1. Field of the Invention
The present invention relates to a paper sheets corner fold detection method and a paper sheets corner fold detection program for surely detecting a minute corner fold arising in the corner part of a paper sheet in a paper sheets processor as an end part corner fold of the paper sheet without misidentifying it as a mending or a break, and separately accommodating the paper sheet wherein the corner fold arises in an accommodation part so that double feed is not caused by the corner fold in the next running-out time.
2. Description of the Related Art
Conventionally, there has been a paper sheets processor for automatically accommodating paper sheets. As a representative example, there is an automated-teller machine, which is installed in banks, post offices, convenience stores and the like, and which automatically performs processes such as accommodating deposit banknotes inserted from outside into a banknote pay-in/out slot or paying withdrawal banknotes.
In such an automated-teller machine, when a customer inserts banknotes into the banknote pay-in/out slot of the automated-teller machine, the inserted banknotes are provided with image recognition by a judgment part in the middle of a carrying route, and then automatically provided with denomination identification and other necessary judgment processes. After that, the number of the banknotes is counted, and then the banknotes are accommodated in a given banknote accommodation vessel.
Further, when a customer withdraws a desired amount of money, the customer inputs intention of cash withdrawal and the withdrawal amount of money from an input operation panel of the automated-teller machine. After that, banknotes corresponding to the desired amount of money are paid out from the banknote pay-in/out slot.
Then, the number of paid-out banknotes is counted while the banknotes are run out from the foregoing banknote accommodation vessel, and carried on the carrying route connected to the banknote pay-in/out slot. However, in this process, there has been a large problem.
First, deposit banknotes inserted into the banknote pay-in/out slot of the automated-teller machine are not always inserted into the banknote pay-in/out slot in a state that all the banknotes are orderly folded out. Some customers roughly insert a banknote wherein a fold arises in the corner part without correctly folding out the corner fold. Apart from the inserted banknote is a forged banknote, in case of the inserted banknote is a true banknote, it is not possible to return the true banknote to the customer (carry back to the banknote pay-in/out slot) due to just the corner fold. That is, the banknote with the corner fold is accommodated as it is.
Aside from a large corner fold, such a relatively small corner fold as above arises in a margin in an edge part wherein no printing is provided. Therefore, the corner fold cannot be recognized by color. When trial is made to determine the corner fold by image recognition based on measurement by the judgment part, it is difficult to determine whether the corner part is torn or folded. Therefore, in any event, such a small corner fold is ignored as a very small defect, and accommodated in the banknote accommodation vessel as it is.
However, if the foregoing corner fold arises in the banknote, when banknotes are run out from the banknote accommodation vessel and paid out through the banknote pay-in/out slot in banknote withdrawal, or when the number of banknotes is counted while the banknotes are run out from the banknote accommodation vessel after, for example, the banknote accommodation vessel is taken out from the automated-teller machine for replacement and returned back to a home office, troubles have been often caused in the banknote automated counter.
When such a double feed running-out is caused, there has been a problem that a carrying jam is caused on the carrying route leading to stop of the automated-teller machine, or a trouble in operation of the process for measuring the number of accommodated banknotes in the home office of the banck.
In view of the foregoing conventional actual circumstances, it is a task of the invention to provide a paper sheets corner fold detection method and a paper sheets corner fold detection program capable of surely detecting a minute corner fold arising in the corner part of a paper sheet, and accommodating the paper sheet in an accommodation part so that double feed is not caused by the corner fold in the next paper sheets running-out time.
First, a paper sheets corner fold detection method in an embodiment of the invention is a paper sheets corner fold detection method in a paper sheets processor, comprising: a carrying-in sensor part for being started by input operation from outside to a transaction start switch part and detecting insertion of a paper sheet inserted from outside for transaction; a light sensor part for detecting light reflective characteristics or light transmissive characteristics of the paper sheet, which passes the carrying-in sensor part and is carried; and a thickness sensor part for detecting a thickness change of the paper sheet, which passes the carrying-in sensor part and is carried, comprising:
an image processing step for image-processing a detection output value from the light sensor part by an image processing part;
an image corner fold determination step for determining whether a corner fold exists or not in the front end part or the back end part of the paper sheet in the carrying direction based on image data processed by the image processing step;
a thickness corner fold determination step for determining whether a corner fold exists or not in the front end part or the back end part of the paper sheet in the carrying direction based on a detection output value from the thickness sensor part; and
a paper sheets corner fold determination step for determining whether a corner fold exists or not in the front end part or the back end part of the paper sheet in the carrying direction based on the image corner fold determination step and the thickness corner fold determination step.
