KR100266366B1 - Processing system of giro paper. - Google Patents

Abstract

PURPOSE: A device for managing a giro paper is provided to receive a giro paper automatically by using a bank card of a user and to manage the giro paper in a cash dispenser rapidly. CONSTITUTION: The device for managing a giro paper includes a receiving portion(10), the first conveying portion(20), an integrated portion(30), the second conveying portion(40), a keeping portion(50) and a returning portion(60). A user inserts a giro paper into the receiving portion(10). The first conveying portion(20) conveys the giro paper inserted into the receiving portion(10). The keeping portion(30) keeps the paper conveyed from the first conveying portion(20). The second conveying portion(40) conveys the collected paper for returning. The returning portion(60) returns the paper conveyed from the second conveying portion(40) to the user. The keeping portion(50) keeps the managed paper received from the integrated portion(30).

Description

Jiro Paper Processing Equipment

1 is a schematic block diagram of the paper stock processing apparatus of the present invention.

2 is an overall configuration diagram of the paper stock processing apparatus of the present invention.

3 is a block diagram of a housing portion of the paper stock processing apparatus of the present invention.

4 is a configuration diagram of a first conveying unit of the paper stock processing apparatus of the present invention.

5 is a configuration diagram of an integrated unit of the paper stock processing apparatus of the present invention.

6 is a block diagram of the classification apparatus of the paper stock processing apparatus of the present invention.

7 is a configuration diagram showing a return state of the paper stock processing apparatus of the present invention.

8 is a block diagram showing a transfer state to the storage of the paper stock processing apparatus of the present invention.

9 is a block diagram of a storage unit of the paper stock processing apparatus of the present invention.

* Explanation of symbols for main parts of the drawings

10: accommodating part 11: feed roller

14: pressing plate 12: take out roller

20: first transfer part 22a: upper belt

22b: lower belt 23: printer

30: integrated part 32: upper idle belt

34: lower transfer belt 40: second transfer unit

42: upper belt 44: lower belt

50: storage unit 60: return unit

72: first timing belt 74: second timing belt

80: classification member 82: storage guide

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a paper machine, and more particularly, to a paper machine which can be configured to automate the receipt of paper from paper that depends on the current manual work.

At present, financial institutions rely solely on manual processing of giro paper. In other words, since the person in charge relies on manual labor to process, check, and receive the papers individually, it causes unnecessary waste of labor for the financial institution, and inconvenience for the customer due to delay in processing time. It was causing. In particular, on the day paying giro concentrated at the end of the month due to the concentrated work volume, the situation is aggravating the inconvenience.

An object of the present invention is to provide a paper processing apparatus that can automate the processing of the paper storage.

Another object of the present invention is to provide an apparatus capable of quickly storing paper of paper.

Next, the present invention will be described in more detail with reference to the embodiments shown in the drawings.

FIG. 1 is a schematic view showing an overview block of the paper processing apparatus according to the present invention.

As shown, the paper-based paper processing apparatus according to the present invention primarily includes an accommodating portion 10 into which the user inserts the paper, and a paper-based paper (hereinafter simply referred to as paper) fed from the accommodating portion 10. A first transfer unit 20 for transferring the paper, an accumulation unit 30 for storing the paper transferred from the first transfer unit 20 up to a predetermined number of sheets, and a second transfer unit for returning the paper temporarily collected by the accumulation unit. It includes a transfer unit 40, a return unit 60 for returning the paper conveyed from the second transfer unit from the user, and a storage unit 50 for receiving and storing the receipt-treated paper in the accumulation unit 30. .

2 is a side view showing the overall configuration of the paper processing apparatus according to the present invention. Referring to FIG. 2 together, each part configured as described above with reference to FIGS. 3 to 3 will be described in more detail.

3 is a view showing the accommodating portion 10 of the paper processing apparatus according to the present invention. The storage portion is a portion for feeding the paper into which the user intends to receive water treatment. The storage portion is a portion for feeding the paper into which the user intends to receive water treatment. The paper used in the paper processing apparatus according to the present invention is the part except for the receipt which is actually returned to the user, and what is presented to the user as a receipt uses a separate one. For example, if the paper processing apparatus according to the present invention is implemented in the existing ATM, it will be used such as a separate receipt supplied to the user in the ATM.

