JP2023069108A - Paper sheet processing device - Google Patents

Abstract

To provide a paper sheet processing device that provides a sense of safety for a user who handles paper sheets such as bills and a manager of the device and keeps the paper sheets such as bills clean in order to cope with the possibility that bacteria and virus may be attached to the paper sheets such as bills deposited through a money depositing port.SOLUTION: A bill deposited through a money depositing port 16 is subjected to identification of denomination and authenticity, and is then transported between a first UV radiation unit 21 and a second UV radiation unit 22. The first UV radiation unit 21 and the second UV radiation unit 22 radiate UV rays to the bill being transported for sterilization. A paper sheet processing device 1 includes a storage part that stores a bill for each denomination. The bill after sterilization is stored in any of a first bill storage unit 13 to a third bill storage unit 15 corresponding to the denomination. Thus, it is possible to provide a paper sheet processing device that sterilizes the bill and keeps the bill clean.SELECTED DRAWING: Figure 1

Description

The present invention relates to a paper sheet processing apparatus. More particularly, the present invention relates to a paper sheet processing apparatus having a paper sheet sterilization function.

Paper sheets such as money and securities have opportunities to come into contact with various people and things, and there is a possibility that microorganisms such as bacteria and viruses may adhere to them. A user of a paper sheet processing apparatus or an administrator of the apparatus may come into contact with money on which microorganisms such as bacteria and viruses are attached. From a sanitary point of view, it is desirable to sterilize bills used in the paper sheet processing apparatus.

In order to solve such problems, there is known a paper sheet processing apparatus equipped with a sterilization means for sterilizing bacteria and viruses adhering to paper sheets. As a method for sterilizing bacteria and viruses adhering to paper sheets, sterilization methods using heating, ultraviolet rays, chemical application, etc. are already known.

As a device having a banknote sterilization function, for example, Japanese Patent Application Laid-Open No. 2013-105481 describes a device that sterilizes banknotes inserted from a banknote slot using an ultraviolet irradiator. The banknotes are irradiated with ultraviolet rays while being conveyed between the ultraviolet irradiators arranged opposite to each other. Banknotes are sterilized by ultraviolet light.

JP 2013-105481 A

In the prior art, a curved reverse guide is provided between the first and second conveyor belts, and slits are provided in the course of the reverse guide. An ultraviolet irradiator for irradiating ultraviolet rays is placed facing the slit. The bills conveyed from the first conveying belt are irradiated with ultraviolet rays in the reverse conveying path and supplied to the second conveying belt. However, the details of the structure and mounting method of the ultraviolet irradiation device are not described. Moreover, the sterilization ability is proportional to the exposure dose of the ultraviolet rays irradiated to the bill. Therefore, it is desired that the banknotes are sufficiently irradiated with ultraviolet rays by the ultraviolet irradiator without spots.

In addition, maintenance work is required to solve problems such as when the ultraviolet ray irradiator breaks down or when paper money is jammed. If bills are jammed between the opposing UV irradiators, it is difficult to remove the bills. A device capable of separately maintaining each of the opposing ultraviolet irradiators is desired.

The paper sheet processing apparatus of the present invention is connected to a deposit port for depositing paper sheets, a withdrawal port for withdrawing the paper sheets, and connected to the deposit port and the withdrawal port to receive the paper sheets. a conveying unit for conveying, an identification unit arranged in the middle of the conveying path of the paper sheets to identify the denomination of the paper sheets, and a sterilization unit arranged in the middle of the conveying path to sterilize the paper sheets and a storage unit arranged in the middle of the conveying path for storing and discharging the paper sheets, wherein the paper sheets identified by the identification unit and sterilized by the sterilization unit are In a paper sheet processing apparatus stored in a storage section, a first ultraviolet irradiation unit disposed in the sterilization section and including a first light source for irradiating ultraviolet rays on one surface of the conveyed paper sheet; a second ultraviolet irradiation unit disposed in a sterilization section, facing the first ultraviolet irradiation unit, and including a second light source for irradiating the other side surface of the conveyed paper sheet with ultraviolet rays; a first support portion disposed between the light source and the second light source and between the first light source and the conveyed paper sheet for supporting the conveyed paper sheet; A second light source disposed between the first light source and the second light source and between the second light source and the conveyed paper sheet for supporting the conveyed paper sheet and a support portion, wherein the paper sheets conveyed between the first support portion and the second support portion are irradiated with ultraviolet rays emitted from the first light source and the second light source. It is characterized by being sterilized.

According to the present invention, both the front and back surfaces of paper sheets such as bills are sufficiently irradiated with ultraviolet rays without spots and are sterilized. By sterilizing conveyed paper sheets in the middle of the conveying path, users who handle paper sheets and administrators of the equipment can feel secure. can provide. Further, according to the present invention, the opposing ultraviolet irradiators can be maintained separately. In addition, when paper sheet jam occurs between the facing ultraviolet ray irradiators, the paper sheet conveyance path including the ultraviolet ray irradiators can be easily maintained because the conveying path can be opened and closed.

FIG. 1 is a first perspective view for explaining the paper sheet processing apparatus. FIG. 2 is a second perspective view for explaining the paper sheet processing apparatus. FIG. 3 is a perspective view explaining the conveyance of banknotes. FIG. 4 is a diagram illustrating the UV irradiation unit. FIG. 5 is a diagram illustrating another example of the UV irradiation unit. FIG. 6 is a diagram illustrating another example of the UV irradiator. FIG. 7 is a diagram illustrating another example of the paper sheet processing apparatus.