This paper sheets corner fold determination method further comprises a control step for controlling ejection carrying of the paper sheet so that the paper sheet is separately accommodated in a reusable accommodation part, a pre-accommodation inversion part, or an unusable accommodation part according to a region where a corner fold exists when it is confirmed that the corner fold exists in the paper sheet in the paper sheets corner fold determination step.
In this case, when the corner fold of the paper sheet confirmed in the paper sheets corner fold determination step is located in a region wherein double running-out is not caused by the corner fold when the paper sheet is run out from the reusable accommodation part in the next time, the ejection carrying is controlled so that the paper sheet is accommodated in the reusable accommodation part as it is in the control step. Further, for example, when the corner fold of the paper sheet confirmed in the paper sheets corner fold determination step is located in a region wherein double running-out may be caused by the corner fold when the paper sheet is run out from the reusable accommodation part the next time, the ejection carrying is controlled so that the paper sheet is accommodated through the pre-accommodation inversion part into the reusable accommodation part in the control step. Further, for example, when the corner fold of the paper sheet confirmed in the paper sheets corner fold determination step is located in both the front end part and the back end part of the paper sheet in the carrying direction, the ejection carrying is controlled so that the paper sheet is accommodated in the unusable accommodation part in the control step.
It is preferable that the reusable accommodation part is constructed from a stacker or a cassette.
Next, a paper sheets corner fold detection program in the embodiment of the invention is a paper sheets corner fold detection program for making a computer execute a paper sheets corner fold detection process in a paper sheets processor, comprising: a carrying-in sensor part for being started by input operation from outside to a transaction start switch part and detecting insertion of a paper sheet inserted from outside for transaction; a light sensor part for detecting light reflective characteristics or light transmissive characteristics of the paper sheet, which passes the carrying-in sensor part and is carried; and a thickness sensor part for detecting a thickness change of the paper sheet, which passes the carrying-in sensor part and is carried, which makes the computer execute:
a process for image-processing a detection output value from the light sensor part by an image processing part;
an image corner fold determination process for determining whether a corner fold exists or not in the front end part or the back end part of the paper sheet in the carrying direction based on image data processed by the said process;
a thickness corner fold determination process for determining whether a corner fold exists or not in the front end part or the back end part of the paper sheet in the carrying direction based on a detection output value from the thickness sensor part; and
a paper sheets corner fold determination process for determining whether a corner fold exists or not in the front end part or the back end part of the paper sheet in the carrying direction based on the image corner fold determination process and the thickness corner fold determination process.
This paper sheets corner fold detection program further makes the computer execute a control process for controlling ejection carrying of the paper sheet so that the paper sheet is separately accommodated in a reusable accommodation part, a pre-accommodation inversion part, or an unusable accommodation part according to a region where a corner fold exists when it is confirmed that the corner fold exists in the paper sheet in the paper sheets corner fold determination process.
In this case, the paper sheets corner fold detection program makes the computer execute a process for controlling the ejection carrying so that the paper sheet is accommodated in the reusable accommodation part as it is in the control process when the corner fold of the paper sheet confirmed in the paper sheets corner fold determination process is located in a region wherein double running-out is not caused by the corner fold when the paper sheet is run out from the reusable accommodation part the next time. Further, for example, the paper sheets corner fold detection program makes the computer execute a process for controlling the ejection carrying so that the paper sheet is accommodated through the pre-accommodation inversion part into the reusable accommodation part in the control process when the corner fold of the paper sheet confirmed in the paper sheets corner fold determination process is located in a region wherein double running-out may be caused by the corner fold when the paper sheet is run out from the reusable accommodation part in the next time. Further, for example, the paper sheets corner fold detection program makes the computer execute a process for controlling the ejection carrying so that the paper sheet is accommodated in the unusable accommodation part in the control process when the corner fold of the paper sheet confirmed in the paper sheets corner fold determination process is located in both the front end part and the back end part of the paper sheet in the carrying direction.
