JP4884550B2 - Game system - Google Patents

Description

  The present invention relates to a gaming device provided corresponding to a gaming machine provided with a gaming processing unit for executing control relating to a game, and a gaming processing unit mounted on each gaming machine delivered to a gaming ground. And a management device that stores identification information that can be identified by the gaming machine, and in particular, the identification information stored in the gaming arithmetic processing device mounted on the gaming machine is stored in the gaming machine corresponding to the gaming machine. The present invention relates to a gaming system that transmits information to a management device via a device and checks whether or not it matches the regular identification information stored in the management device.

Conventionally, as shown in Patent Document 1, an ID number stored in a main control board mounted on a gaming machine is transmitted to a machine, and the transmitted ID number is held by a center management device. Whether the gaming machine is equipped with a regular main control board (in other words, whether the gaming machine is equipped with a regular main control board) A monitoring system for monitoring whether or not a main control board has been replaced with an unauthorized board is known .

JP 2002-258964 (pages 5-6, FIGS. 5-7)

However, if it is configured to activate the lending process in the inter-vehicle machine on condition that the ID numbers match, it has a new gaming machine having a function of transmitting the ID number and a function of transmitting the ID number. In a case where conventional gaming machines that are not used are mixed, the lending machine corresponding to the new gaming machine activates the lending process based on the coincidence of the ID numbers transmitted from the new gaming machine. However, since the ID number is not transmitted from the conventional gaming machine, the lending process cannot be activated in the inter-game machine corresponding to the conventional gaming machine. There is a problem that cannot be secured .

The present invention has been made based on such a background, and an object thereof is to use identification information (corresponding to the ID number) stored in a game arithmetic processing device (corresponding to the main control board). Matching and activating a lending process in a gaming device on condition that the identification information matches, for gaming that can secure a game in a gaming machine that does not have a function of transmitting the identification information To provide a system.

  The present invention adopts the following means in order to solve the above problems. The reference numerals used in the description of the best mode for carrying out the invention and the drawings to be described later are appended in parentheses for reference, but the constituent elements of the present invention are not limited to the appended description.

Invention first described in claim 1 is provided corresponding to Yu TECHNICAL machine (pachinko machine 100), the size of the valuable resource available to the player (deposit balance, the card balance) is information for specifying the recorded A lending process (ball lending process) that lends a game medium (pachinko ball) from the gaming machine using the magnitude of the valuable value specified from the record information of the game recording medium (encapsulated card 7, membership card 8). A gaming device (card unit 200) having a lending processing means (unit control unit 220 ) to be performed, and the gaming device that is communicable with the gaming device and installed in each gaming machine delivered to the gaming hall (2). Management device (center server) provided with identification information storage means (hard disk 25) for storing identification information (chip ID) that can individually identify a game processing unit (main board 150) that executes control related to the game of the machine And bar 20), comprising a gaming system (1) from the gaming device, said corresponding the identification information stored in the corresponding said gaming processor mounted to the gaming machine Identification information acquisition means (unit control unit 220) acquired from the gaming machine, identification information transmission means (card R / W control unit 230) for transmitting the identification information acquired by the identification information acquisition means to the management device, , Bei example, said management apparatus, collating means for collating whether the identification information transmitted from the identification information transmitting means matches the identification information stored in the identification information storage unit (control unit 22 a) Introduction Bei collation result transmitting means for transmitting a verification result by the collating means with respect to the game apparatus which is the source of the identification information (communication unit 21), the said lending processing means, collating result Is it a transmission means? On condition that it has received the unmatched that collation result, the lending process as well as deactivation, the management device, or has a function of the gaming machine installed in a game arcade to send the identification information whether Based on the storage contents of the transmission availability storage means (hard disk 25) and the transmission availability storage means, the game device corresponding to the gaming machine that does not have the function of transmitting the identification information, Identification information transmission impossible information transmitting means (communication unit 21) for transmitting identification information transmission impossible information indicating that the corresponding gaming machine does not have a function of transmitting the identification information; And without performing the processing by the identification information acquisition unit and the processing by the identification information transmission unit on condition that the identification information transmission impossible information has been received from the identification information transmission impossibility information transmission unit. A gaming system, characterized in that for activating the lending processing by the lending processing unit.

The invention according to claim 2, provided corresponding to Yu TECHNICAL machine (pachinko machine 100), the size of the valuable resource available to the player (deposit balance, the card balance) is information for specifying the recorded A lending process (ball lending process) that lends a game medium (pachinko ball) from the gaming machine using the magnitude of the valuable value specified from the record information of the game recording medium (encapsulated card 7, membership card 8). A gaming device (card unit 200) having a lending processing means (unit control unit 220 ) to be performed, and the gaming device that is communicable with the gaming device and installed in each gaming machine delivered to the gaming hall (2). Management device (center server) provided with identification information storage means (hard disk 25) for storing identification information (chip ID) that can individually identify a game processing unit (main board 150) that executes control related to the game of the machine And bar 20), comprising a gaming system (1) from the gaming device, said corresponding the identification information stored in the corresponding said gaming processor mounted to the gaming machine Identification information acquisition means (unit control unit 220) acquired from the gaming machine, identification information transmission means (card R / W control unit 230) for transmitting the identification information acquired by the identification information acquisition means to the management device, , Bei example, said management apparatus, collating means for collating whether the identification information transmitted from the identification information transmitting means matches the identification information stored in the identification information storage unit (control unit 22 and), and the verification result transmitting means for transmitting a verification result by the collating means with respect to the game apparatus which is the source of the identification information (communication unit 21), Bei example, said gaming apparatus, said comparison result Is it a transmission means? On condition that it has received a matching that of the verification result, whether to send activation signal for enabling the operation of the gaming machine in which the corresponding to the player machine to the corresponding, or from the verification result sending unit Game operation signal transmission for performing a process of transmitting to the corresponding gaming machine an immobilization signal for disabling the operation of the corresponding gaming machine on condition that a matching result indicating that they do not match is received Means (unit control unit 220), and the management device stores whether or not each gaming machine installed in the game hall has a function of transmitting the identification information (hard disk 25). And the game machine corresponding to the gaming machine that does not have the function of transmitting the identification information based on the storage content of the transmission permission / inhibition storage means, the corresponding gaming machine sends the identification information to the gaming machine. Identification information transmission impossibility information transmission means (communication unit 21) for transmitting identification information transmission impossibility information indicating that it does not have a function to communicate, and the gaming apparatus includes the identification information transmission impossibility information transmission means. Whether the activation signal is transmitted by the game operation signal transmission unit without performing the processing by the identification information acquisition unit and the processing by the identification information transmission unit on condition that the identification information transmission impossible information is received from Or a gaming system, wherein the disabling signal is not transmitted.

First, according to the gaming system according to claim 1, for a gaming machine having a function of transmitting identification information, by performing a matching identification information, gaming machine is replaced with incorrect gaming processor Since the lending process is disabled in the gaming apparatus corresponding to the above, gaming in the gaming machine can be prevented. On the other hand, since the lending process is activated in a gaming device corresponding to a conventional gaming machine that does not have a function of transmitting identification information, a game in the gaming machine can be reliably secured.

According to the gaming system according to claim 2, for a gaming machine having a function of transmitting identification information, by performing a matching identification information, gaming machine is replaced with incorrect gaming processor Since the operation of the gaming machine is disabled, the gaming on the gaming machine can be prevented. On the other hand, since the lending process is activated in a gaming device corresponding to a conventional gaming machine that does not have a function of transmitting identification information, a game in the gaming machine can be reliably secured.

FIG. 1 is a functional block diagram showing an example of a gaming system according to the present invention. FIG. 2 is a diagram illustrating an example of a delivery chip ID list acquired by the center server from a gaming machine manufacturer. FIG. 3 is a diagram illustrating an example of a screen displayed on the display of the system controller. (A) is a chip ID acquisition screen upon delivery, (b) is an operating chip ID acquisition setting screen, and (c) is an operating chip. It is an ID acquisition request screen. FIG. 4 is a diagram illustrating an example of the sales management DB and the remaining amount management DB stored in the hard disk of the system controller. FIG. 5 is a diagram illustrating an example of a screen displayed on the display of the center server, where (a) is a pre-starting chip ID acquisition setting screen, and (b) is a consumption tax rate setting screen. FIG. 6 is a diagram illustrating an example of a verification chip ID list stored in the hard disk of the center server. FIG. 7A is a front view showing an example of a pachinko machine and a card unit according to the present invention, FIG. 7B is a cross-sectional right side view of the card unit, and FIG. It is line sectional drawing. FIG. 8 (a) is a diagram showing an example of a remaining frequency indicator which is provided in a pachinko machine and is composed of three segment indicators composed of 7 segment LEDs, and FIG. 8 (b) is a diagram showing the remaining frequency indicator on the remaining frequency indicator. FIG. 8C is a diagram illustrating an example in which the frequency is displayed, and FIG. 8C is a diagram illustrating an example in which the fractional amount is displayed on the remaining frequency display. FIG. 9 is a functional block diagram showing an example of a pachinko machine. FIG. 10 is a functional block diagram illustrating an example of a card unit. FIG. 11 is a timing chart showing an example of dynamic lighting control in the remaining frequency indicator, where (a) is a timing chart in normal time other than during business chip ID acquisition processing and fraction ball lending processing, and (b) is sales. It is a timing chart at the time of middle chip ID acquisition processing and fraction ball lending processing. FIG. 12 is a circuit diagram showing an example of a circuit for transmitting and receiving signals between the pachinko machine and the card unit. FIG. 13 is a circuit diagram showing an example of a 7-segment LED interface in a conventional pachinko machine and a card unit. FIG. 14 is a circuit diagram showing an example of a 7-segment LED interface in a pachinko machine and a card unit according to the present invention. FIG. 15A is a timing chart showing an example of the chip ID acquisition process, and FIG. 15B is a timing chart showing an example of the immobilization signal transmission process. FIG. 16 is a timing chart showing an example of the unit ball lending process. FIG. 17 is a timing chart illustrating an example of the fraction lending process. FIG. 18 is a flowchart showing an example of pre-business start processing in the card unit. FIG. 19 is a flowchart showing an example of the business process in the card unit. FIG. 20 is a flowchart showing an example of chip ID acquisition processing in the card unit. FIG. 21 is a flowchart showing an example of visitor ball lending processing in the card unit. FIG. 22 is a flowchart showing an example of a deposit process in the card unit. FIG. 23 is a flowchart showing an example of the member-unit ball lending process in the card unit. FIG. 24 is a flowchart showing an example of the membership fraction lending process in the card unit. FIG. 25 is a flowchart showing an example of pre-business start processing in a pachinko machine. FIG. 26 is a flowchart showing an example of ball lending control in a pachinko machine. FIG. 27 is a flowchart showing an example of the operating chip ID transmission process in the pachinko machine. FIG. 28 is a diagram illustrating an example of the operation of the gaming system according to the first embodiment. FIG. 29 is a diagram illustrating an example of the operation of the gaming system according to the second embodiment. FIG. 30 is a timing chart illustrating an example of the fraction lending process according to the modification.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. As shown in FIG. 7A, the gaming machine (here pachinko machine 100) according to the present invention is composed of a plurality of segment indicators, and the value of value that can be used for the game (here, the balance of the deposit, the card) A value indicator (here, the remaining frequency display) that displays the value of the value specified from the record information of the game recording medium (here, the encapsulated card 7 and the membership card 8) in which information that can specify the remaining amount) is recorded Device 121) and a game processing unit (in this case, the main board 150 shown in FIG. 9) for executing control related to the game. Further, as shown in FIG. 1, the gaming system 1, 1 ′ according to the present invention is provided corresponding to the gaming machine and uses the magnitude of the valuable value to play a gaming medium (here, a pachinko ball). A gaming device (here, card unit 200) that performs a lending process for lending (here, a ball lending process) and a gaming device that is communicable with the gaming device and is mounted on each gaming machine delivered to the amusement hall It comprises a management device (in this case, the center server 20 and the system controller 10 ′) that stores identification information that can individually identify the arithmetic processing device.

  The present invention transmits identification information (here, a chip ID) stored in a gaming arithmetic processing device mounted on a gaming machine to the management device via the corresponding gaming device from the gaming machine. Whether or not the gaming machine is equipped with a regular game processing device by collating with the regular identification information stored in the device (in other words, the regular gaming computing device is Display data signal lines included in the existing signal lines connecting between the gaming machine and the gaming device, in particular. By transmitting the identification information via the terminal, it is not necessary to add a new signal line for transmitting the identification information, and it is not necessary to add a new interface corresponding to the signal line on the gaming machine side. It is characterized in.

  Here, in the gaming system according to the present invention, as shown in FIG. 28, which will be described later, the center server 20 which is a management device provided outside the gaming hall performs the chip ID verification (S39, S69) in the first embodiment. As shown in FIG. 29 to be described later, the gaming system 1 and a system controller 10 ′, which is a management device provided in the game hall, perform chip ID verification (S38 ′, S68 ′) according to the second embodiment. A gaming system 1 '. The gaming machine (pachinko machine 100) according to the present invention is common to both the first embodiment and the second embodiment.

  In the following, the first embodiment will be described first, and then the second embodiment will be described only with respect to differences from the first embodiment. In the following, the light emitting diode is abbreviated as “LED”, the segment as “SEG”, the database as “DB”, the signal input / output unit as “I / O”, and the reader / writer as “R / W”.

  In the present invention, in consideration of collecting a consumption tax on the amount of valuable value used for lending the game medium (the amount of ball lending used), a predetermined unit valuable value ( It is also possible to lend a number of gaming media equivalent to the fractional value (fractional amount) less than 1), especially to the existing signal line connecting the gaming machine and the gaming device Lending number designation signal (ball lending number designation signal) indicating the number of game media (ball lending number) equivalent to the value of fractional value during the non-transmission period of the strobe signal described later via the included display data signal line Is transmitted from the gaming device to the gaming machine, it is not necessary to add a new signal line for transmitting the loan number designation signal, and a new corresponding to the signal line on the gaming machine side. Need to add interface Also characterized in that there is no. In the following, an example will be described in which the consumption tax rate is 5%, and the frequency of one unit value is 105 yen including the consumption tax.

[1. Game system 1 according to the first embodiment]
First, with reference to FIGS. 1-17, the structure of the game system 1 which concerns on 1st Embodiment is demonstrated. As shown in FIG. 1, the gaming system 1 includes a card unit 200 that is a gaming device provided corresponding to the pachinko machine 100 that is a gaming machine according to the present invention, and each gaming hall 2. The system controller 10 that is an in-house management device that can communicate with the card unit 200 provided in the game hall 2 and the center server 20 that is provided outside the game hall and can communicate with the system controller 10. And consist of Although FIG. 1 shows three game halls A to C as the game hall 2, the number of the game halls 2 is not particularly limited.

  Here, the center server 20 is provided in the card company 3 that issues and manages the membership card 8 described later. Further, the center server 20 is communicably connected to the gaming machine manufacturer 4 (in this case, the gaming machine manufacturer AA and the gaming machine manufacturer BB) that manufactures the pachinko machine 100. From each gaming machine manufacturer 4, a delivery chip ID list is provided. To get. As shown in FIG. 2, this delivery chip ID list is a list showing chip IDs of the respective pachinko machines 100 delivered to each game hall 2 with respect to a plurality of game halls 2 (here, game halls A to C). A chip ID is recorded in association with each game hall.

  Here, the chip ID is an example of identification information that can be individually identified for a game processing unit (main board 150) that is mounted on each pachinko machine 100 and executes control related to the game of the pachinko machine 100. Then, it is a 9-digit ID represented by numbers 0 to 9 and letters A to E. Therefore, each digit of the chip ID is represented by 4 bits. The first two digits of the chip ID are an identification code indicating the gaming machine manufacturer 4 that manufactured the pachinko machine 100. The chip ID is stored in a ROM 151b mounted on a basic circuit 151 that is a one-chip microcomputer provided on the main board 150, as shown in FIG.

  In this gaming system 1, as shown in FIG. 7 described later, bills 5, coins 6, an enclosing card 7, and a membership card 8 are used. The banknote 5 is an example of money, and here, as shown in FIG. 7B, four kinds of banknotes such as a 1000 yen banknote, a 2000 yen banknote, a 5000 yen banknote, and a 10000 yen banknote can be used. The coin 6 is also an example of money, and here is a 500 yen coin as shown in FIG. Here, when the membership card 8 is not accepted in the card unit 200 (that is, when a visitor ball lending process shown in FIG. 21 described later is performed), only 1000 yen bills and 500 yen coins can be accepted. When the member card 8 with a card balance of zero or a fractional amount is received in the card unit 200 (that is, when a deposit process shown in FIG. 22 described later is performed), all types of money can be received. However, when the member card 8 whose remaining card amount is equal to or more than the number of times is accepted in the card unit 200, all kinds of money cannot be accepted (that is, money cannot be deposited).

  The encapsulated card 7 is an example of a game recording medium, and records information (here, the balance of deposit) that can identify the value of valuable value that can be used for the game. This deposit balance is received when the card unit 200 accepts money in a state where the member card 8 is not accepted, and the amount of the accepted money is identified by the bill discriminator 240 or the coin discriminator 250 described later. This identification amount is recorded as the deposit balance. The encapsulating card 7 is formed by forming a recording area (not shown) in which a deposit amount is recorded at a predetermined portion of a thin plastic plate having a rectangular shape. Here, a non-volatile recording area is used as the recording area. An IC card on which a non-contact type integrated circuit including an EEPROM is mounted. As shown in FIG. 7B, the enclosing card 7 is encapsulated inside the gaming device in a manner that the player cannot touch.

  The member card 8 is also an example of a game recording medium, and information (here, a member ID and a card remaining amount) that can specify the magnitude of the valuable value that can be used for the game is recorded. This member ID is information that can individually identify each member player, and is recorded in advance on the member card 8. The remaining amount of the card is the amount of money deposited to the member card 8 recorded as the remaining amount of the card. This member card 8 is also formed by forming a recording area (not shown) in which a member ID and the balance of the card are recorded at a predetermined part of a rectangular thin plastic plate. This is an IC card on which a non-contact type integrated circuit including a nonvolatile EEPROM is mounted. This member card 8 is issued to a member player who has registered as a member, and is inserted from the outside of the card unit 200 and used as shown in FIG.

  Hereinafter, each component of the gaming system 1 will be described. First, the system controller 10 will be described with reference to FIGS. The system controller 10 is an example of a management device. Here, the system controller 10 is the on-site management device provided at a predetermined location (for example, a management office) in the game hall 2, and is connected as shown in FIG. 11a, in-field communication unit 11b, control unit 12, display 13, input device 14, hard disk 15 and the like.

  The out-of-field communication unit 11a is communicably connected to a later-described communication unit 21 of the center server 20 and manages communication between the system controller 10 and the center server 20. As shown in FIG. 10 described later, the on-site communication unit 11b is communicably connected to the card R / W control unit 230 of the card unit 200 and manages communication between the system controller 10 and the card unit 200. . The control unit 12 includes a CPU, a RAM, a ROM, and the like. The processing program stored in the hard disk 15 is executed by the CPU using the RAM as a work area, thereby controlling the operation of each component provided in the system controller 10. Various processes are performed.

  The display 13 displays various information, and the input device 14 receives various inputs (for example, a keyboard and a mouse). As shown in FIG. 3, the display 13 displays a screen corresponding to each mode executed in the system controller 10 by an operation of a store clerk in the game hall 2.

  Specifically, when the pachinko machine 100 is delivered or rearranged at the amusement hall 2 (hereinafter collectively referred to as “delivery time”), the system controller 10 delivers the pachinko machine 100 by the operation of the store staff at the amusement hall 2. When the time chip ID acquisition mode is executed, a delivery time chip ID acquisition screen shown in FIG. On this delivery chip ID acquisition screen, a machine number input field for inputting the machine number of the pachinko machine 100 that has been delivered or rearranged is displayed as a chip ID acquisition target.

  In this delivery-time chip ID acquisition screen, the store clerk of the game hall 2 operates the input device 14 to enter the machine number (here, 001 to 010) of the pachinko machine 100 that has been delivered or rearranged in the machine number input field. ) And the “acquisition” button is operated, a delivery chip ID acquisition process is performed on the card unit 200 corresponding to the pachinko machine 100 of the input serial number. In this delivery chip ID acquisition process, a chip ID acquisition request is transmitted to the card unit 200, and the number of the pachinko machine 100 transmitted from the card unit 200 in response to the chip ID acquisition request When the chip ID is received, as shown in the table (upper side) of FIG. 3A, an installed chip ID list in which the received chip ID is recorded in association with the received machine number is created. However, when only the machine number of the pachinko machine 100 is transmitted from the card unit 200 and the chip ID is not transmitted, as shown in the table (lower side) of FIG. An installation chip ID list in which X marks (that is, that the pachinko machine 100 does not have an identification information transmission function described later) is recorded in association with each other. The created installed chip ID list is transmitted to the center server 20 and used for creating a verification chip ID list shown in FIG.

  In addition, when the system controller 10 executes the operating chip ID acquisition setting mode in the system controller 10 by the operation of a store clerk of the gaming hall 2 before the game hall 2 starts operating, the operating chip ID acquisition screen shown in FIG. Is displayed on the display 13. In this operating chip ID acquisition screen, it is possible to set a timing for acquiring a chip ID while the amusement hall 2 is operating, and an “interval designation” check box and an interval for setting a predetermined interval from the start of business as the timing An input field, a “time designation” check box for setting an arbitrary time as the timing, and a time input field are displayed.

  In this operating chip ID acquisition screen, a store clerk at the game hall 2 operates the input device 14 to specify the interval and / or the time, and operates the “set” button to display the specified interval and // Time (here, every 3 hours from the start of business) is set as the timing for acquiring the chip ID during business of the game hall 2. When the set timing is reached, a chip ID acquisition process during business is performed for the card unit 200 corresponding to the pachinko machine 100 having the identification information transmission function among the pachinko machines 100 installed in the game hall 2. . In this operating chip ID acquisition process, the chip ID acquisition request is transmitted to the card unit 200, and the serial number of the pachinko machine 100 is transmitted from the card unit 200 in response to the chip ID acquisition request. When the chip ID is received, as shown in the table of FIG. 3B, an installed chip ID list is created in which the received unit number and the chip ID are recorded in association with each other. The created installed chip ID list is transmitted to the center server 20 and collated with a collating chip ID list shown in FIG.

