JPH07152844A - Automatic transaction device - Google Patents

Abstract

PURPOSE:To provide an automatic transaction device which can return an appropriate transaction medium according to the present transaction processing state when a power failure is detected. CONSTITUTION:The card ejecting conditions are stored in a RAM (not shown in the figure) inside a card reader unit 32 in a user waiting state. Then the card ejecting conditions are changed in response to the transaction processing state while the transaction processing is carried out. When a power supply cut-off state is detected by a power supply cut-off detecting circuit 50, a power supply cut-off signal is supplied to the interruption input terminal of a master CPU 51. The CPU 51 instantaneously transmits a card power failure ejection signal to the interruption terminal of a slave CPU 52. Thus the CPU 52 decide to or not to eject a card based on the present processing stage and the contents of the card ejecting conditions stored in the RAM. Then the CPU 52 actuates a card transfer motor 38 to eject the card when ejection of the card is decided.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic cash transaction system in which, for example, in a financial institution such as a bank, a user inserts a transaction medium such as a card or a passbook and performs an operation to automatically perform a cash payment transaction. The present invention relates to an automatic transaction device such as a payment machine.

[0002]

2. Description of the Related Art In recent years, a cash dispenser that automatically pays cash equivalent to the amount of payment requested by a user by accepting a card provided by the user and communicating online with a host computer (center), or By accepting a passbook and communicating online with the host computer, the cash corresponding to the payment amount requested by the user is automatically paid, or the cash is automatically accepted or the cash is used by using the passbook. Automated teller machines such as automated teller machines (cash deposit / withdrawal devices) that automatically pay money have rapidly developed as automated equipment for bank tellers, and have been introduced to each bank to provide swift service to users. There is.

Recently, in such an automatic transaction device,
When a power failure occurs, there is developed a device having a function of returning a transaction medium such as a passbook or a card, which has been taken into the device and remains, with an auxiliary battery to the user. That is, when the power failure detection means detects a power failure, a power failure detection signal is generated, and the transaction medium carrying motor is connected to the auxiliary battery to be activated by this power failure detection signal to unconditionally discharge the transaction medium. It is to be transported to.

[0004]

However, in the above-described conventional automatic transaction apparatus, when a power failure occurs, a passbook is unconditionally,
Since the transaction medium such as a card is discharged, for example, if a power outage occurs during the recovery of the transaction medium, the user may not be able to receive the transaction medium once the transaction medium is discharged. It may be better not to discharge.

In addition, when operating unmanned on holidays,
When a power failure occurs while rewriting the magnetic data of a card as a transaction medium, and the magnetic data is destroyed, even if there is no person in charge to perform appropriate processing such as reissuing the card , It may be desirable to return the unusable card to the user. This is because if the card can be received, the user can carry out the card reissuance procedure at a sales office that is convenient for the user.

On the other hand, when there is a staff member, a power failure occurs, and the card that cannot be used as described above is ejected,
In some cases, it may be better for the staff to stay in the device so that appropriate processing can be carried out, rather than being taken back by the user.

[0007] Furthermore, the timing at which a power failure occurs during the execution of transaction processing (processing stage), regardless of whether or not there is a staff member.
Depending on the card, it may still be usable. As described above, various factors in the situation at that time should be taken into consideration in determining whether to eject the card at the time of power failure. Therefore, an object of the present invention is to provide an automatic transaction device capable of appropriately discharging a transaction medium according to the situation at the time of a power failure.

[0008]

The automatic transaction device of the present invention accepts a transaction medium offered by a user, automatically conducts a predetermined transaction based on an operation performed by the user, and when the transaction is completed, In the automatic transaction device that discharges the accepted transaction medium, a power failure detection means for detecting a power failure, and when a power failure is detected by this power failure detection means, a preset discharge condition of the transaction medium at the time of power failure and a power failure Judgment means for judging whether or not the accepted transaction medium is to be ejected from the processing content when detected, and ejecting the accepted transaction medium when it is judged by this judgment means to eject the transaction medium. It is equipped with a means for ejecting a trading medium.

