JP2016048481A - Paper sheet processing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To display information on paper sheets accumulated in a plurality of accumulation parts in an understandable manner.SOLUTION: A paper sheet processing device that identifies paper sheets and counts them is configured to include: a conveyance path for conveying a paper sheet; an identification part for identifying a paper sheet conveyed through the conveyance path; a plurality of accumulation parts that each have an opening for removal of paper sheets accumulated therein, sort paper sheets discharged from the conveyance path on the basis of the identification result of the identification part, and accumulate the paper sheets; and a display part for displaying the information on the paper sheets accumulated in the accumulation parts. On a screen of the display part, information on the paper sheets accumulated in each accumulation part is displayed in accordance with the positional relationship among the accumulation parts.SELECTED DRAWING: Figure 20

Description

  The present invention relates to a paper sheet processing apparatus that identifies types of paper sheets and accumulates them in a stacking unit corresponding to the identification result.

  Conventionally, in a financial institution such as a bank, a paper sheet processing apparatus that processes paper sheets such as banknotes and checks is used. For example, a banknote processing apparatus is used to identify the authenticity of banknotes and to count the number and amount of money. Patent Document 1 discloses a small banknote processing apparatus that can be used by a counter (teller) at a counter. This bill processing device has a function of feeding bills placed on a hopper one by one into the device and identifying and counting denominations and authenticity. In addition to the hopper, the banknote handling apparatus includes four stacking sections in which banknotes that have been identified and counted are stacked, and a reject section in which reject banknotes such as banknotes that cannot be recognized as denominations or authenticity or false banknotes are discharged. The banknote of the hopper is conveyed to the stacking unit or the rejecting unit according to the identification result. For example, by processing banknotes received from customers at a counter using a banknote processing device, processing results such as banknote authenticity determination results, number of denominations, total amount, etc. can be obtained. be able to. In addition, by discriminating and counting banknotes by the banknote processing apparatus, it is possible to prevent human error related to authenticity determination and monetary counting.

  In the banknote processing apparatus disclosed in Patent Document 1, information on the processed banknotes is displayed on the screen of the banknote management apparatus. For example, at the time of deposit processing, various information such as the denomination and the number of banknotes accumulated in each of the four stacking units are displayed in addition to the total number and total amount of banknotes to be deposited.

Japanese Patent No. 5313257

  However, the conventional technology has a problem that it is difficult to understand the relationship between the stacking unit and the information displayed on the banknotes stacked in the stacking unit. Specifically, for example, it is difficult to understand where the number of banknotes accumulated in the accumulation unit is displayed on the screen on which various information is displayed. In addition, when a plurality of pieces of sheet number information are displayed on the screen, the correspondence between each piece of piece number information and a plurality of stacking units is difficult to understand, and until the number of sheets stacked in each stacking unit is recognized. Takes time.

  The present invention has been made to solve the above-described problems caused by the prior art, and includes a plurality of stacking units and information on paper sheets stacked on each stacking unit displayed on the screen of the display unit. An object of the present invention is to provide a paper sheet processing apparatus that can easily recognize the relationship.

  In order to solve the above-described problems and achieve the object, the present invention is a paper sheet processing apparatus for identifying and counting paper sheets, a transport path for transporting paper sheets, and transporting the transport path An identification unit for identifying the paper sheets to be collected and an opening for extracting the paper sheets accumulated therein, and classifying the paper sheets discharged from the conveyance path based on the identification result by the identification unit A plurality of stacking units for stacking and a display unit for displaying information on the paper sheets stacked in the stacking unit, and according to the positional relationship of each stacking unit on the screen of the display unit In addition, it is characterized in that information relating to paper sheets accumulated in each accumulation unit is displayed.

  Further, according to the present invention, in the above invention, the plurality of stacking units are provided in a line, and the display unit is provided in front of the apparatus while avoiding openings of the plurality of stacking units arranged in a line. The information on the paper sheets accumulated in the at least two stacking units is displayed on the screen of the unit in accordance with the arrangement direction and the arrangement order of these stacking units.

  Further, according to the present invention, in the above invention, when the display area for displaying information relating to the sheets stacked on each stacking unit on the screen of the display unit is regarded on the front surface of the sheet processing apparatus, each stacking is performed. Information on paper sheets accumulated in each stacking unit is displayed at a position corresponding to the unit.

  Further, the present invention is characterized in that, in the above invention, the plurality of stacking units include a reject unit that stacks reject paper sheets.

  Further, in the present invention according to the above-described invention, when processing of paper sheets is started, a display area for displaying information on rejected paper sheets is not provided on the screen of the display unit, and the paper sheets When a reject paper sheet is generated after starting the process, a display area for displaying information regarding the reject paper sheet appears on the screen of the display section in accordance with the position of the reject section. And

  Further, the present invention is the above invention, wherein the information related to the paper sheets accumulated in each stacking unit is the periphery of the display area for displaying the information related to the paper sheets stacked in each stacking unit on the screen of the display unit It is characterized by being displayed along.

  Further, according to the present invention, in the above invention, each stacking unit is provided with a light emitting element, and the display unit displays information on paper sheets stacked on the stacking unit or a background color of the character. The color emitted from the light emitting element in the integrated portion is a similar color.

  Further, according to the present invention, in the above invention, each integrated unit is provided with a light emitting element, and when the paper sheets accumulated in the integrated unit are required to be extracted, In addition to emitting light, the display unit displays a character displaying information on the paper sheet or the background of the character in a color similar to the light emission of the light emitting element to notify the extraction.

  The present invention is also a paper sheet processing apparatus that identifies and counts paper sheets, a transport path that transports the paper sheets, and an identification unit that identifies the paper sheets transported through the transport path; An opening on the left side of the lower part of the front of the apparatus, a first stacking part for collecting sheets discharged from the conveying path based on the identification result by the identification part, and an opening on the right side of the lower part of the front of the apparatus , A second stacking unit that stacks the sheets discharged from the conveyance path based on the identification result by the identifying unit, and information relating to the sheets stacked in the first stacking unit provided at the upper front of the apparatus Is displayed on the left side of the lower part of the screen, and the display unit displays information on the paper sheets accumulated in the second stacking part on the right side of the lower part of the screen.

  Further, the present invention, in the above invention, further comprises a reject unit having an opening on the right side surface of the upper portion of the apparatus, and collecting reject paper sheets discharged from the conveyance path based on the identification result by the identification unit, Information on the reject paper sheet is displayed on the right side of the upper part of the screen of the display unit.

  Also, in the present invention according to the above invention, the information related to the paper sheets stacked in the first stacking unit and the information related to the paper sheets stacked in the second stacking unit are displayed in the largest font on the screen. It is characterized by that.

  According to the present invention, on the screen of the display unit, information on the paper sheets stacked in the plurality of stacking units is displayed according to the positional relationship of each stacking unit. Can be easily recognized. In addition, regarding information about rejected paper sheets, this information and information about paper sheets accumulated in other stacking units are displayed on the screen in accordance with the positional relationship between the reject unit and other stacking units. Therefore, it is possible to easily recognize where information on rejected paper sheets is displayed on the screen.

  Further, according to the present invention, when processing of paper sheets is started, a display area for displaying information about reject paper sheets is not provided on the screen, and when reject paper sheets are generated, Since an area for displaying information regarding rejected paper sheets appears, it is possible to easily recognize that rejected paper sheets are generated due to a change in the screen.

  In addition, according to the present invention, since the light emitting element provided in each integrated unit emits light in a color similar to the character displaying information on the display unit or the color displaying the background of the character, the light is displayed on the display unit. The position of the accumulation unit corresponding to the information can be easily recognized.

FIG. 1 is a perspective view showing an external appearance of the banknote handling apparatus according to the present embodiment. FIG. 2 is a plan view showing an external appearance of the banknote handling apparatus. FIG. 3 is a diagram illustrating an opening / closing operation of the upper unit and the rear unit. FIG. 4 is a diagram showing the structure of the reject unit. FIG. 5 is a diagram illustrating a positional relationship between the operation display unit and the two banknote stacking units on the front surface of the apparatus. FIG. 6 is a schematic cross-sectional view showing an outline of the internal structure of the banknote handling apparatus. FIG. 7 is a schematic cross-sectional view illustrating the opening / closing operation of the identification unit. FIG. 8 is a schematic cross-sectional view showing the opening / closing operation of the upper unit. FIG. 9 is a diagram illustrating the structure of the dust receiving portion. FIG. 10 is a diagram illustrating the structure of the banknote stacking unit. FIG. 11 is a schematic diagram showing the structure of the transport path. FIG. 12 is a perspective view showing the structure of the pushing member provided inside the banknote stacking unit and the drive mechanism for moving the pushing member. FIG. 13 is a diagram illustrating a method of moving the pushing member by the pushing mechanism. FIG. 14 is a schematic diagram showing the retracted position and the pushing position of the pushing member in the banknote stacking unit. FIG. 15 is a perspective view showing an integrated banknote detection sensor that detects the presence or absence of banknotes stacked in the banknote stacking unit and a sensor brush that cleans the sensor. FIG. 16 is a diagram illustrating a cleaning method using a sensor brush. FIG. 17 is a diagram illustrating an arrangement position of the stacked banknote detection sensor with respect to the banknote stacking unit. FIG. 18 is a development view for explaining the structure of the bill conveyance path inside the bill processing apparatus. FIG. 19 is a schematic diagram showing an arrangement position of the impeller inside the banknote stacking unit. FIG. 20 is a diagram illustrating an example of a screen displayed on the operation display unit during bill processing. FIG. 21 is a diagram illustrating an example of a screen displayed on the operation display unit when a reject banknote is generated during banknote processing. FIG. 22 is a diagram illustrating an example of a screen displayed on the operation display unit in a return process performed when an error occurs during bill processing. FIG. 23 is a diagram illustrating priority setting of a plurality of banknote stacking units provided in the banknote handling apparatus. FIG. 24 is an external view showing an example of a banknote handling apparatus provided with a large number of banknote stacking units. FIG. 25 is a schematic diagram for explaining a method for setting the types of banknotes to be stacked in each banknote stacking unit.

  Hereinafter, a sheet processing apparatus according to the present invention will be described with reference to the accompanying drawings. The paper sheet processing apparatus according to the present invention can process paper sheets such as banknotes, checks, and gift certificates, but in the following, a banknote processing apparatus that processes banknotes as an example. I will explain.

[Appearance configuration of the device]
FIG. 1 is a perspective view showing the external appearance of the banknote handling apparatus 1. The banknote handling apparatus 1 having the hopper 20 and the reject unit 50 on the side surface and the two banknote stacking units 30 and 40 on the front side tilts the banknotes inside the banknote stacking units 30 and 40 having openings for extracting banknotes. One feature is that the apparatus is integrated in a standing position and the protrusion of the reject unit 50 from the side surface of the apparatus is minimized, thereby reducing the lateral width of the apparatus and realizing miniaturization.

  In the present embodiment, of the four side surfaces of the apparatus, the front side on which the operation display unit 70 is provided is the front side, and the right hand side as viewed from the operator who operates the operation display unit 70 from the front side of the banknote handling apparatus 1. The left side is called the right side, the left hand side is called the left side, and the back side is called the back side. In the present embodiment, as shown in FIG. 1, the direction from the left side of the apparatus to the right side is the X-axis direction, the direction from the front of the apparatus to the back is the Y-axis direction, and the direction from the apparatus bottom to the top is the Z-axis. Shown as direction.

  The front side of the banknote handling apparatus 1 includes an upper unit 11 and a lower unit 12. The banknote handling apparatus 1 is a small apparatus that can be installed in a space having a lateral width (X-axis direction) of 450 mm, a depth (Y-axis direction) of 450 mm, and a height (Z-axis direction) of 400 mm. Since a part of the reject portion 50 protrudes on the right side surface, the lateral width of the installation surface is further reduced to 400 mm or less.

  On the left and right lower ends of the front surface of the banknote handling apparatus 1, for example, when the banknote handling apparatus 1 is installed on a desk, recesses 36 and 46 are formed so that a gap is formed between the desk and the apparatus housing. Yes. The recesses 36 and 46 are also provided on the back side of the apparatus, and the banknote handling apparatus 1 can be transported by putting hands in the recesses 36 and 46 at the four corners of the bottom surface.

  A large-sized operation display unit 70 capable of performing various information input operations and various information output displays is disposed in the approximate center of the front surface of the upper unit 11. The operation display unit 70 has an upper side substantially at the same position as the front side of the apparatus, while a lower side protrudes forward from the front side of the apparatus and is tilted upward so that the operator can easily see the display contents. It is fixed. On the left side of the operation display unit 70, there is disposed a push-open type dust tray 71 that protrudes toward the front side by being pushed toward the back side. Garbage such as paper dust generated when a bill is conveyed inside the apparatus can be collected in the garbage tray 71 and taken out of the apparatus.

  On the right side surface of the upper unit 11 is provided a hopper 20 on which a bill to be processed for identification counting is placed. A reject unit 50 for discharging reject banknotes is disposed below the hopper 20. In the reject unit 50, the upper surface of the accumulation space in which reject banknotes are accumulated is on the upper unit 11 side, and the bottom surface is on the lower unit 12 side. An upper lid 13 that can be opened and closed is provided on the upper surface of the upper unit 11. An engaging member is provided between the upper lid 13 and the upper unit 11, and the upper lid 13 and the upper unit 11 are usually fixed by this engaging member. As shown in FIG. 1, a lever for releasing the engagement by the engagement member is provided on the right side of the upper lid 13 at a substantially central position in the front-rear direction, and the upper lid 13 is placed with a finger on the lever. By performing the upward opening operation, the operation of releasing the engagement by the engagement member and the operation of opening the upper lid 13 that has been released from the engagement can be performed as a series of operations. By opening the upper lid 13, the identification unit and the conveyance path in the upper unit 11 are exposed, and inspection and maintenance can be performed.

  On the hopper 20, banknotes can be placed in a stacked state, with the banknote short side facing the front side (Y-axis negative direction) and the banknote length facing the transport direction front side (X-axis negative direction). The banknotes stacked on the stage of the hopper 20 are fed out one by one from the bottom banknote onto the transport path in the apparatus. Each banknote on a conveyance path is conveyed by making a banknote longitudinal direction the front of a conveyance direction. The hopper 20 is provided with a guide member 21 that supports banknotes placed in a stacked state from the short side (Y-axis direction). The guide member 21 is made of a transparent resin so that a bill placed on the hopper 20 can be confirmed from the outside. The two guide members 21 having a symmetrical shape with respect to the XZ plane can be slid in the Y-axis direction in conjunction with each other. By adjusting the position of the two guide members 21 in accordance with the longitudinal length of the bill, the bill is placed in substantially the center in the front-rear direction (Y-axis direction) of the hopper 20 and the width direction of the transport path (Y-axis direction). ) You can pay out bills in the approximate center. The stage on which banknotes are placed by the hopper 20 has a shape in which a substantially central portion in the front-rear direction (Y-axis direction) is recessed in the right direction (X-axis negative direction). From this depression, the inside of the reject space 50 on the lower side of the hopper 20 can be seen (see FIG. 2B). After all the banknotes on the stage have been fed into the apparatus, the reject is made. The presence or absence of reject banknotes discharged to the unit 50 can be easily confirmed.

  As shown in FIG. 1, the reject unit 50 includes two stopper members 52 that stop the reject banknotes discharged from the transport path in the apparatus into the stacking space of the reject unit 50 so as not to jump to the outside. A holding member 53 is provided to hold down rejected banknotes stopped in the space from above. The stopper member 52 is maintained at the normal position shown in FIG. 1 by a spring member, but is supported so as to be rotatable around the Y axis in the device outer direction. When the reject banknotes accumulated in the reject unit 50 are taken out from the right side of the apparatus, the stopper member 52 rotates clockwise so that the reject banknotes can be easily taken out. A recess 51 that is recessed from the front surface of the housing toward the back surface is formed in the lower right of the front surface of the upper unit 11. Further, the side wall that supports the reject banknote from the short side in the accumulation space in the reject unit 50 has a shape in which the right side of the side wall on the near side is cut out toward the left side. The accumulation space of the reject unit 50 and the space in the recess 51 are connected to each other inside the housing outer surface. Since the space in the recess 51 on the front surface of the housing is connected to the accumulation space in the reject unit 50 on the right side surface, the operator of the banknote handling apparatus 1 is in the reject unit 50 while being on the front side of the device. The presence / absence of the reject banknote and the removal of the reject banknote from the reject unit 50 can be easily performed.