As shown in the drawing, the housing 10 according to the present invention includes a plurality of feed rollers 11: 11a, 11b, 11c for feeding paper while contacting the bottom surface of the paper to be loaded, and the feed roller 11. And a presser plate 14 for pressing the sheets on the paper, and a driving device for moving the presser plate 14 downward.

When the paper is input, the pair of sensing sensors (S ₁ : S _1a : S _1b ) attached to the upper and lower sides of the input unit detect that the paper is loaded. Then, the pressing plate 14 moves downward to adhere the paper to the feed roller 11 based on the detection signal, thereby feeding the inserted paper to the first transfer unit 20 described later. The driving device for moving the pressing plate 14 downwardly includes a drive gear 16a that is rotated by the motor 19 and the motor 19, and a driven gear that is engaged with the drive gear 16a to rotate together. 16b) and a link 15 that rotates together with the rotating shaft of the driven gear 16b. Accordingly, the rotation of the motor 19 causes the link 15 to rotate counterclockwise through the drive gear 16a and the driven gear 16b, and the link 15 has a point P1 therewith. The hinge plate 14 connected to the hinge is moved downward. In this way, the sheet conveyed into the housing 10 is supplied to the first transfer unit 20 described later through a pair of take-out rollers 12: 12a: 12b.

As described above, the accommodating part 10 can be seen that it is a part for guiding the inserted paper to the first conveying part 20, so that the other deformation within the range for feeding the paper to the first conveying part 20. Of course this is possible. For example, by installing a plurality of feed rollers which slide in contact with each other from above and below with paper interposed therebetween, the guided paper can be guided to the first transfer unit 20. It would also be possible.

Next, referring to FIG. 4, a description will be given of a first conveying unit 20 for processing paper conveyed from the receiving unit 10.

As shown in the drawing, the paper fed to the first conveying unit 20 through the take-out roller 12 of the storage unit 10 is connected to the upper belt 22a and the lower portion through the pair of introduction rollers 21: 21a: 21b. Enter between the belts 22b. And front and rear sensor for confirming the input direction of the paper (the direction of the front and rear _{surfaces) (S 2: S 2a:} S 2b) prior to entering the upper and lower belts (22a, 22b) is installed. The front and rear sensor S ₂ detects whether or not the front and back sides of the paper input by the user match, and if not, returns the input paper to the user through the return unit 60 as described below. If matched, it will be discharged to the storage unit 50 through a process as described below.

The upper belt 22a and the lower belt 22b are adjacently provided to feed the paper therebetween, and when viewed in plan view, they are configured in pairs on each side. In other words, the left and right sides of the paper to be inserted is configured to be transported in a state held. The upper belt 22a and the lower belt 22b are driven by a pair of upper belt pulleys 22 _a1 and 22 _a2 and lower belt pulleys 22 _b1 and 22 _b2, respectively, and not shown in the driving of the pulleys. The drive motor is driven using a non-drive motor, and control of such a drive motor will be performed by a microprocessor (not shown). As described above, the overall control of the processing apparatus according to the present invention including the drive motor is performed by a microprocessor, and a board on which such a microprocessor is mounted is installed in the board B shown in FIG. In the description of the present invention, each signal connection line by the microprocessor is omitted.

As described above, the lower belt 22b and the upper belt 22a are configured in pairs to hold and transport both sides of the paper, respectively, when viewed from the top view, and between the pair of upper belts 22a is received. The printer 23 which performs printing processing is provided. Therefore, when the front surface and the back surface of the paper are correctly inserted, the receiving process is performed by the printer 23 while being transported through the upper and lower belts 22a and 22b, and the paper which has exited the upper and lower belts 22a and 22b. It is conveyed by the some conveyance roller 25a, 25b etc. which are provided in the 1st conveyance part 20. As shown in FIG.

Then, the image optical readers 24: 24a: 24b are provided on the conveyance path of the paper in the first iso-section 20. The image optical reader 24 detects a giro code described in a bar code or OCR form, and transmits it to a microprocessor to perform necessary computational processing. In addition, on the transfer path of the first transfer unit 20, sensors (S ₃ , S ₄ ) for detecting the jam (jam) of the paper is installed, it is checked whether the jam occurs and the transfer timing during the transfer of the paper. .

