JP4857941B2 - Paper sheet identification device - Google Patents

Description

  The present invention relates to a paper sheet identification device that detects residual magnetism of a magnetized paper sheet and identifies the paper sheet.

  For example, when judging the authenticity of paper sheets such as banknotes, securities, gift certificates, magnetic cards, etc., characters, figures, symbols, etc. printed on paper sheets with printing ink containing a magnetic material The authenticity determination is performed by comparing a signal detected magnetically from the magnetic printing unit with a signal detected in advance from real paper sheets.

  In general, a magnetic sensor of a paper sheet identification device that performs authenticity determination of a paper sheet in a non-contact manner is installed in a conveyance path for conveying the paper sheet. This magnetic sensor includes, as a magnetic detection element, a magnetoresistive element whose resistance value changes according to a change in an external magnetic field, a magnetic impedance element whose impedance changes according to a change in an external magnetic field, or a thin film slack gate element.

  Among these, in the magnetic sensor of the paper sheet identification device using the magnetoresistive element, the magnetoresistive element is formed on the surface of the ceramic substrate. A magnet (magnetized body) is provided on the back side of the substrate. This magnet applies an auxiliary magnetic field in the vertical direction of the magnetoresistive element. And the weak magnetism of the magnetic printing part of paper sheets is detected by applying a magnetic field to a magnetoresistive element with a magnet (for example, refer to patent documents 1).

  Further, the magnetic sensor of the paper sheet identification device using the magneto-impedance element is such that the E-shaped magnetized bodies are arranged so that the three ends on the opened side are aligned perpendicular to the relative movement direction of the paper sheet. And arranged so as to be in contact with or in close proximity to the surface of the paper sheet. In addition, the magneto-impedance element is disposed in a plane parallel to the surface of the magnetic printing portion of the paper sheet so that the magnetosensitive direction coincides with a direction perpendicular to the relative movement direction. Further, a bias magnet is provided in the vicinity of the magnetic impedance element for applying a bias magnetic field to the magnetic impedance element so as to set the magnetic impedance element to a sensitive operating point. When detecting the magnetic printing part of the paper sheet, the magnetic printing part is magnetized by the magnetized body as the paper sheet moves, and the residual magnetic field of the magnetized part is detected by the magnetic impedance element (for example, , See Patent Document 2).

  In addition, the magnetic sensor of the paper sheet identification device using the thin film fluxgate element has the same configuration as that of the paper sheet identification device using the magnetic impedance element, so that the magnetic printing of the paper sheet is performed. Part.

JP 2003-35701 A JP 2000-105847 A

  As described above, the magnetic sensor is composed of the magnet and the magnetic detection element regardless of which magnetic detection element is used. And the magnetic quantity of the magnetic body contained in the printing ink of the magnetic printing part printed on paper sheets is very small. For this reason, in order to detect the magnetism of this magnetic body with high sensitivity, it is necessary to increase the magnetic force of the magnet. Therefore, a magnet with high volume efficiency is used for the magnet. For example, the magnet in the magnetic sensor referred to in Patent Document 1 has a magnetic force of about 150 Gauss to 300 Gauss, and the magnet in the magnetic sensor referred to in Patent Document 2 has a magnetic force of about 1 K Gauss.

  However, as described above, a magnetic sensor using a magnet attracts magnetic substance deposits such as iron sand and iron powder adhering to the surface of a paper sheet by the strong magnetic force of the magnet in an actual usage environment. Resulting in. If a large amount of magnetic substance adhering to the magnetic pole surface of the magnet is attracted and adhered, the magnetic field generated by the magnet will be disturbed, resulting in false detection by the magnetic sensor, or the conveyance path will be blocked and paper sheet conveyance will be hindered. Doing so will cause clogging.

  Therefore, it is necessary to perform maintenance work for the paper sheet identification device at regular intervals and to remove the magnetic substance adhering matter attracted and adhered to the magnetic pole surface of the magnet. In a general cleaning operation, a cover of an identification unit provided with a magnetic sensor is opened, and cleaning is performed with a cotton swab soaked in water or a neutral detergent. However, since the magnetic substance adsorbed attracted to the magnetic pole surface of the magnet is always attracted by the strong magnetic force of the magnet, much labor and time are required to completely remove the adhering substance.