Further, the automatic transaction apparatus of the present invention accepts a transaction medium offered by a user, automatically conducts a predetermined transaction based on an operation performed by the user, and when the transaction is completed, the accepted transaction medium. In an automatic transaction device that discharges a power outage, a power outage detection unit that detects a power outage, and when this power outage detection unit detects a power outage, a preset discharge condition of the transaction medium at the time of a power outage and a time when a power outage is detected From the processing content of the above, the judgment means for judging whether or not the accepted trading medium is discharged, and the discharging means for discharging the accepted trading medium when the judgment means judges that the trading medium is discharged. Means and the power failure detecting means detects a power failure, and supplies auxiliary power to the determining means and the transaction medium ejecting means to operate them. It is provided with a door.

Further, the automatic transaction apparatus of the present invention accepts a transaction medium offered by a user, automatically conducts a predetermined transaction based on an operation performed by the user, and when the transaction is completed, the accepted transaction medium. In an automatic transaction device that discharges a power outage, a power outage detection unit that detects a power outage, an emission condition setting unit that sets an emission condition of the transaction medium at the time of a power outage according to the processing status of the transaction, and a power outage by the power outage detection unit When it is detected, a determination means for determining whether or not to discharge the accepted transaction medium from the discharge condition of the transaction medium set by the discharge condition setting means and the processing content when the power failure is detected. And a transaction medium ejecting unit for ejecting the accepted transaction medium when the decision unit determines that the transaction medium is to be ejected.

Further, the automatic transaction apparatus of the present invention accepts a transaction medium offered by a user, automatically conducts a predetermined transaction based on an operation performed by the user, and when the transaction is completed, the accepted transaction medium is accepted. In an automatic transaction device that discharges a power outage, a power outage detection unit that detects a power outage, an emission condition setting unit that sets an emission condition of the transaction medium at the time of a power outage according to the processing status of the transaction, and a power outage by the power outage detection unit When it is detected, a determination means for determining whether or not to discharge the accepted transaction medium from the discharge condition of the transaction medium set by the discharge condition setting means and the processing content when the power failure is detected. When the determination means determines that the transaction medium is to be discharged, the transaction medium discharge means for discharging the accepted transaction medium and the power failure detection means detect a power failure, Them against determining means and said transaction medium discharging means is provided with an auxiliary power supply for supplying necessary power to operate.

[0012]

[Operation] The discharge condition of the transaction medium is set in advance, and when a power failure is detected, it is determined whether or not the transaction medium is discharged based on the transaction processing contents at that time and the discharge condition of the transaction medium. By doing so, when a power failure occurs, it is possible to appropriately return the transaction medium according to the transaction processing situation at that time.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows the appearance of an automatic teller machine as an automatic transaction apparatus according to this embodiment. In the figure, a substantially L-shaped customer service operating portion 2 is formed on the front surface of a housing 1. On the horizontal surface of the customer service operating section 2, there is provided a bill slot 3 having an openable / closable lid body for receiving the discharged bills collectively.

A color CRT display unit 4 having a transparent touch sensor panel on the display surface is provided on the horizontal surface of the customer service operating unit 2. The color CRT display unit 4 displays operation procedures and other information on the screen by characters, wording, illustrations or image information, guides the user, and displays numbers, katakana, alphabets, and confirmation and cancellation characters. By touching a part of the touch sensor panel with a finger, desired information can be input.

On the vertical surface of the customer service operating section 2, there are provided a card slot 5 for accepting and ejecting a magnetic card as a transaction medium on which a personal identification number, an account number, etc. are recorded, and a staff call button 6 for calling a staff member. Has been.

FIG. 2 schematically shows the internal structure of the above-described automatic teller machine. The card journal unit 1 is shown in FIG.
0, withdrawal unit 11, customer service unit 12, voice guidance unit 13, internal monitor 14, transmission control unit 15, main control unit 16, power supply unit 17, and system bus 18.