  Further, when the in-business chip ID acquisition request mode is executed in the system controller 10 by the operation of a store clerk in the game room 2 during the operation of the game room 2, the operating chip ID acquisition request screen shown in FIG. Is displayed on the display 13. In this operating chip ID acquisition request screen, the serial number of the pachinko machine 100 (for example, the pachinko machine 100 in which the main board 150 may be replaced with an unauthorized board) that wants to check the chip ID as a target for acquiring the chip ID. The unit number input field for entering is displayed.

  In this operating chip ID acquisition request screen, the store clerk of the game hall 2 operates the input device 14 to input the machine number (here, 003) of the pachinko machine 100 for which chip ID verification is desired in the machine number input field. When the “acquisition” button is operated, the chip ID acquisition process during business is performed on the card unit 200 corresponding to the pachinko machine 100 having the input serial number. In this operating chip ID acquisition process, the installed chip ID list shown in the table of FIG. 3C is created in the same manner as described above. The created installed chip ID list is transmitted to the center server 20 and collated with a collating chip ID list shown in FIG.

  The hard disk 15 as a storage device stores a sales management DB and a remaining amount management DB shown in FIG. In the sales management DB, each card unit 200 is associated with information that can be individually identified (here, the machine number of the pachinko machine 100 corresponding to each card unit 200) and used for the ball lending process in each card unit 200. Sales amount and consumption tax amount are stored and managed as the amount of ball lending used. The management contents of this sales management DB will be described later in the ball rental usage amount transmitted from the card unit 200 and the center server 20 every time the ball rental usage amount is transmitted from the card unit 200 in the ball rental processing in the card unit 200. The sales amount and the consumption tax amount calculated based on the consumption tax rate (5% here) set as shown in FIG. 5B are added and updated.

  The ball lending process includes a visitor ball lending process performed when money is received in a state where the membership card 8 is not received in the card unit 200, as shown in FIG. FIG. 24 shows a member-unit ball lending process performed when a ball lending operation is performed in a state where the remaining amount of the member card 8 accepted by the card unit 200 is equal to or more than one number (that is, 105 yen). As shown, the member fraction ball lending process performed when a ball lending operation is performed in a state where the card remaining amount of the member card 8 accepted in the card unit 200 is a fractional amount less than one time (ie, 105 yen). And are included.

  In the remaining amount management DB, each member player and each member card 8 is associated with a member ID that can be individually identified, and the remaining amount of the card that has been deposited with respect to the member card 8 on which the member ID is recorded is stored and managed. Has been. The management content of this balance management DB is that each time deposit information is transmitted from the card unit 200 in the deposit process shown in FIG. 22 described later, the identification amount included in the deposit information is added to the stored card balance. Each time the used amount of ball lending is transmitted from the card unit 200 in the member-unit ball lending process shown in FIG. 23 or the member fraction ball lending process shown in FIG. The rental amount is subtracted and updated from the stored card balance.

  Next, the center server 20 will be described with reference to FIGS. The center server 20 is an example of a management device. Here, the center server 20 is the center management device provided in the card company 3, and is connected to the communication unit 21, the control unit 22, the display 23, and the input device 24 as shown in FIG. , And a hard disk 25 or the like.

  The communication unit 21 is communicably connected to the gaming machine manufacturer 4 and manages communication between the center server 20 and the gaming machine manufacturer 4. Here, as described above, the delivery chip ID shown in FIG. A list is received from the gaming machine manufacturer 4 and acquired. The communication unit 21 is communicably connected to the out-of-field communication unit 11a of the system controller 10 and manages communication between the center server 20 and the system controller 10. Details of the function will be described later. . The control unit 22 includes a CPU, a RAM, a ROM, and the like. The processing program stored in the hard disk 25 is executed by the CPU using the RAM as a work area, thereby controlling the operation of each component provided in the center server 20. Various types of processing are performed. Details of the function will be described later.

  The display 23 displays various information, and the input device 24 receives various inputs (for example, a keyboard and a mouse). As shown in FIG. 5, the display 23 displays a screen corresponding to each mode executed in the center server 20 by an operation of an employee of the card company 3.

  Specifically, when the pre-business start chip ID acquisition setting mode is executed in the center server 20 by an operation of an employee of the card company 3 before the game hall 2 starts business, the business shown in FIG. A pre-start chip ID acquisition setting screen is displayed on the display 23. In the pre-starting chip ID acquisition setting screen, a pull-down menu for setting a chip ID request time for requesting the acquisition of a chip ID to each game hall 2 is displayed, and the opening time today at each game hall 2 A time input field for setting is displayed for each game hall. Here, in the pull-down menu, as the chip ID request time, 1 hour before, 30 minutes before, 15 minutes before, etc. of today's opening time is displayed. In the time input field, the normal store opening time for each game hall stored in advance in the center server 20 is displayed.

  In this pre-starting chip ID acquisition setting screen, when an employee of the card company 3 operates the input device 24, any one of 1 hour before, 30 minutes before, 15 minutes before, etc. displayed in the pull-down menu is displayed. Select the chip ID request time (here 1 hour ago) and change the normal opening time for each game hall displayed in the time input field as necessary (here, the game hall C where the event is held, When the “setting” button is operated after changing the normal opening time of 10:00 to 12:00, which is the opening time of the day, based on the set contents as shown in the table of FIG. Thus, the chip ID request time is set for each game hall. When the chip ID request time set for each game hall is reached, a chip ID acquisition request is transmitted to the system controller 10 provided in each game hall 2, and the system controller 10 receives the chip ID before business start. Acquisition processing is performed.

  In this pre-business chip ID acquisition process, the system controller 10 acquires a chip ID for the card unit 200 corresponding to the pachinko machine 100 having the identification information transmission function among the pachinko machines 100 installed in the game hall 2. When the request is transmitted and the machine number and chip ID of the pachinko machine 100 transmitted from the card unit 200 in response to the chip ID acquisition request are received, as shown in the table of FIG. An installed chip ID list in which the received machine number and chip ID are recorded in association with each other is created. The created installation chip ID list is transmitted from the system controller 10 to the center server 20, and is collated with a collation chip ID list shown in FIG.

  Further, when the consumption tax rate setting mode is executed in the center server 20 by the operation of the employee of the card company 3, the consumption tax rate setting screen shown in FIG. In this consumption tax rate setting screen, when an employee of the card company 3 operates the input device 24 to input the consumption tax rate (here, 5%) in the input field and operate the “setting” button, the input is made. Consumption tax rate is set by contents.

  The set consumption tax rate (set tax rate) is transmitted to and stored in the system controller 10, and further transmitted to and stored in the card unit 200 in response to a request from the card unit 200. The card unit 200 stores an amount equivalent to a preset number of times (here, 100 yen) and a preset amount of a single pachinko ball (4 yen here). Based on the set tax rate, the amount equivalent to the number of times including consumption tax (here, 105 yen) and the ball lending amount of one pachinko ball including consumption tax (here, 4.2 yen) are calculated and stored. To do. The calculated value stored here is used to calculate the remaining frequency and fractional amount, which will be described later, and to specify the number of ball loans, which will be described later.

  The hard disk 25 which is a storage device is an example of identification information storage means, which stores the chip ID of each pachinko machine 100 delivered to the game hall 2, and is an example of transmission permission / inhibition storage means. Whether each pachinko machine 100 installed in the game hall 2 has a function of transmitting a chip ID (hereinafter referred to as “identification information transmission function”) is stored. Here, for the verification shown in FIG. A chip ID list is stored. In this verification chip ID list, each pachinko machine is associated with the machine number of each pachinko machine 100 installed in the game hall, and the pachinko machine 100 having the identification information transmission function is associated with the pachinko machine 100. A regular chip ID is stored, and for the pachinko machine 100 that does not have the identification information transmission function, an X mark (that is, the pachinko machine 100 does not have an identification information transmission function) is stored.

  The verification chip ID list includes the delivery chip ID list shown in FIG. 2 transmitted from the gaming machine manufacturer 4 and the installation shown in the table of FIG. 3A transmitted from the system controller 10 of each game hall 2. Based on the chip ID list, it is updated under the control of the control unit 22. Specifically, the control unit 22 has a chip ID recorded in the installed chip ID list shown in the table of FIG. 3A (that is, a chip ID acquired from the pachinko machine 100 delivered to the game hall 2), and The chip IDs recorded in the delivery chip ID list shown in FIG. 2 (that is, regular chip IDs that should be stored in the pachinko machine 100 delivered to the game hall 2) all match or overlap. Check for any.

  If the verification is OK, the contents of the installed chip ID list shown in the table of FIG. 3A are overwritten and updated with the contents of the verification chip ID list shown in FIG. On the other hand, in the case of the verification NG, the mismatched chip ID or the overlapping chip ID is reported to the game hall 2 and the gaming machine manufacturer 4. In addition, when the installed chip ID list in which the x mark (that is, the pachinko machine 100 does not have the identification information transmission function) is transmitted from the system controller 10 of each game hall 2 in association with the machine number. Does not perform the collation, and updates the contents of the transmitted installed chip ID list overwriting the contents of the collating chip ID list shown in FIG.

  Here, the control unit 22 is an example of a collation unit, and is transmitted from a chip ID (here, the system controller 10 of each game hall 2) transmitted from an identification information transmission unit (card R / W control unit 230) described later. The installed chip ID lists shown in the tables of FIGS. 3B and 3C) are stored in the identification information storage means (hard disk 25) (here, the verification chip ID list shown in FIG. 6). Is matched. Specifically, the control unit 22 recognizes the chip IDs recorded in association with the machine numbers in the installed chip ID list shown in the tables of FIGS. The chip ID acquired from the machine 100) is stored in the pachinko machine 100 delivered to the game hall 2 (that is, the chip ID recorded in association with the machine number in the verification chip ID list shown in FIG. 6). It is checked for each chip ID whether or not it matches with the regular chip ID).

  The communication unit 21 is an example of a collation result transmission unit, and transmits the collation result by the collation unit (control unit 22) to the card unit 200 that is the transmission source of the chip ID. Specifically, the communication unit 21 verifies that the chip ID matches with the card unit 200 that is the transmission source of each chip ID via the system controller 10 according to the verification result by the control unit 22. A result (verification OK) or a verification result (verification NG) indicating that the chip IDs do not match is transmitted. In the case of verification NG, the mismatched chip ID is reported to the gaming machine manufacturer 4.

  Further, the communication unit 21 is an example of identification information transmission impossibility information transmission means, and based on the stored contents of the transmission availability storage means (hard disk 25) (here, the verification chip ID list shown in FIG. 6), the identification information Identification information transmission impossible information indicating that the corresponding pachinko machine 100 does not have an identification information transmission function is transmitted to the card unit 200 corresponding to the pachinko machine 100 not having a transmission function. Specifically, the communication unit 21 responds to the card unit 200 corresponding to the pachinko machine 100 having the serial number in which a cross is recorded in the verification chip ID list shown in FIG. The identification information transmission impossibility information is transmitted via the system controller 10.

  Next, the pachinko machine 100 will be described with reference to FIG. 7, FIG. 8, and FIG. The pachinko machine 100 is an example of the gaming machine, and is placed at a predetermined position on the gaming island (not shown) in the game hall 2 according to the model and the like, and a game is played by driving a pachinko ball as a gaming medium into the gaming area 110. Here, it can communicate with the corresponding card unit 200, and exchanges signals regarding the lending of pachinko balls with the card unit 200 to perform ball lending processing (visitor ball lending processing, member-unit ball lending processing) , And a fractional member lending process), a so-called CR-type pachinko machine. This pachinko machine 100 has an identification information transmission function and a fraction lending processing function (hereinafter referred to as “new game machine”).

  As shown in FIG. 7A, the pachinko machine 100 includes a game area 110, a launch handle 130, an upper plate 120, a lower plate 140, and the like on the front surface thereof, a remaining frequency indicator 121, and a ball rental button 122. , A ball lending lamp 123 and a return button 124, and as shown in FIG. 9, a main board 150, a prize opening switch 153, a payout control board 160, a ball payout device 170, a ball check sensor 171, and a launch A control board 180 and the like are provided, and a relay board 190 is provided behind the control board 180, and these components are connected as shown in FIG.

  The game area 110 is provided with a plurality of winning openings such as a start winning opening, a large winning opening, a general winning opening, and a variable display device capable of variably displaying symbols as a plurality of types of identification information. The launch handle 130 receives an operation for driving a pachinko ball into the game area 110. When the launch handle 130 is turned to the right, the pachinko ball is launched and driven into the game area 110. The upper plate 120 stores pachinko balls paid out as balls or prize balls from the ball dispensing device 170, and the lower plate 140 stores excess pachinko balls that cannot be stored in the upper plate 120. .

  The remaining frequency indicator 121 is an example of a valuable value indicator. As shown in FIG. 8A, the remaining frequency indicator 121 includes a plurality (three in this case) of segment indicators 121 a to 121 c and is recorded on the encapsulated card 7. The value of the valuable value that can be used for the game specified from the remaining deposit amount or the value of the valuable value that can be used for the game specified from the card remaining amount recorded on the member card 8 is displayed.

  Here, each segment indicator (the first digit segment indicator 121a, the second digit segment indicator 121b, and the third digit segment indicator 121c) is constituted by a seven segment LED composed of seven segments A to G. A number or a letter is displayed by turning on a predetermined LED of the seven segments. As shown in FIG. 11, which will be described later, the remaining frequency indicator 121 is subjected to dynamic lighting control by dynamic lighting control means (LED drive circuit 212).

  The value of the valuable value displayed on the remaining frequency indicator 121 is a remaining frequency or a fractional amount. This remaining number is the integer part of the quotient calculated by the unit control unit 220, which will be described later, with the formula of “payment balance or remaining card amount / one frequency including consumption tax (ie, 105 yen)”. This is the remainder of the quotient calculated by the expression. More specifically, when the remaining deposit amount or the remaining card amount is 1000 yen, 1000 yen / 105 yen = the remaining frequency is calculated as 9 degrees and the fractional amount is calculated as 55 yen.

  Here, when the remaining frequency is displayed on the remaining frequency display 121, the calculation is performed on the third-digit segment display 121c to the first-digit segment display 121a as shown in FIG. 8B. The remaining frequency (here, 9) is displayed. Further, when the fractional amount is displayed on the remaining frequency indicator 121, the letter “H” is displayed on the third digit segment indicator 121c and the second digit is displayed as shown in FIG. The calculated fractional amount (55 yen in this case) is displayed on the segment indicator 121b to the first digit segment indicator 121a. When the fractional amount exceeds 100 yen, “H99” is displayed uniformly.

  Returning to FIG. 7, the ball lending button 122 is a button for accepting a ball lending operation using the remaining amount of the card. The operation of the ball lending button 122 is detected by a detection circuit 213 as shown in FIG. When the ball lending button 122 is operated and there is a ball lending operation, a member-unit ball lending process or a member fraction ball lending process described later is performed. The visitor ball lending process described later is performed without relying on a ball lending operation.

  The ball lending lamp 123 is lit when the ball lending operation by the ball lending button 122 is possible (that is, when the member card 8 is accepted in the card unit 200 and there is a remaining card amount of the member card 8). The lamp for notifying that the ball lending operation is possible. The ball lending lamp 123 is constituted by an LED, and is controlled to be lit by an LED drive circuit 212 as shown in FIG.

  The return button 124 is a button for accepting a return operation for the member card 8 accepted in the card unit 200. The operation of the return button 124 is detected by a detection circuit 213 as shown in FIG. When the return button 124 is operated and a return operation is performed, the member card 8 inserted in the member card R / W 290 described later is discharged from the member card insertion slot 291 and returned to the member player.

  The main board 150 is an example of the arithmetic processing unit for gaming, and executes control related to gaming of the pachinko machine 100. As shown in FIG. 9, the main board 150 includes a basic circuit 151, an input driver circuit 152, and the like. ing. The basic circuit 151 includes a CPU 151a, a ROM 151b, a RAM 151c, an I / O 151d, and the like. The processing program recorded in the ROM 151b is connected to the main board 150 by being executed by the CPU 151a using the RAM 151c as a work area. Various operations are performed by controlling the operation of each component. That is, the basic circuit 151 is a one-chip microcomputer in which the CPU 151a, ROM 151b, RAM 151c, and I / O 151d are integrated and mounted on one chip. The basic circuit 151 is connected to an input circuit 162 and an output circuit 163, which will be described later, of the payout control board 160 through an I / O 151d. Here, the ROM 151b is an example of the gaming machine side identification information storage means, and stores the chip ID of the basic circuit 151 (main board 150) as described above.

  The I / O 151d is an example of a gaming machine side identification information transmitting means, and transmits the chip ID stored in the ROM 151b to the corresponding card unit 200 via a display data signal line to be described later. In this case, the chip ID is transmitted to the corresponding card unit 200 via the payout control board 160 and the display data signal line. Details thereof will be described later with reference to FIG. .

  Further, the I / O 151d is an example of a gaming operation signal receiving means, and whether or not the chip ID transmitted by the gaming machine side identification information transmitting means matches the chip ID of the pachinko machine 100 delivered to each game hall 2 The game operation signal transmitted from the corresponding card unit 200 is received via a display data signal line, which will be described later, based on the collation result (that is, the collation result by the collating means). The process waits for the reception of the immobilization signal transmitted based on the collation result (collation NG) indicating that they do not match, details of which will be described later with reference to FIG.

  The basic circuit 151 of the main board 150 receives the activation signal transmitted based on the matching result indicating that the chip IDs match as the gaming operation signal by the gaming operation signal receiving means. The control relating to the game of the machine 100 is activated, or the disabled operation signal transmitted based on the verification result that the chip IDs do not match is received as the game operation signal by the game operation signal receiving means. As described above, the control related to the game of the pachinko machine 100 is disabled. Here, on the condition that the disable signal is received, the I / O 154d is connected to the launch control board 160 via the payout control board 160. On the other hand, a process of transmitting a firing impossible signal is performed. The launch control board 180 that has received this launch disable signal disables control related to the game of the pachinko machine 100 by performing control such that the pachinko ball is not launched even when the launch handle 130 is operated.

  The input driver circuit 152 is a circuit for detecting a winning detection signal output from the winning opening switch 153. The winning opening switch 153 is provided corresponding to each winning opening provided in the game area 110 (start winning opening, large winning opening, general winning opening, etc.), and detects the winning of a pachinko ball to the winning opening. It is. That is, when a pachinko ball that has been driven into the game area 110 wins each winning opening, the winning opening is detected by the winning opening switch 153, and a winning detection signal indicating that the winning has been detected is output to the input driver circuit 152. When the winning detection signal is detected by the input driver circuit 152, a winning ball payout signal for instructing the payout of the number of winning balls corresponding to each winning opening is output from the basic circuit 151 to the payout control board 160, and The number of pachinko balls indicated by the ball payout signal is paid out from a ball payout device 170 described later as a prize ball.

  The payout control board 160 controls the payout of pachinko balls in the pachinko machine 100, and includes a payout control CPU 161, an input circuit 162, an output circuit 163, an I / O 164, and the like as shown in FIG. These are connected by a bus. The payout control board 160 is connected to the I / O 154d of the main board 150 by the input circuit 162 and the output circuit 163 as described above.

  The payout control board 160 is an example of a relay device and can communicate with the corresponding card unit 200. Specifically, as shown in FIG. 10, a display data signal line to be described later is provided by an I / O 164. And is connected to an I / O 224 provided in a unit control unit 220 (to be described later) of the card unit 200. The payout control board 160 functioning as the relay device uses the chip ID (that is, the chip ID acquired from the main board 150) transmitted from the gaming machine side identification information transmitting means (I / O 154d) as the corresponding card unit 200. Remember to send to.

  The payout control board 160 functioning as a relay device erases the chip ID stored in the payout control board 160 for the transmission on condition that a predetermined time has elapsed after obtaining the chip ID from the main board 150. To do. Specifically, as shown in FIGS. 25 and 27, which will be described later, when a chip ID is acquired from the main board 150, a timer T for measuring the predetermined time is set, and the chip is counted before the timer T times out. When the ID cannot be transmitted to the card unit 200, the stored chip ID is erased.

  Also, the payout control board 160 functioning as a relay device transmits the chip ID stored in the payout control board 160 for the transmission on condition that the chip ID acquired from the main board 150 is sent to the corresponding card unit 200. It is to be erased. Specifically, as shown in FIGS. 25 and 27 to be described later, when the disable signal is received from the card unit 200, the stored chip ID is erased.

  The payout control CPU 161 outputs a signal for instructing payout of pachinko balls for one number to the ball payout device 170 when the unit ball lending process shown in FIG. 16 described later is performed, and the fraction shown in FIG. 17 described later. When a ball lending process is performed, a signal for instructing the payout of pachinko balls corresponding to the number of ball lending described later is output to the ball paying device 170, and a prize ball paying signal is input from the main board 150 to the input circuit 162 In addition, a signal for instructing the payout of the number of pachinko balls indicated by the prize ball payout signal is output to the ball payout device 170.

  The payout control board 160 has a unit lending request signal receiving means, a unit lending preparation signal transmitting means, a unit lending command signal receiving means, a lending number designation signal receiving means, and a fraction when ball lending control shown in FIG. It functions as a lending request signal receiving means, a fraction lending preparation signal transmitting means, a fraction lending command signal receiving means, and a lending control means. Details of these functions will be described later.

  The ball payout device 170 pays out a ball that is a pachinko ball lent to a player after a ball lending process and a prize ball that is a pachinko ball given to the player as a result of the game. The ball dispensing device 170 includes a dispensing motor (not shown), and uses the driving force of the dispensing motor to supply pachinko balls supplied from a ball tank (not shown) via a tank rail (not shown). It is something to be paid out. Here, a ball check sensor 171 is provided in the supply path of the pachinko balls from the tank rail to the ball dispensing device 170, and it can be confirmed whether there is a pachinko ball supplied to the ball dispensing device 170. It is configured as follows. The ball payout device 170 and the ball check sensor 171 are connected to the I / O 164 of the payout control board 160.

  The relay board 190 is a signal line that allows the pachinko machine 100 and the card unit 200 to be connected, a ball lending display signal line, a ball lending operation signal line, a return operation signal line, a strobe signal line, a display data signal line, a PSI. It is a substrate for relaying various signals transmitted and received between the pachinko machine 100 and the card unit 200, interposed between the signal line, the PRDY signal line, the BRDY signal line, the BRQ signal line, and the EXS signal line. . Details of these signal lines will be described later.

