JP4708952B2 - Paper sheet separator - Google Patents

Description

  The present invention relates to a paper sheet separating mechanism.

  In recent years, there is a high demand for banknote separators capable of handling overseas banknotes with many types of sizes, so as an example of a conventional paper sheet separating mechanism that separates and feeds paper sheets of different sizes one by one For example, there is a paper sheet feeding device described in JP-A-2002-347961.

  This paper sheet feeding device, when feeding out a long and short mixed banknote, if the leading edge of the banknote is not aligned with respect to the gate part in the paper sheet feeding part, the top banknote is not fed out at the time of feeding the second sheet This is intended to prevent two bills from being fed out (multiple feeding) as a result of being fed out into the gate portion.

  In the above-described conventional example, in order to prevent double feeding, preliminary feeding means for feeding the uppermost one of the paper sheets accumulated on the stage to the gate roller until it hits a low friction surface other than the high friction portion of the feed roller; A kicker roller (hereinafter referred to as a pickup roller) provided between the feed roller and the preliminary feeding means and having a high friction portion in a part of the periphery and driven intermittently in synchronization with the feed roller. It has been. In this way, by providing the preliminary feeding means in the counter feeding direction from the pickup roller, even if there is a paper sheet having a short feeding direction length in the stacked paper sheet, the paper sheet and the gate unit When the interval is large, the short sheet is devised so as to be sent to a predetermined feedable position by the preliminary sending means to prevent double feeding.

JP 2002-347961 A

  The conventional example has a configuration in which the preliminary feeding means is provided in the anti-feeding direction from the pickup roller. In the above conventional example, banknotes are cited as an example of paper sheets, and the length of the shortest euro banknote is 120 mm, and the length of the longest euro banknote is 160 mm. These values are the dimensions of the long side of the bill. That is, the conventional example is an invention that is effective in a feeding device for feeding a paper sheet with a relatively long length in the feeding direction, such as feeding a banknote in a posture in which the short side of the banknote is a leading edge and a trailing edge.

  However, when the length of the paper sheet to be handled is short, the preliminary feeding means may not be provided in the reverse feeding direction of the pickup roller as shown in the conventional example. For example, the shortest dimension of the euro banknote is 62 mm and the longest dimension is 82 mm. In a separation mechanism that feeds out banknotes with the long side of the banknote as the leading edge and trailing edge, the preliminary sending means is the banknote In some cases, it is difficult to provide a short side length.

  As another problem, in the above-described conventional example, the preliminary feeding means is provided in the reverse feeding direction of the pickup roller, and the uppermost paper sheet is moved to a predetermined feedable position by the preliminary feeding means. In the case of feeding, the pickup roller is configured not to contact the paper sheet. In such a configuration, since the distance between the leading edge of the paper sheet and the position where the feeding force is applied by the preliminary feeding means becomes long, the paper sheet can be folded when it is sent to a predetermined feeding position. Some banknotes and paper sheets with low rigidity are likely to be deformed by buckling and cannot be normally fed out.

  An object of the present invention is to provide a paper sheet separating apparatus that prevents double feeding.

The above object is a paper sheet separating apparatus that feeds out paper sheets with different dimensions in the feeding direction and having a long side as a leading edge and a trailing edge, a box for collecting the paper sheets, and a part of the outer periphery a pickup roller having a first high-friction portion, a portion of the outer periphery of the position where the synchronization with the first high-friction portion of the phase of the pickup roller, with said first high-friction portion of the pick-up roller uppermost in A feed roller having a high friction part for feeding out upper sheets, and a gate roller provided at the same axial center as the distance from the inner wall of the box to the axial center of the feed roller, wherein the gate roller sheet separation device forming the overlapping portion is arranged in a nested, the position and the high friction portion of not synchronize the feed roller pickup A roller, provided with a second high-friction portion for conveying the leading edge of the paper sheet in the overlapped portion, the conveying resistance for the gate rollers which sheet after handsome is not fed A distance between a line connecting the axis of the feed roller and the gate roller and a line connecting the axis of the pickup roller is x, a line connecting the axis of the feed roller and the gate roller and the box The distance to the inner wall on the feeding side is y, the width dimension in the feeding direction of the paper sheet storage space of the box is B, and the dimension in the feeding direction of the smallest sheet handled by this paper sheet separating mechanism is Lmin. In this case, the attachment position x of the pickup roller from the line connecting the feed roller and the gate roller is such that the value of x is equal to or greater than the value of y + B−Lmin, and Lmi It is accomplished by being disposed below a position.