An embodiment of the present invention will be described in detail below with reference to FIGS. 1 to 7. FIG. Each drawing is merely a schematic representation to the extent that the present invention can be fully understood. Accordingly, the present invention is not limited to the illustrated examples only. Moreover, in each figure, the same code|symbol is attached|subjected about a common component and a similar component, and those overlapping description is abbreviate|omitted. In addition, paper sheets include bills and securities. A processing device for handling banknotes will be described as an example of a paper sheet processing device.

First, the banknote transport path of the paper sheet processing apparatus will be described. FIG. 1 is a first perspective view for explaining the paper sheet processing apparatus. FIG. 1 is a diagram showing a state in which an openable and closable portion of the paper sheet processing apparatus is opened, and the banknote transport path is visible.

A paper sheet processing apparatus 1 is provided with a frame 2 to which various parts are attached. A lower conveying unit 3 is connected to the frame 2 with a lower conveying unit shaft 5 as a rotation center. A lower damper 6 is provided between the frame 2 and the lower transport unit 3 . An upper transport unit 4 is connected to the lower transport unit 3 with an upper transport unit shaft 8 as a rotation center. An upper damper 9 is provided between the lower transport unit 3 and the upper transport unit 4 . FIG. 1 shows a state in which the lower transport unit 3 is closed and the upper transport unit 4 is open.

The lower transport unit 3 rotates up and down around the lower transport unit shaft 5 with respect to the frame 2 . The lower damper 6 is preferably a damper with a stopper. The upper transport unit 4 rotates up and down around the upper transport unit shaft 8 with respect to the lower transport unit 3 . The upper damper 9 is preferably a damper with a stopper. A lower opening/closing lever 7 is provided in the lower conveying unit 3 . By operating the lower opening/closing lever 7 , the lower conveying unit 3 can be fixed to and released from the frame 2 . For example, by twisting the lower opening/closing lever 7, the lower transport unit 3 fitted in the frame 2 can be removed and opened.

The upper transport unit 4 is equipped with a separation unit 10 , an upper identification unit 11 and a UV unit base 12 . One end side of the upper identification unit 11 is rotatably connected to the upper identification unit shaft 29 and rotates. The UV unit base 12 has a connecting portion on one end side and is connected to a UV unit base shaft 28 to rotate. One end of the separation unit 10 is rotatably connected to a shaft and rotates. FIG. 1 shows the state in which the separation unit 10 is closed, the upper identification unit 11 is open, and the UV unit base 12 is open. In the upper transport unit 4, a separation unit 10 and an upper identification unit 11 are arranged adjacent to each other, and an upper identification unit 11 and a UV unit base 12 are arranged adjacent to each other.

The upper transport unit 4 includes a deposit port 16 for depositing bills and a withdrawal port 17 for dispensing bills. The withdrawal port 17 is adjacent to the withdrawal tray 18 when the upper transport unit 4 is closed. A plurality of banknotes can be piled up and deposited into the deposit port 16.例文帳に追加Deposited banknotes enter the separation unit 10, and the separation unit 10 separates the deposited banknotes one by one. The separating unit 10 can also be said to be a separating section that separates the deposited banknotes one by one and conveys the banknotes one by one to the identification section that is the next process.

A plurality of pressure rollers 20 are arranged in the banknote transport path. The pressing roller 20 is arranged at a position facing the conveying belt 19 . The pressing roller 20 is urged by a spring (not shown) in the direction of the conveying belt 19 . The upper transport unit 4 is provided with a motor (not shown) that drives the transport belts 19 arranged in parallel. The banknotes discharged from the separation unit 10 are sandwiched between the transport belt 19 and the pressure roller 20 and transported. The upper transport unit 4 has an upper transport path 26 and the lower transport unit 3 has a lower transport path 27 . Bills are conveyed on the upper conveying path 26 and the lower conveying path 27 . Each of the separation unit 10, the upper identification unit 11, and the UV unit base 12 is provided with a plurality of pressure rollers 20, and the pressure rollers 20 contact the conveying belt 19 when closed. The conveying belt 19 and the pressing roller 20 are also rotating bodies driven by a motor (not shown).

The upper identification unit 11 is provided with a pressing roller 20 . The pressure roller 20 contacts the conveyor belt 19 when the upper identification unit 11 is closed. Inside the upper identification unit 11, a sensor (not shown) is arranged to detect the denomination and authenticity of bills. A sensor 25 for detecting the denomination and authenticity of bills is also arranged in a portion of the upper transport unit 4 facing the upper identification unit 11 .

The denomination and authenticity of the banknotes discharged from the separation unit 10 are identified by the upper identification unit 11 and the sensor 25 arranged at a position facing the upper identification unit 11 of the upper transport unit 4 . The area in which the upper identification unit 11 is arranged in the bill transport path can be said to be an identification section for identifying the denomination and authenticity of the bill.

Banknotes whose denomination and authenticity have been detected are transported to the sterilization section. The sterilization unit irradiates the banknotes with ultraviolet rays to sterilize them. The sterilization section is arranged after the identification section. The portion of the banknote transport path where the UV unit base 12 is arranged can also be called a sterilization section.