The card journal unit 10 receives the card C inserted from the card slot 5, and the card C
Data is read from or written in the magnetic stripe of the card, and the received card C is ejected from the card slot 5.

The pay-out unit 11 takes out a predetermined number of banknotes stored in a safe in advance and pays them out collectively from the banknote slot 3. The customer service unit 12
It is composed of the color CRT display unit 4.

The voice guidance unit 13 provides voice guidance for user operation. The internal monitor 14
It is provided on a rear operation panel (not shown) that can be seen when the door on the back of this device is opened, and informs the personnel related to the operation of this device of the state of this device, or as described later,
It sets conditions for discharging cards as transaction media in the event of a power failure (hereinafter referred to as card discharging conditions).

The transmission controller 15 is adapted to communicate online with the host computer 20 of the center via the communication line 19. The main control unit 16 refers to the program information in a storage unit (not shown), and each unit 10-1
4 and the internal monitor 14 and the transmission control unit 15 are controlled to perform a predetermined transaction operation.

The power source section 17 distributes the commercial AC power source input from the external power source to each unit. The system bus 18 includes units 10 to 14 and an internal monitor 14
And the main controller 16 are connected.

FIG. 3 schematically shows the internal structure of the card journal unit 10. That is, a card receiving port 31 communicating with the card slot 5 is formed in the front surface of the unit main body 30 substantially in the center thereof, and a card reader unit 32 is provided in the unit main body 30 corresponding to the card receiving port 31. ing. A DC power supply unit 33 and an auxiliary battery 34 are provided below the card reader unit 32, and a main control unit 35 is provided above the card reader unit 32. A journal printer unit 36 is provided at the rear of the unit body 30.

The card reader unit 32 inserts the card C inserted into the card slot 5 by the user into the card receiving slot 31.
A plurality of conveying roller pairs 37 for ejecting the received card C to the card slot 5 through the card receiving slot 31 when the card C is taken in and conveyed inside or when the transaction processing is normally completed.
It has a card carrying motor 38 for driving these carrying roller pairs 37. A magnetic head 39 for reading and writing magnetic data on the magnetic stripe of the card C is provided in the middle of the conveying path formed by the conveying roller pair 37. Also, the pair of transport rollers 3
At the end on the card loading direction side of the transport path formed in 7,
A card storage section 40 for storing the received card C is provided. Further, a card emboss optical reading unit 41 that optically reads the embossed characters of the card C conveyed by the conveying roller pair 37 is provided above the midway portion of the conveying path formed by the conveying roller pair 37.

The journal printer unit 36 records the card embossed image read by the card emboss optical reading unit 41, magnetic data read from the card C, transaction information received from the host computer 20, and the like. It has a heat-sensitive roll paper 42 as a recording paper and a line thermal head 43.

The DC power supply unit 33 includes the power supply unit 17
The required DC power supply voltage is generated from the AC power supply supplied from the device, and is supplied to each unit in the card journal unit 10.

The auxiliary battery 34 backs up the operating power supply of the card reader unit 32 at the time of power failure. The main control unit 35 follows the various instructions sent from the main control unit 16 via the system bus 18.
It controls each function in the card journal unit 10.

FIG. 4 schematically shows a main part of an electric circuit of the card journal unit 10. Incidentally, FIG.
The same parts as those in FIG. The DC power supply unit 33 receives the required DC power supply voltage (for example, 24V, 5V) from the AC power supply supplied from the power supply unit 17.
Etc.) is generated and supplied to each unit via the main control unit 33. In addition, when a power failure of the present device occurs, that is, when the supply of AC power from the power supply unit 17 is cut off, the power cutoff detection circuit 50 provided in the DC power supply unit 33 detects it and generates a power cutoff signal. Then, it is sent to the main control unit 35 to notify that the power is off (power failure).

The main control unit 35 is connected to the main control unit 16 by the system bus 18, and is connected to the master CP.
The card ejection condition information that has U and is supplied from the main control unit 16 via the system bus 18 is the master CPU.
51 is input. The master CPU 51 sends the input card ejection condition information to the card reader unit 32.

