JP6455772B2 - Paper folding device, collating device - Google Patents

Description

  The present invention relates to a sheet folding device that folds a sheet in two. The present invention also relates to a collating apparatus that sandwiches a bundle of sheets taken out from each of a plurality of sheet feeding mechanisms inside a sheet folded by the sheet folding apparatus.

In a newspaper store, a collation apparatus is used to bundle advertisements delivered in bundles for each type so that they can be delivered. This collating apparatus is provided with sheet feed tables on which advertisements are stacked in a vertical direction. When a bundle of advertisements of each type is stacked on each paper feed tray, the advertisements are separated from each paper feed tray, taken out from each other, and merged and stacked while being conveyed from above to below.
One folding sheet feeding table is provided further below the sheet feeding tables arranged in the vertical direction. The advertisements sent one by one from the folding paper feeder are folded in two. An advertisement taken out from each upper paper feed tray is inserted inside the two folds to form a bundle of delivery units (for example, Patent Document 1).

JP 2007-039216 A (paragraphs [0002] to [0008] and [FIG. 1])

  FIG. 16 is a diagram showing a two-fold mechanism of this conventional collating apparatus. The advertisement S1 sent from the folding paper supply base is conveyed in the direction of arrow D along the conveyance path 101, passes above the folding roller pair 102, and stops at the leading end abutting against the stopper 103 (FIG. 16 ( a)). The advertisement bundle S2 fed out from the respective paper feed trays arranged above and superimposed on each other is lowered from above, and the folding knife 104 is rotated so that the tip thereof is in contact with the advertisement S1 (FIG. 16B). )). The advertisement S1 is wound around the pair of folding rollers 102 to give a crease, and is sandwiched between the pair of folding rollers 102 with the advertisement bundle S2 sandwiched between them and sent downward (FIG. 16 (c)). The position of the stopper 103 is adjusted in advance so that a crease is given at the center of the advertisement S1 in the conveyance direction, and the folding knife 104 is immediately before the lower end of the advertisement bundle S2 reaches the upper surface of the advertisement S1. Is controlled so as to contact the advertisement S1 at the timing.

  However, when the advertisement S1 is a thin advertisement that is easily bent, the tip may be buckled when it hits the stopper 103 as shown in FIG. As a result, the buckled tip is bent, or the advertisement S1 is folded at a position shifted from the tip in the direction away from the tip, so that the appearance of the finished bundle is deteriorated. Further, if the advertisement S1 bends downwards above the folding roller pair 102, it may be caught in the folding roller pair 102 before the folding knife 104 abuts. As a result, as shown in FIG. The tip S2a of the advertisement bundle S2 does not match the fold line S1a, and the bundle is completed in a state of being largely retracted.

  The present invention has been made in view of the above problems, and provides a sheet folding device that can be folded in a clean manner in the center without causing buckling of the sheet, and a collating device including the sheet folding device. With the goal.

In order to solve the above problems, a sheet folding device according to the present invention includes a pair of folding rollers that sandwich and fold a sheet, and a conveyance path that conveys the sheet facing the entrance to the nip of the pair of folding rollers. And a creasing means for providing a folding line in a direction orthogonal to the crease provided by the folding roller, and a sheet provided with a folding line to be conveyed through the conveyance path. a stop means for the conveying direction leading end stop is abutted against the abut on the sheet is stopped by stop means, folding the sheet and having a knife folder directing the paper into the nip of a pair folding rollers, the apparatus.

  According to this aspect, since the stiffness is imparted to the sheet by the folding line imparted to the sheet, a sheet folding device that can be folded in two at the center without causing buckling of the sheet is obtained.

  The scoring means may be provided on the upstream side in the transport direction with respect to the portion of the transport path facing the entrance to the nip of the pair of folding rollers. According to this aspect, since the advertisement does not bend downward above the folding roller pair, it is possible to prevent the folding knife from being caught in the folding roller pair before contacting the folding knife. It is possible to prevent a bundle that is retracted from the fold of the fold advertisement that sandwiches the bundle from being completed.

  The creasing means is provided at an upper streak roller that is in contact with the upper surface of the paper that is transported through the transport path, at substantially the same position in the transport direction as the upper streak roller, and at a different position in the width direction, and transports the transport path. A lower streaked roller that abuts the lower surface of the sheet to be printed, and the lowermost position of the outer peripheral surface of the upper streaked roller is located below the uppermost position of the outer peripheral surface of the lower streaked roller, The end faces may be provided close to each other so as to sandwich the sheet conveyed between the end faces opposed to each other in the width direction. According to this aspect, the creasing means can be configured very inexpensively and easily.

  The position in the width direction of either the upper streaked roller or the lower streaked roller can be switched between a first position where the end surfaces are close to each other and a second position which is separated from the first position. May be. According to this aspect, it is possible to selectively use a case in which a folding line is given to the sheet with the lined roller as the first position and a case in which no folding line is given to the sheet with the lined roller as the second position. Originally thick thick paper does not buckle even without a crease. Therefore, it is possible to avoid unnecessary folding lines in the case of thick paper.

  A transmitting element that transmits ultrasonic waves and a receiving element that receives the ultrasonic waves are arranged opposite to each other across the paper conveyance line, and at least the ultrasonic waves transmitted by the transmitting element are received by the receiving element when the paper passes. An ultrasonic multi-feed detection sensor for detecting whether the passing paper is one sheet or two or more sheets depending on whether or not the amplitude exceeds a predetermined value is provided downstream of the scoring means and In addition, the creasing means may be provided at a position different in the width direction. According to this aspect, the folding line given to the paper by the streaking does not overlap the transmission part of the ultrasonic double feed detection sensor, so the influence on the ultrasonic double feed detection result by the folding line itself is not affected. Since it can be eliminated, stable double feed detection becomes possible.

