JP6322823B2 - Paper processing equipment - Google Patents

Description

  The present invention relates to a sheet processing apparatus that processes a sheet while conveying the sheet.

  2. Description of the Related Art Conventionally, there is known a paper processing apparatus that cuts paper at least in the paper transport direction when the paper is transported, and eliminates cutting waste that is no longer necessary as a result of the cutting.

  Patent Document 1 includes a plurality of slit processing units having a slit processing device capable of adjusting the position in the horizontal direction, and a cutting scrapper device provided on the downstream side of the slit processing unit and adjustable in the horizontal direction. There is disclosed a paper processing apparatus that includes a cutting scrapper that has a cut and a plurality of detection sensors that are provided in the transport direction and detect a transported paper at a predetermined position.

JP 2011-201646 A

  In the apparatus disclosed in Patent Document 1, since the detection sensor is fixed at a predetermined position, the slit processed paper that should pass through the detection range of the detection sensor is cut as an unnecessary paper by a cutting scraping device. When the sheet is excluded from the sheet conveyance path, not only the sheet excluded by the sheet detection sensor but also the sheet conveyed downstream without being excluded cannot be detected. For this reason, the control unit determines that the sheet is not normally conveyed and stops the operation of the apparatus.

  Therefore, the present invention continues to downstream on the paper transport path even when cutting waste, which is unnecessary paper, is removed from the paper transport path from paper that has been cut along the transport direction. An object of the present invention is to provide a paper processing apparatus capable of detecting a paper conveyed to the side by a paper detector.

In order to solve the above-described problems, a paper processing apparatus according to the present invention is a paper processing apparatus that processes paper that is transported one by one along a paper transport path by a transport means, and is in the middle of the paper transport path A slit processing unit that cuts the paper along the paper transport direction by a cutting blade that is provided and held by the holder, and eliminates unnecessary cutting waste from the paper cut by the cutting blade outside the paper transport path. A cutting waste removing means that is provided so as to be displaceable at a contact position that selectively contacts the cut paper and removes the cutting waste outside the paper transport path. And a paper detector that is provided downstream of the cutting waste removing means in the paper conveyance direction and detects a predetermined position within a range in the width direction of the paper conveyed on the paper conveyance path, and the slit processing unit Is A cutting blade moving means for moving the paper in the paper width direction, and the paper detector is linked to the movement in the paper width direction of the holder and remains on the paper conveyance path after the paper is cut by the cutting blade. It is installed so as to be movable in the paper width direction beyond the installation position of the cutting blade in the paper width direction to the position of the paper being conveyed to the position, and the exclusion member moves the cutting blade in the paper width direction to a position to remove the cutting waste. It is installed to be movable in the paper width direction beyond the installation position .

  In addition to the above contents, the present invention can further include the following configuration.

A detector moving means for moving (a) the paper detector in the sheet width direction, an input unit for inputting conditions related to the processing of paper, and a control unit for controlling the processing operation of the sheet, and further wherein the The control unit controls the detector moving means to move the paper detector in the paper width direction based on the processing conditions input from the input unit.

( B ) The cutting waste eliminating means includes displacement means for displacing the exclusion member between the contact position and a non-contact position where the paper conveyance path is not brought into contact with the conveyed paper.

( C ) The exclusion member is disposed on both sides of the cutting blade at a predetermined distance in the paper width direction, and the displacement means moves each exclusion member between the contact position and the non-contact position. It can be displaced independently.

( D ) The said exclusion member is connected with the downstream part of the said holder.

According to the present invention, the slit processing unit includes a cutting blade moving means for moving the holder in the paper width direction, and the paper detector is interlocked with the movement of the holder in the paper width direction, After the cutting, the sheet is continuously moved to the position of the sheet remaining on the sheet conveying path downstream and moved so as to be movable in the sheet width direction beyond the installation position of the cutting blade in the sheet width direction. Since it is installed so that it can move in the paper width direction beyond the installation position of the cutting blade in the paper width direction to the position to eliminate waste, within the paper width direction conveyance range that is continuously conveyed on the paper conveyance path after cutting waste is removed The paper detector can be easily positioned.

According to the above configuration ( a ), since the paper detector is moved in the paper width direction based on the processing conditions input from the processing condition input unit, the paper detector continues on the paper conveyance path after cutting waste is removed. It can be easily positioned within the conveyance range in the width direction of the conveyed sheet.

According to the configuration ( b ), since the displacement means for displacing the exclusion member is provided, the sheet cut by the cutting blade can be continuously conveyed on the sheet conveyance path without being excluded as cutting waste.

According to the above configuration ( c ), since the exclusion member is disposed on both sides at a predetermined distance from the cutting blade in the paper width direction, among the papers cut by the cutting blade, It can be set selectively.

According to the configuration ( d ), since the exclusion member is connected to the downstream portion of the holder, the exclusion member is easily located at a position where the cutting waste is generated as the holder moves in the paper width direction. Can do.

1 is a longitudinal sectional view schematically showing a paper processing apparatus according to a first embodiment of the present invention. It is a perspective view of the principal part of the slit processing unit in the paper processing apparatus of FIG. It is a perspective view of the cutting waste removal means in the paper processing apparatus of FIG. FIG. 2 is a perspective view of a paper detector in the paper processing apparatus of FIG. 1. FIG. 2 is a schematic explanatory view of the main part of the paper processing apparatus of FIG. 1 as viewed from above, and shows a state in which the left paper is detected by a paper detector. FIG. 2 is a schematic explanatory view of the main part of the paper processing apparatus of FIG. 1 as viewed from above, and shows a state in which the paper on the right side is detected by a paper detector. FIG. 10 is a schematic explanatory view of the main part of the sheet processing apparatus according to the modification of the first embodiment as viewed from above, and is a diagram illustrating a state in which the left sheet is detected by a sheet detector. FIG. 10 is a schematic explanatory view of a main part of a paper processing apparatus according to a modification of the first embodiment as viewed from above, and shows a state in which the paper on the right side is detected by a paper detector. It is a longitudinal cross-sectional view which shows typically the paper processing apparatus which concerns on 2nd Embodiment of this invention. FIG. 10 is a schematic explanatory view of the main part of the paper processing apparatus of FIG. 9 as viewed from above, and shows a state in which the paper on the left side is detected by a paper detector. FIG. 10 is a schematic explanatory view of the main part of the paper processing apparatus of FIG. 9 as viewed from above, and shows a state in which the paper on the right side is detected by a paper detector. FIG. 10 is a perspective view of a main part of a slit processing unit in which cutting waste removing means is integrally provided in the paper processing apparatus of FIG. 9. It is a longitudinal cross-sectional view which shows typically the paper processing apparatus which concerns on 3rd Embodiment of this invention. FIG. 14 is a schematic right side view of a slit processing unit integrally provided with cutting waste removing means in the paper processing apparatus of FIG. 13. FIG. 15 is a schematic view taken along arrow XV of a main part of the slit machining unit in which the cutting waste removing unit of FIG. 14 is provided integrally. FIG. 15 is a schematic right side view of a slit machining unit integrally provided with cutting waste removing means showing a state in which the cutting waste removing means of FIG. 14 is displaced. FIG. 17 is a schematic view taken along the arrow XVII of the main part of the slit machining unit in which the cutting waste removing means of FIG. 16 is integrally provided. It is a longitudinal cross-sectional view which shows typically the paper processing apparatus which concerns on 4th Embodiment of this invention. FIG. 19 is a schematic right side view of a periphery of a slit processing unit provided with a paper detection unit connected in the paper processing apparatus of FIG. 18. FIG. 20 is a schematic view taken along the line XX of a main part around a slit processing unit provided with the paper detection unit of FIG. 19 connected thereto; It is a longitudinal cross-sectional view which shows typically the paper processing apparatus which concerns on other embodiment of this invention.

