RU2562791C1 - Processing device of paper sheets - Google Patents

Abstract

FIELD: printing.

SUBSTANCE: processing device of paper sheets comprises a feeding unit, a sheet-separating unit, a checking unit, a laying unit, a support drive unit, a tape wrapping unit, at least one power supply source, a mode setting unit, and a fixing unit. A plurality of paper sheets are placed on the feeding unit. The sheet-separating unit pulls the paper sheets from the feeding unit. The checking unit checks the selected sheets of paper. The laying unit puts each predetermined number of the checked sheets of paper on the support. The support drive unit adjusts the position of the support according to the number of the laid sheets of paper. The tape wrapping unit wraps with the tape the laid sheets of paper by wrapping the tape around the laid sheets of paper. At least one power supply source supplies power to the electrical functional parts of the sheet-separating unit, the checking unit, the laying unit, the support drive unit, and the tape wrapping unit. The mode setting unit sets the standby mode in which power supply to at least one of the electrical functional parts is temporarily discontinued. When the standby mode is set by the mode setting unit, the fixing unit fixes the support in the position to adjust the standby mode.

EFFECT: increased efficiency.

8 cl, 8 dwg

Description

FIELD OF THE INVENTION

The embodiments described herein generally relate to a paper sheet processing apparatus.

BACKGROUND

The paper sheet processing device comprises a sheet separating device that separates, at a time, a large number of sheets of paper, a test unit that checks the separated paper sheets, and a tape stacking / wrapping device that lays and winds the checked paper sheets in bundles including a predetermined amount the number of sheets of paper. The tape stacking / wrapping device comprises a support on which sheets of paper are stacked. The support is driven in accordance with the stacked number of sheets of paper.

In recent years, there has been a need to reduce power consumption by turning off excess power sources during operation or pausing operation to increase the energy-saving characteristics of the device.

However, if the power source of the electric motor for driving the support is turned off, the position of the support is shifted.

In this case, the sheets of paper stacked on the support should be removed at some point and then stacked again after restarting due to the resumption of normal mode from standby mode.

The purpose of the invention

An embodiment of the invention is directed to providing a paper sheet processing apparatus that can achieve energy saving without a complicated recovery operation.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view showing a banknote processing apparatus according to a first embodiment;

FIG. 2 is a sectional view showing a tape wrapping module of a paper sheet processing apparatus;

3 is a front view showing a temporary stacking unit of a paper sheet processing apparatus;

4 is a block diagram schematically showing a system configuration of a paper sheet processing apparatus;

5 is a flowchart showing an explanation of an example of the operation of the ribbon wrapping module;

6 is a block diagram schematically showing a system configuration of a paper sheet processing apparatus according to a second embodiment;

7 is a front view showing a temporary stacking unit of the paper sheet processing apparatus according to the third embodiment; and

FIG. 8 is a block diagram schematically showing a system configuration of a paper sheet processing apparatus.

DETAILED DESCRIPTION OF THE INVENTION

In general, according to one embodiment, the paper sheet processing device comprises a feed unit, a sheet separating unit, a test unit, a stacking unit, a support drive unit, a tape wrapping unit, at least one power source, a mode setting unit and a fixing unit. Many sheets of paper are placed on the feed unit. A sheet separating unit separates sheets of paper from the feeding unit. The inspection unit checks the separated sheets of paper as described above. The stacking unit stacks each specified number of checked sheets of paper on a support. The support drive assembly adjusts the position of the support according to the number of sheets of paper stacked. The tape wrapping assembly winds the stack of stacked sheets of paper by wrapping the tape around the stack of stacked sheets of paper. At least one power source supplies power to the electrical functional parts of the sheet separating assembly, test assembly, stacking assembly, support drive assembly, and tape wrapping assembly. The mode setting node sets the standby mode in which the power supply to at least one of the electrical functional parts is temporarily suspended. The fixing unit fixes the support in the position for setting the standby mode when the standby mode is set by the mode setting unit.

First Embodiment

Embodiments are described in detail below with reference to the drawings.

FIG. 1 is a sectional view schematically showing a complete configuration of a paper sheet processing apparatus 1 according to a first embodiment.

As shown in FIG. 1, a paper sheet processing apparatus 1 that processes banknotes as paper sheets comprises a main module 10, a combining module 30, a ribbon wrapping module 60 as a stacking / wrapping device, and an expansion module 174. These modules are placed in line and are electrically and mechanically connected to each other.

The main controller 12, which controls the operation of the main module 10 and the entire device, is provided in the main module 10. The main controller 12 is connected to the functional node 17 to enter various information into the present device, and the monitor 15 as a display device that displays the operating modes and processing status of this device.

The main controller 12 is connected to an un illustrated host computer and transmits / receives information to the host computer and organizes the information.

According to the operator’s work, various functional settings are made by means of a functional unit 17 connected to the main controller 12, including setting up a method of conducting transactions, such as a money receiving service or a money processing organization service, loading processing for loading into the loading compartment, verification processing for banknotes in the loading compartment, setting up the storage compartment to store processed banknotes P, setting up the stacking / wrapping process and setting the shelf life / damaged spine to adjust a certain quality level for each note.

In accordance with the processing of information from the verification device 18 described below, the main controller 12 calculates the processing efficiency per unit time, processing efficiency for each of the many days, processing efficiency for each operator identifier, the total number of sheets in processing and control information including total operating time. The main controller 12 then saves the calculation results to the memory of the main controller 12 and displays them on the monitor 15.

As shown in FIG. 1, the main module 10 comprises a feeding unit 11 on which a large number of sheets of paper are stacked, a sheet separating mechanism 14 that separates, one by one, the sheets P of paper from the feeding unit 11, and a conveyance path 16 through which the banknotes are transported P, separated by a leaf separator. The transport path 16 comprises a plurality of sets of endless conveyor belts (not shown) that extend such that each set of conveyor belts places a transport path 16 in the middle. Separated banknotes P are transported placed between conveyor belts.

The supply unit 11 comprises a support surface 11a that extends obliquely at an arbitrary angle with respect to the perpendicular direction, a holding surface 11b that extends in a direction substantially perpendicular to the abutment surface 11a, and a pair of guide walls 11c that are provided so that they are arranged vertically along two side edges of the supporting surface 11a and the holding surface 11b. An exhaust port 11e for drawing banknotes P inside the present device is formed on the boundary part between the supporting surface 11a and the holding surface 11b.

Many banknotes P, for example 2000 or more banknotes P, can be stacked and placed in the feed unit 11. The stacked banknotes P are placed in the feed unit 11 tilted along the supporting surface so that the lowest of the banknotes is on the holding surface 11b and that, for example, the lateral edge of the longer sides of the banknote is on the supporting surface 11a. The stacked banknotes P are sequentially drawn into the present device in order from the lowest banknote P through the exhaust port 11e by means of a leaf-releasing mechanism 14.