  In the recess 51, a lever that releases the engagement of the engagement member that engages the upper unit 11 and the lower unit 12 is provided at a position obliquely upward to the left. This lever is provided at a position where a finger is applied when the right hand is put into the recess 51 in order to lift the right side surface of the upper unit 11 upward. As a result, an operation of releasing the engagement by the engaging member by performing an operation of opening the upper unit 11 in a state where a hand is put in the recess 51 and a finger is applied to the lever, and the upper portion where the engagement is released The operation of opening the unit 11 can be performed as a series of operations.

  Two banknote stacking units 30 and 40 having openings on the front side are provided on the left and right outer sides of the lower unit 12. The bills fed out from the hopper 20 into the apparatus are identified and counted by the identification unit in the apparatus. The banknotes identified as being stacked on the banknote stacking units 30 and 40 are stacked on the first banknote stacking unit 30 or the second banknote stacking unit 40 according to the identification result. The banknote discharged | emitted in the banknote stacking part from the upper right part in the 1st banknote stacking part 30 is sent toward the left side wall in a banknote stacking part by the impeller 33 which rotates counterclockwise around the Y-axis. The left side wall is inclined such that the upper part is on the left side and the lower part is on the right side. The banknotes sent to the left wall by the impeller 33 are stacked so that the wall surface of the inclined left wall and the banknote surface are parallel to each other, and are stacked in an inclined standing state. Similarly, the banknote discharged | emitted in the banknote stacking part from the upper left by the 2nd banknote stacking part 40 is sent to the right side wall in a banknote stacking part by the impeller 43 rotated clockwise around a Y-axis. The right wall is inclined such that the upper part is on the right side and the lower part is on the left side. The banknotes sent to the right side wall by the impeller 43 are stacked so that the wall surface of the inclined right side wall and the banknote surface are parallel, and are stacked in an inclined standing state. That is, the banknotes stacked in the stacking space of the banknote stacking unit have the shorter side forward and the longer side in contact with the bottom surface, and the shorter side than the shorter side is the outer side of the device. Accumulated in an inclined standing position. The impellers 33 and 43 are stacking wheels that rotate in order to stack the banknotes in an aligned state in the stacking space of the first banknote stacking unit 30 and the second banknote stacking unit 40.

  The banknote handling apparatus 1 has two banknote stacking units 30 and 40 on the left and right sides, but stacks banknotes in an inclined position in each banknote stacking unit, thereby stacking banknotes horizontally and stacking them. Thus, the width of the stacking space necessary for stacking bills is small.

  On the front side of the left side surface of the lower unit 12, a cutout 31 is formed by cutting out the left side surface in a curved shape from the front side to the back side. Similarly, a cutout 41 is formed on the front side of the right side surface of the lower unit 12 by cutting out the right side surface in a curved shape from the front side to the back side. In addition, a recess 60 that is recessed toward the back side is formed between the left and right banknote stacking units 30 and 40 on the front surface of the lower unit 12.

  The left side wall front end forming the stacking space of the first banknote stacking unit 30 is further on the back side than the cutout 31 on the left side of the housing, and the left side between the cutout 31 and the left side wall front end of the stacking space is the open left side. Connected by surface 35. Moreover, the right side wall front end forming the stacking space of the first banknote stacking unit 30 is on the back side with respect to the recess 60 formed between the first banknote stacking unit 30 and the second banknote stacking unit 40 and the impeller 33. On the front side, the opening 60 is connected to the right side wall 32 between the recess 60 and the front end of the right side wall of the accumulation space. Similarly, the right side wall front end forming the stacking space of the second banknote stacking unit 40 and the notch 41 are connected by the opening right side 45. Further, the left side wall front end forming the stacking space of the second banknote stacking unit 40 and the recess 60 are connected by the opening left side surface 42.

  The operator on the front side determines whether or not there are banknotes accumulated inside the first banknote stacking unit 30 and the second banknote stacking unit 40 by the depression 60 on the front surface of the lower unit 12 and the left and right opening side surfaces 32 and 42. It can be easily visually confirmed. Moreover, in the 1st banknote stacking part 30, the opening left side 35 continuing from the notch 31 of the housing | casing left side surface and the notch 31 to the accumulation space left side wall, and the opening right side surface 32 continuing from the accumulation space right side wall to the hollow 60 are provided. As a result, it is possible to easily perform the operation of grasping and removing the banknotes stacked in a standing position inclined along the left side wall of the stacking space so as to be sandwiched from the left and right. Similarly, in the second banknote stacking unit 40, a notch 41 on the right side of the housing, an opening right side 45 extending from the notch 41 to the right side wall of the stacking space, and an opening left side 42 continuing from the left side wall of the stacking space to the recess 60 Therefore, it is possible to easily extract banknotes stacked in a standing state inclined along the right side wall of the stacking space.

  In the 1st banknote stacking part 30 and the 2nd banknote stacking part 40, while the notches 31 and 41 are formed in the side surface, the bottom face continues to the apparatus housing front surface. For this reason, it is possible to stack the banknotes stacked in a stable state in a tilted standing state with the long edge portion along the bottom surface.

  The opening right side surface 32 and the opening left side surface 35 formed in the opening of the first banknote stacking unit 30 are formed by curved surfaces that are inclined so that the opening area becomes narrower toward the accumulation space. And the left and right side wall front ends of the accumulation space may be left exposed. Similarly, the opening left side surface 42 and the opening right side surface 45 formed at the opening of the second banknote stacking unit 40 are formed by curved surfaces inclined so that the opening area becomes narrower toward the stacking space. Also, the front end of the left and right side walls of the accumulation space may be exposed.

  Thus, in the banknote processing apparatus 1, the notches 31, 41 on the left and right sides of the housing of the lower unit 12, the recess 60 formed between the first banknote stacking unit 30 and the second banknote stacking unit 40, and the first The inclined opening side surfaces 32 and 35 of the 1 banknote stacking unit 30 and the inclined opening side surfaces 42 and 45 of the second banknote stacking unit 40 are formed. Thereby, the presence or absence of the banknote integrated | stacked on the stacking space of the 1st banknote stacking part 30 and the 2nd banknote stacking part 40 can be confirmed easily from the apparatus right side. Similarly, the presence / absence of banknotes accumulated in the first banknote stacking unit 30 and the second banknote stacking unit 40 can be easily confirmed from the left side of the apparatus.

  For example, at the counter of a bank window, the right side surface of the apparatus provided with the hopper 20 and the reject unit 50 is installed toward the customer outside the window. Then, the counter operates the banknote handling apparatus 1 from the front side of the apparatus. At this time, the customer can see how the banknotes handed to the counter are placed on the hopper 20 and fed out into the apparatus one by one, and the reject banknotes are discharged to the reject unit 50. Further, by providing the lower unit 12 with the notches 31, 41, the recess 60, and the opening side surfaces 32, 35, 42, 45, the customer who is at the position facing the counter on the right side of the apparatus can collect the first bill. It can be seen that banknotes are stacked on the unit 30 and the second banknote stacking unit 40. As described above, the hopper 20, the first banknote stacking unit 30, the second banknote stacking unit 40, and the reject unit 50 are arranged in the banknote processing apparatus 1 so that the customer can easily see the banknote, and the counter receives the banknote received from the customer. By processing in front of the eyes, it is possible to avoid the question about the operation of the counter related to the banknote processing and the banknote processing in the banknote processing apparatus 1.

[Location of ports]
FIG. 2 is a plan view showing the appearance of the banknote handling apparatus 1. 2A shows the front surface of the banknote processing apparatus 1, FIG. 2B shows the top surface, FIG. 2C shows the right side surface, and FIG. 2D shows the left side surface. 2B shows an example in which the banknote handling apparatus 1 is installed in a place where two sides are wall surfaces with the back surface and the left side surface facing the wall surface, and the cross section of the wall surface seen from the top surface is hatched. Show.

  In the banknote processing apparatus 1, a slot for inserting a memory card as a portable storage medium, a port for connecting a USB cable or a LAN cable, and a power cable are connected to the back side of the right side surface where the hopper 20 and the reject unit 50 are provided. 2B, the banknote processing apparatus 1 can be installed without providing a gap between the left side surface and the back surface of the apparatus and the wall surface, as shown in FIG. 2B. It has one feature.

  As shown in FIG. 2C, the upper unit 11 and the lower unit 12 are on the front side of the apparatus, and the back side is a back unit 14 that is integrated vertically. That is, the housing of the banknote handling apparatus 1 is configured by three units of an upper unit 11 on the front side, a lower unit 12 on the front side, and a back unit 14 on the back side.

  In the banknote handling machine 1, as shown in FIG. 2C, the memory card slot 62, the USB port 63, the LAN port 64, and a dedicated external device such as a printer are connected to the right side surface of the back unit 14. A dedicated port 65, a main power switch 66, and a power inlet 67 are provided, and are arranged in a line in the vertical direction. That is, the ports are concentrated on a part of the vertically long part provided on the back side on the right side of the housing.

  When the banknote handling apparatus 1 is used, the power inlet 67 to which the power cable is connected is disposed on the lowermost side. Further, a LAN port 64 to which a LAN cable may be connected and a dedicated port 65 to which a cable for connecting an external device may be connected are arranged above the power inlet 67. A USB port 63 to which a USB cable may be connected is arranged above the ports 64 and 65. A memory card slot 62 to which no cables are connected is arranged at the top. In this way, by placing the ports that are more likely to be connected to the cables on the lower side, the operation of connecting the cables to each port and inserting a portable storage medium such as a memory card or USB memory Can be easily performed.

  The memory card slot 62 inserts a memory card in which new template data for banknote identification, new firmware for function update of the banknote processing apparatus 1 and the like are inserted, and updates the template data for identification, firmware, and the like. To use. In addition, it is possible to record data relating to banknote processing and log data such as operation records of each part in the banknote processing apparatus 1 in a memory card inserted into the memory card slot 62. The USB port 63 can be used for updating identification template data using a USB memory, updating firmware, recording log data, and the like. The USB port 63 is used to connect a USB cable when connecting a device that supports data communication using a USB cable.

  The LAN port 64 is used to connect the banknote handling apparatus 1 to a network using a LAN cable. By connecting the banknote processing apparatus 1 to a network, it is possible to perform data communication with an external device such as a host terminal or a management server, or to control the banknote processing apparatus 1 from an external device. . In addition, the identification template data of the banknote handling apparatus 1 can be updated, the firmware can be updated, and the log data can be collected from another device such as a host terminal via a network.

  The dedicated port 65 is an interface for connecting a dedicated device such as a printer or a display device. The power inlet 67 is a port for connecting a power cable for supplying power to the banknote handling apparatus 1. The main power switch 66 is a switch for controlling on and off of power supplied from the power cable. As shown in FIG. 2 (C), a sub power switch 61 is provided on the right side surface of the lower unit 12 of the banknote handling machine 1, and by turning on both the main power switch 66 and the sub power switch 61, The banknote handling apparatus 1 is activated. In a state where the main power switch 66 is turned off, even if the sub power switch 61 is turned on, banknote processing cannot be performed by the bill processing apparatus 1, and the main power switch 66 is turned on and the sub power switch 61 is turned off. The device goes into a standby state.

  On the right side of the banknote handling apparatus 1 provided with the hopper 20 and the reject unit 50, it is necessary to place banknotes on the hopper 20 and to remove banknotes from the reject unit 50. For this reason, normally, the banknote processing apparatus 1 cannot be installed so that a right side surface may be closely_contact | adhered to a wall surface. Similarly, in the front surface provided with the opening part of the 1st banknote stacking part 30 and the 2nd banknote stacking part 40, it is necessary to extract the banknote integrated | stacked inside. For this reason, normally, the banknote processing apparatus 1 cannot be installed so that a front surface may contact | adhere to a wall surface. In the banknote processing apparatus 1, ports are provided on the housing surface that cannot be directed to the wall surface in this way.

  Specifically, when performing banknote processing, the memory card slot 62, the USB port 63, the LAN port 64, and the outside are provided on the right side surface that cannot be opposed to the wall surface so that the customer can see the state of banknote processing. All of the dedicated port 65 for connecting devices, the main power switch 66, and the power inlet 67 are intensively arranged. As a result, the left side surface and the rear surface where no ports are provided can be installed so that these surfaces are in close contact with the wall surface as shown in FIG. 2 (B). There will be no wasted space between them. Further, even when the banknote handling apparatus 1 is installed as shown in FIG. 2B, the right side surface provided with the ports is open, so the ports are used without moving the banknote handling apparatus 1. can do.

  FIG. 3 is a diagram illustrating how the upper unit 11, the lower unit 12, and the rear unit 14 are opened and closed. An engaging member is provided between the upper unit 11 and the lower unit 12, and the upper unit 11 and the lower unit 12 are usually fixed by this engaging member. The banknote handling apparatus 1 can open the right side of the upper unit 11 upward with respect to the lower unit 12 as shown in FIG. Further, as shown in FIG. 2C, the right side of the rear unit 14 in which the ports are centrally arranged can be opened rearward with respect to the upper unit 11 and the lower unit 12 as shown in FIG. 3B. it can.

  When an error such as a paper jam (jam) occurs during the banknote processing and the banknote is jammed in the transport path inside the apparatus, the upper unit 11 is opened upward to remove the jammed banknote from the transport path, Each part can be inspected and repaired.

  Inside the rear unit 14, a memory card slot 62, a USB port 63, a LAN port 64, a dedicated port 65 for external devices, a main power switch 66, a power supply inlet 67, a board connected to the power supply unit, and the like are housed. ing. In addition, a substrate that performs control of an identification unit that identifies a denomination of banknotes and the like in the banknote handling apparatus 1 and transport control of banknotes by a transport path is also housed in the back unit 14. For example, when a failure occurs in the banknote processing apparatus 1 installed as shown in FIG. 2B, the upper unit 11 is moved by moving the banknote processing apparatus 1 forward and opening the back unit 14 rearward. In addition, it is possible to check a motor or the like that drives the roller of the conveyance path in the lower unit 12.

[Reject structure]
FIG. 4 is a view showing the structure of the housing recess 51 provided on the front side of the reject unit 50 and the reject unit 50 device. 4A shows a perspective view of the external appearance of the reject unit 50, and FIG. 4B shows a plan view of the reject unit 50 as viewed from above. In the banknote processing apparatus 1, the right side of the front side wall 11a of the reject unit 50 is cut out, and a recess 51 connected to the accumulation space of the reject unit 50 is formed on the front surface of the housing by the cut out 51a. It has one feature. The recess 51 has a shape that is recessed from the front surface 11b of the upper unit 11 toward the back surface side, and is rejected from the recess 51 by the notch 51a of the side wall 11a formed continuously with the front surface 51b in the recess 51. The integrated space in the unit 50 is connected.

  By setting it as such a structure, it becomes easy to take out a reject banknote also from the apparatus front side. As shown in FIG. 4A, the short right-side corner 15a of the reject banknotes 15 stacked in the reject unit 50 protrudes from the stacking surface of the reject unit 50 to the front right side. The reject banknote 15 can be taken out.

  A lever 51 c for opening the upper unit 11 is provided in the recess 51. By engaging the lever 51c so as to be lifted upward, the engagement by the engagement member is released between the upper unit 11 and the lower unit 12. Then, by lifting the lever 51c further upward, the disengaged upper unit 11 can be lifted upward and opened as shown in FIG. 3 (A).

