KR100344639B1 - Banknote Identification Device - Google Patents

Abstract

According to the present invention, there is provided a banknote identification device for reliably identifying a counterfeit bill formed by combining a counterfeit bill by color copying and a counterfeit bill by two-color copying in black and white. The configuration includes a magnetic detection sensor for detecting the magnetism of banknotes, an optical sensor for detecting the pattern of banknotes, and a banknote identification means in which the magnetic detection sensor and the optical sensor are arranged before and after the same row in the conveyance direction of banknotes. The magnetic detection sensor and the optical sensor are arranged in two places orthogonal to the conveyance direction of bills, and one optical sensor is used as a red fluorescent sensor and the other optical sensor is an infrared type optical sensor.

Description

Banknote Identification Device

The present invention relates to a banknote identification device for magnetically and optically identifying whether a banknote of the present invention is forged.

As a conventional banknote identification device of this kind, as disclosed in Japanese Patent Laid-Open No. 4-264997, a banknote insertion opening, a passage connected to the rear of the banknote insertion opening, an identification sensor provided in the passage, and on the passageway A conveyance means for conveying the installed bills, an inlet sensor is provided in the vicinity of the bill insertion slot, and a control means is connected to the inlet sensor and the identification sensor, and after the tip of the bill reaches the identification sensor, the rear end is the inlet. Detecting means for detecting a passing time until passing through the sensor, comparing means for comparing the passing time detected by the detecting means with a reference time at the time of normal transfer set in advance in the reference value setting means, and a comparison result of the comparing means The banknote identification device comprised by the reverse means which reverses the said conveying means is known.

Looking at the configuration of the banknote identification device in more detail, the output of the inlet sensor is connected to the input of the comparison means via the passage time detection means for detecting the passage time of the banknote. The other input of the comparison means is connected to the reference value setting means, and the output of the comparison means is connected to the control means. One of the outputs of the identification sensor for detecting a bill and the optical print pattern is connected to the passage time detecting means, and the other output is connected to the control means via a bill identification means for converting a signal of the identification sensor into a predetermined electrical signal. Connected. Next, the inputs of the transfer motor electrostatic means for electrostatically feeding the transfer motor and the transfer motor reversal means for inverting the transfer motor are connected to the control means, the outputs of which are respectively connected to the transfer motor, and the transfer motor is transferred via the gear block. I transmit the power to the belt.

In addition, the operation of the banknote identification device configured as described above is performed as follows. First, when the banknote is inserted in the insertion slot, the entrance sensor detects the tip of the banknote, thereby transmitting a signal indicating that the banknote has entered the control means through the passage time detecting means and the comparing means. Accordingly, the transfer motor power failure signal is output from the control means to the electrostatic means to power the transfer motor, and this power is transmitted to the conveyance belt so that the banknote enters the passage. When the tip of the banknote reaches the identification sensor, the passage time detecting means is reset, and the passage time of the entrance sensor of the banknote inserted into the insertion opening is started. The identification signal is also output to the control means from the banknote identification means for converting the signal of the identification sensor into a predetermined electric signal. By this, banknote identification is started, the banknote is conveyed by the conveyance belt, and the banknote identification is performed until the banknote end part passes the identification sensor, and the authenticity of the banknote after banknote identification type is determined. When the end of the banknote passes the entrance sensor during banknote identification, the measurement of the passing time detecting means is terminated, and the measured value is compared with the reference time set in the reference value setting means in advance by comparing the measured value measured by the passing time detecting means. If it is larger, it is judged that it is in normal transfer, and banknote identification is continued. If the measured value is smaller than the reference value, it is determined that the banknote is being inclined and returned, and the identification is stopped. Reverse the motor to return the bill.

In the conventional banknote identification device, a magnetoresistive sensor for detecting a magnetic printing component printed by a magnetic ink containing iron, and an optical sensor for detecting a colored printing portion printed by a color ink are placed on a conveyance passage of the banknote. A method of identifying the authenticity of banknotes by means of detection signals respectively arranged and detected by a magnetoresistive sensor and an optical sensor has been used.

However, according to the above method, since the magnetic detection sensor and the optical sensor are arranged in the direction orthogonal to the conveying direction of the banknote, for example, the real banknote is copied by a color copying machine, and the position is corresponding to the magnetic printing part of the real banknote. In the case of using counterfeit bills made of magnetic tape containing iron, etc., the magnetic detection sensor normally detects the magnetic tape and the optical sensor detects the color printing part by the color copying machine. .