The feeding unit 11 comprises a temporary stacking plate 21, which moves each of the banknotes P in the direction of the side of the exhaust port or, in particular, in the direction of the holding surface 11b. A temporary laying plate 21 is provided so that it is contained on the abutment surface 11a and can move along the abutment surface.

The sheet-separating mechanism 14, which separates one banknote P from the feeding unit 11, comprises a plurality of gripping rollers 24 (exhaust rollers) provided with the possibility of preventing contact with the banknote P on the holding surface 11b, separating the roller 25 provided in rolling contact with a gripping roller 24 on the side of the exhaust port 11e, and a drive motor 26 that rotates the gripping rollers 24 at a predetermined speed.

As the gripping roller 24 rotates, the lowest banknote P is separated (or pulled) by the gripping rollers 24 and fed through the exhaust port 11e to the transport path 16 from the exhaust port 11e. At this time, the second and subsequent banknotes P are isolated from the separated banknote. Thus, the banknotes P are separated from the feed unit 11 and fed into the transport path 16.

As shown in FIG. 1, a conveyance pitch correction unit 13 that corrects a conveyance pitch of banknotes P by the conveyance path 16, a verification device 18 that checks one banknote P, the conveyance pitch of which is adjusted, and the barcode reader 19 are placed along the path 16 transportation. A verification device 18 is provided on the upper side of the exhaust port 11e of the supply unit 11 along the perpendicular direction. The verification device 18 determines the strength, shape, thickness, front / back side, authenticity / falsification, suitability / damage and double grip for each of the transported banknotes P. Here, it is assumed that the determination of validity / damage means determination between a recently issued banknote with the possibility of repeated circulation and a worn-out banknote that is dirty and damaged and therefore cannot be re-entered. For example, the barcode reader 19 reads multi-purpose cards that have passed the verification device 18 when using multi-purpose cards, or reads the barcodes added to casino cards. The barcode reader sends the read information to the main controller 12.

The transport path 16 extends downward relative to the sheet separating mechanism 14 and the bleeding port. Then, the transport path 16 obliquely deviates relative to the perpendicular direction and extends from the bottom up. In addition, the transport path 16 is in communication with the alignment module 30 described below. An ejection port is formed at the bottom of the transport path 16, and a collection container 27 is further provided below the ejection port. Impurities that enter the transport path 16 are discharged from the discharge port and collected in a container 27 for collection.

As shown in FIG. 1, in the main module 10, two rejected banknote receiving units 20a and 20b are provided along the conveyance path 16, and a plurality of storage compartments 22a, 22b, 22c and 22d, each of which stacks the banknotes, are arranged in a line. Banknotes P that pass through the verification device 18 are sorted into rejected banknotes and processed banknotes by means of shutters (not shown). Rejected banknotes are determined as counterfeit banknotes by means of the verification device 18 or are determined as bent, torn, wrinkled or unrecognized due to double gripping. The rejected banknotes are collected and stacked, sorted into the rejected banknote receiving unit 20a or 20b. With the exception of counterfeit banknotes, the rejected banknotes are again placed in the feed unit 11 and again involved or included in the calculated data by manual entry. Verification results, such as the total amount and the total number of banknotes processed by the verification device 18, are fed and stored in the main control subsystem 12 and displayed on the monitor 15.

The processed banknotes are banknotes P determined by the verification device 18 as genuine and valid banknotes or genuine and worn banknotes. The processed banknotes are fed and stacked in the storage compartment 22a or 22d. For example, processed banknotes are stacked and sorted into respective storage compartments 22a and 22d depending on the types of banknotes. Worn banknotes are stacked together in the storage compartment.

When multi-purpose cards are used, multi-purpose cards pass through the verification device 18 and the barcode reader 19 and are then fed and stacked on the rejected banknote receiving unit 20a and 20b.

The main module 10 comprises, as electrical functional parts that are controlled by electric power, a monitor 15, a drive motor 26, a verification device 18, rejected banknote receiving units 20a and 20b, and electric motors that activate the shutters of the individual units and the transport mechanism.

The main module 10 comprises a drive mechanism, a power source, and various sensors that are not shown, but that drive the leaf separating mechanism 14, the verification device 18, and the transport mechanism.

As shown in FIG. 1, the combining unit 30 comprises a conveying path 31 that conveys banknotes P supplied from the main module 10, a combining mechanism 32 provided on the upper side along the conveying path 31, a feed back device 34 provided on the lower side of the mechanism 32 alignments along the transport path 31, and a plurality of storage compartments 36a, 36b, 36c and 36d arranged in a line along the transport path 31.

The banknotes P supplied from the combining mechanism 32 or the reverse feeding device 34 are fed into the tape wrapping module 60 through the conveyance path 31 or fed and stacked on any of the storage compartments 36a, 36b, 36c and 36d. The storage compartments 36a, 36b, 36c and 36d can also be used as storage compartments that collect and stack banknotes sorted, respectively, depending on the types of banknotes, or as compartments for receiving rejected banknotes or compartments for receiving worn banknotes that collect and stack rejected or worn banknotes selected from the main module 10.

Otherwise, if the processing of wrapping the tape for wrapping the banknote of the banknote is specified, the genuine and damaged banknotes selected from the main module 10, or the genuine and damaged banknotes selected from the combining unit 30, are fed to the wrapping module 60 through the transport path 31 of the combining unit 30 and wrapped with a ribbon for each predetermined number of banknotes.

Figure 2 is a front view of the tape wrapping module 60 as a tape-laying / wrapping device. As shown in FIGS. 1 and 2, the tape wrapping module 60 includes a conveyance path 62 that communicates with the conveyance path 31 of the alignment module 30, a first stacking device 64a and a second stacking device 64b, each of which collects and stacks banknotes fed through a transport path 62 for each predetermined number of banknotes, a tape wrapping device 68 that wraps a ribbon with each predetermined number of banknotes stacked, for example, every hundred banknotes stacked by stacking devices in a bundle, wrapped wrapped tape, and a transport mechanism 70 that conveys banknotes P stacked by the first stacking device 64a and bundles banknotes wrapped in tape by the second stacking device 64b. Further, an ejector unit 73 that receives and stacks bundles of banknotes wrapped in tape by the tape wrapping device is provided below the tape wrapping device 68.

The first stacking device 64a and the second stacking device 64b are offset from each other in the up and down directions and in the left and right directions. The second stacking device 64b is positioned at an angle θ downward of about 10-80 degrees with respect to the first stacking device 64a so that part of the device 64b overlaps the first stacking device 64a in the perpendicular direction. The tape wrapping device 68 is located below the second stacking device 64b.

Each of the first and second stacking devices 64a and 64b comprises a temporary stacking unit 65 and a stacking device 66 with a paddle wheel as a stacking mechanism that stacks one predetermined number of banknotes P per temporary stacking unit 65. The paddle wheel 66a of the stacking device 66 with a paddle the wheel is configured by arranging a plurality of vanes on the periphery of the rotational shaft and rotates synchronously with the conveyance of banknotes P, so that each of the fed banknotes P is received between the vanes and. By using the impeller 66a, banknotes P are stacked on a temporary stacking unit 65, absorbing the kinetic energy of banknotes P transported at high speed and when combining banknotes P.