  Of the rollers with upper streaks and lower streaks that make a pair at the closest position in the width direction from the double feed detection sensor, the paper surface is placed against the support shaft side that supports the streaked roller closer to the double feed detection sensor. A guide member that guides the sheet surface from the opposite side in the up-down direction may be provided.

  According to this aspect, when performing sheeting with a sheet sandwiched between the end surfaces of the upper and lower lined rollers, the inclination and fluttering of the sheet that occurs due to the bending that occurs in the sheet at the lined portion. Since it can be suppressed by the guide plate, stable double feed detection becomes possible.

  Two or more pairs of a roller with an upper bar and a roller with a lower bar may be provided, and the double feed detection sensor may be provided at an intermediate position in the width direction. In the middle of the two pairs of double feed detection sensors, the inclination and fluttering of the paper caused by the streaking are suppressed, so that stable double feed detection is possible.

  The scoring means is provided on one surface side of the sheet conveyed along the conveyance path, and is provided on the other surface side of the sheet with the convex roller provided with the circumferential protrusion that goes around the outer peripheral surface, and the convex roller And a concave roller having a circumferential groove provided on the outer peripheral surface so as to accommodate the protrusions.

  Further, the scoring means may be arranged coaxially with a pair of conveyance rollers that convey the paper while sandwiching and rotating the sheet from above and below, and symmetrically arranged on both sides with respect to the conveyance roller pair. According to this aspect, it is possible to avoid the skew of the sheet.

  A plurality of sheet feeding mechanisms for feeding sheets one by one from the stacked sheet stack are provided in the vertical direction, the sheets fed from each sheet feeding mechanism are stacked while being conveyed downward, and a plurality of sheet feeding mechanisms 7. A folding sheet feeding mechanism that feeds folded sheets one by one from the stacked sheet bundle and a folding sheet fed from the folding sheet feeding mechanism in a further downward direction. When the folded sheet is sandwiched between the pair of folding rollers and folded into two, the stacked sheets fed from the respective paper feeding mechanisms are inserted inside the folded sheet. A collating apparatus configured to form a bundle of one set is also the present invention.

  According to this aspect, the folded sheet sandwiching the bundled sheets does not buckle when folded, and can be folded in two beautifully. The folded sheet and the bundle of sheets to be sandwiched between the folded sheets Can be surely entered into the folding roller at the same time, so that it is possible to prevent a decrease in the appearance such as a crease between the folded sheets and the leading end of the bundle of sheets sandwiched.

  According to the present invention, there is an effect that a paper folding device and a collating device that can be folded in two at the center without causing buckling of the paper are obtained.

It is a model front view which shows the collation apparatus 1 which concerns on the 1st Embodiment of this invention. It is an external view which shows the collation set S produced with the collation apparatus 1. FIG. FIG. 3 is a top view showing a folding paper feeding mechanism 3 and a transport roller unit 15. It is AA sectional drawing in FIG. It is the figure which looked at the conveyance roller unit 15 from the BB surface in FIG. FIG. 5 is an enlarged view of a roller 155 with an upper line and a roller 157 with a lower line in FIG. 4. FIG. 6 is an enlarged view of a roller 155 with an upper line and a roller 157 with a lower line in FIG. 5. (A), (b) is a figure which shows the cross section of the part by which the roller 155 with an upper line is supported by the upper conveyance axis | shaft 151, (c) supports the roller 155 with an upper line | wire with the upper conveyance axis | shaft 151. It is a figure which shows the external appearance of the state which removed the roller 155 with an upper line | strand, the roller 157 with a lower line | wire, and stopper 159a, 159b of the part. FIG. 6 is a diagram illustrating a state in which the sheet S1 passes between upper streaked rollers 155 and 156 and lower streaked rollers 157 and 158. It is a flowchart which shows operation | movement of the collation apparatus 1 which concerns on the 1st Embodiment of this invention. It is a figure which shows the paper S1 to which the folding lines F1, F2, F3, and F4 were given. It is a figure which shows the roller 253 with an upper line | wire and the roller 254 with a lower line | wire based on the 2nd Embodiment of this invention. It is a figure which shows the rollers 355 and 356 with an upper line | strand and the rollers 357 and 358 with a lower line | wire which concern on the 3rd Embodiment of this invention. It is a figure which shows the rollers 455 and 456 with upper lines, and the rollers 457 and 458 with lower lines which concern on the 4th Embodiment of this invention. It is a figure which shows the modification of the 4th Embodiment of this invention. It is a figure which shows the two folding mechanism of the conventional collation apparatus. It is a figure which shows the case where the buckling of a paper generate | occur | produces in the conventional paper folding apparatus. It is a figure which shows an example of the collation set S produced in the conventional collation apparatus.

(First embodiment)
A first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic front view showing a collating apparatus 1 according to the first embodiment of the present invention, and FIG. 2 is an external view showing a collating set S created by the collating apparatus 1. As shown in FIG. 2, this collation set S is a form in which a bundle S2 of a plurality of sheets is sandwiched inside one folded sheet S1, and is suitable for newspaper advertisements sandwiched between newspapers for delivery. It is a form.

  In the collating apparatus 1, ten paper feeding mechanisms 2a to 2j on the left side shown in FIG. 1 and ten paper feeding mechanisms 2k to 2t on the right side are arranged side by side so as to be stacked vertically. Since the paper feed mechanisms 2a to 2j and the paper feed mechanisms 2k to 2t have the same structure and are attached in opposite directions, the directions are reversed in FIG. Hereinafter, the sheet feeding mechanisms 2a to 2t are collectively referred to as a sheet feeding mechanism 2. A folding paper feed mechanism 3 having the same structure as the paper feed mechanism 2 is disposed below the left paper feed mechanisms 2a to 2j.

  The paper feed mechanism 2 and the folding paper feed mechanism 3 are detachable from the main body of the collating apparatus 1 for each stage. FIG. 1 shows a state where the paper feeding mechanism 2t is removed from the main body of the collating apparatus 1. A paper feed mechanism accommodating portion 2ta is formed on the main body side, and the paper feed mechanism 2t can be inserted and fixed by an appropriate guide and fixing means.

