JP2016010711A - Token processing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a highly usable token processing device capable of accommodating to wide variety of tokens.SOLUTION: The token processing device includes: a supply part in which tokens are supplied; delivery means for delivering the tokens supplied in the supply part one by one; discrimination means for discriminating a type of a token delivered by the delivery means; and distribution means for distributing the token to a distribution destination corresponding to the discrimination result of the discrimination means. The distribution destination consists of at least three distribution destinations, a first distribution destination, a second distribution destination, and a third distribution destination. The discrimination means discriminates tokens into at least three types, a first token, a second token, and a third token. The distribution means distributes tokens to distribution targets corresponding to the types of the tokens on the basis of the discrimination result of the discrimination means.

Description

  The present invention relates to a medal processing device.

  There is a game store in which a gaming machine capable of playing using medals is installed in a game store. In Patent Document 1 below, there is a medal counting machine that counts medals acquired by a customer using a game machine in a game store. It is disclosed. The medal counter is provided with a medal hopper into which medals are inserted, a transport path for transporting medals inserted into the medal hopper, and a medal determination unit for determining the type of medals transported through the transport path. . The medal includes a medal (own store medal) of an amusement store (own store) in which a medal counter is installed, and a medal (other store medal) of a store other than the own store. It is possible to determine whether the medal transported is the own store medal or the other store medal. The transport path is branched into the own store medal transport path and the other store medal transport path on the way, and the medal determined to be the own store medal by the medal determination unit is transported through the own store medal transport path, and the medal determination unit The medals determined as other store medals are collected in the other store medal collection box after being transported through the other store medal transport path.

JP 2007-14625 A

In the medal counting machine of Patent Document 1, only two types of medals can be determined and distributed. There are many types of medals beyond that, so it is convenient to use a variety of medals that can be dealt with in detail according to each type.
The present invention has been made under such a background, and an object of the present invention is to provide a medal processing device that can handle various types of medals and is easy to use.

  The invention according to claim 1 is an insertion unit into which medals are inserted, a feeding unit that feeds out medals inserted into the insertion unit one by one, and a discriminating unit that discriminates the type of medals fed out by the feeding unit. Distribution means for distributing medals to the distribution destination corresponding to the determination result of the determination means, and the distribution destination is at least one of the first distribution destination, the second distribution destination, and the third distribution destination. It consists of three distribution destinations, and the determination means determines at least three types of medals: a first medal, a second medal, and a third medal, and the distribution means determines the determination result of the determination means. Based on the above, the medal processing device is characterized in that medals are distributed to the distribution destinations corresponding to the types of medals.

The invention according to claim 2 is characterized in that the first distribution destination is a return unit that is discharged outside the apparatus, and is a distribution destination to which the first medal determined by the determination unit is distributed. The medal processing device according to claim 1.
According to a third aspect of the present invention, the discriminating unit discriminates the type of medal and also a foreign matter different from the medal, and the sorting unit distributes the foreign matter to the first sorting destination. The medal processing device according to claim 2, wherein:

  According to a fourth aspect of the present invention, regarding the types of medals discriminated by the discriminating means, the first medal is another store medal, the second medal is a group store medal, and the third medal is own store. The medal processing device according to claim 1, wherein the medal processing device is a medal.

FIG. 1 is a diagram showing a medal deposit / payment system 1 provided in an amusement store. FIG. 2 is a perspective view of the medal depositing machine 2. FIG. 3 is a control circuit block diagram of the medal deposit system 1, and is a block diagram showing only a part related to the feature of the present invention. FIG. 4A is a diagram illustrating the member table 50. FIG. 4B is a diagram showing the attendant table 51. FIG. 4C is a diagram illustrating the finger vein data table 52. FIG. 4D is a diagram illustrating the history table 53. FIG. 5A is a diagram illustrating display contents of the display operation unit 16 of the medal deposit machine 2 when registering as a member. FIG. 5B is a diagram showing the display contents of the display operation unit 16, and shows the display contents at the next stage of FIG. 5A. FIG. 5C is a diagram showing the display contents of the display operation unit 16, and shows the display contents at the next stage of FIG. 5B. FIG. 5D is a diagram showing the display content of the display operation unit 16, and shows the display content in the next stage of FIG. 5C. FIG. 5E is a diagram showing the display content of the display operation unit 16, and shows the display content in the next stage of FIG. 5D. FIG. 5F is a diagram showing the display contents of the display operation unit 16, and shows the display contents at the next stage of FIG. 5E. FIG. 5G is a diagram showing the display contents of the display operation unit 16, and shows the display contents at the next stage of FIG. 5F. FIG. 5H is a diagram showing the display content of the display operation unit 16, and shows the display content in the next stage of FIG. 5G. FIG. 5I is a diagram showing the display contents of the display operation unit 16 and shows the display contents at the next stage of FIG. 5H. FIG. 6A is a diagram illustrating display contents of the display operation unit 16 of the medal deposit machine 2 when depositing medals. FIG. 6B is a diagram showing the display contents of the display operation unit 16, and shows the display contents in the next stage of FIG. 6A. FIG. 6C is a diagram showing the display contents of the display operation unit 16, and shows the display contents in the next stage of FIG. 6B. FIG. 6D is a diagram showing the display contents of the display operation unit 16, and shows the display contents in the next stage of FIG. 6C. FIG. 6E is a diagram showing the display contents of the display operation unit 16, and shows the display contents in the next stage of FIG. 6D. FIG. 6F is a diagram showing the display contents of the display operation unit 16, and shows the display contents at the next stage of FIG. 6E. FIG. 6G is a diagram showing the display content of the display operation unit 16, and shows the display content in the next stage of FIG. 6F. FIG. 6H is a diagram showing the display contents of the display operation unit 16, and shows the display contents at the next stage of FIG. 6G. FIG. 7A is a diagram showing display contents of the display operation unit 16 of the medal deposit machine 2 when paying out medals. FIG. 7B is a diagram showing the display contents of the display operation unit 16, and shows the display contents at the next stage of FIG. 7A. FIG. 7C is a diagram showing the display contents of the display operation unit 16, and shows the display contents in the next stage of FIG. 7B. FIG. 7D is a diagram showing the display contents of the display operation unit 16, and shows the display contents in the next stage of FIG. 7C. FIG. 7E is a diagram showing the display contents of the display operation unit 16, and shows the display contents in the next stage of FIG. 7D. FIG. 7F is a diagram showing the display contents of the display operation unit 16, and shows the display contents at the next stage of FIG. 7E. FIG. 7G is a diagram showing the display contents of the display operation unit 16, and shows the display contents in the next stage of FIG. 7F. FIG. 7H is a diagram showing the display content of the display operation unit 16, and shows the display content in the next stage of FIG. 7G. FIG. 8 is a flowchart showing a control operation performed in the medal depositing machine 2B of the child machine. FIG. 9 is a flowchart showing a control operation performed in the medal depositing machine 2A of the parent machine. FIG. 10 is a diagram for explaining processing executed in the medal deposit / payment system 1 when the medal deposit / payment system 1 is activated. FIG. 11A is a diagram for explaining processing performed in the medal deposit / payment system 1 when a transaction related to depositing / dispensing medals is performed in the medal depositing machine 2. FIG. 11B is a diagram for explaining a process performed in the medal deposit / payment system 1 when the medal deposit machine 2 performs a transaction related to depositing / dispensing medals. FIG. 12 is a diagram for explaining processing performed in the medal depositing system 1 when member registration is performed in the medal depositing machine 2. FIG. 13 is a diagram showing the member table 50. FIG. 14 is a diagram showing the display contents (first mode) of the display operation unit 16 when inputting the number of payouts. FIG. 15 is a diagram showing display contents (second mode) of the display operation unit 16 when inputting the number of payouts. FIG. 16 is a schematic diagram showing how the medals M inserted into the medal deposit machine 2 are distributed. FIG. 17 is a block diagram of the control circuit of the medal depositing machine 2, and is a block diagram showing only the parts related to the features of the present invention. FIG. 18 is a flowchart showing a control operation performed regarding the distribution of medals in the medal deposit machine 2.

Embodiments of the present invention will be specifically described below with reference to the drawings.
FIG. 1 is a diagram showing a medal deposit / payment system 1 provided in an amusement store.
Referring to FIG. 1, a medal depositing system 1 (medal paying system) is provided in a game store such as a game arcade. The medal deposit system 1 includes a plurality (here, five) medal deposit machines 2 (medal dispensing machines), a management device 3, and a network 4 configured by a wired or wireless communication line.

  The medal deposit machine 2 is a device that can deposit and pay out medals used in games. Each medal deposit machine 2 is connected to be communicable via a network 4. Any one of the plurality of medal deposit machines 2 is set as the master unit 2A, and the remaining medal deposit machines 2 are set as the slave units 2B. The master unit 2A recognizes that it is a master unit, and the slave unit 2B recognizes which medal depositing machine 2 the master unit 2A is. The setting of the master unit 2A and the slave unit 2B is performed in advance at a predetermined timing such as when the medal deposit system 1 is activated.

  The management device 3 is a device for managing these medal deposit machines 2, and is arranged in a staff office in a game store. The management device 3 is communicably connected to all the medal deposit machines 2 via the network 4. A relay hub 5 is interposed between the management device 3 and all the medal depositing machines 2 in the network 4, and the relay hub 5 relays communication between the management device 3 and each medal depositing machine 2. Also good. Based on the transaction status of each medal deposit machine 2, the management device 3 can analyze the transaction tendency, the customer base, and the like regarding medal deposits and withdrawals at the entire amusement store.

Next, the medal deposit machine 2 will be described.
FIG. 2 is a perspective view of the medal depositing machine 2.
With reference to FIG. 2, the medal deposit machine 2 has a vertically long box shape. The left front side in FIG. 2 is the front of the medal deposit machine 2. Below, each part of the medal teller machine 2 is demonstrated on the basis of the time when the medal teller machine 2 is seen from the front side.

The medal teller 2 includes a main body 10 that forms an outline thereof. The front portion of the main body 10 includes a front vertical surface 11 extending substantially vertically and an inclined surface 12 extending inclined from the upper end of the front vertical surface 11 to the rear upper side.
On the front vertical surface 11, a medal payout opening 13 is provided on the upper left side. Two cup holders 14 are provided to the right of the medal payout opening 13 on the front vertical surface 11. Each cup holder 14 has a U-shaped frame shape that bulges from the front vertical surface 11 to the front side.

  Here, in relation to the medal deposit machine 2, the game store has a medal cup 15 that accommodates medals (see the cup holder 14 on the right side). When the entire medal cup 15 is accommodated in the medal payout opening 13, medals paid out to the medal payout opening 13 are poured directly into the medal cup 15. The medal cup 15 can be temporarily held in the cup holder 14 by inserting the medal cup 15 containing medals or the empty medal cup 15 into each cup holder 14 from above. On the front vertical surface 11, a return port 24 (return unit) is provided next to the medal payout opening 13. When a medal from a store (other store) other than the amusement store (own store) where the medal teller 2 is installed or a foreign matter other than a medal is inserted into the medal teller 2, these medals or foreign matter Is rejected from the return port 24 and paid out.

  In the inclined surface 12, the substantially left half is slightly depressed, and a rectangular display operation unit 16 (setting unit, reception unit, display unit) having a touch panel display is provided in the depression. The display operation unit 16 displays information for customers and staff (information on depositing and paying out medals) and touch keys (not shown) that can be operated by the customers and staff. By operating the display operation unit 16, for example, an arbitrary one of the plurality of medal deposit machines 2 can be set as the master unit 2A (see FIG. 1), or the number of medals to be paid out (the number of payouts) can be designated. (Input). On the right half of the inclined surface 12, a medal depositing port 17 (inserting portion) is provided. The medal to be deposited is inserted into the medal depositing port 17. Note that when the medal deposit is not performed, the medal deposit port 17 is closed by the shutter 18. A finger vein authentication unit 19 is provided at the upper left of the medal deposit door 17 on the inclined surface 12. The finger vein authentication unit 19 is provided with a finger setting unit 19A that is recessed in a concave shape. When the customer or the clerk sets his / her finger on the finger setting unit 19A, the finger vein pattern of the finger is read by the finger vein authentication unit 19, and the customer or the clerk uses the finger vein pattern data (finger vein data). Will be verified.

The main body 10 is provided with a right vertical surface 20 that extends vertically from the right end of the front vertical surface 11 and the inclined surface 12 to the rear side. A medal replenishment door 21 is provided on the right vertical surface 20 so as to be openable and closable. By opening the medal replenishment door 21, the inside of the main body 10 can be accessed and replenished medals can be replenished in the main body 10.
Further, when the inclined surface 12 is regarded as a part of the upper surface 22 of the main body 10, the upper surface 22 has a trapezoidal shape that protrudes upward as viewed from the width direction. A portion of the upper surface 22 forming the upper base of the trapezoid is at a position slightly deviated from the center in the front-rear direction of the main body 10, and a plate-like convex portion 23 that protrudes upward in the width direction is formed in this portion. It is provided integrally. On the convex portion 23, a sign indicating that it is the medal deposit machine 2, an advertisement of a game store, and the like are displayed.

Next, an electrical configuration in the medal deposit system 1 will be described.
FIG. 3 is a control circuit block diagram of the medal deposit system 1, and is a block diagram showing only a part related to the feature of the present invention.
With reference to FIG. 3, the electrical configurations of the management device 3 and the medal depositing machine 2 in the medal depositing system 1 will be described in this order.