  An object of this invention is to provide the paper sheet identification device which can prevent the situation where the magnetic substance adhesion material adhering to paper sheets adheres to a magnetic sensor in view of the said situation. It is another object of the present invention to provide a paper sheet identification apparatus that can remove magnetic substance deposits attracted by a magnetized body of a magnetic sensor.

In order to solve the above object, a paper sheet identification apparatus according to claim 1 of the present invention is provided in a transport path for transporting a paper sheet having a magnetic body, and the paper path. And a magnetic sensor comprising: a magnetizing means for applying a magnetic field to the magnetic material; and a magnetic sensor comprising a magnetic detecting means for detecting residual magnetism of the magnetic material of the paper sheet by applying the magnetic field of the magnetizing means. , Located immediately downstream of the transport means for transporting the paper sheet to the transport path and upstream of the magnetic sensor , and is fixed to a wall constituting the transport path, and passes through the transport path And a deposit removing means for removing the deposit on the paper sheet, the deposit removing means extending in the thickness direction of the sheet from the wall of the transport path toward the transport path. and, especially in that it consists of a brush-like abutment member provided so as to be in contact with the sheet To.

A paper sheet identification apparatus according to claim 2 of the present invention is the paper sheet identification apparatus according to claim 1, wherein the deposit removing means is disposed upstream of the transport path with the transport direction directed upward, and is disposed downstream of the transport path. A magnetic sensor is arranged.

According to a third aspect of the present invention, there is provided the paper sheet identification apparatus according to the second aspect, wherein the deposit material receiving unit receives the deposit removed by the deposit removing means at a position below the upstream portion of the transport path. Is provided.

  According to the paper sheet identification apparatus of the present invention, the adhering material removal means removes the adhering material adhering to the paper sheet before reaching the magnetic sensor. As a result, it is possible to prevent a deposit from adhering to the magnetic sensor.

  Further, according to the paper sheet identification device of the present invention, the contact member provided on the rotating body that rotates in synchronization with the conveying means contacts the magnetized part of the magnetic sensor, and is therefore attracted to the magnetized part. Remove any deposits. As a result, it is possible to prevent a deposit from adhering to the magnetized portion of the magnetic sensor.

  Exemplary embodiments of a paper sheet identification apparatus according to the present invention will be described below in detail with reference to the accompanying drawings.

<Form state of implementation>
FIG. 1 is a schematic view schematically showing a paper sheet identification apparatus according to the present invention. The paper sheet identification device 1 exemplified here is a character, figure, or symbol printed on the paper sheet W by a printing ink containing a magnetic material (hereinafter, these are simply referred to as “magnetic printing unit” as appropriate). Is detected in the vicinity of the transport path R for transporting the paper sheet W. The paper sheet identification apparatus 1 includes an ingress sensor 2, a paper sheet detection sensor (magnetic sensor) 3, an ingress detection unit 4, a magnetic detection unit drive unit 5, a magnetic detection circuit 6, and a signal processing circuit 7.

  The approach sensor 2 is disposed on the upstream side of the transport path R and on one side wall (upper side wall in FIG. 1) of the transport path R. The approach sensor 2 is an optical sensor such as a reflective photointerrupter, for example, and detects the entering paper sheet W in a non-contact manner.

  The paper sheet detection sensor 3 is disposed on one side wall (upper side wall in FIG. 1) of the conveyance path R on the downstream side of the entry sensor 2 in the conveyance path R. This paper sheet detection sensor 3 includes a magnetized body (magnetizing means) 31 and a magnetic detection section (magnetic detection means) 32, and a magnetic printing section printed on a paper sheet W transported along the transport path R. It detects the amount of magnetism.