Further, the above object is achieved by the fact that the conveyance resistance is formed by the non-rotation of the gate roller in the feeding direction .

  ADVANTAGE OF THE INVENTION According to this invention, the paper sheet separator which prevented double feeding can be provided.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a side view of a paper sheet separating apparatus including an embodiment of the present invention.
In FIG. 1, reference numeral 1 denotes a paper sheet separating apparatus. A pickup roller 102 serves as a feeding unit that applies a feeding force to the uppermost paper sheet 101A of the stacked paper sheets 101 during feeding. Reference numeral 103 denotes a feed roller as a conveying unit that applies a conveying force to the fed paper sheet. Reference numeral 104 denotes a gate roller as conveyance resistance means for applying conveyance resistance to the sheets in order to prevent a plurality of sheets from being fed out simultaneously. Reference numeral 105 denotes a conveyance roller for conveying the paper sheets fed out one by one to the downstream side. A stacking unit 106 has a function of stacking stacked sheets and pressing the sheet 101 against the pickup roller 102 during separation. Reference numeral 107 is a box 107 for collecting paper sheets.

  The pickup roller 102 and the feed roller 103 have high friction portions 102A and 103A, part of the outer periphery of which is made of a rubber material. The phase of these high friction portions has no problem with the paper sheet during feeding. It is adjusted to synchronize as it is fed out. In addition, the peripheral speed of the outer peripheral portion of the pickup roller 102 and the peripheral speed of the outer peripheral portion of the feed roller 103 are approximately the same. Further, the pickup roller 102 and the feed roller 103 are configured to rotate synchronously when driving force is transmitted from a driving source (not shown) by a driving mechanism including a gear, a belt, etc. (not shown). These pickup roller 102 and feed roller 103 are driven so as to be rotatable in both directions. For example, when the drive source is a stepping motor, the rotation direction is changed by designating the rotation direction of the stepping motor by a control unit (not shown).

FIG. 2 is a front view of a paper sheet separating and accumulating apparatus equipped with an embodiment of the present invention.
In FIG. 2, the gate roller 104 is arranged between the feed rollers 103 so as to be nested in the feed roller. In the sheet separating and accumulating apparatus 1 according to the present embodiment, four feed rollers 103 are arranged in the axial direction of the shaft 108. Further, in the axial direction of the shaft 109, two gate rollers 104 are arranged so as to overlap the feed roller 103. The gate roller 104 is attached to the shaft 109 via a one-way clutch 111 and is configured to rotate in the paper sheet stacking direction but not in the paper sheet feeding direction. .

FIG. 3 is a view showing a state in which paper sheets have entered between the gate roller and the feed roller.
In FIG. 3, when the paper sheet 110 passes through the feed roller 103, the waveform is deformed. The conveying force that the feed roller 103 acts on the paper sheet during feeding is a frictional force between the feed roller 103 and the paper sheet that is generated by the deformation force caused by the waveform deformation generated on the paper sheet. The amount of overlap depends on the rigidity of the paper sheet to be handled, the elasticity of the gate roller 104 in the radial direction (pressure characteristics), the dimension between adjacent feed rollers, the width dimension of the gate roller 104, and the like. It is set to become.

Next, the position of the pickup roller in the paper sheet separating apparatus of this embodiment will be described with reference to FIG.
FIG. 4 is a side view of the paper sheet separating apparatus.
In FIG. 4, the distance between the line connecting the axis center of the feed roller 103 and the gate roller 104 and the line connecting the axis center of the pickup roller 102 is x, and the line connecting the axis center of the feed roller 103 and the gate roller 104 and the box 107 The distance to the inner wall on the feeding side is y, the width dimension in the feeding direction of the paper sheet storage space of the box is B, and the dimension in the feeding direction of the smallest sheet handled by this paper sheet separation mechanism is Lmin. In this case, the attachment position x of the pickup roller 102 from the line connecting the feed roller 103 and the gate roller 104 is disposed at a position where the value of x is equal to or greater than the value of y + B−Lmin. As shown in FIG. 4, this is a position where the feeding force does not act on the second and subsequent sheets even when the smallest dimension sheet is shifted to the maximum in the anti-feeding direction. Further, the maximum value of the installation position x of the pickup roller 102 is less than or equal to Lmin. This is a position where the feeding force does not act on the second and subsequent sheets even when the smallest size sheet is maximally shifted to the feeding side.