As described above, according to the invention, paper sheets are measured by combining the light sensor and the thickness sensor. Therefore, an actual corner fold and a region thereof are surely detected by discriminating the corner fold from a mending place which is easily misidentified as a corner fold by the thickness sensor and discriminating the corner fold from a break place which is easily misidentified as a corner fold by the light sensor. Thereby, waste of misidentifying as a corner fold and subsequently performing useless processes is avoided. Further, it becomes possible to easily address a trouble which might be caused by the actual corner fold.
Further, even a minute corner fold and a region where the corner fold arises are surely detected. Therefore, when there is the corner fold on the end side wherein double feed might be caused when the paper sheet is run out from an accommodation part in the next time, it is possible to perform inversion of orientation of the corner fold paper sheet before the paper sheet is accommodated in the accommodation part. Thereby, double feed in the next running-out time from the accommodation part is not caused, cause of a trouble such as jam during carriage is resolved, and operation efficiency of the paper sheets processing is improved.
Descriptions will be hereinafter given of an embodiment of the present invention with reference to the drawings.
The paper sheets processor 24 shown in the same figure comprises an input operation panel switch part 25 on the top thereof which is located on the front of the processor (right in the figure) and is formed aslope slightly. In the paper sheets processor 24, a pay-in/out slot 26, through which customers pay in or out paper sheets from outside, a pay-in/out part 27 linked with this pay-in/out slot 26, a pool part 28 interlinked with this pay-in/out part 27 through a paper sheets carrying route shown by a dotted line in the figure, a judgment part 29, an inversion control part 30, a reject box 33, a paper sheets accommodation part 34, a paper sheets accommodation part 35, a clerk vessel 36, a clerk vessel 37, and a central processor 38 are provided.
The foregoing input operation panel switch part 25 is a man-machine interface between a customer and the paper sheets processor 24. The input operation panel switch part 25 comprises an input switch, with which a customer inputs intention that the customer is to make transaction of paper sheets such as withdrawal or deposit of the paper sheets. The input switch can be, for example, a button switch arranged in the vicinity of an display device (not shown in the figure) or can be a touch type input device arranged by being superimposed on the display device.
The foregoing paper sheets accommodation parts 34 and 35 are constructed from a stacker, a cassette or the like for accommodating reusable paper sheets among paper sheets inserted from the pay-in/out slot 26 by customers.
Further, in linkage parts between the carrying route shown by dotted lines of the figure and the respective component parts, switching devices not shown in the figure are respectively arranged. These switching devices can switch carrying directions to the direction to pass the paper sheet in the middle of carriage or the direction to accommodate the paper sheet in the middle of carriage into the component part under the control of the central processor 38.
As a whole, a construction and functions of the paper sheets processor 24 in this example are different from those of conventionally known paper sheets processors in terms of an internal construction of the judgment part 29, an arrangement of the inversion control part 30, and processing contents of the central processor 38, which will be described later in detail.
In
When the number of paper sheets or an amount of money counted during the foregoing takeoff corresponds with the number of paper sheets or an amount of money input from the input operation panel switch part 25 by a customer, the paper sheets temporarily accommodated in the pool part 28 are taken off one by one from the inferior part of the pool part 28, and carried to the judgment part 29 as indicated by arrow b of the figure. Authenticity, stain, a corner fold and the like thereof are determined while the paper sheets pass through the judgment part 29. The determination result by this judgment part 29 is notified to the central processor 38.
The central processor 38 carries the paper sheet which passed the judgment part 29 after inversing the paper sheet by using a switchback mechanism, not particularly shown in the figure, of the inversion control part 30 as indicated by arrows d and e if the paper sheet needs to be inverted based on the foregoing notification in the middle of carriage on the carrying route as indicated by arrows c, f, g, h, i, or k. In the meantime, if the paper sheet is a forged paper sheet, the central processor 38 carries back the paper sheet from the arrow f through arrow s to the pay-in/out part 27.
Further, when the foregoing notification shows that the paper sheet is not a forged paper sheet, but has a large stain or the like, which might cause troubles in future usage, and therefore, the paper sheet needs to be changed to usable other paper sheet, the paper sheet is also carried back from the arrow f through the arrow s to the pay-in/out part 27.
When paper sheets accommodated in the paper sheets accommodation part 34 or 35 are judged by passing them through the judgment part 29 in batch processing, the central processor 38 carries the paper sheet from the arrow f through the arrow g when a notification from the judgment part 29 shows that the paper sheet is a forged paper sheet. Meanwhile, regarding defective paper sheets such as forged paper sheets and paper sheets with a large stain, the central processor 38 switches the switching device of the reject box 33 to a carrying-in side to accommodate these defective paper sheets in the reject box 33, or carries these defective paper sheets back to the pay-in/out part from the arrows c and f through the arrow s as indicated in the figure.