  The paper sheet detection sensor 3 is configured integrally with a magnetized body 31 and a magnetic detection unit 32 housed in a case 33. The magnetized body 31 is configured, for example, by standing three square columnar permanent magnets in parallel at a predetermined interval along a direction orthogonal to the transport direction S of the paper sheet W. Here, as the permanent magnet, for example, a rare earth magnet having excellent magnetic properties such as a samarium / cobalt magnet or a neodymium magnet is used, and has a magnetic field strength higher than the coercive force of the magnetic material of the paper sheet W. is there. The permanent magnet at the center position constituting the magnetized body 31 is erected in such a manner that the magnetic pole surface on the detection side facing the conveyance path R is an S pole and the opposite side is an N pole. The permanent magnets arranged on both sides of the central permanent magnet are erected in such a manner that the magnetic pole surface on the detection side is the N pole and the opposite side is the S pole. Thereby, the magnetized body 31 is a magnetic printing part of the paper sheet W which passes the magnetic field which goes to the south pole which is the detection side of the permanent magnet of the center position from the north pole which is the detection side of the permanent magnet of both sides to the conveyance path R. To be applied.

  The magnetic detection unit 32 is provided on the downstream side of the magnetized body 31 in the transport path R. The magnetic detection unit 32 is constituted by, for example, a magnetic impedance element or a thin film fluxgate type magnetic detection element. Such a magnetic detection unit 32 is driven in an energized state based on the command signal output from the magnetic detection unit driving unit 5, and the magnetic printing unit of the paper sheet W is tinged by application by the magnetized body 31. The magnetic field generated by the residual magnetism is detected. A magnetic shield member (not shown) is provided around the magnetic detection unit 32. The magnetic shield member is made of, for example, permalloy, amorphous, or the like, and is for suppressing the magnetic field spreading from the magnetized body 31.

  The case 33 is a housing that houses the magnetized body 31, the magnetic detection unit 32, and the like. The case 33 is made of a material such as a resin that transmits a magnetic field and is a non-magnetic material.

  The entry detection unit 4 is connected to the entry sensor 2 and detects the entry of the sheet W based on the signal output by the entry sensor 2 detecting the entry of the sheet W.

  The magnetic detection unit drive unit 5 is connected to each of the entry detection unit 4 and the magnetic detection unit 32, and the magnetic detection unit 32 is based on a signal output by the entry detection unit 4 detecting the entry of the paper sheet W. A command signal for driving the motor is output.

  The signal processing circuit 7 is connected to the magnetic detection unit 32 through the magnetic detection circuit 6, and is compared with a reference value stored in advance based on a detection signal output by the magnetic detection unit 32 detecting a magnetic field. The authenticity of the paper sheet W is determined by determining whether it is within the allowable range.

  FIG. 2 is a schematic cross-sectional side view showing the transport system of the paper sheet identification apparatus 1 described above. As shown in FIG. 2, the transport path R has an insertion port R <b> 1 that opens toward the front of the paper sheet identification device 1. The paper sheet W is input from the input port R1. In addition, the transport path R has an upstream portion R2 that faces backward from the input port R1 and faces the transport direction S upward from there. Further, the transport path R has a downstream portion R3 that is folded back from the upper end of the upstream portion R2 and faces the transport direction S downward. And in the lower end of downstream part R3, storage R4 for storing the paper sheet W conveyed to the conveyance path R is provided. In such a conveyance path R, conveyance rollers R5 and R6 constituting a conveyance unit are provided at the folded portion between the upstream portion R2 and the downstream portion R3 and the lower end portion of the downstream portion R3 before the storage R4. It is. The conveying roller R5 provided in the turning portion between the upstream portion R2 and the downstream portion R3 exposes the outer peripheral surface to the upstream portion R2 and the downstream portion R3, and each of the driven rollers constituting the conveying means by the exposed portion. It is in contact with R7 and R8. Further, the conveying roller R6 provided at the lower end of the downstream portion R3 in front of the storage R4 has an outer peripheral surface exposed to the downstream portion R3, and this exposed portion abuts on a driven roller R9 constituting the conveying means. Yes. The transport rollers R5 and R6 are rotationally driven in conjunction with a drive source (not shown) such as a drive motor. When the transport rollers R5, R6 are driven to rotate, the driven rollers R7, R8, R9 are driven accordingly.