The power-off signal sent from the DC power supply unit 33 to the main control unit 35 is input to the interrupt input terminal of the master CPU 51 of the main control unit 35. Upon receiving the power-off signal, the master CPU 51 sends a card power failure discharge signal to the card reader unit 32 immediately (before + 5V is shut off) to notify that the power is off.

The card reader unit 32 is a slave C.
It has a PU 52 and a voltage converter 53, and when the slave CPU 52 receives the card ejection condition information from the master CPU 51, this card ejection condition information is not shown in the figure.
Remember in AM. The card power failure discharge signal sent from the master CPU 51 is input to the interrupt input terminal of the slave CPU 52. Then, the slave CPU 52
It is determined whether or not the processing contents at that time are included in the contents of the card ejection condition information stored in the RAM (not shown) to judge whether or not the card is ejected.

When the slave CPU 52 determines to eject the card, it drives the card transport motor 38 to rotate the transport roller pair 37 in the card ejection direction so that the received card C is ejected from the card slot 5. It has become.

The power supply (voltage value 5V) of the card reader unit 32 is the power supply voltage 24V sent via the main control unit 35 converted to 5V by the voltage converter 53. The 24V power supply voltage sent from the main control unit 35 is backed up by the auxiliary battery 34. The auxiliary battery 34 is, for example, a rechargeable battery such as a large-capacity capacitor that can be repeatedly used.

Next, with reference to the flow chart shown in FIG. 5, an operation for carrying out a balance inquiry transaction will be described. First, in the user waiting state, step S1
Then, the value of the power failure discharge mode as the card discharge condition is set to "1". That is, for example, when a staff member uses the internal monitor 14 to set the power failure discharge mode “1”, the value of the set power failure discharge mode is sent to the main control unit 16 via the system bus 18. The master CP in the main control unit 35 of the card journal unit 10 from the main control unit 16 via the system bus 18.
It is sent to U51. The power failure discharge mode value sent to the master CPU 51 is further sent to the slave CPU 52 in the card reader unit 32, and the slave CPU 5
2 is stored in the RAM (not shown). This allows
A power failure discharge mode “1” is set as a card discharge condition.

Here, what is meant by the power failure discharge mode "1" is, for example, "the card in the card reader unit 32 is discharged at the time of power failure except when the forgotten card is being collected and the magnetic data of the card is being rewritten". Is.

Next, in step S2, when the user inputs a "balance inquiry" from the touch sensor panel of the color CRT display unit 4 and selects "balance inquiry" as a transaction process, the process proceeds to step S3. .

In step S3, the color CRT display unit 4
The message "Please insert the card" is displayed on, and the process proceeds to step S4. In step S4, when the user inserts the card C into the card slot 5, the card C is taken into the card reader unit 32 of the card journal unit 10, and the process proceeds to step S5.

In step S5, the magnetic data of the card C taken into the card reader unit 32 is read by the magnetic head 39, and the card embossed image is read by the card embossed optical reading unit 41.
Go to 6.

In step S6, the main controller 16 sends the system bus 18 and the main CP of the main control unit 35.
Through the U51, the journal printer unit 36 is instructed to print the magnetic data and the card embossed image read in step S5, and the journal printer unit 36 records them and the process proceeds to step S7.

In step S7, based on the magnetic data read in step S5, the main control section 16 communicates online with the host computer 20 via the transmission control section 15 and the communication line 19, and the personal identification number and balance etc. Information is obtained and the process proceeds to step S8.

In step S8, the color CRT display unit 4
Is displayed, the guidance of "Please enter your PIN" is displayed.
Go to step S9. In step S9, when the user inputs the personal identification number from the touch sensor panel of the color CRT display unit 4, the process proceeds to step S10.

In step S10, the main controller 16 causes the personal identification number input by the user and the host computer 2
It collates with the personal identification number obtained from 0, and if the collation result is a match, the process proceeds to step S11.

