JP2018142047A - Automatic transaction device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To decrease conveyance monitoring sensors.SOLUTION: An automatic transaction device comprises: a conveyance path 13 for conveying a medium; a conveyance monitoring sensor 24 for monitoring conveyance of the medium on the conveyance path; a sensor 30 for determination which has a plurality of light receiving elements of a sensor 35 arranged on the conveyance path in an orthogonal direction orthogonal to the conveyance direction of the medium, and acquires information on the medium; and a control unit 11 which acquires, as conveyance information, information on the medium from light receiving elements arranged at the same position in the direction orthogonal to the conveyance monitoring sensor 24 among the plurality of light receiving elements, and controls the conveyance of the medium based upon the conveyance monitoring sensor 24 and the acquired conveyance information.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an automatic transaction apparatus, and, for example, relates to a medium control unit that controls conveyance of a medium.

  Automatic transaction machines such as automated teller machines (ATMs) identify the banknote denomination and the transport path that transports between the deposit / withdrawal port and the banknote storage that stores banknotes in denominations. And a bill discriminating device for discriminating authenticity.

  Patent document 1 is disclosing the banknote discrimination apparatus provided with the intrusion detection sensor provided in the front-end part and the rear-end part, and an optical sensor. Moreover, the banknote discrimination apparatus of patent document 1 abbreviate | omits an intrusion detection sensor, and combines the function of an intrusion detection sensor with the optical sensor. Patent document 2 is disclosing the automatic transaction apparatus provided with the banknote part and the conveyance path which arrange | positioned the several traveling monitoring sensor which monitors the driving | running | working of a banknote in the conveyance direction. This travel monitoring sensor is provided with light emitting elements and light receiving elements on both the left and right sides in the banknote transport direction, and can detect travel abnormalities such as skew and chaining.

JP 2006-221219 (paragraph 0018) Japanese Patent Laid-Open No. 8-19461 (paragraphs 0035, 0083, 0084)

  The banknote discrimination device described in Patent Document 1 is configured such that an optical sensor detects a medium that enters the inside of the device, and a control unit inside the device performs discrimination timing control. However, in addition to the intrusion detection sensor (entrance monitoring sensor) described in Patent Document 1, the automatic transaction apparatus is provided with a plurality of travel monitoring sensors as in Patent Document 2. Patent Documents 1 and 2 are not intended to reduce the number of travel monitoring sensors (conveyance monitoring sensors).

  An object of this invention is to provide the automatic transaction apparatus which can reduce a conveyance monitoring sensor.

  In order to solve the above-described problems, an automatic transaction apparatus according to the present invention includes a transport path (for example, a travel path 13) that transports a medium, a transport monitoring sensor that detects the presence or absence of the medium on the transport path, and a transport path. On the other hand, a plurality of sensors (for example, the light receiving element 37 of the pixel of the line sensor 35 and the thickness sensor 33) are arranged in an orthogonal direction orthogonal to the conveyance direction of the medium, and a sensor unit (for determination) for acquiring information on the medium Sensor 110) and among the plurality of sensors, the medium information is acquired as conveyance information from a sensor arranged at the same position in the orthogonal direction as the conveyance monitoring sensor, and the conveyance monitoring sensor and the acquired conveyance And a control unit that controls conveyance of the medium based on the information. In addition, the code | symbol in () is an illustration.

  According to this, a control part acquires the information on the said medium as conveyance information from the sensor arrange | positioned in the same position as a conveyance monitoring sensor about the orthogonal direction orthogonal to the conveyance direction of a medium. For this reason, the automatic transaction apparatus can reduce a conveyance monitoring sensor.

  According to the present invention, the conveyance monitoring sensor can be reduced.

It is a block diagram of the automatic transaction apparatus which is embodiment of this invention. It is an external view of an automatic transaction apparatus. It is a side view which shows the periphery of the sensor for discrimination | determination of a travel path. It is a side view which shows the relationship between an optical sensor and a driving | running | working monitoring sensor. It is a top view which shows the relationship between an optical sensor and a driving | running | working monitoring sensor. It is the top view and front view of the light-receiving part of an optical sensor. It is explanatory drawing explaining the driving | running | working monitoring by an optical sensor. It is explanatory drawing explaining the output signal of a light-receiving part at the time of skew feeding of a banknote. It is a flowchart explaining operation | movement of a discrimination | determination sensor control part. It is a flowchart explaining operation | movement of a discrimination control part. It is a flowchart explaining operation | movement of a conveyance control part. It is a side view of a banknote handling part. It is a side view which shows the whole traveling path.