  In the transport system, the approach sensor 2 is provided in the upstream portion R2 from the input port R1 to the portion where the transport roller R5 and the driven roller R7 come into contact. Further, in the transport system, the paper sheet detection sensor 3 is provided in a downstream portion R3 between a portion where the transport roller R5 and the driven roller R8 are in contact with a portion where the transport roller R6 and the driven roller R9 are in contact. .

  Further, an abutting member 9 as an adhering material removing means is provided at an upper position in the upstream portion R2 of the conveying system immediately downstream of a portion where the conveying roller R5 and the driven roller R7 abut. The contact member 9 is made of a fiber made of a synthetic resin material such as nylon (R), animal hair, or the like, and is formed into a brush shape as shown in FIG. 3, or a nonwoven fabric. The abutting member 9 extends from both inner walls of the transport path R so as to face the thickness direction of the paper sheet W, and can contact the front and back surfaces of the paper sheet W transported to the transport path R. An interval is provided to allow the leaves W to pass therethrough. The abutting member 9 is made of a non-magnetic material such as a resin that does not cause a load on the paper sheet W and has elasticity so that the paper sheet W can be appropriately contacted and does not generate magnetization. Is preferred. Further, an adhering matter accommodating portion 10 communicating with the conveyance path R is provided at a position below the upstream portion R2 of the conveyance system.

  In such a transport system, the paper sheet W input from the input port R1 comes into contact with the transport roller R5 that is driven to rotate in the forward rotation (counterclockwise in FIG. 2) direction in the upstream portion R2. The paper is conveyed in the conveying direction S (upward) while being sandwiched between the driven rollers R7. Then, the paper sheet W is sandwiched between the transport roller R5 that is driven to rotate counterclockwise in FIG. 2 and the driven roller R8 that is in contact with the transport roller R5 at the upper end of the downstream portion R3, and the transport direction S (downward). It is conveyed toward. Further, the paper sheet W is conveyed to the storage R4 while being sandwiched between a conveyance roller R6 that is driven to rotate counterclockwise in FIG. The The transport rollers R5 and R6 are also driven to rotate in the reverse direction (clockwise in FIG. 2). For example, when the paper sheet W is a container, the transport rollers R5 and R6 are rotationally driven in the reverse direction and are carried out from the insertion port R1.

  The paper sheet identification device 1 determines the authenticity of the paper sheet W conveyed as follows.

  When the paper sheet W transported by the transport means is input from the input port R1 of the transport path R, the ingress sensor 2 detects it and outputs it as a signal to the ingress detection unit 4 to detect that it has entered. The When the signal indicating that the sheet W has entered the magnetic detection unit driving unit 5 is output from the entry detection unit 4, the magnetic detection unit driving unit 5 drives the magnetic detection unit 32 of the paper sheet detection sensor 3. A command is output, and the magnetic detection unit 32 is energized and driven. Further, the transport rollers R5 and R6 of the transport means are rotationally driven in the forward rotation direction.

  When the sheet W reaches the downstream portion R3 that has entered the conveyance path R and reaches the region where the magnetic field of the magnetized body 31 reaches, the sheet detection sensor 3 is centered from the N poles of the permanent magnets on both sides of the magnetized body 31. A magnetic field toward the south pole of the permanent magnet at the position is applied through the case 33 to magnetize the magnetic printing portion of the paper sheet W. The paper sheet W in which the magnetic printing unit is magnetized is conveyed on the conveyance path R as it is.

  Then, the magnetic detection unit 32 in the energized state detects a magnetic field generated by the residual magnetism of the magnetic printing unit, and outputs the detection result as a detection signal to the signal processing circuit 7 through the magnetic detection circuit 6, and then the energized state. Is released and the camera enters a standby state. In the signal processing circuit 7, based on the detection signal output from the magnetic detection unit 32, it is compared with a reference value stored in advance to determine whether it is within a predetermined allowable range, and the authenticity of the paper sheet W is determined. Determine.