A pressing roller 20 is provided on the UV unit base 12 . The pressing roller 20 contacts the conveying belt 19 when the UV unit base 12 is closed. A second UV irradiation unit 22 is arranged on the UV unit base 12 . The third side wall 32 is provided with a recess so as to avoid a portion protruding from the UV unit base 12. - 特許庁The first UV irradiation unit 21 is arranged at a position corresponding to the second UV irradiation unit 22 of the upper transport unit 4 . The first UV irradiation unit 21 has a first light source that emits ultraviolet rays, and the second UV irradiation unit 22 has a second light source that emits ultraviolet rays. The ultraviolet rays emitted from the first UV irradiation unit 21 mainly sterilize one surface of the bill, and the ultraviolet rays emitted from the second UV irradiation unit 22 mainly disinfect the other surface of the bill. The ultraviolet rays irradiated to the other side of the banknote include the ultraviolet rays irradiated from the first UV irradiation unit 21 and reflected by the reflector of the second UV irradiation unit 22, but most of the ultraviolet rays are irradiated from the second UV irradiation unit 22. UV rays. Similarly, the ultraviolet rays irradiated to one surface of the bill include the ultraviolet rays irradiated from the second UV irradiation unit 22 , but mostly the ultraviolet rays irradiated from the first UV irradiation unit 21 . In addition, it is preferable not to consider reflected light, which may cause uneven irradiation of ultraviolet rays, when determining the amount of ultraviolet rays necessary for sterilizing banknotes. It is preferable that the amount of ultraviolet rays required for sterilization is ensured by the amount of ultraviolet rays that are directly irradiated from the light source to the banknotes.

The pressing rollers 20 provided on the UV unit base 12 are arranged upstream and downstream of the first UV irradiation unit 21 and the second UV irradiation unit 22 in the banknote conveying direction, respectively. The distance between the pressing rollers 20 in the bill transport direction is shorter than the length of the bill to be transported. The banknote is sandwiched between at least one of the pressure rollers 20 arranged on the upstream side and the downstream side in the banknote transport direction and the transport belt 19 and transported. The bill to be conveyed is irradiated with ultraviolet rays while being conveyed by the pressing roller 20 and the conveying belt 19 arranged on the upstream side in the conveying direction. After that, the sheet is irradiated with ultraviolet rays while being conveyed by the pressure rollers 20 and the conveying belt 19 arranged on the upstream side and the downstream side in the conveying direction. After that, it is irradiated with ultraviolet rays while being conveyed by the pressure roller 20 and the conveying belt 19 arranged downstream in the conveying direction. Further, in order to shorten the transport path of the banknotes, when the transported banknotes are irradiated with ultraviolet rays while being transported by the pressure roller 20 and the transport belt 19 arranged on the upstream side in the transport direction, the upper identification unit 11, it is preferably also conveyed by the pressure roller 20 and the conveying belt 19 arranged on the most downstream side in the conveying direction. Further, when the ultraviolet rays are irradiated while being conveyed by the pressure roller 20 and the conveying belt 19 arranged on the upstream side and the downstream side in the conveying direction, the upper identification unit 11 arranged on the most downstream side in the conveying direction. It is more preferable that the sheet is also conveyed by the pressing roller 20 and the conveying belt 19 . Conveyance of banknotes is stabilized. In addition, there is a gap in the banknote transport path between the upper transport path 26 and the UV unit base 12, through which the transport belt 19 and the pressing roller 20 are irradiated with ultraviolet rays. The inside of the transport path can be sterilized. Also, a notch may be provided in the upper transport path 26 or the UV unit base 12 to form a gap.

The first UV irradiation unit 21 and the second UV irradiation unit 22 are intended to sterilize bills. It is preferable that the ultraviolet rays with which the bill is irradiated are ultraviolet rays in the UVC region having a wavelength of 200 nm or more and 280 nm or less. It is preferable that ultraviolet rays having a wavelength of 200 nm or more and 280 nm or less account for more than half of the amount of ultraviolet rays. Moreover, it is preferable that the peak of the spectrum of the ultraviolet light source is in the wavelength range of 200 nm or more and 280 nm or less. Among them, ultraviolet rays having a wavelength of about 260 nm, for example, 240 nm or more and 280 nm or less are particularly preferable because they have a high sterilizing effect. In order to reduce the attenuation of ultraviolet rays, it is preferable that there is no intervening object between the banknotes. However, since banknotes must be stably transported, a transport support section 34, which will be described later, is arranged. In addition, the smaller the area that blocks ultraviolet rays, the better. The transport support part 34 is preferably a thin plate or thin wire having a linear contact part with the banknote. If quartz glass is used, ultraviolet rays are less attenuated, so a plate made of quartz glass is preferable when a cover is used. Ultraviolet rays in the UVC region are not preferable because they are greatly attenuated by a resin cover.

When the upper identification unit 11 and the UV unit base 12 are in a closed state, their respective side faces face the third side wall 32 and the fourth side wall 33 erected from both ends of the upper transport path 26 . The upper identification unit 11 and the UV unit base 12 enter between the third side wall 32 and the fourth side wall 33 when closed. When the paper sheet processing apparatus 1 is in use, the separation unit 10, the upper identification unit 11 and the UV unit base 12 are horizontally arranged in a line on the upper transport unit 4. As shown in FIG. A UV unit base 12 is horizontally adjacent to the rear stage of the upper identification unit 11 . That is, the identification section and the sterilization section are horizontally adjacent to each other. By arranging in this way, the front end side of the conveyed banknote is sterilized by the sterilization section while the rear end side is detected by the sensor of the identification section. Since the banknote being identified can be sterilized, the banknote transport path can be shortened.