  Hereinafter, an embodiment of the present invention (hereinafter referred to as “the present embodiment”) will be described in detail with reference to the drawings. In addition, each figure is only shown roughly to such an extent that this embodiment can fully be understood. Therefore, the present invention is not limited to the illustrated example. Moreover, in each figure, the same code | symbol is attached | subjected about the common component and the same component, and those overlapping description is abbreviate | omitted.

(Embodiment)
FIG. 1 is a configuration diagram of an automatic transaction apparatus according to an embodiment of the present invention, and FIG. 2 is an external view of the automatic transaction apparatus.
The automatic transaction apparatus 1000 is an ATM (Automated Teller Machine) including the banknote handling unit 100, a card unit 220, a form issuing unit 230, a numeric keypad 7, a control device 300, and an operation display unit 6. In addition, as shown in the external view of FIG. 2, the automatic transaction apparatus 1000 comprises the customer service part 3 with the card deposit / withdrawal port 4, the operation display unit 6, the numeric keypad 7, the transaction slip port 8, and the deposit / withdrawal port 5. The bill handling unit 100 and the control device 300 are housed in the lower part of the main body housing 2.

The bill handling unit 100 (FIG. 1) includes a travel path 13 as a transport path and a control unit 11 that controls the travel path 13.
The travel path 13 includes a determination sensor 30 as a sensor unit, a travel monitoring sensor 24 as a conveyance monitoring sensor, and a motor 45, and serves as a medium from the deposit / withdrawal unit 12 to the recycling unit 17 as a bill storage unit. The bills BL are conveyed and stored for each denomination by the recycling unit 17.

  The determination sensor 30 includes an optical sensor 35, a thickness sensor 33, and a magnetic sensor 34. The optical sensor 35 includes a line sensor and captures a front surface image, a back surface image, and a transmission image of the banknote BL. The thickness sensor 33 detects the thickness of the banknote BL, and detects the authenticity and heavy running of the banknote BL. The magnetic sensor 34 detects magnetic ink printed for preventing counterfeit bills BL. The magnetic sensor 34 includes an A / D conversion circuit (not shown), and the A / D conversion circuit has a function of temporarily storing the A / D converted magnetic information for a predetermined time. The thickness sensor 33 and the magnetic sensor 34 are provided with a plurality of channels in the width direction (left-right direction) with respect to the conveyance direction of the bills BL.

  The travel monitoring sensors 24 are provided at a plurality of locations along the transport direction at equal intervals L on the travel path 13, and detect heavy running of the bills BL and abnormal transport of the skew. Further, as shown in FIG. 3, the travel monitoring sensors 24 (24aa, 24ab, 24ba, 24bb) provided immediately before and immediately after the optical sensor 35 are set such that the distance from the light receiving unit 35Ba is equal to the interval L. This is because the optical sensor 35 of the present embodiment plays the role of the travel monitoring sensor 24, and details will be described later.

  The recycling unit 17 is a banknote storage for storing the banknotes BL deposited in the depositing / withdrawing unit 12 for each denomination and recycling the stored banknotes BL for withdrawal. The deposit / withdrawal unit 12 is a mechanism unit that manipulates the bill BL deposited in the deposit / withdrawal port 5 (FIG. 2) to the traveling path 13 and dispenses the bill BL fed out from the traveling path 13. The motor 45 is an electric motor that drives the transport rollers 32 (32a, 32b, 32c) (FIG. 3).

  The control unit 11 is a CPU (Central Processing Unit), and by executing a program stored in a ROM (Read Only Memory), the discrimination sensor control unit 110, the transport control unit 120, the discrimination control unit 130, A function with the communication control unit 140 is realized. The present embodiment does not assume a discrimination unit that includes the determination sensor 30 and a control unit that determines the authenticity of the bill BL using the determination sensor 30. That is, the control part 11 of this embodiment controls conveyance of the banknote handling part 100, identifies the denomination of the banknote BL, and discriminates authenticity.

  The discrimination sensor control unit 110 is a functional unit that controls the discrimination sensor 30 and includes a travel monitoring information extraction unit 111 and a banknote image extraction unit 112. The travel monitoring information extraction unit 111 is the same in the width direction (left and right direction) as the same position as the travel monitoring sensor 24 (orthogonal direction orthogonal to the transport direction) from the luminance information (line information) detected by the optical sensor 35. It is a functional unit that extracts position information (travel monitoring information). The banknote image extraction unit 112 is a functional unit that extracts image information of the banknote BL being conveyed using the line information detected by the optical sensor 35.