In step S11, the main controller 16
System bus 18, main C of main control unit 35
Through the PU 51, the journal printer unit 36 is instructed to print the information such as the balance obtained from the host computer 20, and the information such as the balance is transmitted via the system bus 18 and the main CPU 51 of the main control unit 35 to the journal printer. When sent to the unit 36, the journal printer unit 36 records them and
Go to step S12.

In step S12, the main control unit 16 displays the information such as the balance obtained from the host computer 20 on the color CRT display unit 4, and the process proceeds to step S13. In step S13, the user confirms the information displayed on the color CRT display unit 4, and "confirms" the touch sensor panel.
When keying in, the process proceeds to step S14.

In step S14, the guide "Please receive the card" is displayed on the color CRT display portion 4, and the process proceeds to step S15. In step S15, the main control unit 16 to the system bus 18 and the main control unit 3
5, the slave CPU 52 of the card reader unit 32 is instructed to eject the card C, the card transport motor 38 is driven, the card C is ejected from the card slot 5, and the process proceeds to step S16.

In step S16, the user makes the card slot 5
The transaction processing for the balance inquiry is completed by receiving the card C discharged from. On the other hand, in step S10, the personal identification number entered by the user and the host computer 2
When the result of collation with the personal identification number obtained from 0 does not match for three consecutive times, the process proceeds to step S17.

In step S17, the main control unit 16 checks whether or not the apparatus is operated unattended. At this time, information on whether or not unmanned operation is
It is assumed that a person in charge in the standby state of the user sets it by using the internal monitor 14 so that it is stored in a memory (not shown) in the main control unit 16. Then, the information stored in the memory as to whether or not the operation is unattended is checked, and if it is determined that the operation is unattended, the process proceeds to step S18.

In step S18, the main controller 16 changes the value of the power failure discharge mode to "2". That is, the value of the power failure discharge mode is sent from the main control unit 16 to the master CPU 51 in the main control unit 35 of the card journal unit 10 via the system bus 18. The value of the power failure discharge mode sent to the master CPU 51 is further determined by the slave C in the card reader unit 32.
It is sent to the PU 52, and the slave CPU 52 rewrites the value of the power failure discharge mode already stored in the RAM (not shown). As a result, the power failure discharge mode is changed.

Here, what is meant by the power failure discharge mode "2" as a card discharge condition is, for example, "the card reader unit 3 at the time of a power failure except when the forgotten card is being collected.
The card in 2 is ejected. "

Next, in step S19, the magnetic data of the card C is rewritten, that is, the card validity code is changed. Here, the card validity code is an authentication code for preventing the card C from being used by an improper card user. First, when the card C is inserted into the card slot 5 and accepted, the card C If the card validity code recorded as data and the validity code preset in the main control unit 16 are collated by the main control unit 16 and the collation results are the same,
It is determined that this card has not been used by an improper card user. If the card validity code is changed, the verification itself cannot be performed thereafter, so that it is judged that this card is used by an unauthorized card user, and this card cannot be used.

If it is determined in step S17 that the operation is not unmanned, step S18 is jumped to step S19 to perform the same operation as above. Next, in step S20, the color CRT display section 4 displays a guidance of "Please start over again", and the process proceeds to step S14. Thereafter, the card C return processing is performed in the same manner as described above, and the transaction processing ends.

As described above, in the above-described embodiment, the card ejection condition is set in the user waiting state (step S1), or when the user mistakenly inputs the personal identification number three times in a row (step S10), When it is found that the operation is unmanned (step S17), the card ejection condition can be changed according to the processing status of the transaction for the balance inquiry.

Next, a specific operation when a power failure occurs will be described. For example, when the power failure detection circuit 50 detects the power failure during the transaction process described above, a power failure signal is input to the interrupt input terminal of the master CPU 51. Upon receiving this power-off signal, the master CPU 51 immediately outputs a card power failure discharge signal, and this signal is input to the interrupt input terminal of the slave CPU 52 in the card reader unit 32. The slave CPU 52 is
When the card power failure discharge signal is received, the processing contents at that time (any one of the steps S1 to S20 described above)
And whether or not the card C is to be ejected is determined based on the contents of the power failure ejection mode stored in the RAM (not shown).