The paper conveyed as described above and passing through the conveying rollers 25a and 25b and the discharge roller 29 of the first conveying portion 20 falls to the accumulating portion 30 of FIG. That is, the paper which has passed through the feed rollers 25a and 25b is advanced by the discharge roller 29 and falls to the accumulation part 3 mentioned later. The paper sheet dropped to the accumulation unit 30 collects the processed paper or the unprocessed paper by type, and is collectively transferred to the storage unit 50 or the return unit 60.

Even if the giro paper processing apparatus according to the present invention is configured as, for example, a cash dispenser or the giro paper processing apparatus itself, the user can perform transfer processing from his or her own account (such as a credit card or a cash card). Card can be used to directly store the paper in the account. When a user processes multiple sheets of paper with a single card, even if one of them is wrong If so, the entire sheet is returned to the return unit. Therefore, when the aggregator 30 processes a plurality of giro papers using a single card, the accumulation unit 30 corresponds to a portion for collecting and processing the giro papers. Of course, in the case of processing one giro paper with one card, the accumulation unit 30 simply processes one sheet.

As shown in FIG. 5, the integration part 30 is comprised from the upper idle belt 32 and the lower conveyance belt 34. As shown in FIG. The upper idle belt 32 operates as an idler without transmission of power, and moves to a position in contact with and spaced apart from the lower transfer belt 34. In the illustrated embodiment, the upper idle belt 32 shows an example in which the upper idle belt 32 may be contacted or spaced apart from the lower transfer belt 34 while being rotated by the driving motor 39. Specifically, looking at the operating mechanism of the upper idle belt 32, the rotational force of the drive motor 39 is connected to the driven gear 37 through the drive gear 38, the link to rotate like the rotating shaft of the driven gear 37 36 rotates the bracket 32d connected clockwise or counterclockwise through the pin P2 inserted into the long hole 36a formed at the end thereof. As the bracket 32d is shown, since the pair of pulleys 32a and 32b for driving the upper idle belt 32 are supported, when the upper idle belt 32 rotates counterclockwise, The lower transfer belt 34 is in contact with the side. And the upper idle belt 32, when the paper conveyed in the state separated from the lower transfer belt 34 is collected between the upper idle belt 32 and the lower transfer belt 34, the lower transfer belt 34 Of course, other modifications are possible to the drive mechanism within the range of movement in contact with.

The lower transfer belt 34 is a power transmission device driven by the pulley 34a and the pulley 34b to which power is transmitted. Therefore, when the upper idle belt 32 moves downward to come into contact with the lower transfer belt 34, the sheets accumulated therebetween are transferred to the left side in the drawing by the rotational force of the lower transfer belt 34.

Referring to FIG. 8, which shows an embodiment for transmitting power to the pulley 34a of the lower transfer belt 34, the power in the driving motor 70 is firstly timing through the motor pulley 71a. One side of the second timing belt 74 is wound around the other pulley shaft 71b of the first timing belt 72. Since the other side of the second timing belt 74 is caught by the pulley 34a of the lower transfer belt 34, the lower transfer belt 34 is substantially rotated by the power of the drive motor 70. .

Next, with reference to FIG. 6, a description will be given of the conveyance path of the paper discharged from the accumulator 30. The paper discharged from the accumulation unit 30 is transferred to the storage unit 50 or the return unit 60. The papers to be transferred to the storage unit 50 are all received papers, and the papers to be returned to the return unit 60 are papers that have been mishandled on the front or back sides, or papers that are jammed during processing. Say.

As shown in FIG. 6, the paper exiting the upper idle belt 32 and the lower conveyance belt 34 is conveyed by the sorting member 80 to the storage section 50 or the return section 60. This is determined.

The sorting member 80 is installed at a portion where paper is discharged from the accumulator 30 and is rotatably installed around the lower hinge shaft P3. And the sorting member 80, the solenoid connecting portion 86 for rotating the sorting member 80 by the operation of the solenoid 90, and the curved storage to guide the paper to the storage section 50 when rotated to the top The sub guide surface 84 and the flat return part guide surface 82 for sending the sheet | seat to the return part 60 at the time of rotation below are provided.