  As shown in FIG. 4B, the reject banknotes 15 are stacked in the stacking space of the reject unit 50 as shown by the broken lines. On the stacking surface on which the reject banknotes 15 are stacked, the stacking surface 50b between the two stopper members 52 is at a position cut out in the left direction of the apparatus (X-axis negative direction). Thus, the reject banknote 15 can be grasped and extracted.

  The back-side integrated surface 50c of the reject unit 50 is in a position cut out to the same position as the integrated surface 50b between the stopper members 52 in the left direction of the apparatus (X-axis negative direction). On the other hand, the front-side integrated surface 50a of the reject unit 50 is in a position that is cut out deeper than the integrated surface 50b and the back-side integrated surface 50c between the stopper members 52 in the left direction of the apparatus. Further, the notch 51a on the side wall of the reject unit 50 on the front side of the apparatus is located at a position further retracted to the left of the apparatus than the front-side integrated surface 50a. On the front side of the apparatus, an accumulation surface 50a is formed at a position that is notched one step deeper than the other accumulation surfaces 50b and 50c, and a side wall notch 51a is formed at a position that is notched one step further from the accumulation surface 50a. is there. That is, a two-stage cutout is formed on the front side of the apparatus by the front-side integrated surface 50a and the side wall cutout 51a.

[Operation display section]
FIG. 5 is a diagram illustrating a positional relationship between the two banknote stacking units 30 and 40 and the operation display unit 70. The banknote handling apparatus 1 has a large operation display unit 70 that can display a large amount of information while being a small device, and information on each banknote stacking unit is displayed on the operation display unit 70 as information displayed. It has one feature in that it displays so that the relationship with each banknote stacking unit can be easily recognized.

  The operation display unit 70 is a touch panel type liquid crystal display device composed of a 7 inch liquid crystal screen having a length of 107 mm and a width of 142 mm. The operation display unit 70 displays information such as characters, still images, and moving images in color and accepts information input from the touch panel. Is also possible. The size of the front surface of the banknote processing apparatus 1 comprising the upper unit 11 and the lower unit 12 is about 390 mm in length and about 350 mm in width, and the size of the display screen of the operation display unit 70 is the area ratio of the front surface of the apparatus. About 11%.

  As shown in FIG. 5, the first banknote stacking unit 30 and the second banknote stacking unit 40 are disposed on the left and right outer sides of the lower unit 12. The operation display part 70 is arrange | positioned in the position which contains the center line of the left-right direction seeing from the front side, and the banknote stacking part. Further, by disposing the banknote stacking units 30 and 40 in the lower unit 12 and disposing the operation display unit 70 in the upper unit 11, the liquid crystal is more than the distance (D2) between the left and right banknote stacking units 30 and 40. It is possible to use the operation display unit 70 having a wide width (D1) of the display screen.

  The left end of the display screen of the operation display unit 70 is on the apparatus outside (left side) from the right end of the first banknote stacking unit 30, and the right end of the display screen is on the apparatus outside (right side) from the left end of the second banknote stacking unit 40. For this reason, the exclusive 1st display area 201 which displays the information regarding the 1st banknote stacking part 30 in the lower left of the display screen of the operation display part 70 is provided, and the information regarding the 2nd banknote stacking part 40 is displayed on the lower right of the display screen. By providing the second display area 202, it is possible to easily recognize information corresponding to each banknote stacking unit. For example, as shown in FIG. 5, the number of banknotes stacked in the first banknote stacking unit 30 is displayed in the first display area 201, and the number of banknotes stacked in the second banknote stacking unit 40 is displayed in the second display. The total number of banknotes displayed in the area 202 is displayed at the approximate center of the operation display unit 70. Thus, the operation of the banknote processing apparatus 1 can be performed without displaying the character information indicating which banknote stacking unit 30 or 40 is associated with each piece of information displayed in the first display area 201 and the second display area 202. A person can easily recognize the relationship between the displayed information and the banknote stacking units 30 and 40.

  As described above, the upper side of the display screen of the operation display unit 70 corresponds to the upper surface of the banknote processing device 1, the left and right sides of the display screen correspond to the left and right side surfaces of the banknote processing device 1, and the lower side of the display screen corresponds to the bottom surface of the banknote processing device 1. When the display screen of the operation display unit 70 is regarded as the front of the apparatus and the display screen is divided into a plurality of partial areas, the first display area 201 at the lower left of the screen corresponding to the arrangement position of the first banknote stacking unit 30 is displayed. Information related to banknotes accumulated in the first banknote stacking unit 30 is displayed, and information related to banknotes stacked in the second banknote stacking unit 40 in the second display area 202 at the lower right of the screen corresponding to the second banknote stacking unit 40 is displayed. Is displayed. Thereby, the information regarding the banknotes accumulated in the first banknote stacking unit 30 is displayed on the first display area 201 close to the first banknote stacking unit 30 on the display screen of the operation display unit 70, and the second banknote stacking unit. Information on the banknotes accumulated in 40 is displayed in the second display area 202 adjacent to the second banknote accumulation unit 40 on the display screen.

  When displaying information related to the banknote processing device 1 on the display screen of the operation display unit 70, the position of the information to be displayed and the position of the component of the banknote processing device 1 related to this information are displayed in correspondence with each other. Thus, the operator can easily recognize the relationship between each displayed information and the components of the banknote handling apparatus 1.

  In addition, in FIG. 5, although the example which displays on the display screen of the operation display part 70 the number of banknotes integrated | stacked on each banknote stacking part was shown, a denomination is changed by changing the setting which concerns on display information besides this. It is also possible to display the type of banknotes such as or damage, the total amount of banknotes accumulated in each banknote stacking unit, information indicating how many remain until the predetermined number of sheets is reached, and the like. Further, for example, information related to operations performed on each banknote stacking unit, such as information for instructing withdrawal of banknotes from the banknote stacking unit, can be displayed. It is also possible to display a plurality of information in the display areas 201 and 202, for example, to display both the denomination and the number of sheets. Further, the number of batches and the number of batch formations can be displayed on the screen when batch processing is performed, but details will be described later.

[Internal structure of the device]
Next, the internal structure of the banknote handling apparatus 1 will be described. FIG. 6 is a schematic cross-sectional view showing an outline of the internal structure of the banknote handling apparatus 1 as seen from the front. The banknote at the bottom of the plurality of banknotes placed in a stacked state on the hopper 20 on the upper right side of the apparatus is sent out by the kicker roller 23 toward the inside of the apparatus. And the banknote is isolate | separated one by one with the feed roller 25 and the reverse rotation roller 24 which were provided facing each other, and only the lowest banknote is drawn out to a conveyance path. The banknotes fed into the apparatus are conveyed leftward on a conveyance path formed by the upper conveyance guide 26 and the lower conveyance guide 27. In the conveyance path, a large number of rollers and conveyance belts 90 to 95 wound around a plurality of rollers are exposed from the conveyance guides 26 and 27 into the conveyance path, and the bills are conveyed by the rollers or the conveyance belts 90 to 95. It has come to be.

  The conveyor belts 91 to 95 do not make the upper and lower conveyor belts wound around the rollers at both ends parallel to each other, and the conveyor belt on the side forming the conveyance path is pushed up or down by the rollers. . Thereby, even if it does not provide a roller facing up and down of a conveyance path, it is possible to ensure the grip force between the conveyed banknote and a conveyance belt, and to perform stable conveyance.

  The conveyance path in the banknote processing apparatus 1 includes an upper conveyance path that conveys the left side (X-axis negative direction) in the upper unit 11 and a lower part that conveys the banknotes in the right direction (X-axis positive direction) in the lower unit 12. It is comprised by the conveyance path and the intermediate conveyance path which connects an upper conveyance path and a lower conveyance path, and conveys a banknote below (Z-axis negative direction). The banknotes fed out from the hopper 20 and transported leftward in the upper transport path pass through the identification unit 100, then change direction and are transported downward in the intermediate transport path, and then further turn in the lower transport path. Is transported to the right.

  The identification unit 100 provided in the upper conveyance path emits light that is excited by irradiating UV light (ultraviolet light) with a line sensor 101 for acquiring a transmission image, a reflection image on the upper surface of the bill, and a reflection image on the lower surface of the bill. A UV sensor 102 for detecting the thickness of the bill, a thickness detection sensor 103 for detecting the thickness of the bill, and a magnetic detection sensor 104 for detecting the magnetic characteristics of the bill. Based on the optical characteristics, magnetic characteristics, and thickness of the banknote obtained by these sensors, the denomination, authenticity, correctness, front / back, direction, etc. of the banknote can be identified.

  Several conveyance banknote detection sensors 80-85 which detect passage of a bill are arranged in a conveyance way. The transported banknote detection sensors 80 to 85 are configured by a light projecting unit and a light receiving unit, and detect a banknote based on a change in light transmission / shielding due to the passage of the banknote. In the upper conveyance path, the identification unit 100 that recognizes the passage timing of the banknote based on the detection result by the conveyance banknote detection sensor 81 performs a process of identifying the banknote that passes.

  In the lower conveyance path, the first branch member 111 is provided at the first branch point, and the second branch member 112 is provided at the second branch point downstream from the first branch point. At the first branch point, the first branch member 111 distributes the banknotes downstream of the lower conveyance path or to the first banknote stacking unit 30. Similarly, at the second branch point, the second branch member 112 distributes the banknotes to the reject unit 50 or the second banknote stacking unit 40.

  Specifically, the first branch member 111 is controlled based on the identification result by the identification unit 100 and the passage timing of the banknote detected by the transport banknote detection sensor 83 in the intermediate transport path. And when the banknote detected by the conveyance banknote detection sensor 83 is not the collection object of the 1st banknote stacking part 30, the 1st branch member 111 will be in the state shown in FIG. 6, and a banknote will branch to the 1st banknote stacking part 30. Without passing through the first branch point, it is conveyed rightward. On the other hand, if the banknote is a banknote to be stacked by the first banknote stacking unit 30, the first branching member 111 rotates clockwise, and the banknote is branched from the transport path, and then the first banknote stacking unit. It is conveyed toward 30. Similarly, the second branch member 112 is controlled based on the identification result and the passage timing of the banknote detected by the transport banknote detection sensor 84 in the lower transport path. And the banknote used as the collection object of the 2nd banknote stacking part 40 is conveyed toward the 2nd banknote stacking part 40, after being branched from the conveyance path. On the other hand, when the banknote is a reject banknote, the banknote passes through the second branch point without being branched toward the second banknote stacking unit 40 and is further conveyed to the right and is conveyed to the reject unit 50. In the reject unit 50, reject banknotes conveyed at high speed are ejected vigorously, but the front end of the reject banknote is received by the stopper member 52, and the rear end of the reject banknote is hit downward by the rotating bill tapping rubber 54. It is like that. Further, the rejected banknotes are accumulated in the reject unit 50 by being restrained downward by the restraining member 53.

  The downstream side of the second branching member 112 is an upwardly inclined inclined conveying path that is inclined to become higher toward the downstream. And the reject part 50 is arrange | positioned so that it may go into the left direction under this inclination conveyance path, and the rejection banknote conveyed by the inclination conveyance path in the upper diagonal direction is rejected from the upper left of the rejection part 50. 50 is discharged to the accumulation space in 50. As a result of inclining the conveyance path and disposing the reject unit 50 inside the apparatus as much as possible, the position of the rotation axis of the tapping rubber 54 is more horizontal (X-axis direction) than the position of the rotation axis of the kicker roller 23 of the hopper 20. ) In the device internal direction (X-axis negative direction). In the banknote processing apparatus 1, in addition to stacking the banknotes of the banknote stacking sections 30 and 40 in an inclined standing posture, the banknote processing is performed by adopting a structure in which a part of the reject section 50 is embedded in the apparatus in this way. The device 1 is reduced in size.

  In addition, the conveyance banknote detection sensor 85 is provided in the downstream from the 2nd branch member 112, the 2nd banknote stacking from the branch conveyance path branched from the 1st branch member 111 to the 1st banknote stacking part 30, and the 2nd branch member 112 is carried out. The banknote detection sensors 86 and 87 are also provided in the branch conveyance path branched to the section 40 (see FIG. 11), so that banknotes existing in the conveyance path can be detected. These transported banknote detection sensors 80 to 87 detect the presence or absence of a banknote being transported, and are also used to detect the presence or absence of residual banknotes remaining in the transport path when an error occurs and the transport of banknotes is stopped. The

  Extrusion members 34 and 44 are provided on the back side of the first banknote stacking unit 30 and the second banknote stacking unit 40. After the processing of the banknotes placed on the hopper 20 is completed and all banknotes are accumulated in one of the first banknote stacking unit 30, the second banknote stacking unit 40, and the rejecting unit 50, the pushing member 34, When 44 moves forward, all the banknotes accumulated in the accumulation space are pushed out toward the front opening, and details thereof will be described later.

[Opening and closing the upper part of the device]
Next, opening / closing of the upper unit 11 of the banknote handling apparatus 1 and opening / closing of the identification unit 100 of the upper unit 11 will be described. As shown in FIG. 3A, when the upper unit 11 is opened upward, the support shaft 19 which is the center of rotation is provided on the frame 106 fixed to the lower unit 12 as shown in FIG. . Further, when the identification unit 100 in the upper unit 11 is opened upward with the upper unit 11 closed, the support shaft 18 serving as the center of rotation is provided on a frame fixed to the upper unit 11. Yes.

  The upper lid 13 of the housing is divided into a front lid 13a and a rear lid 13b. The rear lid 13b is supported by a support shaft 17 at the rear end of the front lid 13a so as to be pivotable clockwise around the support shaft 17.

  FIG. 7 is a schematic cross-sectional view showing a state where the identification unit 100 is opened upward. The identification unit 100 is divided into two parts above and below the conveyance path. The upper part of the conveyance path of the identification unit 100 and a part of the rollers on the upstream side and the downstream side of the identification unit 100 on the upper side of the conveyance path constitute the identification unit upper unit 105. The identification unit upper unit 105 rotates about the support shaft 18 and opens upward. Thereby, inspection and maintenance of each sensor 101-104 provided in discernment part 100 can be performed, and a bill and garbage jammed in an upper conveyance way can be removed.

  When the identification unit upper unit 105 opens together with the front lid 13a as shown by the solid arrow in FIG. 7, the rear lid 13b rotates around the support shaft 17 as shown by the dashed arrow. By rotating the rear lid 13b while moving the rear lower end downward along the left side surface 12a of the housing, the rear lid 13b is integrated with the front lid 13a and the rear lid 13b. This prevents the rear lower end from interfering with other members to restrict the rotation of the identification unit upper unit 105. For this reason, the identification unit upper unit 105 is greatly opened upward.

  FIG. 8 is a schematic cross-sectional view showing a state in which the upper unit 11 is opened upward. When the upper unit 11 rotates about the support shaft 19 as shown by the solid arrow in FIG. 8 and opens upward, the rear lid 13b rotates around the support shaft 17 as shown by the broken arrow. To do. By rotating the rear lid 13b while moving the rear lower end downward along the housing left side surface 12a, the upper lid 13 does not interfere with other members and does not limit the rotation of the upper unit 11. The upper unit 11 is greatly opened upward.

  The upper conveyance path including the identification unit 100 is included in the upper unit 11 that moves upward when the upper unit 11 is opened upward as shown in FIG. The intermediate conveyance path is divided into a right side and a left side of the conveyance path, and the right side component is included in the upper unit 11, and the left component is included in the lower unit 12. The lower conveyance path is divided into an upper side and a lower side of the conveyance path, and the upper component part is included in the upper unit 11, and the lower component part is included in the lower unit 12. As described above, the intermediate transport path and the lower transport path are divided into the upper unit 11 and the lower unit 12, so that the upper unit 11 is opened, the intermediate transport path and the lower transport path are opened, and the banknotes jammed in the transport path. And garbage can be removed.