<First Embodiment>
A paper processing apparatus according to the first embodiment of the present invention will be described with reference to FIGS.

[overall structure]
FIG. 1 is a longitudinal sectional view schematically showing a paper processing apparatus. The sheet processing apparatus 1 includes a sheet feeding unit 11 and a sheet discharge table 12 at both ends of the apparatus main body 10. The sheet feeding means 11 includes a sheet feeding table 111 and a suction conveyance belt 112 that separates and conveys the sheets S stacked on the sheet feeding table 111 one by one from the top. From the paper supply means 11 to the paper discharge tray 12, a paper transport path 21 is constituted by the transport means 2 including a plurality of transport rollers 20 that receive the paper S transported by the suction transport belt 112 and transport it to the paper discharge tray 12. Has been. The transport unit 2 transports the paper S in the direction of the arrow X1. For convenience of explanation, in the paper conveyance direction indicated by the arrow X1, the paper feeding means 11 side will be described as “upstream side” and the paper discharge tray 12 side will be described as “downstream side”. Also, description will be made assuming that the top, bottom, left, and right when the entire apparatus is viewed in the paper transport direction X1 are the top, bottom, left, and right of the apparatus and each component. On the sheet conveyance path 21, from the upstream side, a sheet front end sensor 30 that detects the leading edge of the sheet on the sheet conveyance path 21, a CCD sensor 31 that reads registration marks and barcodes formed on the sheet S, and A paper processing unit 4 that performs predetermined processing on the paper S is provided. The paper processing unit 4 includes a slit processing unit 40 as a slit processing unit that cuts the conveyed paper along the paper transport direction X1. Further, on the paper conveyance path 21, a cutting waste removing means 5 for removing unnecessary cutting waste SW from the paper S cut by the paper processing unit 4, and a cutting waste on the downstream side of the cutting waste removing means 5. The cutting waste SW is removed by the removing means 5, and a paper detection unit 9 that detects the paper S that remains on the paper transport path 21 and is continuously transported is provided.

  Further, the sheet processing apparatus 1 includes a control unit 6 that controls the operation of the entire apparatus in the apparatus main body 10, and an operation panel 70 that is electrically connected to the control unit 6 and inputs processing conditions for the sheet S is provided. The input unit 7 is provided on the surface of the apparatus main body 10. Further, the sheet processing apparatus 1 includes a trash box 13 for collecting cutting waste SW removed from the sheet conveyance path 21 at the bottom of the apparatus main body 10.

[Paper processing section]
The slit processing unit 40 of the paper processing unit 4 will be described. FIG. 2 is a perspective view of a main part of the slit machining unit.

  The slit processing unit 40 includes a cutting machine 80 having a cutting blade 801 and a holder 802 that holds the cutting blade 801. The holder 802 includes an upper holder 802A that holds the upper rotary blade 801A and a lower holder 802B that holds the lower rotary blade 801B. The cutting machine 80 sandwiches the paper transport path 21 between the upper holder 802A and the lower holder 802B. Are arranged so as to face each other. The upper rotary blade 801A and the lower rotary blade 801B are capable of cutting the paper S by being held by the holder 802 so that a part of the side surface in the paper width direction is rubbed together.

The slit processing unit 40 includes a screw shaft 401, a guide shaft 402, and a drive shaft 403 that are provided between left and right frames (not shown) of the apparatus main body 10. The drive shaft 403 is rotatably provided by a drive means (not shown) provided in the apparatus main body 10. The upper rotary blade 801A is provided on the drive shaft 403 passing through the upper holder 802A, and the lower rotary blade 801B is provided on the lower holder 802B. Are provided so as to rotate together with the respective drive shafts 403. The upper rotary blade 801A and the lower rotary blade 801B are both configured to be driven to rotate, but may be configured to drive and rotate one of them and to rotate the other.

The upper holder 802A and the lower holder 802B are each provided with a guide hole 803, and the guide shaft 402 is inserted into each guide hole 803.

Nuts 804 are provided on the upper surface of the upper holder 802A and the lower surface of the lower holder 802B, respectively. A screw shaft 401 is screwed into each nut portion 804 of the holder 802. Any one of the screw shafts 401 is rotatably provided by a driving means (not shown) provided in the apparatus main body 10, and the driving means, each screw shaft 401, each guide shaft 402, and the like. Thus, the cutting blade moving means 81 is configured. Each screw shaft 401 is connected via a drive transmission means (not shown) so as to rotate at the same speed in the same direction, and the drive transmission means is connected to the drive means of the cutting blade moving means 81. Then, the drive is transmitted to the other screw shaft 401. That is, the cutting blade moving means 81 moves the holder 802 along the guide shafts 402 in the paper width direction by rotating the screw shafts 401.

[Cutting waste removal means]
The cutting waste removing means 5 will be described. FIG. 3 is a perspective view of the cutting waste removing means as seen from the upstream side.

  The cutting waste removing means 5 includes a base portion 500 having a surface orthogonal to the paper transport direction X1, and a lower portion of the base portion 500 that is bent upstream from the base portion 500 and has a surface parallel to the paper transport direction X1. An exclusion member 50 having an exclusion portion 501 integrally formed so as to extend in the direction is provided. A groove 502 is provided from the lower part of the base 500 to the upper part of the exclusion part 501, and a bearing 503 is fitted in the groove 502. A nut portion 504 is provided on the upper portion of the base portion 500.

  The cutting waste removing means 5 includes a screw shaft 510 and a guide shaft 511 provided between left and right frames (not shown) of the apparatus main body 10. A guide shaft 511 is inserted through the guide hole 505 of the bearing 503, and a screw shaft 510 is screwed into the nut portion 504. The screw shaft 510 is rotatably provided by a driving means (not shown) provided in the apparatus main body 10, and an exclusion member moving means 51 is configured by the driving means, the screw shaft 510, and the guide shaft 511. That is, the exclusion member moving means 51 moves the exclusion member 50 along the guide shaft 511 in the paper width direction by rotating the screw shaft 510.