The solenoid connecting portion 86 rotates the sorting member 80 while interlocking with the solenoid 90 by the operation of the solenoid 90. In FIG. 6, the state shown by the solid line is a state in which the solenoid 90 is off, and always maintains this state until integration is completed in the integration unit 30. In FIG. That is, when the solenoid 90 is in the off state, the sorting member 80 is always in a state shown by a solid line (the paper discharged from the accumulation unit 30 can move to the storage unit 50. This state) For example, by inserting and installing an elastic means such as a torsion spring to the hinge shaft (P3) can be implemented by configuring the sorting member to always receive a counterclockwise elastic force, such a support state is a spring or the like In this state, when the power is applied to the solenoid 90, the solenoid 90 is connected to the lower end portion 86 of the sorting member 80. Is pulled downward, so that the sorting member 80 rotates clockwise about the hinge axis P3. That is, when the solenoid 90 is turned on, the sorting member 80 is a dashed line. city And in a state, Jiro paper discharged from the stacking unit 30 in this state is conveyed to the second transfer part (40).

In more detail with respect to the sorting member 80, if it is determined that any one of the papers collected in the accumulation unit 30 is impossible to process [this determination is detected by the sensor (S ₂ or S ₃ ). ], The solenoid 90 is operated while on (on). The sorting member 80 interlocking with the solenoid is rotated in a state shown by a dashed-dotted line, and in this state, the accumulated paper discharged from the accumulator 30 passes through the upper portion of the flat return part guide surface 84. It is transferred to the second transfer part 40. In FIG. 6, reference numeral G6 denotes a sheet conveyed to the return unit 60 through the second transfer unit 50, and G5 denotes a sheet conveyed to the storage unit 50.

When the paper collected in the accumulation unit 30 is judged that the receipt process is completed without any abnormality, the solenoid 90 is kept in an off state, and thus the paper discharged from the accumulation unit 30 is classified into the sorting member 80. Guided along the storage unit guide surface 82 of, and is transferred to the storage unit 50 to be described later.

The sorting member 80 includes a storage guide surface 82 capable of guiding the paper toward at least the storage unit 50, so that when the treated paper is discharged from the accumulation unit without abnormality, it is stored in the storage guide surface. It can be transferred to the storage unit 50 through 82. The return portion guide surface 84, the paper discharged from the accumulator 30 is automatically transferred to the second conveying portion 40 when the sorting member 80 is rotated and the storage portion guide surface 82 does not move downward (clockwise). Is a side that can be returned. Therefore, the storage guide portion 82 is substantially in the off state of the solenoid 90, protrudes upward to guide the paper to the storage portion 50, the solenoid 90 is turned on the storage guide portion 82 The return unit guide surface 84 can be configured within the range in which the paper discharged from the accumulation unit 30 can be immediately transferred to the second transfer unit 40 by moving downward.

Next, referring to FIG. 7, the configuration of the second transfer unit 40 in which the paper discharged from the accumulation unit 30 is returned to the return unit 60 will be described. The second conveying unit 40 refers to a conveying part for discharging the paper from the accumulating unit 30 to the returning unit 60 when no water treatment is performed due to the abnormality of the loaded paper.

As shown, the second conveying unit 40 is composed of an upper belt 42 and a lower belt 44, and conveys the paper returned therebetween to the return unit 60. The upper belt 42 and the lower belt 44 are rotated by hooking the pair of upper pulleys 42a and 42b and lower pulleys 44a and 44b. The power transmission system of each pulley will be described later. The pulley 42b of the upper belt 42 is installed in contact with the lower conveyance belt 34 of the accumulator 30, so that the paper conveyed by the accumulator 30 can be fed directly. The pulley 42b of the upper belt 42 is elastically supported downward by the coil spring 47h so as to be in close contact with the upper portion of the lower conveyance belt 34 of the integrated part 30. .

In addition, the above-described sorting member 80 is provided immediately behind the pulley 42b of the upper belt 42. The upper belt 42 and the lower belt 44 are configured in pairs on the left and right sides when viewed in plan view. That is, a pair is provided to hold both ends of the paper, the sorting member 80 is provided between the pair of lower belts 44, the paper discharged from the accumulator 30 as described above The direction of feed will be determined.

On the path of the upper belt 42, a plurality of guide rollers 42d, 42e, 42f are provided for forming the path of the belt to the return unit 60. The upper belt 42 has a predetermined path toward the return unit 60 by the guide rollers 42d, 42e, and 42f. And the guide roller 44c is installed on the path of the lower belt 44 to form a path that is in contact with the upper belt 42. Accordingly, the upper belt 42 and the lower belt 44 are rotated while being connected to each other by a plurality of guide rollers provided on the paths of the upper and lower belts 42 and 44, thereby conveying the paper to the return unit 60. It will be possible.