As another banknote identification device, for example, by attaching a string to a real banknote and inserting the real banknote with the string into the conveying passage of the banknote so that the magnetoresistive sensor and the optical sensor are normally operated to generate a signal for identifying the real banknote. In order to prevent the fraudulent act of pulling the string immediately after the signal is generated and returning the real bill to the bill insertion slot, in each case, each piece is provided to protrude into the conveyance passage of the bill to block the passage of the bill. When inserted into the conveying passage, the detection signal causes each piece to be immersed in the conveying passage so that the bill passes, and after the signal is generated to identify the real bill, the pulling prevention to protrude the slice into the conveying passage of the bill again. There is a device provided. However, in such a configuration, the real bills are cut into a plurality of small pieces so that the real bills are separated at the position of each piece, which is an anti-traction mechanism, and then the mutually connected pieces are connected by mutually weak adhesive pieces so that the cut pieces can be separated. Restoration of the original form of the banknote, and also attached to each of the cut pieces of a problem that can not be prevented when using the real banknote fraudulently.

It is a main object of the present invention to provide a paper waste identification device capable of validating a counterfeit bill by allowing a magnetoresistive sensor and an optical sensor to pass through the same portion of the inserted bill.

According to the first embodiment of the present invention, a bill transfer path and a transfer means for transferring bills on the bill transfer path, a bill detection sensor, and a detection signal by the detection sensor are compared with a detection signal of a real bill to determine whether it is a counterfeit bill. A bill discrimination apparatus comprising a discriminating means for discriminating and a reversing means for inverting the conveying means in accordance with the discrimination result of the discriminating means, comprising: a magnetoresistive sensor for detecting magnetism of a bill and an optical sensor for detecting a pattern of bills; The present invention relates to a banknote identification device, which is arranged in two places perpendicular to the semi-small direction of a banknote, the optical sensor on one side thereof is a red optical sensor, and the other is an infrared optical sensor.

In addition, in order to be able to identify counterfeit money which is a combination of black and white two-color copying and counterfeit money by color copying, a red type optical sensor and an infrared type optical sensor are placed at an intermediate position in the direction orthogonal to the transfer direction of the banknote. It is arrange | positioned before and after the same row as the conveyance direction.

According to such a structure, when a banknote is inserted in a conveyance path, the same location of a banknote is detected by the magnetic sensor and the optical sensor, Therefore, a magnetic tape, for example, is placed in the position corresponding to the magnetic printing part of a genuine banknote. In the case of adhesion, the transmittance or reflectance of the part changes greatly, so that it can be detected by the optical sensor to reliably identify the counterfeit money.

In this case, for example, when a counterfeit money by copying black and white and a counterfeit money by color copy is created and used illegally, the same point of the counterfeit money identifies a counterfeit money by color copying. Since it is detected by a red type optical sensor and an infrared type optical sensor for detecting counterfeit money by two-color radiation of black and white, counterfeit money can be reliably identified even in the case of such fraudulent use.

In addition, the banknote identification device of the second embodiment of the present invention includes a magnetic detection sensor for detecting the magnetism of the banknote, and an optical sensor for detecting the pattern of the banknote, and in a normal state, each piece protrudes into the conveyance passage of the banknote. In the case of inserting banknotes, the anti-traction mechanism allowing each piece to be immersed from the conveying passage to allow the banknotes to pass and the magnetic detection sensor and the light in the same row as the insertion direction of the banknote corresponding to at least one of the pieces. It further comprises a misconduct prevention means arranged with a sensor.

According to this configuration, the real bill is cut into a plurality of small pieces in accordance with the position of each piece, which is an anti-traction means, and a string is attached to the edge of the cut piece, and the cut pieces are glued using a weak adhesive force. When the bill is inserted into the conveyance passage in this state, the connection part of the bill passes through the position of the magnetic detecting sensor or the optical sensor, and in the process, the magnetic detecting sensor or the optical sensor is connected. The magnetoresistance or the transmitted light rate (or reflected light rate) is detected. Since this signal is different from that of the real banknote at the connection part, a forgery signal is generated, whereby acceptance of the counterfeit money is rejected and returned to the insertion hole. ,

In addition, according to the banknote identification device according to the present invention, the pressing portion in contact with the magnetic detection sensor is arranged in a symmetrical position away from the center line in the spring pressing portion which is curved in an arc shape and presses the pressing portion when viewed in a direction orthogonal to the bill transfer direction. It is supposed to be.