The management device 3 includes a control unit 30 (update means). The control unit 30 is configured by a ROM, a RAM, and the like that store a CPU and its program, and executes predetermined processing such as arithmetic processing according to the program.
In the management device 3, the display unit 31, the operation unit 32 (setting unit), the DB (database) 33 (storage device), and the communication I / F (interface) unit 34 are mainly provided to the control unit 30. Are electrically connected.

  The display unit 31 is, for example, a monitor that displays various information (see also FIG. 1). The operation unit 32 is, for example, a keyboard (see FIG. 1), and a predetermined signal can be input to the control unit 30 by operating this. By operating the operation unit 32, for example, any one of the plurality of medal deposit machines 2 can be set as the parent machine 2A (see FIG. 1). Various information can be recorded in the DB 33. Through the communication I / F unit 34, the control unit 30 is connected to the network 4 and can communicate with each medal deposit machine 2.

The medal deposit machine 2 includes a control unit 40 (detection means, execution means, notification means, transmission means, display control means, calculation means, count means, exclusion means). The control unit 40 is configured by a ROM, a RAM, and the like that store a CPU and its program, and executes predetermined processing such as arithmetic processing according to the program.
In the medal depositing machine 2, the display unit 16, the finger vein authentication unit 19, the depositing unit 41, the paying unit 42 (paying means), and the counting unit 43 are mainly provided to the control unit 40. The memory unit 44 (backup means) and the communication I / F unit 45 are electrically connected.

Display processing (information display, screen switching, etc.) in the display operation unit 16 is controlled by the control unit 40. The control unit 40 performs the identity verification described above based on the finger vein data acquired by the finger vein authentication unit 19.
The depositing unit 41 can perform various processes related to medal depositing. Specifically, the depositing unit 41 opens, for example, the shutter 18 by opening the shutter 18 in accordance with an instruction from the control unit 40 (see FIG. 2), or a medal inserted into the medal depositing port 17. Collecting or closing the shutter 18 after the medal insertion is completed. The payout unit 42 can perform various processes related to the payout of medals. Specifically, in accordance with an instruction from the control unit 40, the payout unit 42, for example, pays out medals for the number of payouts specified by the customer through the display operation unit 16 to the medal payout opening 13 (see FIG. 2). it can. The counting unit 43 can count the medals deposited. Various information can be recorded in the memory unit 44. Through the communication I / F unit 45, the control unit 40 is connected to the network 4 and can communicate with each medal deposit machine 2 and the management device 3.

Next, contents (management data) recorded in the DB 33 of the management apparatus 3 will be described.
For example, a member table 50, an attendant table 51, a finger vein data table 52, and a history table 53 are recorded in the DB 33.
FIG. 4A is a diagram illustrating the member table 50.
Regarding the member table 50 shown in FIG. 4A, customers have members who are registered as members on the store side. Members can deposit medals earned in the game as a stored medal at the game store and withdraw the stored medal at the next visit and use it in the game. In the member table 50, data of each member is recorded. Specifically, the member table 50 mainly records the member number assigned to each member, the date when the member registered as a member (registration date), the member's password, the date of birth, and the number of stored medals (number of stored medals). Has been. In FIG. 4A, for the member whose member number is 123456, the member number, registration date (September 25, 2010), password (12345678), date of birth (December 24, 2000), and the latest storage. The number of medals (250) is recorded in the member table 50.

FIG. 4B is a diagram showing the attendant table 51.
In the clerk table 51 shown in FIG. 4B, for each clerk in the amusement store, an identification symbol (clerk ID), password, and name assigned to each clerk are mainly recorded. In FIG. 4B, the clerk ID, password (0000001), and name (Ox) are recorded in the clerk table 51 for the clerk whose clerk ID is ABCDEF.

FIG. 4C is a diagram illustrating the finger vein data table 52.
In the finger vein data table 52 shown in FIG. 4C, finger vein data of all members and staff members is recorded in association with the member number or staff member ID. Since each finger vein data has an enormous amount of information, the finger vein data is managed not in the member table 50 or the staff table 51 but in the dedicated finger vein data table 52.

FIG. 4D is a diagram illustrating the history table 53.
In the history table 53 shown in FIG. 4D, the transaction history of each member with respect to the medal deposit machine 2 is recorded. Specifically, in FIG. 4D, for the member whose membership number is 123456, the date of transaction, whether the transaction is deposit or withdrawal of medals, the number of medals deposited in the transaction (deposit The number of medals paid out or the number of medals paid out (the number of payouts), and the number of stored medals at the time of the end of the transaction are recorded in the history table 53. That is, the DB 33 stores, in the history table 53, information on the past number of deposits and the number of withdrawals of customers who have made deposit and withdrawal transactions with the medal depositing machine 2.

Note that the memory capacity (maximum value of information that can be recorded) of the memory unit 44 (see FIG. 3) of each medal deposit machine 2 is significantly smaller than that of the DB 33 (see FIG. 3). (Especially finger vein data) cannot be stored.
Next, procedures of various transactions performed with the medal deposit machine 2 will be described. The transactions here mainly include membership registration, medal deposit, and medal payout. The procedure regarding each transaction is performed via the display operation unit 16 (see FIG. 2). Hereinafter, each procedure of member registration, medal deposit and medal payout will be described in this order.

5A to 5I are diagrams showing the display contents of the display operation unit 16 of the medal deposit machine 2 when registering a member.
A member registration procedure will be described with reference to FIGS. 5A to 5I. In each figure, the hand H of the clerk or customer may be schematically shown, but this shows a state in which the touch key on the display operation unit 16 is pointed with the hand H (described later). The same applies to FIGS. 6A to 6H and FIGS. 7A to 7H). When a plurality of hands H are displayed in the same figure, the circled numbers displayed on each hand H indicate the order in which the touch keys are pressed. Moreover, in this embodiment, since the customer who becomes the object of the transaction of the medal deposit machine 2 is a young child, hiragana is mainly used for the characters displayed on the display operation unit 16.

A customer who wants to register as a member first calls an attendant and has the attendant present. As shown in FIG. 5A, the clerk displays a clerk-specific screen with the heading “clerk menu” on the display operation unit 16 and presses the touch key 55 marked “new member registration”.
Then, as shown in FIG. 5B, a birthday input screen with the heading “Please press [OK] if you can press the birthday” is displayed on the display operation unit 16, so this time, The customer operates the numeric keypad 56 displayed on the display operation unit 16 to input his / her birthday. Since the input birthday is displayed on the display operation unit 16, the customer presses the OK key 57 displayed on the display operation unit 16 if there is no mistake in the input content. If the OK key 57 is not pressed within a predetermined time (here, within 15 seconds), the current transaction is cancelled. A display for counting down the predetermined time (display of “15 seconds after” in FIG. 5B) is displayed on the screen (the same applies to the drawings after FIG. 5C).

  When the customer presses the OK key 57, as shown in FIG. 5C, a password registration screen is displayed on the display operation unit 16 with the heading “Please press [OK] if you can get the password.” The customer operates the numeric keypad 58 displayed on the display operation unit 16 to input the password determined by himself (12345678 in FIG. 5C), and presses the OK key 59 if the input content is correct.

When the customer presses the OK key 59, as shown in FIG. 5D, a password confirmation screen with the heading “Please enter your password! Since the entered password is displayed, the customer presses the touch key 60 marked “make this” on the display operation unit 16 if the password is acceptable.
Then, as shown in FIG. 5E, a screen with the heading “Let your finger information roll your hand and place your finger” is displayed on the display operation unit 16. In this screen, a message field 61 stating “I will hang around 3 times” and an illustration 62 of the finger vein authentication unit 19 (see FIG. 2) are mainly displayed. The customer sets his / her finger (one same finger predetermined in the right hand or left hand) on the finger setting unit 19A (see FIG. 2) of the finger vein authentication unit 19 three times in accordance with the contents of this screen. Each time a customer sets a finger on the finger setting unit 19A, the finger vein authentication unit 19 acquires finger vein data (finger information) of the finger once. Therefore, finger vein data is acquired three times. When the finger vein data acquisition (finger information registration) by the finger vein authentication unit 19 is completed once, the message field 61 of the display operation unit 16 displays the content indicating how many times the finger information registration has been completed. The

  When the finger information has been registered three times, the display operation unit 16 displays a confirmation screen with a headline “Let's crawl your hand with your hand open, as shown in FIG. 5F”. Is displayed. On this screen, the same illustration 62 as before is displayed. The customer sets the same finger as the finger previously set on the finger setting unit 19A on the finger setting unit 19A along the content of this screen (see FIG. 2). In response to this, the finger vein authentication unit 19 acquires the finger vein data of the finger once. Of the finger vein data acquired three times in a row, the finger vein data that is most similar to the finger vein data acquired this time and the finger vein pattern is registered as the final finger vein data for this customer. .

When the final finger vein data registration is completed, the password and birthday that the customer has entered so far are displayed on the display operation unit 16 as shown in FIG. 5G. If not, the user touches the touch key 63 marked “Troubleshoot”.
Then, a member number is assigned to the customer from the medal teller 2, and the member number (123456 in FIG. 5H) and the password (see FIG. 5H) are displayed on the display operation unit 16 as shown in FIG. 5H. In 5H, 12345678) and birthday (in FIG. 5H, December 24, 2000) are displayed. The customer presses the OK key 64 if this content is acceptable. In response to this, information about this customer is newly registered in the above-described member table 50 (see FIG. 4A), and finger vein data of this customer is newly registered in the finger vein data table 52 (see FIG. 4C). .

Then, when the OK key 64 is pressed, an end screen with the heading “Thank you” is displayed on the display operation unit 16 as shown in FIG. 5I. Therefore, the OK key 65 on this end screen is pressed. A series of membership registration procedures are completed.
6A to 6H are diagrams showing display contents of the display operation unit 16 of the medal deposit machine 2 when depositing medals.

Next, a medal deposit procedure will be described with reference to FIGS. 6A to 6H.
A standby screen shown in FIG. 6A is displayed on the display operation unit 16 of the medal depositing machine 2 in the standby state. On the standby screen, a deposit key 65 marked as “to win a medal” and a payout key 66 marked as “take out a medal” are displayed.
A customer who wants to deposit a medal first presses the deposit key 65.

  Then, as shown in FIG. 6B, a password input screen with the heading “Please press [OK] if you can press the password” is displayed on the display operation unit 16. The displayed numeric key 67 is operated to input its own password. Since the input password is displayed on the display operation unit 16, the customer presses the OK key 68 displayed on the display operation unit 16 if there is no mistake in the input content.

  When the customer presses the OK key 68, as shown in FIG. 6C, a screen with the heading “Place your hand and put your finger, do not move your finger” is displayed on the display operation unit 16. On this screen, the above-described illustration 62 of the finger vein authentication unit 19 is displayed. The customer sets his / her finger (finger whose finger vein data is registered at the time of member registration) once in the finger setting unit 19A (see FIG. 2) of the finger vein authentication unit 19 in accordance with the contents of this screen. In response to the customer setting a finger on the finger setting unit 19A, the finger vein authentication unit 19 acquires finger vein data of the finger. In the medal depositing machine 2, the control unit 40 (see FIG. 3) associates the finger vein data acquired by the finger vein authentication unit 19 and the member number of the customer who entered the password earlier with the finger vein data table 52 (see FIG. 4C). The finger vein data registered in () is collated. As a result, if the finger vein data acquired by the finger vein authentication unit 19 matches the finger vein data registered in the finger vein data table 52, the customer identity is normally completed.

  In response to the successful completion of identity verification, the display operation unit 16 displays a screen with the heading “Please press [open the entrance] and insert the medal” as shown in FIG. 6D. The On this screen, an illustration 69 showing the vicinity of the medal depositing entrance 17 (see FIG. 2) in the medal depositing machine 2 and a touch key 70 marked “open the entrance” are displayed. The customer presses the touch key 70 along the contents of this screen. Then, the control unit 40 drives the depositing unit 41 (see FIG. 3) to open the shutter 18 (see FIG. 2) that has closed the medal depositing port 17.

  As the shutter 18 is opened and the medal deposit door 17 is opened, as shown in FIG. 6E, the display operation unit 16 has a screen with a headline “Put medal and press [SET]”. Is displayed. On this screen, an illustration 71 showing a state in which the medal M of the medal cup 15 is being inserted into the medal deposit door 17, and a touch key 72 in which “rear” is displayed are displayed. The customer inserts his medal into the medal deposit door 17 along the content of this screen, and then presses the touch key 72. Then, the control unit 40 drives the depositing unit 41 (see FIG. 3), thereby closing the shutter 18 (see FIG. 2) and closing the medal depositing port 17.

  As the shutter 18 closes, the control unit 40 issues a command to the counting unit 43 (see FIG. 3) to count the medals inserted previously. During the medal counting, the display operation unit 16 displays a screen with the heading "I'm counting medals" as shown in FIG. 6F. On this screen, the current count value (1234 sheets in FIG. 6F) is displayed in real time.