  The uppermost sheet bundle stacked on a part or all of the sheet feeding mechanism 2 is separated from the sheet bundle by the separation feeding mechanism 4 and sent out to the horizontal conveyance path 6. A vertical conveyance path 7 is provided in the vertical direction in the center of the collating apparatus 1, and all the horizontal conveyance paths 6 extending from the respective paper feeding mechanisms 2 merge with the vertical conveyance path 7. Each of the paper feeding mechanisms 2 sends out the paper at such a timing that the leading ends thereof are aligned when the fed paper is merged in the vertical conveyance path 7. The sheets sent out one by one from each sheet feeding mechanism 2 are stacked on each other while moving from the upper side to the lower side in the vertical conveyance path 7 to form a sheet bundle S2.

  The uppermost sheet bundle stacked on the folding sheet feeding mechanism 3 is separated from the sheet bundle by the separation feeding mechanism 5. The separated sheet S1 is conveyed by the conveyance roller units 15 and 16 toward the right in FIG. The sheet S1 passes over the pair of folding rollers 11 and enters the folding plate 8, and the leading end comes into contact with the stopper 9 and stops. The folding plate 8 is configured by overlapping an upper plate 8a and a lower plate 8b. 1, the space between the upper plate 8a and the lower plate 8b is widened on the left side, and the sheet S1 enters between them. The stopper 9 is provided so as to penetrate the upper plate 8a and the lower plate 8b. Accordingly, the sheet S1 conveyed rightward in the drawing between the upper plate 8a and the lower plate 8b stops the advance by the stopper 9. It is done.

  Since the rear end of the stopped sheet S1 is in the folding conveyance path 17, the sheet S1 is in a state of blocking the lower end of the vertical conveyance path 7. Thereafter, the folding knife 10 is driven and the leading end thereof comes into contact with the sheet S1, the sheet S1 is wound around the folding roller 11 and folded in two, and the sheet bundle S2 that has descended the vertical conveyance path 7 inside the bifold. The collation set S is created. The collation set S is further discharged out of the apparatus from the paper discharge outlet 13 via the paper discharge conveyance path 12 and accumulated in the stacker 14. The position of the stopper 9 can be adjusted by a driving mechanism (not shown) or manually along the conveyance direction of the sheet S1, and the position of the stopper 9 is adjusted according to the size of the sheet S1 so that the sheet S1 is folded in the center. Is done.

  The transport roller unit 16 is composed of a lower roller to which driving is applied and a lightweight roller placed thereon. Accordingly, even after the trailing edge of the sheet S1 passes through the transport roller unit 15, the sheet S1 can be fed into the folding plate 8 until it abuts against the stopper 9 and stops after the sheet S1 abuts against the stopper 9. The lower drive roller is configured to idle with respect to the sheet S1 being printed.

  A sheet folding device 201 is configured by the conveyance roller units 15 and 16, the folding conveyance path 17, the folding roller 11, the folding plate 8, the stopper 9, and the folding knife 10.

  3 is a top view showing the folding sheet feeding mechanism 3 and the transport roller unit 15, and FIG. 4 is a cross-sectional view taken along the line AA in FIG.

  The folding sheet feeding mechanism 3 includes a sheet feeding plate 21 and a separation feeding mechanism 5. The sheet feeding plate 21 is a plate-like member, and a sheet bundle S0 is stacked on the sheet feeding plate 21 in an inclined state so that the upper sheet is located forward. A conveying plate 30 is provided so as to be continuous from the upper surface of the sheet feeding plate 21 in the sheet feeding direction, and a portion of the sheet bundle S0 that is closer to the downstream side in the sheet feeding direction (right side in FIG. Placed on top.

  The separation feeding mechanism 5 includes a paper feeding roller 22 that feeds the uppermost sheet S1, a buckling plate 23 that presses against the paper feeding roller 22 from below, and an auxiliary paper feeding roller provided upstream of the paper feeding roller 22 in the paper feeding direction. 24, a paper feed shaft 31 that supports the paper feed roller 22, a bracket 25 that supports the shaft of the auxiliary paper feed roller 24, and a drive transmission mechanism from the paper feed shaft 31 to the auxiliary paper feed roller 24.

  The vicinity of both ends of the paper feed shaft 31 is supported by subframes 32 and 32, and the paper feed roller 22 is supported slightly to the right in FIG. 3 from the center in the axial direction. The outer sides of the sub frames 32 and 32 are covered with covers 33 and 33, and a motor M 1 directly connected to the paper feed shaft 31 is accommodated in one cover 33. The outer surfaces of the covers 33 and 33 are detachably supported by the inner surfaces of the frames 34 and 34 of the main body of the collating apparatus 1 by a support mechanism (not shown). The subframes 32 and 32 are connected to the sheet feeding plate 21. The conveyance plate 30 is also supported, so that the sheet feeding plate 21, the conveyance plate 30, and the separation feeding mechanism 5 can be attached to and detached from the collating apparatus 1 body together with the sub frames 32 and 32.

  A bracket 25 is supported on the paper feed shaft 31 adjacent to the paper feed roller 22 in the width direction. The bracket 25 has a box shape with an open bottom, and the paper feed shaft 31 and the support shaft of the auxiliary paper feed roller 24 pass through the bracket 25. Inside the bracket 25, a toothed pulley 26 fixed to the paper feeding shaft 31 and a toothed pulley 27 fixed to the shaft of the auxiliary paper feeding roller 24 are provided, and a toothed belt 28 is hung between them. . While a one-way clutch is interposed between the sheet feeding roller 22 and the auxiliary sheet feeding roller 24 and the respective support shafts, the rotational driving force of the sheet feeding shaft 31 can be transmitted to the auxiliary sheet feeding roller 24. It is possible to idle in the counterclockwise direction shown in FIG.