  Next, the card unit 200 will be described with reference to FIGS. The card unit 200 is an example of the gaming device, and is provided corresponding to the pachinko machine 100 (here, adjacent to the left side of the pachinko machine 100), and has a vertically long box shape. As shown in FIG. 7 (a), a multi-function lamp 270, a bill insertion slot 241, a coin insertion slot 251, a coin return button 254, a coin return slot 256, an encapsulated card confirmation window 281, a membership card insertion slot 291 and the like are provided on the front surface. 7 (b) and 7 (c), a lamp driving circuit 211, a bill discriminator 240, an LED driving circuit 212, a detection circuit 213, a unit controller 220, and a coin discriminator 250 are provided therein. Card R / W controller 230, encapsulated card R / W 280, member card R / W 290, etc., and these components are connected as shown in FIG. .

  The lamp driving circuit 211 is a circuit for controlling the light emission of the multi-function lamp 270, and based on the input of a light emission control command from the unit control unit 220, a signal for instructing a light emission mode according to the command. Is output to the multi-function lamp 270, so that the multi-function lamp 270 is controlled to emit light. The multi-function lamp 270 is a lamp for informing the operation state of the card unit 200. Here, the multi-function lamp 270 notifies that the membership card 8 is not being accepted by lighting in green, and accepts the membership card 8 by lighting in blue. Announce that it is in.

  The LED driving circuit 212 is a circuit for controlling lighting of the ball lending lamp 123. Based on the input of a lighting control command from the unit controller 220, the LED driving circuit 212 sends a signal for instructing a lighting mode according to the command to the LED driving circuit 212 and the ball lending lamp 123. The ball lending lamp 123 is controlled to be turned on by outputting the ball lending display signal line which is a signal line connecting the two. The LED drive circuit 212 functions as dynamic lighting control means for controlling dynamic lighting of the remaining frequency indicator 121 as shown in FIG. 11 described later. Details of the function will be described later.

  The detection circuit 213 is a circuit for detecting an operation of the ball lending button 122 and the return button 124. This detection circuit 213 has a ball lending operation signal line that is a signal line connecting the ball lending button 122 and the detection circuit 213 when a ball lending operation signal is output when the ball lending button 122 is operated. Is output to the unit controller 220 based on the fact that the ball lending operation has been performed. The detection circuit 213 inputs a return operation signal output when the return button 124 is operated via a return operation signal line which is a signal line connecting the return button 124 and the detection circuit 213. Based on this, a signal indicating that there has been a return operation is output to the unit controller 220.

  The unit control unit 220 includes a CPU 221, a ROM 222, a RAM 223, an I / O 224, and the like. When the processing program recorded in the ROM 222 is executed by the CPU 221 using the RAM 223 as a work area, the unit control unit 220 Various processes (each process shown in FIGS. 18 to 24 described later) are performed by controlling the operation of each connected component.

  This unit control unit 220 is an example of identification information acquisition means, and the chip ID stored in the main board 150 mounted on the corresponding pachinko machine 100 is sent to the corresponding pachinko machine via a display data signal line to be described later. The process of acquiring from 100 (chip ID acquisition process) is performed, and details thereof will be described later with reference to FIG.

  Further, the unit control unit 220 is an example of a game operation signal transmission unit, and the corresponding pachinko machine is provided on the condition that the matching result (verification OK) is received from the verification result transmission unit (communication unit 21). An activation signal for activating the operation of 100 is transmitted to the corresponding pachinko machine 100 via a display data signal line to be described later, or the verification result transmission means (communication unit 21) does not agree On the condition that the verification result (verification NG) is received, an immobilization signal for disabling the operation of the corresponding pachinko machine 100 is sent to the corresponding pachinko machine 100 via a display data signal line to be described later. In this case, a process of transmitting an immobilization signal (disabling signal transmission process) is performed in the case of collation NG. Figure 15 will be described below with reference to (b).

  The unit control unit 220 functioning as the game operation signal transmission unit receives the identification information acquisition unit (unit control) on condition that the identification information transmission impossibility information is received from the identification information transmission impossibility information transmission unit (communication unit 21). Unit 220) and the identification information transmission means (card R / W control unit 230) to be described later, without transmitting the activation signal, or without transmitting the disable signal, Here, when the identification information transmission impossible information is received, the disable signal is not transmitted.

  The unit control unit 220 is an example of a lending processing means, and uses the magnitude of valuable value (payment balance, remaining card amount) specified from the record information of the game recording medium (encapsulated card 7, membership card 8). Thus, a lending process for lending a pachinko ball from the pachinko machine 100 is performed. The unit control unit 220 functioning as the lending processing unit disables the lending process on the condition that the collation result (verification NG) indicating that there is no match is received from the collation result transmitting unit (communication unit 21). . The unit control unit 220 functioning as a lending processing unit receives the identification information acquisition unit (unit control unit 220) on condition that the identification information transmission impossibility information transmission unit (communication unit 21) has received the identification information transmission impossibility information. ) And the processing by the identification information transmitting means (card R / W control unit 230) to be described later, the lending process is activated.

  Further, the unit control unit 220 is an example of a game medium number specifying means, and the number of ball lending that is the number of pachinko balls corresponding to a fractional amount of less than one of the remaining card amounts specified from the recorded information of the member card 8 Is specified. The number of balls loaned is specified by rounding up the number of pachinko balls less than one of the quotient calculated by the formula of “fractional amount ÷ pain amount of one pachinko ball including consumption tax” (ie 4.2 yen). (In other words, for fractional amounts less than 4.2 yen, the pachinko ball is lent out at the expense of the game hall 2). Specifically, when the fractional amount is 70 yen, the number of ball lending is specified as 17 because 70 yen / 4.2 yen = 16.6.

  The unit control unit 220 is an example of a lending number designation signal transmitting unit, and when the lending of the number of pachinko balls specified by the game medium number specifying unit is instructed to the pachinko machine 100, display data to be described later A lending number designation signal (hereinafter referred to as a “ball lending number designation signal”) indicating the number of balls lending specified by the game medium number specifying means is transmitted via a signal line. Will be described later with reference to FIG.

  It should be noted that the unit control unit 220 provides a loan command means when a unit ball lending process (see FIG. 16) is performed in a visitor ball lending process shown in FIG. 21 described later and a member unit ball lending process shown in FIG. It functions as a unit lending request signal transmitting means, a unit lending preparation signal receiving means, and a unit lending command signal transmitting means, and in the visitor ball lending process shown in FIG. When the lending process (see FIG. 17) is performed, these functions function as lending command means, fraction lending request signal transmitting means, fraction lending preparation signal receiving means, and fraction lending command signal transmitting means. Details of this will be described later.

  The card R / W control unit 230 includes a CPU, a RAM, a ROM, and the like, and the card R / W control unit 230 is executed by a CPU executing a processing program stored in the ROM using the RAM as a work area. Various operations are performed by controlling the operations of the enclosing card R / W 280 and the membership card R / W 290 connected to the. As described above, the card R / W control unit 230 is communicably connected to the out-of-field communication unit 11a of the system controller 10.

  The card R / W control unit 230 is an example of an identification information transmitting unit, and transmits the chip ID acquired by the identification information acquiring unit (unit control unit 220) to the center server 20 via the system controller 10. To do.

  Then, the card R / W control unit 230 functioning as the identification information transmitting means stores the card R / W control unit 230 in the card unit 200 for the transmission on condition that a predetermined time has elapsed since the acquisition of the chip ID by the identification information acquiring means. The chip ID is erased. Specifically, as shown in FIGS. 18 and 20, which will be described later, when a chip ID is acquired by the unit controller 220, a timer T for measuring the predetermined time is set, and until the timer T times out, When the verification result (verification OK or verification NG) cannot be received from the system controller 10 and when the chip ID cannot be transmitted to the system controller 10 before the timer T times out, the stored chip ID is deleted. .

  Further, the card R / W control unit 230 functioning as the identification information transmitting unit transmits the chip ID acquired by the identification information acquiring unit to the center server 20 via the system controller 10 on the condition. Therefore, the chip ID stored in the card unit 200 is erased. Specifically, as shown in FIGS. 18 and 20 to be described later, when the verification result (verification OK or verification NG) is received from the system controller 10 before the timer T times out, the stored chip ID is stored. Erase.

  Further, when the member card 8 is received by the member card R / W 290, the card R / W control unit 230 transmits a verification request including the member ID read from the member card 8 and the remaining amount of the card to the system controller 10. When the deposit processing shown in FIG. 22 described later is performed in the card unit 200, the deposit information including the member ID of the member card 8 and the identification amount is transmitted to the system controller 10. Further, when a ball lending process (visitor ball lending process, member unit ball lending process, or member fraction lending process) is performed in the card unit 200, the amount of ball lending used for the ball lending process is set as a system controller. 10 is transmitted.

  The encapsulated card R / W 280 accepts money in a state where the membership card 8 is not accepted in the card unit 200, and when the amount of the accepted money is identified by the bill discriminator 240 or the coin discriminator 250 described later, The identification amount is recorded (written) on the encapsulated card 7 encapsulated in the encapsulated card R / W 280 as a deposit balance. In addition, the enclosing card R / W 280 sequentially applies the amount after subtracting the amount of money for one time from the remaining amount of payment of the enclosing card 7 to the enclosing card 7 when the visitor ball lending process shown in FIG. Are recorded (written), and finally the processing of setting the balance of the encapsulated card 7 to 0 is performed. The enclosing card R / W 280 includes an IC card R / W corresponding to the enclosing card 7 which is the IC card. Note that the encapsulated card 7 encapsulated in the encapsulated card R / W 280 is visible to the player through the enclosed card confirmation window 281 and cannot be touched.

  As shown in FIG. 7C, the member card R / W 290 accepts the insertion of the member card 8 from the member card insertion slot 291 and reads the member ID and the remaining card amount from the accepted member card 8. The verification request including the member ID read here and the remaining card amount is transmitted from the card unit 200 to the system controller 10 as described above, and the transmitted card remaining amount and the transmitted card balance are transmitted in the system controller 10. The remaining card ID stored in the remaining amount management DB shown in FIG.

  Further, the membership card R / W 290 is provided with an amount obtained by adding the identification amount identified by the banknote discriminator 240 or the coin discriminator 250 to the remaining amount of the membership card 8 when the deposit processing shown in FIG. This is recorded (written) on the member card 8 as a new card balance. Further, the member card R / W 290 is a ball lending use amount used for the member unit ball lending processing from the remaining amount of the member card 8 when the member unit ball lending processing shown in FIG. The amount after subtracting the amount of money is recorded (written) on the member card 8 as a new card balance. Furthermore, the membership card R / W 290 performs processing for setting the remaining amount of the membership card 8 to 0 when the membership fraction lending processing shown in FIG. The membership card R / W 290 includes an IC card R / W corresponding to the membership card 8 which is the IC card.

  The bill validator 240 is an example of money accepting means and accepts money. Here, as shown in FIG. 7 (b), the bill insertion machine 241 accepts a 1000 yen bill from the bill insertion slot 241 in a state where the membership card 8 is not accepted. Or the four kinds of banknotes 5 are received from the banknote insertion slot 241 in a state in which the member card 8 with a remaining card amount of zero or a fractional amount is received, and identifies the received banknotes 5. The bill 5 received by the bill validator 240 is discharged from the back of the card unit 200 to the outside through the bill passage 242 and is transported by a bill transport mechanism (not shown) provided on the amusement island. ).

  The coin discriminator 250 is also an example of money accepting means, and accepts money. Here, as shown in FIG. 7B, the member card 8 is not accepted, or the remaining card amount is zero or a fractional amount. This is a discriminator that accepts a 500 yen coin from the coin insertion slot 251 while accepting the membership card 8 and identifies the coin 6 conveyed through the coin passage 252. The coin 6 received by the coin discriminator 250 is also discharged to the outside from the back of the card unit 200 through the coin passage 253 and is transported by a coin transport mechanism (not shown) provided on the amusement island. ). The coin return button 254 is a button for accepting a return operation of the coin 6 jammed in the coin passage 252 or the coin discriminator 250, and when the coin return button 254 is operated by the player, the jammed coin 6 is Return to the coin return 256 through the passage 255.

  Next, with reference to FIG. 9 and FIG. 10, signal lines for connecting the pachinko machine 100 and the card unit 200 will be described. Since the ball lending display signal line, the ball lending operation signal line, and the return operation signal line have been described above, description thereof will be omitted.

  The strobe signal line is a signal line for transmitting a strobe signal for dynamic lighting control of the remaining frequency indicator 121 from the card unit 200 to the pachinko machine 100 (in other words, for inputting in the pachinko machine 100). is there. This strobe signal line is connected to the LED drive circuit 212 on the card unit 200 side and the DG1 signal line connected to the segment display 121a on the pachinko machine 100 side, as shown in FIGS. This is a total of three signal lines: a DG2 signal line connected to the segment display 121b and a DG3 signal line connected to the segment display 121c.

  The display data signal line is a signal for transmitting a display data signal for dynamic lighting control of the remaining frequency indicator 121 from the card unit 200 to the pachinko machine 100 (in other words, for inputting in the pachinko machine 100). Is a line. This display data signal line is connected to the LED drive circuit 212 on the card unit 200 side and to the segment A of each segment display 121a to 121c on the pachinko machine 100 side, as shown in FIGS. SEGA signal line connected, SEGB signal line connected to the same segment B, SEGC signal line connected to the same segment C, SEGD signal line connected to the same segment D, SEGE signal line connected to the same segment E , SEGF signal lines connected to the same segment F and SEGG signal lines connected to the same segment G, a total of seven signal lines.

  Of the display data signal lines, the SEGG signal line is subjected to chip ID acquisition processing in the card unit 200 (in other words, chip ID transmission processing in the pachinko machine 100) as shown in FIG. In addition, the card unit 200 functions as a chip ID transmission request signal line that is a signal line for requesting the pachinko machine 100 to transmit the chip ID, and the chip ID is transmitted from the pachinko machine 100 to the card unit 200. It functions as a chip ID signal line that is a signal line for this purpose.

  Further, among the display data signal lines, the SEGG signal line is an immobilization signal transmission process in the card unit 200 (in other words, an immobilization signal reception process in the pachinko machine 100) as shown in FIG. Is performed, it functions as an immobilization signal line that is a signal line for transmitting the immobilization signal from the card unit 200 to the pachinko machine 100.

  Further, the display data signal line is a lending number designation signal line and a fraction lending in a T4 ′ period shown in FIG. 11, which will be described later, which is a strobe signal non-transmission period (in other words, a strobe signal non-input period in the pachinko machine 100). It functions as a request signal line, a fraction lending preparation signal line, and a fraction lending command signal line. Specifically, as shown in FIG. 17 to be described later, the SEGA signal line to SEGD signal line transmits the ball lending number designation signal from the card unit 200 to the pachinko machine 100 in the T4 ′ period which is a non-transmission period of the strobe signal. Function as a lending number designation signal line which is a signal line for transmitting (in other words, receiving at the pachinko machine 100).

  Further, the SEGE signal line sends a fraction lending request signal (hereinafter referred to as “fraction ball lending request signal”) requesting lending of the number of pachinko balls indicated by the ball lending number designation signal from the card unit 200 to the pachinko machine 100. It functions as a fraction lending request signal line that is a signal line for transmission (in other words, for reception by the pachinko machine 100). Further, the SEGE signal line sends a fraction lending command signal (hereinafter referred to as a “fraction ball lending command signal”) for lending the number of pachinko balls indicated by the ball lending number designation signal from the card unit 200 to the pachinko machine 100. It functions as a fraction lending command signal line that is a signal line for transmitting (in other words, receiving at the pachinko machine 100).

  Further, the SEGF signal line sends a fraction lending preparation signal (hereinafter referred to as a “fraction ball lending preparation signal”) from the pachinko machine 100 to indicate that the number of pachinko balls indicated by the ball lending number designation signal is ready to be lent. It functions as a fraction lending preparation signal line which is a signal line for transmitting to the unit 200 (in other words, for receiving in the card unit 200). The SEGF signal line transmits a fraction lending completion signal (hereinafter referred to as “fraction ball lending completion signal”) indicating that the number of pachinko balls lending indicated by the ball lending number designation signal has been completed from the pachinko machine 100 to the card unit. It also functions as a fraction lending completion signal line which is a signal line for transmitting to 200 (in other words, for receiving in the card unit 200).

  The PSI signal line is a signal line for confirming the connection between the card unit 200 and the pachinko machine 100. The PSI signal line is a signal line connected to the I / O 224 of the unit control unit 220 on the card unit 200 side and connected to the I / O 164 of the payout control board 160 on the pachinko machine 100 side. By transmitting a connection confirmation signal via this PSI signal line, the launch handle 130 can be operated in the pachinko machine 100.

  The PRDY signal line is a signal line for transmitting a payable signal indicating that communication between the pachinko machine 100 and the card unit 200 is possible (standby state) from the pachinko machine 100 to the card unit 200. It is. This PRDY signal line is a signal line connected to the I / O 164 of the payout control board 160 on the pachinko machine 100 side and to the I / O 224 of the unit control unit 220 on the card unit 200 side.

  The BRDY signal line is used for transmitting a ball lending possible signal from the card unit 200 to the pachinko machine 100 when there is a ball lending operation in a standby state where the card unit 200 receives the payable signal. It is a signal line. The BRDY signal line is a signal line for transmitting a ball lending end signal from the card unit 200 to the pachinko machine 100 when a ball lending process for a set frequency described later is completed. The BRDY signal line is a signal line connected to the I / O 224 of the unit control unit 220 on the card unit 200 side and to the I / O 164 of the payout control board 160 on the pachinko machine 100 side.

  A BRQ signal line is an example of a unit lending request signal line, and a unit lending request signal (hereinafter referred to as “unit ball lending”) that requests lending of a number of pachinko balls corresponding to the value of the unit valuable value (that is, several times). Request signal ”) is a signal line for transmitting the card unit 200 to the pachinko machine 100 (in other words, for receiving at the pachinko machine 100). The BRQ signal line is an example of a unit lending command signal line, and a unit lending command signal (hereinafter referred to as a “unit ball lending command signal”) that commands lending of the pachinko balls for the number of times is sent from the card unit 200 to the pachinko. A signal line for transmitting to the machine 100 (in other words, for receiving at the pachinko machine 100). This BRQ signal line is a signal line connected to the I / O 224 of the unit control unit 220 on the card unit 200 side and to the I / O 164 of the payout control board 160 on the pachinko machine 100 side.

  The EXS signal line is an example of a unit lending preparation signal line, and a unit lending preparation signal (hereinafter referred to as “unit ball lending preparation signal”) indicating that preparation for lending of the pachinko balls for the number of times is completed. Is a signal line for transmitting the signal from the pachinko machine 100 to the card unit 200 (in other words, for receiving at the card unit 200). The EXS signal line is an example of a unit lending completion signal line, and a unit lending completion signal (hereinafter referred to as “unit ball lending completion signal”) indicating that the lending of the pachinko balls for the number of times has been completed is a pachinko machine. 100 is a signal line for transmitting from 100 to the card unit 200 (in other words, for receiving at the card unit 200). This EXS signal line is a signal line connected to the I / O 164 of the payout control board 160 on the pachinko machine 100 side and to the I / O 224 of the unit control unit 220 on the card unit 200 side.

  Here, the LED driving circuit 212 is an example of dynamic lighting control means, and transmits a strobe signal for controlling dynamic lighting of the remaining frequency indicator 121 via the strobe signal line and also via the display data signal line. By transmitting a display data signal for dynamic lighting control of the remaining frequency indicator 121 and selectively controlling lighting of the plurality of segment indicators 121a to 121c by combining the transmitted strobe signal with the display data signal. The remaining frequency indicator 121 is controlled to be dynamically lit.

  With this dynamic lighting control, the after-image phenomenon of the human eye is caused by repeating the lighting of the first digit segment display 121a, the second digit segment display 121b, and the third digit segment display 121c at high speed. Using this control, each digit appears to be lit continuously.

  Specifically, in the remaining frequency indicator 121, as to which of the seven segments in each of the segment indicators 121a to 121c is lit, a voltage is applied to the segment corresponding electrode corresponding to each of the seven segments. It is controlled by applying (that is, a display data signal is transmitted via the SEGA signal line to the SEGG signal line which is a display data signal line), and which number of the segment display devices 121a to 121c is turned on. Control is performed by applying a voltage to the common electrodes corresponding to the segment indicators 121a to 121c of each digit (that is, transmitting a strobe signal via the DG1 signal line to the DG3 signal line which are strobe signal lines).

  Then, if the segment display of a certain digit is turned on for a short time (eg, 5.0 ms), the segment indicator of the next digit is turned on for a short time (eg, 5.0 ms) after a predetermined period (eg, 2.5 ms). By repeating the control at a high speed, one digit is lit at a certain moment, but there is an afterimage phenomenon in the human eye, and if you look at the light once, it will continue for about 100 ms. Therefore, if the above lighting control is repeated at a speed of several tens of ms, each digit appears to be lit continuously.

  This dynamic lighting control will be described with reference to FIG. Here, FIG. 11A is a timing chart in a normal time other than the operating chip ID acquisition process and the fraction lending process, and FIG. 11B is the timing in the operating chip ID acquisition process and the fraction lending process. It is a chart.

  The LED drive circuit 212 functioning as dynamic lighting control means transmits a strobe signal having a length T1 (for example, 5.0 ms) to the DG1 signal line among the strobe signal lines in the normal state shown in FIG. Next, after elapse of a predetermined period T2 (for example, 2.5 ms), a strobe signal having a T1 length (for example, 5.0 ms) is transmitted to the DG2 signal line among the strobe signal lines, and then for a predetermined period T2 (for example, 2.. 5 ms), a strobe signal having a T1 length (for example, 5.0 ms) is transmitted to the DG3 signal line among the strobe signal lines, and after a predetermined period T2 (for example, 2.5 ms), one cycle of T3 In addition to performing control to end the period, processing for transmitting the display data signal to the display data signal line is performed during the period of each length T1.

  Specifically, as shown in FIG. 8B, when displaying “9” frequency on the remaining frequency display 121, a strobe signal is applied to the DG1 signal line connected to the first digit segment display 121a. During transmission (ie, voltage application), display data signals are transmitted to the SEGA signal line, SEGB signal line, SEGC signal line, SEGD signal line, SEGF signal line, and SEGG signal line among the display data signal lines. By transmitting (that is, applying a voltage), 9 degrees are displayed on the remaining frequency display 121, and dynamic lighting control is performed so that 9 degrees is always displayed due to the afterimage phenomenon.