The temporary stacking unit 65 of the first stacking device 64a comprises, for example, a support 75a, which can be moved in the up and down directions, and stacks the banknotes P on the support. The temporary stacking unit 65 of the second stacking device 64a comprises, for example, a support 75b, which can be moved in the up and down directions, and stacks the banknotes P on the support.

In addition, the first stacking device 64a and the second stacking device 64b include an indicator 71, such as an LED, that indicates the processing status of the device, such as a stacking device error or a banknote re-accessibility status. Indicators 71 are provided at positions where visual inspection is readily accessible from the outside by opening the outer cover of the ribbon wrapping module 60. Indicators 71 indicate various processing conditions for stacking devices by flashing, turning on, off, and highlighting in different colors to enable the operator to determine whether, for example, banknotes should be fed again, errors occur or not, the result of banknote calculation is fixed or not.

Figure 3 is a front view of the stacking unit 65, which contains each of the first laying device 64a and the second laying device 64b. The temporary stacking unit 65 of the first stacking device 64a and the temporary stacking unit 65 of the second stacking device 64b have the same configuration. Next, the first stacking device 64a is described in detail as a typical example.

As shown in FIG. 3, the temporary stacking unit 65 comprises a substantially horizontal support 75a on which banknotes tied in the bundle are stacked, a connecting rod 76 (support member) connected to the support 75a and extending in the perpendicular direction, a support frame 79 that supports and guides the connecting rod 76 to allow it to freely rise and lower, and the support drive assembly 81, which moves the support 75a up and down by the connecting rod 76.

The support drive assembly 81 includes a rack 85 attached to the connecting rod 76 and extending in the perpendicular direction, a support electric motor 78 (servo motor) and a gear transmission 77 that transfers a driving force to the connecting rod 76 from the support electric motor 78 provided between the rack 85 and the pinion gear 78a connected to a drive shaft of a support electric motor. The electric motor 78 of the support and the gear 77 are supported by the bracket 87.

Gear 77 comprises a first gear 77a, a second gear 77b and a third gear 77c. The first gear 77a and the second gear 77b are configured in a design in which a large diameter gear and a small diameter gear are combined so that they respectively have rotation axes corresponding to each other. The third gear 77c is configured by a gear having a diameter substantially equal to the diameter of the large diameter gears for gears of the first gear 77a and the second gear 77b.

The large-diameter gear of the first gear 77a is engaged with the drive gear 78a connected to the drive shaft of the support motor 78. The large diameter gear of the second gear 77b engages with the small diameter gear of the first gear 77a. The third gear 77c is engaged with the small diameter gear of the second gear 77b and the rack 85. When the support electric motor 78 is driven, the pinion gear 78a, the first gear 77a, the second gear 77b and the third gear 77c rotate, respectively, in order. When the third gear 77c rotates, the third gear 77c moves the rack 85, the connecting rod 76 and the support 75a up or down in accordance with the direction of rotation of the third gear 77c.

The temporary stacking unit 65 adjusts the height position of the support 75a according to the number of banknotes stacked, so that the stacking device 64 properly stacks the banknotes on the support 75a. In other words, the temporary stacking unit 65 adjusts the height position of the support 75a by moving up and down the support 75a through the support drive assembly 81. For example, the stacking unit 65 adjusts the support 75 so that it moves upward when zero or a small number of banknotes are stacked in a bundle. Otherwise, when a large number of banknotes are stacked in a bundle, the temporary stacking unit 65 adjusts the support 75 so that it moves down. As a result, the temporary stacking unit 65 may maintain a constant distance from the upper surface of the stack of banknotes stacked on the stacking device 64.

The first laying device 64a and the second laying device 64b, respectively, comprise locking mechanisms that lock the support 75a and the support 75b in positions for setting the standby mode during the standby mode described below.

As shown in FIG. 2, the conveyance mechanism 70, which conveys the stacks of stacked banknotes between the first stacking device 64a and the second stacking device 64b and the tape wrapping device 68, comprises a pair of guide rods 74 provided so that they are arranged vertically along the perpendicular direction, a base carrier 80 allowing free rise and fall along the guide rods 74, and sheet transfer means 82 (conveyor tray) provided on the base carrier ente 80 so that it can perform a reciprocating movement along the horizontal direction. The base carrier 80 and the sheet transfer means 82 configure the carrier for the conveyor.

The base carrier 80 is in the form of a substantially rectangular tray and is supported, in the end portion, by a pair of guide rods 74. The base carrier 80 is guided so that it can freely rise and fall along these guide rods. The base carrier 80 extends substantially horizontally. In addition, the base carrier 80 is connected to the drive belts via a pair of brackets. By direct or reverse driving an electric motor (not shown), the drive belts are moved either up or down, and the base carrier 80 is raised and lowered by these drive belts. The base carrier 80 rises up and down between the first position in which the base carrier 80 is adjacent and is located opposite the support 75a of the first laying device 64a below the support 75a, the second position in which the base bearing 80 is located opposite the side of the supporting 75b of the second laying device 64b, and a third position in which the base carrier 80 is located opposite the side of the support 84 for dispensing the tape wrapping apparatus 68 described below. For example, a position sensor, such as a photo interrupter, is provided at each of the positions described above. By determining the base carrier 80 using position sensors, the base carrier 80 can be moved and positioned at any of these positions.

On the other hand, the sheet transfer means 82 has the shape of a rectangular plate that is larger than the banknote P and configured to allow the placement of stacked banknotes on it. The sheet transfer means 82 is provided so that it can reciprocate along horizontal directions on the base carrier 80. In other words, the base carrier 80 is provided on the sheet transfer means 82 so that it can reciprocate along the direction crossing the direction of movement of the base carrier 80, between the standby position, in which the sheet transfer means 82 is positioned overlapping the base carrier 80, and extended position in which sheet transfer means 82 protrudes substantially horizontally from the front end of the base support member. On the base carrier 80, a driving source is provided, for example, an electric motor or plunger, which moves the sheet transfer means 82 in horizontal directions.

The sheet transfer means 82 comprises a plurality of banknote clamps 88 that hold bundled banknotes on the sheet transfer means 82. These banknote clamps 88 are attached to a rotational shaft 89 supported by the sheet transfer means 82. As the drive motor provided on the sheet transferring means 82 rotates the rotational shaft 89, the banknote clamps 88 rotate between the open position at a distance from the supporting surface of the sheet transferring means 82 and the clamped position while pressing the bundled banknotes from above to compress and hold bundled banknotes.