When the paper sheets inserted into the pay-in/out part 27 by the customer as above pass the judgment part 29, and the judgment result shows that the paper sheets are not forged paper sheets or paper sheets with a large stain, after the paper sheets required to be inverted are inverted, the central processor 38 carries the paper sheets as indicated by the arrows c, f, g, h, and i, switches the switching device to arrow j side, and accommodates the paper sheets in the paper sheets accommodation part 35, or carries the paper sheets as indicated from the arrow i through the arrow k, switches the switching device to arrow m side, and accommodates the paper sheets in the paper sheets accommodation part 34.
When the paper sheet accommodated as above is run out from the paper sheet accommodation part 34 or 35 the next time, the paper sheet is run out in the same direction as the carrying direction when accommodated as indicated by arrow n or arrow o. That is, the back part of the paper sheet in the carrying direction when accommodated becomes the back part in the carrying direction when the paper sheet is run out as it is.
Therefore, when the corner fold as shown in
An amplification circuit part 45 and an A/D conversion part 46 are connected to the foregoing carrying-in sensor part 41 in series. An output from the A/D conversion part 46 is fed back to the central processor 38. Further, an amplification circuit part 47, an A/D conversion part 48, an image processing part 51, and a corner fold determination part 49 are connected to the foregoing light sensor part 42 in series. An output from the corner fold determination part 49 is fed back to the central processor 38.
Further, an amplification circuit part 52, an A/D conversion part 53, and a corner fold determination part 54 are connected to the thickness sensor part 43 in series. An output from the corner fold determination part 54 is fed back to the central processor 38.
The reject gate part 44 controls switching of carrying routes to the reject part (reject box 33 or pay-in/out part 27), switching of carrying routes to the inversion control part 30, or switching of carrying routes to the paper sheets accommodation parts 34 and 35.
In the foregoing construction, when the central processor 38 receives an input operation event directing transaction start from the foregoing input operation panel switch part 25, the central processor 38 turns an not-shown carrying motor to start carrying paper sheets to be inserted from the pay-in/out slot 26 into the pay-in/out part 27 of
The carrying-in sensor part 41 is constructed from light reflective or light transmissive at least two single light sensors. The carrying-in sensor part 41 detects that the front end part of the paper sheet in the carrying direction is carried into the judgment part 29. This detection signal is input to the amplification circuit 45, amplified at a given ratio by the amplification circuit 45, which is output to the A/D conversion part 46. The A/D conversion part 46 converts the input paper sheet detection analog signal to a digital signal, and outputs this converted paper sheet detection digital signal to the central processor 38.
The light sensor part 42 is a line sensor constructed from a minute light sensor device array. A line length thereof corresponds to the maximum width in the direction perpendicular to the carrying direction of the paper sheet passing the judgment part 29. The light sensor part 42 segmentalizes a whole area of the paper sheet passing the judgment part 29 into minute regions, and measures the minute regions in the main scanning direction along the line direction of the sensor. Further, in sync with carrying operation of the paper sheet, the light sensor part 42 repeats the foregoing main scanning measurement in the carrying direction of the paper sheet, that is, in the sub-scanning direction.
Measurement data by this light sensor part 42 is input to the amplification circuit 47, amplified by the amplification circuit 47 at a given ratio output to the A/D conversion part 48. The A/D conversion part 48 converts the input paper sheet face measurement analog data to digital data, and outputs this converted paper sheet face measurement digital data to the image processing part 51.
The image processing part 51 provides image data of the paper sheet shown by the digital data with various image processing such as skewing correction, concentration correction, and origin correction, and outputs this digital data after image processing to the corner fold determination part 49.
Though not particularly shown, the corner fold determination part 49 comprises a memory device, in which template files for respective paper sheets are stored. The paper sheet data in this template file and the paper sheet data shown by the measured digital data are compared with each other to determine presence of a corner fold. The corner fold determination result is output to the central processor 38.