  With this configuration, the uppermost sheet S1 is fed between the paper feed roller 22 and the suction plate 23 by the auxiliary paper feed roller 24, and further downstream (right side shown in FIG. 4) by the paper feed roller 22. Sent out. The paper feed roller 22 is made of silicon rubber, and the bottom plate 23 is made of urethane rubber. The frictional force between the paper feed roller 22 and the paper S1> the frictional force between the paperboard 23 and the paper S1> the frictional force between the papers S1. It is made of a material that establishes a relationship. As a result, the paper S1 is fed out by the frictional force between the paper feed roller 22 and the paper S1, and the feeding of the next and subsequent sheets is prevented by the frictional force between the paper plate 23 and the subsequent and subsequent sheets. Only one sheet S1 passes through the feed roller 22 and the baffle plate 23 and is sent out on the transport plate 30 to the downstream side.

  The rollers 35 are provided on both sides of the paper feed roller 22 and are supported by the paper feed shaft 31 so as to make contact with the uppermost paper S1 and compensate for the force with which the paper S1 is conveyed.

  The folding sheet feeding mechanism 3 is configured as described above. The paper feed mechanism 2 also has the same configuration as the folding paper feed mechanism 3.

  A conveyance roller unit 15 is provided on the downstream side of the folding paper feeding mechanism 3. Further, a double feed detection sensor 40 is provided on the downstream side of the transport roller unit 15. The double feed detection sensor 40 includes a transmitting element 40a that emits ultrasonic waves and a receiving element 40b that receives ultrasonic waves transmitted from the transmitting element 40a. When the paper passes between the oscillation element 40a and the receiving element 40b, the amplitude of the ultrasonic wave reaching the receiving element 40b through the paper is different between the case of one sheet and the case of two sheets, It detects whether only one sheet is normally sent or two sheets are overlapped.

  FIG. 5 is a view of the transport roller unit 15 as seen from the BB plane in FIG. The transport roller unit 15 is provided with an upper transport shaft 151 on the upper side and a lower transport shaft 152 on the lower side across the sheet transport surface, and parallel to each other with the direction perpendicular to the transport direction as the axial direction. An upper transport roller 153 and a lower transport roller 154 are fixedly supported on the upper transport shaft 151 and the lower transport shaft 152, respectively, so that the paper fed from the folding paper feeding mechanism 3 is sandwiched and transported further downstream. In addition, a nip is formed. The upper conveyance roller 153 and the lower conveyance roller 154 are wider than the paper feed roller 22, and are provided at positions where the center line in the width direction substantially coincides with the paper feed roller 22. The upper conveyance roller 153 and the lower conveyance roller 154 are rubber rollers in which at least the outer ring portion is formed of rubber.

  Both the upper conveyance shaft 151 and the lower conveyance shaft 152 are applied with a driving force from a main motor that is constantly rotating during operation of the collating apparatus by a drive transmission mechanism (not shown), and are rotating in the opposite directions at the same rotation number. . The upper conveyance roller 153 and the lower conveyance roller 154 are formed to have the same diameter so that the outer circumferences do not slip.

  Rollers with upper streaks 155 and 156 are fixedly supported on the upper transport shaft 151 on both sides in the width direction of the upper transport roller 153, and rollers with lower streaks 157 and 158 are disposed on both sides in the width direction of the lower transport roller 154. Each is supported by the transport shaft 152. The lower streaks 157 and 158 are provided outside the upper streaks 155 and 156, respectively, by a predetermined distance. A key 161 is inserted between the upper streaks 155 and 156 and the upper transport shaft 151 so that the upper streaks 155 and 156 do not rotate relative to the upper transport shaft 151. A keyway for receiving the key 161 is formed on the inner peripheral surface of the upper streaks 155 and 156 and the outer peripheral surface of the upper transport shaft 151.

  The upper streaked roller 155 and the lower streaked roller 157 have the same diameter, and have slightly larger outer diameters than the upper transport roller 153 and the lower transport roller 154. Therefore, the height position of the lower end of the outer peripheral surface of the upper streaked roller 155 is lower than the height position of the upper end of the outer peripheral surface of the lower streaked roller 157. 6 is an enlarged view of the roller 155 with the upper line and the roller 157 with the lower line in FIG. In FIG. 6, a circle indicating the outer periphery of the upper streaked roller 155 overlaps with a circle indicating the outer periphery of the lower streaked roller 157, and the maximum overlapping width in the height direction is d1. In the present embodiment, d1 = 1 mm.

  FIG. 7 is an enlarged view of the upper streaked roller 155 and the lower streaked roller 157 in FIG. As shown in FIG. 7, the upper streaked roller 155 is between the first position 155x close to the lower streaked roller 157 and the second position 155y farther from the lower streaked roller 157 than the first position 155x. Can be moved along the axial direction of the upper conveying shaft 151. In this embodiment, the distance d2 from the right end surface of the upper streaked roller 155 in FIG. 7 to the left end surface of the lower streaked roller 157 in FIG. 7 is 0.5 mm at the first position 155x and at the second position 155y. Is 4 mm. Further, a stopper 159a is provided on the upper transport shaft 151 so that the upper streaked roller 155 does not move to the right in FIG. 7 from the first position 155x. Similarly, a stopper 159b is provided so that the upper streaked roller 155 at the second position 155y does not move to the left in FIG.

  FIGS. 8A and 8B are views showing a cross section of a portion where the upper streaked roller 155 is supported by the upper conveying shaft 151. FIG. 8A shows the upper streaked roller 155 at the first position 155x. FIG. 8B shows a state where the upper streaked roller 155 is at the second position 155y. FIG. 8C is a diagram showing an appearance of the upper conveyance shaft 151 that supports the roller 155 with the upper streak, with the upper streaked roller 155, the lower streaked roller 157, and the stoppers 159a and 159b removed. is there.