  When counting is complete. On the display operation unit 16, a count result display screen shown in FIG. 6G is displayed. On this screen, the current counting result (1234 in FIG. 6G) is displayed on the right side of the item “Made to me”. Here, when the counted day is the birthday of the customer who has performed the counting, a predetermined number of medals are given to the customer as present medals from the amusement store. When a present medal is awarded, the number of present medals (201 in FIG. 6G) is displayed on the screen to the right of the item “present medal”. On this screen, the current number of stored medals (567890 in FIG. 6G) including the current counting result and the number of present medals is displayed on the right side of the item “Medal in Chokinba”. Is done. Furthermore, the expiration date of the medal saved (in FIG. 6G, December 24, 2010) is also displayed on this screen. The customer who deposited the medal presses the OK key 73 if the contents of this screen are acceptable. As a result, the control unit 40 transmits transaction data (the number of deposits, the number of medals, etc.) related to the current transaction to the management device 3. In the DB 33 (see FIG. 3) of the management device 3, the number of stored medals of the corresponding customer is updated in the member table 50 (see FIG. 4A) based on the received transaction data, and the history table 53 (see FIG. 4D). ), A history of the current transaction (deposit) by the customer is newly added.

Then, in response to the customer pressing the OK key 73, an end screen with the heading “Thank you” is displayed on the display operation unit 16 as shown in FIG. 6H. When the OK key 74 is pressed, a series of medal deposit procedures is completed.
7A to 7H are diagrams showing display contents of the display operation unit 16 of the medal deposit machine 2 when paying out medals.

Next, a medal payout procedure will be described with reference to FIGS. 7A to 7H. Here, it is assumed that the customer who is going to pay out medals from now on has a stored medal.
A standby screen (described above) shown in FIG. 7A is displayed on the display operation unit 16 of the medal depositing machine 2 in the standby state.
A customer who wants to pay out medals first presses the payout key 66 on the standby screen.

  Then, as shown in FIG. 7B, a password input screen with the heading “Please press [OK] if you can press the password” is displayed on the display operation unit 16. The displayed numeric keypad 75 is operated to input its own password. Since the input password is displayed on the display operation unit 16, the customer presses the OK key 77 displayed on the display operation unit 16 if there is no mistake in the input content.

  When the customer presses the OK key 77, as shown in FIG. 7C, a screen with the heading “Place your hand and put your finger, do not move your finger” is displayed on the display operation unit 16. On this screen, the above-described illustration 62 of the finger vein authentication unit 19 is displayed. The customer sets his / her finger (finger whose finger vein data is registered at the time of member registration) once in the finger setting unit 19A (see FIG. 2) of the finger vein authentication unit 19 in accordance with the contents of this screen. In response to the customer setting a finger on the finger setting unit 19A, the finger vein authentication unit 19 acquires finger vein data of the finger. Then, in the medal depositing machine 2, the control unit 40 confirms the identity of the customer by collating the finger vein data as described above.

  In response to successful completion of identity verification, as shown in FIG. 7D, the display operation unit 16 has a payout with the heading “Press [OK] if you can press the number of medals to be released”. The number input screen is displayed. On the payout number input screen, the number of medals saved by the customer whose identity has been confirmed (123456 in FIG. 7D) and the maximum number of medals that can be paid out this time (9999 in FIG. 7D) are shown. Is displayed. Since the ten-key 77 is displayed on the payout number input screen, the customer designates the number of medals to be paid out this time by operating the ten-key 77. Since the designated payout number is displayed on the payout number input screen (1234 in FIG. 7D), the customer presses the OK key 78 if this number is acceptable.

  Then, as shown in FIG. 7E, the display operation unit 16 displays a screen with a heading “Place medal cup at medal exit [please push medal]”. On this screen, an illustration 79 showing a state in which the medal cup 15 is set in the medal payout opening 13 and a touch key 80 in which “Take out a medal” is displayed. The customer sets the medal cup 15 in the medal payout opening 13 along the content of this screen, and then presses the touch key 80. Then, when the control unit 40 drives the payout unit 42 (see FIG. 3), the payout unit 42 pays out the designated number of medals to the medal payout opening 13.

During the payout of medals, the display operation unit 16 displays a screen with the heading “I'm paying out medals” as shown in FIG. 7F. On this screen, the number of medals for which the current payout has been completed (1234 in FIG. 7F) is displayed in real time.
When the withdrawal is completed. The display operation unit 16 displays a payout result screen shown in FIG. 7G. On this screen, the number of medals paid out this time (1234 in FIG. 7G) is displayed on the right side of the item “Awarded medals”. In this screen, the current number of stored medals after subtracting the number of medals paid out (567890 in FIG. 7G) is displayed on the right side of the item “Medal in Chokinba”. . Further, on this screen, the expiration date of the stored medal (December 24, 2010 in FIG. 7G) is also displayed. Then, the customer who has paid out medals presses the OK key 81 if the contents of this screen are acceptable. Accordingly, the control unit 40 transmits transaction data (the number of payouts, the number of medals, etc.) relating to the current transaction to the management device 3. In the DB 33 (see FIG. 3) of the management device 3, the number of stored medals of the corresponding customer is updated in the member table 50 (see FIG. 4A) based on the received transaction data, and the history table 53 (see FIG. 4D). ), A history of the current transaction (payout) by the customer is newly added.

Then, in response to the customer pressing the OK key 81, an end screen with the heading “Thank you” is displayed on the display operation unit 16 as shown in FIG. 7H. When the OK key 82 is pressed, a series of payout procedures is completed.
Next, a control operation performed in the medal deposit machine 2 will be described. In this control operation, when the management device 3 goes down due to a failure or the like, a communication abnormality occurs between each of the plurality of (here, five) medal deposit machines 2 and the management device 3. (See FIG. 1).

  In this medal deposit system 1, when there is no communication abnormality, each medal deposit machine 2 performs a normal operation (so-called online operation) in which processing is performed while communicating with the management device 3. Normal operation refers to a case where each medal depositing machine 2 has a member registration or medal depositing transaction in a normal state where communication between each of the plurality of medal dispensing machines 2 and the management device 3 is possible. The exchange of data and signals related to these transactions is performed with the management device 3. On the other hand, when a communication abnormality occurs, the parent machine 2A operates as a substitute machine for the management apparatus 3 during the communication abnormality, and each medal depositing machine 2 performs a degenerate operation (so-called offline operation). . Degenerate operation means that each medal depositing machine 2 regards the parent machine 2A as an alternative machine to the management apparatus 3, and exchanges data and signals related to the transaction described above with the parent machine 2A, not with the management apparatus 3. Is to do between. Specific contents of the degenerate operation will be described later.

FIG. 8 is a flowchart showing a control operation performed in the medal depositing machine 2B of the child machine.
First, the control operation of the child medal depositing machine 2B will be described with reference to FIG.
The control unit 40 (see FIG. 3) of the child device 2B monitors whether or not the parent device 2A is operating as the management device 3 (that is, whether or not communication is already abnormal) (step S1). ).

  When the communication is not abnormal (NO in step S1), when the predetermined timing comes (YES in step S2), the control unit 40 transmits a test signal to the management device 3 (step S3). When the control unit 40 receives a response signal from the management device 3 after transmitting the test signal, the communication is successful (YES in step S4). In other words, the control unit 40 checks whether or not communication with the management apparatus 3 can be normally performed by transmitting a test signal to the management apparatus 3 at steps S2 to S4 at a predetermined timing. doing.

  When it is not the predetermined timing for checking the communication state (NO in step S2), the control unit 40 determines whether or not there is a transaction with the management apparatus 3 regarding the above-described member registration, medal deposit (deposit or withdrawal), and the like. Monitoring is performed (step S5). If there is a transaction (YES in step S5), the control unit 40 confirms whether communication with the management device 3 has succeeded in the transaction (step S4).

If the communication is successful in step S3 (communication status check) or step S5 (transaction with the management apparatus 3) (YES in step S4), the control unit 40 returns to the standby state and repeats the processing from step 1 onwards. .
On the other hand, if the communication is not successful (NO in step S4), a communication abnormality has occurred between the medal depositing machine 2 having the control unit 40 and the management device 3. In this case, the control unit 40 has detected a communication abnormality between its own medal depositing machine 2 and the management device 3, and in response to detecting the communication abnormality, the communication abnormality is transmitted to the parent device 2A. Transmit (notify) (step S6). In response to this, since an instruction (degenerate operation execution instruction) to execute the degenerate operation is transmitted from the base unit 2A that has received a communication abnormality as described later, the control unit 40 receives this instruction. (YES in step S7) When the communication is abnormal, the master unit 2A is set as an alternative device of the management device 3 and the degenerate operation is executed (step S8).

  In addition, when the communication status is not checked (NO in step S2) and there is no transaction with the management device 3 (NO in step S5), communication is performed between another medal depositing machine 2 and the management device 3. When an abnormality occurs, a degenerate operation execution instruction is transmitted from the parent device 2A. Also in this case, when the control unit 40 receives this instruction (YES in step S7), the control unit 40 performs the degenerate operation (step S8).

Note that the control unit 40 of the child device 2B having a communication abnormality with the management apparatus 3 may notify the communication abnormality to not only the parent device 2A but also other child devices 2B in step S6. . In that case, the control unit 40 of each slave unit 2B regards the notification of the communication abnormality as reception of the degenerate operation execution instruction (YES in Step S7), and executes the degenerate operation (Step S8).
If the base unit 2A is operating as the management apparatus 3 in step S1, that is, if communication is already abnormal (YES in step S1), the control unit 40 monitors whether the communication abnormality has been resolved. Yes. When the communication abnormality is resolved, an instruction to stop the degeneration operation (degeneration operation stop instruction) is transmitted from the base unit 2A. Therefore, the control unit 40 monitors whether or not the instruction has been received. (Step S9). When the control unit 40 receives the instruction (YES in step S9), the control unit 40 stops the degenerate operation and resumes the normal operation (step S10).

FIG. 9 is a flowchart showing a control operation performed in the medal depositing machine 2A of the parent machine.
Next, the control operation in the medal depositing machine 2A of the parent machine will be described with reference to FIG.
The control unit 40 (see FIG. 3) of the parent device 2A monitors whether it is operating as the management device 3 (that is, whether communication is already abnormal) (step S21).

  When the communication is not abnormal (NO in step S21), when the predetermined timing is reached (YES in step S22), the control unit 40 transmits a test signal to the management device 3 (step S23). When the control unit 40 receives a response signal from the management device 3 after transmitting the test signal, the communication is successful (YES in step S24). That is, the control unit 40 of the parent device 2A transmits a test signal to the management device 3 every time a predetermined timing is reached in steps S22 to S24, as in the case of the child device 2B (steps S2 to S4). Thus, it is checked whether or not communication with the management apparatus 3 can be normally performed.

  When it is not the predetermined timing for checking the communication state (NO in step S22), the control unit 40 monitors whether or not there is a transaction with the management apparatus 3 regarding the above-described member registration, medal deposit, etc. ( Step S25). If there is a transaction (YES in step S25), the control unit 40 checks whether or not communication with the management device 3 has succeeded in the transaction (step S24).

When communication is successful in step S23 (communication status check) or step S25 (transaction with the management apparatus 3) (YES in step S24), the control unit 40 returns to the standby state and repeats the processing from step S21 onward. .
On the other hand, if the communication is not successful (NO in step S24), a communication abnormality has occurred between the medal deposit machine 2 (master unit 2A) having the control unit 40 and the management device 3. In this case, the control unit 40 has detected a communication abnormality between its own medal depositing machine 2 and the management device 3, and in response to this detection, transmits a degenerate operation execution instruction to each child machine 2B. (Step S26). Each slave unit 2B (all slave units 2B) that has received the degenerate operation execution instruction executes the degenerate operation (step S8 in FIG. 8). Then, when the communication is abnormal, the control unit 40 operates its own medal teller machine 2 (master machine 2A) as a substitute machine for the management apparatus 3 and executes a degenerate operation (step S27).

  In addition, when it is not the timing for checking the communication state (NO in step S22) and there is no transaction with the management device 3 (NO in step S25), a communication error occurs between any slave unit 2B and the management device 3 If a communication error occurs with the management device 3, a communication error is transmitted in association with the identification number (such as the machine number) of the child device 2B from the child device 2B that has detected a communication error. . When receiving the communication abnormality (YES in step S28), control unit 40 of parent device 2A transmits a degenerate operation execution instruction to each child device 2B (step S26). The operation is performed as an alternative machine of the management apparatus 3 and the degenerate operation is executed (step S27).

  That is, in this case, the control unit 40 of the master unit 2A determines that each medal depositing machine 2 (master unit 2A) in response to the master unit 2A receiving a notification of communication abnormality (including the above-mentioned unit number) from the slave unit 2B. All the medal depositing machines 2) including 2A are caused to perform degenerate operation. Therefore, it is easy to use because it is possible to know which of the plurality of medal tellers 2 is the medal teller 2 in which a communication abnormality has occurred with the management device 3. Furthermore, after the master unit 2A receives a notification from the medal depositing machine 2 in which a communication error has occurred with the management device 3, the degenerate operation of each medal depositing machine 2 is started, so that each slave unit 2B is managed. In spite of no occurrence of communication abnormality with the device 3, it is possible to prevent a malfunction that the degenerate operation is erroneously started.