  Here, the LED drive circuit 212 functioning as a dynamic lighting control unit is configured to obtain a chip ID acquisition process while the identification information acquisition unit (unit control unit 220) is operating in the game hall 2 based on a command from the unit control unit 220. (See FIG. 15 (a2)), when the game operation signal transmission means performs the disablement signal transmission process during the operation of the game hall 2 (see FIG. 15 (b2)), and the number of loans When the designation signal transmitting means transmits the ball lending number designation signal (see FIG. 17), control is performed to extend the non-transmission period of the strobe signal. Here, as shown in FIG. Control is performed to extend the last T2 period (hereinafter referred to as “T4 period”) of the T3 period to the T4 ′ period. When the T4 'period is extended, the T3 period, which is necessarily one cycle, is also extended to become the T3' period.

  The unit control unit 220 is an example of a lending command unit, and instructs the pachinko machine 100 to lend a pachinko ball. The unit lending request signal transmitting unit, the unit lending preparation signal receiving unit, and the unit lending command It has signal transmission means, fraction lending request signal transmission means, fraction lending preparation signal reception means, and fraction lending command signal transmission means.

  Here, when the unit control unit 220 functioning as a unit lending request signal transmission unit instructs the pachinko machine 100 to lend a pachinko ball for several times, the unit ball lending request signal is sent to the BRQ signal line. Send through. The unit controller 220 functioning as a unit lending preparation signal receiving means receives the unit ball lending preparation signal transmitted from the pachinko machine 100 in response to the unit ball lending request signal via the EXS signal line. .

  The unit control unit 220 functioning as a unit lending command signal transmitting unit receives the unit lending preparation signal by the unit lending preparation signal receiving unit, and sends the unit ball lending command signal to the BRQ signal line. Send through. The unit control unit 220 also functions as a unit lending completion signal receiving unit, and receives the unit ball lending completion signal transmitted from the pachinko machine 100 in response to the unit ball lending command signal via the EXS signal line. To do.

  The unit control unit 220 functioning as a fraction lending request signal transmission means sends the fraction lending request signal to the SEG signal line functioning as the fraction lending request signal line in the T4 ′ period which is a non-transmission period of the strobe signal. Send through. The unit control unit 220 functioning as a fraction lending preparation signal receiving unit is a period during which the strobe signal is not transmitted to the fraction lending preparation signal transmitted from the pachinko machine 100 in response to the fraction lending request signal. Received via the SEGF signal line functioning as the fraction lending preparation signal line in the T4 ′ period.

  The unit control unit 220 functioning as a fraction lending command signal transmitting means sends the fraction lending command signal to the SEG signal line functioning as the fraction lending command signal line in the T4 ′ period which is a non-transmission period of the strobe signal. Send through. The unit controller 220 also functions as a fraction lending completion signal receiving means, and the fraction lending completion signal transmitted from the pachinko machine 100 in response to the fraction lending command signal is transmitted in a non-transmission period of the strobe signal. Received via the SEGF signal line functioning as the fraction lending completion signal line in a certain T4 ′ period.

  The payout control board 160 is an example of a unit lending request signal receiving means, and receives the unit ball lending request signal via the BRQ signal line. The payout control board 160 is an example of a unit lending preparation signal transmitting unit, and is prepared to lend a pachinko ball for several times on the basis that the unit lending request signal is received by the unit lending request signal receiving unit. The unit ball lending preparation signal is transmitted via the EXS signal line on condition that the unit ball lending request signal is received. The unit ball lending preparation signal is transmitted on the condition that it is confirmed that the preparation for lending pachinko balls for several times is completed (that is, there is a pachinko ball supplied to the ball dispensing device 170).

  The payout control board 160 is an example of a unit lending command signal receiving means, and the unit ball lending command signal transmitted from the card unit 200 in response to the unit ball lending preparation signal is transmitted via the BRQ signal line. Is received. Further, the payout control board 160 is an example of a unit lending completion signal transmitting unit, and transmits the unit ball lending completion signal via the EXS signal line.

  The payout control board 160 is an example of a lending number designation signal receiving means, and the ball lending transmitted from the card unit 200 via the display data signal line during the T4 ′ period which is a non-input period of the strobe signal. SEGA, which is a display data signal line that functions as the lending number designation signal line in the T4 ′ period, which is a non-input period of the strobe signal, as shown in FIG. The ball lending number designation signal transmitted via the signal line to the SEGD signal line is received.

  The payout control board 160 is an example of a fraction lending request signal receiving unit, and the SEG request signal line functions as the fraction lending request signal line in a T4 ′ period which is a non-input period of the strobe signal. It is received via a signal line. The payout control board 160 is an example of a fraction lending preparation signal transmission unit, and the number of ball lending number designation signal indicates the number indicated by the fraction lending request signal received by the fraction lending request signal receiving unit. On the condition that the pachinko ball is ready to be loaned, the fraction ball lending preparation signal is transmitted via the SEGF signal line functioning as the fraction lending preparation signal line in the T4 ′ period which is a non-input period of the strobe signal. Specifically, when the fraction ball lending request signal is received, the ball confirmation sensor 171 is ready to lend the pachinko balls for the number of ball lending (that is, to the ball dispensing device 170). On the condition that it is confirmed that there is a pachinko ball to be supplied), a fraction lending preparation signal is transmitted.

  The payout control board 160 is an example of a fraction lending command signal receiving means, and the fraction lending command signal transmitted from the card unit 200 in response to the fraction lending preparation signal is not input to the strobe signal. It is received via the SAGE signal line functioning as the fraction lending command signal line in the period T4 ′. Further, the payout control board 160 is an example of a fraction lending completion signal transmitting means, and the SEGF functioning as the fraction lending completion signal line is used as the fraction lending completion signal line in the T4 ′ period which is a non-input period of the strobe signal. It transmits via a signal line.

  Further, the payout control board 160 is an example of a lending control means, and performs control for lending a pachinko ball for several times when a unit ball lending command signal is received by the unit lending command signal receiving means. When the ball lending number designation signal is received by the lending number designation signal receiving means, control is performed to lend the number of pachinko balls indicated by the received ball lending number designation signal (ball lending number). Here, when the fraction lending command signal receiving means receives the fraction lending command signal, control for lending pachinko balls for the number of balls lending is performed.

  Next, an interface between the pachinko machine 100 and the card unit 200 will be described with reference to FIGS.

  FIG. 12 is a circuit diagram illustrating an example of a circuit for transmitting and receiving signals between the pachinko machine 100 and the card unit 200. As shown in this circuit diagram, an AC voltage 24V output from an AC power source 500 provided on the pachinko machine 100 side is input to the power circuit 501 on the card unit 200 side via the relay board 190. The power supply circuit 501 includes a rectifier circuit and a smoothing capacitor, converts the AC voltage 24V into a DC voltage (18V) by the rectifier circuit, smoothes the ripple by the smoothing capacitor, and applies it to various circuits and electronic devices. Is. A DC voltage VL (DC + 18V) is supplied from the power supply circuit 501.

  Photocouplers 401 to 403 are connected to the I / O 224 of the unit controller 220, and photocouplers 302 to 303 are connected to the I / O 164 of the payout control board 160. A PSI signal line is connected to the photocoupler 401, a BRDY signal line is connected between the photocoupler 402 and the photocoupler 302, and a BRQ signal line is connected between the photocoupler 403 and the photocoupler 303. .

  Here, in the photocoupler 401, the collector terminal of the phototransistor is connected to the I / O 224, and the emitter terminal is grounded. The VL is supplied to the anode side of the LED of the photocoupler 401, and the cathode side is connected to one end of the PSI signal line. The other end of the PSI signal line is connected to a ground circuit provided in the I / O 164 of the pachinko machine 100. Therefore, when the card unit 200 and the pachinko machine 100 are connected, a current flows from the anode to the cathode of the LED to emit light, illuminate the phototransistor, and the current flows between the collector and emitter of the phototransistor with the light. Yes. That is, connection confirmation is performed between the pachinko machine 100 and the card unit 200 by confirmation (detection) of this current (or current flowing through the LED).

  Next, in the photocoupler 402, the cathode side of the LED is connected to the I / O 224, and VL is supplied to the anode side. Further, the collector terminal of the phototransistor of the photocoupler 402 is connected to one end of the BRDY signal line, and the emitter terminal is grounded. The other end of the BRDY signal line is connected to the cathode side of the LED of the photocoupler 302, and VL is supplied to the anode side of the LED. The collector terminal of the phototransistor of the photocoupler 302 is connected to the I / O 164, and the emitter terminal is grounded. Therefore, when a current is passed through the LED of the photocoupler 402, a current flows between the collector and the emitter of the phototransistor, and the voltage at the collector terminal drops (that is, the cathode voltage of the LED of the photocoupler 302 drops). A current flows through the LED of the photocoupler 302 due to the drop, and light is emitted, and a current flows between the collector and the emitter of the phototransistor. Thereby, the ball lending possible signal and the ball lending end signal are transmitted from the I / O 224 to the I / O 164 via the BRDY signal line. That is, the photocoupler 402 on the card unit 200 side functions as a transmission circuit, and the photocoupler 302 on the pachinko machine 100 side functions as a reception circuit.

  The photocoupler 403 and the photocoupler 303 are also connected to each end of the BRQ signal line in the same manner as described above, and the unit ball lending from the I / O 224 to the I / O 164 via the BRQ signal line is also performed. A request signal and the unit ball lending command signal are transmitted. That is, the photocoupler 403 on the card unit 200 side functions as a transmission circuit, and the photocoupler 303 on the pachinko machine 100 side functions as a reception circuit.

  Further, a photocoupler 404 as a transmission circuit is connected to the LED drive circuit 212 on the card unit 200 side, and the cathode side of the ball lending lamp 123 that is an LED is connected to the phototransistor collector side of the photocoupler 404, The VL is supplied to the anode side of the ball lending lamp 123. Therefore, the lens lending lamp 123 is turned on when a current is passed through the LED of the photocoupler 404 by the LED drive circuit 212.

  In contrast to the photocoupler 402 connected to one end of the BRDY signal line and the photocoupler 403 connected to one end of the BRQ signal line, the I / O 224 on the card unit 200 side is a photocoupler as a receiving circuit. 405 and 406 are connected, and the I / O 164 on the pachinko machine 100 side is opposite to the photocoupler 302 connected to the other end of the BRDY signal line and the photocoupler 303 connected to the other end of the BRQ signal line. In addition, photocouplers 305 and 306 as transmission circuits are connected. Note that a DC voltage VP different from the VL is supplied to the anode side of the LEDs of the pachinko machine side photocouplers 305 and 306 as the transmission circuit. A PRDY signal line is connected between the photocoupler 405 and the photocoupler 305, and an EXS signal line is connected between the photocoupler 406 and the photocoupler 306. As a result, the payout enable signal is transmitted from the I / O 164 to the I / O 224 via the PRDY signal line. The unit ball lending preparation signal and the unit ball lending completion signal are transmitted from the I / O 164 to the I / O 224 via the EXS signal line.

  Further, a photocoupler 407 as a receiving circuit is connected to the detection circuit 213 on the card unit 200 side, and a ball lending button 122 is connected to the cathode side of the LED of the photocoupler 407. When the ball lending button 122 is pressed, a current flows through the LED of the photocoupler 407, and a current flows between the collector and emitter of the phototransistor. The detection circuit 213 detects the pressing operation of the ball lending button 122 by detecting this current.

  A photocoupler 408 as a receiving circuit is connected to the detection circuit 213 on the card unit 200 side, and a return button 124 is connected to the cathode side of the LED of the photocoupler 408. When the return button 124 is pressed, a current flows through the LED of the photocoupler 408, and a current flows between the collector and emitter of the phototransistor. The detection circuit 213 detects the pressing operation of the return button 124 by detecting this current.

  Next, referring to FIGS. 13 and 14, an interface of the 7-segment LED (segment indicators 121 a to 121 c constituting the remaining frequency indicator 121) in the pachinko machine 100 and the card unit 200 will be described.

  First, referring to FIG. 13, an interface of conventional segment display devices 121a to 121c will be described. In the conventional interface, photocouplers 411 to 413 that transmit strobe signals for dynamic lighting control of the segment display devices 121a to 121c are connected to the LED drive circuit 212. The emitter side of the phototransistors of these photocouplers 411 to 413 is grounded, and the base terminal and collector terminal of the transistor are connected to the collector side, and an output signal (that is, positive voltage) from the emitter terminal of this transistor. Are provided to the segment displays 121a to 121c via the strobe signal lines (DG1 signal line to DG3 signal line). Here, the output signal (strobe signal) is applied to the anode side of the 7-segment LED constituting the segment display (which is a common electrode for the 7 LEDs). The application of the output signal (strobe signal) is repeatedly performed in the order of the DG1 signal line, the DG2 signal line, and the DG3 signal line (that is, the order of the segment indicators 121a, 121b, and 121c) as shown in FIG.

  The LED driving circuit 212 is connected to the cathode side of the LEDs of the photocouplers 421 to 427 that transmit display data signals to the seven LEDs for display of the segment indicators 121a to 121c, and VL is supplied to the anode side. Yes. The emitter side of the phototransistors of these photocouplers 421 to 427 is grounded, and the collector side is an LED (A that constitutes the segment display devices 121a to 121c via display data signal lines (SEGA signal line to SEGG signal line), respectively. ) To the cathode side of the LED (G). As a result, the LED drive circuit 212 causes a current to flow through the LEDs of the photocouplers 421 to 427, so that the voltage on the cathode side of the LEDs (A) to LED (G) drops. Here, in the LED (A) to LED (G) of the segment display to which the strobe signal is applied, a positive voltage is applied to the anode side, so that a current flows from the anode side to the cathode side and lights up. That is, only the segment display devices 121a to 121c to which the strobe signal is applied display according to the display data signal.

  That is, the display data signal corresponding to the first digit display (segment display 121a) is transmitted during the strobe signal transmission period by the DG1 signal line, and the display corresponding to the second digit display (segment display 121b). The transmission of the data signal is performed during the transmission period of the strobe signal by the DG2 signal line, and the transmission of the display data signal corresponding to the third digit display (segment indicator 121c) is performed during the transmission period of the strobe signal by the DG3 signal line. To do.

  Next, with reference to FIG. 14, the interface of the segment display devices 121a to 121c of the present invention will be described. In the conventional interface shown in FIG. 13, photocouplers 421 to 427 for outputting display data signals to each segment (LED) are provided, but a circuit for receiving information transmitted from the pachinko side 100 is provided. There is also no circuit for transmitting / receiving information to / from the card unit 200 on the pachinko machine 100 side. On the other hand, in the interface of the present invention shown in FIG. 14, on the card unit 200 side, it is connected to a display data signal line (SEGA signal line to SEGG signal line) and can receive information from the pachinko machine 100. To 437 are provided. On the pachinko machine 100 side, photocouplers 321 to 327 connected to display data signal lines (SEGA signal line to SEGG signal line) and capable of receiving information from the card unit 200 are provided. Photocouplers 331 to 337 that can transmit the information are provided.

  These display data signal lines (SEGA signal line to SEGG signal line) and the photocouplers (421 to 427, 431 to 437, 321 to 327, 331 to 337) connected to the display data signal lines are fractional amounts. This function functions as an interface for performing communication for lending pachinko balls corresponding to the number (ie, the number of balls lent), and each function will be described below. The functions of the photocouplers 411 to 413 and the strobe signal lines (DG1 signal line to DG3 signal line) shown in FIG. 14 are the same as those shown in FIG.

  As in FIG. 13, the LED drive circuit 212 is connected to the cathode side of the LEDs of the photocouplers 421 to 427 that transmit display data signals to the seven LEDs for display of the segment displays 121a to 121c. On the side, VL is supplied. Further, the emitter side of the phototransistors of these photocouplers 421 to 427 is grounded, and the collector side is an LED constituting the segment indicators 121a to 121c via display data signal lines (SEGA signal line to SEGG signal line), respectively. (A)-It is connected with the cathode side of LED (G). In parallel with each of the photocouplers 421 to 427, photocouplers 431 to 437 for receiving signals transmitted from the pachinko machine 100 via display data signal lines (SEGA signal line to SEGG signal line) are provided. ing. In these photocouplers 431 to 437, the cathode side of the LED is connected to the collector side (display data signal line) of the phototransistor of the photocouplers 421 to 427, and VL is supplied to the anode side. The emitter terminals of the phototransistors of the photocouplers 431 to 437 are grounded, and the collector terminal is connected to the I / O 224 of the unit controller 220. That is, the unit controller 220 receives a signal transmitted from the pachinko machine 100 via the display data signal line (SEGA signal line to SEGG signal line).

  Here, the photocouplers 421 to 427 are examples of signal output circuits, and are connected to display data signal lines (SEGA signal line to SEGG signal line) to request transmission of the chip ID, disable signal, and display data signal. , A ball lending number designation signal, a fraction lending request signal, and a fraction lending command signal. The photocouplers 431 to 437 are examples of signal input circuits, and are connected to display data signal lines (SEGA signal lines to SEGG signal lines) in parallel with signal output circuits (photocouplers 421 to 427). To the unit control unit 220 is input with a signal transmitted via the transmission photocouplers 331 to 337 described later. According to this, not only the display data signal can be output to the pachinko machine 100 via the display data signal line, but also various signals transmitted from the pachinko machine 100 can be input via the display data signal line. In particular, in the present invention, the chip ID transmitted from the pachinko machine 100 can be input (acquired) by the photocoupler 437 via the display data signal line.

  During output of signals from the signal output circuit (photocouplers 421 to 427), the voltage on the cathode side of the LED of the signal input circuit (photocouplers 431 to 437) drops and current flows. A signal is input to the I / O 224 of the unit 220. At this time, the unit controller 220 does not perform any processing on the input signal. That is, the unit controller 220 invalidates the signal input to the signal input circuit (photocouplers 431 to 437) while the signal is output from the signal output circuit (photocouplers 421 to 427). According to this, the signal output circuit (photocouplers 421 to 427) and the signal input circuit (photocouplers 431 to 437) are connected in parallel to the display data signal line, thereby allowing the signal input circuit to output the display data signal. Inconvenience due to the input of a signal can be avoided.

  Photocouplers 321 to 327 for receiving signals transmitted from the card unit 200 are provided on the pachinko machine 100 side of each display data signal line (SEGA signal line to SEGG signal line). In these photocouplers 321-327, the emitter terminal of the phototransistor is grounded, and the collector terminal is connected to the I / O 164 of the payout control board 160. Further, the cathode side of the LEDs of the photocouplers 321 to 327 is connected to display data signal lines (SEGA signal line to SEGG signal line), respectively, and VL is supplied to the anode side. That is, the photocouplers 321 to 327 pay the signals output from the photocouplers 421 to 427 for transmission in the card unit 200 and transmitted via the display data signal lines (SEGA signal line to SEGG signal line). It is a circuit for receiving by. Further, photocouplers 331 to 337 for transmitting signals to the card unit 200 are provided in parallel with the photocouplers 321 to 327, and the phototransistor collector side of the photocouplers 331 to 337 is connected to the photocouplers 321 to 321. 327 is connected to the cathode side (and display data signal line) of the LED, and the emitter side is grounded. The VP is supplied to the anode side of the LEDs of the photocouplers 331 to 337, and the cathode side is connected to the I / O 164 of the payout control board 160. That is, the photocouplers 331 to 337 are circuits for transmitting signals from the payout control board 160 to the unit control unit 220 of the card unit 200 via display data signal lines (SEGA to SEGG).

  Here, the photocouplers 331 to 337 are examples of signal output circuits, and are connected to display data signal lines (SEGA signal lines to SEGG signal lines), and signals to the unit control unit 220 (photocouplers 431 to 437). Is output. According to this, not only the signal transmitted from the card unit 200 can be input via the display data signal line, but also various signals can be output to the card unit 200 via the display data signal line. . In particular, in the present invention, the chip ID can be output to the card unit 200 via the display data signal line by the photocoupler 337. The photocouplers 321 to 327 are examples of signal input circuits, and are connected to display data signal lines (SEGA signal lines to SEGG signal lines) in parallel with the signal output circuits (photocouplers 331 to 337). An ID transmission request, an immobilization signal, a ball lending number designation signal, a fraction lending request signal, and a fraction lending command signal are input.

  During the output of the signal from the signal output circuit (photocouplers 331 to 337), the voltage on the cathode side of the LED of the signal input circuit (photocouplers 321 to 327) drops and the current flows. A signal is input to the I / O 164 of the substrate 160. At this time, the payout control board 160 does not perform any processing on the input signal. That is, the payout control board 160 invalidates the input of signals to the signal input circuits (photocouplers 321 to 327) during the output of signals from the signal output circuits (photocouplers 331 to 337). According to this, a signal output circuit (photocouplers 331 to 337) and a signal input circuit (photocouplers 321 to 327) are connected in parallel to the display data signal line, so that a signal is output to the signal input circuit during signal output. Inconvenience due to input can be avoided.

  As described above, in the present invention, the display data signal line (SEGA signal line to SEGG signal line) is connected to the signal output circuit on the card unit 200 side (photocouplers 421 to 427 on the card unit side) and the signal input circuit (card). Unit-side photocouplers 431 to 437) are connected, a signal output circuit on the pachinko machine 100 side (photocouplers 331 to 337 on the pachinko machine side) and a signal input circuit (photocouplers 321 to 327 on the pachinko machine side). Is connected, bidirectional signal exchange is possible between the card unit 200 and the pachinko machine 100.

  Next, FIG. 15A is a timing chart showing an example of the chip ID acquisition process. When chip ID acquisition processing in the card unit 200 (in other words, chip ID transmission processing in the pachinko machine 100) is performed, the following signals are exchanged between the two.