  The transport control unit 120 controls the travel monitoring sensor 24 and controls the motor 45 and the switching blade that switches the transport route using the information of the travel monitoring sensor 24 and the travel monitoring information extracted by the travel monitoring information extraction unit 111. To do.

  By arranging the travel monitoring sensor 24 at an equal interval L, the control unit 11 can obtain, for example, a time T = L / (V · n) obtained by further dividing a conveyance time obtained by dividing the interval L by the conveyance speed V by a natural number n. By periodically capturing the monitoring information detected by the travel monitoring sensor 24, it is possible to efficiently detect the conveyance abnormality of the bills BL.

  The discrimination control unit 130 uses the thickness information of the thickness sensor 33, the magnetic information of the magnetic sensor 34, and the image information of the bill BL extracted by the bill image extraction unit 112 (information on the front surface image, the back surface image, and the transmission image). This is a functional unit that identifies the denomination of the banknote BL and discriminates the authenticity.

  The communication control unit 140 is a functional unit that controls an interface with the control device 300, and is controlled by the control device 300 via hardware and controls transmission of the discrimination result to the control device 300.

  The card unit 220 is a mechanism unit that captures the contents of an IC card or a magnetic card inserted into the card deposit / withdrawal port 4. The form issuing unit 230 is a printing unit that prints and issues a form, and includes a transaction form port 8. The numeric keypad 7 is a PINPAD (Personal Identification Number PAD) for inputting a personal identification number.

  The control device 300 is a control computer equipped with an OS (Operating System), and controls each part such as the bill handling unit 100, the form issuing unit 230, the card unit 220, etc., and executes a transaction. The operation display unit 6 is connected to the control device 300 and displays a transaction screen.

FIG. 3 is a side view showing the periphery of the traveling path discrimination sensor.
The travel path 13 includes a discrimination transport path 14 and is connected to other mechanism units via transport rollers 41 and 42 before and after the transport path 13. The discrimination conveyance path 14 is a portion that performs discrimination of the banknote BL using the discrimination sensor 30 in the traveling path 13. That is, the identification transport path 14 includes a transport roller 32a, a magnetic sensor 34, a transport roller 32b, an optical sensor 35, a transport roller 32c, a thickness sensor 33, and a transport roller 32d in order from the front side along the transport surface U1. ing.

  The optical sensor 35 includes an upper unit 35A and a lower unit 35B having the same configuration with the conveyance surface U1 interposed therebetween, and is configured to be able to capture a front surface image, a back surface image, and a transmission image of the bill BL. Yes. The upper unit 35A includes a light emitting unit 35Aa as a linear light source set in a direction perpendicular to the conveyance direction of the bills BL. The lower unit 35B includes a light receiving unit 35Ba disposed on the opposite side of the light emitting unit 35Aa. The light receiving unit 35Ba is a line sensor and includes a plurality of light receiving elements 37 (FIG. 6B) corresponding to pixels. The light receiving unit 35Ba outputs luminance information (line information) output from the plurality of light receiving elements 37 as a time series signal.

  The light emitting unit 35Aa is a linear light source perpendicular to the transport direction, and is configured to instantaneously emit red (R), green (G), blue (B), and infrared alternately. The light receiving unit 35Ba is a line sensor in which a plurality of cylindrical lenses 36 (FIG. 6B) and a light receiving element 37 as a plurality of sensors (FIG. 6B) are arranged perpendicular to the transport direction. . The light receiving unit 35Ba is configured to scan the plurality of light receiving elements 37 linearly when the light emitting unit 35Aa is lit.

  The thickness sensor 33 is attached to the movable holder 33A rotatably supported by the upper conveyance guide 13A, the movable roller 33B rotatably supported by the movable holder 33A, and the lower conveyance guide 13B, and does not move in the vertical direction. A fixed roller 33C and a displacement sensor (not shown) for detecting the displacement of the movable holder 33A are provided.

  A plurality of magnetic sensors 34 and thickness sensors 33 are arranged in the width direction (left-right direction) with respect to the transport direction. The plurality of magnetic sensors 34 are provided to cope with different locations of magnetic ink depending on the bills BL, and the plurality of thickness sensors 33 are provided to detect skew of the bills BL. Yes. The conveyance rollers 32a, 32b, 32c, and 32d are provided above and below the conveyance surface and hold the bill BL.