  The holding member 53 that suppresses the banknotes by the hopper 20 and the reject unit 50 is included in the upper unit 11, and the main body of the reject unit 50 is included in the lower unit 12. In order to reduce the size of the apparatus, in the banknote handling apparatus 1, the arrangement positions of the respective parts are embedded in the apparatus as much as possible in the apparatus so that the reject section 50 does not protrude greatly from the right side surface of the apparatus. However, by opening the upper unit 11 as shown in FIG. 8, banknotes, dust, etc. jammed in the lower conveyance path to the reject unit 50 and the reject unit 50 can be easily removed.

  In the lower unit 12, the length of the branch conveyance path from the first branch point that branches the banknotes toward the first banknote stacking unit 30 from the lower transport path to the first banknote stacking unit 30 is the banknote length in the transport direction, That is, it is shorter than the short length of the banknote. For this reason, even when the banknote branched by the 1st branch point is jammed in the middle of being conveyed to the 1st banknote stacking part 30, the state which the banknote front end was exposed in the stacking space of the 1st banknote stacking part 30 or It will be in any state of the state where the rear end of the bill is exposed on the lower conveyance path. Similarly, the length of the branch conveyance path from the second branch point that branches the banknotes toward the second banknote stacking unit 40 from the lower transport path to the second banknote stacking unit 40 is also shorter than the short length of the banknotes, Even when the conveyance of banknotes stops at this position, either the banknote front end in the stacking space of the second banknote stacking unit 40 or the banknote rear end on the lower transport path can be confirmed.

  Thus, in the banknote processing apparatus 1, when conveyance stops due to banknote jam or the like, as shown in FIG. 7 and FIG. 8, the identification unit upper unit 105 and the upper unit 11 are opened upward so that the upper conveyance is performed. It is possible to reliably remove banknotes in the path, intermediate transport path and lower transport path, banknotes stopped after passing through the first branch point and the second branch point, and the like.

[Trash receptacle]
As shown in FIG. 1, a push-open type dust tray 71 that protrudes toward the front side by being pushed toward the back side is disposed on the front surface of the upper unit 11. As shown in FIG. 6, the dust tray 71 slides in the front-rear direction in a groove formed in a dust receiving plate 72 fixed below the identification unit 100, and is pushed to the rear side of the dust tray 71. An open mechanism is provided. A dust receiving portion is formed by the dust tray 71 and the dust receiving plate 72.

  The thickness detection sensor 103 of the identification unit 100 includes a reference roller on the lower side of the conveyance path that is rotatably supported on a fixed shaft, and a detection roller that is supported on the upper side of the conveyance path so as to be displaceable and rotatable in the vertical direction. Are made in close contact with each other to form a roller pair, and the thickness of the banknote is detected based on the movement of a detection roller in which the banknote passes between the roller pair and is displaced in the vertical direction. A large number of roller pairs composed of a reference roller and a detection roller are provided in a direction perpendicular to the conveying direction (Y-axis direction), and dust attached to the banknotes while passing between a plurality of closely contacted roller pairs. It is easy to fall off. In addition, paper dust may be peeled off from the bill itself. In the magnetic detection sensor 104, the bills are brought into close contact with the magnetic detection sensor arranged on the upper side of the conveyance path by the bristle roller arranged on the lower side of the conveyance path. However, dust and paper dust are also easily generated here. For this reason, a dust tray 71 is disposed below the thickness detection sensor 103 and the magnetic detection sensor 104 so that paper dust and dust are received by the dust tray 71.

  FIG. 9 is a schematic diagram showing the shapes of the dust tray 71 and the dust receiving plate 72. FIG. 9A shows a view of the dust tray 71 and the dust receiving plate 72 as viewed from above, and FIG. 9B shows a view as seen from the front. FIG. 9C shows the dust tray 71 and the dust receiving plate 72 viewed from the front when the upper unit 11 is opened as shown in FIG. 9A shows a portion below the conveyance path of the identification unit 100, the reference roller is shown at the position of the thickness detection sensor 103, and the hair at the position of the magnetic sensor 104. A roller is shown.

  As shown in FIG. 9A, the length of the dust tray 71 and the dust receiving plate 72 in the apparatus front-rear direction (Y-axis direction) is the width of the transport path formed by the transport guides 26 and 27 (length in the Y-axis direction). Is longer than the identification unit 100.

  As shown in FIG. 9B, the shape of the dust receiving plate 72 viewed from the front is a shape inclined to the left from the left end located below the magnetic detection sensor 104 toward the dust tray 71 on the left side of the dust tray 71. It has become. As a result, as shown by arrows in FIG. 9B, paper dust and dust received at the inclined portion slide down into the dust tray 71.

  The shape of the dust receiving plate 72 is horizontal on the right side of the dust tray 71. However, when the right side surface of the upper unit 11 is opened upward as shown in FIG. As shown in FIG. 9C, the dust receiving portion made of the plate 72 is also tilted so that the right side is raised upward. For this reason, as shown by an arrow in FIG. 9C, the paper dust and the dust accumulated in the horizontal portion on the right side of the dust receiving plate 72 slide down and collect in the dust tray 71.

  Thus, when the dust tray 71 in which paper dust and dust are collected is pushed toward the back side, a part of the dust tray 71 pops out to the front side by a push-open mechanism provided on the back side. By removing the dust tray 71 partially protruding from the front surface of the housing from the apparatus, it is possible to discard paper dust and garbage collected in the dust tray 71.

  The structure of the dust receiving portion is not limited to a shape in which the dust receiving plate 72 is integrally formed with a groove portion that slides the dust tray 71 and a plate portion that collects dust. There may be a mode in which a dust collecting plate portion is provided separately, and a dust collecting plate 72 is used as the dust collecting plate portion. Further, the dust receiving plate 72 may be configured by a single plate or may be configured by a plurality of plates. Further, not only the left side of the dust tray 71 but also the right side, the back side, and the like may be provided with an inclined plate on which the dust slides on the dust tray 71, and this may be used as the dust receiving plate 72. Regardless of the configuration of the dust receiving portion, at least one of the dust tray 71 and the dust receiving plate 72 is disposed below the thickness detection sensor 103 and the magnetic detection sensor 104 of the identification portion 100.

[Structure of banknote stacking unit]
FIG. 10 is a diagram for explaining the structure of the first banknote stacking unit 30. In addition, since the 2nd banknote stacking part 40 has the same structure as the 1st banknote stacking part 30, it will become a structure which shows the 2nd banknote stacking part 40 if the 1st banknote stacking part 30 shown in FIG. The description of the second banknote stacking unit 40 will be omitted, and the first banknote stacking unit 30 will be described.

  In addition, although the accumulation space of the 1st banknote stacking part 30 is formed by several members, such as a side wall member, the code | symbols 30a and 30b are used as a part of the 1st banknote stacking part 30 in FIG. 30c. A triangular plane parallel to the XZ plane is formed at the front end of the left side wall 30b, and a substantially triangular plane parallel to the XZ plane is formed at the front end of the right side wall 30c. The bottom side of the front end plane part of the left side wall 30b and the bottom side of the front end plane part of the right side wall 30c are at different heights, and the left side wall 30b and the right side wall 30c are in a position retracted in the back direction compared to the bottom face 30a. . An opening left side surface 35 shown in FIG. 1 is formed on a surface (see reference numeral 130a in FIG. 15) that protrudes forward from the bottom of the triangular plane of the left side wall 30b in parallel with the XY plane, and the substantially triangular shape of the right side wall 30c. The opening right side surface 32 shown in FIG. 1 is formed on a surface (see 131a in FIG. 15) that protrudes forward from the bottom of the shape plane in parallel with the XY plane. Specifically, the left side surface 35 of the opening shown in FIG. 1 is formed by connecting the left side wall 30b and the cutout 31 on the left side surface of the housing so as to cover the triangular plane portion at the front end of the left side wall 30b. The right side surface 32 of the opening shown in FIG. 1 is formed by connecting the right side wall 30c and the recess 60 so as to cover a substantially triangular plane portion at the front end of the right side wall 30c.

  In the 1st banknote stacking part 30, the banknote branched by the 1st branch member 111 from the lower conveyance part is conveyed by a branch conveyance path, and is discharged | emitted from the upper right part into accumulation space. The banknotes discharged into the banknote stacking unit are sent leftward by an impeller 33 that rotates counterclockwise, and stacked so that the banknote surface is along the inclined side wall 30b, and the banknote longitudinal edge is in contact with the bottom surface 30a. Accumulated in form.

  The angle a between the horizontal plane and the side wall 30b shown in FIG. 10 is 70 degrees, the angle b between the horizontal plane and the bottom face 30a is 15 degrees, and the angle c between the bottom face 30a and the side wall 30b is 95 degrees. . When the angle a is decreased, the size of the banknote stacking unit in the lateral direction (X-axis direction) is increased, and the banknote handling apparatus 1 is increased in size. In addition, when the angle a is increased, the banknotes in the inclined standing state are not stabilized, and the stacked banknotes fall toward the impeller 33 and interfere with banknotes that have newly entered the banknote stacking unit, resulting in poor stacking. Will occur. For this reason, it is preferable that the angle a is 60 degrees or more and 80 degrees or less.

  For example, in the first banknote accumulated from the state where there is no banknote, the upper longitudinal edge is in contact with the side wall 30b, while the lower longitudinal edge is in contact with the bottom surface 30a at a position away from the side wall 30b. Often accumulated. Thereafter, while the subsequent banknotes are sequentially stacked, the long side edge of the banknote in contact with the bottom surface 30a is pushed and moved toward the side wall 30b. It comes along the side wall 30b. Subsequent banknotes move in the same manner and are stacked on the first banknote. It is preferable that the angle b formed by the bottom surface 30a is larger than 0 degrees so that the lower longitudinal edge of the previously accumulated banknote is pushed by the succeeding banknote and the bottom surface 30a is easily moved toward the side wall 30b. On the other hand, if the angle b is increased too much, it is necessary to reduce the angle a accordingly, and the lateral size of the banknote stacking unit is increased, resulting in an increase in size of the apparatus. For this reason, it is preferable that the angle b is larger than 0 degree and 30 degrees or less.

  With the above range setting of the angle a and the angle b, the angle c between the bottom surface 30a and the side wall 30b is preferably larger than 70 degrees and smaller than 120 degrees. Moreover, the length d of the side wall 30b is set according to the largest banknote with the shortest length among the banknotes to be processed. For example, when the short length of the largest banknote is 85 mm, the length d of the side wall 30b is set to 93 mm.

  The height e from the rotation axis center of the impeller 33 to the upper surface of the accumulation space is set according to the largest banknote having the shortest length among the banknotes to be processed. If a banknote entering from the upper right of the stacking space collides with the upper surface of the stacking space while being sent to the left by the impeller 33 rotating counterclockwise, the banknotes cannot be stacked in an aligned state, resulting in poor stacking. For this reason, while the largest banknote penetrates between the blades of the impeller 33 and the impeller 33 rotates while one longitudinal edge of the largest banknote is in contact with the root portion of the blade, The height e is set so that the locus drawn by the longitudinal edge is lower than the upper surface of the accumulation space.

  In the banknote handling machine 1, 16 blades are provided at an interval of 30 degrees on the outer peripheral surface of a base portion having an outer diameter of 50 mm with the rotation axis as the center, and the tip of each blade is in a direction opposite to the rotation direction of the impeller 33. An impeller 33 having an outer diameter of 100 mm is formed. When viewed from the center of the impeller 33, the central angle from the base of each blade to the tip of each blade is 60 degrees. In the banknote processing apparatus 1, the height e is set to 71.5 mm so that the maximum banknote having a short length of 85 mm can be stacked without causing a stacking failure by the impeller 33.

  The length f of the bottom surface 30a is set according to the number of banknotes stacked on the banknote stacking unit. Since banknotes to be processed include those with folds or wrinkles, the length f is set in consideration of this. In the banknote handling apparatus 1, the length f is set to 33 mm in order to stack 200 banknotes.

[Bill transport path structure]
FIG. 11 is a schematic diagram illustrating the shape of the lower conveyance path in the lower unit 12 as viewed from the front. FIG. 11A shows the shape of the lower conveyance path of the banknote handling apparatus 1 shown in FIG. 6, and FIG. 11B shows an example in which the shape of the lower conveyance path is different. In FIG. 11, in order to facilitate understanding of the shape of the lower conveyance path, the conveyance belts and rollers are omitted, and the shape of the conveyance path is shown by the conveyance guides 26 and 27. The bill is conveyed between the conveyance guides 26 and 27. Moreover, although illustration was abbreviate | omitted in FIG. 6, the conveyance banknote detection sensor 86 is provided in the branch conveyance path after branching from the lower conveyance path to the 1st banknote stacking part 30, as shown in FIG. The banknote detection sensor 87 is also provided in the branching conveyance path after branching from the first banknote stacking unit 40 to the second banknote stacking unit 40.

  As shown in FIG. 11A, the first branch point where the first branch member 111 is installed in the lower transport path in which the banknote 15 transported downward in the intermediate transport path changes its direction and is transported to the right. The conveyance path is formed horizontally up to a position passing through 111a. In the banknote handling apparatus 1, the branching member having the same shape as the first branching member 111 is used as the second branching member 112 even at the second branching point 112 a that branches the banknotes to the second banknote stacking unit 40.

  In order to convey the banknotes to the second banknote stacking unit 40 or the reject unit 50 by swinging the second branching member 112, a transport direction 112b to the second banknote stacking unit 40 and a transport direction 112c to the reject unit 50 It is necessary to ensure an angle between the predetermined angle or more. In other words, if the conveyance path of the second branch point 112a is the horizontal direction, the angle between the horizontal conveyance path and the conveyance path that branches in the conveyance direction 112b becomes narrow, and the second branch member 112 cannot be used. For this reason, in the banknote processing apparatus 1, the conveyance path of the 2nd branch point 112a is inclined upwards so that the height of the downstream side may become high, and to the conveyance direction 112b to the 2nd banknote stacking part 40, and the rejection part 50 By enlarging the angle with respect to the conveying direction 112c, the second branching member 112 having the same components as the first branching member 111 can be used. As a result, the conveyance direction of the banknote passing through the first branching point 111a toward the second banknote stacking unit 40 is different from the conveyance direction of the banknote passing through the second branching point 112a toward the rejecting unit 50. ing.

  Further, after the banknote is branched at the first branch point 111a, the branch transport path is transported toward the first banknote stacking unit 30, and after the bank branch is branched at the second branch point 112a, the branch transport path is The direction conveyed toward the second banknote stacking unit 40 is a different direction. Specifically, a straight line connecting the first branch point 111a and the rotation axis of the impeller 33 of the first banknote stacking unit 30, and the rotation axis of the second branch point 112a and the impeller 43 of the second banknote stacking unit 40 are defined. The connecting line is in a different direction.

  In addition, as described above, even when the conveyance of banknotes is stopped, the front end in the banknote conveyance direction is exposed in the stacking space in the banknote stacking unit, or the rear end in the banknote conveyance direction is exposed on the lower conveyance path. In order to be in a state, it is necessary to make the distance from the lower conveyance path to the accumulation space shorter than the short length of the banknote. When the first branching member 111 and the second branching member 112 are provided at the same height, and the first banknote stacking unit 30 and the second banknote stacking unit 40 have the same shape, the second banknote stacking unit 40 Will be higher than the first banknote stacking unit 30. For this reason, in the banknote processing apparatus 1, the first banknote stacking unit 30 that satisfies the conditions related to the transport distance and has the same shape by lowering the installation height of the second branching member 112 from the installation height of the first branching member 111 and The positional relationship which makes the 2nd banknote stacking part 40 the same height is implement | achieved.

  And since the horizontal conveyance path of the 1st branch point 111a and the conveyance path inclined upwards of the 2nd branch point 112a are connected, the height of a conveyance path becomes low in the downstream of the 1st branch point 111a. The lower conveyance path is formed so as to be connected to the upwardly inclined conveyance path after changing the direction after being inclined downward.