  In such a paper sheet identification apparatus 1, the contact member 9 contacts the front and back surfaces of the paper sheet W in the upstream portion R2 of the transport path R in the process of transporting the paper sheet W to the transport path R. To do. For this reason, as shown in FIGS. 4 (a) and 4 (b), magnetic substance deposits such as iron sand and iron powder adhering to the front and back surfaces of the paper sheet W (hereinafter simply referred to as “deposits” as appropriate). F) is removed. As a result, since the deposit F is removed in advance before the paper sheet W reaches the paper sheet detection sensor 3, the deposit F adheres to the wall surface of the conveyance path R that is the magnetized portion of the magnetized body 31. It becomes possible to prevent the situation. Therefore, the magnetic field of the paper sheet W applied by the magnetized body 31 does not fluctuate greatly, and the residual magnetism of the paper sheet W can be detected well.

  If the contact member 9 is elastic, the contact member 9 is deformed in the transport direction S of the paper sheet W as shown in FIG. The deposit F is flipped downward by the elastic deformation returning to the original. As a result, since the deposit F that can remain on the contact member 9 is reduced, the removal performance of the deposit F on the contact member 9 can be maintained.

  Further, since the contact member 9 is provided immediately downstream of the portion where the transport roller R5 and the driven roller R7 are in contact, a frictional force is generated when the paper sheet W passes through the portion of the contact member 9. Also, the paper sheet W can be conveyed against the frictional force. Further, since the transport roller R5 and the driven roller R7 resist the frictional force of the contact member 9, it is preferable to use a roller having a larger diameter than other rollers so that the transport force is increased.

  In addition to the iron sand and iron powder, the contact member 9 also removes non-magnetic material adhering to the front and back surfaces of the paper sheet W, so that the paper that has passed through the transport path R is removed. The leaves W can be kept clean.

  Further, the contact member 9 is disposed in the upstream portion of the transport path R facing the transport direction S and the paper sheet detection sensor 3 is disposed in the downstream portion of the transport path R. The situation of reaching the position of the paper sheet detection sensor 3 can be prevented.

  Further, the deposit removed by the contact member 9 is accommodated in the deposit accommodating portion 10. As a result, it is possible to prevent the removed deposits from adhering to the other paper sheets W fed from the slot R1.

Further, in the form status of this embodiment are removed deposits F adhered to the sheet W at the upstream portion R2. For this reason, it becomes possible to prevent the situation where the deposit F adheres to each roller of the downstream portion R3. As a result, the paper sheet W is clogged due to a decrease in the conveying force due to dirt on the roller surface, or the paper sheet W is skewed due to a decrease in the conveyance balance due to dirt on the roller surface, and the paper sheet W is clogged. The situation that occurs is prevented, and a highly reliable paper sheet identification device can be provided.

< Reference Example 1 >
FIG. 5 is a schematic sectional side view showing a paper sheet identification apparatus according to Reference Example 1 of the present invention. In Reference Example 1 described below, the deposit removal means form on purpose basic structure of embodiments described above are the same different. Therefore, about the same part, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

The adhering matter removing means here includes a magnet 11 arranged with the magnetic pole surface facing the conveyance path R side. The magnet 11 is a permanent magnet and employs a magnet whose magnetic force is stronger than that of the magnetized body 31. This magnet 11 is disposed upstream of the conveyance path R, and upstream of the portion where the conveyance roller R5 and the driven roller R7 are in contact with each other in the first reference example. The magnetic pole face is disposed in close contact with the wall.

  In such a paper sheet identification device 1, in the process of determining the authenticity of the paper sheet W, the paper sheet W being transported to the transport path R as shown in FIG. Passes through the part where the magnet 11 is arranged in the upstream portion R2. For this reason, as shown in FIG. 6B, magnetic substance deposits such as iron sand and iron powder (hereinafter, simply referred to as “adhesions”) F attached to the front and back surfaces of the paper sheet W are present. It is attracted and removed by the magnet 11. As a result, since the deposit F is removed in advance before the paper sheet W reaches the paper sheet detection sensor 3, the deposit F adheres to the wall surface of the conveyance path R of the part where the magnetized body 31 is provided. It becomes possible to prevent. Therefore, the magnetic field of the paper sheet W applied by the magnetized body 31 does not fluctuate greatly, and the residual magnetism of the paper sheet W can be detected well.