  As shown in FIGS. 8A and 8B, the upper streaked roller 155 is configured by providing an outer ring 155b outside the inner ring 155a, and is fixed to each other by a screw 155c. Two holes 155d and 155e are formed through the inner ring 155a from the outer peripheral surface to the inner peripheral surface. Inside the hole 155d, a pressing spring 155f and a sphere 155h are inserted in this order from the outside. Similarly, a push spring 155g and a sphere 155i are inserted into the hole 155e from the outside in this order. Since the outer ends of the push springs 155f and 155g are in pressure contact with the inner peripheral surface of the outer ring 155b and the inner ends are in pressure contact with the spheres 155h and 155i, the spheres 155h and 155i are urged so as to be in pressure contact with the outer peripheral surface of the upper conveying shaft 151. Has been.

  In FIG. 8A, a recess 151a is formed in a portion of the outer peripheral surface of the upper transport shaft 155 where the sphere 155h is in pressure contact. On the other hand, in FIG. A concave portion 151b is formed in a portion where the spherical body 155i is in pressure contact. The recesses 151a and 151b are both spherical recesses formed on the outer periphery of the upper conveyance shaft 151. By accommodating the spheres 155h and 155i in the recesses 151a and 151b, respectively, the upper streaked roller 155 is moved to the upper conveyance shaft. 151 is positioned in the axial direction.

  As shown in FIG. 8C, the upper transport shaft 155 is arranged with the axial and circumferential positions shifted so that the concave portion 151a corresponds to the first position 155x and the concave portion 151b corresponds to the second position 155y. Has been. The relative positions of the upper conveying shaft 151 and the upper streaked roller 155 are determined by the key 161 so that the positions of the spherical body 155h and the concave portion 151a are aligned. The same applies to the sphere 155i and the recess 151b. The grooves 151e and 151f provided outside these are grooves for fixing the stoppers 159a and 159b, respectively.

  With this configuration, when the upper streaked roller 155 at the first position 155x is moved by hand to the left in FIG. 8C, the sphere 155h has the diameter of the hole 155d against the bias of the spring 155f. By moving outward in the direction and detaching from the recess 151a, it moves to the left along the upper conveying shaft 151. When the second position 155y is reached, it is fitted into the sphere 155i and the recess 151b and positioned at the second position 155y. With this configuration, it is possible to manually move and position between the first position 155x and the second position 155y, and to obtain a click feeling at both the first position 155x and the second position 155y, It can be an easy-to-use device. The key 161 prevents the upper streaked roller 155 from rotating with respect to the upper conveying shaft 151 during movement.

  In this embodiment, the circumferential positions of the recesses 151a and 151b are different from each other. However, the circumferential positions may be the same. In this case, a hole formed in the inner ring 155a is formed in the circumferential direction. It is good also as one place corresponding to a position. In the case of this embodiment, since the first position 155x and the second position 155y are close to each other, if they are formed at the same circumferential position, the recesses are too close to each other, so they are formed at different circumferential positions. Yes.

  3 and 5 is also configured in the same manner as the upper streaked roller 155 shown in FIG. 8, and is separated from the lower streaked roller 158 at the first position close to the lower streaked roller 158. It is configured to be switchable between the second position.

  FIG. 9 is a view showing a state in which the sheet S1 passes between the upper streaked rollers 155 and 156 and the lower streaked rollers 157 and 158. FIG. 9A shows the upper streaked rollers 155 and 156. FIG. 9B shows the case where the upper streaked rollers 155 and 156 are at the second positions 155y and 156y when they are at the first positions 155x and 156x. As shown in FIG. 9A, when the upper streaked rollers 155 and 156 are at the first positions 155x and 156x, that is, when they are close to the lower streaked rollers 157 and 158, respectively, the sheet S1 passing between them. Bends between the respective streaked rollers, and a folding line is formed at the bending point. That is, by bending, the lower end of the roller with the upper streaks 155 comes into contact with the lower end of the right end surface in FIG. 9 and the upper end of the left end surface of the lower streak roller 157 in FIG. 9, and the sheet S1 is bent at the contact point. The folding lines F1 and F2 of the book are formed, and a lower end of the upper end roller 156 is in contact with the lower end of the left end surface in FIG. 9 and the upper end of the lower end roller 158 in FIG. The sheet S1 is bent to form two folding lines F3 and F4, respectively.

  On the other hand, when the upper streaks 155, 156 are at the second positions 155y, 156y, the distance from the lower streaks 157, 158 is large, so the sheet S1 has the upper streaks 155, 156, lower Although the lined rollers 157 and 158 come into contact with each other, no folds are formed.

  As described above, whether or not the folding lines are formed on the sheet S1 passing between the upper streaks 155 and 156 by switching between the first positions 155x and 156x or the second positions 155y and 146y. It is possible to switch.

  That is, if both the upper streaks 155 and 156 are set to the first position, a total of four folding lines are formed on the passing paper S1 by two folding lines. The positional relationship in the width direction between the upper streaked roller 156 and the lower streaked roller 158 is opposite to that of the upper streaked roller 155 and the lower streaked roller 157. Therefore, when the upper streaked roller 156 is moved to the first position 156x, it is moved to the right as shown in FIG. 9, and when it is moved to the second position 156y, it is moved to the left.

  The pair of the upper streaked roller 155 and the lower streaked roller 157 and the pair of the upper streaked roller 156 and the lower streaked roller 158 are symmetrical with respect to the center in the width direction of the upper transport roller 153 and the lower transport roller 154. Is arranged. With this configuration, since the left and right sides are streaked, it is possible to prevent the sheet S1 from being skewed due to a biased load. The roller 160 is for lightly contacting the upper surface of the sheet S1 to assist the conveyance force.