In addition to the fact that each medal depositing machine 2 automatically performs a degenerate operation when each medal depositing machine 2 notices a communication abnormality as described above, an attendant notices a communication abnormality and responds to each medal dispensing machine 2. The degenerate operation may be performed manually.
If the base unit 2A is operating as the management device 3 in step S21, that is, if communication is already abnormal (YES in step S21), the control unit 40 monitors whether or not the communication abnormality has been resolved. doing. When the communication abnormality is resolved, a message indicating that the communication abnormality has been resolved (communication abnormality resolution) is transmitted from the slave unit 2B (or the management apparatus 3 itself) that has communication abnormality with the management apparatus 3. Upon receiving this communication error resolution (YES in step S29), the control unit 40 becomes the parent when there is a member registration or medal deposit transaction in each slave device 2B or itself (master device 2A) during the communication error. The data (transaction data) acquired by the machine 2A is transmitted to the management device 3 (step S30).

On the other hand, when the communication abnormality cancellation from the slave unit 2B has not been received (NO in step S29), there is actually a communication abnormality between the master unit 2A and the management device 3, and the communication abnormality has been resolved. In addition (YES in step S31), control unit 40 of base unit 2A performs the process of step S30.
When the control unit 40 transmits the transaction data to the management device 3 in step S30, the control unit 30 of the management device 3 that has received the transaction data updates the management data in its own DB 33 based on the transaction data (FIG. 3), after the update is completed, a notification to that effect (update notification) is transmitted to the parent device 2A. When receiving the update notification (YES in step S32), the control unit 40 of the base unit 2A stops the operation of the management device 3 as a substitute unit, and instructs the slave units 2B to stop the above-described degeneration operation. Is transmitted (step S33). As a result, each medal deposit machine 2 resumes normal operation. That is, the control unit 40 of the base unit 2A stops the degeneration operation for each medal depositing machine 2 including the base unit 2A in response to the completion of the update of the management data in the management apparatus 3, and the normal operation To resume. As described above, when the communication abnormality is resolved, the management data of the management apparatus 3 is updated based on the data acquired by the parent device 2A during the communication abnormality, so that the management apparatus 3 can be recovered normally. When the management device 3 is restored, each medal deposit machine 2 can resume normal operation.

  Here, a group of the control units 40 of the parent device 2A and the child device 2B can be regarded as one control unit 40 in the medal deposit system 1 as a whole. In this case, as described above, the control unit 40 (a group of control units 40) detects a communication abnormality between each medal deposit machine 2 and the management device 3 (steps S4 and S24), and In response to the detection, when the communication is abnormal, the base unit 2A is operated as a substitute for the management device 3 and the deduction operation of all the medal depositing machines 2 is executed (steps S8 and S27).

As described above, when a communication abnormality occurs between the management device 3 and each medal depositing machine 2, during communication abnormality, one of the plurality of medal depositing machines 2 set as the parent machine 2A is Since it operates as an alternative machine of the management device 3 and each medal depositing machine 2 operates in a degenerate manner, it is possible to continue transactions in each medal depositing machine 2 (see FIG. 1).
Here, since any of the plurality of medal teller machines 2 can be set as the parent machine 2A, it is not necessary to make only a specific medal teller machine 2 of higher specifications than other medal teller machines 2, All medal deposit machines 2 can be unified with the same specifications. Therefore, the structure which can continue the transaction with each medal deposit machine 2 when communication abnormality occurs can be realized at low cost.

Further, as described above, when the group of the control units 40 of the master unit 2A and the slave unit 2B is regarded as one control unit 40, the control unit 40 (group of control units 40) In response to the completion of the management data update in the management device 3, each of the medal deposit machines 2 is caused to stop the degeneration operation and resume normal operation (step S10, step S33).
Next, processing performed in the medal depositing system 1 will be described based on the fact that the medal depositing machine 2 can perform normal operation or degenerate operation as described above.

FIG. 10 is a diagram for explaining processing executed in the medal deposit / payment system 1 when the medal deposit / payment system 1 is activated.
First, with reference to FIG. 10, processing when the medal deposit system 1 is started in conjunction with the start of business in the morning at a game store will be described. In FIG. 10, time elapses downward in the drawing (the same applies to FIGS. 11A to 12 described later).

  When the power is turned on in each medal depositing machine 2 and the management apparatus 3 with the activation of the medal depositing system 1 (step S41), the management apparatus 3 transmits setting data to the master unit 2A and all the slave units 2B. . The setting data includes the number of present medals to be given to customers whose birthday is birthday, the upper limit number of medals that can be paid out at one time, and the like. That is, the setting data is shared by the management device 3 and each medal deposit machine 2.

  Next, each medal deposit machine 2 transmits untransmitted data to the management device 3. The untransmitted data includes the above-described transaction data (see step S30 in FIG. 9) in the degenerate operation that existed before the medal deposit system 1 was activated. The untransmitted data of each slave unit 2B may be directly transmitted from the slave unit 2B to the management device 3, or may be once aggregated by the master unit 2A and then transmitted to the management device 3. If there is untransmitted data, the management device 3 updates the management data (see FIGS. 4A to 4D) in the DB 33 based on the received untransmitted data (step S42). That is, the process in the portion surrounded by the broken line in FIG. 10 is a recovery process of the DB 33 when there is untransmitted data (transaction data) due to the previous communication abnormality.

After step S42, the management device 3 transmits member information, authentication data, and clerk information to the parent device 2A, and also transmits clerk information to the child device 2B.
The member information is information about members registered in the member table 50 (see FIG. 4A) and the history table 53 (see FIG. 4D) of the DB 33. The management device 3 transmits member information for all members to the parent device 2A. Therefore, the parent device 2A is in a state where all information in the member table 50 and the history table 53 is shared with the management device 3. The member information includes temporary transaction data described later. The temporary transaction data is data that exists for each member, and includes information on whether or not to give a present medal today, information on the maximum number of medals that can be paid out today, and the like.

  The authentication data is the finger vein data of members and attendants recorded in the finger vein data table 52 of the DB 33 (see FIG. 4C). As described above, the finger vein data has an enormous amount of information, but the memory capacity of the memory unit 44 (see FIG. 3) of each medal depositing machine 2 including the parent machine 2A is relatively small. Therefore, the management device 3 narrows down the authentication data of members (so-called regular customers) that satisfy a predetermined condition such as a large number of visits, not the authentication data of all members, and the predetermined number (here, 30,000 in total) Only 10,000 authentication data) are extracted and transmitted to the main unit 2A. Therefore, the base unit 2A is in a state where a part of the information in the finger vein data table 52 is shared with the management device 3.

  The staff information includes information on staff registered in the staff table 51 of the DB 33 and authentication data of each staff (see FIGS. 4B and 4C). The management device 3 transmits clerk information about all clerks to the parent device 2A and each child device 2B. Therefore, the parent device 2A and each child device 2B share all information in the staff table 51 with the management device 3. In addition, each subunit | mobile_unit 2B does not need to memorize | store authentication data in clerk information.

  The parent device 2A and each child device 2B record the various information transmitted from the management device 3 in this way in their own memory unit 44 (see FIG. 3). At this time, the control unit 40 of the parent device 2A newly manages the management data of the management device 3 (data in the DB 33) in the memory unit 44 in a normal state without communication abnormality. In particular, in the memory unit 44 of the base unit 2A, a part of the specific type of data (authentication data) having a huge amount of information in the management data is backed up and managed. Therefore, the parent machine 2A does not have to have a high specification that allows backup management of all the management data of the management device 3, so that all the medal depositing machines 2 that can be set in the parent machine 2A have the same low specification. Can be unified. Therefore, the structure which can continue the transaction with each medal deposit machine 2 when communication abnormality occurs can be realized at lower cost.

Thereafter, the medal deposit / payment system 1 starts standby, and each medal deposit machine 2 can perform transactions (step S43).
In the DB 33 (see FIG. 3), when there is a change in the member information, the authentication data, or the clerk information transmitted from the management device 3 to the parent device 2A or the child device 2B, the changed information each time. Is transmitted from the management apparatus 3 to the parent device 2A and the child device 2B, and the corresponding data is updated in the parent device 2A and the child device 2B.

FIG. 11A and FIG. 11B are diagrams for explaining processing performed in the medal deposit / payment system 1 when a transaction relating to depositing / dispensing medals is performed in the medal depositing machine 2.
Next, with reference to FIG. 11A and FIG. 11B, processing in the case where deposit and withdrawal transactions are performed in each medal deposit machine 2 in the standby medal deposit system 1 will be described.
When the medal deposit / payment system 1 is on standby (step S51), for example, when the customer presses the deposit key 65 or the dispense key 66 (see FIGS. 6A and 7A) of the display operation unit 16 in the slave unit 2B, Assume that there is an instruction to deposit or pay out medals to the child device 2B (step S52). When this instruction is given, as described above (see FIGS. 6B and 7B), the customer inputs his / her password (step S53).

  Upon receiving the password input, the control unit 40 (see FIG. 3) of the slave unit 2B inquires the management apparatus 3 about the password. Specifically, the control unit 40 inquires of the management apparatus 3 whether the data associated with the password is in the DB 33 (see FIG. 3). In the management device 3 that has received the password inquiry, the control unit 30 (see FIG. 3) has member information (member number, date of birth, number of medals, and history associated with the password, as shown in FIG. 4A and FIG. 4D) and finger vein data (authentication data) of the member number associated with the password are searched in the respective tables 51 to 53 (see FIGS. 4A to 4D) of the DB 33. In addition, the inquired password may be a clerk's password. In this case, the control unit 30 of the management device 3 associates the clerk information (see FIG. 4B) associated with the password and the password. The finger vein data (authentication data) of the staff ID is searched. Moreover, even if it is a different customer or a staff member, the password may be duplicated, and in that case, the control unit 30 of the management device 3 is a member for all the members and staff members associated with the corresponding password. Search information, staff information and finger vein data.

  As a result of the search, if there is corresponding member information, clerk information, and finger vein data, the control unit 30 of the management device 3 transmits response data including these information and data to the slave device 2B that has made the inquiry. . Here, since the response data includes only the finger vein data of the input password, not the finger vein data of all the members, the information amount of the response data can be suppressed as much as possible.

  The control unit 40 of the child device 2B temporarily records the received response data in the memory unit 44 (see FIG. 3). Note that clerk information and clerk finger vein data are recorded in the memory 44 (see FIG. 3) of each medal depositing machine 2 at the time of activation described above (see FIG. 10). The search may be performed in the slave unit 2B without making an inquiry to 3.

  However, when there is a communication error, the above-described password inquiry and response data transmission (the portion surrounded by a broken line in FIG. 11A) is performed between the medal depositing machines 2. That is, the control unit 40 (see FIG. 3) of the child device 2B inquires of the parent device 2A, which is an alternative device of the management device 3, about the password as the degenerate operation. And the control part 40 of the main | base station 2A replaces the management apparatus 3 instead of the management apparatus 3, and the member information, authentication data, and staff information (management apparatus at the time of starting) recorded on its own memory part 44 (refer FIG. 3). 3), the data associated with the inquired password is retrieved from the information managed from backup sent from step 3). If there is corresponding member information, staff information, or finger vein data, the control unit 40 of the parent device 2A transmits response data to the child device 2B that has made the inquiry. As described above, the base unit 2A can operate as a substitute machine for the management device 3 based on the management data that has been backed up in the normal state during the communication abnormality. The transaction at each medal deposit machine 2 can be reliably continued.

Note that if there is no corresponding member information, clerk information, or finger vein data in the memory unit 44 of the master unit 2A, the member of the member information cannot perform degenerate operation, and the clerk directly deals with the transaction.
Then, regardless of the presence or absence of communication abnormality, the slave unit 2B that has received the response data in this manner is the finger vein authentication for the customer who has previously input the password (the finger vein data verification described above, and FIG. 6C and FIG. 7C (Refer to step S54). That is, when the customer sets his / her finger on the finger setting unit 19 </ b> A (see FIG. 2) of the finger vein authentication unit 19, the finger vein authentication unit 19 acquires the finger vein data of this finger. Then, the control unit 40 of the child device 2B collates the finger vein data acquired this time with the finger vein data included in the response data received earlier and confirms the identity of the customer.

  However, when the customer does not properly set the finger on the finger setting unit 19A or the customer's finger is damaged, finger vein data verification (finger vein authentication) may not be successful. If the finger vein authentication (identity verification) does not succeed even if the finger vein authentication unit 19 acquires the finger vein data of the customer a predetermined number of times (for example, three times) (NO in step S54), the slave unit 2B The display operation unit 16 receives the birthday input from the customer (see FIG. 5B). The control unit 40 verifies the customer's identity by comparing the input birthday with the birthday of the member information included in the response data received earlier. In addition to the birthday, other information (address, telephone number, etc.) that can identify the person may be appropriately combined to confirm the person.

If the identity verification based on the birthday is not successful (NO in step S55), the control unit 40 cancels the transaction relating to the current deposit or withdrawal (step S56).
If identity verification using finger vein data is successful (YES in step S54), or identity verification based on birthday is successful even if identity verification using finger vein data is not successful (YES in step S55), The control unit 40 of the child device 2 </ b> B transmits a notification (member identification completion notification) indicating that the identity verification (member identification) is completed to the management device 3. When receiving the notification, the control unit 30 of the management device 3 locks the member information (step S57). That is, the management device 3 prevents the member information (see FIGS. 4A and 4D) regarding the member whose identity has been confirmed in the child device 2B that has transmitted the member identification completion notification from being arbitrarily updated. As a result, the medal depositing machine 2 other than the child device 2B cannot perform a transaction (double transaction) for a customer who is currently dealing with the child device 2B.