  First, as shown in FIG. 15 (a1), a case where a chip ID acquisition process is performed at the time of delivery of the pachinko machine 100 and before the game hall 2 starts business will be described. In this case, first, the unit control unit 220 of the card unit 200 sets SEGG to LOW, via the SEGG signal line functioning as a chip ID transmission request signal line, via the dispensing control board 160 of the pachinko machine 100. The main board 150 is requested to transmit a chip ID. Next, the main board 150 of the pachinko machine 100 transmits the chip ID stored in the ROM 151b to the payout control board 160, and the payout control board 160 acquires and stores the chip ID and also sends a chip ID signal. The chip ID is transmitted to the unit control unit 220 of the card unit 200 via the SEGG signal line functioning as a line. The chip ID transmitted here is transmitted for each digit from the first digit to the ninth digit of the chip ID, and each transmitted digit is 4 bits sandwiched between a start bit and a stop bit. It is represented by

  Next, as shown in FIG. 15 (a2), a case where a chip ID acquisition process is performed during business of the game hall 2 will be described. In this case, since the display by the remaining frequency indicator 121 is performed, the chip ID transmission request and the chip ID transmission are performed in the T4 'period so as not to affect the display. Specifically, first, the LED drive circuit 212 of the card unit 200 performs control to extend the T4 period to the T4 ′ period based on a command from the unit control unit 220, and the unit control unit 220 of the card unit 200 In the T4 ′ period (that is, the strobe signal non-transmission period), by setting SEGG to LOW, the SEGG signal line functioning as the chip ID transmission request signal line is passed through the payout control board 160 of the pachinko machine 100. The main board 150 is requested to transmit a chip ID. Next, the main board 150 of the pachinko machine 100 transmits the chip ID stored in the ROM 151b to the payout control board 160, and the payout control board 160 acquires and stores the chip ID, and the T4 ' In the period (that is, the strobe signal non-input period), the chip ID is transmitted to the unit controller 220 of the card unit 200 via the SEGG signal line functioning as the chip ID signal line.

  That is, the unit controller 220 functioning as the identification information acquisition unit requests the corresponding pachinko machine 100 to transmit the chip ID via the display data signal line during the non-transmission period of the strobe signal, and responds to the request. Thus, the chip ID transmitted from the corresponding pachinko machine 100 via the display data signal line in the non-transmission period of the strobe signal is acquired. Further, the I / O 154d functioning as the gaming machine side identification information transmitting means transmits the chip ID to the corresponding card unit 200 via the display data signal line during the non-input period of the strobe signal.

  Next, FIG. 15B is a timing chart showing an example of the immobilization signal transmission process. When the disablement signal transmission process in the card unit 200 (in other words, disablement signal reception process in the pachinko machine 100) is performed, the disablement is performed from the card unit 200 to the pachinko machine 100 as follows. A signal is transmitted.

  First, as shown in FIG. 15 (b1), the case where the immobilization signal transmission process is performed before the game hall 2 starts business will be described. In this case, the unit control unit 220 of the card unit 200 is immovable with respect to the main board 150 via the payout control board 160 of the pachinko machine 100 via the SEGG signal line that functions as an immobilization signal line. Send a digitized signal. The disablement signal transmitted here is represented by, for example, predetermined 4 bits.

  Next, as shown in FIG. 15 (b2), a case where the immobilization signal transmission process is performed during the operation of the game hall 2 will be described. In this case, since the display by the remaining frequency indicator 121 is performed, the disabling signal is transmitted in the T4 'period so as not to affect the display. Specifically, the LED drive circuit 212 of the card unit 200 performs control to extend the T4 period to the T4 ′ period based on a command from the unit control unit 220, and the unit control unit 220 of the card unit 200 In the T4 ′ period (that is, the strobe signal non-transmission period), the main board 150 is disabled through the payout control board 160 of the pachinko machine 100 via the SEGG signal line functioning as the disabled signal line. Send a digitized signal.

  Next, FIG. 16 is a timing chart showing an example of the unit ball lending process. When the unit ball lending process is performed in the card unit 200 and the pachinko machine 100, the following signals are exchanged between them.

  First, when the connection between the pachinko machine 100 and the card unit 200 is confirmed when the pachinko machine 100 and the card unit 200 are turned on, the payout control board 160 of the pachinko machine 100 sets the PRDY to LOW so that the card is connected via the PRDY signal line. A payout enable signal is transmitted to the unit controller 220 of the unit 200 (S1), and a standby state is entered.

  Next, when the unit control unit 220 of the card unit 200 detects the operation of the ball lending button 122 by the detection circuit 213 in the standby state where PRDY LOW (payable signal) is received, the BRDY is set to LOW. A ball lending possible signal is transmitted to the payout control board 160 of the pachinko machine 100 via the BRDY signal line (S2). In the visitor ball lending process, the unit ball lending process is performed regardless of the operation of the ball lending button 122. Therefore, not the detection of the operation of the ball lending button 122 by the detection circuit 213 but the deposit amount 7 When the recorded deposit balance is read out, the control in S2 is performed.

  In this state, the unit control unit 220 of the card unit 200 transmits a unit ball lending request signal to the payout control board 160 of the pachinko machine 100 via the BRQ signal line by setting BRQ to LOW (S3). Next, when the payout control board 160 of the pachinko machine 100 receives a BRQ LOW (unit ball lending request signal) in a state where the BRDY LOW (ball lending available signal) is received, the ball check sensor 171 corresponds to the number of times. Check whether or not the number of pachinko balls is ready for lending (ball lending preparation), and on condition that the ball lending preparation is ready, by setting EXS to LOW, via the EXS signal line The unit ball lending preparation signal is transmitted to the unit control unit 220 of the card unit 200 (S4).

  Next, the unit control unit 220 of the card unit 200 that has received the LOW (unit ball lending preparation signal) of the EXS sets the BRQ to HIGH, so that the payout control board 160 of the pachinko machine 100 is connected to the payout control board 160 via the BRQ signal line. A unit ball lending command signal is transmitted (S5). Next, the payout control board 160 of the pachinko machine 100 that has received the HIGH (unit ball lending command signal) of the BRQ outputs a payout signal to the ball payout device 170, and on the basis of this, the number corresponding to one number of times is output. Pachinko balls (for example, 25 balls) are paid out, and, based on the completion of the payout, by setting EXS to HIGH, unit ball lending is completed to the unit control unit 220 of the card unit 200 via the EXS signal line. A signal is transmitted (S6).

  Then, the unit control unit 220 of the card unit 200 that has received the HIGH (unit ball lending completion signal) of the EXS is a few minutes from the deposit remaining amount recorded on the encapsulated card 7 or the card remaining amount recorded on the member card 8. The amount of money after subtracting the amount of money (105 yen in this case) is recorded, and the display of the remaining frequency indicator 121 is subtracted once and displayed. The unit control unit 220 of the card unit 200 repeats the control of S3 to S6 by the set frequency, and sets BRDY to HIGH based on the end of these controls, so that the pachinko machine 100 is connected via the BRDY signal line. The ball lending end signal is transmitted to the payout control board 160 (S7), and the unit ball lending process is terminated.

  FIG. 17 is a timing chart illustrating an example of the fraction lending process. When the fraction lending process is performed in the card unit 200 and the pachinko machine 100, the following signals are exchanged between the two.

  First, when the unit controller 220 of the card unit 200 detects the operation of the ball lending button 122 by the detection circuit 213 in the standby state in which the PRDY LOW (payable signal) is received, the BRDY is set to LOW. A ball lending possible signal is transmitted to the payout control board 160 of the pachinko machine 100 via the BRDY signal line (S2). In the visitor ball lending process, fractional ball lending processing is performed regardless of the operation of the ball lending button 122. Therefore, the unit ball lending process is not performed when the detection circuit 213 detects the operation of the ball lending button 122. When finished, the control of S2 is performed.

  In this state, the LED drive circuit 212 of the card unit 200 performs control to extend the T4 period, which is the non-transmission period of the strobe signal, to the T4 ′ period based on a command from the unit controller 220. The unit controller 220 transmits a ball lending number designation signal to the payout control board 160 of the pachinko machine 100 via the SEGA signal line to SEGD signal line functioning as a lending number designation signal line in the T4 ′ period.

  Here, when the display data signal line functions as a lending number designating signal line, the SEGA signal line functions as a signal line for designating 2 to the power of 0 = 1, and the SEGB signal line is 1 of 2. Multiplier = functions as a signal line for designating 2 ball lending numbers, SEGC signal line functions as a square for 2 = signal line for designating 4 ball lending numbers, SEGD signal line is 2 To the third power = 8 functions as a signal line for designating the number of balls loaned.

  Therefore, any number of ball lending numbers up to 1 + 2 + 4 + 8 = 15 can be designated in one cycle by combining ball lending number designation signals transmitted via the SEGA signal line to SEGD signal line. For example, when 6 balls are specified as the number of balls to be loaned, although not shown, a ball loan number specification signal is transmitted via the SEGB signal line and the SEGC signal line in the first cycle, thereby 2 + 4 = 6 ball loan numbers. Is specified.

  If the number of balls lent is 16 or more, the number of balls lent is specified in two cycles. For example, when 17 balls are designated as the ball lending number, as shown in FIG. 17, the ball lending number is designated via the SEGA signal line, SEGB signal line, SEGC signal line, and SEGD signal line in the T4 ′ period of the first cycle. By transmitting a signal and transmitting a ball lending number designation signal via the SEGB signal line during the T4 ′ period of the second cycle, (1 + 2 + 4 + 8) + 2 = 17 ball lending numbers are designated.

  Next, the unit control unit 220 of the card unit 200 sets the SEGE to LOW in this state, and thereby the payout control board of the pachinko machine 100 via the SAGE signal line functioning as a fraction lending request signal line in the T4 ′ period. A fraction lending request signal is transmitted to 160 (S3). Next, when the payout control board 160 of the pachinko machine 100 receives the SEGE LOW (fractional lending request signal) in the state of receiving the BRDY LOW (ball lending available signal), the ball check sensor 171 specifies the ball lending number designation. Check whether or not the number of pachinko balls indicated by the signal is ready (ball lending preparation), and set SEGF to LOW on condition that the ball lending preparation is ready. Then, a fraction lending preparation signal is transmitted to the unit controller 220 of the card unit 200 via the SEGF signal line functioning as a fraction lending preparation signal line (S4).

  Next, the unit control unit 220 of the card unit 200 that has received the SEGF LOW (fractional loan lending preparation signal) sets the SEGE to HIGH so that it functions as a fractional loan command signal line in the T4 ′ period. Then, a fraction lending command signal is transmitted to the payout control board 160 of the pachinko machine 100 (S5). Next, the payout control board 160 of the pachinko machine 100 that has received the SEGE HIGH (fractional ball lending command signal) outputs a payout signal to the ball payout device 170, and the ball lending number designation signal is based on this. The payout of the number of pachinko balls shown is performed, and by setting SEGF HIGH based on the completion of the payout, the card unit is passed through the SEGF signal line functioning as a fractional ball lending completion signal line in the T4 ′ period. A fraction lending completion signal is transmitted to the 200 unit controller 220 (S6). The control of S3 to S6 is performed within one cycle T4 'period. In FIG. 17, the length of the T4 ′ period is shown to be different, but this is for the convenience of drawing, and the length of the T4 ′ period in this embodiment is the same.

  Then, the unit control unit 220 of the card unit 200 that has received the SEGF HIGH (fractional loan completion signal) sets the deposit remaining amount recorded on the encapsulated card 7 or the card remaining amount recorded on the member card 8 to zero. In addition to performing the process, a process for setting the display of the remaining frequency indicator 121 to 0 is performed. The unit control unit 220 of the card unit 200 outputs a ball lending end signal to the payout control board 160 of the pachinko machine 100 via the BRDY signal line by setting BRDY to HIGH based on the end of these controls. (S7) The LED drive circuit 212 of the card unit 200 performs control to return the extended T4 ′ period to the normal T4 period, and ends the fraction lending process.

  Next, the operation of the card unit 200 will be described with reference to FIGS. 18 to 24, the operation of the pachinko machine 100 will be described with reference to FIGS. 25 to 27, and the gaming system 1 will be described with reference to FIG. 28. The operation will be described.

  First, FIG. 18 is a flowchart showing an example of pre-business start processing in the card unit 200. In the card unit 200, after the power of the card unit 200 is turned on and the AC 24V power supplied from the powered pachinko machine 100 is rectified to the DC 18V power (VL), the step Sa (hereinafter simply referred to as “Sa”) is performed. According to 1 to 23, pre-business start processing is performed.

  Specifically, first, when the connection is confirmed with the pachinko machine 100 via the PSI signal line at Sa1, the transmission control board 160 of the pachinko machine 100 is transmitted via the PRDY signal line at Sa2. It waits for the receipt of a payout enable signal. If it is determined at this Sa2 that a payout enable signal is received (YES), the process proceeds to Sa3.

  In Sa3, whether or not the identification information transmission impossible information transmitted from the center server 20 via the system controller 10 has been received (that is, the corresponding game machine has an identification information transmission function and a fraction lending processing function) Or not). If it is determined that the identification information transmission impossibility information is received in Sa3 (YES), that is, if the corresponding gaming machine is not a new gaming machine, the fact that the fraction lending process is not performed is set in Sa16. The process proceeds to Sa12. According to this, in the conventional gaming machine that does not have the fraction lending processing function, the processing for transmitting the ball lending number designation signal in the fraction lending processing is not performed, so that the gaming machine that does not support the fraction lending The influence on the gaming machine side by receiving the designated signal can be completely eliminated.

  Further, in this case, the ball lending process is activated in the card unit 200 corresponding to the conventional gaming machine having no identification information transmission function without performing the chip ID acquisition process (see Sa12). A game on the gaming machine can be securely secured. Further, in this case, the operation of the gaming machine is active in the conventional gaming machine that does not have the identification information transmission function without performing the chip ID acquisition process and the immobilization signal transmission process. Therefore, it is possible to securely secure a game on the gaming machine. On the other hand, if it is determined at Sa3 that the identification information transmission impossibility information has not been received (NO), that is, the corresponding gaming machine is a new gaming machine, the process proceeds to Sa4.

  In Sa4, reception of a chip ID acquisition request transmitted from the center server 20 via the system controller 10 at the chip ID request time set in FIG. If it is determined at this Sa4 that a chip ID acquisition request has been received (YES), at Sa5, as shown in FIG. 15 (a1), the display data signal line ( Here, the corresponding pachinko machine 100 is requested to transmit the chip ID via the SEGG signal line), and the process proceeds to Sa6.

  In Sa6, the reception of the chip ID transmitted from the corresponding pachinko machine 100 via the display data signal line (here, the SEGG signal line) functioning as the chip ID signal line in response to the request for transmitting the chip ID is awaited. According to this, the card is connected via the display data signal line included in the signal line connecting the conventional pachinko machine 100 having the remaining frequency indicator 121 and the conventional card unit 200 corresponding to the pachinko machine 100. Since the unit 200 acquires the chip ID of the main board 150 from the pachinko machine 100, it is not necessary to add a new signal line for acquiring the chip ID, and a new one corresponding to the signal line on the pachinko machine 100 side. No need to add additional interfaces.

  If it is determined in Sa6 that no chip ID has been received within a predetermined period (NO), the ball lending process is disabled, as shown in FIG. 15 (b1). Then, the disabling signal is transmitted to the corresponding pachinko machine 100 via the display data signal line (here, the SEGG signal line) functioning as the disabling signal line, and the pre-business start processing is terminated. On the other hand, if it is determined at Sa6 that the chip ID has been received within a predetermined period (YES), a timer T for measuring a predetermined time is set at Sa7, and the acquired chip ID at Sa8. Is stored in the card R / W control unit 230, and in Sa9, the machine number of the corresponding pachinko machine 100 and the stored chip ID are transmitted to the system controller 10, and the process proceeds to Sa10.

  In Sa10, it is determined whether or not a verification result (verification OK) transmitted from the center server 20 via the system controller 10 has been received. If it is determined in Sa10 that no verification OK has been received (NO), whether or not a verification result (verification NG) transmitted from the center server 20 via the system controller 10 is received in Sa17. Make a decision. If it is determined in Sa17 that no verification NG has been received (NO), it is determined in Sa21 whether or not the timer T set in Sa7 is timed out. In this case, it is determined that a timeout has occurred. When the machine number and the chip ID are transmitted to the system controller 10, the verification OK or the verification NG cannot be received from the system controller 10. The case where the machine number and the chip ID cannot be transmitted to 10 (for example, when an offline state incapable of communicating with the system controller 10 occurs) is included. If it is determined in this Sa21 that the timeout has not occurred (NO), the process returns to Sa10 and waits for reception of verification OK or verification NG.

  On the other hand, if it is determined at Sa21 that the timeout has occurred (YES), the chip ID stored at Sa8 is erased at Sa22, and error processing (for example, disabling the ball lending process and pachinko machine is performed at Sa23). 100), the pre-business start processing is terminated. According to this, since the chip ID stored in the card unit 200 is erased on the condition that a predetermined time has elapsed since the card unit 200 acquired the chip ID from the pachinko machine 100, the card unit 200 Even when the acquired chip ID cannot be transmitted to the system controller 10 due to the inability to communicate with the system controller 10 or the like, the possibility that the chip ID is illegally acquired from the memory in the card unit 200 is significantly reduced. Is done.

  If it is determined in Sa17 that the verification NG is received (YES), the chip ID stored in Sa8 is erased in Sa18, and the process proceeds to Sa19. According to this, the chip ID acquired by the card unit 200 from the pachinko machine 100 is transmitted to the system controller 10 (in this example, the chip ID is transmitted to the system controller 10, and the system controller 10 Since the chip ID stored in the card unit 200 is erased on the condition that the verification NG has been received), the possibility that the chip ID is illegally acquired from the storage in the card unit 200 is significantly reduced.

  In Sa19, the ball lending process is disabled, and in Sa20, as shown in FIG. 15 (b1), it is handled via the display data signal line (here, the SEGG signal line) that functions as the disabled signal line. An immobilization signal is transmitted to the pachinko machine 100, and the pre-business start processing is terminated. According to this, since the operation of the pachinko machine 100 is disabled on condition that the verification of the chip IDs does not match, it is possible to completely prevent a game in the pachinko machine 100 replaced with an unauthorized main board. That is, it is possible to completely prevent a game by bringing a pachinko ball or the like, or a game by a so-called double sand (a ball lending device provided separately from the card unit 200).

  If it is determined in Sa10 that the verification OK is received (YES), the chip ID stored in Sa8 is erased in Sa11, and the process proceeds to Sa12. According to this, the chip ID acquired by the card unit 200 from the pachinko machine 100 is transmitted to the system controller 10 (in this example, the chip ID is transmitted to the system controller 10, and the system controller 10 Since the chip ID stored in the card unit 200 is erased on the condition that the verification OK has been received), the possibility that the chip ID is illegally acquired from the storage in the card unit 200 is significantly reduced.

  In Sa12, the ball lending process is activated. In Sa13, the system controller 10 is requested to transmit the set tax rate. In Sa14, the center server 20 transmits the tax to the system controller 10 and stores it in the system controller 10. The system waits for reception of the set tax rate transmitted from the system controller 10 in response to the transmission request. If it is determined in Sa14 that the set tax rate is received (YES), the received set tax rate is stored in the RAM 223 of the unit control unit 220 in Sa15, and the pre-business start processing is terminated.

  Next, FIG. 19 is a flowchart showing an example of the business process in the card unit 200. In the card unit 200, during the business of the game hall 2, the business process is performed by steps Sb (hereinafter simply referred to as “Sb”) 1 to 31.

  Specifically, first, in Sb1, the multifunction lamp 270 is lit in green to notify that the member card 8 is not being accepted, and the process proceeds to Sb2. In Sb2, it is determined whether or not the membership card 8 is accepted. If it is determined in Sb2 that the membership card 8 is not received (NO), it is determined whether or not money is received in Sb14. If it is determined in Sb14 that money is accepted (YES), a visitor ball lending process shown in FIG. 21 described later is performed in Sb15, and the process returns to Sb2. On the other hand, if it is determined at Sb14 that no money is accepted (NO), the system controller at Sb25 at the timing set in FIG. 3B or in response to the request in FIG. 3C. It is determined whether or not a chip ID acquisition request transmitted from 10 has been received. If it is determined in Sb25 that a chip ID acquisition request has been received (YES), in Sb26, after-execution chip ID acquisition processing shown in FIG. 20 described later is performed, the process returns to Sb2. On the other hand, if it is determined in Sb25 that no chip ID acquisition request has been received (NO), the process returns to Sb2.

  If it is determined in Sb2 that the membership card 8 is accepted (YES), in Sb3, the multifunction lamp 270 is lit in blue to notify that the membership card 8 is being accepted, and in Sb4, The member card R / W 290 reads the member ID and the remaining card amount from the received member card 8, and in Sb5, sends a verification request including the read member ID and the remaining card amount to the system controller 10, and Sb6 Proceed to

  In Sb6, it is determined whether or not the collation OK transmitted from the system controller 10 is received in response to the collation request. If it is determined in Sb6 that no verification OK is received (NO), it is determined in Sb16 whether or not there is a verification NG received from the system controller 10 in response to the verification request. . If it is determined in Sb16 that no verification NG has been received (NO), the process returns to Sb6 and waits for reception of verification OK or verification NG. On the other hand, if it is determined in Sb16 that the verification NG is received (YES), the accepted member card 8 is returned in Sb30, and the multi-function lamp 270 is lit in green in Sb31. Is notified that it is not being accepted and performs RETURN.

  If it is determined in Sb6 that the verification OK is received (YES), it is determined in Sb7 whether or not the read card balance is zero. If it is determined in Sb7 that the remaining card amount is zero (YES), 0 is displayed on the remaining frequency display 121 by the dynamic lighting control means in Sb17, and the process proceeds to Sb18. In Sb18, it is determined whether or not money is accepted. If it is determined in Sb18 that no currency is accepted (NO), it is determined in Sb27 whether or not there is a return operation (ie, a pressing operation of the return button 124). If it is determined in Sb27 that there is no return operation (NO), the process returns to Sb18 and waits for a currency acceptance or return operation. On the other hand, when it is determined in Sb27 that there is a return operation (YES), RETURN is performed through Sb30 to Sb31. If it is determined in Sb18 that money is accepted (YES), a deposit process shown in FIG. 22 described later is performed in Sb24, and then the process proceeds to Sb9.

  If it is determined in Sb7 that the remaining card amount is not zero (NO), the remaining number and the fractional amount are calculated based on the remaining card amount in Sb8, and the process proceeds to Sb9. In Sb9, it is determined whether or not the calculated remaining frequency is 1 or more. If it is determined in Sb9 that the remaining number is 1 or more (YES), the remaining number is displayed on the remaining number display 121 by the dynamic lighting control means in Sb19, and the ball lending lamp 123 is displayed in Sb20. Is turned on to notify that the ball lending operation can be accepted, and the process proceeds to Sb21. In Sb21, it is determined whether or not there is a ball lending operation (that is, a pressing operation of the ball lending button 122). If it is determined in Sb21 that there is no ball lending operation (NO), it is determined in Sb28 whether or not there is a return operation (that is, a pressing operation of the return button 124). If it is determined in Sb28 that there is no return operation (NO), the process returns to Sb21 and waits for a ball lending operation or a return operation. On the other hand, if it is determined in Sb28 that there is a return operation (YES), RETURN is performed through Sb30 to Sb31. If it is determined in Sb21 that there is a ball lending operation (YES), a member-unit ball lending process shown in FIG. 23 described later is performed in Sb22, and then the process returns to Sb7.