The thickness sensor part 43 is constructed from a thickness detection roller having a length corresponding to a width of an appropriate margin in addition to the maximum width in the direction perpendicular to the carrying direction of the paper sheet passing the judgment part 29, and two angle sensors arranged at both ends of the thickness detection roller. When the thickness of the paper sheet passing the judgment part 29 is changed, a slant of the foregoing thickness detection roller corresponding to the thickness change is detected (measured) by the two angle sensors as a slant variation.
The analog data obtained by measuring the thickness variation from these two angle sensors, that is, the thickness sensor part 43 is input to the amplification circuit 52, amplified at a given ratio by the amplification circuit 52, which is output to the A/D conversion part 53. The A/D conversion part 53 converts the input thickness measurement analog data to digital data, and outputs this converted thickness measurement digital data to the corner fold determination part 54.
Based on wave form of the digital data input from the A/D conversion part 53, the corner fold determination part 54 determines presence of a corner fold, and outputs the corner fold determination result to the central processor 38.
When the central processor 38 recognizes that a paper sheet is carried into the judgment part 29, based on the paper sheet detection digital signal from the carrying-in sensor part 41, which is input through the A/D conversion part 46, the central processor 38 activates the light sensor part 42 and the thickness sensor part 43, and performs sampling of sensor measurement data for the required number of times.
The sampling data of the light sensor part 42 and the thickness sensor part 43 are, as described above, amplified at the amplification circuits, converted to digital data at the A/D converters, and finally input to the central processor 38 as a corner fold determination result through the corner fold determination parts 49 and 54 respectively. Based on the input corner fold determination result, the central processor 38 controls the reject gate part 44.
Based on the control from the central processor 38, the reject gate part 44 performs direction switching of the direction switching device on the carrying route to the reject part (reject box 33 or pay-in/out part 27), direction switching of the direction switching device on the carrying route to the inversion control part 30, and direction switching of the direction switching device on the carrying route to the paper sheets accommodation parts (paper sheets accommodation part 34 or 35) among the carrying direction switching devices on the carrying route of the paper sheets.
That is, when a corner fold is detected at the corner fold determination part 49 or 54, direction of the direction switching device is switched as follows: the paper sheet is carried to the reject part (33 or 27) in the case of corner folds in both ends, the paper sheet is carried to the paper sheets accommodation part (34 or 35) in the case of a corner fold only in the front end, and the paper sheet is firstly carried to the inversion control part 29 once, and then carried from the inversion control part 29 to the paper sheets accommodation part (34 or 35) in the case of a corner fold only in the back end.
Forged paper sheets or paper sheets with a large stain or the like, which might cause trouble in future usage are not herein described, since these paper sheets are not within the scope of the invention.
The foregoing carrying-out sensor part 56 detects that the back end part of the paper sheet 55 in the carrying direction is carried out from the judgment part 29 to outside (right in the figure). The carrying-in sensor part 41 and the carrying-out sensor part 56 are not necessary to be the light sensor. For example, the carrying-in sensor part 41 and the carrying-out sensor part 56 can be constructed from a sensor formed by, for example, a combination of a rotational pin and a switching circuit, which mechanically detects presence of the paper sheet 55.
Due to the construction of this light sensor part 42, the measurement part which is segmentalized into the minute regions of the paper sheet 55 measured by the light sensor 42 is detected whether it is transparent or opaque. Further, when it is opaque, luminance of the opaque part is concurrently detected, and thereby presence of a corner fold is determined as described later.
The image processing part 51 extracts an end point (upper left corner of the paper sheet 55 in this example) of the sensor raw image (left figure of
Thereby, comparative judgment with the template data becomes easy. Further, it becomes possible to easily extract the light image on the corner part of the paper sheet 55, and determine presence of a minute corner fold 60 of the paper sheet 55 as shown in
That is, an upper left corner part 61 of the original paper sheet 55 with no corner fold 60 shown in
Meanwhile,
As shown in
Then, when it is determined that the corner fold exists, based on the output of the thickness sensor part 43 (determination result of S1: Y), whether a break exists or not in the front end part of the paper sheet 55 in the carrying direction is subsequently determined, based on an output of the light sensor part 42 (S2). This process is a process for determining whether a detection output by the transmissive line light sensor 58 described in
Then, when it is determined that there is no break, that is, there is no detection output of the transmissive line light sensor 58 and there is a detection output of the reflective line light sensor 57 (determination result of S2: N), it is determined that the thickness change detected by the thickness sensor 43 in Process S1 is not caused by a corner fold, but caused by a foreign object such as a tape used for mending a break or the like adhered to the paper sheet (S3). In this case, the flow is forwarded to the next Process S8 as no corner fold.