  And the control part 30 of the management apparatus 3 transmits the transaction temporary data to the subunit | mobile_unit 2B which transmitted the member specific completion notification after step S57. In the temporary transaction data, information specific to the customer whose identity has already been confirmed in the slave unit 2B (for example, whether or not to give a present medal to the customer today, or to pay out to the customer today) The maximum number of medals that can be made).

  However, when there is a communication abnormality, the above-described member identification completion notification and transaction temporary data transmission (portion surrounded by a one-dot chain line in FIG. 11A) are performed between the medal deposit machines 2. That is, the control unit 40 (see FIG. 3) of the child device 2B inquires of the parent device 2A that is a substitute device of the management device 3 for the member identification completion notification as the degenerate operation. Then, as a degenerate operation, the control unit 40 of the parent device 2A makes an inquiry about the temporary transaction data that is backed up and managed by its own memory unit 44 (see FIG. 3) instead of the management device 3. Send to. As described above, the base unit 2A can operate as a substitute machine for the management device 3 based on the management data that has been backed up in the normal state during the communication abnormality. The transaction at each medal deposit machine 2 can be reliably continued.

When the slave unit 2B that has transmitted the member identification completion notification receives this transaction temporary data regardless of whether there is a communication abnormality, it currently makes a transaction among the response data (member information, authentication data, and clerk information) described above. Data other than that relating to the customer is discarded as unnecessary data from the memory unit 44 (see FIG. 3) or the like (step S58).
If the identity verification based on the finger vein data described above is the identity verification of the clerk, the clerk is identified. In that case (YES in step S59), handset 2B enters the clerk mode, and executes processing such as maintenance in accordance with the clerk's instruction (step S60).

However, in the following, it is assumed that the identity confirmation based on finger vein data (step S54) and the identity confirmation based on the birthday (step S55) are identity confirmations about the members.
In that case, as shown in FIG. 11B, the control unit 40 of the child device 2B confirms whether or not to give a present medal to the customer who is currently trading based on the temporary transaction data received earlier. (Step S61). If there is a present medal to be granted (YES in step S61), the control unit 40 creates transaction data indicating that the present medal given today is deposited as a stored medal (step S62). This transaction data includes the member number of the customer who is the trading partner, today's date, the number of present medals (considered as the number of deposits), and the latest number of stored medals taking into account the number of present medals. (See FIGS. 4A and 4D). Moreover, the control part 40 produces | generates the log | history regarding present gift medal grant based on the said transaction data in step S62, and records it on the memory part 44 (refer FIG. 3).

  Thereafter, the control unit 40 transmits the previously created transaction data to the management device 3. The control unit 30 of the management device 3 updates the corresponding data in the DB 33 (see FIG. 3) based on the received transaction data (step S63). Specifically, the control unit 30 updates the number of stored medals in the member table 50 (see FIG. 4A) for the customer of the received transaction data, or updates the customer's history table 53 (see FIG. 4D). Or add transaction data as a new history.

  When the update of the DB 33 is completed, the control unit 30 of the management device 3 transmits a notification to that effect to the slave unit 2B that has transmitted the transaction data. Furthermore, the control unit 30 of the management device 3 transmits the transaction data received by itself to the parent device 2A. Based on the received transaction data, the control unit 40 of the parent device 2A updates the corresponding data (backup data) in the memory unit 44 (see FIG. 3) in the same manner as in the management device 3 (step S64). In step S64, the control unit 40 of the base unit 2A updates the data (the same data as the management data in the DB 33 of the management device 3) that is backed up and managed by the memory unit 44 in a normal state where there is no communication abnormality.

  However, when there is a communication abnormality, the above-described transaction data and response notification transmission (the portion surrounded by a broken line in FIG. 11B) is performed between the medal deposit machines 2. That is, the control unit 40 of the child device 2B transmits transaction data to the parent device 2A that is an alternative device of the management device 3 as a degenerate operation. And the process of step S63 is abbreviate | omitted, and the control part 40 of the main | base station 2A updates applicable data in the memory part 44 (refer FIG. 3) based on the received transaction data as a degeneration operation (step S64). In this case, when the update of the data is completed, the control unit 40 of the parent device 2A transmits a notification to that effect to the child device 2B that has transmitted the transaction data.

  The control unit 40 of the slave unit 2B performs the process of step S65 in response to receiving the response notification regardless of whether there is a communication abnormality. Here, in the case of a medal deposit transaction, the medal inserted by the customer is received by the depositing unit 41 (see FIG. 3) and counted by the counting unit 43 (see FIG. 3) (see FIGS. 6E and 6F). In the case of a medal payout transaction, the payout unit 42 (see FIG. 3) pays out the number of medals specified by the customer (see FIGS. 7E and 7F).

  When the counting of medals inserted by the customer (deposited medals) or the payout of medals is completed, the control unit 40 of the slave unit 2B creates transaction data relating to depositing or paying out (step S66). This transaction data includes the membership number of the customer who is the trading partner, today's date, whether this transaction was deposited or withdrawn, the number of deposits or withdrawals of medals, and the number of deposits or withdrawals. The latest number of medals taken into account is included (see FIGS. 4A and 4D). Moreover, the control part 40 produces | generates the log | history regarding this deposit or withdrawal based on the said transaction data in step S66, and records it on the memory part 44 (refer FIG. 3). If there is a trouble in depositing or withdrawing medals, the clerk records the history recorded in the memory unit 44 of the slave unit 2B (the history recorded in step S62) without accessing the management device 3. The cause of the trouble can be searched based on the

  Thereafter, the control unit 40 transmits the previously created transaction data to the management device 3. The control unit 30 of the management device 3 updates the corresponding data in the DB 33 (see FIG. 3) based on the received transaction data (step S67). Specifically, the control unit 30 updates the number of stored medals in the member table 50 (see FIG. 4A) for the customer of the received transaction data, or updates the customer's history table 53 (see FIG. 4D). Or add transaction data as a new history.

  When the update of the DB 33 is completed, the control unit 30 of the management device 3 transmits a notification to that effect to the slave unit 2B that has transmitted the transaction data. Furthermore, the control unit 30 of the management device 3 transmits the transaction data received by itself to the parent device 2A. Based on the received transaction data, the control unit 40 of the parent device 2A updates the corresponding data in the memory unit 44 (see FIG. 3) in the same manner as in the management device 3 (step S68). In step S68, the control unit 40 of the base unit 2A updates the data (the same data as the management data in the DB 33 of the management apparatus 3) that is backed up and managed by the memory unit 44 in a normal state without communication abnormality.

  However, when there is a communication abnormality, the above-described transaction data and response notification transmission (portion surrounded by a one-dot chain line in FIG. 11B) is performed between the medal depositing machines 2. That is, the control unit 40 of the child device 2B transmits transaction data to the parent device 2A that is an alternative device of the management device 3 as a degenerate operation. And the process of step S67 is abbreviate | omitted, and the control part 40 of the main | base station 2A updates the applicable data in the memory part 44 (refer FIG. 3) based on the received transaction data as a degeneration operation (step S68). In this case, when the update of the data is completed, the control unit 40 of the parent device 2A transmits a notification to that effect to the child device 2B that has transmitted the transaction data.

Control unit 40 of slave unit 2B allows the customer to press OK key 74 (see FIG. 6H) or OK key 82 (see FIG. 7H) in response to receiving the response notification regardless of whether there is a communication abnormality. It is certain whether or not all the current transactions have been completed (step S69).
If the transaction ends (YES in step S69), the control unit 40 transmits an end notification indicating that fact to the management device 3 (step S70). In response to receiving the end notification, the control unit 30 of the management device 3 releases the above-described member information lock for the current customer (step S71). As a result, the customer can make a new transaction in the medal depositing machine 2 as well as the child machine 2B transacted this time.

Then, as described above, the data (steps S64 and S68) updated in the base unit 2A during the communication abnormality is transmitted to the management device 3 after the communication abnormality is resolved (step S30 in FIG. 9), and managed. The management data in the DB 33 of the device 3 is updated.
FIG. 12 is a diagram for explaining processing performed in the medal depositing system 1 when member registration is performed in the medal depositing machine 2.

Next, with reference to FIG. 12, a description will be given of processing when a member registration transaction is performed in each medal depositing machine 2 in the standby medal depositing system 1. FIG.
When the medal deposit / payment system 1 is on standby (step S81), for example, in the slave unit 2B, a birthday to be entered is displayed on the display operation unit 16 (see FIG. 5B) by a customer who intends to register as a member (step S82). Thereafter, a password is input through the display operation unit 16 (see FIG. 5C) (step S83).

  Receiving the input of the birthday and the password, the control unit 40 of the slave unit 2B inquires of the management apparatus 3 whether or not a password overlapping with the input password has already been registered in the DB 33 (see FIG. 4A and FIG. 4B). (See FIG. 3). However, duplication of passwords is allowed up to a predetermined number (for example, 5). This is because the medal teller machine 2 uses not only the password but also finger vein data when the identity is confirmed.

  The control unit 30 of the management device 3 that has received the inquiry confirms in the member table 50 (see FIG. 4A) and the attendant table 51 (see FIG. 4B) of the DB 33 whether or not the same password as the password related to the inquiry has already been registered. To do. As a result of the confirmation, if there is no duplicate password in the member table 50 or the like, or even if it exists, if there is less than the predetermined number (less than 5) described above, the control unit 30 in the slave unit 2B A notification that the password input this time is OK (password OK notification) is transmitted to the child device 2B.

  However, if there is a communication error, the password duplication inquiry and the password OK notification transmission (the portion surrounded by the broken line in FIG. 12) are performed between the medal depositing machines 2. That is, the control unit 40 (see FIG. 3) of the child device 2B inquires of the parent device 2A, which is an alternative device of the management device 3, as a degenerate operation. Then, the control unit 40 of the base unit 2A performs the backup operation in the own memory unit 44 (see FIG. 3) instead of the management device 3 as the degenerate operation, and the member information or the staff information (from the management device 3 at the time of activation). It is confirmed whether or not the inquired password has already been registered from the transmitted information (member table 50 and staff table 51). As a result of the confirmation, if there is no duplicate password in the memory unit 44, or if it exists, but less than the predetermined number described above, the control unit 40 of the base unit 2A notifies the password OK notification. Transmit to handset 2B. As described above, the base unit 2A can operate as a substitute machine for the management device 3 based on the management data that has been backed up in the normal state during the communication abnormality. The transaction at each medal deposit machine 2 can be reliably continued.

Then, regardless of the presence or absence of communication abnormality, in the handset 2B that has received the password OK notification in this manner, the finger vein authentication unit 19 reads (acquires) the finger vein data of the customer as described above (FIG. 5E). (Refer) 3 times (step S84).
Thereafter, the finger vein authentication unit 19 acquires the finger vein data of the finger once more, and the final finger vein data for this customer is registered as described above (see FIG. 5F) (step S85).

  When the registration of the final finger vein data is completed, the control unit 40 of the handset 2B obtains the member information (birth date, password, today's date, etc.) obtained in the current transaction and the finger vein data (authentication) previously registered. Data) is transmitted to the management apparatus 3. Upon receiving these data, the control unit 30 of the management apparatus 3 registers the data as new member data in the member table 50 (see FIG. 4A) and the finger vein data table 52 (see FIG. 4C). A history table 53 (see FIG. 4D) for the customer who has become is newly established in the DB 33 (see FIG. 3) (step S86).

  Thereafter, the control unit 30 of the management apparatus 3 transmits a notification (member registration confirmation notification) that the member registration (data registration in step S86) for the new member has been confirmed to the child device 2B that has registered the member. To do. The control unit 30 of the management device 3 transmits the new member data registered in step S86 to the parent device 2A. In response to this, the control unit 40 of the parent device 2A registers (new member data registration) the received new member data in its own memory unit 44 (see FIG. 3) (step S87). In step S87, the control unit 40 of the parent device 2A newly manages the management data of the management device 3 (data in the DB 33) in the memory unit 44 in a normal state without communication abnormality.

  However, when there is a communication abnormality, transmission of member information and authentication data and transmission of a member registration confirmation notification (portion surrounded by a one-dot chain line in FIG. 12) are performed between the medal depositing machines 2. That is, the control unit 40 (see FIG. 3) of the child device 2B transmits the member information and the authentication data to the parent device 2A that is an alternative device of the management device 3 as the degenerate operation. Then, the control unit 40 of the base unit 2A performs new member data registration (backup registration) in its own memory unit 44 (see FIG. 3) instead of the management device 3 as a degenerate operation (step S86), and thereafter The member registration confirmation notice is transmitted to the slave unit 2B that has registered the member. In this case, the process of step S87 is omitted. As described above, the new member data registered in the parent device 2A during the communication abnormality is transmitted to the management apparatus 3 after the communication abnormality is resolved (step S30 in FIG. 9), and is newly created in the DB 33 of the management apparatus 3. be registered.

Regardless of whether there is a communication abnormality, the control unit 40 of the slave unit 2B that has received the member registration confirmation notification temporarily records the customer who has become a new member this time in its own memory unit 44 (see FIG. 3) or the like. The stored data is erased (step S88). Thus, a series of member registration transactions is completed, and the medal deposit system 1 starts standby (step S89).
10 to 12, the case where there is a transaction in the slave unit 2B is described, but the case where there is a transaction in the master unit 2A is almost the same as the case where there is a transaction in the slave unit 2B. . However, in the data processing in which the data acquired by the slave unit 2B is transmitted to the management device 3 and is backed up by the master unit 2A, the data acquired by the master unit 2A is once stored in the master unit 2A. Data processing is performed such that backup management is performed by the parent device 2A after transmission to the management device 3. In the degenerate operation, the processing in which the slave unit 2B transmits data or inquires to the master unit 2A is processing in which the master unit 2A transmits data to or inquires of itself.