  The first transport front portion 21A of the travel path 13 includes a transport roller 41 and travel monitoring sensors 24aa and 24ab. The first transport rear portion 21B of the travel path 13 includes a transport roller 42 and travel monitoring sensors 24ba and 24bb. An interval L between the travel monitoring sensors 24aa, 24ab, the light emitting unit 35Aa, and the light receiving unit 35Ba is set equal to an interval L between the travel monitoring sensors 24ba, 24bb, the light emitting unit 35Aa, and the light receiving unit 35Ba. Further, the discrimination sensor control unit 110 (FIG. 1) extracts information having the same phase as that of the travel monitoring sensor 24 using time-series line information output from the light receiving unit 35Ba. Thereby, the optical sensor 35 can play the role of the travel monitoring sensor 24.

FIG. 4 is a side view showing the relationship between the optical sensor and the travel monitoring sensor.
The traveling path 13 has a discrimination conveyance path 14, and a light emitting part 35 </ b> Aa and a light receiving part 35 </ b> Ba are opposed to each other through the conveyance surface of the bill BL inside the identification conveyance path 14. The travel path 13 includes travel monitoring sensors 24aa and 24ab in front of the discrimination conveyance path 14, and travel monitoring sensors 24ba and 24bb in the rear of the discrimination conveyance path 14.

  The travel monitoring sensors 24aa and 24ba are light emitting elements, and the travel monitoring sensors 24ab and 24bb are light receiving elements. The travel monitoring sensors 24aa and 24ba and the travel monitoring sensors 24ba and 24bb are arranged to face each other via the transport surface U1 of the bill BL to constitute a light emission / light reception pair. Thereby, the control part 11 (FIG. 1) can detect that the banknote BL passed the driving | running | working monitoring sensor 24. FIG. The distance L between the transport monitoring sensors 24aa and 24ab, the light emitting part 35Aa, and the light receiving part 35Ba is set equal to the distance L between the travel monitoring sensors 24ba and 24bb, the light emitting part 35Aa, and the light receiving part 35Ba. .

FIG. 5 is a plan view showing the relationship between the optical sensor and the travel monitoring sensor.
The traveling path 13 includes a discrimination conveyance path 14, and a light receiving portion 35 </ b> Ba of the optical sensor 35 is disposed inside the identification conveyance path 14 perpendicular to the conveyance direction. The travel path 13 includes light emission travel monitoring sensors 24aa and 24ac in front of the identification transport path 14, and light emission travel monitoring sensors 24ba and 24bc in the rear. The light emission travel monitoring sensors 24aa, 24ac, 24ba, and 24bc are light receiving travel monitoring sensors 24ab, 24ad (not shown), 24bb, and 24bd (not shown) on the opposite side of the transport surface U1 (FIG. 4). ) Are facing each other. That is, the conveyance monitoring sensor 24 is configured by arranging a plurality of pairs of light emitting elements and light receiving elements in the width direction (left-right direction) with respect to the conveyance direction. In other words, the conveyance monitoring sensor 24 is configured by arranging a plurality of pairs of light emitting elements and light receiving elements in the orthogonal direction perpendicular to the conveyance direction of the bills BL, and a plurality of them are arranged in the conveyance plane of the bills BL.

  The travel monitoring sensor 24 is provided with light emission travel monitoring sensors 24aa and 24ba and light emission travel monitoring sensors 24ac and 24bc so as to have a line-symmetric relationship with respect to the central axis of the travel path 13. Has been. That is, the travel monitoring sensors 24aa and 24ba are disposed on the left side of the travel path 13, and the travel monitoring sensors 24ac and 24bc are disposed on the right side of the travel path 13. The width d of the travel monitoring sensors 24aa and 24ac is set equal to the width d of the travel monitoring sensors 24ba and 24bc. The width d is set to such a length that the two travel monitoring sensors 24aa and 24ac can detect the bill BL even when the shortest bill BL in the longitudinal direction approaches the left end or the right end of the transport path. .

  4 and 5, when the bill BL is normally conveyed, the travel monitoring sensor 24 receives light almost simultaneously by the left and right light receiving travel monitoring sensors 24ab and a light receiving travel monitoring sensor 24ad (not shown). Disappear. Thereafter, when a time determined by the product of the length of the bill BL in the conveyance direction and the conveyance speed V elapses, the left and right light-receiving travel monitoring sensors 24ab and 24ac receive light almost simultaneously.

  In addition, when the bills BL are continuously conveyed, when a predetermined time elapses, the light received by the light receiving travel monitoring sensors 24ab and 24ad is blocked by the next bill BL.