As described above, the present invention can reliably prevent fraudulent use of counterfeit money formed by combining counterfeit money by color copying and counterfeit money by black and white two-color copying.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 is a plan view of a banknote transfer path showing an arrangement relationship of each sensor.

The conveyance belt 1 runs in the width direction in parallel with the conveyance direction (the arrow direction in the figure). The conveying belt 1 is rotationally driven through the gear mechanism 3 by the conveying motor 2, and the motor pulse 4 is also operated with the rotation.

Banknote insertion detection sensors 5L and 5R for detecting the insertion of banknotes are arranged at both sides in the width direction near the entrance of the transfer passage, and the transfer motor 2 is moved in the forward direction by turning on the detection sensors 5L and 5R. Rotate

An identification trigger element 6 is provided in close proximity to one detection sensor 5L, and banknotes are transferred in synchronization with the motor pulse 4 in accordance with the operation of the identification trigger element 6. In the left and right positions of the conveyance belt 1, magnetic detection sensors (for example, magnetoresistive sensors) 7L and 7R are located on the same row n away from the sensors 7L and 7R in the transfer direction of bills. The light sensors 8L and 8R are respectively arranged in the center, and the infrared light sensor (for example, an infrared light emitting diode) 9 is located at the center of the width direction on the same row (m) as the banking direction. And a red type optical sensor (for example, a red light emitting diode) 10 are disposed.

However, in Fig. 1, when the banknote is inserted into the conveying passage, the banknote insertion detecting sensors 5L and 5R are turned on so that the conveying motor 2 rotates forward, and the banknote is conveyed in the direction of the arrow in the drawing, and at the same time, the identification trigger element 6 By the ON, the banknotes are transferred in synchronization with the motor pulse 4, and in the transfer process, the magnetic printed portions of the banknotes are transferred by the magnetic detection sensors 7L and 7R, and the colored printed portions are transferred to the optical sensors 8L and 8R. It is detected by each.

Thus, for example, in the case of fraudulent use of copying a real banknote by a color copying machine and inserting a counterfeit banknote made by attaching a magnetic tape containing iron at a position corresponding to the self-printing part of the real banknote to the transfer passage. In magnetic resistance sensors 7L and 7R, magnetic detection signals such as real banknotes can be obtained. However, when the magnetic tape is attached to the position of the optical sensors 8L and 8R, the light transmittance or reflectance of the magnetic tape is reduced. Since it is so different from real banknotes, it is possible to reliably identify counterfeit bills with magnetic tape. This result is the same even when the positions of the magnetoresistive sensors 7L and 7R and the optical sensors 8L and 8R are changed.

In addition, as a result of the experiment, the waveform of the detection signal by the red type optical sensor shows little difference with the real banknote when the counterfeit money is a two-color copy of a hoax, but there is a big difference in the case of color copying. The waveform of the detection signal by the optical sensor is very different from the real banknote when the counterfeit money is a two-color copy of black and white, and there is almost no difference in the case of color copying. Infrared light sensors are effective, and it has been found that infrared light sensors are effective for the identification of counterfeit money by black and white two-color radiation.

Therefore, in the above embodiment, the counterfeit bill can be identified more reliably by making one of the photosensors 8L and 8R the red photo sensor and the other the infrared photo sensor.

In addition, the colored printing portion is detected by the infrared light sensor 9 and the red light sensor 10 in the course of transferring the bill. In other words, in the case of cheating, there was an example in which one fake banknote was made by cutting the counterfeit money with black and white copying and the counterfeit money with color copying, and connecting them in the shorter direction of the bill. In the case of the inserted counterfeit bill, the same point passes through the positions of the infrared light sensor 9 and the infrared light sensor 10, so that the same point of the counterfeit money is also red for the infrared light sensor 9; Since the same detection signal as that of a real banknote cannot be obtained unless the special light sensor 10 responds to the fluorescent sensor 10 in the same manner, the infrared light sensor 9 and the red light sensor 10 are moved in the direction of bills. By arranging on the same line as, it is possible to more accurately identify the counterfeit bill by the optical sensor.

2, only the infrared type optical sensor 9 and the red type optical sensor 10 are arranged on the same line of the bill as the optical sensor.