In consideration of the improvement of the adhesion between the upper belt 42 and the lower belt 44 and the case where a plurality of sheets of paper pass through the second conveying part 40, the upper belt 42 and the lower belt 44 are brought into close contact with each other. Elastic members 47a, 47b, and 47c are provided. That is, by connecting the guide roller 42f of the upper belt 42 and the pulley 44b of the lower belt 44 to each other with the coil spring 47a, the upper belt 42 and the lower belt 44 are in close contact with each other. The guide roller 42e of the upper belt 42 to the lower belt 44 side using the coil spring 46b, and the pulley 42a of the upper belt 42 using the coil splice 47c. To be elastically supported toward the lower belt 44. By this configuration, the upper belt 42 and the lower belt 44 can be elastically in close contact with each other, it is to provide a sufficient elastic deformation force when a plurality of sheets of paper passes.

Next, a power transmission structure for power transmission of the second transfer unit 40 will be described with reference to FIG. 8.

As described above, the upper belt 42 and the lower belt 44, and the lower transfer belt 34 of the integrated unit 30 may be configured to be driven by different power sources. However, in the embodiment shown in FIG. 8, the belts are driven by one driving motor 70.

Specifically, the motor pulley 71a and the pulley shaft 71b of the lower belt 44 that rotate together with the rotation shaft of the driving motor 70 as the driving source are rotated by the first timing belt 72. Therefore, the pulley shaft 71b that receives power through the first timing belt 72 drives the lower belt 44. Power is transmitted to the pulley shaft 71b and the pulley 34a of the lower transfer belt 34 of the integration unit 30 by the second timing belt 74. Therefore, the lower transfer belt 34 of the integrated part 30 receives power by the second timing belt 74 to rotate. And the pulley shaft 71b of the lower belt 44 is actually formed as a rotating shaft having a predetermined length, so that a gear portion 71bg is formed at a part of the outer circumference thereof, and the pulley of the upper belt 42 is formed. The gear part 42ag is also formed in the outer periphery which engages with the gear part 71bg of the said pulley shaft, and 42a is engaged with each other. Therefore, the pulley shaft 71b rotated by the drive motor 70 and the pulley 42a of the upper belt 42 rotate with each other, and the upper belt 42 also receives power from the driving motor 70. It means to rotate.

Next, referring to FIG. 9, the structure of discharging the paper to the storage unit 50 by the sorting member 80 will be described. As shown in the drawing, the storage section 50 includes a casing 52, a paper base 54 which is elastically supported up and down in the casing, and the paper downward when the paper falls to the base 54 side. It is configured to include a close contact 56 for pushing.

The casing 52 constitutes the overall appearance of the storage portion 50 and supports the inner paper base 54 so as to be movable in the vertical direction. The paper base 54 is elastically supported upward by a pair of elastic springs 53. When the paper G is supplied onto the base 54, the paper base 54 is elastically supported by the elastic springs 53. It is supported and caught by the locking portion 52a which extends inwardly from the upper end of the casing 52. When the received paper G is stacked, the paper G is moved downward by its own weight. In addition, the contact member 56 moves downward (counterclockwise) when paper is introduced into the inside in a state shown by a solid line, thereby completely pushing the paper into the casing 52. That is, the rotational force of the motor 56c is transmitted to the pair of transmission gears 56a and 56b, and the contact member 56 configured to cooperate with the rotation shaft of the transmission gear 56a rotates in accordance with the rotation of the transmission gear 56a. Done. Therefore, it rotates within a predetermined section according to the rotational direction of the motor 56c. While the state shown by the solid line is maintained, when the paper falls, the upper surface of the paper is pushed downward so that it can be completely seated on the upper portion of the base 54, so that the upper surface of the paper G is caught by the locking portion 52a. Rotate to the original position. The operation of the contact member 56 may be performed only once to insert the paper (G), it is also possible to be repeated two or three times for complete storage of the paper (G).

Next, the return unit 60 will be described with reference to FIG. The return unit 60 is a part installed so that the user can take out the paper returned through the second transfer unit 40. Therefore, the return unit 60 may be completed by forming a portion where the user can receive and return the paper returned by hand when the paper returned from the second transfer unit 40 is piled apart. And if necessary, it is possible to control the opening and closing of the return unit 60 by installing a shutter (2) for opening and closing the entrance of the return unit (60). In the illustrated embodiment, the shutter 2 opens and closes the entrances of the storage unit 10 and the return unit 60 while moving in the direction of the arrow shown.