  Moreover, the control part 11 is the length (length of a transversal direction) of the conveyance direction of the banknote BL from the time (passage time of the banknote BL) in which the driving | running | working monitoring sensors 24ab and 24ad for light reception on either side are not receiving light. ) Can be calculated. Thereby, the control part 11 can discriminate | determine that it is an abnormal banknote with which folding and cutting | disconnection has generate | occur | produced, if calculation length differs from a setting value. Further, the controller 11 receives the light from the right and left light-receiving travel monitoring sensors 24ab and 24ad that have not received light, and then starts again from the time until the light is not received again. The interval can be calculated. Thereby, the control part 11 can discriminate | determine that it is the abnormal traveling banknote in which the chain | linkage has generate | occur | produced that it is a space | interval shorter than a predetermined space | interval.

  In FIG. 5, it is assumed that the right side of the bill BL is transported obliquely so as to enter the discrimination transport path 14 first. The light receiving travel monitoring sensors 24ac and 24ad detect the entry of the bill BL first, and the travel monitoring sensors 24aa and 24ab detect the entrance of the bill BL later. Moreover, in the rear part of the discrimination conveyance path 14, the travel monitoring sensors 24bc and 24bd detect the exit first, and the travel monitoring sensors 24ba and 24bb detect the exit later.

6A and 6B are a plan view and a front view of the light receiving unit of the optical sensor, in which FIG. 6A is a plan view and FIG. 6B is a front view.
The light receiving unit 35Ba of the optical sensor 35 is a line sensor including a plurality of cylindrical lenses 36 arranged in a line and a plurality of light receiving elements 37 arranged in a line. The cylindrical lens 36 has a rectangular shape in plan view, the short side direction is the arrangement direction, and the long side is in contact with the adjacent cylindrical lens. A plurality of light receiving elements 37 are linearly arranged corresponding to one cylindrical lens 36, and the number of cylindrical lenses 36 and light receiving elements 37 is not the same.

FIG. 7 is an explanatory diagram for explaining traveling monitoring by the optical sensor.
The optical sensor 35 is disposed perpendicular to the transport direction, and the light receiving portion 35Ba has a plurality of light receiving elements 37 corresponding to the pixels arranged in a line. That is, the optical sensor 35 is configured to capture an image in a direction perpendicular to the conveyance direction of the banknote BL in a linear shape.

  Here, the travel monitoring information extraction unit 111 (FIG. 1) of the control unit 11 uses the linear captured image captured by the optical sensor 35, and is at the same position as the travel monitoring sensors 24aa and 24ac (perpendicular to the transport direction). Image information at the same position in the direction) is extracted. The travel monitoring information extraction unit 111 can monitor the conveyance of the banknote BL by binarizing the image information (pixel signal level) of the optical sensor 35. That is, the travel monitoring information extraction unit 111 can monitor whether or not the bill BL has passed through the light receiving unit 35Ba.

  Here, the light receiving surfaces of the travel monitoring sensors 24ab (FIG. 4) and 24ad (not shown) for light reception of the travel monitoring sensors 24aa and 24ac have a size (diameter) of about three times the width of the cylindrical lens 36. is there. The width of the cylindrical lens 36 is several times the pixel width of the light receiving element 37.

  Further, the travel monitoring information extraction unit 111 can monitor the skew of the bill BL from the time difference between two pieces of image information at the same position as the travel monitoring sensors 24aa and 24ac. That is, the control unit 11 can calculate the skew amount of the banknote BL to be transported using a time difference at which light is not received by the left and right light receiving travel monitoring sensors 24ab and 24ad. The control unit 11 determines that the banknote is an abnormal running bill by skewing a predetermined amount or more.

FIG. 8 is an explanatory diagram for explaining an output signal of the light receiving unit when the bill is skewed.
The travel monitoring sensors 24aa and 24ac and the light receiving portion 35Ba (FIG. 5) of the optical sensor 35 are arranged in a direction (main scanning direction) perpendicular to the transport direction.
The bill BL in the skew state passes through the travel monitoring sensor 24ac first, and then passes through the travel monitoring sensor 24aa. Therefore, the output signal of the travel monitoring sensor 24ac (the signal level changing in time series) rises (changes) prior to the output signal of the travel monitoring sensor 24aa, and a time difference occurs between each output signal.