The stacking of banknotes by means of the first and second stacking devices 64a and 64b and the transportation of bundled banknotes by the transport mechanism 70 are as follows. For example, a predetermined number, such as one hundred banknotes of a unique type, is stacked on a support 75a by means of a first stacking device 64a. At this time of laying, the base carrier 80 is forcibly awaited in the first position, and the sheet transfer means 82 on the base carrier 80 is adjacent and opposite the support 75a below the support 75a. During laying, the support 75a gradually moves down from a position near the impeller 66a in order to adjust the position of the support according to the number of banknotes stacked. When one hundred banknotes P are stacked on the support 75a, the stacked banknotes P are then transferred to the sheet transfer means 82 from the support 75a. Then, the stacked banknotes P are pressed by the banknote clamps 88 to hold the stacked banknotes P on the sheet transfer means 82, and the base carrier 80 then lowers to the third position.

Then, the sheet transfer means 82 moves forward from the ready position to the extended position and moves the stacked banknotes P to the support 84 to eject the tape wrapping device. Then, the end portion of the stacked banknotes P in the longitudinal direction is gripped by the handle of the gripping / retrieval mechanism of the tape wrapping device 68, which is described below, and at the same time, the clamps 88 forcefully stop holding. After that, the sheet transfer means 82 is moved from the extended position to the ready position. Due to this, a stack of stacked banknotes P is delivered to the tape wrapping device 68.

On the other hand, after one hundred banknotes are stacked by the first stacking device 64a, the 101st and subsequent banknotes are fed into the second stacking device 64b. A predetermined number of banknotes to be fed, for example one hundred banknotes, is stacked on the support 75b by the second stacking device 64b. During laying, the base carrier 80 is forcibly awaited in the second position and is located opposite the side of the support 75b. Also during laying, the support 75a gradually moves down from a position near the impeller 66a to adjust the position of the support in accordance with the number of banknotes stacked. When one hundred banknotes P are stacked on the support 75b, the sheet transfer means 82 moves forward from the ready position to the extended position, enters and inserts into the support 75b, and is placed below the stacked banknotes P.

In this state, the stacked banknotes P are pressed by the banknote clamps 88 to hold the stacked banknotes P on the sheet transfer means 82. After this, the sheet transfer means 82 returns to the ready position, and the sheet transfer means 82 and the stacked banknotes P are moved to the base carrier 80. Then, the sheet transfer means 82 and the base carrier 80 are moved down to the third position.

Then, in the third position, the sheet transfer means 82 moves forward from the ready position to the extended position and moves the stacked banknotes P to the support 84 to eject the tape wrapping device. Then, the end portion of the stacked banknotes P is gripped by the handle of the gripping / retrieval mechanism of the tape wrapping apparatus 68, which is described below, and at the same time, the clamps 88 forcibly stop holding. After that, the sheet transfer means 82 is moved from the extended position to the ready position. Thus, the stacked banknotes P are transferred to the tape wrapping device 68.

The following describes a tape wrapping apparatus 68.

As shown in FIG. 2, the tape wrapping device 68 comprises a substantially rectangular dispensing support 84, which is defined obliquely at an angle downward from the level surface, and a tape feeding device that feeds the wrapping tapes. The stacked banknotes P are fed into place above the post 84 for dispensing. The tape feed device comprises a belt reel 83 around which a wrapping tape is wound for wrapping a tape of stacked banknotes P, and a tape feeding mechanism that retrieves and feeds a loop-shaped wrapping tape from the tape reel. In addition, the tape wrapping device 68 includes an un illustrated ribbon winder that winds a wrapping tape around bundled notes, a heater that heats and seals the wrapped wrapping tape, and an un illustrated cutting mechanism that cuts the wrapping tape.

The tape wrapping module 60 comprises, as electrical functional parts, paddle wheel-laying devices 66, a support electric motor 78, a heater 69, indicators 71, and an electric motor that drives the individual parts of the tape wrapping module, for example, dampers.

As shown in FIG. 1, the expansion module 174 provided on the underside of the ribbon wrapping module 60 includes a conveyance path 141 through which notes P supplied from the ribbon wrapping module 60 are transported and storage compartments 175, each of which has a large capacity , allowing the stacking of a specific number of banknotes supplied through the path 141 transportation.

The expansion module 174 comprises, as an electrical functional part, an electric motor that drives a shutter and a transport path 141 for operation.

A protective pocket 176 is provided on the lowest side of all modules. When there is a banknote that cannot be processed during transportation, this banknote is issued in a protective pocket 176 and removed from the device.

The following describes the system configuration of the paper sheet processing apparatus 1.

4 is a block diagram schematically showing a system configuration of a paper sheet processing apparatus 1.

The main controller 12 is provided in the control panel in the main module 10. The main controller 12 contains a modular CPU 13a, which controls the operation of each component of the main module and calculates the efficiency of the operating modes, and a memory device that stores various data, a control program and control information. As the above various data, the storage device stores the identifiers of operators, date / time, serial numbers, destination information, bank logos, images of administrators' signatures, print information printed on bundle binding tapes, for example, fonts of the languages of the respective countries and processing speed in many stages for sheets of paper.

As shown in FIG. 4, the main controller 12 is connected to a functional unit 17, which inputs various information into the device, and a monitor 15 as a display device that displays the operating and processing states of the device. Functional node 17 is configured using a mouse and keyboard. Alternatively, the monitor 15 and the functional unit 17 can be permanently configured as a touch panel.

Functional node 17 includes a switch for indicating the operational status of the paper sheet processing apparatus 1. The function unit 17 includes an ON switch for switching the paper sheet processing device 1 to an on state, a standby switch for switching the paper sheet processing device 1 to the standby mode, a cancel switch for leaving the paper sheet processing device 1 from the standby mode, and an OFF switch for switching device 1 processing sheets of paper in the off state. When any of the switches is pressed, the functional unit 17 then transmits a signal indicating the corresponding pressed switch to the modular CPU 13a.

The main controller 12 contains a modular CPU 13a, a timer 13b, a system controller, an APL PC board that controls the monitor 15 and the function unit 17, RECO, electrically connected to the system controller, an electric motor controller, a color sensor controller, electrically connected to the electric motor controller, PCB and damper controller. A timer 13b, an electric motor controller, a PCB and a damper controller are electrically connected to the modular CPU 13a.

The modular CPU 13a is installed on the control panel. The modular CPU 13a is powered from the control panel. Additionally, the modular CPU 13a can control each node through a control panel. The modular CPU 13a is also electrically connected to the modular CPU 61a and the modular CPU 177a. The modular CPU 13a, the modular CPU 61a, and the modular CPU 177a can mutually transmit and receive data.

The timer 13b measures the elapsed time from the moment the banknote P was stacked for the last time. A timer 13b transmits information indicating the measured elapsed time to the modular CPU 13a. The timer 13b may transmit information indicating the elapsed time to the modular CPU 13a at constant time intervals and may transmit information indicating the elapsed time to the modular CPU 13a in response to a request from the modular CPU 13a.

The system controller is also electrically connected to the modular CPU 61a and the modular CPU 177a. The system controller transmits to the modular CPU 13a, the modular CPU 61a and the modular CPU 177a the instructions entered in the function node 17, or displays the data on the monitor 15 in accordance with the instructions from the CPU.