Through the process of processing the giro paper according to the present invention configured as described above, the overall operation will be described.

Although the paper processing apparatus according to the present invention can be configured as its own single processing apparatus, it is also possible to apply the above configuration to a cash dispenser that is currently being supplied.

When the user selects the processing of the paper, the storage unit is opened and the user inserts the paper to be processed through the storage unit 10. As shown in FIG. 3, when paper is inserted into the accommodating part 10, the press plate 14 rotates counterclockwise to make the paper fed into the feed roller 11 close. The paper fed by the rotation of the conveying roller 11 is conveyed to the first conveying unit 20 by the take-out roller 12.

And as shown in FIG. 4, it enters into the 1st conveyance part 20 by the introduction roller 21. As shown in FIG. It is detected whether the front and rear surfaces of the paper inserted by the front and rear sensor S2 installed before entering the first transfer unit 20 are correctly installed. If not, the return unit may be returned by a transfer process to be described later. 60). For example, if a user processes multiple giro papers using a single card, and if one giro paper is inserted incorrectly, the giro paper that is inserted thereafter is not recognized by the front and back sensor (S2) and immediately. It will be conveyed to the accumulator 30 and then all will be discharged to the return unit 60. And if the surface is correctly input, the feed between the upper belt 22a and the lower belt 22b of the first transfer portion 20, while receiving the print by the printer 23 installed on the path. And it is discharged to the accumulation part 30 through the feed roller 25 and the discharge roller 29 which are installed in the rear end of the upper and lower belts 22a, 22b on the first transfer unit 20.

The image optical reader 24 provided in the path conveyed through the feed roller 25 reads the giro code on the paper and performs the necessary processing.

As shown in FIG. 5, the paper G fed into the accumulator 30 is stacked on the lower conveyance belt 34 in a state where the upper idle belt 32 is opened upward. For example, when a user processes a plurality of giro papers using a single card, they are collectively collected in the accumulation unit 30 and transferred to the storage unit 50 or the return unit 60. Therefore, when it is recognized that the user inputs the giro paper, the upper idle belt 32 is rotated counterclockwise by the operation of the driving motor 39 to be in close contact with the lower transfer belt 34, and at the same time The driving force is transmitted to the conveyance belt 34, and all of the giro paper collected in the integrated part 30 enters the inlet of the second conveyance part 40. In this case, as shown in FIG. 8, the driving force of the lower transfer belt 34 is driven by the driving force of the driving motor 70 through the first timing belt 72 and the second timing belt 74. It is driven by being delivered to).

In this case, if any one of the collecting papers collected in the accumulating unit 30 is not inserted into the receiving unit by mistake, the control unit turns on the solenoid 90 shown in FIG. 6 to turn the sorting member 80 clockwise. To the state shown in FIG. 6 to maintain the state shown by the dashed-dotted line. Therefore, as the storage guide surface 82 of the sorting member 80 is rotated downward, it will be transported to the second conveying unit 40 through the upper portion of the return guide surface 84 and discharged to the return unit 60. As the sorting member 80 rotates in the clockwise direction, the state in which the paper collected in the accumulator 30 is conveyed to the second conveyer 40 is shown in detail in FIG. As shown in FIG. 7, the paper guided to the second conveying part 40 in this way is transported between the upper belt 42 and the lower belt 44, and falls to the storage part 60.

And if the paper collected in the accumulator 30 is all received correctly, as the solenoid 90 maintains the original off state, the sorting member 80 is supported by the storage guide surface 82 upwards. (The solid line state of FIG. 6), and thus the series of branch paper G5 discharged from the contact portion 30 is moved to the storage portion 50 along the storage portion guide surface 82 of the sorting member 80. Will be dropped. In this way, a state in which the paper discharged from the accumulation unit 30 is dropped into the storage unit 50 is illustrated in FIG. 8.

Referring to FIG. 8, the sheet | seat G guided to the said storage part 50 by the sorting member 80 is pressed down by the contact member 56. As shown in FIG. Of course, the driving of the close contact member 56 rotates in a counterclockwise direction by the drive motor 56c, and adheres the sheet of paper that is dropped downward to be stacked on the paper base 54. In addition, the contact member 56 serves to push down the paper to the lower portion of the locking portion 52a through the process of closely contacting the paper ground G downward, and by contact with the paper ground G, It also serves to remove static electricity from the paper that has been generated during the transfer process.