  If it is determined in Sb9 that the remaining frequency is not 1 or more (NO), that is, it is determined that the remaining card amount is a fractional amount, the fractional amount is displayed on the remaining frequency indicator 121 by the dynamic lighting control means in Sb10, In Sb11, the ball lending lamp 123 is turned on to notify that the ball lending operation can be accepted, and the process proceeds to Sb12. In Sb12, it is determined whether or not there is a ball lending operation (ie, a pressing operation of the ball lending button 122). If it is determined at Sb12 that there is no ball lending operation (NO), it is determined at Sb23 whether or not money is accepted. If it is determined in Sb23 that no money is received (NO), it is determined in Sb29 whether or not there is a return operation (ie, a pressing operation of the return button 124). If it is determined in Sb29 that there is no return operation (NO), the process returns to Sb12 and waits for a ball lending operation, accepting money, or a return operation. On the other hand, when it is determined in Sb29 that there is a return operation (YES), RETURN is performed through Sb30 to Sb31. If it is determined in Sb23 that money is accepted (YES), a deposit process shown in FIG. 22 described later is performed in Sb24, and then the process proceeds to Sb9. If it is determined in Sb12 that there is a ball lending operation (YES), the member fraction ball lending process shown in FIG. 24 described later is performed in Sb13, and then the process returns to Sb18.

  Next, FIG. 20 is a flowchart showing an example of the operating chip ID acquisition process in the card unit 200. In the card unit 200, when the chip ID acquisition request transmitted from the system controller 10 is received at the timing set in FIG. 3B or in response to the request in FIG. In Sb26 of FIG. 19, a sub-routine of the operating chip ID acquisition process is performed in steps Sc (hereinafter simply referred to as “Sc”) 1-16.

  Specifically, first, in Sc1, control is performed to extend the T4 period, which is the non-transmission period of the strobe signal, to the T4 'period, and the process proceeds to Sc2. Here, the processing of Sc2 to Sc8 is substantially the same as the processing of Sa5 to Sa11 in FIG. However, in Sc2, as shown in FIG. 15 (a2), the display data signal line (here, SEGG signal line) functioning as a chip ID transmission request signal line is passed through the T4 ′ period, which is the non-transmission period of the strobe signal. Thus, the corresponding pachinko machine 100 is requested to transmit the chip ID. In Sc3, as shown in FIG. 15A2, the display data signal line (herein, the SEGG signal line) functioning as a chip ID signal line in the T4 ′ period, which is the non-transmission period of the strobe signal, A chip ID is received from the corresponding pachinko machine 100. According to this, by transmitting a chip ID transmission request from the card unit 200 to the pachinko machine 100 and transmitting a chip ID from the pachinko machine 100 to the card unit 200 during the non-transmission period of the strobe signal, the remaining frequency indicator Since the display of 121 is not affected, the time limit for performing the verification of the chip ID is relaxed. For example, the verification of the chip ID can be performed not only before the game hall 2 starts business or after the business ends, but also during the game hall 2 business (during a game). After the process of Sc8, in Sc9, control is performed to return the T4 'period, which is the non-transmission period of the strobe signal, to the T4 period, and the operating chip ID acquisition process is terminated.

  Moreover, since the process of Sc10-Sc13 is substantially the same as the process of Sa17-Sa20 in the said FIG. 18, description is abbreviate | omitted. However, in Sc13, as shown in FIG. 15 (b2), through the display data signal line (here, the SEGG signal line) functioning as an immobilization signal line in the T4 ′ period, which is the non-transmission period of the strobe signal. The immobilization signal is transmitted to the corresponding pachinko machine 100. According to this, the disabling signal is transmitted from the card unit 200 to the pachinko machine 100 during the non-transmission period of the strobe signal, so that the display of the remaining frequency indicator 121 is not affected. After the processing of Sc13, the processing for Sc9 is completed through the processing of Sc9.

  Further, the processes of Sc14 to Sc16 are the same as the processes of Sa21 to Sa23 in FIG. After the process of Sc16, the operating chip ID acquisition process is terminated through the process of Sc9.

  Next, FIG. 21 is a flowchart showing an example of visitor ball lending processing in the card unit 200. In the card unit 200, when money is accepted in a state where the membership card 8 is not accepted, visitor ball lending is performed in steps Sd (hereinafter simply referred to as “Sd”) 1-31 in Sb15 of FIG. A processing subroutine is performed.

  Specifically, first, in Sd1, the money accepted in the Sb14 is identified by the money accepting means, and the process proceeds to Sd2. In Sd2, it is determined whether or not the identification result is normal. If it is determined in Sd2 that the identification result is not normal (NO), the accepted money is returned in Sd18, and the visitor ball lending process is terminated. On the other hand, if it is determined in Sd2 that the identification result is normal (YES), the identification amount in Sd1 is recorded on the encapsulating card 7 as the deposit amount in Sd3 by the enclosing card R / W 280, and in Sd4, The deposit card R / W 280 reads the remaining deposit amount from the encapsulated card 7, and in Sd 5, the remaining frequency is calculated based on the read deposit balance, and in Sd 6, the calculation is performed on the remaining frequency indicator 121 by the dynamic lighting control means. The remaining frequency is displayed, and the process proceeds to the unit ball lending process of Sd7 to Sd17.

  In Sd7, the calculated remaining number is set as the ball lending number, and in Sd8, a ball lending available signal is transmitted to the payout control board 160 of the pachinko machine 100 via the BRDY signal line. In Sd9, the BRQ signal line is set. The unit ball lending request signal is transmitted to the payout control board 160 of the pachinko machine 100, and the unit ball lending preparation signal transmitted from the payout control board 160 of the pachinko machine 100 via the EXS signal line is received at Sd10. Wait.

  If it is determined in Sd10 that no unit ball lending preparation signal is received within a predetermined time (NO), the ball lending process is terminated. On the other hand, if it is determined in Sd10 that a unit ball lending preparation signal is received (YES), a unit ball lending command signal is sent to the payout control board 160 of the pachinko machine 100 via the BRQ signal line in Sd11. Then, in Sd12, the reception of the unit ball lending completion signal transmitted from the payout control board 160 of the pachinko machine 100 via the EXS signal line is awaited. If it is determined in Sd12 that the unit ball lending completion signal has not been received within the predetermined time (NO), the ball lending process is interrupted, and the multi-function lamp 270 notifies that there is an error. On the other hand, if it is determined in Sd12 that a unit ball lending completion signal is received (YES), the process proceeds to Sd13.

  At Sd13, the encapsulated card R / W280 records the amount after subtracting the amount of money for one time (105 yen in this case) from the balance of the encapsulated card 7 into the encapsulated card 7, and at Sd14, the dynamic lighting control means The remaining frequency display unit 121 displays the remaining frequency obtained by subtracting one frequency, and the process proceeds to Sd15.

  In Sd15, it is determined whether or not the ball lending for the set frequency set in Sd7 has ended. If it is determined in Sd15 that the ball lending for the set frequency is not completed (NO), the process returns to Sd9, and the loop of Sd9 to Sd14 is repeated until the ball lending for the set frequency is completed. On the other hand, if it is determined in Sd15 that the ball lending for the set frequency has been completed (YES), in Sd16, the dynamic lighting control means displays the fractional amount calculated in Sd5 on the remaining frequency indicator 121, and Sd17 Then, a ball lending end signal is transmitted to the payout control board 160 of the pachinko machine 100 via the BRDY signal line, the unit lending process is terminated, and the ball lending of Sd19 to Sd30 is performed regardless of the ball lending operation. Proceed to processing.

  In Sd19, the number of ball lending is specified based on the fractional amount calculated in Sd5, and in Sd20, control is performed to extend the T4 period, which is the non-transmission period of the strobe signal, to the T4 ′ period. In Sd21, the BRDY signal line , A ball lending possible signal is transmitted to the payout control board 160 of the pachinko machine 100, and at Sd22, during the T4 ′ period which is a non-transmission period of the strobe signal, as shown in FIG. A ball lending number designation signal is transmitted to the payout control board 160 of the pachinko machine 100 via the SEGA signal line to SEGD signal line functioning as a lending number designation signal line, and the process proceeds to Sd23.

  According to this, since the ball lending number designation signal is transmitted through the display data signal line during the non-transmission period of the strobe signal, it is necessary to add a new signal line for transmitting the ball lending number designation signal. In addition, there is no need to change the interface on the pachinko machine 100 side, and not only the number of pachinko balls indicated by the ball lending number designation signal can be lent in a fraction-compatible gaming machine, but also compatibility with conventional gaming machines. Can also be secured. In addition, since the ball lending number designation signal is transmitted during the non-transmission period of the strobe signal, the display of the remaining frequency indicator 121 is not affected. Also, when the ball lending number designation signal is transmitted, control is performed to extend the T4 period, which is the non-transmission period of the strobe signal, to the T4 ′ period, so that the ball lending number designation signal is missed on the pachinko machine 100 side. The risk of doing so is reduced.

  In Sd23, the fraction lending request signal is transmitted to the payout control board 160 of the pachinko machine 100 via the SAGE signal line functioning as a fraction lending request signal line of the display data signal lines. In Sd24, the display data signal is displayed. The reception of the fraction lending preparation signal transmitted from the payout control board 160 of the pachinko machine 100 via the SEGF signal line functioning as a fraction lending preparation signal line is awaited.

  If it is determined in Sd24 that no fraction lending preparation signal has been received within a predetermined time (NO), the ball lending process is terminated. When there is a ball lending operation, the ball lending process is resumed. On the other hand, if it is determined in Sd24 that the fraction lending preparation signal is received (YES), in Sd25, the SEG signal line that functions as the fraction lending command signal line of the display data signal lines is used. A payout control board 160 of the pachinko machine 100 is transmitted to the payout control board 160 of the pachinko machine 100, and a payout control board of the pachinko machine 100 is transmitted via the SEGF signal line functioning as a fractional payout completion signal line of the display data signal lines in Sd26. It waits for reception of the fraction lending completion signal transmitted from 160. If it is determined in Sd26 that the fraction lending completion signal has not been received within a predetermined time (NO), the ball lending process is interrupted, and the multi-function lamp 270 notifies that there is an error. On the other hand, if it is determined in Sd26 that a fraction lending completion signal has been received (YES), the process proceeds to Sd27. These processes of Sd23 to Sd26 are performed within a T4 'period of one cycle.

  As described above, since the round ball lending request signal, the fraction ball lending preparation signal, and the fraction ball lending command signal are transmitted and received (so-called handshake), the number of pachinko balls indicated by the ball lending number designation signal on the pachinko machine 100 side. Since no lending command is issued in the state where it is not ready to lend, and signal transmission and reception for that is performed via the display data signal line, there is no need to add a new signal line and gaming It is not necessary to add a new interface corresponding to the signal line on the machine side, and compatibility with a conventional gaming machine can be ensured.

  In Sd27, the deposit card R / W 280 sets the deposit remaining amount of the encapsulated card 7 to 0, and in Sd28, the display of the remaining frequency display 121 is set to 0 by the dynamic lighting control means. In Sd29, the pachinko machine The ball lending end signal is transmitted to the payout control board 160 of the machine 100. At Sd30, the T4 ′ period, which is the non-transmission period of the strobe signal, is controlled to return to the T4 period, the fraction lending process is terminated, and at Sd31 The ball lending usage amount (that is, the remaining deposit amount in Sd3) is transmitted to the system controller 10, and the visitor ball lending process is terminated.

  Next, FIG. 22 is a flowchart showing an example of a deposit process in the card unit 100. In the card unit 200, when money is received in a state in which the remaining amount of the membership card 8 is zero or a fractional amount, Step Se (hereinafter simply referred to as “Se”) 1 to 7 in Sb24 of FIG. Thus, a deposit processing subroutine is performed.

  Specifically, first, at Se1, the money accepted at the Sb18 or Sb23 is identified by the money accepting means, and the process proceeds to Se2. In Se2, it is determined whether or not the identification result is normal. If it is determined in Se2 that the identification result is not normal (NO), the accepted money is returned in Se7, and the deposit process is terminated. On the other hand, if it is determined in Se2 that the identification result is normal (YES), in Se3, payment information including the member ID read in Sb4 and the identification amount in Se1 is transmitted to the system controller 10. Then, in Se4, it waits for receipt of the deposit completion information transmitted from the system controller 10 in response to the transmission of the deposit information. If it is determined that there is receipt of payment completion information at Se4 (YES), at Se5, the member card R / W 290 records the amount obtained by adding the identification amount in Se1 to the remaining card amount of the member card 8. In Se6, the remaining frequency and the fractional amount are calculated based on the remaining card amount after the addition, and the deposit process is completed.

  Next, FIG. 23 is a flowchart showing an example of the membership unit ball lending process in the card unit 200. In the card unit 200, when a ball lending operation is performed in a state where the remaining amount of the membership card 8 is one or more times, in Sb22 of FIG. 19, steps Sf (hereinafter simply referred to as “Sf”) 1 to 1. 13, a subroutine for member-unit ball lending processing is performed.

  Specifically, first, in Sf1, it is determined whether or not the remaining frequency calculated in Sb8 is equal to or larger than a preset ball lending frequency (for example, 5). If it is determined in Sf1 that the remaining frequency is equal to or greater than the ball lending setting frequency (YES), the ball lending setting frequency (here, 5 degrees) is set as the ball lending frequency in Sf2, and Sf3 to Sf11 Proceed to the unit ball lending process. On the other hand, if it is determined in Sf2 that the remaining frequency is not equal to or more than the ball lending setting frequency (NO), the remaining frequency (the remaining frequency of the integer part not including the fractional amount) is set as the ball lending frequency, and Sf3 Proceed to the unit ball lending process of Sf11.

  Here, the processing of Sf3 to Sf10 is substantially the same as the processing of Sd9 to Sd15 in FIG. However, in Sf8 corresponding to Sd13 in FIG. 21, the member card R / W 290 records the amount after subtracting the amount of money for one time (105 yen in this case) from the remaining amount of the member card 8 on the member card 8. .

  In the next Sf11, a ball lending end signal is transmitted to the payout control board 160 of the pachinko machine 100 via the BRDY signal line, and the unit ball lending process is terminated. In Sf12, the ball lending process is performed to the system controller 10. The amount used (that is, the amount corresponding to the set frequency in Sf2 or Sf13) is transmitted, and the member-unit ball lending process is terminated.

  Next, FIG. 24 is a flowchart showing an example of the member fraction ball lending process in the card unit 200. In the card unit 200, when there is a ball lending operation in a state where the remaining amount of the membership card 8 is a fractional amount, in Sb13 of FIG. 19, steps Sg (hereinafter simply referred to as “Sg”) 1-13. Thus, a subroutine for member fraction lending processing is performed.

  Here, the processing of Sg1 to Sg13 is substantially the same as the processing of Sd19 to Sd31 in FIG. However, in Sg9 corresponding to Sd27 in FIG. 21, the remaining amount of the membership card 8 is set to zero by the membership card R / W 290. In Sg13 corresponding to Sd31 in FIG. 21, the fractional amount calculated in Sb8 is transmitted to the system controller 10 as the ball lending usage amount.

  Next, FIG. 25 is a flowchart showing an example of pre-business start processing in the pachinko machine 100. In the pachinko machine 100, after the power of the pachinko machine 100 is turned on, pre-business start processing is performed in steps Sh (hereinafter simply referred to as “Sh”) 1 to 13.

  Specifically, first, in Sh1, when the connection is confirmed with the card unit 200 via the PSI signal line, the payment is made to the unit control unit 220 of the card unit 200 via the PRDY signal line in Sh2. Transmit possible signal and go to Sh3.

  In Sh3, as shown in FIG. 15 (a1), chip ID transmission transmitted from the corresponding card unit 200 via a display data signal line (here, SEGG signal line) functioning as a chip ID transmission request signal line. Wait for a request to be received. If it is determined at this Sh3 that a chip ID transmission request has been received (YES), the payout control board 160 acquires the chip ID stored in the ROM 151b of the main board 150 at Sh4, and at Sh5 the predetermined ID is obtained. A timer T for measuring time is set, and in Sh6, the chip ID acquired in Sh4 is stored in the dispensing control board 160, and the process proceeds to Sh7.

  In Sh7, as shown in FIG. 15A1, the stored chip ID is stored in the corresponding card unit 200 via a display data signal line (here, SEGG signal line) that functions as a chip ID signal line. Send to Sh8. According to this, via the display data signal line included in the signal line connecting the conventional pachinko machine 100 having the remaining frequency indicator 121 and the conventional card unit 200 corresponding to the pachinko machine 100, Since the chip ID of the board 150 is transmitted to the card unit 200, it is not necessary to add a new signal line for transmitting the chip ID, and a new interface corresponding to the signal line on the pachinko machine 100 side. There is no need to add.

  In Sh8, as shown in FIG. 15 (b1), the disable signal is received from the corresponding card unit 200 via the display data signal line (here, the SEGG signal line) functioning as the disable signal line. Judge whether or not. If it is determined in Sh8 that the disabling signal has not been received (NO), it is determined in Sh11 whether or not the timer T set in Sh5 is timed out. Here, when it is determined that a timeout has occurred, the chip ID is transmitted to the card unit 200, but the disable signal cannot be received from the card unit 200. The case where the chip ID cannot be transmitted is included. If it is determined that the timeout has not occurred (NO) in Sh11, the process returns to the Sh8 and waits for reception of the disable signal.

  On the other hand, if it is determined that a timeout has occurred (YES) in Sh11, the chip ID stored in Sh6 is erased in Sh12 and the process proceeds to Sh13. According to this, the chip ID stored in the dispensing control board 160 is erased on the condition that a predetermined time has elapsed since the dispensing control board 160 obtained the chip ID from the main board 150. Even when the chip ID cannot be transmitted to the card unit 200, the possibility that the chip ID is illegally acquired from the storage in the payout control board 160 is significantly reduced. In Sh13, the game operation is activated and the pre-business start processing is terminated.

  If it is determined in Sh8 that the disabling signal has been received (YES), the chip ID stored in Sh6 is erased in Sh9 and the process proceeds to Sh10. According to this, the chip ID stored in the dispensing control board 160 is erased on condition that the chip ID acquired by the dispensing control board 160 from the main board 150 is transmitted to the card unit 200. While it is possible to prevent an illegal signal from being input to the main board 150 from the card unit 200, the possibility that the chip ID is illegally acquired from the memory in the payout control board 160 is significantly reduced. In Sh10, the game operation is disabled and the pre-business start processing is terminated. According to this, since the control regarding the game is disabled on condition that the verification of the chip IDs does not match, the game can be completely prevented even when it is replaced with an unauthorized main board 150. That is, it is possible to completely prevent a game by bringing a pachinko ball or the like, or a game by a so-called double sand (a ball lending device provided separately from the card unit 200).

  Next, FIG. 26 is a flowchart showing an example of ball lending control in the pachinko machine 100. In the pachinko machine 100, ball lending control is performed in steps Si (hereinafter simply referred to as “Si”) 1 to 16 during the operation of the game hall 2.

  Specifically, first, Si1 waits for reception of a ball lending possible signal transmitted from the unit control unit 220 of the card unit 200 via the BRDY signal line. If it is determined that the ball lending signal is received at Si1 (YES), the display data signal line is displayed at Si2 during the period T4 ′, which is the non-input period of the strobe signal, as shown in FIG. It is determined whether or not a ball lending number designation signal transmitted from the unit control unit 220 of the card unit 200 is received via the SEGA signal line to SEGD signal line functioning as a lending number designation signal line. .

  If it is determined that the ball lending number designation signal is not received at Si2 (NO), the unit ball lending request signal transmitted from the unit control unit 220 of the card unit 200 via the BRQ signal line at Si3. It is determined whether or not there is reception. If it is determined that the unit ball lending request signal is not received in Si3 (NO), the unit control unit of the card unit 200 via the BRDY signal line after the ball lending for the set frequency is completed in Si9. It is determined whether or not a ball lending end signal transmitted from 220 is received. If it is determined that no ball lending end signal is received (NO) in Si9, the process returns to Si2 to lend the ball. Waiting for the reception of the number designation signal, the reception of the unit lending request signal, or the reception of the ball lending end signal, and if it is determined in Si9 that the ball lending end signal is received (YES), RETURN is performed.

  If it is determined that the unit ball lending request signal is received in Si3 (YES), whether or not the ball confirmation sensor 171 is ready to lend a pachinko ball for several times in Si4 (ie, Whether or not there is a pachinko ball to be supplied to the ball dispensing device 170), and on condition that the preparation is complete, the unit control unit 220 of the card unit 200 via SiS and the EXS signal line. A unit ball lending preparation signal is transmitted to S6 and the process proceeds to Si6. When the preparation is not completed, the unit ball lending preparation signal is not transmitted.

  In Si6, it waits for reception of the unit ball lending command signal transmitted from the unit controller 220 of the card unit 200 via the BRQ signal line. When it is determined that the unit ball lending command signal is received at Si6 (YES), at S7, the ball dispensing device 170 pays out and lends a number of pachinko balls (here 25), In Si8, a unit ball lending completion signal is transmitted to the unit controller 220 of the card unit 200 via the EXS signal line, and the process returns to the Si3. When the ball lending for the set number of times ends, the unit lending request signal is transmitted instead of the unit ball lending request signal from the unit control unit 220 of the card unit 200, so it is determined NO in the Si3, and in the Si9 It is determined YES and RETURN is performed.

  If it is determined at Si2 that the ball lending number designation signal is received via the display data signal line during the period T4 ', which is the non-input period of the strobe signal (YES), the process proceeds to Si10. According to this, since the ball lending number designation signal is received through the display data signal line during the non-input period of the strobe signal, it is necessary to add a new signal line for receiving the ball lending number designation signal. In addition to not adding a new interface corresponding to the signal line on the pachinko machine 100 side, not only is it possible to lend the number of pachinko balls indicated by the ball lending number designation signal in the fraction-compatible gaming machine, Compatibility with conventional gaming machines can also be ensured. In addition, since the ball lending number designation signal is received during the non-input period of the strobe signal, the display of the remaining frequency indicator 121 is not affected.

