JP2021045808A - Post-processing device and image formation system - Google Patents

Abstract

To prevent the occurrence of the drop failure of cutting dust generated in cutting processing and the conveyance failure of a created product.SOLUTION: A post-processing device comprises: a CD cutting unit 100 which has a pair of cutting blades 101a, 101b arranged on the upper and lower sides with a conveyance path D1 held therebetween and can cut a portion of a sheet conveyed along the conveyance path as cutting dust; and an air blower unit 106 which blows the air in the direction along the inclined surface of the tip of the cutting blade (lower blade 101b) on the lower side at the cutting position where the pair of cutting blades 101a, 101b cuts the sheet.SELECTED DRAWING: Figure 6

Description

The present invention relates to an aftertreatment device and an image forming system.

Conventionally, a post-processing apparatus has been used in which a sheet on which an image is formed by an image forming apparatus is subjected to a cutting process such as cutting an end portion of the sheet or dividing the sheet into a plurality of regions. The aftertreatment device includes a cutting portion having an upper blade and a lower blade, and a waste box for storing cutting waste generated by cutting is installed below the cutting portion.

In such an aftertreatment device, it is preferable that the cutting waste generated by cutting is smoothly collected in the waste box, and in order to promote the falling of the cutting waste, for example, on the side where the upper blade and the lower blade rub against each other A technique of blowing air toward the blade from above has been proposed (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2006-205309

However, as in Patent Document 1, simply blowing wind from above is insufficient for paper charged with static electricity. In particular, if the cutting width (FD length: length in the transport direction) of the cutting waste is short, there is a high possibility that the cutting waste will be electrostatically adsorbed on the lower blade of the cutting portion, resulting in a drop failure. It is conceivable to increase the air volume in order to stably drop the cutting debris electrostatically adsorbed on the lower blade, but in some cases a considerable amount of air may be required, and the tip of the product created by the cutting process by that wind. May be sprayed downward (dust falling direction), resulting in poor transportation.

An object of the present invention is to provide a post-processing device and an image forming system capable of preventing the occurrence of a drop defect of cutting waste generated by a cutting process and a transfer defect of a created product product.

In order to solve the above problems, the aftertreatment device of the present invention is used.
A cutting portion having a pair of cutting blades arranged one above the other across a transport path and capable of cutting off a part of a sheet transported along the transport path as cutting scraps.
At the cutting position where the pair of cutting blades cut the sheet, a blower portion that sends air in a direction along the slope of the tip of the lower cutting blade, and a blower portion.
It is characterized by having.

Further, the image forming system of the present invention is
An image forming device that forms an image on a sheet,
With the above post-processing device
It is characterized by having.

According to the present invention, it is possible to prevent the drop failure of the cutting waste generated by the cutting process and the transfer failure of the created product.

It is a block diagram of the image formation system in this embodiment. It is an enlarged view which shows the composition of the main part of a CD cutting part. (A) is a perspective view of the guillotinecutter, (b) is an enlarged view of the central portion of the lower blade of the guillotinecutter, and (c) is a cross-sectional view taken along the line cc of (b). .. It is a perspective view of the upstream guide part. It is a perspective view of the waste guide part. It is a figure for demonstrating the blower part. It is a block diagram which shows the functional structure of an image formation system. It is a figure for demonstrating the cutting mode. It is a figure for demonstrating the movement of the CD cutting part at the time of cutting a paper tip part. It is a figure for demonstrating the movement of the CD cutting part at the time of cutting the rear end part of a paper. It is a figure for demonstrating the movement of the CD cutting part at the time of cutting the central part of a paper. It is a figure for demonstrating the movement of the CD cutting part at the time of jam processing.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, the scope of the invention is not limited to the illustrated examples.

<Structure>
FIG. 1 is a configuration diagram of an image forming system 1 according to an embodiment of the present invention. The image forming system 1 includes an image forming device 10 that forms an image on paper as a sheet, and a post-processing device 20 that performs a cutting process on the paper on which an image is formed by the image forming device 10. ..
The image forming system 1 in the present invention includes both a case where the image forming apparatus 10 and the post-processing apparatus 20 which are individually configured are connected and a case where they are integrally configured. obtain.

The image forming apparatus 10 forms an image on paper according to an operation instruction input from the operation display unit 18 or an image forming instruction received from a PC (Personal Computer) or the like via a communication network. The image forming apparatus 10 carries out the image-formed paper to the post-processing apparatus 20.
The image forming apparatus 10 includes a paper feeding unit 15, an image reading unit 16, an image forming unit 17, an operation display unit 18, and the like.