That is, when a power failure occurs in the processing steps of steps S1 to S9, the value of the power failure discharge mode is "1", but at this stage, "forgotten card recovery" and "card magnetic Since there is no processing content corresponding to "during data rewriting", the card C in the card reader unit 32 is always ejected at the time of power failure. Further, steps S19 to S20 and S14, which are processing steps in the case where the user makes a mistaken input of the personal identification number three times in a row and the operation is not unmanned
If a power failure occurs in steps S16 to S16, the value of the power failure discharge mode is "1", and the processing stage corresponding to "means rewriting magnetic data of card" means step S19.
Therefore, if a power outage occurs during the process of step S19, the card C is not ejected, but if a power outage occurs at any other processing stage, the card C is ejected. further,
Steps S18 to S20, S, which are processing steps in the case where the user makes a mistaken input of the personal identification number three times in a row and the operation is unmanned
When a power failure occurs in 14 to S16, the value of the power failure discharge mode is “2”, and there is no processing stage corresponding to the meaning of “collecting a forgotten card”, so there is always a card during a power failure. Discharge C.

When it is determined that the card C is to be ejected, the slave CPU 52 drives the card conveyance motor 38 to rotate the conveyance roller pair 37 in the card ejection direction and eject the card C from the card slot 5.

After the power failure detection circuit 50 detects the power failure and the power supply from the DC power supply unit 33 is cut off, the auxiliary battery 34 is used by the auxiliary battery 34 for a sufficient period of time to carry out the above-mentioned processing. Power can be supplied to 32.

As described above, according to the above embodiment, when the power failure is detected, the transaction processing contents at that time and the preset card ejection conditions are used.
By determining whether or not to eject the accepted card, it is possible to return the card appropriately when the power failure occurs, depending on the transaction processing situation at that time.

The power outage modes "1" and "2" as card ejection conditions mean "excluding the collection of a forgotten card", but this "collecting a forgotten card" should be received. It means that there is no owner of. Therefore, the case where the card is not used by a person who is not the original card holder is also included.

The value of the power failure discharge mode is not limited to "1" and "2" described above, but the conditions required by the user of this device and the card discharge conditions corresponding to each of the conditions. Each value of can be defined appropriately.

Further, in the above-described embodiment, the timing for changing the value of the power failure discharge mode is when the user makes a mistaken input of the personal identification number three times in a row (step S10) and the operation is unmanned. If found (step S1
In the case of 7), the present invention is not limited to this, and can be appropriately determined by the user of this device.

Further, in the above-mentioned embodiment, the card is used as the transaction medium and the automatic teller machine is used as the automatic transaction apparatus, but the application of the present invention is not limited to this.
It is also effective as a transaction medium for passbooks, transfer tickets, etc. Also, as an automatic transaction device, accepts cards, passbooks, utility bill transfer tickets, etc., and makes online communication with the host computer, so that the payment amount requested by the user It is also effective for various automated devices such as automatic teller machines that automatically accept cash equivalent to or accept cash automatically. In addition to automated equipment at bank tellers, for example, like an automatic checkout machine at a station in transportation, once the user's property (ticket as a transaction medium) is taken into the device and some processing (settlement) is performed. This is effective for all devices that are returned after processing).

[0061]

As described above, according to the present invention, it is possible to provide an automatic transaction device capable of returning an appropriate transaction medium according to the transaction processing situation at the time of a power failure.

[Brief description of drawings]

FIG. 1 is a perspective view showing an appearance of an automated teller machine according to an embodiment of the present invention.

FIG. 2 is a block diagram schematically showing an internal configuration of an automatic teller machine.

FIG. 3 is a vertical sectional side view schematically showing the configuration of a card journal unit.

FIG. 4 is a block diagram schematically showing a main part of an electric circuit of a card journal unit.

FIG. 5 is a flowchart for explaining an operation when a transaction for balance inquiry is performed.