  The light receiving unit 35Ba is configured to output a signal that changes in time series by scanning of the plurality of light receiving elements 37. Therefore, when the travel monitoring information extraction unit 111 (FIG. 1) extracts the luminance information of the pixels having the same phase as the travel monitoring sensors 24aa and 24ac using the output signal of the light receiving unit 35Ba of the control unit optical sensor 35, the time difference Information on the occurrence of T1 can be obtained.

For example, the shortest distance between the center of the travel monitoring sensor 24ac and the bill BL is L1, and the shortest distance between the center of the travel monitoring sensor 24aa and the bill BL is L2. At this time, the conveyance length from the bill BL passing through the travel monitoring sensor 24ac to passing through the travel monitoring sensor 24aa is (L2-L1). This transport length (L2−L1) is expressed as (L2−L1) when the transport speed V is set using the time difference T1 from the change in the output signal of the travel monitoring sensor 24ac to the change in the output signal of the travel monitoring sensor 24aa. ) = V · T1. That is, the inclination angle θ of the banknote BL is θ = tan ⁻¹ (V · T1 / d), where d is the width between the center of the travel monitoring sensor 24aa and the center of the travel monitoring sensor 24ac.

FIG. 9 is a flowchart for explaining the operation of the discrimination sensor control unit.
This flow is executed sequentially and periodically using a timer interrupt, and is assumed to be a depositing operation in which the bill BL is conveyed from the front to the back.

  First, the discrimination sensor control unit 110 (FIG. 1) captures image information of the optical sensor 35 (S12). That is, the discrimination sensor control unit 110 turns on the linear light source of the light emitting unit 35Aa (FIG. 2) of the optical sensor 35 and incorporates line information output in a time series by the light receiving unit 35Ba. After S12, the travel monitoring information extraction unit 111 of the determination sensor control unit 110 determines the presence or absence of a medium (banknote BL) using the luminance information of the optical sensor 35 (S14). If the traveling monitoring information extraction unit 111 determines that there is no banknote BL (no medium in S14), the process ends. Then, the determination sensor control unit 110 executes this routine again in the next cycle.

  On the other hand, if it is determined that there is a bill BL as a medium (there is a medium in S14), the traveling monitoring information extraction unit 111 cuts out a region corresponding to the traveling monitoring sensor 24 from the image information captured from the optical sensor 35 (S16). That is, the travel monitoring information extraction unit 111 cuts out information on the same position as the travel monitoring sensors 24aa and 24ac (the same position in the direction perpendicular to the transport direction). After S16, the travel monitoring information extraction unit 111 temporarily stores the cut-out information as travel monitoring information in a storage unit (RAM (Random Access Memory)) (S18). After S18, the banknote image extraction unit 112 (FIG. 1) extracts a two-dimensional image (banknote image) of the banknote BL being conveyed (S20), and the extracted banknote image (front image, back image, and transmission image). ) In the storage unit.

  After S20, the discrimination sensor control unit 110 (FIG. 1) controls the thickness sensor 33 and the magnetic sensor 34 (S22). That is, the determination sensor control unit 110 acquires magnetic sensor information temporarily stored in an A / D conversion circuit that controls the magnetic sensor 34, and further controls the thickness sensor 33 to acquire thickness information. After S22, the discrimination sensor control unit 110 transfers control to the discrimination control unit 130 (FIG. 1), and performs bill discrimination (S30).

FIG. 10 is a flowchart for explaining the operation of the discrimination control unit.
In S30, the discrimination control unit 130 (FIG. 1) uses the two-dimensional image (banknote image) extracted in S20 to identify the denomination of the banknote BL and discriminate true / false (S32). After S32, the discrimination control unit 130 performs bill discrimination using the information (magnetic sensor information) of the magnetic sensor 34 (S36), and ends the process.

FIG. 11 is a flowchart for explaining the operation of the transport control unit.
Similar to the discrimination sensor control (FIG. 9), this flow is periodically and sequentially executed using a timer interrupt.
The conveyance control unit 120 captures all the state information of the travel monitoring sensor 24 (S42). In other words, the transport control unit 120 monitors not only the travel monitoring sensors 24a (24aa, 24ab) and 24b (24ba, 24bb) immediately before and after the identification transport path 14, but also all travel monitoring disposed on the travel path 13. The state information of the sensors 24a, 24b, 24c, 24d, 24e, 24f, 24g, 24h,.