  Next, the diameters of the pickup roller 102 and the feed roller 103 and the dimensions of the high friction portion in this embodiment will be described with reference to FIG.

FIG. 5 is a diagram showing the shapes of the pickup roller and the feed roller.
In FIG. 5, as described above, in the paper sheet separating apparatus in this embodiment, the diameters Df and Dp of each roller are determined so that the peripheral speeds of the feed roller 103 and the pickup roller 102 are the same. Further, the length of the high friction portion 103A of the feed roller 103 is Rf, and the length of the high friction portion 102A at the position synchronized with the high friction portion 103A of the feed roller 103 among the high friction portions of the pickup roller 102 is Rp1. When the length of the high friction portion 102B at the position where it is not taken is Rp2, Rf and Rp1 have substantially the same dimensions. Further, the dimension of Rp1 is set to be a value that does not exceed the value of 2Lmin-y-B. This is a position where the high friction portion 102A does not apply a feeding force to the second and subsequent sheets. Furthermore, the length Rp2 of the high friction portion 102B of the pickup roller 102 is also set to a value that does not exceed the value of 2Lmin−y−B. Note that the dimensions of Rf and Rp1 are larger than the distance z between the line connecting the shaft centers of the feed roller 103 and the sheet roller 104 and the position of the adjacent downstream conveying roller.

FIG. 6 is a diagram for explaining the operations of the pickup roller and the feed roller during separation.
In FIG. 6, when performing the separation operation, the stacking table 106 is once lowered and controlled so that the uppermost sheet 101 </ b> A does not contact the pickup roller 102. As the pickup roller 102 and the feed roller 103 are rotated, the position is adjusted. The position to be adjusted is a position where the high friction portion 102B of the pickup roller first contacts the paper sheet when the pickup roller 102 and the feed roller 103 rotate in the paper feeding direction. For this phase control, the position of the phase plate 112 attached to the shaft 108 shown in FIG. 2 is detected by a sensor (not shown), and the drive source (not shown) is stopped based on this signal.
Next, the stacking table 106 moves upward and stops when the paper sheet 101 is pressed against the pickup roller 102 with a predetermined pressure. The pressure is detected by detecting the pressure or a position corresponding to the pressure with a pressure detection sensor (not shown). The loading platform 106 is stopped by stopping a driving source (not shown) based on the detected pressure signal.

FIG. 7 is a diagram illustrating the subsequent movement of the pickup roller and the feed roller.
In FIG. 7, the conveying roller 105 is driven to rotate in the paper feeding direction as indicated by an arrow. At this time, when the minimum size paper sheet is shifted to the maximum in the reverse feeding direction, it is conveyed by the high friction portion 102B of the pickup roller 102 to the vicinity of the overlap portion formed by the feed roller 103 and the gate roller 104. When the paper sheets are not shifted to the maximum extent, the paper sheets are transported to the overlap part by the high friction part 102B, but the transport force of the high friction part 102B is the same even if the paper sheets enter the overlap. Since the material of the feed roller 103 is determined so that the conveyance force received from other than the high friction part of the feed roller is extremely small, and the value is set to be smaller than the conveyance resistance force by the gate roller, Leaves are not drawn out from the overlap part. At this time, the distance z between the line connecting the shaft centers of the feed roller 103 and the gate roller 104 and the position of the downstream transport roller does not cause the paper sheet to be caught in the transport roller 105 even in the above case. Is set to Further, in the above-described case, the material and pressure of the high friction portion are set so that the conveying force by the high friction portion 102B has a value that does not cause buckling deformation in the paper sheet to be handled.

FIG. 8 is a diagram illustrating the movement of the pickup roller and the feed roller when the uppermost sheet is on the feeding direction side.
In FIG. 8, as described above, even when the uppermost paper sheet has the maximum size or when the uppermost paper sheet is on the feeding direction side, the conveyance force of the high friction portion 102B is as described above. Is set so as to be a small value, it is not drawn out greatly beyond the overlap portion and does not buckle the paper sheets.