  As described above, in the lower conveyance path of the banknote handling apparatus 1, the banknote that has passed through the first branch point 111a in the horizontal direction is transported through the conveyance path that is inclined downward from the horizontal direction, and then the direction is changed. The transport path is transported to the second branch point 112a, and then the transport path inclined upward is further transported toward the reject unit 50. In order to reliably convey the banknote in the curved conveyance path in this way, in the banknote handling apparatus 1, the lower conveyance section is configured by the banknote conveyance belts 91 to 95 as shown in FIG.

  In addition, although the lower conveyance path of the banknote processing apparatus 1 has the shape shown in FIG. 11A in order to share the parts of the first branching member 111 and the second branching member 112, the shape of the lower conveyance path is the same. The shape shown in FIG. 11B may be used. Specifically, the second banknote stacking unit 40 or the reject is made using a second branch member 113 having a shape different from that of the first branch member 111 in the horizontally extending conveyance path on the downstream side of the first branch member 111. The aspect conveyed to the part 50 may be sufficient.

  A control unit is provided inside the banknote handling apparatus 1. The above-described feeding out from the hopper 20, conveyance of banknotes on the conveyance path, identification of banknotes by the identification unit 100, determination of the conveyance destination of banknotes based on the identification result, control of the branch members 111 and 112 based on this determination, and the like Is done by. Moreover, the movement of the extrusion member 34 demonstrated below, the extraction detection of the banknote from the banknote stacking parts 30 and 40, the display of various information to the operation display part 70, the notification of various information with respect to an operator, and a plurality of banknote stacking parts Selection of banknote stacking unit based on priority setting with priority set, banknote stacking unit priority setting and assignment of banknote type to each banknote stacking unit based on number of processed banknotes processed in the past The above is also realized by the control unit controlling each unit. These controls are performed by the control unit executing each program stored in the storage unit while referring to various setting contents stored in the storage unit. However, a method for realizing the control is a conventional method. Since it is the same as the technology, the function and operation of each unit realized by the control unit will be mainly described below.

[Bill extruding mechanism]
Next, the extrusion members 34 and 44 provided on the back side in the stacking space of the first banknote stacking unit 30 and the second banknote stacking unit 40 of the banknote handling apparatus 1 will be described. After the processing of the banknotes placed on the hopper 20 is completed and all banknotes are stacked on one of the first banknote stacking unit 30, the second banknote stacking unit 40, and the reject unit 50, the first banknote stacking unit In 30 and the 2nd banknote stacking part 40, when the extrusion members 34 and 44 move ahead, all the banknotes integrated | stacked in the banknote stacking part are extruded toward the front opening part. Since the structure of the extruding members 34 and 44 and the drive mechanism for moving the extruding members 34 and 44 are the same in the first banknote stacking unit 30 and the second banknote stacking unit 40, the first banknote stacking unit will be described below. 30 will be described.

  FIG. 12 is a perspective view showing the structure of the pushing member 34 provided inside the first banknote stacking unit 30 and the drive mechanism for moving the pushing member 34. In FIG. 12, the outer side wall member 130 on the apparatus outer side (X-axis negative direction side) where the banknotes sent by the impeller 33 in the stacking space of the first banknote stacking unit 30 are stacked so as to contact the banknote surface, The push-out member 34 provided to be slidable in the front-rear direction (Y-axis direction) along the outer side wall member 130 fixed to the apparatus, and a drive mechanism for driving the push-out member 34 are shown. FIG. 12A shows a retracted position when banknotes are stacked, and FIG. 12B shows an extruding position when the banknotes accumulated inside are pushed forward by the pushing member 34.

  The pushing member 34 has a structure in which the back plate 34a, the bottom plate 34b, and the side plate 34c are integrated. The back plate 34a, the bottom plate 34b, and the side plate 34c have a thin plate shape, and the strength is maintained on the back side of the back plate 34a, the bottom plate 34b, and the side plate 34c with the inside of the stacking space of the banknote stacking unit as the front side. Ribs are provided. In the banknote processing apparatus 1, for example, an extrusion member 34 in which a back plate 34a, a bottom plate 34b, and a side plate 34c are integrally formed of a resin material is used.

  A plurality of serrated projections are provided on the outer peripheral edge of the back plate 34a, and grooves are provided in the front-rear direction at corresponding positions on the wall surface forming the accumulation space so as to mesh with the projections. When the pushing member 34 moves, the protrusion of the back plate 34a moves in the groove on the wall surface, so that bills do not enter the gap between the pushing member 34 and the wall surface. Further, the side surface plate 34c has a stepped shape corresponding to the protrusion of the back plate 34a, and the outer side wall member 130 has a shape matched to the surface shape. A bill is prevented from entering the gap between the face plate 34 c and the outer side wall member 130.

  The first banknote stacking unit 30 is provided with a plurality of banknote detection sensors for detecting the presence or absence of banknotes in the stacking space. The integrated banknote detection sensor is composed of two units that project and receive light that traverses the accumulation space. For example, the light irradiated from the light projecting unit installed outside one of the banknote accumulation units passes through the accumulation space, Light is received by a light receiving unit installed outside the other side of the banknote stacking unit. When the light from the light projecting unit is blocked by the banknotes stacked in the banknote stacking unit, the light receiving unit cannot receive the light, thereby detecting the presence or absence of banknotes. A plurality of stacked banknote detection sensors are arranged by adjusting the positions of the light projecting section and the light receiving section so that the banknotes in the banknote stacking section can be reliably detected. The pusher member 34 is provided with sensor brushes 140a and 140b for cleaning the stacked banknote detection sensor when the pusher member 34 is moved, and details thereof will be described later.

  As shown in FIG. 12A, the side plate 34c of the pushing member 34 is provided with three through holes 37a to 37c for the accumulated banknote detection sensor, and the outer side wall member 130 also has two holes for the accumulated banknote detection sensor. Through holes 137a and 137b are provided. Corresponding to the through hole 37c of the side plate 34c in the retracted position, the stacked banknote detection sensor is arranged on the back side of the side plate 34c, that is, outside the banknote stacking unit. In addition, an accumulated banknote detection sensor is arranged on the back side of the outer side wall member 130 corresponding to the through holes 137a and 137b of the fixed outer side wall member 130.

  When the push-out member 34 is in the retracted position shown in FIG. 12A, the stacked banknote detection sensor is not disposed at a position corresponding to the through holes 37a and 37b of the side plate 34c, but these through holes 37a and 37b are not provided. As shown in FIG. 12 (B), when the pushing member 34 moves to the pushing position, it is provided so as to overlap the through holes 137a and 137b of the outer side wall member 130. Thereby, even when the pushing member 34 moves to the pushing position, the light of the accumulated banknote detection sensor on the back side of the outer side wall member 130 is not blocked by the side plate 34c, so that these accumulated banknote detection sensors can be used. It has become.

  The drive mechanism that slides the push-out member 34 back and forth includes a motor 120, a cam plate 121 that is rotated by the motor 120, and a link plate 122 that is driven by the cam plate 121. The rotation of the cam plate 121 is converted into the back-and-forth movement of the pushing member 34 by the link plate 122.

  The pushing member 34 is supported so as to be slidable only in the front-rear direction, with the movement in the lateral direction (X-axis direction) and the vertical direction (Z-axis direction) restricted. One end of the link plate 122 is rotatably attached to a shaft that protrudes from the bottom side of the bottom plate 34 b of the push member 34. The other end of the link plate 122 is rotatably attached to a rotating shaft 122b fixed to the apparatus. The link plate 122 is provided with an elongated through hole 122a. The shaft on the other end side of the cam plate 121 having one end connected to the rotating shaft of the motor 120 is inserted into the through hole 122a. When the cam plate 121 is rotated by the motor 120, the shaft of the cam plate 121 reciprocates within the through hole 122 a of the link plate 122. By this reciprocation, the other end of the link plate 122 supported by the rotating shaft 122b moves back and forth, and the pushing member 34 connected to the other end moves back and forth.

  A spring member (not shown) that applies a tensile force in the direction indicated by the arrow in FIG. 12 is attached to the shaft 122c of the link plate 122. When the motor 120 is stopped, the link plate 122 is pulled by the tensile force of the spring member. Moves so that the pushing member 34 returns to the retracted position.

  In addition, the front end of the outer side wall member 130 is on the back side from the notch 31 provided on the left side surface of the first banknote stacking unit 30, and a triangular plane parallel to the XZ plane is formed at the front end portion. (See FIG. 10). An opening left side surface 35 shown in FIG. 1 is formed in a portion 130a on the front side of the apparatus from the plane of the front end.

  FIG. 13 is a schematic diagram showing a method of moving the push member 34 by the drive mechanism. 13 shows a view from above, FIG. 13 (A) shows a retracted position corresponding to FIG. 12 (A), and FIG. 13 (B) shows an extrusion position corresponding to FIG. 12 (B). ing. As shown in FIG. 13, the push member 34 is provided with three sensor brushes 140 c to 140 e in addition to the sensor brushes 140 a and 140 b shown in FIG. 12. Details of the sensor brushes 140 a to 140 e are as follows. It will be described later.

  The bottom plate 34b of the pushing member 34 has a rib on the back side, and this rib is provided with a through hole. A rod-shaped slide guide 123 is fixed to the apparatus in a state of penetrating the through hole of the rib of the pushing member 34. This slide guide 123 guides the slide movement of the push-out member 34 in the front-rear direction and restricts the movement in the other direction.

  The bottom plate 34b of the pushing member 34 has a shaft 122d protruding to the back side, and one end side of the link plate 122 is rotatably attached to the shaft 122d. When the motor 120 fixed to the apparatus rotates the cam plate 121, the link plate 122 swings around the rotation shaft 122b at the other end, and the pushing member 34 moves in the longitudinal direction of the apparatus (Y Move in the axial direction).

  The banknote handling apparatus 1 is provided with a retracted position detection sensor 124 for detecting that the pushing member 34 is in the retracted position. Further, on the back side of the back plate 34 a of the pushing member 34, a light shielding plate 38 used by the retreat position detection sensor 124 is provided. As shown in FIG. 13A, when the pushing member 34 is in the retracted position, the light projected and received between the light projecting portion and the light receiving portion of the retracted position detection sensor 124 is shielded by the light shielding plate 38. When the motor 120 starts to rotate with the pushing member 34 in the retracted position and the pushing member 34 starts to move forward, the light transmission portion between the light projecting portion and the light receiving portion of the retracting position detection sensor 124 is in a translucent state. Become. When the motor 120 continues to rotate, the pushing member 34 that moves forward reaches the pushing position. Thereafter, the motor 120 continues to rotate without stopping, and the pusher member 34 starts to move backward from the push-out position to the retreat position with this rotation. Then, when the light shielding plate 38 on the back side of the retreating pushing member 34 reaches the position of the retreat position detection sensor 124, the retreat position detection sensor 124 returns the retraction position 34 to the retreat position due to the light shielding state again. Detect that. Then, in response to the detection result by the retreat position detection sensor 124, the rotation of the motor 120 is stopped.

  As described above, in the banknote processing apparatus 1, the push member 34 is moved back and forth by the link mechanism while rotating the rotation shaft of the motor 120 in the same direction by using the inexpensive motor 120 that cannot detect the rotation angle or the like. Can do. In addition, the motor 120 can be stopped at an appropriate timing by providing the light blocking plate 38 on the push member 34 and detecting the retreat position of the push member 34 by the retreat position detection sensor 124. Further, by pulling the shaft 122c of the link plate 122 in the direction indicated by the arrow in FIG. 13 by a spring member (not shown), the pushing member 34 is surely returned to the retracted position after the motor 120 is stopped. .

  FIG. 14 is a schematic diagram for explaining the retracted position and the pushing position of the pushing members 34 and 44 in the banknote stacking unit. FIG. 14 shows a view of the banknote handling apparatus 1 as viewed from the right side, showing the upper unit 11 in appearance and the lower unit 12 in a schematic sectional view. FIG. 14A shows a state where the pushing member 44 of the second banknote stacking unit 40 is in the retracted position, and FIG. 14B shows a state where the pushing member 44 is in the pushing position. In FIG. 14, the pushing member 44 of the second banknote stacking unit 40 is described as an example, but the pushing member 34 of the first banknote stacking unit 30 operates in the same manner.

  As shown in FIG. 14A, two impellers 43 a and 43 b are provided in the second banknote stacking unit 40. The bills 15 fed out from the hopper 20 into the device, transported in the device, and discharged into the bill stacking unit are sent toward the right outer side of the device by the impellers 43a and 43b, and in the inclined standing state, FIG. They are accumulated as indicated by the broken lines.

  When the banknotes placed on the hopper 20 are identified by the identification unit 100 and all the banknotes are accumulated in any of the first banknote stacking unit 30, the second banknote stacking unit 40, and the reject unit 50, the control unit By the control, the pushing operation by the pushing member 44 is automatically started. As shown in FIG. 14B, the pushing member 44 moves from the impeller 43a on the back side to the pushing position on the back side. Thereby, the front short side of the stacked banknote 15 is in a state of protruding forward from the cutout 41 on the side surface of the second banknote stacking unit 40, and the front end of the banknote in the inclined standing state is grasped from the left and right. Can be easily extracted.

  In addition, after reaching the pushing position, the pushing member 44 returns to the retracted position shown in FIG. 14A and automatically stops. Further, as shown in FIG. 14A, in the second banknote stacking unit 40, a notch 41 is formed on the side surface, while the bottom surface continues to the front surface of the apparatus. For this reason, when the banknote is pushed out by the pushing member 44, a part of the short side on the front side of the banknote 15 is exposed from the notch 41, while the long side of the bottom side of the banknote 15 remains in contact with the bottom surface. Become. Further, the notch 41 has a shape that exposes only a part of the short side of the extruded bill 15, and the extruded bill 15 has a lower side of the short side exposed by an opening right side surface 45 shown in FIG. 1. In addition to being supported, the paper sheet surface is supported by the side wall forming the accumulation space behind it. Thereby, the banknote 15 pushed out by the extruding members 34 and 44 does not fall forward from the opening, and a stable accumulation state of the banknotes 15 can be maintained even after being pushed out.

[Sensor brush]
FIG. 15 is a perspective view of the pushing member 34 of the first banknote stacking unit 30 as seen from the back side. 15A shows an outer side wall member 130 that forms a side wall on the apparatus outer side (X-axis negative direction side) inside the banknote stacking unit of the first banknote stacking unit 30, and a side wall on the inner side of the apparatus (X-axis positive direction side). The pushing member 34 is in a retracted position between the inner side wall member 131 and the inner side wall member 131, and FIG. 5B shows the pushing member 34 in the pushing position.

  A slide guide 123 passes through two through holes 39a and 39b provided in the back rib of the push member 34, and the slide guide 123 guides the slide movement of the push member 34 in the front-rear direction. The two grooves 133a and 133b provided in the inner side wall member 131 indicate grooves in which the two impellers 33 are provided, and although not shown in FIG. A bill entering from the upper part of the inner side wall member 131 is sent to the outer side wall member 130.

  The first banknote stacking unit 30 is provided with four stacked banknote detection sensors 151 to 154 that detect the presence or absence of banknotes stacked by blocking light passing through the inside of the banknote stacking unit. The accumulated banknote detection sensor 151 includes a unit 151 a disposed on the back side of the side plate 34 c of the push member 34 and a unit 151 b disposed on the back side of the inner side wall member 131. The stacked banknote detection sensor 152 includes a unit 152 a disposed on the back side of the outer side wall member 130 and a unit 152 b disposed on the back side of the inner side wall member 131. The stacked banknote detection sensor 153 includes a unit 153 a disposed on the back side of the outer side wall member 130 and a unit 153 b disposed on the back side of the inner side wall member 131. The stacked banknote detection sensor 154 includes a unit 154a disposed on the back side of the top surface of the banknote stacking unit and a unit 154b disposed on the bottom side of the bottom surface of the banknote stacking unit.