An electric motor controller controls each of the electric motors in the main module 10. A damper controller controls each of the dampers of the main module 10.

The main unit power supply unit 12a supplies power to the control panel of the modular CPU 13a. The main module power supply unit 12a also supplies power to the component parts of the main module 10 under the control of the modular CPU 13a. The components of the main module 10 are powered by the power supplied from the power unit 12a of the main module.

An expansion module controller 170 is provided on a control panel in expansion module 174. An expansion module controller 170 controls the operation of each component of the expansion module 174.

The expansion module controller 170 comprises a modular CPU 177a, a centering assembly, a PCB, a damper controller, and an electric motor controller. The centering assembly, the motor controller, the PCB and the damper controller are electrically connected to the modular CPU 177a.

The modular CPU 177a is installed on the control panel. Modular CPU 177a is powered from the control panel. Additionally, the modular CPU 177a can control the components through the control panel.

An electric motor controller controls each of the electric motors in expansion module 174. The flap controller controls each of the flaps of the expansion module 174.

The expansion unit power supply unit 170a supplies power to the control panel of the modular CPU 177a. The expansion module power supply 170a powers the respective nodes of the expansion module 174 under the control of the modular CPU 177a. The components of the line 174 are powered by the power supplied from the power supply unit 170a of the expansion module.

A ribbon wrapping module controller 59 is provided on a control panel in the expansion module 60. A ribbon wrapping module controller 59 controls the components of the expansion module 60. Additionally, the ribbon wrapping module controller 59 controls the power supply to the first power supply system 63 and the second power supply system 67.

The controller 59 of the tape wrapping module comprises a modular CPU 61a, a tape wrapping controller, an electric motor controller 61b and an electric motor controller 61c. The ribbon wrapping controller, the motor controller 61b and the motor controller 61c are electrically connected to the modular CPU 61a.

The modular CPU 61a is installed on the control panel. Modular CPU 61a is powered by the control panel. The modular CPU 61a can control the components through the control panel.

The modular CPU 61a controls the power supply to the first power supply system 63 and the second power supply system 67. In other words, the modular CPU 61a controls the power supply unit 59a of the tape wrapping unit and instructs the power supply unit 59a of the tape wrapping unit to supply power to the first power supply system 63 and the second power supply system 67. When the tape wrapping module 60 is in the standby mode described below, the modular CPU 61a cuts off power to the first power supply system 63. The first power supply system 63 and the second power supply system 67 may be a physically independent electrical system or may serve as an independent electrical system when the modular CPU 61a executes firmware.

The ribbon wrapping controller controls the electric motor controllers 61b and 61c based on instructions from the modular CPU 61a.

An electric motor controller 61b controls the electric motor 63a. The pylon electric motor controller 61c controls the pylon electric motor 78.

The tape wrapping unit power supply unit 59a supplies power to the control panel of the modular CPU 61a. The tape wrapping unit power supply unit 59a supplies power to the components of the tape wrapping unit 60 under the control of the modular CPU 61a. The constituent parts of the tape wrapping module 60 are powered by the power supplied from the tape wrapping module power supply unit 59a.

The power supply unit 59a of the tape wrapping module supplies power to the first power supply system 63 and the second power supply system 67 under the control of the modular CPU 61a. If the first power supply system 63 and the second power supply system 67 are physically independent power systems, respectively, the power supply unit 59a of the ribbon wrapping module comprises a first power supply unit that supplies power to the first power supply unit and a second power supply unit that supplies power to the second power supply system 67 . The power supply unit 59a of the tape wrapping module supplies power to the first power supply system 63 and the second power supply system 67 by turning the first and second power supplies on or off under the control of the modular CPU 61a. Otherwise, if the first power supply system 63 and the second power supply system 67 are configured to serve as independent power supply systems via firmware, the tape wrapping unit power supply unit 59a supplies power to the first power supply system 63 and the second power supply system 67 under the control of the firmware.

Power cannot be supplied to the first power supply system 63 when the tape wrapping module 60 is in standby mode. In other words, the modular CPU 61a cuts off power to the first power supply system 63 when the tape wrapping module 60 is in standby mode.

When the tape wrapping module 60 is in standby mode, the first power supply system 63 supplies power to parts that do not cause problems if the power supply is cut off. The first power supply system 63 supplies power, for example, to an electric motor 63a, a heater 69, and indicators 71.

The electric motor 63a drives parts of the ribbon wrapping module 60 to operate, except for the support 75. For example, the term “electric motor 63a” is a generic term encompassing an electric motor that drives a paddle wheel arrangement 66, an electric motor that drives a clamp 88 banknotes, and an electric motor that drives the sheet transfer means 82.

The second power supply system 67 is energized even when the tape wrapping module 60 is in standby mode. In other words, the modular CPU 61a cuts off power to the second power supply system 67 when the tape wrapping module 60 is in standby mode.

When the tape wrapping module 60 is in standby mode, the second power supply system 67 supplies power to parts that cause a problem if the power supply is cut off. The second power supply system 67 supplies power, for example, to the electric motor of the support 63a, the sensors 67a, and the communication unit 67b between the boards.

Sensors 67a are provided in the constituent parts of the tape wrapping module 60 and detect banknote positions P and occurrence of a jam. Sensors 67a transmit certain information to the modular CPU 61a.

The inter-circuit communication unit 67b is an interface for communicating with other modular CPUs (e.g., modular CPU 13a and modular CPU 177a). Modular CPU 61a transmits / receives data to / from other CPU modules via communication unit 67b. The communication node between the boards 67b may be, for example, an interface for LAN communication.

The following describes an example of the operation of the paper sheet processing apparatus 1.

The paper sheet processing apparatus 1 can switch to an on state, an off state, and a standby mode.

The following are descriptions of an example of operation when the paper sheet processing apparatus 1 goes into an on state, an off state, or a standby state.

In the on state, the power source of the paper sheet processing device 1 is turned on, and the paper sheet processing device 1 stacks and wraps a tape of banknote P. In the off state, the power source of the paper sheet processing device 1 is turned off, and all operations of the paper sheet processing device 1 are stopped.

In standby mode, the power source of the paper sheet processing device 1 is turned on, and the operations of the components of the paper sheet processing device 1 are stopped. In standby mode, part of the paper sheet processing devices 1 is energized to enable immediate start of operation, while other parts are not energized.

When the operating state switches to standby mode, the modular CPU 13a then instructs the power supply unit 12a of the main module to cut off power to the components of the main module 10. Accordingly, the electric motors, sensors and indicators in the main module 10 are stopped. Additionally, the modular CPU 13a instructs the power unit 12a of the main module to supply power to the modular CPU 13a and the communication center between the boards, which is an interface for communication between the boards. Thus, the modular CPU 13a can determine whether or not the cancel switch is pressed, and can perform the transition of the paper sheet processing apparatus 1 to the on state from the standby mode. The modular CPU 13a transmits to the modular CPU 177a and the modular CPU 61a a signal indicating that the paper sheet processing apparatus 1 is in standby mode.