  After the process of S42, the conveyance control unit 120 takes in the travel monitoring information of the optical sensor 35 (S44). That is, the conveyance control unit 120 stores the two pieces of traveling monitoring information at the same position (the same position in the vertical direction perpendicular to the conveying direction) as the traveling monitoring sensor 24 stored in the storage unit in S18 (FIG. 9). take in. After S44, the conveyance control unit 120 takes in the banknote discrimination result performed in S30 (FIG. 10) (S46). After S46, the conveyance control unit 120 executes conveyance control based on the fetched banknote discrimination result (S50).

FIG. 12 is a side view of the banknote handling unit.
In the banknote handling unit 100, the inside of the banknote handling unit housing 19 is divided into an upper block 10U and a lower block 10L, and a safe housing 10S that can be pulled forward is built in the lower block 10L. The upper block 10 </ b> U includes a control unit 11, a deposit / withdrawal unit 12, a travel path 13, a temporary storage unit 15, and a fake ticket storage 18. The safe housing 10S includes a reject box 16 and a recycling unit 17 inside.

  The deposit / withdrawal unit 12 is disposed at the front upper portion of the upper block 10U. The depositing / withdrawing unit 12 includes a container 12A that accommodates one of the bill BL received from the customer and the bill BL to be withdrawn to the customer, and a shutter 12B that opens and closes the upper portion of the container 12A. . Further, the deposit / withdrawal unit 12 is provided with an intake / discharge port 12C and a deposit / withdrawal transport unit 12D for separating and feeding the bills BL one by one.

  The temporary storage unit 15 employs a tape escrow method in which the banknote BL is accommodated by winding the banknote BL together with the tape around the outer peripheral surface of the cylindrical drum, and the banknote BL is fed out by peeling the tape from the outer peripheral surface. The counterfeit bill store 18 stores counterfeit banknotes determined by the discrimination control unit 130 (FIG. 1). The reject box 16 stores banknotes that are determined to be damaged and cannot be reused. The recycling unit 17 includes a plurality of banknote storages 17A, 17B, 17C, 17D, and 17E that store the banknotes BL for each denomination.

FIG. 13 is a side view showing the entire travel path.
The travel path 13 is divided into a first transport section 21 on the front side, a second transport section 22 on the rear side, and a temporary hold switching section 20 that connects both, and a linear transport path is formed along the front-rear direction. Has been. The temporary hold switching unit 20 switches the transport path between the temporary hold unit 15 and the recycle unit 17 using a switching blade. In addition, the 1st conveyance part 21 is divided into 21 A of 1st conveyance front parts, the discrimination conveyance path 14 demonstrated in FIG. 3, and the 1st conveyance rear part 21B in order from the front.

  The second transport unit 22 uses the switching blades 23c, 23d, 23e, and 23f to switch the transport path to any one of the plurality of banknote storages 17A, 17B, 17C, 17D, and 17E and the fake banknote 18. It is.

  The travel path 13 includes a plurality of travel monitoring sensors 24b (24ba, 24bb), 24c (24ca, 24cb), 24d (24da, 24db), 24e (24ea, 24eb), 24f (24fa, 24fb), 24g (24ga). 24gb), 24h (24ha, 24hb), 24i (24ia, 24ib) are arranged at equal intervals L. In addition, as described with reference to FIG. 3, the distance L is equal to the distance between the travel monitoring sensors 24a and 24b and the light receiving unit 35Ba.

  Since the travel monitoring sensors 24 are arranged at equal intervals L, the control unit 11 (FIGS. 1 and 12), for example, has a time T obtained by further dividing a conveyance time obtained by dividing the interval L by the conveyance speed V by a natural number n. By periodically acquiring the state information of the travel monitoring sensor 24 at = L / (V · n), it is possible to efficiently detect a conveyance abnormality. Moreover, the control part 11 detects the skew of the banknote BL efficiently by taking in the state information of the driving | running | working monitoring sensor 24 periodically with the time T / m which divided the time T by the natural number m. Can do. That is, it is preferable that the control unit 11 captures the state information of the travel monitoring sensor 24 in time T = L / (V · n) and captures in detail at the time T / m in the vicinity before and after that.

(Explanation of effect)
As described above, the automatic transaction apparatus 1000 according to the present embodiment uses the optical sensor 35 that is the determination sensor 30 as the same function as the travel monitoring sensor 24. For this reason, one pair of the driving | running | working monitoring sensor 24 required inside the banknote handling part 100 becomes unnecessary. This is useful in terms of both mounting space and cost.