When performing maintenance work, if the cord crosses the upper conveying path 26, workability is deteriorated. Therefore, the UV unit base 12 can be opened and closed in the bill conveying direction about the UV unit base shaft 28 arranged downstream in the bill conveying direction. A cord or the like connected to the UV unit base 12 can be prevented from crossing the upper conveying path 26, which is the bill conveying path, by opening and closing the UV unit base 12.例文帳に追加Further, since the second UV irradiation unit and the pressing roller 20 are arranged on the UV unit base 12, the banknotes are released from the pressure by opening the UV unit base 12, and the banknotes can be easily removed.

Banknotes conveyed one by one from the separating unit 10 are conveyed along the linearly arranged upper conveying path 26, the denomination and authenticity of the bills are identified by the identifying unit, and then sterilized by the sterilizing unit. The sterilized bills are conveyed along the conveying path curved downward, folded back, and conveyed along the lower conveying path 27 . Conveyed banknotes are prevented from deviating from the conveying path by the third side wall 32 and the fourth side wall 33 in the upper conveying path 26 and by the first side wall 30 and the second side wall 31 in the lower conveying path 27 .

Two transport belts 19 are arranged in parallel on the side of the upper transport unit 4 facing the lower transport path 27 . A plurality of pressure rollers 20 are arranged at positions corresponding to the transport belts 19 on the lower transport path 27 . The pressing roller 20 is urged in the direction of the conveying belt 19 by a spring (not shown). The banknotes are conveyed while being sandwiched between the conveying belt 19 and the pressure roller 20 .

A first banknote storage unit 13, a second banknote storage unit 14, and a third banknote storage unit 15 are detachably provided below the lower transport unit 3. As shown in FIG. The lower transport unit 3 has a storage unit entrance 23 that changes the transport direction of the transported bills and takes in the bills from the lower transport path 27 and a storage unit exit 24 that delivers the stored bills to the lower transport path 27 . Prepared. The storage unit entrance 23 and the storage unit exit 24 are arranged corresponding to the first banknote storage unit 13, the second banknote storage unit 14, and the third banknote storage unit 15, respectively.

Discharged banknotes are superimposed on the withdrawal tray 18 . Banknotes transported later are stacked on the banknotes placed on the dispensing tray 18 . The end of the withdrawal tray 18 is adjacent to the withdrawal port 17 when the upper transport unit 4 is closed. Banknotes placed on the withdrawal tray 18 can be taken out from the withdrawal port 17 .

The paper sheet processing apparatus 1 is provided with a transport section for transporting banknotes including a transport belt 19 , a pressure roller 20 , an upper transport path 26 and a lower transport path 27 . The paper sheet processing apparatus 1 also includes a separation unit that separates and conveys a plurality of deposited banknotes one by one, including the separation unit 10 . Further, the paper sheet processing apparatus 1 is provided with an identification unit for identifying the denomination and authenticity of banknotes. The identification section includes the upper identification unit 11 and a sensor arranged at a portion of the upper transport unit 4 facing the upper identification unit 11 . Further, the paper sheet processing apparatus 1 is provided with a sterilization section that sterilizes banknotes with ultraviolet rays, including the first UV irradiation unit 21 and the second UV irradiation unit 22 . The paper sheet processing apparatus 1 also includes storage units that store banknotes by denomination, including a first banknote storage unit 13 , a second banknote storage unit 14 and a third banknote storage unit 15 .

For example, the paper sheet processing apparatus 1 is an apparatus for depositing and withdrawing banknotes used in an automatic change machine, an automatic payment machine, or the like. Banknotes are put into the deposit slot 16.例文帳に追加Information such as the denomination, authenticity, and number of deposited banknotes is acquired by a control unit (not shown) and used for control. Deposited banknotes are identified for denomination and authenticity, sterilized, and further stored in banknote storage units by denomination. When paying out banknotes, a control unit (not shown) calculates the denomination and number of banknotes to be paid out, and instructs the banknote storage unit to discharge the banknotes. The ejected banknotes are ejected outside the apparatus from the withdrawal port 17 .

FIG. 2 is a second perspective view for explaining the paper sheet processing apparatus. FIG. 2 shows a state in which the upper transport unit 4 is opened and the separation unit 10, the upper identification unit 11 and the UV unit base 12 of the upper transport unit 4 are closed. The upper transport unit 4 is shown opened from the lower transport unit 3 . The lower transport path 27 of the lower transport unit 3 can be exposed. Also, a state in which a front cover is attached to the front side of the frame 2 where the deposit port 16 and the withdrawal port 17 are arranged is shown.

FIG. 3 is a perspective view explaining the conveyance of banknotes. FIG. 3 shows a state in which the upper transport unit 4 is closed. 3 shows a state in which the upper identification unit 11 and the UV unit base 12 of the upper transport unit 4 are removed in order to explain the upper transport path 26. As shown in FIG. The upper transport path 26 is arranged along the horizontal direction, and the direction facing the upper transport path 26 is upward.