  The outer side wall member 130, the inner side wall member 131, the upper surface and the bottom surface that form the stacking space of the first banknote stacking unit 30, and the side plate 34 c of the pushing member 34 are positioned at positions corresponding to the stacked banknote detection sensors 151 to 154. A through hole is provided. For example, as shown in FIG. 15A, a through-hole 137b is provided in the outer side wall member 130 corresponding to the unit 153a constituting the stacked banknote detection sensor 153, and the inner side wall member 131 is penetrated corresponding to the unit 153b. A hole 138b is provided.

  Further, the pusher member 34 is provided with sensor brushes 140a to 140e for cleaning the light projecting and receiving surfaces of some units of the stacked banknote detection sensors 151 to 154. Specifically, as shown in FIG. 15A, a sensor brush 140a is provided on the inner side wall member 131 side on the back side of the back plate 34a of the pushing member 34, and as shown in FIG. When the push-out member 34 moves to the push-out position to push out the banknote, the unit 151b of the stacked banknote detection sensor 151 is cleaned. Further, when the push-out member 34 returns from the push-out position to the retracted position, the sensor brush 140a again cleans the unit 151b of the stacked banknote detection sensor 151.

  FIG. 16 is a diagram illustrating sensor cleaning by the sensor brushes 140b to 140e provided on the push member 34. FIG. A sensor brush 140 b is provided on the back side of the bottom plate 34 b of the push member 34. While the push-out member 34 reciprocates between the retracted position shown in FIG. 16A and the push-out position shown in FIG. 16B, the sensor brush 140b cleans the unit 154b of the stacked banknote detection sensor 154.

  The sensor brushes 140c to 140e are provided on the back side of the side plate 34c of the push member 34. While the push-out member 34 reciprocates between the retracted position shown in FIG. 16A and the push-out position shown in FIG. 16B, the sensor brush 140c accumulates the unit 151a of the accumulated banknote detection sensor 151, and the sensor brush 140d accumulates. The sensor brush 140e cleans the unit 152a of the banknote detection sensor 152 and the unit 153a of the stacked banknote detection sensor 153. Also for these sensor brushes 140c to 140e, each of the stacked banknote detection sensors 151 to 153 while the push-out member 34 reciprocates between the retracted position shown in FIG. 16A and the push-out position shown in FIG. The units 151a to 153a are cleaned.

  The unit 152b of the integrated banknote detection sensor 152, the unit 153b of the integrated banknote detection sensor 153, and the unit 154a of the integrated banknote detection sensor 154 shown in FIG. Since the unit 153b is located near the opening of the first banknote stacking unit 30, it can be cleaned from the through-hole 138b of the inner side wall member 131 by putting a hand through the opening. Since the unit 154a is installed so that the light projecting / receiving surface faces downward, dust and dust are less likely to adhere and the frequency of cleaning is less than that of other units. The unit 152b is located between the two impellers 33, and it is difficult to perform a cleaning operation as compared with other units. For this reason, by forming the through hole 138a penetrating the inner side wall member 131 in the left-right direction (X-axis direction) corresponding to the unit 152b in a shape penetrating in the up-down direction (Z-axis direction), dust and dirt are accumulated. It is difficult.

  In the inner side wall member 131, the front end of the side wall portion forming the accumulation space is on the back side from the recess 60 on the front surface of the apparatus, and a substantially triangular plane parallel to the XZ plane is formed at the front end portion ( (See FIG. 10). The right side surface 32 of the opening shown in FIG. 1 is formed in a portion 131b on the front side of the apparatus from the front end plane.

  FIG. 17 is a schematic diagram showing an arrangement angle of the stacked banknote detection sensors 151 to 154 shown in FIGS. 15 and 16. As shown in FIG. 17, in the first banknote stacking unit 30, the banknotes 15 are stacked in an inclined standing state such that the long edge of the banknote 15 is in contact with the bottom surface and the banknote surface is along the outer side wall member 130. Is done.

  The stacked banknote detection sensor 154 is provided so that the units 154a and 154b are opposed to each other in the vertical direction at positions corresponding to the through holes on the top surface and the bottom surface forming the stacking space. The two stacked banknote detection sensors 151 and 153 arranged at the same height and shifted in the longitudinal direction of the apparatus are provided with units 151a and 151b and units 153a and 153b facing each other in the horizontal direction. Further, the units 152a and 152b constituting the stacked banknote detection sensor 152 disposed between the stacked banknote detection sensors 151 and 153 in the front-rear direction of the apparatus are opposed to the direction perpendicular to the wall surface of the outer side wall member 130. Is provided.

[Installation position of impeller]
FIG. 18 is a schematic diagram showing the arrangement relationship between the rollers and the impellers 33 and 43 constituting the conveyance path by developing the conveyance path of the banknote handling apparatus 1 in a plan view. As shown in FIG. 6, the conveyance path in the banknote handling apparatus 1 is an upper conveyance path in which the banknotes fed from the hopper 20 into the apparatus are conveyed in the left direction, and a banknote that has passed through the identification unit 100 is in the conveyance direction. The first banknote stacking unit 30 and the second banknote stacking unit 40 are based on the identification result by the identification unit 100, and the intermediate conveyance path that is conveyed in the downward direction while changing the conveyance direction and the banknote that is conveyed in the right direction by changing the conveyance direction. And a lower conveyance path that is conveyed to one of the reject units 50. In FIG. 18, the upper conveyance path, the intermediate conveyance path, and the lower conveyance path are shown from the left side, and the impeller 33 of the first banknote stacking unit 30 and the impeller 43 of the second banknote stacking unit 40 are shown on the right end.

  When the upper unit 11 is opened upward as shown in FIG. 8, the conveyance path portion included in the upper unit 11 side is 190 mm wide as shown in FIG. 18, but remains on the lower unit 12 side. The conveyance path portion has a width of 200 mm. When the upper unit 11 is opened upward, the upper transport path is included on the upper unit 11 side. The intermediate conveyance path for conveying the banknotes in the vertical direction is separated into a left side and a right side. When the upper unit 11 is opened, the right side part is included in the upper unit 11 and the left side part remains on the lower unit 12 side. Further, the lower transport path is also separated into an upper side and a lower side, and when the upper unit 11 is opened, the upper part is included in the upper unit 11 and the lower part remains on the lower unit 12 side.

  The range shown as the intermediate conveyance path in FIG. 18 shows the left side portion of the intermediate conveyance path remaining on the lower unit side when the upper unit 11 is opened. In the range indicated as the lower conveyance path, the lower part of the lower conveyance path remaining on the lower unit side when the upper unit 11 is opened is shown. However, the roller on the right side and the roller on the left side of the intermediate conveyance path are arranged opposite to each other, and the roller on the upper part and the roller on the lower part are arranged opposite to each other in the lower conveyance path. The arrangement positions of all the rollers to be formed are as shown in FIG.

  As shown in FIG. 18, the rollers of the upper conveyance path are arranged symmetrically with respect to the center line C1 in the width direction of the conveyance path having a width of 190 mm. In the intermediate conveyance path and the lower conveyance path, the rollers are arranged symmetrically with respect to the center line C1 in the width direction of the conveyance path having a width of 200 mm. Since the center line C1 is a straight line common to the upper transport path, the intermediate transport path, and the lower transport path, all rollers for transporting banknotes shown in FIG. Are arranged at positions overlapping on a straight line Ca or Cb symmetrical to the center line C1.

  The two impellers 33a and 33b of the first banknote stacking unit 30 are arranged such that the center line in the rotational axis direction of the rear-side impeller 33a is on the same straight line Ca as the roller that transports banknotes in the transport path. ing. On the other hand, the impeller 33b on the opening side has a center line in the rotation axis direction at a position farther from the center line C1 of the transport path than the straight line Cb on which the roller for transporting the banknote is disposed on the transport path, that is, the banknote. It arrange | positions so that it may become a position near the opening of a stacking part. Similarly, with respect to the two impellers 43a and 43b of the second banknote stacking unit 40, the rear impeller 43a is arranged so that the center line in the rotation axis direction is on the straight line Ca. The opening-side impeller 43b is arranged such that the center line in the rotation axis direction is closer to the opening than on the straight line Cb. Specifically, the opening-side impellers 33b and 43b inside the banknote stacking unit have a center line in the rotation axis direction on a straight line C2 that is a distance L2 (L1 <L2) away from the center line C1 of the conveyance path. Are arranged as follows.

  FIG. 19 is a schematic diagram for explaining an arrangement position of the opening-side impeller 33b with respect to the center line C1 of the conveyance path. FIG. 19 schematically shows the positional relationship when the transport path and the first banknote stacking unit 30 are viewed from above. The impeller 43b on the opening side of the second banknote stacking unit 40 is the same as the arrangement shown in FIG. 19 that is reversed left and right, and therefore the description of the impeller 43b of the second banknote stacking unit 40 is omitted. Now, the impeller 33b of the first banknote stacking unit 30 will be described.

  A distance L2 from the center line C1 of the conveyance path to the center line C2 in the rotation axis direction of the opening-side impeller 33a is set based on the smallest banknote having the shortest longitudinal length. Specifically, when the longest length of the minimum banknote is L4, as shown in FIG. 19, the distance from the opening side wall in the state where the short side of the minimum banknote is in contact with the opening side wall of the conveyance path. The distance L2 is set so that L3 is shorter than half of L4. In other words, the arrangement position of the impeller 33b on the opening side of the banknote stacking unit is such that, even when the minimum banknote is transported in a state of being closest to the opening side of the banknote stacking unit, It is set to be closer to the opening side than on the center line.

  The banknotes transported through the transport path and discharged into the banknote stacking unit are received by the impellers 33a and 33b. At this time, if the impeller 33b receives banknotes on the back side from the center line in the longitudinal direction of the banknotes, There is a possibility that the banknote is inclined to the opening side and jumps out from the banknote stacking section opening to the outside of the apparatus. For this reason, the impeller 33b is arrange | positioned so that most banknotes made into a process target may be received in the opening side rather than a longitudinal direction center so that the banknote received by the impellers 33a and 33b may not incline to the opening side. Yes.

  In order to reliably receive the banknotes by the impellers 33a and 33b, the two impellers 33a and 33b may be installed symmetrically with respect to the center line C1 of the conveyance path and separated from the center line C1, but the rear side If the impeller 33a is set apart from the center line C1, the amount of movement of the push member 34 toward the front side is limited. For this reason, in the banknote processing apparatus 1, the impeller 33b on the opening side is installed away from the center line C1, while the impeller 33a on the back side is installed at a position close to the center line C1. As described above, the banknote handling apparatus 1 prevents the banknotes from popping out from the first banknote stacking unit 30 by arranging the two impellers 33a and 33b asymmetrically with respect to the center line C1 of the transport path. In this structure, the extrusion amount by the extrusion member 34 is ensured.

  Further, as shown in FIG. 19, the left side surface 35 of the opening shown in FIG. 1 is formed in the front side portion 130 a from the front end of the outer side wall member 130 of the first banknote stacking unit 30, and from the front end of the inner side wall member 131. The right side surface 32 of the opening shown in FIG. 1 is formed in the front side portion 131a.

[Display contents of operation display section]
The banknote handling apparatus 1 has one feature in that the large-sized operation display unit 70 is used to display information relating to banknote processing so that it can be easily recognized. 20 to 22, each character is shown in white or black. However, in the actual operation display unit 70, each information is color-coded and displayed in color.

  FIG. 20 is a diagram illustrating an example of a screen displayed on the operation display unit 70 during bill processing. First, the basic configuration and display contents of the screen will be described with reference to FIG. Since the operation display unit 70 including a touch panel type liquid crystal display device is also used as an operation unit for inputting various information, as shown in FIG. Various buttons 204 and 205 are displayed.

  In the information display area excluding the upper and lower belt-like areas for displaying the operation buttons 204 and 205, the first display area 201 is provided in the lower left, and the second display area 202 is provided in the lower right. The first display area 201 is an area for displaying information about the banknotes accumulated in the first banknote stacking unit 30, and the second display area 202 displays information about the banknotes accumulated in the second banknote stacking unit 40. It is an area to do. Between the 1st display area 201 and the 2nd display area 202, the sum total of the banknote integrated | stacked on the 1st banknote stacking part 30 and the 2nd banknote stacking part 40 above the 1st display area 201 and the 2nd display area 202 A total display area 203 for displaying the information on is provided.

  For example, the number of banknotes stacked in the first banknote stacking unit 30 is displayed in the first display area 201, and the number of banknotes stacked in the second banknote stacking unit 40 is displayed in the second display area 202. The total display area 203 displays the total number of banknotes stacked on the first banknote stacking unit 30 and the banknotes stacked on the second banknote stacking unit 40 on the lower side, and the first banknote stacking unit 30 on the upper side. The total amount of the banknotes stacked on the banknote and the banknotes stacked on the second banknote stacking unit 40 is displayed.

  On the right side of the first display area 201, batch information including the number of batches of batch processing performed in the first banknote stacking unit 30 and the number of batch formations is displayed. Similarly, on the left side of the second display area 202, batch information indicating the number of batches and the number of batch formations of batch processing performed in the second banknote stacking unit 40 is displayed. Specifically, in “100 × 0” of the batch information shown in FIG. 20A, “100” indicates the number of batches and “0” indicates the number of batch formations, which will be described in detail later.

  In FIG. 20A, the internal and external boundaries of the first display area 201 and the second display area 202, and the internal and external boundaries of the area displaying the total amount above the total display area 203 are shown. Is shown by a black line, but on the actual screen, these boundaries appear due to the difference in color. Specifically, for example, in the first display area 201 and the second display area 202, blue characters are displayed on a white background. In addition, blue characters are displayed on a gray background on the upper side of the total display area 203, and white characters are displayed on a blue background on the lower side. Further, the outer sides of the first display area 201, the second display area 202, and the total display area 203 are displayed in light gray. As a result, a boundary due to a color difference appears between the inside and the outside of the first display area 201. Similarly, in the second display area 202 and the total display area 203, a boundary due to a color difference appears between the inside and the outside of the area.

  Moreover, as shown to FIG. 20 (A), the information regarding the banknote with which the character in the 1st display area 201 and the 2nd display area 202 was displayed largest on the screen, and was integrated | stacked on the 1st banknote stacking part 30, and The information regarding the banknotes accumulated in the second banknote accumulation unit 40 can be easily recognized.

  In the following, a bundle of thousand yen bills is placed on the hopper 20, and the first bill stacking unit 30 performs batch processing to extract 100 thousand yen bills from the apparatus each time they are stacked. In the two-banknote stacking unit 40, a case will be described as an example in which batch processing is performed in which a thousand-yen banknote is collected outside the apparatus each time it is stacked. First, the operation display unit 70 is operated to set the number of batches and the number of batch completion notifications. The batch completion notification count is a setting for notifying that the batch processing has reached a predetermined number.

  Settings such as the type of banknotes to be processed in batch processing, the number of batches, the number of batch completion notifications, etc. can be stored in the storage unit as a pattern. Just call the pattern. Note that the banknote type, the number of batches, and the number of batch completion notifications can be set to the same or different settings in the first banknote stacking unit 30 and the second banknote stacking unit 40. For example, the first banknote stacking unit 30 is set to notify every time batch processing of 50 ten thousand yen bills is established five times, and the second banknote stacking unit 40 performs batch processing of 100 thousand yen bills 10 times. It is also possible to make a setting such that notification is made every time it is established.

  By operating the operation display unit 70, the first banknote stacking unit 30 sets the type of banknotes to be stacked as a thousand yen bill, 100 batches, and 5 batch completion notifications. And in the 2nd banknote stacking part 40, the kind of banknote to stack | stack is set to a thousand yen bill loss ticket, the number of batches is set to 100 sheets, and the batch completion notification frequency | count is set to 5 times. When these setting operations are completed, the number and amount of money displayed in the first display area 201, the second display area 202, and the total display area 203 are displayed on the screen of the operation display unit 70 as shown in FIG. It is reset to 0 (zero) and enters a standby state. Further, on the right side of the first display area 201, the number of batches in the first banknote stacking unit 30 is set to “100”, and the current batch establishment count in the first banknote stacking unit 30 is “0”. “100 × 0” batch information is displayed. Similarly, on the left side of the second display area 202, the number of batches in the second banknote stacking unit 40 is set to “100”, and the current number of batch formations in the second banknote stacking unit 40 is “0”. “100 × 0” batch information is displayed.