  A guide unit 506 that is inclined downward from the upstream side toward the downstream side and extends from the upper side of the paper transport path 21 to the lower side of the paper transport path 21 is provided at a lower portion of the exclusion unit 501. The guide unit 506 makes contact with the cutting waste SW conveyed on the paper conveyance path 21 to remove the cutting waste SW from the paper conveyance path 21 and guide it to the trash box 13.

  Further, the cutting waste removing means 5 is provided with a non-contact position where the exclusion member 50 does not contact the sheet S to be conveyed outside the area in which the sheet S is conveyed so that the exclusion member 50 does not contact the sheet S to be conveyed. By moving to the contact position, the cut paper S can be discharged to the paper discharge tray 12 without contacting the exclusion member 50.

[Paper detection section]
The paper detection unit 9 will be described. FIG. 4 is a perspective view of the sheet detection unit as seen from the downstream side.

  The paper detection unit 9 is disposed so as to face the paper conveyance path 21 and has a light receiving unit 900 disposed above the paper conveyance path 21 and a light emitting unit 901 disposed below the paper conveyance path 21. A paper detector 90 having a light receiving unit bracket 902 that holds the light receiving unit 900 and a light emitting unit bracket 903 that holds the light emitting unit 901 is provided.

  The light-receiving unit bracket 902 has a base 9020 having a surface orthogonal to the paper transport direction X1, and a surface that is bent downstream from the base 9020 and parallel to the paper transport direction X1 at both ends of the intermediate portion of the base 9020. The side part 9021 integrally formed so as to extend in the vertical direction and the lower end of the base part 9020 are bent downstream from the base part 9020 and have a plane parallel to the horizontal plane and extend in the paper transport direction. As described above, the holding portion 9022 is integrally formed. Each side portion 9021 is provided with a groove 904 extending from the upper end to the center portion. Each groove 904 is fitted with a bearing 905, and a nut portion 906 is provided above the base portion 9020. ing. A light receiving unit 900 is fixed to the lower surface of the holding unit 9022.

Further, a light receiving portion guide 907A is provided which is fixed to the lower portion of the upstream side surface of the base portion 9020, is bent downstream from the fixed portion and extends below the light receiving portion 900, and the light receiving portion guide 907A has a light emission. A light passage hole 908 is provided so as not to block light emitted from the portion 901.

  The light emitting unit bracket 903 has a configuration in which the light receiving unit bracket 902 is turned upside down, and has a base 9030 having a surface orthogonal to the paper transport direction X1 and both sides of the intermediate part of the base 9030 and downstream from the base 9030. Is bent to the downstream side from the base portion 9030 and the side portion 9031 integrally formed so as to have a surface parallel to the paper transport direction X1 and to extend in the vertical direction. And a holding portion 9032 integrally formed so as to have a surface parallel to the horizontal plane and to extend in the paper conveyance direction. Each side portion 9031 is provided with a groove 904 extending from the lower end to the center portion. Each groove 904 is fitted with a bearing 905, and a nut portion 906 is provided below the base portion 9030. ing. In addition, a light emitting unit 901 is fixed on the upper surface of the holding unit 9032.

Further, a light emitting portion guide 907B is provided which is fixed to the upper portion of the upstream side surface of the base portion 9030, is bent downstream from the fixed portion and extends above the light emitting portion 901, and the light emitting portion guide 907B has a light emission. A light passage hole 908 is provided so as not to block light emitted from the portion 901.

  In addition, the paper detection unit 9 includes a screw shaft 910 and a guide shaft 911 that are provided between left and right frames (not shown) of the apparatus main body 10. A guide shaft 911 is inserted into the guide hole 909 of each bearing 905, and a screw shaft 910 is screwed into each nut portion 906. One of the screw shafts 910 is rotatably provided by a driving means (not shown) provided in the apparatus main body 10, and the driving means, each screw shaft 910, and each guide shaft 911 Detector moving means 91 is configured. The screw shafts 910 are connected via drive transmission means (not shown) so as to rotate at the same speed in the same direction. The drive transmission means is connected to the drive means of the detector moving means 91. Then, the drive is transmitted to the other screw shaft 910. That is, the detector moving means 91 moves the paper detector 90 along the guide shafts 911 in the paper width direction by rotating the screw shafts 910.

[Control unit]
The controller 6 controls the operation of the cutting blade moving means 81 so that the cutting blade 801 is positioned at the cutting position by moving the holder 802 based on the processing conditions of the input paper S, and the exclusion member 50. Is moved, the operation of the exclusion member moving means 51 is controlled so that the guide portion 506 of the exclusion member 50 is located at a position in contact with the cutting waste SW, the paper detector 90 is moved, and the paper detector 90 is moved. In the width direction conveyance range of the sheet S that is continuously conveyed and remains on the sheet conveyance path 21 after the cutting waste SW is removed, in other words, toward the light receiving unit 900 by the sheet S that is continuously conveyed. The operation of the detector moving means 91 is controlled so as to be positioned so as to block the light emitted by 901. That is, the exclusion member 50 and the paper detector 90 are moved in conjunction with the movement of the holder 802 in the paper width direction.

When the cutting conditions are changed by changing the processing conditions, the control unit 6 moves the holder 802 in the paper width direction so that the cutting blade 801 is positioned at the cutting position, that is, the cutting blade moving means 81 is moved. Operate. Further, the respective operations of the exclusion member moving means 51 and the detector moving means 91 are interlocked with the operation of the cutting blade moving means 81 to move the exclusion member 50 and the paper detector 90 in the paper width direction. That is, since the removal member 50 and the paper detector 90 are moved in conjunction with the movement of the holder 802 in the paper width direction, the cutting waste SW can be removed even if the cutting position is changed, The cutting waste SW is eliminated, and the paper S remaining on the paper conveyance path 21 and continuously conveyed can be detected.

  Further, the control unit 6 conveys the paper S by controlling the operation of driving means (not shown) connected to the paper feed tray 111, the suction conveyance belt 112, and the conveyance roller 20, respectively.

  Further, the control unit 6 continues or stops the operation of the entire apparatus related to the processing of the paper S according to the detection signal of the paper S output from the paper detector 90. For example, the paper detector 90 detects the front edge of the paper S and the paper detector 90 detects the front edge of the paper S until the first predetermined time elapses after the paper front edge sensor 30 detects the front edge of the paper S. If the trailing edge of the sheet S is detected by the sheet detector 90 from the time when the second predetermined time elapses, it is determined that the sheet S has been normally conveyed, and thereafter the operation of the entire apparatus is continued in the same manner. However, when the front end of the paper S cannot be detected by the paper detector 90 before the first predetermined time elapses, or the rear end of the paper S cannot be detected by the paper detector 90 before the second predetermined time elapses. Then, it is determined that the conveyance failure of the sheet S has occurred on the upstream side or the downstream side of the sheet detector 90, and the operation of the entire apparatus is stopped.