A dent is provided in the middle of the banknote transport path of the upper transport path 26, and the first UV irradiation unit 21 is fixed to the dent. The banknotes to be conveyed are horizontally conveyed with the front surface or the back surface facing the upper conveying path 26 . Above the first UV irradiation unit 21, a plurality of transport supports 34, which are supports for supporting the transported banknotes, are spaced apart. A space is provided between adjacent transport support portions 34 . In the first UV irradiation unit 21, a first UV lamp 38 and a second UV lamp 39, which are light emitting portions for emitting ultraviolet rays, are arranged below the transport support portion 34. As shown in FIG. A first UV connector 36 and a second UV connector 37 which are connectors for a first UV lamp 38 and a second UV lamp 39 are arranged so as to protrude from the recess of the third side wall 32 . A cord (not shown) is connected to the connector to supply power for light emission to the first UV lamp 38 and the second UV lamp 39 . The second UV irradiation unit 22 ( FIG. 1 ) also has the same configuration as the first UV irradiation unit 21 .

When the transport support part 34 is arranged along the transport direction, the transport support part 34 covers the same part of the banknote, and uneven irradiation of ultraviolet rays occurs. Therefore, the surface of the transport support portion 34 that contacts the banknote is arranged in a direction that intersects the transport direction of the banknote. The transport support portion 34 is arranged at an angle of about 5 to 10 degrees with respect to the bill transport direction. If the angle is too large, the bill cannot be supported. The transport support part 34 creates a shadow of the irradiated ultraviolet rays. By arranging the transport support portion 34 so as to be inclined with respect to the transport direction of the banknotes, the transported banknotes are irradiated with ultraviolet rays all over. Since the transport support part 34 shields the ultraviolet rays irradiated to the bill, it is preferable that the transport support part 34 is erected perpendicularly to the transport direction of the bill or is composed of thin wires. When the first UV irradiation unit 21 and the second UV irradiation unit 22 are the same, the direction of inclination of the transport support part 34 with respect to the bill transport direction of the first UV irradiation unit 21 and the transport support with respect to the bill transport direction of the second UV irradiation unit 22 The direction of inclination of the portion 34 is different. Since the directions of inclination of the transport support portions 34 of the first UV irradiation unit 21 and the second UV irradiation unit 22 are opposite to each other, the effect of the transport support portions 34 on the transport of bills is offset.

In addition, it is necessary to prevent the amount of ultraviolet rays irradiated to the conveyed banknote from greatly varying depending on the location on the surface of the banknote. Assuming that the amount of ultraviolet rays irradiated to banknotes when there is no object that blocks the ultraviolet rays from the first UV irradiation unit 21, that is, when there is no transport support section 34, is 100, the amount of ultraviolet rays when the transport support section 34 is present is The amount is preferably 50 or more, more preferably 80 or more. If it is 50 or more, if the amount of ultraviolet rays emitted is at least twice that of the ultraviolet rays, the amount of ultraviolet rays equal to or greater than that in the case where the transfer support section 34 is not provided can be obtained. The more UV light that is blocked, the more UV light needs to be emitted, and the less efficient it is. The second UV irradiation unit 22 is also similar to the first UV irradiation unit 21 . Further, the shape of the contact surface of the transport support portion 34 with the banknote is such that the center side in the transport direction of the banknote protrudes more than the upstream side and the downstream side. When the first UV irradiation unit 21 and the second UV irradiation unit 22 are opposed to each other, a portion is provided to narrow the paper money conveying path so as to reduce variations in the distance from each light source to the paper money and make it uniform. Conveyed banknotes can be prevented from leaning toward either the first UV irradiation unit 21 or the second UV irradiation unit 22 . As a result, the difference between the amount of UV irradiation on the front side of the banknote and the amount of UV irradiation on the back side of the banknote can be reduced.

The upper opening/closing lever 35 is provided in the upper transport unit 4 . By operating the upper opening/closing lever 35 , the upper transport unit 4 can be fixed to and released from the lower transport unit 3 . For example, by twisting the upper open/close lever 35, the upper transport unit 4 fitted in the lower transport unit 3 can be removed and opened.

Next, the UV irradiation unit will be described using the first UV irradiation unit 21. FIG. The first UV irradiation unit 21 and the second UV irradiation unit 22 are the same. FIG. 4 is a diagram illustrating the UV irradiation unit.

The first UV irradiation unit 21 includes a reflector 40 , a first UV lamp 38 , a second UV lamp 39 and a fixing portion 42 . The reflector 40 serves both as a reflecting mirror for reflecting ultraviolet rays and as a frame. The first UV lamp 38 includes a light emitter 44 , a first UV connector 36 and an electrode 43 . The light emitting portion 44 is curved at the curved portion 41 . The reflector 40 has a recess that is open on one side, and the bottom of the recess is surrounded by side walls.

A first UV lamp 38 and a second UV lamp 39 are fixed to the side wall of the reflector 40, and a first UV connector 36 and a second UV connector 37 protrude to the outside. Electrodes 43 are provided in the first UV connector 36 and the second UV connector 37, and drive signals are input from an external device. The reflector 40 is preferably made of aluminum, an aluminum alloy, or stainless steel in terms of weight, strength, ultraviolet reflectance, and availability. The first UV lamp 38 and the second UV lamp 39 are preferably fluorescent lamps that emit UVC. Fluorescent lamps can emit ultraviolet rays from a wide area, and can reduce unevenness in the intensity of ultraviolet rays on the irradiated surface. Ultraviolet rays emitted from the first UV lamp 38 and the second UV lamp 39 to the reflector 40 side are reflected by the reflector 40 and can be emitted to banknotes. The ultraviolet rays emitted by the reflector 40 can be utilized without waste.