In the case that in the foregoing Process 2, there is a break, that is, there is no detection output of the reflective line light sensor 57 and there is a detection output of the transmissive line light sensor 58 (determination result of S2: Y), it means the thickness change detected by the thickness sensor part 43 in Process S1 is a corner fold. In this case, it is determined that there is a corner fold in the front end part of the paper sheet 55 in the carrying direction (S4), and the flow is forwarded to the next Process S8.
In the foregoing Process S1, when there is no corner fold based on an output of the thickness sensor part 43 (determination result of S1: N), whether a break exists or not in the front end part of the paper sheet 55 in the carrying direction is subsequently determined by an output of the light sensor part 42 (S5). This process is also a process for determining whether a detection output by the transmissive line light sensor 58 described in
When a break exists (determination result of S5: Y), it is determined that there is a corner break in the front end part of the paper sheet 55 in the carrying direction (S6). In this case, the flow is forwarded to the next Process S8 as no corner fold.
When in the foregoing Process S5, there is no break (determination result of S5: N), it is determined that the front end part of the paper sheet 55 in the carrying direction is in a normal state that there is no corner fold (S7). The flow is forwarded to the next Process S8.
Subsequent Processes S8 to S14 are the same processes as the foregoing processes S1 to S7, except that a region wherein presence of a corner fold is determined is changed from the front end part of the paper sheet 55 in the carrying direction to the back end part of the paper sheet 55 in the carrying direction.
Thereby, when Process S10, S11, or S14 is finished, determination is established whether there is a corner fold in the front end part of the paper sheet 55 in the carrying direction, in the back end part of the paper sheet 55 in the carrying direction, or in the both end parts in the carrying direction.
Following this establishment of the determination whether a corner fold exists or not, it is determined whether the established determination represents that corner folds exist in the both end parts of the paper sheet 55 in the carrying direction or not (S15). When corner folds do not exist in the both end parts of the paper sheet 55 in the carrying direction (determination result of S15: N), this determination process is immediately finished. Meanwhile, when paper folds exist in the both end parts of the paper sheet 55 in the carrying direction (determination result of S15: Y), control is made so that this paper sheet 55 is carried to the reject part (reject box 33 or pay-in/out part 27) (S16). After that, this determination process is finished.
In
Then, when the corner fold is in a position becoming the back end part in the running-out direction next time (determination result of S102: Y), it is possible that double feed is caused at the next running out occasion as shown in
Thereby, when this paper sheet 55 with the corner fold is accommodated in the stacker of the paper sheets accommodation part 34 or 35 and run out next time, based on the foregoing orientation inversion, the corner fold part is located on the front end part in the running-out direction. Therefore, there is no possibility of double feed.
When in the Process S102, the region wherein the corner fold arises in the paper sheet 55 is not on the back end part in the running-out direction in the next time, that is, on the front end part (determination result of S102: N), there is no possibility of double feed in the next running-out time. Therefore, in this case, the flow is immediately forwarded to Process S104.
Next, processes shown in
As described above, the actual corner fold and the region where the corner fold arises are surely detected without being misidentified as a mending or a break by using the paper sheets corner fold detection method and the paper sheets corner fold detection program of the invention for the paper sheets processor. Therefore, it becomes possible to perform orientation inversion so that no trouble is caused in the subsequent processes. Further, it becomes possible to provide a highly reliable paper sheets processor with a low pause ratio, which operates stably.
In particular, round-the-clock paper sheets processors in unmanned stores have been common recently. Therefore, existence of a highly reliable paper sheets processor with a low pause ratio, which operates stably is extremely beneficial.
Further, the series of processes described above are performed on a program. Therefore, as long as a paper sheets processor comprises a light sensor and a thickness sensor, the invention is a superior technique capable of being easily applied to already shipped processors as well.
In this case, when the paper sheet processor has no space to additionally arrange a device for performing orientation inversion of corner fold paper sheets, it is possible that paper sheets with a corner fold on the end part, which might cause double feed in the next running-out occasion from an accommodation part are all accommodated in a reject part.
This application is a continuation of an International Application No. PCT/JP02/08813, which was filed on Aug. 30, 2002.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | PCT/JP02/08813 | Aug 2002 | US |
Child | 11046779 | US |