  Moreover, since the magnet 11 employs a magnet whose magnetic force is stronger than that of the magnetized body 31, it is possible to appropriately attract the deposit F that can be attracted by the magnetized body 31.

Further, in the first reference example , the deposit F attached to the paper sheet W is removed immediately after the insertion port R1 and upstream of the portion where the transport roller R5 and the driven roller R7 abut. For this reason, it is possible to prevent a situation where the deposit F adheres to each of the rollers R5, R6, R7, R8, and R9. As a result, the paper sheet W is clogged due to a decrease in the conveying force due to dirt on the roller surface, or the paper sheet W is skewed due to a decrease in the conveyance balance due to dirt on the roller surface, and the paper sheet W is clogged. The situation that occurs is prevented, and a highly reliable paper sheet identification device can be provided.

< Reference Example 2 >
FIG. 7 is a schematic sectional side view showing a paper sheet identification apparatus according to Reference Example 2 of the present invention. In Example 2 described below, the deposit removal means form on purpose basic structure of embodiments described above are the same different. Therefore, about the same part, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  The deposit removing means here is mainly composed of a rotating body 12. The rotating body 12 is a cylindrical roller, and has an abutting member 13 along the circumferential direction on the outer peripheral portion thereof. The contact member 13 is made of a fiber made of a synthetic resin material such as nylon (R), a material in which animal hair extends radially from the outer peripheral portion of the rotating body 12, or a non-woven fabric. It is made up of things wound around the part. The rotating body 12 is located at a position facing the paper sheet detection sensor 3 across the transport path R, and is directed to the outside of the transport path R so that the outer peripheral portion does not contact the paper sheet W. It is provided so as to be rotatable around an axis. Further, the contact member 13 provided on the rotating body 12 is in contact with a magnetized portion (a wall surface of the transport path R) where the magnetized body 31 in the paper sheet detection sensor 3 faces the transport path R. When the rotating body 12 rotates, the contact member 13 constantly comes into contact with the magnetized portion of the magnetized body 31. Note that the abutting member 13 has elasticity so as not to be a load for transporting the paper sheet W and can be appropriately brought into contact with the magnetized portion of the magnetized body 31, and is a non-magnetic material such as a resin that does not generate magnetization. Preferably it consists of.

  The rotating body 12 rotates in synchronization with the transport roller R5, which is a transport unit, by the drive transmission unit. As shown in FIG. 7, the drive transmission means includes an endless belt 14 that is wound around the shaft of the transport roller R <b> 5 and the shaft of the rotating body 12. That is, when the transport roller R5 is rotationally driven by a drive source (not shown) such as a drive motor, the rotator 12 rotates in synchronization with the endless belt 14. This drive transmission means may be an endless belt wound around the shaft of the transport roller R6 and the shaft of the rotating body 12 although not explicitly shown in the drawing. The drive transmission means is not limited to the endless belt 14 but is not clearly shown in the drawing, but a drive gear provided on the shaft of the transport roller R5 (or the transport roller R6), a driven gear provided on the shaft of the rotating body 12, And you may comprise by the intermediate gear which meshes | engages between a drive gear and a driven gear.

  Further, a magnet 15 is provided outside the transport path R and on the side of the rotating body 12 opposite to the paper sheet detection sensor 3. The magnet 15 is a permanent magnet and employs a magnet whose magnetic force is stronger than that of the magnetized body 31. The abutting member 13 deviating to the outside of the transport path R contacts the magnetic pole surface of the magnet 15 at a position outside the transport path R.

  In such a paper sheet identification device 1, in the process of determining the authenticity of the paper sheet W, the paper sheet detection sensor 3 uses the magnetic force of the magnetized body 31 to convey the conveyance path as shown in FIG. Magnetic material deposits such as iron sand and iron powder (hereinafter referred to as “adhesions” as appropriate) F adhering to the paper sheet W conveyed to R are attracted.

