating that the paper sheet is authentic,
As a result of the communication means communicating with the RFID tag, at least the RFID tag that cannot be communicated or the paper sheet to which the RFID tag not including the authentic identification information is attached is regarded as an abnormal paper sheet. As well as being accumulated in the accumulation part in distinction from
3. The sheet counter according to claim 2, wherein the number of the other sheets excluding the abnormal sheets is counted. The controller is
The paper sheet that is distinguished from the abnormal paper sheet is classified into at least the “communication impossible” and the “not including authentic identification information”, and the counting result is displayed on the display unit. The single wafer counter according to 3. The controller is
Furthermore, it comprises counting instruction acquisition means for acquiring counting instruction information including the type and number of sheets.
Based on the acquired count instruction information, the communication means confirms whether the type indicated by the count instruction information from the RFID tag information, counts a predetermined number, and accumulates it in the accumulation unit. The single wafer counter according to claim 3 or 4. The controller is
Furthermore, it has a sales information acquisition means for acquiring sales information including store information,
For the RFID tag attached to the other paper sheet that was not distinguished from the abnormal paper sheet by the communication means, the sales information was written to the communication means, and it was confirmed that the information was written. The sheet counting machine according to any one of claims 3 to 5, wherein the sheets are counted as sheets that can be sold and stacked in the stacking unit. The sheet counter according to claim 6, which counts paper sheets attached with RFID tags to be identified and counted;
An input device for inputting the number of paper sheets;
A storage unit that stores type information indicating the type of the paper sheet and authentic identification information indicating that the paper sheet is authentic;
A display device for displaying the type of the paper sheet and the input number of sheets;
A sales terminal device comprising: a terminal body that is communicably connected to the sheet counter and controls a counting process of the sheet counter;
The terminal body is
Counting instruction information input means for enabling selection of a corresponding type from among the types of the paper sheets displayed on the display screen of the display device, and input of the number of sheets;
Counting instruction information output means for outputting the counting instruction information to the single wafer counter,
The authentic identification information is read from the storage unit corresponding to the selected type of the paper sheet, and output to the sheet counter together with the counting instruction information,
Let the sheet counter check whether the authentic identification information is included in the RFID tag attached to the paper sheet by the input number of the paper sheets of the selected type. Sales terminal device characterized in that it is counted. A counting method in a sheet counter for counting paper sheets with an RFID tag to be identified and counted,
The control unit
A step of counting one sheet at a time based on a detection signal from a counting sensor;
Counting one by one based on the RFID tag information read from the RFID tag attached to the paper sheet by the tag reader;
A counting method in a single wafer counter comprising a step of comparing a counting result based on a detection signal from the counting sensor and a counting result based on the RFID tag information read by the tag reader.

Images