A second embodiment of the present invention will be described with reference to FIGS. 3 to 4. This applies the sensor of the said structure to the identification apparatus provided with the attraction prevention mechanism. FIG. 3 is a side cross-sectional view of the banknote identification device with a pulling prevention means in the conveyance passage of the banknote, and each sensor, and FIG. 4 is a partial plan view.

The conveying passage 11 of the banknote is formed of the upper chute 12 and the lower chute 13, and is turned ON when the banknote is inserted at both positions of the banknote inserting opening of the conveying passage 11 so that the conveying belt ( Insertion detecting sensors 14L and 14R for driving (not shown) are arranged. An identification trigger element 15 is arranged near one of the insertion detection sensors 14L, and a pulse motor (not shown) is activated by turning on the identification trigger element 15, and is synchronized with the pulse motor. While the bills are transferred from right to left in the drawing.

In addition, a pair of left and right magnetic detection sensors, for example, magnetoresistive sensors 16L and 16R, which are located in the conveying direction of the banknote and detect the magnetic printed portion containing magnetic powder printed on the banknote, are colored printed on the banknote. A pair of left and right optical sensors 17L and 17R for detecting the portion are arranged in front and rear of each other in the same row in the conveying direction of the banknote, and in the axial middle portion of the conveying passage 11, which is effective for identification of counterfeit money that has been color-copied. A red type optical sensor (e.g., red light emitting diode) 18 and an infrared type optical sensor (e.g., infrared light emitting diode) 19, which are effective for identifying black and white two-color copied counterfeit money, are provided in the conveyance direction of bills. It is arranged in the same column.

In the figure, reference numeral 20 denotes a pressing member which is pressed against the magnetoresistive sensors 16L and 16R by an appropriate pressure of the banknote.

In the inserted banknote, the magneto-resistance sensors 16L and 16R and the light sensors 17L and 17R detect the magneto-resistance, transmittance or reflectance in the same position in the transfer process, thus copying the real bill. In the case of using a counterfeit paper with magnetic tape attached to a position corresponding to the magnetic printed part of a real paper money, the light transmittance or light reflectance by the optical sensors 17L and 17R is different from the real paper money, so the counterfeit paper can be identified. In addition, when the counterfeit money made by combining the counterfeit money by the black-and-white two-color copying and the counterfeit money by the color copying is used, the same location of the counterfeit money is the red type optical sensor 18 and the infrared type optical sensor 19. Since it is detected by, counterfeit money can be identified even in this case.

In addition, the attraction prevention means 25 of the present invention is provided in the chute 12, the attraction prevention means 25 is when the insertion detection sensors 14L, 14R are turned on by the insertion of banknotes Protruding orthogonally from the two-pronged rotating member 28 and the base portion 29 which rotate vertically with the shaft 27 as a point by the actuation of the actuating electron plunger 26 and the electron plunger 26. Angle pieces 33 protruding into the transfer passage 11 through the through holes 32 provided in the upper and lower chutes 12 and 13 at the free ends of the plurality of arms 31 (five in this embodiment). Member is formed at right angles to each other, and at the same time the free end of the intermediate arm 31 is integrally formed with an engaging portion 35 for engaging with the engaging pin 34 provided at the free end of the rotating member 28 ( 36), and in this embodiment, at least one or more of the blocking members 36 configured as described above. A magnetoresistive sensor (16L, 16R) and disposed, and / or optical sensor (17L, 17R) in the same column in the leg pieces (33a) of the two side portions of the side position to the conveying direction of the bills were arranged in the same column. In the above embodiment, the magnetoresistive sensors 16L and 16R are arranged to be located on the banknote insertion side than the light sensors 17L and 17R, but the present invention is not limited thereto.

Moreover, as the optical sensors 17L and 17R, the optical sensor which detects the transmittance | permeability is preferable.

When the banknote is inserted into the conveying passage 11, the detecting sensors 14L and 14R of the banknote are turned ON, the conveying belt proceeds in the forward direction, and the banknote is synchronized with the motor pulse by turning on the identification trigger element 15. While being transported, the electronic plunger 26 is operated by turning on the insertion detection sensors 14L and 14R, whereby the rotating member 28 is rotated counterclockwise in the drawing so that the coupling pin 34 and the coupling hole ( The coupling member 35 rotates counterclockwise in the drawing so that each piece 33 is immersed in the chute 12 from the transfer passage 11.