[Operation]
The operation of the sheet processing apparatus of this embodiment will be described. 5 and 6 are schematic explanatory views of the main part of the sheet processing apparatus as viewed from above.

  First, the processing conditions of the paper S are set by the input unit 7 so that the paper S is cut as shown in FIG. This setting is normally performed by the operator operating the operation panel 70. However, the barcode indicating the processing conditions printed on the paper S is automatically displayed by the CCD sensor 31 together with the registration mark. It may be performed by reading, or may be performed by a personal computer or other terminal device connected to the outside of the apparatus main body 10.

  Next, under the control of the control unit 6, the cutting blade moving means 81 is operated to rotate each screw shaft 401 while detecting the amount of rotation of the screw shaft 401, and 880 follows each guide shaft 402. Move in the paper width direction. Thereafter, when the cutting blade 801 is positioned at the cutting position, the operation of the cutting blade moving means 81 is stopped, and the rotation of the screw shaft 401 is stopped. In FIG. 5, the cutting position is set near the center in the paper width direction.

  Further, when the exclusion member moving means 51 is operated under the control of the control unit 6, the screw shaft 510 is rotated while the rotation amount of the screw shaft 510 is detected, and the exclusion member 50 is moved along each guide shaft 511. Move in the paper width direction. Thereafter, when the guide portion 506 is located at a position where it contacts the cutting waste SW, the operation of the exclusion member moving means 51 is stopped, and the rotation of the screw shaft 510 is stopped. In FIG. 5, the cutting waste SW is set to be generated on the right side of the cutting position.

  Further, when the detector moving means 91 is operated under the control of the control unit 6, the screw shaft 910 is rotated while the rotation amount of the screw shaft 910 is detected, and the sheet detector 90 is moved to each guide shaft 911. Along the paper width direction. After that, when the paper detector 90 is located within the widthwise conveyance range of the paper S that is continuously conveyed on the paper conveyance path 21 after the cutting waste SW is removed, the operation of the detector moving unit 91 is stopped. Thus, the rotation of the screw shaft 910 stops. In FIG. 5, the cutting waste SW is eliminated, and the sheet S that is continuously conveyed and remains on the sheet conveying path 21 is set to be generated on the left side of the cutting position.

  Then, the respective driving means (not shown) connected to the sheet feeding table 111, the suction conveying belt 112, and the conveying roller 20 are operated to send out the sheets S stacked on the sheet feeding table 111 one by one from the top to the downstream side, The front edge of the fed paper S is detected by the paper front edge sensor 30, and then a barcode or a registration mark is appropriately read from the paper S conveyed immediately below the CCD sensor 31 by the CCD sensor 31 and conveyed to the paper processing unit 4. To do.

  Further, when the driving means (not shown) connected to the drive shaft 403 is operated, the rotary blade 801 is rotated. The paper S that has reached the paper processing unit 4 is cut along the paper transport direction X1 by the rotating cutting blade 801, and is further transported downstream.

  Of the sheets S cut by the cutting blade 801, the right sheet contacts the guide portion 506 of the exclusion member 50. The guide unit 506 deflects the conveyed paper S, that is, the cutting waste SW in a downward direction, and collects the cutting waste SW in the trash box 13. Further, among the sheets S cut by the cutting blade 801, the left side sheet S does not contact the guide portion 506 of the exclusion member 50, so that it remains on the sheet conveyance path 21 and is continuously conveyed, and the sheet detector 90 is The sheet S that is continuously conveyed is detected.

The paper S that has passed through the paper detection unit 9 is further transported and discharged onto the paper discharge tray 12. In the case of processing a plurality of sheets S, the sheet S is sent out from the sheet feed table 111 by the suction conveyance belt 112, conveyed by the conveyance roller 20, cutting by the sheet processing unit 4, and cutting waste removing means 5 Repeat the elimination of the cutting waste SW.

  Also, under the control of the control unit 6, the front end of the paper S is detected by the paper detector 90 until the first predetermined time elapses from the time when the front edge of the paper S is detected by the paper front edge sensor 30, and the paper detection When the trailing edge of the sheet S is detected by the sheet detector 90 from when the leading edge of the sheet S is detected by the container 90 until the second predetermined time has elapsed, it is determined that the sheet S has been normally conveyed. In the same manner, the operation of the entire apparatus is continued. However, when the front end of the paper S cannot be detected by the paper detector 90 before the first predetermined time elapses, or by the paper detector 90 until the second predetermined time elapses. If the trailing edge of the sheet S cannot be detected, it is determined that a conveyance failure of the sheet S has occurred on the upstream side or downstream side of the sheet detector 90, and the operation of the entire apparatus is stopped.

  After processing a predetermined number of sheets S, the operation of the entire apparatus is stopped.

  Further, when the processing conditions of the paper S are changed so as to perform the cutting processing of the paper S as shown in FIG. 6, that is, the processing conditions after the setting change are shown in FIG. It is the same as the cutting position, and the cutting waste SW is generated on the left side of the cutting position. The cutting waste SW is eliminated, and the paper S that is continuously conveyed on the paper transport path 21 is on the right side of the cutting position. The operation of the paper processing apparatus when the setting is changed to the setting that occurs in the operation of the cutting blade moving means 81, the exclusion member moving means 51, the detector moving means 91, and the removal of the cutting waste SW and the paper detector. Only the detection of the sheet S by 90 will be described, and the other operations are the same as before the setting change, and thus description thereof will be omitted.

  First, under the control of the control unit 6, the cutting blade moving means 81 operates. However, since the cutting position is the same as before the setting change, the cutting blade moving means 81 operates without rotating each screw shaft 401. Stops.

  Further, when the exclusion member moving means 51 is operated under the control of the control unit 6, the screw shaft 510 is rotated while the rotation amount of the screw shaft 510 is detected, and the exclusion member 50 is moved along each guide shaft 511. Thus, the position moves from the right side to the left side from the cutting position indicated by the phantom line in FIG. After that, when the guide portion 506 is located at a position to the left of the cutting position indicated by the solid line in FIG. Stop.

  Further, when the detector moving means 91 is operated under the control of the control unit 6, the screw shaft 910 is rotated while the rotation amount of the screw shaft 910 is detected, and the sheet detector 90 is moved to each guide shaft 911. Along the right side from the cutting position indicated by the phantom line in FIG. Thereafter, the sheet detector 90 is positioned on the right side of the cutting position indicated by the solid line in FIG. 6, that is, the cutting waste SW is removed, and the conveyance direction in the width direction of the sheet S that is continuously conveyed on the sheet conveyance path 21. If it is located at the inner position, the operation of the detector moving means 91 is stopped, and the rotation of the screw shaft 910 is stopped.