The modular CPU 177a instructs the expander power supply unit 170a to cut off power to the components of the expander 174. Accordingly, electric motors, sensors and indicators in expansion module 174 are stopped. Additionally, the modular CPU 177a instructs the expansion unit power unit 170a to supply power to the modular CPU 177a and the communication center between the cards as an interface for communication between the cards. Thus, the modular CPU 177a can receive a signal indicating an on state from the modular CPU 13a and can instruct the expansion module power unit 170a to supply power to the components of the expansion module 174.

The modular CPU 61a instructs the power supply unit 59a of the tape wrapping module to cut off power to the first power supply system 63. The electric motors 63a, the heater 69, and the indicators 71, which thereby supply power from the first power supply system 63, are stopped.

The modular CPU 61a supports supplying power to the modular CPU 61a and the second power supply system 67. By maintaining the power supply to the support motor 78 in the second power supply system 67, the support electric motor 78 is driven and locked even in standby mode. As a result, the support 75, which operates in synchronization with the operation of the electric motor 78 of the support, does not move downward by gravity even in standby mode and is maintained in position immediately before the paper sheet processing apparatus 1 goes into standby mode. Therefore, after exiting the standby mode, the tape wrapping module 60 can additionally stack the banknotes on the banknotes P already laid on the support 75.

Additionally, by supplying power to the modular CPU 61a and the communication between the boards 67d, the modular CPU 61a can receive a signal indicating an on state from the modular CPU 13a and can instruct the ribbon wrapping unit power unit 59a to supply power to the components of the wrapping unit 60 tape.

When the standby switch is pressed in the on state to turn the paper sheet processing apparatus 1 into the standby mode, the paper sheet processing apparatus 1 goes into standby mode. The paper sheet processing apparatus 1 goes into standby mode if the banknotes P are not stacked for a predetermined period.

When the cancel switch to exit the standby mode is pressed in the standby mode, the paper sheet processing apparatus 1 goes into the on state and wraps a tape of the banknote P.

5 is a flowchart for explaining an example of the operation of the paper sheet processing apparatus 1.

In this example, the paper sheet processing apparatus 1 is assumed to be in an off state.

Firstly, the modular CPU 13a of the paper sheet processing apparatus 1 determines whether or not the ON switch is pressed to execute the switching of the paper sheet processing apparatus 1 to an on state (step S11). In other words, the modular CPU 13a determines whether or not a signal indicating pressing performed for the ON switch is received from the function unit 17.

If it is determined that the ON switch is not pressed (step S11, “No”), the modular CPU 13a returns to step S11.

If it is determined that the ON switch is pressed (step S11, “Yes”), the modular CPU 13a performs initialization processing (step S12). Initialization processing sets the components of the paper sheet processing device 1 to a state that allows the packing and wrapping of the banknote P in tape. For example, in the initialization processing, the modular CPU 13a transmits a command to execute the initialization processing to the modular CPU 61a and the modular CPU 177a. The modular CPU 13a, the modular CPU 61a and the modular CPU 177a drive the electric motors of the respective modules and place the moving parts in the proper positions. For example, the modular CPU 61a instructs the electric motor 63a and the electric motor 78 to operate and places the impeller 66 with the impeller, the banknote clamps 88, the sheet transfer means 82 and the support 75 in the proper processing positions.

After the initialization processing is completed, the modular CPU 13a determines whether or not the standby switch is pressed (step S13). In other words, the modular CPU 13a determines whether or not a signal indicating pressing performed for the ON switch is received from the function unit 17.

If it is determined that the ON switch is not pressed (step S13, “No”), the modular CPU 13a determines whether or not the predetermined period has elapsed since the banknote P was last stacked (step S14). In other words, the modular CPU 13a determines whether or not the elapsed time exceeds a predetermined period based on information indicating the elapsed time that is transmitted from the timer 13b.

If it is determined that the predetermined period has not expired (step S14, “No”), the modular CPU 13a determines whether or not the OFF switch is pressed (step S15). In other words, the modular CPU 13a determines whether or not a signal indicating pressing performed for the OFF switch is received from the function unit 17.

If it is determined that the OFF switch is not pressed (step S15, “No”), the modular CPU 13a returns to step S13.

If it is determined that the standby switch is pressed (step S13, “Yes”), or if the predetermined time has passed (step S14, “Yes”), the modular CPU 13a performs processing (step S16). Processing in standby mode sets the device 1 for processing sheets of paper in a state that allows transition to standby mode. Standby processing continues processing, which cannot be paused in the middle. For example, when the paddle-laying device 66 conveys the bill P, the standby processing is performed with the possibility to rotate the paddle-laying apparatus 66 with the paddle wheel to the transport end position for the bill P and loads the bill P on the support 75.

Otherwise, when the banknote P is on the transport path 16, 31 or 62, the standby processing transfers the banknote P to the ribbon wrapping unit 60, rotates the paddle-laying device 66 with the impeller, and loads the banknote P onto the support 75.

After processing the processing in the standby mode, the modular CPU 13a enters the standby mode (step S17). In other words, the modular CPU 13a cuts off power from the main unit power supply 12a. Additionally, the modular CPU 13a transmits to the modular CPU 61a and the modular CPU 177a a signal indicating that the paper sheet processing apparatus 1 is in standby mode.

Upon receipt of the signal, the modular CPU 177a cuts off power from the expander power unit 170a.

Upon receipt of the signal, the modular CPU 61a cuts off power to the first power supply system 63. For example, when the first power supply system 63 and the second power supply system 67 are physically independent, the modular CPU 61a transmits a command to the power supply unit 59a of the tape wrapping unit in order to cut off the power supply to the first power supply system 63. The power supply unit 61a of the tape wrapping module receives a command and cuts off power to the first power supply system 63. Otherwise, if the first power supply system 63 and the second power supply system 67 are set independent by firmware, the modular CPU 61a stops supplying power to the first power supply system 63 by the firmware.

After entering the standby mode, the modular CPU 13a determines whether or not the OFF switch is pressed (step S18). If it is determined that the OFF switch is not pressed (step S18, “No”), the modular CPU 13a determines whether or not the cancel switch is pressed to exit the standby mode of the paper sheet processing apparatus 1 (step S19). In other words, the modular CPU 13a determines whether or not a signal indicating pressing performed for the cancel switch is received from the function unit 17.

If it is determined that the cancel switch is not pressed (step S19, “No”), the modular CPU 13a returns to step S18.

Otherwise, if it is determined that the cancel switch is pressed (step S19, “Yes”), the modular CPU 13a exposes the components, except the support 75, to the initialization processing (step S20). In other words, the modular CPU 13a instructs the power supply unit 12a of the main module to supply power to the respective components of the main module 10. After the power is supplied to the corresponding components, the modular CPU 13a places the moving parts in the proper starting positions. Additionally, the modular CPU 13a transmits a signal indicating the transition from the standby state to the modular CPU 61a and the modular CPU 177a.