In this state, the banknote enters into the transfer passage 11, and when the banknote passes through the identification trigger element 15, the identification trigger element 15 is turned OFF, so that the electronic plunger 26, the rotating member 28, and the blocking Each of the members 36 returns, and each piece 33 protrudes into the conveying passage 11 again.

In such a configuration, the signal piece 33 is in front of the magnetic detection sensors 16L and 16R and at the same time a signal indicating that it is a real banknote does not occur until at least the banknote passes through the magnetic detection sensors 16L and 16R. Therefore, even if you want to pull the real banknotes with a string immediately after the signal indicating that the real money occurs, the configuration is impossible due to each piece 33 is not a big difference from the conventional configuration.

However, in accordance with the position of each piece 33 arranged in the width direction of the transfer passage, the real banknote is cut in the shorter direction of the banknote (in this embodiment, five square pieces 33 in the width direction of the transfer passage 11). The bills are cut into six pieces in the short direction, and the strings are attached to the edges of the cut pieces and lightly bonded to the cut pieces using, for example, a weak adhesive. When the banknote is inserted into the conveyance passage 11 in this state, the connecting portions of the banknotes that are joined are located at the positions of the magnetoresistive sensors 16L and 16R and the optical sensors 17R and 17L. In the course of passing through, the magnetoresistance detected by the magnetoresistive sensors 16L and 16R and / or the transmitted light rate or reflected light rate detected by the optical sensors 17L and 17R are genuine due to the bonded state and the presence of the adhesive pieces. It is different and are closed-reject acceptance thereof by the signal indicating that the thereby counterfeiting occurs, and thus the counterfeit banknote insertion port is sent back by the backhaul of the conveyance belt. In other words, it is possible to prevent cheating by counterfeit bills created by joining the pieces together. In addition, in the present embodiment, the bill is returned to the bill insertion slot by a counterfeit bill identification signal. Alternatively, the bill may be inserted back into the bill identifier.

Next, FIG. 5: shows the block diagram of a banknote press part in this invention. The conveyance passage 41 of the banknote is formed by the upper chute 41a and the lower chute 41b. The banknote enters in the direction indicated by the arrow and is guided to the banknote storing section by a conveying belt (not shown).

The conveying path 41 is provided with a pressing member 42 facing the magnetoresistive sensor M. As shown in FIG. The pressing member 42 extends in the curved direction and the symmetrical direction under the pressing portion 42a and the lower portion of the pressing portion 42a, which hold a connection surface curved in an arc when viewed in a direction orthogonal to the conveying direction of the banknote. The blade pieces 42b and 42b which are used are provided, and the said blade pieces 42b and 42b are fitted so that it can move to the guide mold 43 provided in the lower surface of the lower chute 41b so that it may move to an up-down direction.

A fixed receiving plate 44 is provided below the guide mold 43, and is formed between the receiving plate 44 and the wing pieces 42b and 42b from the center line N of the pressing portion 42a. Springs 45 and 45 are interposed in a state in which the curved surface of the pressing portion 42a with respect to the magnetoresistive sensor M is distributed symmetrically so as to be contacted by an appropriate pressing force.

When the banknote enters in the direction of the arrow by such a configuration, the banknote is brought into contact with the magnetoresistive element M by the pressing section 42a by an appropriate pressing pressure. Is identified. In addition, although the case where the springs 45 and 45 are arrange | positioned in two places of the banknote entry direction is shown in the said Example, when there exists sufficient margin on a mechanism, the blade pieces 42a and 42a make the springs 45 and 45 fall. You may arrange in two places of the direction orthogonal to the entry direction of a banknote.

According to the configuration of the present invention as described above, when the banknote is inserted into the conveyance passage, the same position of the banknote is detected by the magnetic detection sensor and the optical sensor, and thus, for example, magnetic tape is placed at the position corresponding to the magnetic printing part of the real banknote. In the case of adhering, the transmittance or reflectance of the part is greatly changed, so that it can be detected by the optical sensor to reliably identify the counterfeit bill.

In addition, a red type optical sensor that identifies counterfeit bills by color copying when the counterfeit bill is created and used illegally by combining a black and white two-color copy counterfeit bill and a color copy counterfeit bill and using it illegally; Since it is detected by an infrared light sensor that identifies counterfeit money by two-color radiation of black and white, counterfeit money can be reliably identified even in the case of such fraudulent use.