  FIG. 9 is a diagram illustrating the movement of the pickup roller and the feed roller when the high friction portion of the pickup roller that is synchronized with the high friction portion of the feed roller contacts the uppermost sheet and applies a conveying force.

  In FIG. 9, the pickup roller 102 and the feed roller 103 rotate, and this time, the pickup roller high friction portion 102 </ b> A synchronized with the high friction portion 103 </ b> A of the feed roller 103 comes into contact with the uppermost sheet and applies a conveying force. The uppermost sheet is fed to the transport roller 105 by the transport force of the high friction portion 102A and the high friction portion 103A of the feed roller 103. At this time, even if the second and subsequent sheets are taken out at the same time as the first sheet, the second and subsequent sheets are not fed out by the conveyance resistance force of the gate roller 104.

  Even when the uppermost paper sheet has the maximum dimension or when the uppermost paper sheet depends on the feeding direction side, as described above, the conveying force of the high friction portion 102B is a small value. Therefore, the paper sheet is not drawn far beyond the overlap portion and does not buckle the paper sheets.

FIG. 10 is a view showing another embodiment of the paper sheet separating apparatus.
In FIG. 10, in the paper sheet separating apparatus 2, a pick-up roller 202 serving as a feeding means that applies a feeding force to the uppermost paper sheet 201A of the stacked paper sheets 201 during feeding, and a paper sheet to be fed out. A feed roller 203 as a conveying means for imparting a conveying force to the sheet, and a gate roller 204 as a conveying resistance means for imparting a conveying resistance to the sheets in order to prevent a plurality of sheets from being fed out simultaneously. , A transport roller 205 for transporting the fed paper sheets one by one to the downstream side, and a function of loading the stacked paper sheets and pressing the paper sheets 201 against the pickup roller 202 during separation It is composed of a loading table 206 and a box 207 for collecting paper sheets.

  The pickup roller 202 and the feed roller 203 are dimensioned so that the pickup roller 202 rotates twice while the feed roller 203 rotates once. The pickup roller 202 and the feed roller 203 are configured so that a driving force is transmitted from a driving source (not shown) by a driving mechanism including a gear or a belt (not shown) so that the pickup roller 202 rotates in synchronization. Although the peripheral speed of the outer peripheral portion and the peripheral speed of the outer peripheral portion of the feed roller 203 are the driving mechanism that is an angular speed that is substantially the same. These pickup roller 202 and feed roller 203 are driven so as to be rotatable in both directions. For example, when the drive source is a stepping motor, the rotation direction is changed by designating the rotation direction of the stepping motor by a control unit (not shown).

  The pickup roller 202 and the feed roller 203 have high friction portions 202A and 203A, part of the outer periphery of which is made of a rubber material. The phase of these high friction portions is the same as that of the pickup roller 202 rotating twice. Once, adjustment is made to synchronize with the high friction portion 203A of the feed roller 203 so that the paper sheet is fed out without any problem at the time of feeding.

  In the paper sheet separating and accumulating apparatus according to the present invention, as shown in FIG. 2, the gate roller 204 is disposed between the feed rollers 203 so as to be nested in the feed rollers as in the case of the first embodiment. This is called the overlap method. The gate roller 204 is attached to the shaft 209 via a one-way clutch, and is configured to rotate in the paper sheet stacking direction but not in the paper sheet feeding direction. With this configuration, when the paper sheet passes through the feed roller 203, the waveform is deformed as shown in FIG. The conveying force that the feed roller 203 acts on the paper sheet during feeding is a frictional force between the feed roller 203 and the paper sheet that is generated by the deformation force generated by the waveform deformation generated on the paper sheet. The amount of overlap depends on the rigidity of the paper sheet to be handled, the elasticity of the gate roller 204 in the radial direction (pressure characteristics), the dimension between adjacent feed rollers, the width dimension of the gate roller 204, etc. It is set to become.