  The double feed detection sensor 40 is disposed between a pair of the upper streaked roller 155 and the lower streaked roller 157 and a pair of the upper streaked roller 156 and the lower streaked roller 158. The right side of the upper streaked roller 155 and the lower streaked roller 157 and the left side of the upper streaked roller 156 and the lower streaked roller 158 are shown by the bending of the paper passing between the upper streaked roller and the lower streaked roller. In this case, a force in a direction in which the sheet is inclined so as to rise as it moves away from the lined roller acts. As a result, the position in the height direction of the paper is not stable outside the two streaked rollers and is conveyed in a fluttered state. When the paper to be measured is fluttering, the double feed detection sensor does not stabilize the amplitude, and it is difficult to determine whether or not it is a double feed. Between the pair of rollers with upper streaks 155 and rollers with lower streaks 157 and between the pair of rollers with top streaks 156 and rollers with lower streaks 158, both sides are held by the streaks and upper transport rollers Since it is also pinched by 153 and the lower conveyance roller 154, flapping is suppressed. Therefore, stable double feed detection is possible.

  Next, operations of the sheet folding apparatus 201 according to the first embodiment of the present invention configured as described above and the collating apparatus 1 including the sheet folding apparatus will be described. FIG. 10 is a flowchart showing the operation of the collating apparatus 1 according to the first embodiment of the present invention.

  Before operating the collating apparatus 1, the operator previously loads sheets (advertisements) on some or all of the plurality of sheet feeding mechanisms 2 and the folding sheet feeding mechanism 3 (S01). Then, it is determined whether or not a folding line is to be added to the sheets stacked on the folding sheet feeding mechanism 3 (S02). When a crease is to be added (Y in S02), the upper streaks 155 and 156 are manually set to the first position (S03). When a crease is not added (N in S02), the rollers with the upper lines 155 and 156 are manually set to the second position (S04).

  Next, a start switch provided on an operation panel (not shown) or the like that accepts the entire operation of the collating apparatus 1 is pressed (S05). Then, the sheets are fed one by one from the sheet feeding mechanisms 2 on which the sheets are stacked, merge and overlap each other, and move down the vertical conveyance path 7 while forming the sheet bundle S2. Each of the papers to be fed so that the paper is fed with a predetermined time difference from the upper paper feed mechanism 2 toward the lower paper feed mechanism 2 so that the leading edges are aligned when they merge in the vertical conveyance path 7. Is set. Further, one sheet S1 is also fed from the folding sheet feeding mechanism 3 and is fed through the folding conveyance path 17 by the conveyance roller units 15 and 16 to enter between the upper plate 8a and the lower plate 8b of the folding plate 8, and the leading end is Stops by contacting the stopper 9 (S06). The feeding timing of the folding sheet feeding mechanism 3 is set so that the leading edge of the sheet S1 contacts the stopper 9 before the leading edge of the sheet bundle S2 reaches the line from the folding conveyance path 17 to the folding plate 8. .

  Next, immediately before the front end of the sheet bundle S2 reaches the sheet S1, the folding knife 10 feeds the sheet S1 between the nips of the folding rollers 11. Immediately after that, the sheet bundle S2 descends and enters the nip of the folding roller 11 together with the sheet S1. Then, a collation set S in which the sheet bundle S2 is sandwiched inside the folded sheet S1 is formed (S07). The collation set S is further discharged out of the apparatus from the discharge port 13 via the discharge conveyance path 12 (S08).

  When the user presses the stop switch on the operation panel or the like, or the creation of the collation set S for the preset count number is completed (Y in S09), the apparatus is stopped. Otherwise, the process returns to S06 and the collating operation is repeated.

  When the upper streaks 155 and 156 are in the first position, when the paper S1 fed from the folding paper feeding mechanism 3 passes through the transport roller unit 15, a crease is formed in a direction parallel to the transport direction of the paper S1. It is done. As shown in FIG. 11, the folding lines are provided with a total of four folding lines, that is, folding lines F1 and F2 by the upper lined roller 155 and folding lines F3 and F4 by the upper lined roller 156.

  Accordingly, since the waist of the sheet S1 is given by these folding lines and the occurrence of deflection in the direction perpendicular to the transport direction can be prevented, when the leading edge of the sheet S1 hits the stopper 9, the leading edge bends. It is possible to prevent problems that the folding position is shifted or that the folding roller 11 is touched and caught before the folding knife 10 contacts.

  In addition, when a relatively stiff sheet such as a thick sheet or a sheet that has been folded in advance is loaded on the folding sheet feeding mechanism 3, it bends when it comes into contact with the stopper 9 without providing a folding line. There is no. In such a case, it is possible to avoid the crease on the sheet S1 by setting the upper streaks 155 and 156 to the second position. In particular, since the crease lines are conspicuous in the stiff paper, it is desirable to avoid the crease lines.

  Therefore, when a thin and weak sheet is stacked on the folding paper feeding mechanism 3, the folding when the upper streaks 155 and 156 are placed at the first position to apply the folding lines and come into contact with the stopper 9 is provided. The collating set S having a good appearance can be formed, and when stiff paper is stacked on the folding paper feeding mechanism 3, the upper streaks 155 and 156 are set to the second position. It is possible to avoid a noticeable crease.

  In this embodiment, the lower streaks 157 and 158 are fixed to the lower transport shaft 152, and the upper streaks 155 and 156 are moved along the upper transport shaft 151 between the first position and the second position. However, the present invention is not limited to this, and the upper streaked rollers 155 and 156 are fixed to the upper transport shaft 151, and the lower streaked rollers 157 and 158 are moved along the lower transport shaft 152. You may make it move between the 1st position approached with respect to the lined rollers 155 and 156, and the 2nd position separated. Also, the upper streaked roller 155 and the lower streaked roller 157, or the upper streaked roller 156 and the lower streaked roller 158 may be moved together so that they can be moved closer to or away from each other. In short, it is only necessary to shift the positions in the width direction from each other so that the rollers having portions overlapping each other when viewed from the axial direction can be brought close to or separated from each other as long as they do not contact each other.

  In this embodiment, the streaked rollers are provided on both sides of the upper conveyance roller 153 and the lower conveyance roller 154. However, the present invention is not limited to such a configuration, and may be provided on only one of the sides. In this case, in order to prevent the skew of the sheet S1, it is preferable that the grip force of the upper transport roller 153 and the lower transport roller 154 is sufficiently strong.