The first UV lamp 38 and the second UV lamp 39 are arranged in parallel in order to increase the amount of exposure to ultraviolet rays for sufficient sterilization. The light emitting portions of the first UV lamp 38 and the second UV lamp 39 are bent in a U shape. The first UV lamp 38 and the second UV lamp 39 are arranged in a U-shape when viewed from the top in order to increase the amount of ultraviolet rays that directly hit the banknotes.

A transport support portion 34 is provided between the side walls of the reflector 40 . The transport support portion 34 is arranged in a direction intersecting the longitudinal direction of the light emitting portion 44 of the first UV lamp 38 when viewed from above. In addition, the longitudinal direction of the light emitting portion 44 of the first UV lamp 38 is arranged in a direction perpendicular to the paper money conveying direction. Further, the transport support portion 34 is arranged in a direction intersecting with the transport direction of the banknotes. A first UV lamp 38 is bent from the center so that the bent portions of one UV arc tube are parallel to each other, and the ends are fixed to the first UV connector 36 . The length of the linear portion of the first UV lamp 38 is longer than the width of the bill. When the banknote is being conveyed, the bent portion of the first UV lamp 38 protrudes from the banknote in top view. In addition, the side wall to which the first UV lamp 38 is fixed does not overlap the bill when viewed from above. This is because the bills are evenly irradiated with the ultraviolet rays without spots.

The transport support part 34 is fixed to the side wall by erecting a thin plate. Five transport support portions 34 are arranged in parallel. Moreover, the reflector 40 is provided with a fixing portion 42 . A screw can be passed through the hole of the fixing portion 42 and fixed to a housing, a frame, or the like. The width of the banknote is smaller than the length of the straight portion of the light emitting portion 44 . The thickness of the transport support portion 34 is desirably 0.1 mm or more and 2 mm or less. If the conveying support portion 34 is too thin, it will be easily damaged, and if it is too thick, it will block a lot of ultraviolet rays. It is preferable that the thickness when the transfer support portion 34 is stacked is 0.5 to 20% or less of the length of the light emitting portion of the first UV lamp 38 or the second UV lamp 39 . For example, when the length of the light emitting portion is 100 mm and five transport support portions 34 with a thickness of 0.1 mm are used, the thickness ratio of the transport support portions 34 is 0.5%. Moreover, the transfer support part 34 is preferably a metal thin plate. A thin metal plate is less likely to deteriorate due to ultraviolet rays. Since quartz glass has a high UVC transmittance, a thin plate made of quartz glass may be erected and used as the transfer support section 34 .

FIG. 5 is a diagram illustrating another example of the UV irradiation unit.

In the first UV irradiation unit 21 in which the transport support parts 34 are arranged, banknotes may enter between the transport support parts 34 and jam may occur. Banknotes with cuts or creases are more likely to jam. In the worst case, the paper money damages the light source. Therefore, it is preferable that the first UV irradiation unit 21 includes, in addition to the transport support section 34 , an obstruction that prevents banknotes from entering the inside of the first UV irradiation unit 21 . For example, the obstructer is a mesh 45 made of metal wires. Banknotes are guided by the transport support part 34 and transported by projecting the transport support part 34 outward from the position where the net 45 is arranged. Bills are conveyed by the net 45 without entering the inside of the first UV irradiation unit 21 . The second UV irradiation unit 22 can have the same configuration as the first UV irradiation unit 21 . Further, control may be performed to stop the first UV irradiation unit 21 and the second UV irradiation unit 22 when there is an abnormality in the conveyance of banknotes. In addition, if the metal wires forming the net 45 have a portion extending along the banknote conveying direction, the amount of UV irradiation in that portion is reduced. , for example, it is preferable to arrange them with an inclination of about 10 degrees. Since quartz glass has a high UVC transmittance, the blocker can also be a plate of quartz glass.

A control circuit (not shown) controls the entire device. Sensors for detecting banknotes are arranged at a plurality of locations on the banknote transport path to detect passing banknotes. The control circuit calculates and acquires the paper money transport speed from the detection result, and compares it with a predetermined allowable range. The control circuit determines that the transport is normal if the passing timing is within the allowable range, and that the transport is abnormal if it is outside the allowable range. The control circuit controls the first UV irradiation unit 21 and the second UV irradiation unit 22 to stop ultraviolet irradiation when there is a transport abnormality. It monitors the state of transport of banknotes, and turns on/off the irradiation of ultraviolet rays according to the monitoring results. Further, a sensor for detecting opening and closing of the UV unit base 12 is arranged, and when the opening of the UV unit base 12 is detected, the control circuit performs control to stop irradiation of ultraviolet rays. Such control can prevent workers from being exposed to ultraviolet rays during maintenance work.