  Since a plurality of the travel monitoring sensors 24 are arranged in the vertical direction perpendicular to the transport direction, the skew angle of the banknote BL can be detected. Further, since the optical sensor 35 is an extraction target only for the pixel region corresponding to the same position as the travel monitoring sensor 24 (the same position in the vertical direction perpendicular to the transport direction), the optical sensor 35 has the same scale as the travel monitoring sensor 24. The skew angle θ can be detected.

  Moreover, since the control part 11 extracts the pixel of the same position as the driving | running | working monitoring sensor 24 from the pixel of the optical sensor 35, it can determine the presence or absence of the banknote BL at the same timing as the driving | running | working monitoring sensor 24. For this reason, the control part 11 can handle similarly, without distinguishing the optical sensor 35 and the driving | running | working monitoring sensor 24. FIG.

(Modification)
The present invention is not limited to the embodiments described above, and various modifications such as the following are possible.
(1) In the first example of each of the above embodiments, an example using an optical line sensor as a discrimination sensor has been described. Similarly, for a sensor that can detect a medium, such as a thickness sensor 33 that detects a thickness. Even adaptation is possible. That is, the position of any one of the plurality of thickness sensors 33 is made equal to the position of the travel monitoring sensor 24 (a position in the direction perpendicular to the conveyance direction). Further, the distance between the thickness sensor 33 and the travel monitoring sensor 24 is made equal to the distance L between the travel monitoring sensors 24.

(2) Although two travel monitoring sensors 24 of the above embodiment are disposed in the direction perpendicular to the transport direction, three or more travel monitoring sensors 24 may be disposed.

11 Control unit 13 Traveling path (conveyance path)
14 Discrimination conveyance path 17 Recycling part 17A, 17B, 17C, 17D, 17E Bill storage 24, 24a, 24aa, 24ab, 24b, 24ba, 24bb Travel monitoring sensor (conveyance monitoring sensor, first conveyance monitoring sensor, second conveyance monitoring) Sensor)
24c, 24ca, 24cb, 24d, 24da, 24db, 24e, 24ea, 24eb, 24f, 24fa, 24fb, 24g, 24ga, 24gb, 24h, 24ha, 24hb, 24i, 24ia, 24ib Travel monitoring sensor (conveyance monitoring sensor)
30 Discriminating sensor (sensor part)
33 Thickness sensor (sensor)
35 Optical sensor 35Aa Light emitting part 35Ba Light receiving part (line sensor)
36 Cylindrical lens 37 Light receiving element (sensor)
100 bill handling unit 110 sensor control unit for discrimination 111 travel monitoring information extraction unit 300 control device 1000 automatic transaction device

Claims (6)

A transport path for transporting the medium;
A conveyance monitoring sensor for detecting the presence or absence of the medium on the conveyance path;
A plurality of sensors are arranged in an orthogonal direction perpendicular to the conveyance direction of the medium with respect to the conveyance path, and a sensor unit that acquires information on the medium;
Among the plurality of sensors, information on the medium is acquired as conveyance information from a sensor arranged at the same position in the orthogonal direction as the conveyance monitoring sensor, and based on the conveyance monitoring sensor and the acquired conveyance information An automatic transaction apparatus comprising: a control unit that controls conveyance of the medium. The automatic transaction apparatus according to claim 1,
The transport monitoring sensor is a first transport monitoring sensor and a second transport monitoring sensor disposed in front of and behind the sensor along the transport direction of the medium,
The automatic transaction apparatus, wherein an interval between the first conveyance monitoring sensor and the sensor is equal to an interval between the sensor and the second conveyance monitoring sensor. The automatic transaction apparatus according to claim 2,
A plurality of the transport monitoring sensors are provided along the transport direction of the medium,
The automatic transaction apparatus characterized in that an interval between an arbitrary conveyance monitoring sensor and an adjacent conveyance monitoring sensor is equal to an interval between the first conveyance monitoring sensor and the sensor. The automatic transaction apparatus according to claim 3,
The said control part acquires the information of the said medium sequentially from the said sensor with the period which remove | divided the product of the said space | interval and the conveyance speed of the said medium by the natural number, The automatic transaction apparatus characterized by the above-mentioned. An automatic transaction apparatus according to any one of claims 1 to 4,
The automatic transaction apparatus, wherein the sensor is one or both of a light receiving element corresponding to a pixel of a line sensor and a thickness sensor. An automatic transaction apparatus according to any one of claims 1 to 5,
2. The automatic transaction apparatus according to claim 1, wherein the conveyance monitoring sensor is configured such that a plurality of pairs of light emitting elements and light receiving elements are arranged in the orthogonal direction and are disposed in a conveyance surface of the medium.

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