FIG. 13 is a diagram showing the member table 50. FIG. 14 is a diagram showing the display contents (first mode) of the display operation unit 16 when inputting the number of payouts. FIG. 15 is a diagram showing display contents (second mode) of the display operation unit 16 when inputting the number of payouts.
Next, with reference to FIGS. 13 to 15, a procedure for inputting the number of medals to be paid out this time (payout number) in the case where each medal depositing machine 2 performs a medal payout transaction will be described.

In the member table 50 shown in FIG. 13, in addition to the above-described member number, password, date of birth, etc., information such as a payout number input setting content is recorded for each member number (each member).
The payout number input setting content is how to input the payout number when paying out medals, and can be arbitrarily determined by the customer (member) at the time of member registration.
The payout number input setting content is to directly input (designate) an arbitrary payout number with the numeric keypad 85 (see FIG. 15) in the case of the member with the member number 123456.

  The payout number input setting content of the member with the member number 234567 is selected from the most recent predetermined number of payouts (here, 4 times). For example, referring to the history table 53 of FIG. 4D, the most recent four payouts are 100 sheets as of December 5, 2010, 80 sheets as of November 24, 2010, 100 sheets as of October 13, 2010, And since it is 120 sheets on October 1, 2010, one of these payout numbers is the current payout number.

  Returning to FIG. 13, the payout number input setting content of the member number 345678 is that the average value of payout numbers for the most recent predetermined number of times (here, four times) is used as a candidate for the current payout number. is there. For example, referring to FIG. 4D, the most recent four payouts are 100 sheets as of December 5, 2010, 80 sheets as of November 24, 2010, 100 sheets as of October 13, 2010, and 2010. Since it is 120 sheets on October 1, the average value of these payout numbers is the current payout number.

  Returning to FIG. 13, the payout number input setting contents of the member number 456789 are the average payout number for each medal payout after an arbitrary predetermined timing (in this case, October 2010) as the current payout number candidate. It is to do. For example, referring to FIG. 4D, the number of payouts after October 2010 is 100 sheets as of December 5, 2010, 80 sheets as of November 24, 2010, 100 sheets as of October 13, 2010, and Since it is 120 sheets on October 1, 2010, the average value of these payout numbers is the current payout number.

Returning to FIG. 13, the payout number input setting content of the member number 567890 is that the average value of all the payout numbers so far included in the history of this customer is the candidate for the current payout number. .
The payout number input setting content of the member with the member number 678901 is such that a specified value (50 in this case) specified in advance at the time of member registration is used as the number of payouts for each time.

  The control unit 40 (see FIG. 3) of the medal depositing machine 2 that performs the medal payout transaction displays the payout number input screen (see FIG. 7D) when the above-described identity verification (see FIGS. 7B and 7C) is completed normally. Is displayed on the display operation unit 16 and the input of the customer's desired payout number is received by the display operation unit 16, but the content of the payout number input screen is changed according to the content of the customer's payout number input setting.

Specifically, when the identity verification is completed, the control unit 40 refers to the member table 50 and confirms the payout number input setting content of the customer who has confirmed the identity. If the customer this time is a member with the membership number 234567 in FIG. 13, the control unit 40 displays a payout number input screen having the contents shown in FIG. 14 on the display operation unit 16.
In FIG. 14, for example, a headline “Please enter the payout number” is displayed at the upper end of the display operation unit 16, and a history display field 83 is displayed in the left half area of the display operation unit 16. In the right half area of 16, a numeric keypad 85 and an input field 86 are displayed side by side.

In the history display field 83, the history of the number of payouts for the latest four times is displayed side by side with the date and time of the payout transaction under the heading “Payout number for the past four times”. In the history display field 83, the display of the numerical value part (“100”, “80”, “100”, “120” in order from the top) of the payout number of the history for four times is displayed on the touch key 84 (designating means). It has become.
The input field 86 displays the number of payouts to be input this time. However, immediately after the payout number input screen is displayed on the display operation unit 16, the input field 86 is blank, and no numerical value is displayed in the input field 86. Alternatively, “0 (zero)” is displayed in the input field 86 as a default value. When the customer presses the touch key 84 of the numerical value to be used as the current payout number among the four payout numbers displayed in the history display field 83, the numerical value is displayed in the input field 86. That is, the touch key 84 displays a payout history and also serves as a designation unit for designating a payout number received by the display operation unit 16.

  Alternatively, if the customer wishes to use a number different from the four payouts displayed in the history display field 83 as the current payout number, the user operates the numeric keypad 85 instead of the touch key 84 to set the value. It is displayed in the input field 86. Specifically, when the numeric key 85 is operated to display the numerical value in the input field 86 and then the ET (enter) key 85A is pressed, the operation of the numeric key 85 is confirmed. If it is desired to correct the numerical value displayed in the input field 86, the CL (clear) key 85B is pressed to erase the numerical value, and then the touch key 84 or the numeric keypad 85 is operated again to obtain the current payout number. The numerical value to be displayed may be displayed in the input field 86.

  The customer displays a numerical value to be used as the current payout number in the input field 86, and then presses an OK key 87 labeled "OK" if the numerical value is to be confirmed as the current payout number. Then, the control unit 40 of the medal depositing machine 2 performs a process of paying out medals for the number of payouts (see step S65 in FIGS. 7E to 7H and FIG. 11B). If it is desired to cancel the current transaction, it is only necessary to press a cancel key 88 marked “Stop”.

  As described above, for a customer who wants to receive a medal payout, each payout number in the history of his / her past payout number displayed on the display operation unit 16 (history display field 83) is the desired payout number this time. Cheap. Therefore, the customer can quickly specify the desired number of payouts from the history and select the display (touch key 84) of each payout number in the history on the display operation unit 16 to select the desired number of times. It is also possible to quickly specify the number of payouts to be made. Therefore, it is possible to further improve the usability with respect to the designation of the number of medals to be paid out.

On the other hand, when the member number in FIG. 13 is a customer other than 234567, the control unit 40 displays a payout number input screen having the contents shown in FIG. In the display operation unit 16 shown in FIG. 15, the above-described numeric keypad 85, input field 86, OK key 87, and cancel key 88 are displayed under the heading “Please enter the payout number”.
Here, in the case of the customer whose membership number is 123456 (see FIG. 13), in the state immediately after the payout number input screen is displayed on the display operation unit 16, the input field 86 is blank (or , “0 (zero)” is initially displayed), and the customer operates the numeric keypad 85 as described above to display the numeric value desired to be paid out this time in the input field 86. Thereafter, when the OK key 87 is pressed, as described above, the control unit 40 of the medal deposit machine 2 performs a process of paying out medals corresponding to this numerical value (the number of payouts). Therefore, a customer who wants to receive a medal payout can arbitrarily designate the payout number with the numeric keypad 85 displayed on the display operation unit 16 as necessary. Therefore, it is possible to improve the usability regarding the designation of the number of medals to be paid out.

  In the case of the customer whose membership number is 345678 as described above (see FIG. 13), the control unit 40 calculates the average value of the number of payouts for the four most recent times selected by the customer and displays the payout number input screen. The average value is displayed as a payout number candidate in the input field 86 immediately after being displayed on the operation unit 16. That is, the control unit 40 calculates a payout number candidate based on the past payout number of the customer and displays it in the input field 86.

  The customer presses the OK key 87 if the candidate numerical value displayed in the input field 86 is acceptable. Then, as described above, the control unit 40 of the medal deposit machine 2 performs a process of paying out medals corresponding to this numerical value (the number of payouts). On the other hand, if the customer wants to correct the numerical value displayed in the input field 86, the numerical value is erased by operating the numeric keypad 85, and the desired numerical value is displayed in the input field 86. The key 87 may be pressed. As a result, medals of the desired number of payouts are paid out from the medal deposit machine 2.

  In the case of the customer whose membership number is 456789 (see FIG. 13), the control unit 40 calculates an average value of the number of payouts for October 2010 and after that customer has selected in advance, and inputs the number of payouts. The average value is displayed as a payout number candidate in the input field 86 immediately after the screen is displayed on the display operation unit 16. That is, the control unit 40 calculates a payout number candidate based on the past payout number of the customer and displays it in the input field 86.

  In the case of the customer whose membership number is 567890 (see FIG. 13), the control unit 40 calculates the average value of all of the payout numbers (see FIG. 4D) that the customer has selected in advance and pays out. The average value is displayed as a payout number candidate in the input field 86 in a state immediately after the number input screen is displayed on the display operation unit 16. That is, the control unit 40 calculates a payout number candidate based on all past payout numbers of the customer and displays it in the input field 86.

  In the case of the customer whose membership number is 678901 (see FIG. 13), the input field 86 immediately after the payout number input screen is displayed on the display operation unit 16 is designated by the customer in advance. The value (50 sheets) is displayed by default. That is, in the case of a customer whose membership number is 678901, the control unit 40 displays a value designated in advance by the customer in the input field 86 as a candidate for the number of payouts. In this way, a customer who wants to receive a medal payout can quickly determine the payout number and input it on the display operation unit 16 by using the value designated in advance as the current payout number. . Therefore, it is possible to improve the usability regarding the designation of the number of medals to be paid out.

  A customer whose membership number is 456789, 567890, or 678901 (see FIG. 13) presses the OK key 87 if the numerical value displayed in the input field 86 is acceptable. Then, as described above, the control unit 40 of the medal deposit machine 2 performs a process of paying out medals corresponding to this numerical value (the number of payouts). On the other hand, if the customer wants to correct the numerical value displayed in the input field 86, the numerical value is erased by operating the numeric keypad 85, and the desired numerical value is displayed in the input field 86. The key 87 may be pressed. As a result, medals of the desired number of payouts are paid out from the medal deposit machine 2.

  As described above, when performing the medal payout transaction, the control unit 40 of the medal depositing machine 2 accepts the input of the payout number on the display operation unit 16 by the customer who receives the medal payout. The payout information on the past payout number for the customer is displayed on the display operation unit 16 (see FIGS. 14 and 15). The payout information is a history of a predetermined number of payouts for the customer in the past (see FIG. 14) and the candidate calculated based on the payout number (an average value of the number of payouts for a predetermined number of times).

A customer who wants to receive a medal payout can grasp the payout information related to his / her past payout number on the display operation unit 16, so that the desired payout number can be quickly determined based on the payout information and the display operation can be performed. It can be input (specified) in the section 16. Therefore, it is possible to improve the usability with respect to the designation of the number of medals to be paid out.
Here, for a customer who wants to receive a medal payout, a payout number candidate calculated based on his / her past payout number tends to be the desired payout number this time.

  In particular, candidates for the number of payouts calculated as described above (the average value of the number of payouts for the most recent predetermined number of times, the average value of the number of payouts after the predetermined timing, and the average value of the number of payouts for all cases included in the history) ) Are only values that the customer is likely to select as the desired number of payouts this time. The customer can designate the desired number of payouts this time very quickly by setting it as the candidate, and can input it on the display operation unit 16.

Accordingly, the customer can quickly designate the desired number of payouts this time by using the candidate displayed on the display operation unit 16 and input it on the display operation unit 16. Therefore, it is possible to further improve the usability with respect to the designation of the number of medals to be paid out.
Note that, in the above, (1) the past payout number history, (2) the average number of payouts for the most recent predetermined number of times, (3) the average value of the number of payouts after the predetermined timing, and (4) the history are included. Either the average value of the total number of payouts or (5) a value specified in advance by the customer is displayed on the display operation unit 16 as a candidate for the number of payouts this time. These (1) to (5 ) May be displayed on the display operation unit 16 in an appropriately combined state. Then, there is an advantage for the customer that the number of options for the number of payouts increases.

Next, the flow of medals deposited in the medal deposit machine 2 will be described.
FIG. 16 is a schematic diagram showing how the medals M inserted into the medal deposit machine 2 are distributed.
Referring to FIG. 16, the medal deposit machine 2 has a configuration for processing medals inserted into the medal deposit entrance 17 (see FIG. 2) as described above (configuration of the depositing unit 41 and the counting unit 43 described above). A turntable 90, a partition wall 91, a conveyance path 92, a conveyance belt 93, a first branch path 94, a second branch path 95, a discrimination sensor 96 (discrimination means), a first passage sensor 97, A second passage sensor 98, a third passage sensor 99, and a fourth passage sensor 100 are mainly provided.

  The turntable 90 is a disk disposed at the point where the medal M inserted into the medal depositing port 17 falls. FIG. 16 shows the turntable 90 in plan view. The turntable 90 is disposed so as to be flat in the horizontal direction, and in this state, rotates in a predetermined direction (a clockwise direction along a solid arrow in FIG. 16). The medal M on the turntable 90 gradually moves to the outer peripheral side of the turntable 90 by centrifugal force as the turntable 90 rotates.