Also, instead of the net 45, a plurality of wires or erected thin plates may be arranged in a direction intersecting the transport support portion 34. FIG. Bills can be prevented from entering toward the bottom of the reflector 40. - 特許庁When an obstruction is arranged between the first UV lamp 38 and the second UV lamp 39 and the conveyed banknote, the amount of ultraviolet rays irradiated to the banknote is reduced. It is preferable that the amount of ultraviolet rays irradiated to the banknotes with the transport support part 34 and the obstruction is 50% or more of the amount of ultraviolet light irradiated to the banknotes without the transport support part 34 and the obstruction. , more preferably 80% or more. If the amount of ultraviolet rays is 50% or more, the bills can be irradiated with the same amount or more of ultraviolet rays as in the case where the conveyance support portion 34 and the obstacles are not present, if the ultraviolet rays are irradiated at least twice as much. The more UV light that is blocked, the more UV light needs to be emitted, and the less efficient it is. The blocker may be made of plastic if it consists of mesh, wire, plate, etc., but is preferably made of metal. The second UV irradiation unit 22 is also similar to the first UV irradiation unit 21 .

Next, another example of the ultraviolet light source will be described with reference to FIG. FIG. 6 is a diagram illustrating another example of the UV irradiator.

The LED UV irradiator 50 uses an LED 54 that emits ultraviolet rays as a light source of ultraviolet rays. A plurality of LEDs 54 are fixed in the longitudinal direction of the substrate 52 . Each LED is connected to a terminal 51 by wiring 53 provided on the substrate 52 . A terminal 51 receives an externally supplied LED drive signal. The LED 54 is a point light source, and the light becomes weaker as it moves away.

Next, a configuration in which rollers are used instead of the conveyor belt 19 for conveying banknotes will be described. FIG. 7 is a diagram illustrating another example of the paper sheet processing apparatus. FIG. 7 is a diagram showing a schematic configuration of the paper sheet processing apparatus 1. As shown in FIG.

Banknotes 60 inserted from the deposit port 16 are sent from the separation unit 10 one by one. A banknote 60 is sandwiched between a transport roller 64 and a driven roller 65 and transported between an upper sensor unit 62 and a lower sensor unit 63 for identifying denomination and authenticity. The denomination and authenticity of bills are detected and identified by the upper sensor unit 62 and the lower sensor unit 63 . The identified banknote is sandwiched between the transport roller 64 and the driven roller 65 and transported horizontally between the first UV irradiation unit 21 and the second UV irradiation unit 22 . The bills are irradiated with ultraviolet rays and sterilized by the first UV irradiation unit 21 and the second UV irradiation unit 22 . The sterilized banknotes are sandwiched between the transport roller 64 and the driven roller 65 and transported by changing the direction on the folding path 66 . The banknote 60 is bent downward by the folding path 66 and conveyed in the direction of the withdrawal port 17 .

A first banknote storage unit 13, a second banknote storage unit 14, and a third banknote storage unit 15 are arranged between the turnaround path 66 and the withdrawal port 17. As shown in FIG. The denominations of banknotes stored in the first banknote storage unit 13, the second banknote storage unit 14, and the third banknote storage unit 15 are different.

Since the first banknote storage unit 13, the second banknote storage unit 14, and the third banknote storage unit 15 differ only in the denominations they store, the first banknote storage unit 13 will be described as an example. A switching path 61 is provided in the first banknote storage unit 13 . Roller pairs of a transport roller 64 and a driven roller 65 are arranged before and after the switching path 61, respectively, to sandwich and transport bills entering or discharged from the first bill storage unit 13. As shown in FIG. The switching path 61 guides bills into the first bill storage unit 13 , allows bills to pass through without storing them, or discharges bills from the first bill storage unit 13 . The switching path 61 changes the banknote transport path by switching the entrance and exit of the passage.

The identified banknotes are stored in corresponding units among the first banknote storage unit 13 , the second banknote storage unit 14 and the third banknote storage unit 15 . Also, when withdrawing money, the banknotes discharged from the first banknote storage unit 13, the second banknote storage unit 14, or the third banknote storage unit 15 are sandwiched between the transport roller 64 and the driven roller 65 and transported to the dispensing port. .

As described above, instead of the transport belt 19 and the pressing roller 20, a plurality of roller pairs that pinch and transport the banknotes may be used to transport the banknotes.

1 Paper sheet processing device 2 Frame 3 Lower transport unit 4 Upper transport unit 5 Lower transport unit shaft 6 Lower damper 7 Lower open/close lever 8 Upper transport unit shaft 9 Upper damper 10 Separation unit 11 Upper identification unit 12 UV unit base 13 First Banknote storage unit 14 Second banknote storage unit 15 Third banknote storage unit 16 Receipt port 17 Withdrawal port 18 Withdrawal tray 19 Conveyor belt 20 Pressing roller 21 First UV irradiation unit 22 Second UV irradiation unit 23 Storage unit entrance 24 Storage unit exit 25 sensor 26 upper transfer path 27 lower transfer path 28 UV unit base shaft 29 upper identification unit shaft 30 first side wall 31 second side wall 32 third side wall 33 fourth side wall 34 transfer support section 35 upper opening/closing lever 36 first UV connector 37 2UV connector 38 First UV lamp 39 Second UV lamp 40 Reflector 41 Curved portion 42 Fixed portion 43 Electrode 44 Light-emitting portion 45 Net 50 LEDUV irradiator 51 Terminal 52 Board 53 Wiring 54 LED
60 bill 61 switching path 62 upper sensor unit 63 lower sensor unit 64 transport roller 65 driven roller 66 return path

Claims (15)