  In Si10, reception of the fraction lending request signal transmitted from the unit control unit 220 of the card unit 200 via the SAGE signal line functioning as a fraction lending request signal line among the display data signal lines is waited. If it is determined that no fractional ball lending request signal has been received within a predetermined time in Si10 (NO), the ball lending process is terminated. On the other hand, if it is determined that the fractional ball lending request signal is received at Si10 (YES), the ball confirmation sensor 171 is ready to lend the number of pachinko balls indicated by the ball lending number designation signal at Si11. (I.e., whether there is a pachinko ball supplied to the ball dispensing device 170), and on the condition that the preparation is complete, the fractional ball of the display data signal line at Si12 A fraction lending preparation signal is transmitted to the unit controller 220 of the card unit 200 via the SEGF signal line functioning as a lending preparation signal line, and the process proceeds to Si13. When the preparation is not complete, the fraction lending preparation signal is not transmitted.

  In Si13, reception of the fraction lending command signal transmitted from the unit controller 220 of the card unit 200 via the SAGE signal line functioning as a fraction lending command signal line among the display data signal lines is waited. If it is determined that no fraction ball lending command signal has been received within a predetermined time in Si13 (NO), the ball lending process is terminated. On the other hand, if it is determined that there is a fractional ball lending command signal received at Si13 (YES), the ball payout device 170 pays out and lends the number of pachinko balls indicated by the ball lending number designation signal at Si14, In Si15, a fraction lending completion signal is transmitted to the unit controller 220 of the card unit 200 via the SEGF signal line functioning as a fraction lending completion signal line of the display data signal lines, and the process proceeds to Si16. These processes of Si10 to Si15 are performed within one cycle of T4 'period.

  In this way, the transmission / reception (so-called handshake) of the fraction loan request signal, the fraction loan preparation signal, and the fraction loan command signal is performed. Since there is no need to receive a lending command in a state where it is not ready to lend, and transmission and reception of signals therefor are performed via the display data signal line, there is no need to add a new signal line and the gaming machine Therefore, it is not necessary to add a new interface corresponding to the signal line on the side, and compatibility with a conventional gaming machine can be ensured.

  In Si16, it waits for the reception of the ball lending end signal transmitted from the unit controller 220 of the card unit 200 via the BRDY signal line. If it is determined that the ball lending end signal has been received in Si16 (YES), RETURN is performed.

  Next, FIG. 27 is a flowchart showing an example of the operating chip ID transmission process in the pachinko machine 100. In the pachinko machine 100, during the business of the game hall 2, the business chip ID transmission process is performed in steps Sj (hereinafter simply referred to as “Sj”) 1 to 10.

  Here, the processing of Sj1 to Sj8 is substantially the same as the processing of Sh3 to Sh10 in FIG. However, in Sj1, as shown in FIG. 15 (a2), the display data signal line (here, SEGG signal line) functioning as a chip ID transmission request signal line is passed in the T4 ′ period which is a non-input period of the strobe signal. The chip ID transmission request is received from the corresponding card unit 200. In Sj5, as shown in FIG. 15A2, the display data signal line (herein, the SEGG signal line) functioning as a chip ID signal line in the T4 ′ period which is a non-input period of the strobe signal, A chip ID is transmitted to the corresponding card unit 200. According to this, the reception of the chip ID transmission request from the card unit 200 and the transmission of the chip ID to the card unit 200 are performed during the non-input period of the strobe signal, thereby affecting the display of the remaining frequency indicator 121. Since it is not given, the time restriction for verifying the chip ID is relaxed. In other words, the verification of the chip ID can be performed not only before the game hall 2 starts business or after the business ends, but also during the game hall 2 business.

  Further, in Sj6, as shown in FIG. 15 (b2), through the display data signal line (herein, the SEGG signal line) functioning as an immobilization signal line in the T4 ′ period which is the non-input period of the strobe signal. The inactivation signal is received from the corresponding card unit 200. According to this, the immobilization signal is received from the card unit 200 during the non-input period of the strobe signal, so that the display of the remaining frequency indicator 121 is not affected. After the processing of Sj8, the operating chip ID transmission processing is terminated.

  Moreover, since the process of Sj9-Sj10 is the same as the process of Sh11-Sh12 in the said FIG. 25, description is abbreviate | omitted. After the processing of Sh12, since the gaming operation has already been activated in the processing of Sh13 in FIG. 25, the operating chip ID transmission processing is terminated without newly activating the gaming operation.

  Finally, FIG. 28 is a diagram illustrating an example of the operation of the gaming system 1 according to the first embodiment. First, in the gaming system 1, when the pachinko machine 100 is delivered, the processes of S00 to S24 shown in FIG. Specifically, the center server 20 first acquires the delivery chip ID list shown in FIG. 2 from the gaming machine manufacturer 4 (S00). Next, when the system controller 10 receives the chip ID acquisition operation shown in FIG. 3A by the operation of the store clerk in the game hall 2 (S10), the system controller 10 transmits a chip ID acquisition request to each card unit 200. (S11). The card unit 200 that has received the chip ID acquisition request transmits the chip ID to the corresponding pachinko machine 100 via the display data signal line (SEGG signal line) as shown in FIG. 15 (a1). Is requested (S12). The pachinko machine 100 that has received the chip ID acquisition request acquires the chip ID from the main board 150 and stores the acquired chip ID in the payout control board 160 (S13), as shown in FIG. 15 (a1). In addition, the stored chip ID is transmitted to the corresponding card unit 200 via the display data signal line (SEGG signal line) (S14). The card unit 200 that has received the chip ID stores the acquired chip ID in the card R / W control unit 230 (S15), and stores the stored serial number of the corresponding pachinko machine 100 and the system controller 10 The chip ID is transmitted (S16).

  The system controller 10 that has received the unit number and the chip ID creates an installation chip ID list shown in the table of FIG. 3A (S17), and sends the created installation chip ID list to the center server 20, The game hall 2 is transmitted together with identifiable information (S18). The center server 20 that has received the installed chip ID list collates as described above based on the delivery chip ID list acquired in S00 and the received installed chip ID list. Is created and stored in the hard disk 25 (S19), and the creation completion of the collation chip ID list is transmitted to the system controller 10 (S20). The system controller 10 that has received the creation completion transmits the creation completion to each card unit 200 (S21).

  The card unit 200 that has received the creation completion erases the chip ID stored in S15 (S22), and replaces the disable signal shown in FIG. 15B1 with a display data signal line (SEGG signal line). Then, the completion of work is transmitted to the corresponding pachinko machine 100 (S23). The pachinko machine 100 that has received the completion of the operation deletes the chip ID stored in S13 (S24) and ends the process.

  Next, in the gaming system 1, before the game hall 2 starts business, the processing of S30 to S51 shown in FIG. Specifically, the center server 20 first transmits a chip ID acquisition request to the system controller 10 when the chip ID request time set in 5 (a) is reached (S30). Receiving the chip ID acquisition request, the system controller 10 transmits a chip ID acquisition request to each card unit 200 (S31). The card unit 200 that has received the chip ID acquisition request transmits the chip ID to the corresponding pachinko machine 100 via the display data signal line (SEGG signal line) as shown in FIG. 15 (a1). Is requested (S32). The pachinko machine 100 that has received the chip ID acquisition request acquires the chip ID from the main board 150 and stores the acquired chip ID in the payout control board 160 (S33), as shown in FIG. 15 (a1). The stored chip ID is transmitted to the corresponding card unit 200 via the display data signal line (SEGG signal line) (S34). The card unit 200 that has received the chip ID stores the acquired chip ID in the card R / W control unit 230 (S35), and stores the stored serial number of the corresponding pachinko machine 100 with respect to the system controller 10. The chip ID is transmitted (S36).

  The system controller 10 that has received the unit number and the chip ID creates an installation chip ID list shown in the table of FIG. 3B (S37), and transmits the created installation chip ID list to the center server 20. (S38). The center server 20 that has received the installed chip ID list checks whether or not the received installed chip ID list matches the verification chip ID list created and stored in S19 (S39). On the other hand, the verification result of verification OK or verification NG for each pachinko machine 100 is transmitted (S40). The system controller 10 that has received the verification result transmits the verification result to each card unit 20 (S41).

  The card unit 200 that has received the verification result deletes the chip ID stored in S35 (S42). Here, when the collation result transmitted in S41 is collation OK, the card unit 200 activates the ball lending process (S43), and does not transmit the immobilization signal to the corresponding pachinko machine 100. (S44). In the pachinko machine 100 that does not receive the disable signal, the chip ID stored in S33 is erased (S45), the gaming operation is activated (S46), and the process is terminated.

  On the other hand, when the collation result transmitted in S41 is collation NG, the card unit 200 disables the ball lending process (S43), and the corresponding pachinko machine as shown in FIG. 15 (b1). A disabled signal is transmitted to 100 via a display data signal line (SEGG signal line) (S48). In the pachinko machine 100 that has received the disable signal, the chip ID stored in S33 is erased (S49), the game operation is disabled (S50), and the process ends.

  If the collation result transmitted in S40 is collation NG, the system controller 10 notifies that the collation is NG (S51). If the collation result in S39 is collation NG, the center server 20 notifies that the collation is NG, and reports a mismatched chip ID to the gaming machine manufacturer 4 (S52).

  Next, in the gaming system 1, the processing of S61 to S79 shown in FIG. Specifically, first, when the system controller 10 reaches the timing set in FIG. 3B or receives a chip ID acquisition request in FIG. Then, a chip ID acquisition request is transmitted (S61). The card unit 200 that has received the chip ID acquisition request sends a strobe signal to the corresponding pachinko machine 100 via the display data signal line (SEGG signal line) as shown in FIG. During the transmission period, the transmission of the chip ID is requested (S62). The pachinko machine 100 that has received the chip ID acquisition request acquires the chip ID from the main board 150 and stores the acquired chip ID in the payout control board 160 (S63), as shown in FIG. 15 (a2). In addition, the stored chip ID is transmitted to the corresponding card unit 200 through the display data signal line (SEGG signal line) during the non-input period of the strobe signal (S64). Upon receiving the chip ID, the card unit 200 stores the acquired chip ID in the card R / W control unit 230 (S65), and stores the stored serial number of the corresponding pachinko machine 100 with respect to the system controller 10. The chip ID is transmitted (S66).

  The system controller 10 that has received the unit number and the chip ID creates an installation chip ID list shown in the table of FIG. 3B or FIG. 3C (S67), and creates it for the center server 20. The installed chip ID list is transmitted (S68). The center server 20 that has received the installed chip ID list checks whether or not the received installed chip ID list matches the verification chip ID list created and stored in S19 (S69). On the other hand, the verification result of verification OK or verification NG for each pachinko machine 100 is transmitted (S70). The system controller 10 that has received the verification result transmits the verification result to each card unit 20 (S71).

  The card unit 200 that has received the verification result erases the chip ID stored in S65 (S72). Here, when the collation result transmitted in S71 is collation OK, the card unit 200 does not transmit the disable signal to the corresponding pachinko machine 100 (S73). In the pachinko machine 100 that does not receive the disable signal, the chip ID stored in S63 is erased (S74), and the process ends.

  On the other hand, when the collation result transmitted in S71 is collation NG, the card unit 200 disables the ball lending process (S75), and the corresponding pachinko machine as shown in FIG. 15 (b2). A disable signal is transmitted to 100 during the non-transmission period of the strobe signal via the display data signal line (SEGG signal line) (S76). In the pachinko machine 100 that has received the disable signal, the chip ID stored in S63 is erased (S77), the game operation is disabled (S78), and the process ends.

  When the collation result transmitted in S70 is collation NG, the system controller 10 notifies that the collation is NG (S79). If the collation result in S69 is collation NG, the center server 20 informs that it is collation NG and reports a mismatched chip ID to the gaming machine manufacturer 4 (S80).

  As described above, according to the gaming system 1 of the present invention, the conventional pachinko machine 100 including the remaining frequency indicator 121 and the conventional card unit 200 corresponding to the pachinko machine 100 are connected. Since the card unit 200 acquires the chip ID of the main board 150 from the pachinko machine 100 via the display data signal line included in the signal line, it is not necessary to add a new signal line for acquiring the chip ID. In addition, it is not necessary to add a new interface corresponding to the signal line on the pachinko machine 100 side. Therefore, for the pachinko machine 100 having the function of transmitting the chip ID while ensuring compatibility with the conventional gaming machine that does not have the function of transmitting the chip ID, by checking the chip ID, The ball lending process is disabled in the card unit 200 corresponding to the pachinko machine 100 replaced with the unauthorized main board 150, and the operation of the pachinko machine 100 is disabled. Game can be prevented.

  Moreover, according to the pachinko machine 100 according to the present invention, display data included in a signal line connecting the conventional pachinko machine 100 including the remaining frequency indicator 121 and the conventional card unit 200 corresponding to the pachinko machine 100. Since the chip ID of the main board 150 is transmitted to the card unit 200 via the signal line, it is not necessary to add a new signal line for transmitting the chip ID, and the signal is generated on the pachinko machine 100 side. There is no need to add a new interface for the line. Therefore, for the pachinko machine 100 having a function of transmitting a chip ID while ensuring compatibility with a conventional gaming machine that does not have a function of transmitting a chip ID, the chip ID can be verified. .

[2. Game System 1 ′ According to Second Embodiment]
Next, with reference to FIG. 1, the configuration of a gaming system 1 ′ according to the second embodiment will be described. The gaming system 1 ′ according to the second embodiment is different from the gaming system 1 according to the first embodiment in that the system controller 10 ′ is replaced with the system controller 10 and the center server 20 ′ is replaced with the center server 20. The other points are the same.

  Compared with the system controller 10 according to the first embodiment, the system controller 10 ′ according to the second embodiment replaces the hard disk 15 with a hard disk 15 ′, replaces the control unit 12 with a control unit 12 ′, and an in-field communication unit 11b. It is different in that the in-field communication unit 11b ′ and the out-of-field communication unit 11a are replaced with the out-of-field communication unit 11a ′, and the other points are the same.

  Similar to the hard disk 15 according to the first embodiment, the hard disk 15 ′ according to the second embodiment stores a sales management DB and a remaining amount management DB illustrated in FIG. 4. Further, unlike the hard disk 15 according to the first embodiment, the hard disk 15 ′ according to the second embodiment is an example of identification information storage means, and stores the chip ID of each pachinko machine 100 delivered to the game hall. In addition, it is an example of a transmission permission / inhibition storage means, and stores whether each pachinko machine 100 installed in the game hall 2 has a function of transmitting a chip ID (identification information transmission function). Yes, the collation chip ID list shown in FIG. 6 is stored here. This verification chip ID list is created and stored in the center server 20 ′ in the same manner as in the first embodiment, transmitted from the center server 20 ′ to the system controller 10 ′, and in the system controller 10 ′. Remembered.

  Unlike the control unit 12 according to the first embodiment, the control unit 12 ′ according to the second embodiment is an example of a verification unit, and is transmitted from the identification information transmission unit (card R / W control unit 230). Chip IDs (here, the installed chip ID lists shown in the tables of FIGS. 3B and 3C created based on the chip IDs) are stored in the identification information storage means (hard disk 15 ′). Whether or not it matches (here, the chip ID list for verification shown in FIG. 6) is verified. Specifically, the control unit 12 ′ is installed in the chip ID (that is, the game hall 2) recorded in association with the machine number in the installation chip ID list shown in the tables of FIGS. 3B and 3C. The chip ID acquired from the pachinko machine 100) is stored in the chip ID (that is, the pachinko machine 100 delivered to the game hall 2) that is recorded in the matching chip ID list shown in FIG. It is verified for each chip ID whether or not it matches the regular chip ID).

  Unlike the in-field communication unit 11b according to the first embodiment, the in-field communication unit 11b ′ according to the second embodiment is an example of a verification result transmitting unit, and the verification result by the verification unit (control unit 12 ′) is obtained. This is transmitted to the card unit 200 that is the transmission source of the chip ID. Specifically, the on-site communication unit 11b ′ determines the verification result (verification OK) to the card unit 200 that is the transmission source of each chip ID according to the verification result by the control unit 12 ′. ) Or a verification result (verification NG) indicating that the chip IDs do not match.

  The in-field communication unit 11b ′ according to the second embodiment is an example of the identification information transmission impossible information transmission unit, unlike the in-field communication unit 11b according to the first embodiment, and includes the transmission availability storage unit (hard disk 15 ′. ) (In this case, the matching chip ID list shown in FIG. 6), the corresponding pachinko machine 100 identifies the card unit 200 corresponding to the pachinko machine 100 having no identification information transmission function. Identification information transmission impossibility information indicating that the information transmission function is not provided is transmitted. Specifically, the on-site communication unit 11b ′, before the game hall 2 starts business, the card unit 200 corresponding to the pachinko machine 100 of the serial number in which a cross is recorded in the verification chip ID list shown in FIG. In contrast, identification information transmission impossible information is transmitted.

  Unlike the out-of-field communication unit 11a according to the first embodiment, the out-of-field communication unit 11a ′ according to the second embodiment receives the verification chip ID list shown in FIG. 6 from the center server 20 ′ as described above, and the control unit When the collation result by 12 ′ is collation NG, the mismatched chip ID is reported to the center server 20 ′.

  Compared with the center server 20 according to the first embodiment, the center server 20 ′ according to the second embodiment replaces the hard disk 25 with a hard disk 25 ′, replaces the control unit 22 with a control unit 22 ′, and a communication unit 21. Instead of providing a communication unit 21 ', the other points are the same.

  Similar to the hard disk 25 according to the first embodiment, the hard disk 25 ′ according to the second embodiment stores the verification chip ID list shown in FIG. 6, but unlike the hard disk 25 according to the first embodiment, It does not function as the identification information storage means and the transmission permission / inhibition storage means. That is, the stored verification chip ID list is not used for verification of chip IDs, and is not used for transmission of identification information transmission impossible information.

  Unlike the control unit 22 according to the first embodiment, the control unit 22 ′ according to the second embodiment does not function as a verification unit. Also, the communication unit 21 ′ according to the second embodiment does not function as the collation result transmission unit and the identification information transmission impossibility information transmission unit, unlike the communication unit 21 according to the first embodiment.

  Next, with reference to FIG. 29, the operation of the gaming system 1 'according to the second embodiment will be described. First, in the gaming system 1 ′, the processes of S00 to S24 shown in FIG. 29 are performed when the pachinko machine 100 is delivered. Specifically, first, the same processing as S00 to S19 shown in FIG. 28 is performed, and after the processing of S19, the center server 20 ′ makes a verification for the system controller 10 ′ created in S19. A chip ID list is transmitted (S20 ′). The system controller 10 ′ that has received the verification chip ID list stores the received verification chip ID list in the hard disk 15 ′ and deletes the installed chip ID list created in S17 (S21 ′). After the processing of S21 ′, the same processing as S21 to S24 shown in FIG. 28 is performed, and the processing is terminated.

  Next, in the gaming system 1 ′, the processing of S <b> 30 to S <b> 52 ′ shown in FIG. Specifically, first, processing similar to S30 to S37 shown in FIG. 28 is performed, and after the processing of S37, the system controller 10 ′ stores the installed chip ID list created in S37 in S21 ′. Whether or not it matches with the verification chip ID list is verified, the installed chip ID list created in S37 is deleted (S38 '), and the verification result is transmitted to each card unit 20 (S41). After the processing of S41, processing similar to S42 to S50 shown in FIG. 28 is performed, and the processing is terminated.

  When the collation result in S38 ′ is collation NG, the system controller 10 ′ notifies the collation NG, and reports a mismatched chip ID to the center server 20 ′ (S51 ′). ). Receiving the report, the center server 20 'informs that it is a verification NG, and reports a mismatched chip ID to the gaming machine manufacturer 4 (S52').

  Next, in the gaming system 1 ′, the processing of S <b> 61 to S <b> 80 ′ shown in FIG. Specifically, first, the same processing as S61 to S67 shown in FIG. 28 is performed, and after the processing of S67, the system controller 10 ′ stores the installed chip ID list created in S67 in S21 ′. Whether or not it matches with the verification chip ID list is verified, the installed chip ID list created in S67 is deleted (S68 '), and the verification result is transmitted to each card unit 20 (S71). After the processing of S71, processing similar to S72 to S78 shown in FIG. 28 is performed, and the processing is terminated.

  When the collation result in S68 ′ is collation NG, the system controller 10 ′ informs that the collation is NG and reports a mismatched chip ID to the center server 20 ′ (S79 ′). ). Receiving the report, the center server 20 'informs that the verification is NG, and reports a mismatched chip ID to the gaming machine manufacturer 4 (S80').

  According to the gaming system 1 ′ according to the second embodiment described above, the regular chip ID of each pachinko machine 100 delivered to each gaming hall 2 is sent from the center server 20 ′ to the system controller 10 ′. Since the system controller 10 ′ collates the chip ID based on the transmitted chip ID that has been transmitted and stored, the system controller 10 ′ has to input the regular chip ID of each pachinko machine 100. Can be omitted.

[3. Modified example]
Finally, a modification of the present invention will be described.

  In the above embodiment, as shown in FIG. 28 and FIG. 29, when the verification results by the verification means (control unit 22, control unit 12 ′) do not match, the lending process in the gaming device (card unit 200) is impossible. Although the example in which both the activation and the disabling of the game operation in the gaming machine (pachinko machine 100) are described has been described, the present invention is not limited to this, and the disabling of the lending process or the disabling of the game operation is performed. The present invention includes only one of them.

  In the above embodiment, as shown in FIG. 1, the example in which the gaming machine is the pachinko machine 100 has been described. However, the gaming machine is not limited to this example, and the gaming machine is, for example, a slot machine that uses medals as gaming media, A pachinko slot machine that uses a pachinko ball as a game machine, a pachinko machine with a pachinko ball that is a non-touchable game medium, and a pachinko that can be played using score data without using pachinko balls or medals It may be a machine, a slot machine, an image-type pachinko machine in which game areas and pachinko balls are displayed as images, an image-type slot machine in which reels are displayed as images, and the like.

  In the above-described embodiment, an example in which the lending process is a ball lending process that lends a pachinko ball has been described. However, the lending process is not limited to this, and the lending process includes a medal lending process that lends the medal or the image expression In a pachinko machine or a slot machine, a process of converting the value of the valuable value into a score as a game medium and using it in a game may be used.