FIG. 11 is a diagram illustrating the pickup roller position in the paper sheet separating apparatus according to the present embodiment.
In FIG. 11, the distance between the line connecting the axis center of the feed roller 203 and the gate roller 204 and the line connecting the axis center of the pickup roller 202 is x, the line connecting the axis center of the feed roller 203 and the gate roller 204 and the box 207. The distance to the inner wall on the feed side is y, the width dimension in the feed direction of the paper sheet storage space of the box is B, and the dimension in the feed direction of the smallest sheet handled by this paper sheet separation mechanism is Lmin. In this case, the attachment position x of the pickup roller 202 from the line connecting the feed roller 203 and the gate roller 204 is disposed at a position where the value of x is equal to or greater than the value of y + B−Lmin. As shown in FIG. 11, this is a position where the feeding force is not applied to the second and subsequent sheets even when the smallest dimension sheet is shifted to the maximum in the anti-feeding direction. The maximum value of the installation position x of the pickup roller 202 is equal to or less than the value of Lmin. This is a position where the feeding force is not applied to the second and subsequent sheets even when the smallest size sheet is maximally shifted to the feeding side.

  FIG. 12 is a diagram for explaining the diameters of the pickup roller and the feed roller and the dimensions of the high friction portion in the present embodiment.

  In FIG. 12, as described above, in the paper sheet separating apparatus in this embodiment, the diameters Df2 and Dp2 of each roller are determined so that the peripheral speeds of the feed roller 203 and the pickup roller 202 are the same. Further, when the length of the high friction portion 203A of the feed roller 203 is Rf2 and the length of the high friction portion 202A of the pickup roller 202 is Rp3, Rf2 and Rp3 have substantially the same dimensions. The dimension of Rp3 is set to a value that does not exceed the value of 2Lmin-y-B. This is a position where the high friction portion 202A does not apply a feeding force to the second and subsequent sheets.

FIG. 13 is a diagram for explaining the operation at the time of separation according to the present embodiment.
In FIG. 13, when the separation operation is performed, the stacking table 206 is once lowered, and control is performed so that the uppermost sheet 201 </ b> A does not contact the pickup roller 202. Thereafter, the pickup roller 202 and the feed roller 203 are rotated to adjust the position. The position to be adjusted is that when the pickup roller 202 and the feed roller 203 are rotated in the paper feeding direction, the high friction portion 202A of the pickup roller first contacts the paper and first overlaps the paper leaf. The high friction portion 203A of the feed roller 203 does not synchronize with the pickup roller 202A even if the feed roller 203 is conveyed. For the phase control for this purpose, the position of a phase plate (not shown) attached to the shaft 208 is detected by a sensor (not shown) as in the case of the phase plate 112 attached to the shaft 108 shown in FIG. Position control is performed by stopping a drive source (not shown).

  Next, the stacking table 206 moves upward and stops when the paper sheet 201 is pressed against the pickup roller 202 with a predetermined pressure. The pressure is detected by detecting the pressure or a position corresponding to the pressure with a pressure detection sensor (not shown). The loading table 206 is stopped by stopping a driving source (not shown) based on the detected pressure signal.

  As shown in FIG. 14, thereafter, the pickup roller 202, the feed roller 203, and the transport roller are rotationally driven in the sheet feeding direction as indicated by arrows. At this time, as shown in FIG. 14, when the paper sheet of the minimum size is shifted to the maximum in the reverse feeding direction, the overlap formed by the feed roller 203 and the gate roller 204 by the high friction portion 202 </ b> B of the pickup roller 202. It is conveyed to the vicinity of the part. When the paper sheets are not shifted to the maximum extent, the paper sheets are transported to the overlap part by the high friction part 202A. However, even if the paper sheets enter the overlap, the high friction part 202A is transported. Since the material of the feed roller 203 is determined so that the conveyance force received from other than the high friction part of the feed roller is extremely small, and the value is set to be smaller than the conveyance resistance force by the gate roller, Leaves are not drawn out from the overlap part. At this time, the distance z between the line connecting the axis centers of the feed roller 203 and the gate roller 204 and the position of the downstream transport roller does not cause the paper sheet to be caught in the transport roller 205 even in the above case. Is set to Further, in the above-described case, the material and pressure of the high friction portion are set so that the conveying force by the high friction portion 202A has a value that does not cause buckling deformation in the paper sheet to be handled.

  As shown in FIG. 15, the pickup roller 202 and the feed roller 203 further rotate, and this time, the pickup roller high friction portion 202A synchronized with the high friction portion 203A of the feed roller 203 comes into contact with the uppermost sheet and the conveying force. Act. The uppermost sheet is fed to the transport roller 205 by the transport force of the high friction portion 202A and the high friction portion 203A of the feed roller 203. At this time, even if the second and subsequent sheets are taken out at the same time as the first sheet, the second and subsequent sheets are not fed out by the conveyance resistance force of the gate roller 204.