A deposit slot for depositing paper sheets,
a withdrawal port for withdrawing the paper sheets;
a transport unit connected to the deposit port and the withdrawal port and transporting the paper sheets;
an identification unit arranged in the middle of the transportation path of the paper sheet and identifying the denomination of the paper sheet;
a sterilization unit disposed in the middle of the transport path for sterilizing the paper sheets;
a storage unit arranged in the middle of the transport path for storing and discharging the paper sheets,
In a paper sheet processing apparatus that stores the paper sheets identified by the identification unit and sterilized by the sterilization unit in the storage unit,
a first ultraviolet irradiation unit disposed in the sterilization section and including a first light source for irradiating ultraviolet rays onto one surface of the conveyed paper sheet;
A second ultraviolet irradiation unit disposed in the sterilization section, facing the first ultraviolet irradiation unit, and including a second light source for irradiating the other side surface of the conveyed paper sheet with ultraviolet rays;
A first light source disposed between the first light source and the second light source and between the first light source and the conveyed paper sheet for supporting the conveyed paper sheet a support;
A second light source disposed between the first light source and the second light source and between the second light source and the conveyed paper sheet for supporting the conveyed paper sheet a support;
The paper sheets conveyed between the first support section and the second support section are sterilized by ultraviolet rays irradiated from the first light source and the second light source. paper sheet handling equipment. The first support unit includes a plurality of first supports, and the first supports are arranged along a direction in which the longitudinal direction of the first supports intersects the conveying direction of the paper sheets. are placed at
The second support unit includes a plurality of second supports, and the second supports are arranged along a direction in which the longitudinal direction of the second supports intersects the transport direction of the paper sheets. are placed at
The ultraviolet light emitted from the first light source is applied to the paper sheet through the gap between the first supports, and the ultraviolet light emitted from the second light source is applied to the space between the second supports. 2. The paper sheet processing apparatus according to claim 1, wherein said paper sheet is irradiated through said gap. 3. A paper sheet processing apparatus according to claim 2, wherein the longitudinal direction of said first support crosses the longitudinal direction of said second support. The conveying unit includes a rotating body that sandwiches and conveys the paper sheet, and the rotating body is arranged between the first support unit and the second support unit on the upstream side in the conveying direction of the paper sheet. including an upstream rotator and a downstream rotator positioned on each of the downstream outer sides,
The paper sheet is transported while being pinched by at least one of the upstream rotating body and the downstream rotating body in the area where the first support section and the second support section are arranged. The paper sheet processing apparatus according to claim 2. 3. The paper sheet processing apparatus according to claim 2, wherein the support is a plate or wire that shields ultraviolet rays. 3. The paper sheet processing apparatus according to claim 2, wherein wavelengths of ultraviolet rays mainly emitted from said first light source and said second light source are 240 nm or more and 280 nm or less. The first light source and the second light source are fluorescent lamps in which a light-emitting portion is continuous over at least the width direction of the paper sheet, and a plurality of the light-emitting portions are arranged along the width direction of the paper sheet. 7. The paper sheet processing apparatus according to claim 6, wherein the paper sheet processing apparatus is characterized by: a first light source interposed between the conveyed paper sheet and the first light source to prevent the paper sheet from moving in the direction of the first light source through the supports of the first support portion; with 1 inhibitor,
A second light source is provided between the conveyed paper sheet and the second light source to prevent the paper sheet from passing through the supports of the second support portion and moving in the direction of the second light source. 3. The paper sheet processing apparatus according to claim 2, wherein two obstructions are provided. 9. The paper sheet processing apparatus according to claim 8, wherein the first obstruction and the second obstruction are plates, wires, or nets. The first light source is fixed to a side wall of the first ultraviolet irradiation unit, and the side wall to which the first light source is fixed is arranged at a position that does not overlap the conveyed paper sheet in a top view,
The second light source is fixed to a side wall of the second ultraviolet irradiation unit, and the side wall to which the second light source is fixed is arranged at a position that does not overlap the conveyed paper sheets when viewed from above. The paper sheet processing apparatus according to claim 1, characterized in that: The conveying unit has a sensor for detecting the conveyed paper sheet, and the conveying state of the paper sheet is monitored based on the detection result of the sensor. 2. A paper sheet processing apparatus according to claim 1, wherein said first ultraviolet irradiation unit and said second ultraviolet irradiation unit stop emitting ultraviolet rays. 5. The paper sheet processing apparatus according to claim 4, wherein the rotating body is sterilized by being irradiated with ultraviolet rays from the first ultraviolet irradiation unit or the second ultraviolet irradiation unit. 9. The paper sheet processing apparatus according to claim 8, wherein at least one of the first inhibitor and the second inhibitor is a quartz glass plate. Having a unit base to which the second ultraviolet irradiation unit is fixed,
The unit base has a connecting portion that rotatably supports the unit base,
When the unit base is rotated and closed, the transport path is formed by facing the second ultraviolet irradiation unit to the first ultraviolet irradiation unit, and when the unit base is rotated and opened, the transport path is formed. 14. Any one of claims 1 to 13, wherein the second ultraviolet irradiation unit is separated from the first ultraviolet irradiation unit to expose the conveying path, the first light source, and the second light source. The paper sheet processing apparatus according to the item. The sterilization section is arranged after the identification section, the identification section and the sterilization section are arranged adjacent to each other in the horizontal direction, and the connection section is arranged downstream of the unit base in the conveying direction of the paper sheets. 15. The paper sheet processing apparatus according to claim 14, wherein the upstream side of the unit base in the conveying direction of the paper sheets opens and closes.

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