  In such a case, in the paper sheet identification apparatus 1 described above, after the paper sheet W has passed the position of the paper sheet detection sensor 3, as shown in FIG. The abutting member 13 provided on the rotating body 12 comes into contact with the magnetized portion (the wall surface of the transport path R) of the magnetized body 31 in the paper sheet detection sensor 3. For this reason, as shown in FIG. 8C, the deposit F attracted to the magnetized portion of the magnetized body 31 is wiped off by the abutting member 13 that moves as the rotating body 12 rotates. In this case, if the abutting member 13 has elasticity, the abutting member 13 is deformed as shown in FIG. 8B, and then attached by elastic deformation returning to the original as shown in FIG. 8C. Kimono F will be paid off. As a result, since the deposit F is removed immediately after being attracted to the magnetized portion of the magnetized body 31 in the paper sheet detection sensor 3, it is possible to prevent the deposit F from adhering to the magnetized portion of the magnetized body 31. It becomes possible. Therefore, the magnetic field of the paper sheet W applied by the magnetized body 31 does not fluctuate greatly, and the residual magnetism of the paper sheet W can be detected well.

  Furthermore, in the paper sheet identification device 1 described above, the rotating body 12 is disposed in a manner in which the contact member 13 deviates from the outside of the transport path R, and the contact member 13 is positioned at a position outside the transport path R. The magnet 15 which contacts is provided. For this reason, as shown in FIG. 8D, the deposit F remaining on the contact member 13 is attracted and collected by the magnetic force of the magnet 15. As a result, it is possible to prevent the deposit F remaining on the contact member 13 from being attracted again by the magnetic force of the magnetized body 31 due to the rotation of the rotating body 12 and attached to the magnetized portion of the magnetized body 31. Therefore, the magnetic field of the paper sheet W applied by the magnetized body 31 does not fluctuate greatly, and the residual magnetism of the paper sheet W can be detected well.

It is the schematic which showed typically the paper sheet identification device which concerns on this invention. It is a schematic cross sectional side view of the transfer system of the paper sheet recognition apparatus according to the shape condition of the present invention. It is an enlarged view of the contact member shown in FIG. The operation of the paper sheet recognition apparatus according to the shape condition of the present invention is a schematic diagram showing. It is a schematic sectional side view which shows the paper sheet identification device which concerns on the reference example 1 of this invention. It is the schematic which shows the effect | action of the paper sheet identification device which concerns on the reference example 1 of this invention. It is a schematic sectional side view which shows the paper sheet identification device which concerns on the reference example 2 of this invention. It is the schematic which shows the effect | action of the paper sheet identification device which concerns on the reference example 2 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Paper sheet identification device 2 Ingress sensor 3 Paper sheet detection sensor 31 Magnetized body 32 Magnetic detection part 33 Case 4 Ingress detection part 5 Magnetic detection part drive part 6 Magnetic detection circuit 7 Signal processing circuit 9 Contact member 10 Adherence accommodation Part 11 Magnet 12 Rotating body 13 Contact member 14 Endless belt 15 Magnet F Adherent R Transport path R1 Input port R2 Upstream part R3 Downstream part R4 Storage R5, R6 Transport roller R7, R8, R9 Follow roller S Transport direction W Paper sheets

Claims (3)

A transport path for transporting a paper sheet having a magnetic material;
Magnetizing means for applying a magnetic field to the magnetic material of the paper sheet, and magnetic detecting means for detecting the residual magnetism of the magnetic material of the paper sheet by applying the magnetic field of the magnetizing means. In a paper sheet identification device having a magnetic sensor
Located near the downstream of the transport means for transporting the paper sheet to the transport path and upstream of the magnetic sensor , and is provided in a manner fixed to the wall constituting the transport path, and passes through the transport path. Includes a deposit removing means for removing deposits on the magnetic material attached to the paper sheet ,
The adhering matter removing means includes a brush-like contact member that extends in the thickness direction of the paper sheet from the wall of the transport path toward the transport path and is provided so as to be able to contact the paper sheet. Characteristic paper sheet identification device. The paper sheet identification apparatus according to claim 1, wherein the deposit removing means is disposed upstream of the transport path with the transport direction directed upward, and a magnetic sensor is disposed downstream of the transport path. The paper sheet identification apparatus according to claim 2, further comprising a deposit container that receives deposits removed by the deposit removing means at a position below the upstream portion of the transport path.

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