  Even when the uppermost paper sheet has the maximum dimension or when the uppermost paper sheet depends on the feeding direction side, as described above, the conveying force of the high friction portion 202A is a small value. Therefore, the paper sheet is not drawn out greatly beyond the overlap portion, and the paper sheets are not buckled.

  As described above, the present invention relates to an apparatus for handling paper sheets such as banknotes, and more particularly to a separation mechanism that separates and feeds paper sheets stored or stacked in a bundled state one by one. Effective for banknotes of different sizes.

As described above, the present invention
1. Conveying means for imparting a conveying force to the accumulated paper sheets, a conveying resistance means for imparting a conveying resistance force to the paper sheets, a stacking means for stacking the paper sheets, and a high friction on a part of the outer periphery A feed roller having a member, a pickup roller having a high friction member on a part of the outer periphery thereof, a gate roller having an outer periphery made of a high friction member, a gate portion composed of the feed roller and the gate roller, and the gate portion A paper sheet separating apparatus including a transport unit configured to transport the paper sheet that is fed out to a downstream portion; the paper sheet separating apparatus includes a first unit that is in phase with the position of the high friction member of the feed roller when the paper sheet is fed out. A second high friction portion is provided on the pickup roller at a position not synchronized with the one high friction portion and the feed roller high friction portion.
2. X is the distance from the gate position composed of the feed roller and the gate roller to the position where the pickup roller contacts the sheets stacked on the loading table, and the downstream position in the hopper portion feeding direction from the gate position , Y is the distance to the sheet storage portion of the hopper, B is the length in the feeding direction, and Lmin is the dimension of the shortest feeding direction in the feeding direction. The pickup roller is provided at a position where the value is equal to or greater than y + B−Lmin.
3. X is the distance from the gate position composed of the feed roller and the gate roller to the position where the pickup roller contacts the sheets stacked on the loading table, and the downstream position in the hopper portion feeding direction from the gate position Y is the distance to the sheet storage portion of the hopper, B is the length in the feeding direction, Lmin is the dimension of the shortest feeding direction in the feeding direction, and Lmin is the first of the pickup rollers. When the length of the high friction part is Rp1, the length of the second high friction part is Rp2, and the length of the high friction part of the feed roller is Rf, the value of x is equal to or greater than the value of y + B−Lmin. In addition, a pickup roller is provided, and Rp1 and Rf are substantially the same size, the size of Rp1 is not less than y and not more than the value of Lmin−x, and the size of Rp2 is not more than x. Those were.
4). A pickup roller having a diameter approximately half the diameter of the feed roller and rotating at the same double rotational speed and having a high friction member on a part of the outer periphery thereof, and the outer periphery thereof being high. A gate roller made of a friction member; a conveying means provided on the downstream side of the gate portion composed of the feed roller and the gate roller; and for conveying the paper sheet fed from the gate portion further to the downstream portion; and the pickup The roller is provided with a high friction portion at a synchronized position so that the paper sheet can be fed out once in two rotations of the position of the high friction member of the feed roller when the paper sheet is fed out, The distance from the gate position constituted by the gate roller to the position where the pickup roller contacts the sheets stacked on the loading table is x, and the distance from the gate position to the front. The distance to the downstream position in the hopper portion feeding direction is y, the feeding direction length of the paper sheet storage portion of the hopper portion is B, and the dimension of the shortest feeding direction length among the fed paper sheets is Lmin. In this case, a pickup roller is provided at a position where the value of x is equal to or greater than the value of y + B−Lmin.
5. X is the distance from the gate position composed of the feed roller and the gate roller to the position where the pickup roller contacts the sheets stacked on the loading table, and the downstream position in the hopper portion feeding direction from the gate position Y is the distance to the paper sheet storage portion of the hopper, B is the length in the feeding direction, Lmin is the dimension of the shortest feeding length in the feeding direction, and the high friction part of the pickup roller When the length of Rp is Rp and the length of the high friction portion of the feed roller is Rf, a pickup roller is provided at a position where the value of x is equal to or greater than the value of y + B-Lmin. Also, the Rp1 and Rf are substantially the same. The dimension Rp is not less than y and not more than the value of Lmin−x.