[Explanation of symbols]

1 ... Housing, 2 ... Customer service section, 3 ... Bill slot, 4 ... Color C
RT display section, 5 ... card slot, 6 ... call button for staff, 10
… Card journal unit, 11… Withdrawal unit, 1
2 ... Customer service unit, 13 ... Voice guidance unit, 14 ... Internal monitor, 16 ... Main control unit, 17 ... Power supply unit, 18 ... System bus, 19 ... Communication line, 20 ... Host computer, 30 ... Unit body, 31 ... Card Reception, 32 ...
Card reader unit, 33 ... DC power supply unit, 34
... auxiliary battery (auxiliary power source), 35 ... main control unit, 36 ... journal printer unit, 37 ... transport roller pair, 38 ... card transport motor, 39 ... magnetic head,
40 ... Card storage section, 41 ... Card embossing optical reading unit, 42 ... Thermal roll paper, 43 ... Line thermal head, 50 ... Power failure detection circuit, 51 ... Master CPU,
52 ... Slave CPU, 53 ... Voltage converter, C ... Card (transaction medium).

Claims (4)

[Claims] 1. A transaction medium offered by a user is accepted,
A predetermined transaction is automatically performed based on the operation performed by the user, and when the transaction ends, in the automatic transaction device that discharges the accepted transaction medium, a power failure detection means for detecting a power failure and this power failure detection means When a power failure is detected, a determining means for determining whether or not to discharge the accepted transaction medium, based on a preset discharge condition of the transaction medium at the time of power failure and a processing content when the power failure is detected. And a transaction medium ejecting unit for ejecting the accepted transaction medium when the transaction medium is determined to be ejected by the determination unit. 2. Accepting the transaction medium offered by the user,
A predetermined transaction is automatically performed based on the operation performed by the user, and when the transaction ends, in the automatic transaction device that discharges the accepted transaction medium, a power failure detection means for detecting a power failure and this power failure detection means When a power failure is detected, a determining means for determining whether or not to discharge the accepted transaction medium, based on a preset discharge condition of the transaction medium at the time of power failure and a processing content when the power failure is detected. When the determination means determines that the transaction medium is to be discharged, the transaction medium discharge means that discharges the accepted transaction medium; and when the power failure detection means detects a power failure, the determination means and the transaction medium An automatic transaction device, comprising: an auxiliary power supply that supplies the discharge means with power necessary for them to operate. 3. Accepting the transaction medium offered by the user,
A predetermined transaction is automatically performed based on the operation performed by the user, and when the transaction is completed, in the automatic transaction device that discharges the accepted transaction medium, a power failure detection means for detecting a power failure, and the transaction processing status. Discharge condition setting means for setting the discharge condition of the transaction medium at the time of power failure according to, and when the power failure is detected by the power failure detection means, the discharge condition of the transaction medium set by the discharge condition setting means, and the power failure From the processing content when the transaction medium is detected, the determining means for determining whether or not to eject the accepted transaction medium, and the determining means to eject the transaction medium, the accepted transaction medium An automatic transaction device comprising: a transaction medium ejecting means for ejecting. 4. A transaction medium offered by a user is accepted,
A predetermined transaction is automatically performed based on the operation performed by the user, and when the transaction is completed, in the automatic transaction device that discharges the accepted transaction medium, a power failure detection means for detecting a power failure, and the transaction processing status. Discharge condition setting means for setting the discharge condition of the transaction medium at the time of power failure according to, and when the power failure is detected by the power failure detection means, the discharge condition of the transaction medium set by the discharge condition setting means, and the power failure From the processing content when the transaction medium is detected, the determining means for determining whether or not to eject the accepted transaction medium, and the determining means to eject the transaction medium, the accepted transaction medium When the power outage is detected by the power outage detecting unit and the power outage detecting unit, the power supply necessary for operating the determining unit and the transaction medium outflowing unit is supplied. Automatic transaction apparatus for an auxiliary power source for, characterized by comprising a.