  In the first embodiment described above, as shown in FIG. 6, an example in which the hard disk 25 of the center server 20 is a transmission availability storage unit and the communication unit 21 is an identification information transmission impossibility information transmission unit has been described. Not limited to this, the transmission permission / inhibition storage means may be the hard disk 15 of the system controller 10, and the identification information non-transmission information transmission means may be the in-field communication unit 11b. In contrast, in the second embodiment, the hard disk 15 ′ of the system controller 10 ′ is a transmission permission / non-transmission storage unit, and the on-site communication unit 11b ′ is an identification information transmission impossibility information transmission unit. However, the present invention is not limited thereto. Alternatively, the transmission enable / disable storage means may be the hard disk 25 ′ of the center server 20 ′, and the identification information transmission impossible information transmission means may be the communication unit 21 ′.

  In the above embodiment, as shown in FIG. 7, the example in which both the banknote 5 and the coin 6 can be used as money has been described. However, the present invention is not limited thereto, and only one of the banknote 5 or the coin 6 is used. It may be usable. Moreover, in said embodiment, only the member player can use a large amount banknote (2000 yen banknote, 5000 yen banknote, and 10000 yen banknote) as the banknote 5, and a visitor player can use only 1000 yen banknote. Although an example has been described, the present invention is not limited to this, and a visitor player may be able to use a highly accurate banknote. Conversely, a member player may be able to use only a 1000 yen banknote.

  In the above embodiment, as shown in FIG. 7, an example in which only a 500 yen coin can be used as the coin 6 has been described. However, the present invention is not limited to this, and a 100 yen coin may be used as the coin 6. In this case, when a 100-yen coin is deposited in a state where the membership card 8 is not accepted, the 100-yen is less than one degree (ie, 105 yen), so in the visitor ball lending process shown in FIG. The process proceeds to Sd16 without going through Sd6 to Sd15 and Sd17.

  In the above embodiment, as shown in FIG. 7, the currency (banknote 5, coin 6) received by the currency receiving means (banknote discriminator 240, coin discriminator 250) is placed outside the gaming apparatus (card unit 200). Although the example discharged | emitted and conveyed by the banknote conveyance mechanism and the coin conveyance mechanism was demonstrated, not only this but the received money may be made to store inside the game device.

  In the above embodiment, as illustrated in FIG. 7, an example in which the receipt of money (banknote 5, coin 6), which is a tangible object, has been described in the currency reception unit (banknote identification machine 240, coin identification machine 250). Not limited to this, contact with deposits of intangible money (for example, money data such as electronic money, money amount specified from a credit card, deposit amount specified from a debit card, etc.) You may make it accept without contact.

  In the above embodiment, as shown in FIG. 7, the example in which the game recording medium accepted in the gaming apparatus (card unit 200) is the membership card 8 has been described. However, the present invention is not limited to this, and the game recording medium May be a prepaid card in which information that can specify the magnitude of the valuable value that can be used in the game is recorded.

  In the above embodiment, as shown in FIG. 8C, an example in which a fractional amount (55 yen in this case) is displayed on the remaining frequency indicator 121 has been described. In the device 121, the number of game media (for example, 14) corresponding to the fractional amount specified by the game media number specifying means (unit control unit 220) may be displayed. You may comprise so that display of the number of media can be switched.

  In the above embodiment, as shown in FIG. 9, the identification information (chip ID) stored in the game arithmetic processing device (main board 150) is transferred from the game arithmetic processing device to the relay device (payout control board 160). ) And the display data signal line (SEGG signal line) are transmitted to the gaming device (card unit 200). However, the present invention is not limited to this, and the identification information does not pass through the relay device. The game processing device may be transmitted to the game device via the display data signal line.

  In the above embodiment, the game medium number specifying means (unit control unit 220) shown in FIG. 10 specifies the number of game media by rounding up the number of game media less than one calculated based on the fractional amount (ie, 4). .For the fractional amount less than 2 yen, the pachinko ball was lent out at the expense of the game hall 2), but not limited to this, rounding down the number of game media less than one calculated based on the fractional amount The number of game media may be specified (that is, for a fractional amount less than 4.2 yen, a pachinko ball is not lent as a player's burden). The system controller 10 sets whether the fractional amount less than 4.2 yen is to be borne by the game hall 2 or the player and is transmitted to the gaming device (card unit 200). And the number of game media may be specified based on the stored contents.

  In the above embodiment, an example in which the game medium number specifying means (unit control unit 220) is provided in the gaming device (card unit 200) and the number of ball lending is specified in the gaming device has been described. However, the present invention is not limited to this, and the system controller 10 may be provided with means for specifying the number of game media, and the system controller 10 may specify the number of balls lent and notify the gaming device of the specified number of balls lent. .

  In the above-described embodiment, as illustrated in FIG. 11B, the example in which the control for extending the T4 period to the T4 ′ period is performed as the control for extending the T4 period that is the non-transmission period of the strobe signal has been described. However, the present invention is not limited to this. For example, control for extending the T4 period may be performed by changing the duty ratio between the T1 period and the T2 period in the T3 period that is one cycle, or the T3 period itself that is one cycle. May be extended.

  In the above embodiment, as shown in FIG. 11B, an example in which control is performed to extend the T4 period, which is the non-transmission period of the strobe signal, to the T4 ′ period while the fraction lending process is performed. In FIG. 17, the T4 ′ period when the ball lending number designation signal is transmitted, and the fraction lending request signal, the fraction lending preparation signal, the fraction lending command signal, and the fraction lending completion signal are transmitted and received. In such a case, the control may be performed so that the T4 ′ period is different (ie, S3 to S6). In other words, the T4 'period obtained by extending the non-transmission period of the strobe signal may be a period that can reduce the possibility that a signal transmitted / received during the T4' period will be lost on the gaming machine side.

  In the above embodiment, as shown in FIG. 12, the unit ball lending request signal line and the unit ball lending command signal line are described as the same signal line (BRQ signal line). The unit ball lending request signal line and the unit ball lending command signal line may be separate signal lines.

  In the above embodiment, as shown in FIG. 14, a signal input circuit (reception photocouplers 431 to 437) is provided on the gaming device (card unit 200) side, and a signal is sent to the gaming machine (pachinko machine 100) side. An example has been described in which an output circuit (transmission photocouplers 331 to 337) and a signal input circuit (reception photocouplers 321 to 327) are provided, and so-called handshake is performed via the display data signal line. Not limited to this, if the handshake is not performed, a signal output circuit on the gaming apparatus side for transmitting a chip ID transmission request, an immobilization signal, and a ball lending number designation signal, and a chip ID are received. Game device side signal input circuit, gaming machine side signal output circuit for transmitting chip ID, chip ID transmission request, disabling signal, and ball lending number designation A signal input circuit on the gaming machine side for receiving the signal is sufficient, and no other signal output circuit and signal input circuit on the gaming machine side or other signal output circuit and signal input circuit on the gaming machine side are required. is there. That is, the signal output circuit and signal input circuit on the gaming device side and the signal output circuit and signal input circuit on the gaming machine side need to be provided on all of the seven display data signal lines (SEGA signal line to SEGG signal line). Instead, a necessary number may be provided according to the number of signals to be transmitted and received.

  In the above embodiment, as shown in FIG. 15A, the example in which the chip ID transmission request signal line and the display data signal line functioning as the chip ID signal line are SEGG signal lines has been described. Instead, the chip ID transmission request signal line and the display data signal line functioning as the chip ID signal line may be any of the SEGA signal line to the SEGF signal line, or a combination of the SEGA signal line to the SEGG signal line. . Similarly, in the above-described embodiment, as shown in FIG. 15B, the example in which the display data signal line functioning as the disable signal line is the SEGG signal line has been described. The display data signal line that functions as the activating signal line may be one of the SEGA signal line to the SEGF signal line, or a combination of the SEGA signal line to the SEGG signal line.

  In the above embodiment, as illustrated in FIG. 15A2, the example in which the chip ID is transmitted in one T4 ′ period has been described. However, the present invention is not limited to this, and the chip ID may be transmitted in a plurality of times. It may be divided into T4 ′ periods. Similarly, in the above-described embodiment, as illustrated in FIG. 15 (b2), the example in which the transmission of the immobilization signal is performed in one T4 ′ period has been described. The digitized signal may be transmitted by being divided into a plurality of T4 ′ periods.

  In the above embodiment, as shown in FIG. 17, the display data signal lines functioning as the lending number designation signal lines in the T4 ′ period, which is the non-transmission period of the strobe signal, are four SEGA signal lines to SEGD signal lines. Although an example has been described, the present invention is not limited to this, and the number of display data signal lines functioning as the lending number designation signal line may be five. According to this, even if the number of ball lending is 16 or more, 1 You can specify the number of balls you want to borrow in a cycle. Note that the number of display data signal lines functioning as the loan number designation signal line may be three or less.

  In the above embodiment, as shown in FIG. 17, when the number of balls lent is 16 or more, the number of balls lent is specified in two cycles, and when the number of balls lent is 15 or less, the number of balls lent in one cycle. Although the example of specifying has been described, the present invention is not limited to this, and even when the number of ball lending is 15 or less, the ball lending number designation signal is transmitted in two cycles and the ball lending number designation signal is combined. Thus, the number of balls lent may be specified in two cycles.

  In the above embodiment, as illustrated in FIG. 17, the example in which the fraction lending request signal line and the fraction lending command signal line are the same signal line (SEGE signal line) is described. The fraction loan request signal line and the fraction loan command signal line may be separate signal lines.

  In the above embodiment, the chip ID acquisition process performed during the business of the game hall 2 shown in FIG. 15 (a2), the disablement signal transmission process performed during the business of the game hall 2 shown in FIG. 15 (b2), In the fraction lending process shown in FIG. 17, the example in which the non-transmission period of the strobe signal is extended from the T4 period to the T4 ′ period has been described in order to reduce the possibility of signal loss. If there is no problem of signal loss in step 1, the non-transmission period of the strobe signal does not necessarily have to be extended.

  In the above embodiment, as shown in Sa1 of FIG. 18 and Sh1 of FIG. 25, an example in which connection confirmation is automatically performed when the gaming machine (pachinko machine 100) and gaming device (card unit 200) are turned on. Although described, the present invention is not limited thereto, and connection confirmation may be performed based on a request from either a gaming machine or a gaming device.

  In the above embodiment, as shown in Sa16 of FIG. 18, when it is determined that the identification information transmission impossibility information has been received, an example in which the fraction lending process is not performed has been described. In this case, the member card 8 with the fractional amount remaining as a result of the game on the gaming machine (pachinko machine 100) may be used for the game on the fraction-compatible gaming machine, or may be inserted into the settlement machine. The fractional amount may be returned to the member player.

  In the above embodiment, as shown in FIGS. 18 and 20, identification information (chip ID) is transmitted to the management apparatus (system controller 10), and the verification result (verification OK or verification NG) is sent from the management apparatus. Although the example in which the identification information stored in the gaming device (card unit 200) is erased when the card is received has been described, the present invention is not limited to this, and when the identification information is transmitted to the management device (that is, management) The identification information stored in the gaming apparatus may be erased without waiting for reception of the verification result from the apparatus. That is, the identification information stored in the gaming device may be deleted on condition that the identification information is transmitted to the management device.

  In the above-described embodiment, as illustrated in Sa16 in FIG. 18, the example in which the disabling signal is not transmitted to the gaming machine (pachinko machine 100) on the condition that the identification information transmission impossibility information has been received has been described. However, the present invention is not limited to this, and an activation signal may be transmitted to the gaming machine on condition that the identification information transmission impossibility information has been received.

  In the above-described embodiment, as shown in Sa20 in FIG. 18 and Sc13 in FIG. 20, an immobilization signal is transmitted to the gaming machine (pachinko machine 100) on the condition that the verification result of verification NG has been received. However, the present invention is not limited to this, and the activation signal may be transmitted to the gaming machine (pachinko machine 100) on the condition that the verification result of the verification OK is received.

  In the above embodiment, as the error processing shown in Sa23 in FIG. 18 or Sc16 in FIG. 20, the ball lending process is disabled, and the disablement signal is transmitted to the gaming machine (pachinko machine 100). As described above, instead of these processes or in addition to these processes, the gaming device (card unit 200) may notify that the error has occurred.

  In the above embodiment, as shown in Sb6 of FIG. 19, the remaining card amount recorded on the member card 8 and the remaining card amount managed by the system controller 10 in association with the member ID of the member card 8 Although the example in which the member-unit ball lending process and the member fraction ball lending process are performed based on the remaining card amount recorded in the member card 8 when the collation is performed and the collation is OK is not limited, For example, the member card 8 does not record the remaining amount of the card, but the member unit ball lending process or the member fraction ball lending process is performed based on the card remaining amount managed by the system controller 10 in association with the member ID of the member card 8. On the contrary, the system controller 10 does not manage the remaining amount of the card, and instead, based on the remaining amount of the card recorded in the member card 8, the member unit ball lending And membership fraction ball loan processing may be performed.

  In the above embodiment, as shown in Sb21 to Sb22 of FIG. 19, the example in which the member fraction ball lending process is performed by the ball lending operation is described, but not limited to this, the ball lending operation is not automatically performed. Alternatively, the member fraction ball lending process may be performed.

  In the above embodiment, as shown in FIG. 21, the example in which the visitor ball lending process is performed without relying on the ball lending operation has been described. However, the present invention is not limited to this. Similarly, a visitor ball lending process may be performed by a ball lending operation.

  In the above embodiment, as shown in Sd3 of FIG. 21, an example has been described in which the deposit remaining amount is recorded in the enclosing card 7 and the visitor ball lending process is performed based on the deposit remaining amount recorded in the enclosing card 7. Not limited to this, for example, the deposit amount may be stored in the RAM 223 of the unit controller 220, and the visitor ball lending process may be performed based on the deposit amount stored in the RAM 223 of the unit controller 220. . In this case, the RAM 223 of the unit controller 220 corresponds to a game recording medium. According to this, it is not necessary to provide the enclosing card 7 and the enclosing card R / W 280 in the gaming apparatus (card unit 200).

  In the above embodiment, the example in which the ball rental number is specified by the game medium number specifying unit (unit control unit 220) immediately before the ball rental number designation signal shown in Sd20 of FIG. 21 or Sg4 of FIG. 24 is transmitted. Although described above, the present invention is not limited to this, and the ball lending number may be specified at an arbitrary timing after the calculation of the fractional amount shown in Sb8 of FIG. 19 or Se6 of FIG.

  In the above embodiment, as shown in Sh8 of FIG. 25 and Sj6 of FIG. 27, the game operation signal receiving means (I / O 154d) of the gaming machine (pachinko machine 100) indicates that the chip IDs do not match. The example of waiting for the reception of the immobilization signal transmitted based on (verification NG) has been described, but not limited to this, it is transmitted based on the verification result (verification OK) that the chip IDs match. You may make it wait for reception of the activation signal which comes. In this case, the game processing unit (main board 150) activates the game-related operation of the gaming machine on condition that the activation signal is received.

  In the second embodiment, the example in which the verification chip ID list is created in the center server 20 ′ as shown in S19 of FIG. 29 has been described. However, the present invention is not limited to this, and the verification chip ID list is It may be created in the system controller 10 ′. In this case, the delivery chip ID list shown in FIG. 2 acquired from the gaming machine manufacturer 4 is transmitted from the center server 20 ′ to the system controller 10 ′, and transmitted from the center server 20 ′ in the system controller 10 ′. The verification chip ID list shown in FIG. 6 may be created based on the delivered chip ID list and the installed chip ID list shown in the table of FIG. In this case, the system controller 10 ′ may create a verification chip ID list when rearranging the gaming machine (pachinko machine 100) in the game hall 2.

  In the second embodiment described above, the diagram obtained from the gaming machine manufacturer 4 from the center server 20 ′ to the system controller 10 ′ without creating the verification chip ID list as shown in S19 of FIG. The delivery chip ID list shown in FIG. 2 may be transmitted, and the system controller 10 ′ may collate based on the delivery chip ID list transmitted from the center server 20 ′. In the second embodiment, the chip IDs transmitted from the card units 200 may be sequentially verified without creating the installation chip ID list as shown in S37 and S67 of FIG. .

  In the above embodiment, as shown in FIG. 17, in the fraction lending process, the transmission of the fraction lending request signal, the fraction lending command signal, and the fraction lending preparation signal (so-called handshake) is performed on the display data signal line. However, the present invention is not limited to this, and as shown in FIG. 30, the fraction lending request signal and the fraction lending command signal are transmitted via the BRQ signal line, and the fraction lending preparation signal is transmitted as EXS. You may make it perform handshake by transmitting via a signal wire | line.

  In the above embodiment, as shown in FIG. 30, a gaming machine (pachinko machine 100) that has received a ball lending number designation signal in a non-input period (T4 ′ period) of a strobe signal via a display data signal line The ball lending number confirmation signal indicating the number of pachinko balls indicated by the received ball lending number designation signal in the non-input period of the strobe signal to the device (card unit 200) via the display data signal line Here, a signal having the same waveform as the ball lending number designation signal) may be transmitted via the display data signal line. In this case, in the gaming device performing the visitor ball lending process shown in FIG. 21, after the processing of Sd22 is performed, the ball lending number designation signal is waited for at Sd22 ′ to receive the ball lending number confirmation signal. If it is determined that there is reception (YES), the process may proceed to Sd23. Further, in the gaming device that performs the member fraction ball lending process shown in FIG. 24, after the processing of Sg4 is performed, the reception of the ball lending number confirmation signal is awaited at Sg4 ′, and the ball lending number designation signal is received. If it is determined that there is (YES), the process may proceed to Sg5. Further, in the gaming machine that performs ball lending control shown in FIG. 26, after YES processing is performed in Si2, the ball lending number confirmation is transmitted in Si2 ', and the processing proceeds to Si10.

DESCRIPTION OF SYMBOLS 1 ... Game system 2 ... Game hall 7 ... Enclosed card 8 ... Member card 10 ... System controller 11a ... Out-of-field communication part 12 ... Control part 15 ... Hard disk 20 ... Center server 21 ... Communication part 22 ... Control part 25 ... Hard disk 100 ... Pachinko machine 121 ... Remaining frequency display 121a-121c ... Segment display 150 ... Main board 151 ... Basic circuit 151b ... ROM
151d ... I / O
160 ... Discharge control board 200 ... Card unit 212 ... LED drive circuit 220 ... Unit controller 230 ... Card R / W controller DG1 signal line to DG3 signal line ... Strobe signal line SEGA signal line to SEGG signal line ... Display data signal line

Claims (2)

It provided corresponding to Yu technique machine, using the size of the valuable resource information capable of specifying the size of the valuable resource available to the player is identified from the recorded information of the recorded game recording medium wherein a gaming device including a lending process hand stage of performing lending processing for lending game media from the gaming machine,
An identification that stores identification information that can be communicated with the gaming device and that can individually identify a gaming arithmetic processing device that is mounted on each gaming machine delivered to the game hall and that executes control related to the gaming of the gaming machine A management device comprising information storage means;
A gaming system comprising:
The gaming device is:
An identification information acquiring means for acquiring the identification information stored in on-board the gaming processing unit to the corresponding gaming machine from the corresponding gaming machine,
An identification information transmission means for transmitting the acquired identification information by the identification information acquiring unit to said management apparatus, Bei give a,
The management device
Collation means for collating whether or not the identification information transmitted from the identification information transmission means matches the identification information stored in the identification information storage means;
E Bei a collation result transmitting means for transmitting a verification result by the collating means with respect to the game apparatus which is the source of the identification information, and
The lending processing means disables the lending process on the condition that the matching result indicating that the matching result is not received from the matching result transmitting means is received ,
The management device
Transmission availability storage means for storing whether or not each gaming machine installed in the game hall has a function of transmitting the identification information;
Based on the stored contents of the transmission permission / inhibition storage means, the corresponding gaming machine has a function of transmitting the identification information to a gaming device corresponding to a gaming machine that does not have the function of transmitting the identification information. An identification information transmission impossibility information transmitting means for transmitting identification information transmission impossibility information indicating that it does not,
The gaming device performs the processing by the identification information acquisition unit and the processing by the identification information transmission unit on the condition that the identification information transmission impossibility information is received from the identification information transmission impossibility information transmission unit. A gaming system, wherein the lending processing by the processing means is activated. It provided corresponding to Yu technique machine, using the size of the valuable resource information capable of specifying the size of the valuable resource available to the player is identified from the recorded information of the recorded game recording medium wherein a gaming device including a lending process hand stage of performing lending processing for lending game media from the gaming machine,
An identification that stores identification information that can be communicated with the gaming device and that can individually identify a gaming arithmetic processing device that is mounted on each gaming machine delivered to the game hall and that executes control related to the gaming of the gaming machine A management device comprising information storage means;
A gaming system comprising:
The gaming device is:
An identification information acquiring means for acquiring the identification information stored in on-board the gaming processing unit to the corresponding gaming machine from the corresponding gaming machine,
An identification information transmission means for transmitting the acquired identification information by the identification information acquiring unit to said management apparatus, Bei give a,
The management device
Collation means for collating whether or not the identification information transmitted from the identification information transmission means matches the identification information stored in the identification information storage means;
E Bei a collation result transmitting means for transmitting a verification result by the collating means with respect to the game apparatus which is the source of the identification information, and
The gaming device, subject to the reception of the verification result indicating matching from the verification result sending unit, to the game machine a activation signal for activating the corresponding one of the operation of the gaming machine in which the corresponding to send Te, or the verification result on condition that it has received the collation result that does not match the transmitting unit, the corresponding game machine a deactivation signal for deactivation of the operation of the gaming machine to the corresponding further provided with a game operation signal transmitting means for processing to be transmitted to,
The management device
Transmission availability storage means for storing whether or not each gaming machine installed in the game hall has a function of transmitting the identification information;
Based on the stored contents of the transmission permission / inhibition storage means, the corresponding gaming machine has a function of transmitting the identification information to a gaming device corresponding to a gaming machine that does not have the function of transmitting the identification information. An identification information transmission impossibility information transmitting means for transmitting identification information transmission impossibility information indicating that it does not,
The gaming device performs the processing without the processing by the identification information acquisition unit and the processing by the identification information transmission unit on the condition that the identification information transmission impossibility information is received from the identification information transmission impossibility information transmission unit. A game system, wherein the activation signal is transmitted by the operation signal transmitting means or the disabled signal is not transmitted.

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