  When a number of thousand yen bills are placed on the hopper 20 and batch processing is started, and the number of thousand yen bills stacked in the first bill stacking unit 30 reaches 100 batches, the bill processing apparatus The conveyance of banknotes in 1 is stopped. At this time, the screen of the operation display unit 70 is displayed as shown in FIG. In the total display area 203, the total amount and the total number of banknotes accumulated in the first banknote stacking unit 30 and the banknotes stacked in the second banknote stacking unit 40 are displayed.

  In the first display area 201 on the screen, the background in the area is displayed in blue, and the letter “100”, which is the number of banknotes stacked in the first banknote stacking unit 30, is displayed in white. That is, when the number of accumulated banknotes reaches the number of batches, the display mode of the number display changes. Further, when the batch processing is established, the batch information displayed on the right side of the first display area 201 is updated to display “100 × 1”. Note that the timing for updating batch information on the assumption that batch processing has been established may be the timing at which banknotes for the number of batches are stacked, or the timing at which removal of banknotes for the number of stacked batches is detected. It can be set to either.

  Inside the first banknote stacking unit 30 and the second banknote stacking unit 40 of the banknote handling apparatus 1, light emitting elements such as LEDs that emit light corresponding to the display in the first display area 201 and the second display area 202 are provided. It has been. When the batch processing is in a state of waiting for extraction of 100 banknotes stacked on the first banknote stacking unit 30, the operator is prompted to extract banknotes, and the banknote stacking unit that is the target of the sampling operation is the first banknote stacking. In order to notify that it is the part 30, the light emitting element in the 1st banknote stacking part 30 blinks.

  At this time, the background of the first display area 201 of the operation display unit 70 is displayed in blue, and the light emitting elements in the first banknote stacking unit 30 are blinked in the same blue. The operator recognizes that the number of banknotes accumulated in the first banknote stacking unit 30 has reached the number of batches by the display on the operation display unit 70 and the flashing of the light emitting elements in the first banknote stacking unit 30. Can do. When the operator pulls out 100 banknotes stacked on the first banknote stacking unit 30, in the banknote handling apparatus 1, the banknotes in the first banknote stacking unit 30 are pulled out by the stacked banknote detection sensors 151-154. Is recognized and bill processing is automatically resumed.

  Thus, every time the number of banknotes stacked in the first banknote stacking unit 30 or the second banknote stacking unit 40 reaches 100, the number of batch formations included in the corresponding batch information is displayed on the screen of the operation display unit 70. Counts up by one.

  For example, when the number of batch establishments in the first banknote stacking unit 30 reaches five times set as the number of batch completion notifications, the screen display shown in FIG. The batch information of the first banknote stacking unit 30 is updated to “100 × 5”, and an icon indicating that the batch completion notification count has been reached is displayed above the batch information display. Moreover, although the light emitting element in the 1st banknote stacking part 30 blinks, when the number of batch completion notifications is reached, it blinks in a mode different from that at the time of normal batch establishment. Specifically, for example, the number of blinks per second is changed when the normal batch is established and the number of batch completion notifications is reached, or the emission color of the flashing light emitting element is changed.

  Note that the number of banknotes accumulated in the first banknote stacking unit 30 is displayed in the first display area 201 on the screen, but in the total display area 203, the first banknote stacking part is started after the batch processing is started. 30 and the total amount and total number of banknotes accumulated in the second banknote stacking unit 40 are displayed. In the example of FIG. 20C, since there are no banknotes accumulated in the second banknote stacking unit 40, the total amount and the total number of batches for five batches established in the first banknote stacking unit 30 are displayed. .

  When the batch establishment count reaches the batch completion notification count, the batch establishment count of the batch information displayed on the right side of the first display area 201 is reset to “0” as shown in FIG. “0” is displayed. And the process which counts the number of batches and notifies this whenever 5 times is reached is repeated. In the total display area 203, information including banknotes processed before resetting is displayed even after the batch establishment count is reset.

  In addition, when the timing which updates batch information is set to the extraction timing of a banknote, after the accumulation | stacking number reaches 100 sheets, the batch formation frequency is counted up at the timing when a banknote is extracted. When the batch establishment count reaches the batch completion notification count, the batch establishment count is incremented at the timing when the banknotes are extracted, and the display becomes “100 × 5”. When the banknote is extracted, this is detected and the banknote processing is automatically started. However, after the display of “100 × 5” is maintained for a predetermined time (for example, 5 seconds) on the screen, the number of batch establishment is reset. Then, “100 × 0” is displayed.

  Thus, in the banknote processing apparatus 1, since it is notified that the preset number of batches has been reached, for example, when performing an operation such as packing five bundles of 100 banknotes, It is only necessary to continue the operation of extracting 100 bills accumulated in the bill accumulation unit. Since it is notified that 5 bundles have been reached without counting the number of batch formations, it is only necessary to carry out packing work upon receiving this notification. As a result, the operator can easily proceed with the work.

  Next, the screen display of the operation display unit 70 when a reject banknote is generated in the banknote handling apparatus 1 will be described. As shown in FIG. 20, the screen displayed when the banknote processing is started by the operation display unit 70 does not include an area for displaying information regarding the reject unit 50. If a reject banknote is generated while proceeding with the banknote processing, a partial area for displaying information on the reject banknote is set on the screen.

  FIG. 21 is a diagram illustrating an example of a screen displayed on the operation display unit 70 when a reject banknote is generated. For example, 23 thousand-yen bills are stacked on the first banknote stacking unit 30 and 10 thousand-yen bills are stacked on the second banknote stacking unit 40, for a total of 33 sheets. When the banknote identified after becoming a reject banknote, the screen display shown in FIG.

  On the screen, a first display area 201 that displays information about the first banknote stacking unit 30, a second display area 202 that displays information about the second banknote stacking unit 40, and a reject that displays information about the rejecting unit 50. The display area 206 is displayed in a positional relationship corresponding to the arrangement positions of the first banknote stacking unit 30, the second banknote stacking unit 40, and the reject unit 50 of the banknote handling apparatus 1 as viewed from the front. Specifically, as shown in FIG. 1 and the like, in the banknote handling apparatus 1, the first banknote stacking unit 30 is on the left side of the lower front part, the second banknote stacking unit 40 is on the right side of the lower front part, and the second banknote stacking unit 40 is on the right side. Since the reject unit 50 is provided on the upper side, the first display region 201 is displayed at the lower left of the region where information is displayed on the operation display unit 70, the second display region 202 is displayed at the lower right, and the reject display is displayed above the second display region 202. Region 206 is provided. In FIG. 21, the boundary between the inside and the outside of the reject display area 206 is indicated by a black line. However, in the same manner as the first display area 201 and the second display area 202, the surrounding color is displayed on the actual screen. The boundary appears by the difference.

  The reject display area 206 is displayed smaller than the first display area 201 and the second display area 202. Further, in the first display area 201 and the second display area 202, there is no display indicating that the information displayed in the area is the information of the banknotes accumulated in the banknote stacking units 30 and 40, but the reject display area 206 In the lower part of the area, “REJECT” is displayed to indicate that the information is related to the rejected banknote.

  Among rejected banknotes, banknotes rejected by different rejection factors are included. For example, when a single banknote fed out from the hopper 20 to the transport path is identified by the identification unit 100, the banknote determined to be unidentifiable, the counterfeit bill determined to be not a true banknote, and the possibility of a counterfeit bill The determined banknote, and the banknote determined to be unable to normally branch and stack to the banknote stacking unit because it is transported in a skewed state, are transported to the rejecting unit 50 as a reject banknote. Moreover, the identification part 100 or the conveyance banknote detection sensors 80-84 conveys in the state in which the space | interval of the conveyance direction of the banknote conveyed continuously in the state with which the several banknote overlap | superposed, and the banknote conveyed continuously is below a predetermined value. Also when the chain | linkage currently performed is detected, these banknotes are conveyed to the rejection part 50 as a rejection banknote. In addition, even when the size and thickness of the banknote are not within the predetermined range, the banknote is conveyed to the reject unit 50 as a reject banknote.

  In the banknote processing apparatus 1, the identification part 100 and the conveyance banknote detection sensors 80-84 detect the size and thickness of the banknotes conveyed on the conveyance path, thereby conveying a plurality of banknotes in a partially or entirely overlapped state. It is also possible to detect that a piece of paper out of a plurality of separated bills is being transported in addition to the multifeed. That is, it is possible to determine whether or not the banknote being conveyed is a single banknote. For this reason, while the number of reject banknotes can be determined, the total number of reject banknotes accumulated in the reject unit 50 is displayed in the reject display area 206.

  On the other hand, if it is not possible to determine that the banknote being conveyed is a single banknote, such as double feeding, chaining, thickness abnormality, or size abnormality, that is, if a reject banknote whose number cannot be determined occurs, the display content of the reject display area 206 is changed. To do. Specifically, the number of rejects is displayed instead of the number of rejects. For example, when a double feed is detected, the number of rejects is counted as one, but it is not possible to determine how many bills are conveyed in a state where the double feed is overlapped. The number of banknotes cannot be determined. For this reason, the banknote processing apparatus 1 displays the number of rejects instead of the number of rejects.

  Further, in the banknote handling apparatus 1, the number of rejects and the number of rejects are displayed in different display modes so that the information displayed in the reject display area 206 can recognize which of the number of rejects and the number of rejects is displayed. Is done.

  FIG. 21B shows an example of a screen on which the number of rejects is displayed. Thus, when displaying the number of rejects, an exclamation mark (exclamation mark) is displayed in the reject display area 206, and the number of rejects is displayed in parentheses. By changing the display mode in the reject display area 206, the number of rejects is displayed as shown in FIG. 21A, and the number of rejects is displayed as shown in FIG. It is possible to easily recognize whether the information displayed in the display area 206 is the number of rejects or the number of rejects.

  When both a reject that can determine the number of banknotes and a reject that cannot determine the number of banknotes occur, the total of the rejected number of rejects and the number of rejects that cannot determine the number of banknotes is displayed as the number of rejects.

  Specifically, for example, when 23 banknotes are stacked on the first banknote stacking unit 30 and 10 banknotes are stacked on the second banknote stacking unit 40, a reject that can determine the number of banknotes occurs. As shown in FIG. 21A, the reject display area 206 displays “1” as the number of rejects. Then, when a rejection occurs, and this rejection cannot confirm the number of sheets, such as double feeding, an exclamation mark is displayed in the rejection display area 206 as shown in FIG. In addition, the display of “2” obtained by adding the number of rejects detected “1” to the previous reject number “1” is displayed in parentheses.

  In this way, when the number of reject banknotes can be determined, by displaying the reject number, after the processing is completed, the total number displayed in the total display area 203 and the reject number displayed in the reject display area 206 are displayed. The total number of processed banknotes can be confirmed. In addition, when the number of rejects cannot be determined, the number of rejects is displayed, and the total number of processed banknotes cannot be accurately calculated, but information serving as a guide for the total number of banknotes can be obtained.

  Even when the reject unit 50 prompts the operator to remove the reject banknote, the display of the reject display area 206 changes on the screen of the operation display unit 70. Specifically, as shown in FIG. 21 (C), reject is performed in the same manner as when the number of stacked banknotes in the first banknote stacking unit 30 and the number of stacked banknotes in the second banknote stacking unit 40 reach the number of batches. The background in the display area 206 is displayed in blue and the characters are displayed in white.

  A light emitting element such as an LED that emits light corresponding to the display of the reject display area 206 is also provided in the integrated space of the reject unit 50. If it will be in the standby state which waits for a rejection banknote to be extracted from the rejection part 50, the light emitting element in the rejection part 50 will blink. At this time, the background of the reject display area 206 of the operation display unit 70 is displayed in blue, and the light emitting elements in the reject unit 50 are blinked in the same blue. The operator can recognize that it is necessary to remove the reject banknote from the reject unit 50 by the display on the operation display unit 70 and the flashing of the light emitting element in the reject unit 50.

  In addition, the notification process which prompts extraction of a banknote by changing the display mode of the information regarding the 1st banknote stacking part 30, the 2nd banknote stacking part 40, and the rejection part 50 by the operation display part 70, the 1st banknote stacking part 30, The notification process that prompts the banknotes to be removed by blinking the light emitting elements in the second banknote stacking unit 40 and the rejecting unit 50 means that the stacking number reaches a predetermined number such as the number of batches, the stacking upper limit number (full or near full number), etc. In addition to this, it is also performed when banknote processing is completed.

  In the banknote processing apparatus 1, a return process may be performed when an error occurs during the banknote processing. The return process is a process for returning the banknotes accumulated in the first banknote stacking unit 30 and the second banknote stacking unit 40 to the state at the time of error occurrence after recovery from the error.

  Specifically, when an error occurs and the apparatus stops, as shown in FIGS. 7 and 8, the conveyance path in the apparatus is exposed and all banknotes remaining on the conveyance path are removed. And when it will be in the state which can restart a banknote process with the banknote processing apparatus 1, the banknote taken out from the conveyance path in an apparatus, and the banknote currently integrated | stacked on the 1st banknote stacking part 30 and the 2nd banknote stacking part 40 at the time of error generation | occurrence | production Is placed on the hopper 20 and the return process is started. In the banknote handling apparatus 1, information relating to banknotes accumulated in each of the first banknote stacking unit 30 and the second banknote stacking unit 40 when an error occurs is stored. Using this information, the banknotes placed on the hopper 20 are classified into the first banknote stacking unit 30 and the second banknote stacking unit 40 and stacked, thereby reproducing the stacking state when an error occurs.

  FIG. 22 is a diagram illustrating an example of a screen displayed on the operation display unit 70 when the return process is executed. For example, when 21 bills are stacked on the second banknote stacking unit 40 when an error occurs, if the operation display unit 70 performs an operation to start the return process, the second display area 202 on the screen displays 22, the number “21” of banknotes accumulated in the second banknote stacking unit 40 is displayed. However, it is displayed in a display mode different from that during normal banknote processing.

  Specifically, for example, a boundary line between the inside and the outside of the second display area 202 is highlighted with a red line, and characters in the area are displayed in red. Thus, the operator can easily recognize that it is not normal banknote processing by displaying the boundary line in a color that is not displayed during normal banknote processing, or displaying characters in a different color. .

  When the return processing is started from the screen display state shown in FIG. 22 and the bills are sequentially stacked on the second bill stacking unit 40, the number display in the second display area 202 is counted down by one accordingly. When the number of banknotes stacked in the second banknote stacking unit 40 reaches 21 when an error occurs, the number display becomes “0”. When the return process is completed, the banknote process interrupted due to the error is resumed, and the display in the second display area 202 returns to the normal display. Then, after the banknote processing is resumed, the number display in the second display area 202 changes from “0” to “22” when the 22nd banknote is stacked on the second banknote stacking unit 40.

  Thus, in the banknote processing apparatus 1, since the information regarding the banknote process in execution is displayed on the operation display unit 70 so that it can be easily recognized, the operator can check the banknote processing while confirming the information on the operation display unit 70. Can be easily advanced. For example, not only the number of sheets accumulated in the banknote stacking units 30 and 40 but also the number of batches and the number of batch formations are displayed, and this is notified when the number of batch formations reaches a predetermined number of times. Batch processing can proceed. Moreover, since not only the information regarding the banknote identified and counted but the information regarding a reject banknote can be displayed, the information regarding the total number of processed banknotes can be recognized at the time of completion of a banknote process.

  Moreover, in the operation display part 70, the information regarding a some banknote stacking part is displayed in the corresponding position on a screen according to the positional relationship of each banknote stacking part seen from the operator who operates the operation display part 70. Therefore, the operator can easily recognize which banknote stacking unit is the information on the screen.