  The partition wall 91 is a substantially annular vertical wall that surrounds the outer periphery of the turntable 90 in plan view. A slit 101 through which one medal M can pass exactly is formed at one place on the circumference of the partition wall 91. In addition, a thing (foreign matter etc.) that is larger in diameter or thicker than the medal M is not allowed to pass through the slit 101 and remains on the turntable 90 and is collected during the maintenance of the medal teller machine 2. The

  The conveyance path 92 is connected to the partition wall 91 and extends from the slit 101 in a band shape. In FIG. 16, the conveyance path 92 in plan view is shown. The conveyance path 92 is long in the direction in which the conveyance path 92 extends (the horizontal direction in FIG. 16). On the floor surface (bottom surface) of the conveyance path 92, two drop holes 102 larger than the medal M in plan view are formed at intervals in the longitudinal direction of the conveyance path 92. The two drop holes 102 are distinguished from the first drop hole 102A and the second drop hole 102B in order from the side closer to the slit 101. Each drop hole 102 is formed in the transport path 92 at a position biased to one side (downward in FIG. 16) in a direction (vertical direction in FIG. 16) perpendicular to the longitudinal direction of the transport path 92. Therefore, in the area where the first drop hole 102A exists in the longitudinal direction on the floor surface of the conveyance path 92, the portion where the first drop hole 102A is formed (the lower portion in FIG. 16) and the first drop hole 102A are formed. There is a portion that is not formed (the upper portion in FIG. 16, referred to as “first passage portion 92 </ b> A”). Further, in the area where the second drop hole 102B exists in the longitudinal direction on the floor surface of the transport path 92, a portion where the second drop hole 102B is formed (the lower portion in FIG. 16) and the second drop hole 102B are formed. There is a portion that is not formed (the upper portion in FIG. 16, referred to as “second passage portion 92 </ b> B”).

In the medal depositing machine 2, a main hopper 103 is disposed at the tip of the conveyance path 92 farthest from the slit 101 (left end portion in FIG. 16). In FIG. 16, for convenience of explanation, the main hopper 103 is a cup-shaped container.
As described above, the medal M on the turntable 90 moved to the outer peripheral side of the turntable 90 by the centrifugal force with the rotation of the turntable 90 passes through the slit 101 and is delivered onto the floor surface of the transport path 92. .

  The conveyor belt 93 is, for example, an endless belt, and has an annular shape when viewed from the horizontal direction (the direction along the paper surface of FIG. 16). In FIG. 16, the conveyance belt 93 in plan view is shown. The conveyance belt 93 is disposed in the conveyance path 92 in a plan view, and extends along the conveyance path 92 in this state. When the transport belt 93 moves around, the portion of the transport belt 93 that faces the floor surface of the transport path 92 moves along the longitudinal direction of the transport path 92 in the direction away from the slit 101 (left side in FIG. 16). The medal M passed through the slit 101 on the floor surface of the transport path 92 is sandwiched between the part of the transport belt 93 facing the floor surface of the transport path 92 and the floor surface of the transport path 92. Thus, the inside of the conveyance path 92 is conveyed in the direction away from the slit 101 by the conveyance belt 93 that moves around. At this time, the medal M is transported in the transport path 92 in a state of being biased to the side (upper side in FIG. 16) away from each drop hole 102 in a direction orthogonal to the longitudinal direction of the transport path 92 in plan view. Therefore, when the medal M reaches the portion where each drop hole 102 is positioned in the longitudinal direction of the transport path 92, when the external force is not acting on the medal M from the other, the first passing portion 92A described above. Or the second passage portion 92B (portion where the drop hole 102 is not formed) and does not fall from the drop hole 102. Therefore, the medal M is accommodated in the main hopper 103 when it is transported through the transport path 92 as it is without dropping from the drop holes 102.

The first branch path 94 extends continuously downward from the first drop hole 102 </ b> A of the transport path 92 (back side in FIG. 16). The return port 24 (see FIG. 2) is located at the tip of the first branch path 94. In FIG. 16, for convenience of explanation, the return port 24 is regarded as a cup-shaped container.
The medal deposit machine 2 is provided with a first reject bearing 105 at a position outside the conveyance path 92 and sandwiching the first passage portion 92A with the first drop hole 102A. The first reject bearing 105 can be moved back and forth. When the first reject bearing 105 is in the retracted position, the first reject bearing 105 is located outside the conveyance path 92. However, when the first reject bearing 105 is advanced from the retracted position, the first drop hole 102A crosses the first passage portion 92A. To. Therefore, when the first reject bearing 105 is in the retracted position, even if the medal M reaches the first passage portion 92A, the medal M passes through the first passage portion 92A without falling from the first drop hole 102A. It is conveyed downstream along the conveyance path 92. However. When the first reject bearing 105 advances from the retracted position when the medal M reaches the first passage portion 92A, the medal M is struck by the first reject bearing 105 toward the first drop hole 102A. It falls from the drop hole 102A, passes through the first branch path 94, and finally reaches the return port 24.

The second branch path 95 continuously extends downward from the second drop hole 102 </ b> B of the transport path 92. In the medal deposit machine 2, a sub hopper 104 is disposed at the tip of the second branch path 95. In FIG. 16, for convenience of explanation, the sub hopper 104 is a cup-shaped container.
The medal deposit machine 2 is provided with a second reject bearing 106 at a position outside the transport path 92 and sandwiching the second passage portion 92B with the second drop hole 102B. The second reject bearing 106 can be moved back and forth. When the second reject bearing 106 is in the retracted position, the second reject bearing 106 is positioned outside the conveyance path 92. However, when the second reject bearing 106 advances from the retracted position, the second drop hole 102B crosses the second passage portion 92B. To. Therefore, when the second reject bearing 106 is in the retracted position, even if the medal M reaches the second passage portion 92B, the medal M passes through the second passage portion 92B without falling from the second drop hole 102B. It is conveyed downstream along the conveyance path 92. However, when the second reject bearing 106 advances from the retracted position when the medal M reaches the second passage portion 92B, the medal M is struck by the second reject bearing 106 toward the second drop hole 102B. It falls from the second drop hole 102B, passes through the second branch path 95, and finally reaches the sub hopper 104.

  The discrimination sensor 96 is disposed between the second drop hole 102 </ b> A and the slit 101 in the transport path 92. The discrimination sensor 96 can discriminate the type of medal M that passes through the portion where it is disposed in the transport path 92. Here, the medal M includes a medal M (called “own store medal M1”) handled by an amusement store (own store) in which the medal depositing machine 2 is arranged, and another store in the same series as the own store (in the same amusement store group). The chain store) medal M (referred to as “the other affiliated medal M2”) and the medal M of another store (unrelated) from the own store (referred to as “other affiliated medal M3”). There are two types. Note that the foreign affiliated medal M3 includes foreign objects that are not medals M in the first place. In FIG. 16, the medal M that is a white circle is the own store medal M 1, and the medal M that is a circle with dots is the other affiliated medal M 2, and is a circle that is hatched. The medal M is the other affiliated store medal M3.

In this amusement store (own store), the own store medal M1 is a regular medal M, and the other affiliated store medal M2 and the other affiliated other store medal M3 are non-regular medals M. Comparing the medal M2 and the other affiliated store medal M3, the other affiliated store medal M3 has a relatively higher degree of irregularity than the affiliated affiliated store medal M2.
The discrimination sensor 96 is a so-called image sensor, and previously holds image data of each medal of the own store medal M1, the same series other store medal M2, and the other series other store medal M3. The discrimination sensor 96 discriminates the type of the medal M by comparing the image of the medal M that passes through the portion where it is arranged in the transport path 92 with the image data held by the discrimination sensor 96 itself. In addition, since the form of the front and back of each medal M is generally the same, the discrimination sensor 96 can discriminate the type of the medal M by either the front or back of the medal M. The discrimination sensor 96 discriminates the type of the medal M to determine whether or not the medal M is regular (own store medal M1) or the degree of irregularity when the medal M is irregular (same as above). It is possible to determine whether it is affiliated other store medal M2 or other affiliated medal M3).

As will be described later, of the medals M transported on the transport path 92, the own store medal M1 is transported through the transport path 92 to the end and collected by the main hopper 103, and the other store medal M2 falls in the second drop. It drops from the hole 102B and is collected in the sub hopper 104, and the other series other store medal M3 falls from the first drop hole 102A and is returned to the return port 24.
Each of the first passage sensor 97, the second passage sensor 98, the third passage sensor 99, and the fourth passage sensor 100 constitutes a so-called light shielding sensor. These passage sensors are arranged so as to be spaced apart in the length direction of the transport path 92. The first passage sensor 97 is disposed between the slit 101 and the discrimination sensor 96, and the second passage sensor 98 is disposed between the discrimination sensor 96 and the first drop hole 102A. The third passage sensor 99 is disposed between the first drop hole 102A and the second drop hole 102B, and the fourth pass sensor 100 is positioned downstream of the second drop hole 102B (first position) in the direction away from the slit 101. 2 between the fall hole 102B and the main hopper 103).

  The first passage sensor 97 includes a light emitting element 97A that emits detection light (not shown) and a light receiving element 97B that receives the detection light from the light emitting element 97A. The light emitting element 97A and the light receiving element 97B are opposed to each other with an interval so as to sandwich the conveyance path 92 from a direction (vertical direction in FIG. 16) orthogonal to the length direction of the conveyance path 92 in plan view. . The first passage sensor 97 detects that one medal M has passed at the position where the first passage sensor 97 is disposed, by the fact that the detection light is once blocked.

  Each of the second passage sensor 98 to the fourth passage sensor 100 also has the same configuration as the first passage sensor 97. That is, the second passage sensor 98 includes a light emitting element 98A and a light receiving element 98B that are arranged to face each other with the conveyance path 92 interposed therebetween, and the detection light between the light emitting element 98A and the light receiving element 98B is once blocked. It is detected that one medal M has passed at the position where is placed. Similarly, the third passage sensor 99 includes a light emitting element 99A and a light receiving element 99B that are opposed to each other with the conveyance path 92 interposed therebetween, and the detection light between the light emitting element 99A and the light receiving element 99B is interrupted once. It detects that one medal M has passed at the position where it is placed. Similarly, the fourth passage sensor 100 includes a light emitting element 100A and a light receiving element 100B that are opposed to each other with the conveyance path 92 interposed therebetween, and the detection light between the light emitting element 100A and the light receiving element 100B is interrupted once. It detects that one medal M has passed at the position where it is placed.

Hereinafter, each of the first passage sensor 97 to the fourth passage sensor 100 is assumed to be “ON” when it is detected that one medal M has passed.
FIG. 17 is a block diagram of the control circuit of the medal depositing machine 2, and is a block diagram showing only the parts related to the features of the present invention.
Referring to FIG. 17, the medal deposit machine 2 includes the control unit 40 (see FIG. 3) described above. In the medal depositing machine 2, the discrimination sensor 96, the first passage sensor 97, the second passage sensor 98, the third passage sensor 99, the fourth passage sensor 100, and the rotating disk motor 107 are described with respect to the control unit 40. The conveyor belt drive motor 108, the first actuator 109, and the second actuator 110 are electrically connected. These constitute the depositing part 41 and the counting part 43 (see FIG. 3) described above.

  The turntable motor 107 drives the turntable 90 to rotate. The conveyor belt drive motor 108 moves the conveyor belt 93 around. The first actuator 109 advances and retracts the first reject bearing 105. The second actuator 110 advances and retracts the second reject bearing 106. A stepping motor can be used for each of the first actuator 109 and the second actuator 110.

FIG. 18 is a flowchart showing a control operation performed regarding the distribution of medals in the medal deposit machine 2.
Next, a procedure for processing medals deposited in the medal depositing machine 2 by being inserted into the medal depositing gate 17 (see FIG. 2) in the medal depositing machine 2 will be described with reference to FIG.
It is assumed that the turntable motor 107 has already driven the turntable 90 to rotate, and the transport belt drive motor 108 has moved the transport belt 93 around (see FIG. 16).

  The controller 40 (see FIG. 17) monitors whether or not the first passage sensor 97 (see FIG. 16) is turned on in the standby state (step S91). When the medal M on the turntable 90 starts to be conveyed on the conveyance path 92 through the slit 101 and passes through the first passage sensor 97 (between the light emitting element 97A and the light receiving element 97B), the first passage sensor 97 is turned on. (See FIG. 16).

When the first passage sensor 97 is turned on (YES in step S91), the control unit 40 increments (+1) the variable P (initially 0 “zero”) (step S92).
Next, the control unit 40 confirms whether or not the medal M has been discriminated by the discriminating sensor 96 when the medal M that has passed the first passing sensor 97 passes through the discriminating sensor 96 (step S93). If there is no discrimination by the discrimination sensor 96 even after the predetermined time has elapsed (NO in step S93), the medal M is jammed on the upstream side (the slit 101 side) of the discrimination sensor 96 in the transport path 92. The unit 40 notifies the error via the display / operation unit 16 (see FIG. 2) or the like, and prompts the staff to cancel the error (step S94).

When there is a determination by the determination sensor 96 (YES in step S93), the control unit 40 determines whether or not the determined medal M is a medal of another series (that is, the other series other store medal M3 described above). Confirm (step S95).
If the medal M is the other series other store medal M3 (YES in step S95), the control unit 40 monitors whether or not the second passage sensor 98 (see FIG. 16) is turned on (step S96). When the other series other store medal M3 is subsequently conveyed after being identified by the discrimination sensor 96 and passes through the second passage sensor 98 (between the light emitting element 98A and the light receiving element 98B), the second passage sensor 98 is turned ON ( (See FIG. 16). If the second passage sensor 98 does not turn ON after the predetermined time has passed (NO in step S96), the other-affiliated other store medal M3 is jammed upstream of the second passage sensor 98 in the transport path 92. Therefore, the control unit 40 notifies an error as described above (step S94).