  As a result, the present invention allows the paper sheets to be fed out by feeding the bills mixed long and short, before the leading edge position of the paper sheets is fed out by the high friction portion of the pickup roller that is not synchronized with the high friction portion of the feed roller. If the leading edges of the banknotes are not aligned with respect to the gate part in the feeding part, it is possible to prevent double feeding caused by feeding the second banknote and entering the gate part without feeding the top banknote during feeding. .

It is a figure explaining the paper sheet separation mechanism provided with one Example of this invention. It is a figure explaining the overlap part of the paper sheet separation mechanism provided with one Example of this invention. It is a figure explaining the deformation | transformation state of paper sheets at the time of paper sheet separation provided with one Example of this invention. It is a figure explaining various dimensions of a paper sheet separation mechanism provided with one example of the present invention. It is a figure explaining each roller dimension of the paper sheet separation mechanism provided with one example of the present invention. It is a figure explaining the feeding operation | movement of the paper sheet separation and accumulation mechanism provided with one Example of this invention. It is a figure explaining the feeding operation | movement of the paper sheet separation and accumulation mechanism provided with one Example of this invention. It is a figure explaining the feeding operation | movement of the paper sheet separation and accumulation mechanism provided with one Example of this invention. It is a figure explaining the feeding operation | movement of the paper sheet separation and accumulation mechanism provided with one Example of this invention. It is a figure explaining the paper sheet separation mechanism provided with the other Example of this invention. It is a figure explaining the various dimensions of the paper sheet separation mechanism provided with the other Example of this invention. It is a figure explaining each roller dimension of the paper sheet separation mechanism provided with the other Example of this invention. It is a figure explaining the delivery operation | movement of the paper sheet separation and accumulation mechanism provided with the other Example of this invention. It is a figure explaining the delivery operation | movement of the paper sheet separation and accumulation mechanism provided with the other Example of this invention. It is a figure explaining the delivery operation | movement of the paper sheet separation and accumulation mechanism provided with the other Example of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Paper sheet separation apparatus, 101 ... Paper sheet, 102 ... Pick-up roller, 103 ... Feed roller, 104 ... Gate roller, 105 ... Conveyance roller, 106 ... Loading table, 107 ... Storage box, 108 ... Shaft, 109 ... Shaft, 110 ... conveying guide, 111 ... one-way clutch, 112 ... phase plate, 2 ... paper sheet separator, 201 ... paper sheet, 202 ... pickup roller, 203 ... feed roller, 204 ... gate roller, 205 ... conveying roller 207 206 Loading table 207 Storage box 208 Shaft 209 Shaft 210 Transport guide 211 211 One-way clutch

Claims (2)

A paper sheet separating apparatus for feeding out paper sheets in a posture in which the dimensions in the feeding direction are different and the long side is the leading edge and the trailing edge,
The box for accumulating the paper sheets, a pickup roller having a first high friction part on a part of the outer periphery, and a part of the outer periphery at a position synchronized with the phase of the first high friction part of the pickup roller. A feed roller having a high friction part for feeding the uppermost paper sheet together with the first high friction part of the pickup roller, and an axial center equal to the distance from the inner wall of the box to the axial center of the feed roller And a gate roller provided in
In the paper sheet separating apparatus in which the feed roller and the gate roller are arranged in a nested state to form an overlap portion,
A second high friction part for conveying the leading edge of the paper sheet to the overlap part is provided in the pickup roller at a position not synchronized with the high friction part of the feed roller ,
The gate roller has a conveyance resistance for preventing the second and subsequent sheets from being fed out .
The distance between the line connecting the axis center of the feed roller and the gate roller and the line connecting the axis center of the pickup roller is x, the line connecting the axis center of the feed roller and the gate roller and the inner wall on the feeding side of the box The pickup distance is Y, the width dimension in the feeding direction of the paper sheet storage space of the box is B, and the minimum feeding dimension of the paper sheet handled by this paper sheet separating mechanism is Lmin. A paper sheet , wherein the attachment position x of the roller from the line connecting the feed roller and the gate roller is arranged at a position where the value of x is not less than y + B−Lmin and not more than Lmin. Separation device. In the paper sheet separating apparatus according to claim 1,
The paper sheet separating apparatus according to claim 1, wherein the conveyance resistance is formed by the non-rotation of the gate roller in a feeding direction.

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