The modular CPU 177a receives the signal and instructs the expansion unit power unit 170a to supply power to the components of the expansion unit 174. After power is supplied to the components, the modular CPU 13a places the corresponding moving parts in the proper starting positions.

The modular CPU 61a receives the signal and instructs the power supply unit 59a of the tape wrapping module to supply power to the first power supply system 63. When power is supplied to the first power supply system 63, the modular CPU 61a places moving parts (for example, a paddle-type stacker 66, banknote clip 88 and sheet transfer means 82), with the exception of the support 75, in the proper starting positions.

When components other than the support 75 are subjected to initialization processing, the modular CPU 13a returns to step S13.

If it is determined that the OFF switch is pressed (step S15, “Yes”), or if it is determined that the OFF switch is pressed (step S18, “Yes”), the modular CPU 13a performs completion processing (step S21). The completion processing sets the paper sheet processing apparatus 1 to a state allowing a transition to an off state. For example, if bundled banknotes P are stacked on a support 75 of the ribbon wrapping module 60, the completion processing causes the stacked banknotes P to extend outside the supports 75. When the stacking device 66 with a paddle wheel conveys the banknote P, the completion processing rotates the stacking device 66 with a paddle wheel to the final transport position for banknote P and stacks banknote P on a support 75. In this case, the completion processing then gives the stacked banknotes P out of the support 75. After processing, The modular CPU 13a turns off the power source of the paper sheet processing apparatus 1 (step S22). In other words, the modular CPU 13a transmits a command that turns off the power source to the modular CPU 61a and the modular CPU 177a. The modular CPU 13a also turns off the power to the main unit power supply 12a.

Upon receipt of the signal, the modular CPU 13a turns off the power to the expander power unit 170a. Upon receipt of the signal, the modular CPU 13a turns off the power of the power supply unit 59a of the tape wrapping module.

At this point in time, the modular CPU 13a can control the power supply unit 59a of the tape wrapping module so as to supply power only to the function unit 17, which determines if the ON switch is pressed. In this case, the modular CPU 13a may instruct the power supply unit 12a of the main module to supply power to the modular CPU 13a so as to allow reception of a signal that determines the ON switch is pressed.

When the power supply of the entire paper sheet processing apparatus 1 is turned off, the modular CPU 13a terminates.

A paper sheet processing device configured as described above may go into standby mode. During standby mode, the support of the ribbon wrapping module is fixed in position during setup and the standby mode does not move. Accordingly, the support is maintained in a state in which sheets of paper remain stacked. As a result, when returning to normal mode from standby mode, there is no need to collect or replenish banknotes stacked on a support. Additionally, there is no need for an operation to initialize the support. Accordingly, the paper sheet processing apparatus 1 can continuously restart stacking of paper sheets. From the foregoing, the standby mode can be set without requiring laborious recovery processing, and a paper sheet processing device capable of reducing power consumption can be obtained.

Second Embodiment

The second embodiment is described below.

The paper sheet processing apparatus according to the second embodiment has a configuration different from the configuration of the first embodiment in that power is supplied to the support motor 78 from the first power supply system 63, and in that the first gear 77a, the second gear 77b and the third gear 77c can fix the support 75 through the use of gear ratios and weights of the respective gears. In the second embodiment, the remaining features of the configuration of the paper sheet processing apparatus, with the exception of the features described above, are identical to those of the paper sheet processing apparatus according to the first embodiment. Identical components, respectively, are denoted by identical reference numbers, and their detailed descriptions are omitted.

6 is a block diagram schematically showing a system configuration of a paper sheet processing apparatus 1.

As shown in FIG. 6, a support electric motor 78 is contained in the first power supply system 63. In other words, when the ribbon wrapping module 60 goes into standby mode, the ribbon wrapping module controller 59 cuts off power to the support motor 78.

The first gear 77a, the second gear 77b and the third gear 77c of the support drive assembly configure a locking mechanism having a structure capable of supporting the weight of the stacked banknotes P stacked on the support 75, even if the power supply to the support electric motor 78 is cut off. In other words, even when the power supply to the bearing motor 78 is cut off, the first gear 77a, the second gear 77b and the third gear 77c can support the support 75 so that it does not move down due to the resistance formed from the gear ratios and weights of the respective gears. The support 75 is fixed without moving down due to the resistance formed from the respective gears.

For each of the first gear 77a, the second gear 77b and the third gear 77c, the gear ratio and weight are determined depending on the weights of the support 75 and the stacked banknotes P. For example, the weight of the support 75 is supposed to be 700 g and the weight of one hundred banknotes P, as assumed to be 100 g. The weight of the connecting rod 76 is assumed to be 300 g. In this case, the weight of the first gear 77a is 100 g. The large diameter gear of the first gear 77a contains forty gear teeth and its small diameter gear contains sixteen gear teeth . Further, the weight of the second gear 77b is 100 g. The large diameter gear of the second gear 77b contains forty gear teeth, and its small diameter gear contains sixteen gear teeth. The weight of the third gear 77c is 100 g. The third gear 77c contains forty gear teeth. The gear mounted on the far end of the rotational shaft of the support electric motor 78 contains nine gear teeth.

When the tape wrapping module 60 goes into standby mode, the modular CPU 61a then cuts off power to the first power supply system 63. Accordingly, the modular CPU 61a cuts off power to the foot motor 78.

When the power supply to the support electric motor 78 is stopped, the support 75 is then not supported by the driving force of the support electric motor 78. However, since the first gear 77a, the second gear 77b and the third gear 77c are configured to support the weight of the support 75 and the weight of the banknotes P stacked on the support 75, the support 75 can be maintained in a position identical to the position immediately before the paper sheet processing apparatus transitions to Standby mode. Accordingly, the tape wrapping module 60 can continuously lay banknotes P on the support 75 after exiting the standby mode, similarly to the first embodiment.

A paper sheet processing device configured as described above may cut off power even to the stand motor in standby mode. As a result, in the standby mode, the paper sheet processing apparatus 1 can save more power than the paper sheet processing apparatus 1 according to the first embodiment.

Third Embodiment

The following describes a paper sheet processing apparatus according to a third embodiment.

The third embodiment has a configuration different from that of the first embodiment in that the electric motor 78 of the support is supplied with power from the first power supply system 63, in that the temporary stacking unit 65 includes a solenoid, a plunger and a fastener that act as a locking mechanism, and the fact that the connecting rod 76 contains an engaging part. In the third embodiment, the remaining features of the configuration of the paper sheet processing apparatus, with the exception of the features described above, are identical to those of the paper sheet processing apparatus according to the first embodiment. Identical components, respectively, are denoted by identical reference numbers, and their detailed descriptions are omitted.

7 is a front view of a temporary stacking unit 65, which comprises a paper sheet processing apparatus 1 according to a third embodiment.

As shown in FIG. 7, the locking mechanism of the temporary laying assembly 65 includes an engaging portion, a solenoid, and a plunger provided on the connecting rod 76. In other words, an engaging groove 93 that acts as the engaging portion is provided at the lower end portion of the connecting rod 76. The engaging groove 93 is in the form of a gear in which the convex and concave parts are alternately arranged in a perpendicular direction.