  Of the sheets S cut by the cutting blade 801, the left side sheet contacts the guide portion 506 of the exclusion member 50. The guide unit 506 deflects the conveyed paper S, that is, the cutting waste SW in a downward direction, and collects the cutting waste SW in the trash box 13. In addition, among the sheets S cut by the cutting blade 801, the right side sheet S does not come into contact with the guide portion 506 of the exclusion member 50, so that it remains on the sheet conveyance path 21 and is continuously conveyed. The sheet S that is continuously conveyed is detected.

  By the way, when the cut sheet S is discharged to the paper discharge tray 12 without being brought into contact with the exclusion member 50, the exclusion member moving unit 51 is operated to detect the rotation amount of the screw shaft 510 while detecting the rotation amount of the screw shaft 510. The shaft 510 rotates and the exclusion member 50 moves along the guide shafts 511 in the paper width direction. After that, when the exclusion member 50 is located at a non-contact position that is provided on the outer side of the sheet S in the sheet width direction and does not contact the sheet S, the operation of the exclusion member moving unit 51 is stopped and the screw shaft 510 is stopped. Stops rotating. Therefore, both the right sheet S and the left sheet S, which are generated by cutting with the cutting blade 801, are conveyed without contacting the exclusion member 50, and are discharged to the discharge table 12.

[effect]
According to the paper processing apparatus of this embodiment, the following effects can be exhibited.

(1) Since the exclusion member 50 is provided so as to be movable in the paper width direction, that is, displaceable to a contact position where the cutting waste SW is excluded to the outside of the paper conveyance path 21, the paper S from which the exclusion member 50 has been cut is provided. Therefore, unnecessary cutting waste SW can be eliminated by selectively contacting the surface.

(2) After the paper detector 90 is cut by the paper processing unit 4, the cutting waste SW is removed, and the paper detector 90 is provided in the widthwise conveyance range of the paper S that is continuously conveyed on the paper conveyance path 21. Because
The paper S being conveyed by the paper detector 90 can be detected.

(3) Further, since the paper detector 90 is provided so as to be movable in the paper width direction, the cutting waste SW is eliminated and the paper detector 90 is continuously conveyed on the paper conveyance path 21. The sheet S can be easily positioned within the conveyance range in the width direction.

(4) Since the cutting machine 80 having the cutting blade 801 is provided so as to be movable in the paper width direction, the cutting position can be arbitrarily set.

(5) Since the cutting machine 80 is moved in the paper width direction based on the set processing conditions of the paper S, the cutting blade 801 of the cutting machine 80 can be easily moved to the cutting position.

(6) Since the removal member 50 is moved in the automatic paper width direction based on the set processing conditions of the paper S, the removal member 50 can be easily placed at a contact position where the cutting waste SW is removed from the paper conveyance path 21. Can be displaced.

(7) Since the paper detector 90 is automatically moved in the paper width direction based on the set processing conditions of the paper S, the cutting waste SW is removed from the paper detector 90, and the paper transport path 21 It can be easily positioned within the transport range in the width direction of the paper S that is continuously transported remaining above.

(8) Further, the exclusion member 50 is provided so as to be movable to a position where it does not come into contact with the paper S provided outside the area in which the paper S is transported in the paper width direction, that is, displaceable to a non-contact position. Therefore, after the cut sheet S is detected by the sheet detector 90 without being brought into contact with the exclusion member 50, it can be discharged as it is onto the sheet discharge tray 12.

[Modification]
A sheet processing apparatus according to a modification of the first embodiment of the present invention will be described with reference to FIGS. 7 and 8 are schematic explanatory views of the main part of the sheet processing apparatus as viewed from above.

  The paper processing apparatus 1 can arrange the paper detectors 90 on both sides at a predetermined distance from the cutting blade 801 in the paper width direction.

  The processing condition in FIG. 7 is that the cutting position is a position slightly to the right of the center in the paper width direction, and the cutting waste SW is generated on the right side of the cutting position. The sheet S that is continuously conveyed and remains on the upper side is set to be generated on the left side of the cutting position. The paper detector 90 disposed on the left side of the cutting blade 801 detects the continuously conveyed paper S, and the paper detector 90 disposed on the right side of the cutting blade 801 detects the paper S. do not do.

  Further, the processing conditions in FIG. 8 are the same as the cutting position shown in FIG. 7 at the cutting position, a position slightly to the right of the center in the paper width direction, and the cutting waste SW is generated on the left side of the cutting position. The cutting waste SW is eliminated, and the sheet S that is continuously conveyed and remains on the sheet conveying path 21 is set to be generated on the right side of the cutting position. The paper detector 90 disposed on the right side of the cutting blade 801 detects the paper S that is continuously conveyed, and the paper detector 90 disposed on the left side of the cutting blade 801 detects the paper S. do not do.

  According to this modification, the paper detector 90 is disposed on both sides of the cutting blade 801 at a predetermined distance in the paper width direction, so that the cutting waste SW is eliminated and the paper detector 90 continues to remain on the paper conveyance path 21. Even if the sheet S conveyed in this way occurs on either the right side or the left side of the cutting position, it can be detected by any one of the sheet detectors 90.

Second Embodiment
The cutting waste removing means 5 of the first embodiment is provided at a position away from the slit processing unit 40 (cutting machine 80) in the paper transport direction X1, but the cutting waste removing means 5 of the present embodiment is It is connected to the slit processing unit 40 (cutting machine 80) and is provided integrally.

  9 is a longitudinal sectional view schematically showing a paper processing apparatus similar to that of FIG. 1, and FIGS. 10 and 11 are top views of the main parts of the paper processing apparatus similar to FIGS. It is a schematic explanatory drawing. As shown in FIGS. 10 and 11, the slit processing unit 40 includes two cutting machines 80 arranged side by side in the paper width direction, and engages with a cutting machine 80A provided on the right side and 80B provided on the left side. Each cutting machine 80 can be independently moved in the paper width direction by the cutting blade moving means 81 similar to that of the first embodiment.

  FIG. 12 is a perspective view of the main part of the slit machining unit in which cutting waste removing means is integrally provided, and particularly shows the periphery of the cutting machine 80A. Based on FIG. 12, the cutting waste removing means 5 according to the present embodiment will be described. The cutting waste removing means 5 includes a connecting plate 52 whose upper portion is fixed to the downstream side surface of the upper holder 802A of the cutting machine 80A by a bolt (not shown) and whose lower portion is suspended to the vicinity of the lower end of the lower holder 802B, and an upstream portion below the connecting plate 52. And an exclusion member 50 fixed to the side surface by an adhesive or a bolt (not shown). The exclusion member 50 includes an exclusion portion 501 having a guide portion 506 for removing the cutting waste SW from the sheet conveyance path 21 and guiding it to the trash box 13. In other words, the exclusion member 50 is connected to the downstream portion of the holder 802, the cutting dust removal unit 5 does not include the exclusion member moving unit 51 alone, and the cutting blade moving unit 81 also serves as the exclusion member moving unit 51. ing. Therefore, when the cutting machine 80A moves in the paper width direction, the exclusion member 50 connected to the cutting machine 80A also moves in the paper width direction.