1 is a plan view of a banknote conveyance passage showing an arrangement relationship of each sensor of the first embodiment of the present invention.

2 is a plan view of a banknote transfer path showing an arrangement relationship of still another sensor of the first embodiment of the present invention.

3 is a side cross-sectional view of the banknote identification device of the second embodiment of the present invention.

4 is a partial plan view of the banknote identification device of FIG.

5 is a configuration diagram of a banknote pressing unit in the banknote identifying apparatus of the present invention.

Claims (8)

A conveying means for conveying bills on the bill conveying path and the bill conveying path, a bill insertion detecting sensor disposed near an inlet of the bill conveying path, and when the bill inserting detection sensor is turned on to drive the conveying means; Drive means, a detection sensor for detecting a banknote inserted and conveyed, a discrimination means for discriminating whether the counter signal is a counterfeit bill by comparing the detection signal by the detection sensor with a detection signal of a real banknote, and according to the discrimination result of the discriminating means In the case of a counterfeit bill, in the bill discrimination device consisting of a reverse means for reversing the transfer means, The detection sensor is composed of a magnetic detection sensor for detecting the magnetism of the bill, and an optical sensor for detecting the pattern of the bill, The magnetic detection sensor and the optical sensor is a banknote identification device, characterized in that arranged before and after the same row as the transfer direction of the banknote. The optical sensor according to claim 1, wherein the magnetic detection sensor and the optical sensor are disposed at two places perpendicular to the transfer direction of the bill, and one optical sensor is used as a red optical sensor, and the other optical sensor is used. Banknote identification device characterized in that consisting of an infrared light sensor. The bill recognition apparatus according to claim 1, wherein the red type optical sensor and the infrared type optical sensor are disposed at a middle position in a direction orthogonal to the direction in which the bill is transferred, before and after the same row as the direction in which the bill is transferred. A conveying means for conveying bills on the bill conveying path and the bill conveying path, a bill insertion detecting sensor disposed near an inlet of the bill conveying path, and when the bill inserting detection sensor is turned on to drive the conveying means; Drive means, a detection sensor for detecting a banknote inserted and conveyed, a discrimination means for discriminating whether the counter signal is a counterfeit bill by comparing the detection signal by the detection sensor with a detection signal of a real banknote, and according to the discrimination result of the discriminating means In the case of a counterfeit bill, in the bill discrimination device consisting of a reverse means for reversing the transfer means, The detection sensor is made of an optical sensor for detecting the pattern of the bill, In addition, the optical sensor includes a red type optical sensor and an infrared type optical sensor, The red type optical sensor and the infrared type optical sensor are bills identification device, characterized in that arranged before and after the same row as the transfer direction of the bill. The banknote identification device according to claim 4, wherein the red type optical sensor and the infrared type optical sensor are disposed at a central position in the width direction. A conveying means for conveying bills on the bill conveying path and the bill conveying path, a bill insertion detecting sensor disposed near an inlet of the bill conveying path, and a rotation of the bill inserting detection sensor when the bank is inserted to drive the conveying means. Drive means, a detection sensor for detecting a banknote inserted and conveyed, a discrimination means for discriminating whether the counter signal is a counterfeit bill by comparing the detection signal by the detection sensor with a detection signal of a real banknote, and according to the discrimination result of the discriminating means In the case of a counterfeit bill, in the bill discrimination device consisting of a reverse means for reversing the transfer means, The detection sensor is composed of a magnetic detection sensor for detecting the magnetism of the bill, and an optical sensor for detecting the pattern of the bill, In the normal state, each piece protrudes into the conveyance passage of the banknote to block the passage of the banknote, and when inserting the banknote, each side further includes an anti-traction means for allowing the passage of the banknote by immersing from the conveying passage, And the magnetic detection sensor and the optical sensor arranged in the same row as the carrying direction of the bill corresponding to one or more of the respective pieces. 7. The magnetic sensor according to claim 6, wherein the magnetic detecting sensor and the optical sensor are disposed at two places perpendicular to the conveyance direction of the bill, and one optical sensor is used as a red optical sensor, and the other optical sensor is used. Banknote identification device characterized in that composed of an infrared light sensor. 7. The bill discrimination apparatus according to claim 6, wherein the red type optical sensor and the infrared type optical sensor are disposed at a middle position in a direction orthogonal to the conveying direction of the bills before and after the same row as the conveying direction of the bills.