(Second Embodiment)
Subsequently, a second embodiment of the present invention will be described. The paper folding apparatus and the collating apparatus according to the second embodiment do not have the upper streaked rollers 155 and 156 and the lower streaked rollers 157 and 158 in the first embodiment, and further, the upper transport roller. 153, instead of the lower conveying roller 154, there is a difference that an upper streaked roller 253 and a lower streaked roller 254 are provided. Other configurations are the same as those of the first embodiment. FIG. 12 is a diagram showing the upper streaked roller 253 and the lower streaked roller 254. The same number is attached | subjected to the member same as 1st Embodiment.

  The upper conveying roller 253 is formed with a long and long convex ridge 253a at the center in the width direction, and has a circumferential surface portion 253b on both sides thereof. The lower conveying roller 254 has a groove 254a formed at the center in the width direction, and a circumferential surface portion 254b formed on both sides thereof. The ridge 253a is formed in such a dimension that it can be accommodated in the groove 254a, and the circumferential surface portions 253b and 254b are in pressure contact with each other. As with the upper transport roller 153 and the lower transport roller 154 in the first embodiment, the outer ring portions of the circumferential surface portions 253b and 254b are formed of rubber.

  Therefore, when the sheet S1 is fed between the upper streaked roller 253 and the lower streaked roller 254, a single crease is formed by the ridges 253a and the grooves 254b. Therefore, in the configuration of the present embodiment, similarly to the first embodiment, it is possible to prevent the deflection when the sheet S1 comes into contact with the stopper 9. Of course, the combination of the ridge and the groove may be upside down.

(Third embodiment)
Subsequently, a third embodiment of the present invention will be described. In the paper folding device and the collating device according to the third embodiment, instead of the upper streaked rollers 155 and 156 and the lower streaked rollers 157 and 158 in the first embodiment, rollers with upper streaks 355 and 356, The difference is that it has rollers 357 and 358 with lower lines. FIG. 13 is a view showing the upper streaked rollers 355 and 356 and the lower streaked rollers 357 and 358. The same number is attached | subjected to the member same as 1st Embodiment.

  Each of the upper streaked rollers 355 and 356 has a ridge 355a and 356a at the center in the width direction of the outer peripheral surface, and a combination of the ridge and grooves 357b and 358b formed on the outer peripheral surface of the lower streaked rollers 357 and 358. Thus, two folding lines are given to the sheet S1. Therefore, in the configuration of the present embodiment, similarly to the first embodiment, it is possible to prevent the deflection when the sheet S1 comes into contact with the stopper 9.

  Of course, the combination of the strip and the groove may be upside down, and may be either one pair instead of two pairs in the axial direction. In addition, the streaked roller having the ridges may be detachable, and in the case of a stiff sheet, the streak roller having the ridges may be removed so that the streaks can be released.

(Fourth embodiment)
Subsequently, a fourth embodiment of the present invention will be described. In the paper folding apparatus and the collating apparatus according to the fourth embodiment, instead of the upper streaked rollers 155 and 156 and the lower streaked rollers 157 and 158 in the first embodiment, rollers with upper streaks 455, 456, There are rollers 457 and 458 with lower lines. Further, a double feed detection sensor 440 is provided instead of the double feed detection sensor 40 in the first embodiment.

  FIG. 14 is a view showing, together with the double feed detection sensor 440, rollers with upper stripes 455 and 456 and rollers with lower stripes 457 and 458 according to the fourth embodiment, and the sheet S1 passes therebetween. The same number is attached | subjected to the member same as 1st Embodiment. The upper streaks of rollers 155 and 156 in the first embodiment are disposed inside the bottom streaks of rollers 157 and 158, respectively, whereas the upper streaks of rollers 455 and 456 in the fourth embodiment are respectively It is arrange | positioned on the outer side of the rollers 457 and 458 with a bottom line.

  FIG. 14A shows a state where the upper streaked rollers 455 and 456 are in the first positions 455x and 456x close to the lower streaked rollers 457 and 458, respectively, and FIG. 14B shows the upper streaked rollers 455 and 456. Indicates a state in which the second positions 455y and 456y are spaced apart from the rollers 457 and 458 with the lower streak, respectively. As in the first embodiment, the distance between the opposing surfaces of the upper and lower streak rollers at the first and second positions is 0.5 mm at the first position and 4 mm at the second position. . Further, the upper streaked rollers 457 and 458 can be manually selected and moved between the first position and the second position by the same mechanism as in the first embodiment.

  As shown in FIG. 14A, when the upper streaked rollers 455 and 456 are at the first positions 455x and 456x, the sheet S1 passing between them is bent between the respective streaked rollers and the bent The folding lines F5 to F8 are formed at the points. On the other hand, when the upper streaks 455 and 456 are at the second positions 455y and 456y, the sheet S1 contacts the upper streaks 455 and 456 and the bottom streaks 457 and 458, but no folding lines are formed. .

  The double feed detection sensor 440 is provided on the right side of the pair of the upper streaked roller 455 and the lower streaked roller 457. Due to the bending of the sheet passing between the upper and lower barbed rollers, the right side of the upper barbed roller 455 and the lower barbed roller 457 in the direction shown in FIG. However, since the lower surface of the sheet S1 is supported by the conveyance plate 30, the sheet S1 is kept horizontal following the conveyance plate 30, so that stable multifeed detection can be performed. Of course, the double feed detection sensor 440 may be provided on the left side of the upper streaked roller 456 and the lower streaked roller 458 in the drawing.