  Further, the cutting machine 80A and the cutting machine 80B basically have a symmetrical structure. In the cutting machine 80A, the exclusion member 50 is provided on the right side of the cutting blade 801. The exclusion member 50 is provided on the left side of the cutting blade 801. Therefore, when the cutting machine 80B moves in the paper width direction, the exclusion member 50 connected to the cutting machine 80B also moves in the paper width direction.

In the sheet processing apparatus 1 according to the present embodiment, the non-contact position is provided on the outer side in the sheet width direction from the area where the sheet S is conveyed, in which the cutting blade 801 and the exclusion member 50 do not contact the sheet S. The non-contact position includes a left non-contact position provided on the left outer side in the paper width direction from the area where the paper S is conveyed so that the cutting blade 801 and the exclusion member 50 of the cutting machine 80B do not contact the paper S. In order to prevent the cutting blade 801 and the exclusion member 50 of the cutting machine 80 </ b> A from coming into contact with the paper S, the cutting edge 801 includes a right non-contact position provided on the right outer side in the paper width direction from the area where the paper S is conveyed.

  The control unit 6 determines which of the cutting blade 801 of the cutting machine 80A and the cutting blade 801 of the cutting machine 80B is to be used for cutting based on the input processing conditions of the paper S, and sets each cutting machine 80 to The operation of the cutting blade moving means 81 is controlled so as to move to the cutting position or the non-contact position. Further, the control unit 6 controls the paper detector 90 based on the input processing conditions of the paper S to remove the cutting waste SW and remain on the paper transport path 21 in the width direction of the paper S. The operation of the detector moving means 91 is controlled so as to move to a position within the transport range.

  In the cutting process of the paper S shown in FIG. 10, the paper S is cut by the cutting blade 801 of the cutting machine 80A, and the paper S generated on the right side of the cutting position is an exclusion member 50 provided integrally with the cutting machine 80A. Therefore, the sheet generated on the left side of the cutting position is removed from the cutting position and does not come into contact with the rejection member 50. Therefore, the sheet remains on the sheet conveyance path 21 and is continuously conveyed, and the sheet detector 90 continuously conveys the sheet. The sheet S to be detected is detected. At this time, the cutting machine 80B is located at the left non-contact position.

  In the cutting process of the paper S shown in FIG. 11, the paper S is cut by the cutting blade 801 of the cutting machine 80B, and the paper S generated on the left side of the cutting position is integrally provided in the cutting machine 80B. Therefore, the sheet generated on the right side of the cutting position is removed from the cutting position and does not come into contact with the rejection member 50. Therefore, the sheet remains on the sheet conveying path 21 and is continuously conveyed. The sheet S to be detected is detected. At this time, the cutting machine 80A is positioned at the right non-contact position.

  The other structure is the same as that of the first embodiment, and the same parts and portions are denoted by the same reference numerals.

  According to the present embodiment, not only the same effects as in the first embodiment are exhibited, but also the exclusion member 50 is connected to the downstream portion of the holder 802, and therefore the following effects can be exhibited.

(1) It is not necessary to provide the exclusion member moving means 51 alone, and the configuration can be simplified.

(2) The displacement member 50 can be easily displaced to a contact position where the cutting waste SW is removed out of the paper transport path 21 by simply moving each cutting machine 80 to the cutting position.

<Third Embodiment>
The cutting waste removing means 5 of the present embodiment is connected to the slit machining unit 40 (cutting machine 80) as in the second embodiment. However, although the cutting waste removing means 5 of the second embodiment is provided with one removing member 50 for one cutting machine 80, the cutting waste removing means 5 of the present embodiment is provided with one cutting machine 80. In contrast, two exclusion members 50 are provided.

  FIG. 13 is a longitudinal sectional view schematically showing the same paper processing apparatus as in FIGS. 1 and 9, and FIG. 14 is a schematic diagram on the right side of the slit processing unit integrally provided with cutting waste removing means. FIG. 15 is a schematic view of the main part of the slit machining unit provided with the cutting waste removing means of FIG. FIG. 16 is a schematic right side view of a slit machining unit integrally provided with cutting waste removing means showing a state in which the cutting waste removing means of FIG. 14 is displaced. FIG. 17 is a schematic view of FIG. It is the XVII arrow schematic diagram of the principal part of the slit processing unit in which the exclusion means was provided integrally.

  As shown in FIGS. 14 to 17, the cutting machine 80 can be moved in the paper width direction by a cutting blade moving means 81 similar to that of the second embodiment. Further, the cutting waste removing means 5 includes a support portion 53 that is connected to the downstream side surface of the upper holder 802A of the cutting machine 80 and protrudes toward the downstream side, and the right side surface of the support portion 53 is more than the cutting blade 801. Located on the right side, the left side surface of the support portion 806 is located on the left side of the cutting blade 801.

  The exclusion member 50 of the cutting waste removing means 5 includes an exclusion portion 501, and a guide portion 506 that is inclined downward from the upstream side toward the downstream side is provided at a lower portion of the exclusion portion 501. Further, two elongate holes 507 are extended in the vertical direction on the upper portion of the exclusion portion 501. Further, on the upper portion of the exclusion portion 501, a grip portion 508 having a shape protruding toward the downstream side is formed. Is formed.

  Two pins 530 each projecting in the paper width direction are provided on the right side surface and the left side surface of the support portion 53. The support portion 53 supports the exclusion member 50 one by one on the right side surface and the left side surface thereof, and the exclusion portion 501 of one exclusion member 50 is provided on each pin 530 on the right side surface of the support portion 53. The respective long holes 507 are engaged, and the respective long holes 507 of the exclusion portion 501 of the other exclusion member 50 are engaged with the respective pins 530 on the left side surface of the support portion 53, thereby supporting each exclusion member 50. ing. That is, two exclusion members 50 are connected to one cutting machine 80 (holder 802), and each exclusion member 50 is disposed on both sides at a predetermined distance from the cutting blade 801 in the paper width direction. Yes.

  Each exclusion member 50 extends along the elongated hole 507 in the vertical direction between a position where the pin 530 engages at the upper end of the elongated hole 507 and a position where the pin 530 engages at the lower end of the elongated hole 507. The pin 530 is provided so as to be slidable and can be held at a position where the pin 530 is engaged at the upper end of the elongated hole 507 and a position where the pin 530 is engaged at the lower end of the elongated hole 507 by a locking means (not shown). That is, the displacement means for displacing each exclusion member 50 in the vertical direction has at least each long hole 507 and each pin 530. Each exclusion member 50 is located at a contact position where the pin 807 engages with the upper end of the long hole 507 and can contact the paper S, and does not contact the paper S at a position where the pin 807 engages with the lower end of the long hole 507. Located in a possible non-contact position. Therefore, the operator can displace each exclusion member 50 independently between the contact position and the non-contact position by gripping the grip portion 508 and sliding the exclusion member 50 in the vertical direction.