Advantageously, the land paper processor according to the present invention constituted as described above is capable of processing the land paper by using its own card in addition to the function as an existing cash dispenser, when it is configured as a cash dispenser currently widely spread. There is also. Therefore, the user can take advantage of the receipt of giro paper by using a cash dispenser that is widely installed without having to visit a financial institution. In other words, the user has the advantage of being able to store the giro simply by using his own card without cash and the advantage of being able to store the giro at a convenient place where a cash dispenser is installed, such as an unmanned corner.

In addition, from the financial institution's point of view, it is possible to prevent the concentration of customers, especially at the end of the month, enabling efficient time and manpower management. In addition, by constructing the above-mentioned giro paper processor by itself, a person in charge in the financial institution can use it to process the giro paper, so that high-speed processing is possible, and thus it is expected to benefit from the convenience of the financial institution and the customer.

Claims (17)

Storage means for receiving paper; Transfer means for transferring the stored paper into the paper; An accumulating means for accumulating a predetermined number of paper sheets conveyed from the conveying means and discharging them collectively; Sorting means for classifying a conveying path of paper for paper discharged from the stacking means; Return means for returning the land paper classified by the sorting means; And storage means for storing the paper of the paper sorted by the sorting means. According to claim 1, The receiving means; A paper processing apparatus consisting of a plurality of feed rollers, and an adhering plate in close contact with the drive rollers to bring the injected paper into the drive rollers. The method of claim 1 or 2, wherein the transfer means; Jiro paper processing apparatus comprising an upper belt and a lower belt for transferring the paper therebetween. The paper processing apparatus according to claim 3, further comprising a printer installed to perform the receipt factor processing of the paper on the paper conveyance path of the paper by the conveying means. 4. The paper processing apparatus of claim 3, further comprising a reading device installed to read the paper code of the paper on the paper by the conveying means. The method of claim 1, wherein the integration means; It consists of a lower conveyance belt, and an upper idler belt in close contact with and spaced apart from the lower conveyance belt, the paper is accumulated on the lower conveyance belt in a state in which the upper idler belt is spaced apart, the upper idler belt is in close contact to transfer the paper in a batch Jiro paper processing device. The method of claim 1 or 6, wherein the return means; Jiro paper processing apparatus consisting of a pair of upper and lower belts for returning the giro paper discharged from the direct means to the user. 8. The paper processing apparatus of claim 7, wherein the upper and lower belts are elastically in close contact with each other by an elastic member. 8. The paper processing apparatus of claim 7, wherein the tip of the upper belt of the return means is in contact with the rear end of the lower conveyance belt of the accumulating means. According to claim 1, wherein said sorting means; And a sorting member rotatably installed between the accumulating means and the return means, and a driving part for rotating the sorting member, wherein the sorting member has a storage means guide surface for guiding the paper discharged from the accumulating means to the storage means. Jiro paper processing apparatus is guided to the storage means when the paper is in contact with the storage means guide surface, the ground paper is guided to the return means when the storage means guide surface is rotated downward. 12. The paper processing apparatus of claim 10, wherein the driving unit comprises a solenoid connected to one end of the sorting member. The paper processing apparatus according to claim 1 or 10, wherein the storage means includes a casing for storing the paper into which the paper is conveyed from the sorting means, and a contact member that rotates to push the paper into the casing. 13. The paper processing apparatus of claim 12, further comprising a base in which the paper is piled on top of the casing, and an elastic member elastically supporting the base on the top of the casing. The paper processing apparatus according to claim 13, wherein the upper end of the casing is formed with a locking portion to which the paper is stacked on the base. 8. The paper processing apparatus of claim 7, wherein the upper and lower belts of the return means and the lower conveying belt of the accumulator are driven by one driving motor. The lower belt of the return means and the lower conveyance belt of the integrated unit are powered from the driving motor to the belt, and the gears formed on the outer circumference of the pulley of the upper belt and the lower belt of the return means are engaged with each other. Giro paper processing device delivered. Storage means for receiving paper; Means for conveying the stored paper into the paper; Sorting means for classifying the land paper in the transport path of the land paper; Return means for returning the land paper classified by the sorting means; And storage means for storing the paper of the paper sorted by the sorting means.

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