  As described above, of the upper streaked roller 455 and the lower streaked roller 456 that are paired at the closest position in the width direction from the double feed detection sensor 440, the upper streaked roller 455 that is close to the double feed detection sensor 440 is formed on the sheet S1. The upper conveying shaft 151 is supported above the conveying surface. By providing a guide member (conveying plate 30) for guiding the sheet surface from the opposite side in the vertical direction with respect to the sheet surface from the upper conveying shaft 151 side, that is, from below, the sheet surface is inclined downward as the distance from the lined roller increases. Since the sheet to be tried is guided by the guide member and the inclination is suppressed, stable double feed detection can be performed. When the upper streaked roller and the lower streaked roller are opposite in the width direction, a guide member for guiding the upper side of the sheet may be provided.

  FIG. 15 shows a modification of the fourth embodiment, in which the roller with upper streak 456 and the roller with lower streak 458 in the fourth embodiment are omitted, and a roller with upper streak 455 and a roller with lower streak 457 are shown. Just do the streaking. Accordingly, the only folding lines to be applied are F7 and F8. Thus, even if there is only one pair of the roller with the upper streak and the roller with the lower streak, the effect of preventing the buckling of the paper by the folding line and preventing the paper from being caught in the folding roller is obtained.

  Note that the deformation of the paper due to the streaks also affects the result of the ultrasonic double feed detection, and the double feed detection becomes difficult. Therefore, in any of the above-described embodiments, the position in the width direction and the position with the line for ultrasonic double feed detection are different positions in the width direction.

   DESCRIPTION OF SYMBOLS 1 Collating apparatus, 2a-2t paper feeding mechanism, 3 folding paper feeding mechanism, 8 folding plate, 9 stopper, 10 folding knife, 11 folding roller, 15 conveyance roller unit, 17 folding conveyance path, 21 paper feeding plate, 22 paper feeding Roller, 153 Upper conveying roller, 154 Lower conveying roller, 155, 156 Upper streaked roller, 157, 158 Lower streaked roller, 253 Upper streaked roller, 254 Lower streaked roller, 355, 356 Upper streaked roller, 357, 358 Roller with lower stripe, 455,456 Roller with upper stripe, 457,458 Roller with lower stripe, S collating set, S1 paper, S2 paper bundle

Claims (10)

A pair of folding rollers that sandwich the paper and make a crease;
A transport path for transporting paper facing the entrance to the nip of a pair of folding rollers;
A creasing means for providing a folding line in a direction perpendicular to the fold line provided by the folding roller, with respect to the sheet conveyed through the conveyance path;
Note the stopping means the folding muscle conveyed on the conveying path is stopped by contact with the conveying direction leading edge of the paper granted,
A folding knife that abuts against the paper stopped by the stopping means and guides the paper to the nip of a pair of folding rollers ;
Sheet folding apparatus characterized by having a.   2. The sheet folding device according to claim 1, wherein the creasing means is provided on the upstream side in the transport direction with respect to the portion of the transport path facing the entrance to the nip of the pair of folding rollers. . A transmitting element that transmits ultrasonic waves and a receiving element that receives the ultrasonic waves are arranged opposite to each other across the paper conveyance line, and at least the ultrasonic waves transmitted by the transmitting element are received by the receiving element when the paper passes. An ultrasonic multi-feed detection sensor for detecting whether the passing paper is one sheet or two or more sheets depending on whether or not the amplitude exceeds a predetermined value is provided downstream of the scoring means and The sheet folding device according to claim 1 , wherein the sheet folding device is provided at a position different from the creasing means in the width direction. The creasing means is
An upper streaked roller that comes into contact with the upper surface of the paper conveyed through the conveyance path;
An upper streaked roller and a lower streaked roller provided at substantially the same position in the transport direction and at different positions in the width direction and contacting the lower surface of the paper transported through the transport path;
The lowermost position of the outer peripheral surface of the upper streaked roller is located below the uppermost position of the outer peripheral surface of the lower streaked roller, and the sheet conveyed between the end surfaces facing each other in the width direction is sandwiched between them. The sheet folding device according to any one of claims 1 to 3 , wherein the end faces are provided close to each other so as to make a line. The position in the width direction of one of the upper streaked roller and the bottom streaked roller can be switched between a first position where the end faces are close to each other and a second position which is separated from the first position. The sheet folding device according to claim 4 , wherein the sheet folding device is configured as follows. Of the roller with the upper streak and the roller with the lower streak paired at the closest position in the width direction from the multi-feed detection sensor, the paper surface with respect to the support shaft side that supports the streak roller closer to the multi-feed detection sensor 6. A sheet folding apparatus according to claim 4, further comprising a guide member for guiding the sheet surface from the opposite side in the vertical direction across the sheet. A pair of upper muscle with rollers and a lower muscle with rollers are provided two or more pairs, the double feed detection sensor, to any one of claims 4 to 6, characterized in that provided in the intermediate position in the width direction The paper folding apparatus described.   The scoring means is provided on one surface side of the sheet conveyed through the conveyance path, provided on the other surface side of the sheet, a convex roller provided with a circumferential protrusion that goes around the outer peripheral surface, and The sheet folding apparatus according to claim 1, further comprising a concave roller having a circumferential groove provided on an outer peripheral surface so as to receive a protrusion of the convex roller. The urging muscle means, the conveying roller pair and coaxial to convey by sandwiching rotating the sheet from above and below, to any claims 1 to 8, characterized in that it is symmetrically arranged on both sides with respect to the conveying roller pair The paper folding apparatus described. A plurality of sheet feeding mechanisms that stack sheets one by one from the stacked sheet bundle are stacked in the vertical direction, and the sheets fed from each sheet feeding mechanism are stacked while being conveyed downward,
2. A folding sheet feeding mechanism that feeds folded sheets one by one from the stacked sheet bundle further below the plurality of sheet feeding mechanisms, and a folding sheet fed from the folding sheet feeding mechanism for folding the folded sheet in two. The sheet folding device according to any one of claims 9 to 9 is provided, and when the folded sheet is folded in two by being sandwiched between the nips of the pair of folding rollers, the sheet is fed from each sheet feeding mechanism inside the folded sheet. The collating apparatus is configured such that the stacked sheets are inserted to form a set of bundles.

Images