  If the second passage sensor 98 is turned on (YES in step S96), the control unit 40 increments (+1) the variable Q (initially 0 “zero”), and the second passage sensor 98 is turned on. When a predetermined time has elapsed, the first actuator 109 (see FIG. 17) is turned on, and the first reject bearing 105 (see FIG. 16) is temporarily advanced (step S97). The predetermined time is a time required for the other series other store medal M3 to pass through the second passage sensor 98 and reach the first passage portion 92A, and is predetermined by an experiment or the like. It should be noted that the error correction for the predetermined time is appropriately performed in accordance with the conveyance speed of the medals in the conveyance path 92 (circulation speed of the conveyance belt 93 and the like). When the error is corrected, the passing timing (passing time) of the medal M between the first passing sensor 97 and the second passing sensor 98 is taken into consideration. In this way, the advance timing of the first reject bearing 105 is adjusted.

  When the first reject bearing 105 advances in step S97, the other-affiliated other store medal M3 that has reached the first passage portion 92A falls from the first drop hole 102A and passes through the first branch path 94 before being returned. It is returned to the customer from the mouth 24 (see FIG. 2) (see FIG. 16). Since the advance timing of the first reject bearing 105 is adjusted as described above, the advanced first reject bearing 105 can drop the other series other store medal M3 from the first drop hole 102A without swinging. it can. Even if another type of medal M is transported in the transport path 92 before and after the other-affiliated other store medal M3, only the other-affiliated other-store medal M3 is the first by the error correction of the advance timing described above. 1 It falls from 102A of fall holes.

  On the other hand, if the medal M determined in step S93 is not another series of medals (other series other store medal M3) (NO in step S95), the medal M is the same as the above-mentioned own store medal M1, the same series other, etc. One of the store medals M2. In this case, the control unit 40 checks whether or not the medal M is a medal of another store (that is, the same series other store medal M2) based on the determination result by the determination sensor 96 (step S98).

  When the medal M is a medal of another store (the same series other store medal M2) (YES in step S98), the control unit 40 causes the second affiliated sensor medal M2 to pass through the second passage sensor 98. It is monitored whether or not the 2-pass sensor 98 (see FIG. 16) is turned on (step S99). If the second passage sensor 98 is not turned ON after the predetermined time has elapsed (NO in step S99), the same-series other store medal M2 is clogged upstream of the second passage sensor 98 in the transport path 92. Therefore, the control unit 40 notifies an error in the same manner as in step S94 (step S100).

  When the second passage sensor 98 is turned on (YES in step S99), the control unit 40 monitors whether or not the third passage sensor 99 (see FIG. 16) is turned on (step S101). ). When the medal M2 in the same series passes through the second passage sensor 98 and is subsequently conveyed through the conveyance path 92 and passes through the third passage sensor 99 (between the light emitting element 99A and the light receiving element 99B), the third passage The sensor 99 is turned on (see FIG. 16). If the third passage sensor 99 does not turn ON after the predetermined time has elapsed (NO in step S101), the same-series other store medal M2 is jammed upstream of the third passage sensor 99 in the transport path 92. Therefore, the control unit 40 notifies an error as described above (step S100).

  If the third passage sensor 99 is turned on (YES in step S101), the control unit 40 increments (+1) the variable R (initially 0 “zero”) and the third passage sensor 99 is turned on. When the predetermined time has elapsed, the second actuator 110 (see FIG. 17) is turned on, and the second reject bearing 106 (see FIG. 16) is temporarily advanced (step S102). The predetermined time is a time required for the same-line affiliated store medal M2 to pass through the third passage sensor 99 and reach the second passage portion 92B, and is determined in advance by an experiment or the like. It should be noted that the error correction for the predetermined time is appropriately performed in accordance with the conveyance speed of the medals in the conveyance path 92 (circulation speed of the conveyance belt 93 and the like). At the time of error correction, the passage timing (passing time) of the medal M between the second passage sensor 98 and the third passage sensor 99 is taken into consideration. In this way, the advance timing of the second reject bearing 106 is adjusted.

  When the second reject bearing 106 advances in step S102, the other-affiliated medal M2 that has reached the second passage portion 92B falls from the second drop hole 102B, passes through the second branch path 95, and then enters the sub hopper. 104 (see FIG. 16). The affiliated other store medal M2 stored in the sub hopper 104 is collected by a staff member during the maintenance of the medal depositing machine 2, and returned to the affiliated other store handling the affiliated other store medal M2. Since the advance timing of the second reject bearing 106 has been adjusted as described above, the advanced second reject bearing 106 can drop the other store medal M2 from the second drop hole 102B without swinging. it can. Further, even if another type of medal M is transported in the transport path 92 before and after the same-line affiliated store medal M2, only the relevant affiliated store medal M2 is the first by the above-described error correction of the advancement timing. 2 It falls from the fall hole 102B.

  In step S98, when the medal M determined by the determination sensor 96 is not the medal of another store but the own store medal M1 (NO in step S98), the control unit 40 determines that the own store medal M1 is the second passage sensor. It is monitored whether or not the second passage sensor 98 (see FIG. 16) is turned on by passing the passage 98 (step S103). If the second passage sensor 98 does not turn ON after the predetermined time has elapsed (NO in step S103), the own store medal M1 is jammed upstream of the second passage sensor 98 in the transport path 92. The control unit 40 notifies an error (step S100).

  When the second passage sensor 98 is turned ON (YES in step S103), the control unit 40, this time, the control unit 40 causes the first store medal M1 to pass through the third passage sensor 99. It is monitored whether or not the 3-pass sensor 99 (see FIG. 16) is turned on (step S104). If the third passage sensor 99 is not turned ON after the predetermined time has elapsed (NO in step S104), the own store medal M1 is jammed upstream of the third passage sensor 99 in the transport path 92. The control unit 40 notifies an error (step S100).

  When the third passage sensor 98 is turned on (YES in step S104), the control unit 40 monitors whether or not the fourth passage sensor 100 (see FIG. 16) is turned on (step S105). ). When the own store medal M1 passes through the third passage sensor 99 and is subsequently conveyed through the conveyance path 92 and passes through the fourth passage sensor 100 (between the light emitting element 100A and the light receiving element 100B), the fourth passage sensor 100 is obtained. Is turned on (see FIG. 16). If the fourth passage sensor 100 does not turn ON after the predetermined time has elapsed (NO in step S105), the own store medal M1 is jammed upstream of the fourth passage sensor 100 in the transport path 92. The control unit 40 notifies an error as described above (step S100).

  If the fourth passage sensor 100 is turned on (YES in step S105), the control unit 40 increments (+1) the variable S (initially 0 “zero”) (step S106). Referring to FIG. 16, the own store medal M <b> 1 that has passed through the fourth passage sensor 100 is collected to the main hopper 103 after being conveyed through the conveyance path 92 to the end, and during the subsequent medal payout transaction, To be paid out.

  In this way, the medals M on the turntable 90 inserted from the medal deposit opening 17 (see FIG. 2) are successively transferred from the slit 101 to the transport path 92 and are determined by the determination sensor 96. The medal M that has been discriminated by the discrimination sensor 96 is sent to the return port 24 from the first drop hole 102A via the first branch hole 94 if it is another series other store medal M3 according to the discrimination result of the discrimination sensor 96. If the medal M2 of the same series is stored in the sub hopper 104 from the second drop hole 102B via the second branch path 95, the medal M1 is stored in the main hopper 103 after flowing through the transport path 92 to the end. Collected. That is, the medal M on the turntable 90 is changed according to the determination result by the determination sensor 96 (depending on the type of the medal M), the return port 24 that is the first distribution destination, and the sub hopper that is the second distribution destination. 104 and any one of the main hoppers 103 that are the third distribution destinations (any of the three distribution destinations). The distribution of the medals M is performed by a distribution unit that is a group of the control unit 40, the first passage sensor 97, the second passage sensor 98, the third passage sensor 99, the first actuator 109, and the second actuator 110 (see FIG. 17). Executed.

That is, in the medal depositing machine 2, it is possible to determine that the deposited medal M is one of the three types of medals M, and distribute each type of medal M to different distribution destinations. Therefore, it is compatible with many kinds of medals M and is easy to use.
In particular, the other-affiliated other-store medals M3 having a relatively high degree of irregularity can be quickly returned to customers outside the machine by rejecting them to the return port 24, which is convenient. Here, among the first to third distribution destinations, the distribution of the other series other store medal M3 to the first distribution destination (return port 24) is performed first (FIG. 18). Steps S93 to S97). Therefore, since the other-affiliated other store medal M3 is first sorted and the other-affiliated other-store medal M3 is promptly returned to the customer, the customer inserts the wrong medal M3 into the medal deposit machine 2. It is easy to use and is easy to use.

  Each time one medal M passes through each of the first passage sensor 97 to the fourth passage sensor 100, the control unit 40 increments the variables P, Q, R, and S by one (step in FIG. 18). S92, S97, S102, S106). Here, at the time immediately after the medal M depositing process is completed by all the medals M (except those that cannot pass through the slit 101) on the turntable 90 being distributed to the first to third distribution destinations, Each of the variables P and Q is the total number of medals M (excluding those that could not pass through the slit 101) that were on the turntable 90 before the start of sorting. The variable R at that time is the total number of the own store medal M1 and other affiliated medal M2 that did not fall in the first drop hole 102A, and the variable S at that time is the first drop hole 102A and This is the total number of own store medals M1 that did not fall in the second drop hole 102B. The control unit 40 can obtain the total number of other affiliated medals M3 sent to the return port 24 by subtracting the variable R from the variable P or Q at the time. In addition, the control unit 40 can obtain the total number of the same-series other-store medals M2 sent to the sub hopper 104 by subtracting the variable S from the variable R at that time.

  In this medal deposit machine 2, the other-affiliated other store medal M3 is not subject to deposit (the aforementioned saving medal), and the own store medal M1 and the other affiliated medal M2 are subject to deposit, so the own store medal M1 The variable R, which is the total number of other store medals M2 of the same series, is the number of medals M finally deposited (the number of deposited medals, the number of additional stored medals). That is, the control unit 40 counts the medals M to be deposited by using the first currency sensor 97 to the fourth currency sensor 100 as described above, but other than being distributed to the return port 24 from the count target. The affiliated store medal M3 is excluded. Therefore, it is possible to prevent the miscalculation from occurring in the number of deposits by counting the medals M in a state where the other series other store medals M3 are mixed.

  For the convenience of managing medals M, not only the number of deposits but also the total number of other series other store medals M3 and the same series other store medals M2 are managed. In addition, when the discrimination sensor 96 discriminates the same series other store medal M2 or the other series other store medal M3, a warning to that effect (the inserted medal M is not the own store medal M1) at an arbitrary timing. Alternatively, the display operation unit 16 may notify the customer that the other store medal M2 can be deposited as a stored medal.

  In this embodiment, the medals M on the turntable 90 inserted from the medal deposit door 17 are changed according to their types into the first distribution destination (return port 24) and the second distribution destination (sub hopper). 104) and the third distribution destination (main hopper 103). Here, if the medals M can be subdivided into three or more types, three or more distribution destinations for the medals M are provided accordingly, and the medals M are distributed to the distribution destinations according to the types. Also good.

The present invention is not limited to the contents of the above embodiments, and various modifications can be made within the scope of the claims.
For example, only one of the plurality of medal depositing machines 2 is set as the parent machine 2A, but a plurality of medal depositing machines 2 may be used as the parent machine 2A. What is necessary is just to set the priority which becomes the main | base station 2A. By doing so, the medal depositing system 1 can be maintained because the medal depositing machine 2 of the next priority is substituted for the parent unit 2A even if the condition of the parent unit 2A during the degenerate operation is deteriorated.

  Further, the above-described degenerate operation execution instruction may be transmitted from the slave unit 2B that has detected a communication abnormality to the all medal depositing device 2 instead of being transmitted from the master unit 2A to the all medal depositing unit 2.

2 medal deposit machine 17 medal deposit port 24 return port 40 control unit 96 discrimination sensor 97 first passage sensor 98 second passage sensor 99 third passage sensor 103 main hopper 104 sub hopper 109 first actuator 110 second actuator M medal M1 own store Medals M2 Other affiliate medals M3 Other affiliate medals

Claims (4)

An insertion section where medals are inserted;
A feeding means for feeding out the medals thrown into the insertion unit one by one;
Discriminating means for discriminating the type of medal paid out by the paying means;
A distribution unit that distributes medals to a distribution destination corresponding to a determination result of the determination unit;
Including
The distribution destination includes at least three distribution destinations, a first distribution destination, a second distribution destination, and a third distribution destination.
The discriminating means discriminates medals into at least three types of first medal, second medal, and third medal,
The medal processing device, wherein the distribution unit distributes medals to a distribution destination corresponding to each type of medal based on a determination result of the determination unit.   2. The medal according to claim 1, wherein the first distribution destination is a return unit that is discharged outside the apparatus, and is a distribution destination to which the first medal determined by the determination unit is distributed. Processing equipment.   The determination means determines the kind of medal and also determines a foreign object different from the medal, and the distribution means distributes the foreign object to the first distribution destination. 2. The medal processing device according to 2.   Regarding the types of medals determined by the determining means, the first medal is an other store medal, the second medal is a group store medal, and the third medal is an own store medal. The medal processing device according to any one of claims 1 to 3.

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