The solenoid 90 and the plunger 91 are provided substantially horizontally below the gear 77. The plunger 91 is inserted into the solenoid 90 so that it can reciprocate along horizontal directions. In the solenoid 90, the compression spring 94 supplies energy to the plunger 91 in the protruding direction from the solenoid 90. Additionally, the fastener 92 is attached to the distal end of the plunger 91. The fastener 92 includes an engaging end having a convex and concave shape or gear shape that can engage in the engaging Groove 93.

The solenoid 90 and the plunger 91 are provided so that they are located opposite the connecting rod 76. The plunger 91 is supported to move between a fixed position in which the fastener 92 provided at the distal end engages in the engaging groove 93 of the connecting rod 76 and the disengaged position in which the fastener extends from the engaging groove 93. When the solenoid 90 is electrically conductive, the plunger 91 is removed to the disengaging position by means of a magnetic field, Rowan of the solenoid. When the conductivity in the solenoid 90 is stopped, the plunger 91 is energized by the compression spring 94, and it moves to a fixed position. When the plunger 91 moves to the locked position, the fastener 92 engages in the engaging groove 93 of the connecting rod 76 and fixes the connecting rod 76. Thus, the connecting rod 76 and the support 75a are locked in a stopped position to prevent additional movement.

When the support motor 78 moves the support 75, the modular CPU 61a of the ribbon winding module 60 controls the flow of electric current to the coil of the solenoid 90 and pulls the plunger 91 into the solenoid 90. As a result, the fastener 92 moves away from the connecting rod 76, and the support motor 78 then can move the support 75.

8 is a block diagram schematically showing a system configuration of a paper sheet processing apparatus 1.

As shown in FIG. 8, the first power supply system 63 comprises a support electric motor 78 and a solenoid 90.

Therefore, when the paper sheet processing apparatus 1 is set in the standby mode, the power supply to the support electric motor 78 and the solenoid 90 is stopped.

The modular CPU 61a goes into standby mode after the formation of a state in which the fastener 92 contacts the connecting rod 76 through standby processing.

When the paper sheet processing apparatus 1 goes into standby mode, the modular CPU 61a then cuts off power to the first power supply system 63. Accordingly, the modular CPU 61a cuts off power to the solenoid 90.

When the power supply to the support electric motor 78 is stopped, the support 75 is then not supported by the driving force of the support electric motor 78. However, a fastener 92 provided at the distal end of the plunger 91 remains pressed against the connecting rod 76 by means of the mechanical stress of the spring. As a result, the support 75 remains permanently fixed by means of a fastener 92 provided at the distal end of the plunger 91, and can be maintained at a position identical to that immediately before the paper sheet processing apparatus goes into standby mode. Accordingly, the tape wrapping module 60 can continuously lay banknotes P on the support 75 after exiting the standby mode, similarly to the first embodiment.

A paper sheet processing device configured as described above may cut off power even to the stand motor in standby mode, as in the second embodiment. As a result, in the standby mode, the paper sheet processing device 1 can save power from the paper sheet processing device 1 according to the first embodiment. In addition, the paper sheet processing apparatus can fix the support independently of gear ratios and weights.

Although specific embodiments have been described, these embodiments are provided by way of example only and are not intended to limit the scope of the invention. In fact, the new embodiments described herein can be implemented in many other forms; in addition, various omissions, substitutions, and changes in the form of the embodiments described herein may be made without departing from the spirit of the invention. The appended claims and their equivalents are intended to cover such forms and modifications as fall within the scope and spirit of the invention.

Claims (8)

1. A device for processing sheets of paper, containing:
a feed unit (11) into which a plurality of sheets of paper are stacked;
a sheet separating unit (14) that draws sheets of paper from the feed unit;
a test assembly (18) that checks the selected sheets of paper;
a stacking unit (66), which stacks each predetermined number of checked sheets of paper on a support (75);
a support drive unit (81) that adjusts the position of the support depending on the number of sheets of paper stacked;
a tape wrapping unit (68) that wraps the laid sheets of paper with the tape by wrapping the tape around the laid sheets of paper;
at least one power source (12a, 59a, 170a) that supplies power to the electrical functional parts of the sheet separator assembly, the test assembly, the stacking assembly, the support drive assembly, and the tape wrapping assembly;
a mode setting unit (13a) that sets a standby mode with a temporary interruption of power supply to at least one of the electrical functional parts; and
a fixing unit (77, 78, 90, 91, 92, 93) that fixes the support in position for the standby mode when the standby mode is set by the mode setting unit. 2. The device for processing sheets of paper according to claim 1, in which:
the support drive assembly comprises an electric motor (78) that drives the support, and
the fixation unit contains a power supply system (63) that supplies power to the electric motor, and in a predetermined standby mode, the fixation unit supplies power to the electric motor of the support drive unit and fixes the support in a stopped position by the electric motor. 3. The device for processing sheets of paper according to claim 1, in which:
the support drive assembly comprises an electric motor (78) and a gear transmission (77) that transfers the driving force of the electric motor to the support, and
the fixing unit is configured by means of a gear train, wherein the gear train utilizes gear ratios and weights at which the support and sheets of paper laid on the support can be held in a stopped position. 4. The device for processing sheets of paper according to claim 1, in which:
the support drive assembly comprises a support member (76) connected to the support and supported with free movement, and an electric motor that drives the support member, and
the fixing unit comprises an engaging part (93) provided on the support element, a plunger adapted to move between a fixed position in which the plunger engages with the engaging part and an uncoupled position in which the plunger moves away from the engaging part, a solenoid that transmits energy to the plunger for the trip position, and an energy message element (94) that reports energy to the plunger for a fixed position, while when the standby mode is set and the power supply to the solenoid is stopped, the plunger moves to a fixed position, and the support element is fixed by means of a plunger. 5. The paper sheet processing apparatus according to claim 1, further comprising:
measuring unit (13b), which measures the time elapsed from the moment the sheet of paper is stacked for the last time, while:
the mode setting unit sets the standby mode if the time measured by the measuring unit exceeds a predetermined period of time. 6. The paper sheet processing apparatus according to claim 2, further comprising:
measuring unit (13b), which measures the time elapsed from the moment the sheet of paper is stacked for the last time, while:
the mode setting unit sets the standby mode if the time measured by the measuring unit exceeds a predetermined period of time. 7. The paper sheet processing apparatus according to claim 3, further comprising:
measuring unit (13b), which measures the time elapsed from the moment the sheet of paper is stacked for the last time, while:
the mode setting unit sets the standby mode if the time measured by the measuring unit exceeds a predetermined period of time. 8. The device for processing sheets of paper according to claim 4, further comprising:
measuring unit (13b), which measures the time elapsed from the moment the sheet of paper is stacked for the last time, while:
the mode setting unit sets the standby mode if the time measured by the measuring unit exceeds a predetermined period of time.

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