  In addition, each banknote stacking unit is provided with a light emitting element. For example, when the number of banknotes stacked in the banknote stacking unit reaches a predetermined number and the banknotes need to be extracted, an extraction operation is required. Since the light emitting element of the banknote stacking unit blinks, the operator can easily recognize that the banknote needs to be extracted and the position of the banknote stacking unit that needs to be extracted. Moreover, since the light emitting element of the banknote stacking unit that needs to extract the banknote is caused to emit light in the same color as the background color of the display area that displays the information of the banknote stacking unit that needs to be extracted on the screen of the operation display unit 70. The correspondence between the information on the screen and the banknote stacking unit can be easily recognized.

[Priority setting for banknote stacking unit]
In the banknote handling apparatus 1, the priority of the first banknote stacking unit 30 and the second banknote stacking unit 40 can be set. For example, when the banknote identified by the identification unit 100 is a banknote that may be stacked on either the first banknote stacking unit 30 or the second banknote stacking unit 40, the banknote is based on a preset priority setting. The transport destination is determined.

  FIG. 23 is a diagram illustrating the priority setting of the plurality of banknote stacking units 30 and 40 provided in the banknote handling apparatus 1. Thus, by setting and saving the priorities of the first banknote stacking unit 30 and the second banknote stacking unit 40 as patterns, it is possible to select a pattern and set the priority during banknote processing. Although not shown in FIG. 23, in addition to the priority, information such as denomination, harm, new / old, true / false can be registered in the pattern.

  For example, when the banknote processing apparatus 1 is installed at a bank window with the right side of the apparatus provided with the hopper 20 and the reject unit 50 facing a customer outside the window, the pattern 2 shown in FIG. 23 is selected. As a result, since the second banknote stacking unit 40 located near the customer is given priority as the banknote transport destination, the customer can easily check how banknotes are stacked. Moreover, for example, when the operator of the banknote handling apparatus 1 is left-handed, the pattern 1 shown in FIG. 23 is selected, and the banknote processing is performed by switching so that the first banknote stacking unit 30 is given priority. The operator can pull out the banknotes accumulated in the first banknote stacking unit 30 with the left hand which is a dominant hand.

  When the banknote handling apparatus 1 has a large number of banknote stacking units, a remarkable effect can be obtained by setting the priority of the banknote stacking unit. Below, the example which allocates the kind of banknote accumulate | stored in each banknote stacking part based on priority setting with the banknote processing apparatus which has 16 banknote stacking parts is demonstrated.

  FIG. 24 shows an example of a banknote handling apparatus having 16 banknote stacking units. There are 16 banknote stacking sections having openings for extracting banknotes on the front side of the apparatus, and a hopper, a reject section, an operation display section and the like are provided above the four banknote stacking sections from the left end.

  For example, a pattern for one-person operation in which one operator performs banknote processing is set in the priority setting. With this one-person work pattern, the priority is set higher as the position of the banknote stacking unit is on the left side. As a result, the banknote stacking unit on the left side of the apparatus provided with the hopper and the operation display unit has priority, so that the operator can place the banknote from the banknote stacking unit while placing the banknote on the hopper and operating the operation display unit. When drawing out, it is not necessary to move to the banknote stacking part at the right end, and the operation can be easily performed.

  In the priority setting, in addition to setting the priority based on the positional relationship of the banknote stacking unit, it is also possible to set the priority based on information relating to banknote processing processed in the past. For example, by setting the priority setting of the banknote stacking unit to “left” and the banknote denomination assigned to the banknote stacking unit to be prioritized as “multiple”, the number of banknotes stacked on the left side is increased. As described above, the denominations of the banknotes to be stacked in each banknote stacking unit are automatically assigned. The relationship between the denomination of banknotes and the number of banknotes stacked is determined based on information on the denominations of banknotes processed in the past and the number of processed banknotes.

  For example, the priority setting for the pattern for one-person operation is set so that a denomination with a larger number of processed sheets is stacked on the left banknote stacking unit. Thereby, the denomination with the largest number of processed sheets is assigned to the leftmost banknote stacking unit based on the data accumulated in the past banknote processing. Also, denominations with the largest number of processed sheets are allocated in order from the left banknote stacking unit, such that the denomination with the second largest number of processed sheets is allocated to the second banknote stacking unit from the left end. As a result, when banknote processing is performed, as shown in FIG. 25A, the number of banknotes stacked increases as the banknote stacking unit is on the left side. FIG. 25 is a schematic diagram showing the number of banknotes stacked on each of the 16 banknote stacking units. FIG. 25A shows that the number of banknotes stacked increases as the banknote stacker is on the left side.

  For example, when one operator performs an operation of packing the banknotes extracted from the banknote stacking unit into a transport container such as a transport cassette or bag, the operation is performed with the transport container placed near the left end of the apparatus. The operator performs the operation of extracting the banknotes from the banknote stacking unit and packing them into the transport container while placing the banknotes on the hopper and operating the operation display unit. At this time, as shown in FIG. 25 (A), as the banknote stacking unit is on the left side, the number of banknotes stacked increases, so that the number of times of movement to the rightmost banknote stacking unit to pull out banknotes can be minimized. . Further, since the number of accumulated banknotes decreases as the distance from the transport container increases, it is not necessary to extract a large amount of banknotes and carry a long distance to the transport container, thereby reducing the operator's workload.

  For example, when two people work, one person only performs the work of placing banknotes on the hopper, and another person only performs the work of drawing out the banknotes from the banknote stacking unit and filling them into the transport container The priority setting of the two-person work pattern is set so that a denomination with a larger number of processed sheets is stacked on the right banknote stacking unit.

  As a result, denominations with a larger number of processed sheets are assigned in order from the right banknote stacking unit, and a banking state as shown in FIG. On the left side of the device, one person continuously performs the work of placing banknotes on the hopper, and the other person places a transport container near the right end of the apparatus, pulls out banknotes from each banknote stacking unit, and packs them into the transport container. By doing so, it is possible to work efficiently.

  In addition, for example, two people work, one person performs both the work of placing the banknotes on the hopper and the work of extracting the banknotes from the banknote stacking unit, and another person pulls out the banknotes from the banknote stacking unit. In the case where only the operation of filling the transport container is performed, the priority setting of the two-person work pattern is set so that the banknote stacking number increases as the banknote stacking part is located on the left and right outer sides.

  As a result, denominations with a larger number of processed sheets are assigned in order from the left and right outer banknote stacking units, and the banknote is processed as shown in FIG. Work to place the transport container at approximately the center in the arrangement direction of the banknote stacking part, and one person pulls out the banknotes stacked on the banknote stacking part while continuously performing the work of placing the banknotes on the hopper, and packs them into the transport container I do. The other person is on the right side of the transport container placed in the approximate center and pulls out banknotes from each banknote stacking unit and packs them into the transport containers. Since two people do not cross and move at the time of work, one person works only on the left side from the center in the arrangement direction of the banknote stacking unit, and one person works only on the right side, so the work can be advanced efficiently. . Also, since the number of banknotes handled by two people is a close value, only the work burden on one person does not increase.

  In addition, when one person performs both the work of placing the banknotes on the hopper and the work of extracting the banknotes from the banknote stacking unit, and the other person only performs the operation of extracting the banknotes from the banknote stacking unit and filling them into the transport container The banknote stacking unit is divided into a group of eight banknote stacking units on the left side and a group of eight banknote stacking units on the right side, and the priority setting of the pattern for two-person work is on the left side in each group You may set so that the number of accumulated banknotes increases.

  As a result, denominations with a larger number of processed sheets are assigned in order from the left banknote stacking unit in each of the left and right groups, and the banknote processing is performed as shown in FIG. Place the transport container in the approximate center of the banknote stacking direction, and one person performs the work of placing the banknotes in the hopper while pulling out the banknotes stacked in the banknote stacking section Do. The other person is on the right side of the transport container placed substantially in the center, pulls out the banknotes from each banknote stacking part and packs them into the transport container, but in the right eight banknote stacking parts, the position where the transport container is placed Since the number of stacked banknotes increases in the banknote stacking unit close to, the operation of extracting banknotes and filling them into the transport container is easier than in FIG.

  As described above, in the banknote handling apparatus 1, banknotes are placed in each banknote stacking unit by performing priority setting based on the position of the banknote stacking unit and priority setting based on the number of processed banknotes for each type of banknote to be processed. Are appropriately assigned, and the operator can easily proceed with the work related to the banknote processing. When there are a large number of banknote stacking units, the type of banknotes to be stacked in each banknote stacking unit can be automatically assigned based on a preset priority setting, so the operator can stack each banknote stacking unit. It is not necessary to perform an operation of examining and setting the type of banknotes to be performed, and the work can be efficiently performed only by performing banknote processing with automatically set settings.

  In the present embodiment, for example, a light emitting element provided in the first banknote stacking unit 30 emits blue light, and information on banknotes stacked in the first stacking unit 30 is displayed on the screen of the operation display unit 70. Although the background of the first display area 201 to be displayed is displayed in the same blue color, the present embodiment is not limited to this. For example, the aspect which displays the character of the 1st display area 201 in blue, and displays a background in a different color may be sufficient. Moreover, the color of the character or background of the 1st display area 201 and the luminescent color of the light emitting element of the 1st banknote stacking part 30 are not the same, For example, you may be similar colors, such as blue and light blue. Moreover, not all the banknote stacking parts emit light in the same color, but a mode in which light emitting elements having different colors for each banknote stacking part emit light may be used. A mode in which light emitting elements of different colors emit light may be used. For example, when there are a large number of banknote stacking sections, banknote stacking sections that stack Japanese banknotes when stacking Japanese banknotes in some banknote stacking sections and stacking US banknotes in other banknote stacking sections If the light emitting elements and information display of the group are set to red, the banknote stacking unit for stacking US banknotes is set to one group and the light emitting elements and information display of the group are set to blue, light emission and information display From the color information, it is possible to easily recognize the relationship between the type of banknote and the banknote stacking unit.

  As described above, according to the present embodiment, when information on each banknote accumulated in a plurality of places, such as a banknote stacking unit and a rejecting unit, is displayed on one screen, each information is displayed on the periphery of the screen. Is displayed larger than other information at a position close to the corresponding stacked banknote. Specifically, for example, as shown in FIG. 21A, “1”, “10”, and “23” are displayed on the screen periphery in a large font on the screen of the operation display unit 70 shown in FIG. For example, the operator can easily recognize whether each numerical value is information related to the banknotes accumulated in the first banknote stacking unit 30, the second banknote stacking unit 400, or the reject unit 50.

  Moreover, the information regarding the banknote integrated | stacked on each of the 1st banknote stacking part 30 and the 2nd banknote stacking part 40 provided by arranging in a line in the left-right direction is the 1st banknote stacking on the screen of the operation display part 70. Displayed in accordance with the arrangement direction and arrangement order of the unit 30 and the second banknote stacking unit 40. In this way, three or more banknote handling apparatuses 1 are displayed by displaying information on the paper sheets accumulated in each stacking unit in accordance with the arrangement direction and arrangement order of a plurality of stacking units that classify and stack banknotes. Even when the banknote stacking unit is provided, the correspondence between the information displayed on the screen and each stacking unit can be easily recognized.

  Moreover, in the operation display part 70, the information regarding the banknote integrated | stacked on the 1st banknote stacking part 30, the 2nd banknote stacking part 40, and the rejection part 50 is set to the peripheral part on a screen according to the positional relationship of these stacking parts. Since it is displayed, the correspondence between the displayed information and each stacking unit can be easily recognized.

  As described above, the paper sheet processing apparatus according to the present invention is a useful technique for easily displaying information related to paper sheets accumulated in a plurality of stacking units.

DESCRIPTION OF SYMBOLS 1 Banknote processing apparatus 11 Upper unit 12 Lower unit 13 Upper cover 14 Back unit 20 Hopper 30, 40 Bill accumulation part 33, 43 Impeller 34, 44 Pushing member 50 Rejection part 61 Sub power switch 62 Memory card slot 63 USB port 64 LAN port 65 Dedicated Port 66 Main Power Switch 67 Power Inlet 70 Operation Display Unit 71 Dust Tray 72 Dust Receiving Plates 80 to 87 Conveyance Bill Detection Sensors 90 to 95 Conveyance Belt 100 Identification Units 111 and 112 Branch Members 140a to 140e Sensor Brushes 151 to 154 Stacked Bills Detection sensor

Claims (11)

A paper sheet processing apparatus for identifying and counting paper sheets,
A transport path for transporting paper sheets;
An identification unit for identifying paper sheets conveyed on the conveyance path;
A plurality of stacking units for classifying and stacking the paper sheets discharged from the transport path based on the identification result by the identification unit, and having openings for extracting the paper sheets accumulated inside;
A display unit for displaying information on the paper sheets accumulated in the accumulation unit,
A paper sheet processing apparatus that displays information related to paper sheets accumulated in each stacking unit in accordance with the positional relationship of each stacking unit on the screen of the display unit. The plurality of stacking units are arranged in a line,
The display unit is provided on the front surface of the apparatus avoiding openings of a plurality of integrated units arranged in a line,
2. The paper according to claim 1, wherein information relating to paper sheets accumulated in at least two stacking units is displayed on the screen of the display unit in accordance with an arrangement direction and an arrangement order of the stacking units. Leaf processing equipment.   Each stacking unit is positioned at a position corresponding to each stacking unit when a display area for displaying information on the sheets stacked on each stacking unit on the screen of the display unit is viewed on the front surface of the sheet processing apparatus. The paper sheet processing apparatus according to claim 1, wherein information relating to the paper sheets accumulated in the paper is displayed.   The paper sheet processing apparatus according to claim 1, wherein the plurality of stacking units include a reject unit that stacks rejected paper sheets. When processing of paper sheets is started, a display area for displaying information about rejected paper sheets is not provided on the screen of the display unit.
When rejected paper sheets are generated after starting the processing of the paper sheets, a display area for displaying information on the rejected paper sheets according to the position of the rejected part is displayed on the screen of the display part. The paper sheet processing apparatus according to claim 4, which appears.   Information on the paper sheets accumulated in each stacking unit is displayed along the periphery of a display area for displaying information on the paper sheets stacked in each stacking unit on the screen of the display unit. The paper sheet processing apparatus according to any one of claims 1 to 5. Each integrated part is provided with a light emitting element,
A character for displaying information on paper sheets accumulated in the accumulation unit in the display unit or a background color of the character and a color emitted from the light emitting element in the accumulation unit are similar colors. The paper sheet processing apparatus of any one of Claims 1-6. Each integrated part is provided with a light emitting element,
When it is necessary to remove paper sheets accumulated in the accumulation section,
The light emitting element is caused to emit light by the stacking unit, and the display unit displays a character for displaying information on the paper sheet or the background of the character in a color similar to the light emission of the light emitting element to notify the extraction. The paper sheet processing apparatus according to any one of claims 1 to 6. A paper sheet processing apparatus for identifying and counting paper sheets,
A transport path for transporting paper sheets;
An identification unit for identifying paper sheets conveyed on the conveyance path;
A first stacking unit that has an opening on the left side of the lower part of the front surface of the apparatus, and stacks paper sheets discharged from the transport path based on the identification result by the identifying unit;
A second stacking unit that has an opening on the right side of the lower part of the front surface of the apparatus, and stacks the sheets discharged from the transport path based on the identification result by the identifying unit;
Information on the sheets stacked on the first stacking unit is displayed on the left side of the lower part of the screen, and information on the sheets stacked on the second stacking unit is displayed on the right side of the lower part of the screen. A paper sheet processing apparatus comprising: a display unit configured to display on the paper sheet. An opening on the right side of the upper part of the apparatus, further comprising a reject unit that accumulates reject paper sheets discharged from the transport path based on the identification result by the identification unit;
The paper sheet processing apparatus according to claim 9, wherein information regarding the reject paper sheet is displayed on a right side of an upper portion of the display unit. The information on the paper sheets accumulated in the first accumulation unit and the information on the paper sheets accumulated in the second accumulation unit are displayed in the largest font on the screen. The paper sheet processing apparatus according to 10.

Images