  Therefore, the cutting waste removing means 5 does not include the removing member moving means 51 alone, the cutting blade moving means 81 also serves as the removing member moving means 51, and the cutting machine 80 moves in the paper width direction. The exclusion member 50 connected to 80 also moves in the paper width direction.

  The controller 6 controls the operation of the cutting blade moving means 81 so that the cutting blade 80 is moved to match the cutting position based on the input processing conditions of the paper S. When the operator removes the sheet S generated on the right side of the cutting position as cutting waste SW by the removal member 50, the worker supports the sheet S on the right side of the support portion 53 as shown in FIGS. The displacement member 50 is displaced to the contact position, the displacement member 50 supported on the left side of the support portion 53 is displaced to the non-contact position, and the sheet S generated on the left side of the cutting position is removed as cutting waste SW. 16 and 17, the exclusion member 50 supported on the right side of the support portion 53 is set to the non-contact position and the exclusion member 50 supported on the left side of the support portion 53 as shown in FIGS. Are respectively displaced to the contact positions. Further, the control unit 6 controls the paper detector 90 based on the input processing conditions of the paper S to remove the cutting waste SW and remain on the paper transport path 21 in the width direction of the paper S. The operation of the detector moving means 91 is controlled so as to move to a position within the transport range.

  In the slit processing unit 40 in this embodiment, two cutting machines 80 may be provided side by side in the paper width direction as in the second embodiment, but the cutting machine 80 is provided in the same manner as in the first embodiment. Only one may be provided. Other structures are the same as those of the second embodiment, and the same parts and portions are denoted by the same reference numerals.

  According to this embodiment, not only the same effects as those of the first embodiment and the second embodiment are exhibited, but also two exclusion members 50 are provided for one cutting machine 80, and each exclusion member 50 is provided. Can be displaced independently between the contact position and the non-contact position, so that the following effects can be exhibited.

(1) Even if the cutting waste SW is generated on either the right side or the left side of the cutting blade 801, the cutting waste SW can be eliminated.

(2) By positioning each exclusion member 50 at the non-contact position, the cut sheet S can be transported to the paper discharge tray 12 without generating cutting waste SW.

<Fourth embodiment>
The paper detection unit 9 of the third embodiment is provided with the detector moving means 91 alone, but the paper detection unit 9 of the present embodiment is connected to the slit processing unit 40 (cutting machine 80). Is provided.

  FIG. 18 is a longitudinal sectional view schematically showing the same paper processing apparatus as that of FIG. 1, FIG. 9, and FIG. 13, and FIG. 19 is a right side of the periphery of the slit processing unit provided with the paper detection unit connected thereto. FIG. 20 is a schematic view taken along the line XX of the main part around the slit processing unit provided with the paper detection unit of FIG. 19 connected thereto.

  As shown in FIGS. 19 and 20, the cutter 80 can be moved in the paper width direction by the same cutting blade moving means 81 as in the third embodiment. In the cutting waste removing means 5, as in the third embodiment, two removing members 50 are connected to one cutting machine 80 (holder 802), and each removing member 50 has a cutting blade 801. Are arranged on both sides spaced apart from each other by a predetermined distance in the paper width direction, and can be independently displaced between the contact position and the non-contact position by the displacement means. Further, the cutting waste removing unit 5 does not include the removing member moving unit 51 alone, and the cutting blade moving unit 81 also serves as the removing member moving unit 51. When the cutting machine 80 moves in the paper width direction, the cutting machine moves. The exclusion member 50 connected to 80 also moves in the paper width direction.

The sheet detection unit 9 has one end side fixed to the upper end surface of the upper holder 802A of the cutting machine 80 by a bolt (not shown) and one end side fixed to the lower end surface of the lower holder 802B of the cutting machine 80 by a bolt (not shown). And a sheet detector 90 fixed to the other end of the upper connecting plate 92 and the other end of the lower connecting plate 93, respectively.

  The upper connecting plate 92 includes one end side fixed to the upper end surface of the upper holder 802A, an arm portion 920 extending horizontally from the one end to the downstream side of the downstream side surface of the support portion 53, and a downstream side of the arm portion 920. It has a vertical portion 921 that is bent and extends downward from the end, and a holding portion 922 that is bent and extends horizontally from the lower end of the vertical portion 921 toward the downstream side. In addition, the lower connecting plate 93 includes one end side fixed to the lower end surface of the lower holder 802B, an arm portion 930 extending horizontally from the one end to the downstream side of the downstream side surface of the lower holder 802B, and the arm portion 930. A vertical portion 931 that bends and extends upward from the downstream end thereof, and a holding portion 932 that is bent toward the downstream side from the upper end of the vertical portion 931 and extends horizontally.

The paper detector 90 includes a light receiving unit 900A fixed by a bolt (not shown) so as to be positioned on the right side of the cutting blade 801 on the horizontal plane of the holding unit 922, and on the horizontal plane of the holding unit 922 and on the left side of the cutting blade 801. The light receiving portion 900B fixed by a bolt (not shown) so as to be positioned, and the light emission fixed on the horizontal surface of the holding portion 932 on the right side of the cutting blade 801 and fixed by a bolt (not shown) so as to face the light receiving portion 900A. The light emitting portion 901B is fixed to the horizontal surface of the holding portion 932 on the left side of the cutting blade 801 and fixed by a bolt (not shown) so as to face the light receiving portion 900B.

That is, the paper detector 90 is connected to the downstream side of the holder 802, the paper detection unit 9 does not include the detector moving means 91 alone, and the cutting blade moving means 81 also serves as the detector moving means 91. ing. Therefore, when the cutting machine 80 moves in the paper width direction, the paper detector 90 connected to the cutting machine 80 also moves in the paper width direction.

  The controller 6 controls the operation of the cutting blade moving means 81 so that the cutting blade 80 is moved to match the cutting position based on the input processing conditions of the paper S. For example, in the cutting process of the sheet S shown in FIGS. 19 and 20, the operator excludes the exclusion member 50 supported on the right side of the support portion 53 at the contact position and supported on the left side of the support portion 53. The members 50 are respectively displaced to the non-contact positions. In this case, the sheet S generated on the right side of the cutting position is excluded as cutting waste SW by the removing member 50, and the sheet S generated on the left side of the cutting position remains on the sheet conveying path 21 and is continuously conveyed. Since the paper detector 90 moves in the paper width direction with the movement of the cutting machine 80, the light receiving unit 900B and the light emitting unit 901B located on the left side of the cutting blade 801 are continuously conveyed. S is detected.

The other structure is the same as that of the third embodiment, and the same parts and portions are denoted by the same reference numerals.

  According to this embodiment, not only the same effects as those of the first to third embodiments are exhibited, but also the paper detector 90 is connected to the downstream side of the holder 802, and the cutting blade Since the sheet detectors 90 are provided on both sides of the sheet 801 in the sheet width direction, the following effects can be exhibited.

(1) It is not necessary to provide the detector moving means 91 alone, and the configuration can be simplified.

(2) Even if the cutting waste SW is removed and the sheet S that is continuously conveyed on the sheet conveying path 21 is generated on either the right side or the left side of the cutting blade 801, the light receiving unit 900A and the light emitting unit 901A are generated. Alternatively, the sheet S continuously conveyed can be detected by the light receiving unit 900B and the light emitting unit 901B.

<Other embodiments>
In the first embodiment to the fourth embodiment, the sheet processing unit 4 includes only one slit processing unit 40. However, the sheet processing unit 4 can include a plurality of slit processing units 40. It is also possible to provide a sheet processing unit 4 for processing other sheets.

For example, the paper processing apparatus 1 shown in FIG. 21 includes seven paper processing units (4A, 4B, 4C, 4D, 4E, 4F, and 4G) along the paper transport direction X1. In particular, the first paper processing unit 4A includes a margin slit processing unit 41 that cuts both side edges of the paper S along the paper transport direction X1, and the margin slit processing unit 41 is the slit of the second embodiment. The configuration is the same as that of the processing unit 40. The second paper processing unit 4B, the third paper processing unit 4C, the fourth paper processing unit 4D, and the fifth paper processing unit 4E pass through the first paper processing unit 4A and are conveyed on the paper conveyance path 21. Are each provided with a slit processing unit 40 that cuts along the sheet conveying direction X1, and has the same configuration as the slit processing unit 40 of the first embodiment. The sixth sheet processing unit 4F forms a fold along the sheet width direction with respect to the sheet S that is continuously conveyed on the sheet conveyance path 21 through the fifth sheet processing unit 4E. 42 is provided. The seventh paper processing unit 4G includes a cutter unit 43 that cuts the paper S that passes through the sixth paper processing unit 4F and is transported on the paper transport path 21 along the paper width direction. Further, a cutting waste removing means 5 and a paper detection unit 9 are provided between the fifth paper processing unit 4E and the sixth paper processing unit 4F. That is, the second paper processing unit 4B to the fifth paper processing unit 4E, the cutting waste removing means 5, and the paper detection unit 9 are the same as the configuration of the first embodiment. Note that a plurality of cutting waste removing means 5 may be arranged along the paper transport direction X1, and the cutting waste removing means 5 may include a plurality of removal members 50 in the paper width direction.

Then, the control unit 6 moves the cutting machines 80 of the first paper processing unit 4A to the fifth paper processing unit 4E based on the input processing conditions of the paper S, so that the cutting blades 801 have their respective cutting positions. The operation of each cutting blade moving means 81 is controlled so as to match the above, and the exclusion member moving means 51 is operated so as to match the contact position where the exclusion member 50 contacts the cutting waste SW by moving the exclusion member 50. And the paper detector 90 is moved so that the cutting waste SW is eliminated and the paper detector 90 is left on the paper transport path 21 and is positioned at a position within the transport range of the paper S in the width direction. Thus, the operation of the detector moving means 91 is controlled. Further, the control unit 6 performs folding processing in the folding processing unit 42 and cutting processing in the sheet width direction in the cutter unit 43 in accordance with the detection signal of the paper S by the paper detector 90. The operations of the sixth paper processing unit 4F and the seventh paper processing unit 4G are controlled so as to match the cutting position.

Therefore, the paper processing apparatus 1 includes a plurality of paper processing apparatus units, so that more processing can be performed on the paper S. Even in this case, the cutting waste SW is eliminated and the paper transport path 21 is processed. The paper S that is continuously conveyed and remains on the top can be detected by the paper detector 90. Note that the processing by the first paper processing unit 4A to the fifth paper processing unit 4E is not limited to slit processing, and in order to perform a plurality of types of processing on the paper S, for example, perforation processing or It can comprise so that other processing units provided with the processing tool which performs a half cut process etc. may be used. In addition, a handle 400 is provided in each of the margin slit processing unit 41, the slit processing unit 40, the perforation processing unit, and the half cut processing unit so that the processing type for the paper S can be freely changed. It is also possible to configure the apparatus so as to be detachable from the apparatus main body 10.

DESCRIPTION OF SYMBOLS 1 Paper processing apparatus 4 Paper processing part 5 Cutting waste removal means 6 Control part 9 Paper detection part 10 Main body 20 Conveyance roller 21 Paper conveyance path 40 Slit processing unit 50 Exclusion member 51 Exclusion member movement means 52 Connecting plate 80, 80A, 80B Cutting machine 81 Cutting blade moving means 90 Paper detector 91 Detector moving means 92 Upper connecting plate 93 Lower connecting plate 501 Eliminating portion 506 Guide portions 900, 900A, 900B Light receiving portions 901, 901A, 901B Light emitting portion S Paper SW Cutting waste

Claims (5)

A paper processing apparatus for processing paper conveyed one by one along a paper conveyance path by a conveyance means,
A slit processing unit that is provided in the middle of the paper transport path and cuts the paper along the paper transport direction by a cutting blade held by a holder;
Among the papers cut by the cutting blade, an exclusion member that excludes unnecessary cutting waste outside the paper transport path, and the exclusion member selectively contacts the cut paper and A cutting waste removing means provided to be displaceable at a contact position for removing the cutting waste outside the paper transport path;
A paper detector that is provided downstream of the cutting waste removing means in the paper conveyance direction and detects a predetermined location within a range in the width direction of the paper conveyed on the paper conveyance path;
The slit processing unit includes a cutting blade moving means for moving the holder in the paper width direction,
The paper detector is interlocked with the movement of the holder in the paper width direction, and after the paper is cut by the cutting blade, the cutting blade in the paper width direction to the position of the paper remaining on the paper conveyance path and continuously conveyed downstream It is installed so that it can move in the paper width direction beyond the installation position of
The paper removal apparatus is installed such that the exclusion member is movable in the paper width direction beyond the installation position of the cutting blade in the paper width direction to a position where the cutting waste is removed . Detector moving means for moving the paper detector in the paper width direction;
An input section for inputting conditions relating to paper processing
A control unit for controlling the processing operation of the paper,
The paper processing apparatus according to claim 1, wherein the control unit controls the detector moving unit to move the paper detector in a paper width direction based on a processing condition input from the input unit. The cutting waste removing means includes displacement means for displacing the exclusion member between the contact position and a non-contact position where the paper conveyance path is not brought into contact with the conveyed paper. The paper processing apparatus as described. The exclusion member is disposed on both sides at a predetermined distance from the cutting blade in the paper width direction, and the displacement means is configured so that each exclusion member can be moved independently between the contact position and the non-contact position. The paper processing apparatus according to claim 3, which is displaceable. The paper processing apparatus according to any one of claims 1 to 4, wherein the exclusion member is connected to a downstream portion of the holder.

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