The paper feed unit 15 includes a plurality of paper feed trays T1 to T3 capable of storing papers having different sizes, types (paper types), basis weights, etc., and the papers stored in the designated paper feed trays T1 to T3. Is supplied to the image forming unit 17.

The image reading unit 16 reads the original and generates image data. Specifically, the image reading unit 16 reads the reflected light emitted from the light source and reflected by the document by a CCD (Charge Coupled Device) image sensor or the like.

The image forming unit 17 forms an image on the paper. The image forming unit 17 charges the photoconductor with a charging unit, exposes and scans the photoconductor with a laser beam emitted by the exposed unit based on the image data to form an electrostatic latent image, and the developing unit performs electrostatic latent image. The image is developed with toner, the toner image is transferred to the paper by the transfer portion, and the toner image is fixed on the paper by the fixing portion.

The operation display unit 18 is composed of an LCD (Liquid Crystal Display), and includes a display unit for displaying various screens, and an operation unit composed of a touch panel and various keys stacked on the display unit. The operation display unit 18 outputs an operation signal input by a touch operation or a key operation to the CPU (Central Processing Unit) 11 (see FIG. 7).

The aftertreatment device 20 is a cutting machine that performs a cutting process on paper. The post-processing device 20 performs a cutting process on the paper carried in from the image forming device 10 as necessary, and discharges the product created by the cutting process to the paper output trays T11, T12 or the card tray T13.
The aftertreatment device 20 includes a transport path D1, a cutting section 26, a sensor 27, a waste box 29, and the like.

The transport path D1 is provided with a long paper transport path D2 that branches off from the transport path D1 and merges downstream thereof. The long paper transport path D2 is used as a buffer when transporting long paper.

The cutting unit 26 performs a cutting process for cutting the paper to be conveyed. The cutting section 26 includes FD cutting sections 26a and 26b and a CD cutting section 100 at a plurality of positions of the paper transport path D1.
The FD cutting portions 26a and 26b are slitters that cut the paper along the feed direction. The FD cutting portion 26a includes a top-bottom slitter that cuts end portions (back side / front side) in a direction orthogonal to the paper transport direction. The FD cutting unit 26b includes a dove cutting slitter that cuts a margin between adjacent deliverables in a direction orthogonal to the paper conveying direction.
The CD cutting unit 100 includes a guillotine cutter that cuts paper along a direction (Cross Direction) orthogonal to the transport direction.

Whether or not the FD cutting units 26a and 26b and the CD cutting unit 100 are used is determined according to the cutting mode. The cutting mode refers to a cutting control method determined by the cutting type, paper size, type, basis weight, and the like.

The FD cutting portions 26a and 26b and the CD cutting portion 100 constituting the cutting portion 26 may be modularized and detachable from the main body of the post-processing device 20. In this case, the arrangement order of each module can be changed.

The sensor 27 detects the cutting waste at a predetermined position in the waste box 29 in the depth direction (Z direction shown in FIG. 1), and outputs the detection result to the CPU 21 (see FIG. 7). That is, the sensor 27 detects that the cutting waste is loaded in the waste box 29 to a certain amount.

The waste box 29 is installed below the cutting unit 26, and stores the cutting waste generated by the cutting operation by the cutting unit 26 and falling from the cutting unit 26. The user opens the door of the aftertreatment device 20, takes out the waste box 29, and discards the cutting waste in the waste box 29.

Here, the detailed configuration of the CD cutting unit 100 will be described.
FIG. 2 is an enlarged view showing a main part configuration of the CD cutting unit 100.
As shown in FIG. 2, the CD cutting portion 100 includes, for example, a guillotine cutter 101 having an upper blade 101a and a lower blade 101b extending along the CD direction of the transport path D1, and an upstream side of the lower blade 101b in the FD direction. The upstream guide portion 103 provided in the FD, the downstream guide portion 104 provided on the downstream side of the lower blade 101b in the FD direction, and the waste guide portion 105 provided at a position facing the upstream guide portion 103 across the transport path D1. It is provided with a blower unit 106 that blows wind near the cutting position of the paper by the upper blade 101a and the lower blade 101b, and an auxiliary blower unit 108 (see FIG. 6) that additionally blows wind near the cutting position.

FIG. 3A is a perspective view of the guillotinecutter 101, FIG. 3B is an enlarged view of the central portion of the lower blade 101b of the guillotinecutter 101, and FIG. 3C is FIG. 3B. It is sectional drawing of the lower blade 101b in line cc of).
As shown in FIG. 3A, the guillotine cutter 101 includes an upper blade 101a arranged above the transport path D1 and a lower blade 101b arranged below the transport path D1. The guillotine cutter 101 is arranged so that its longitudinal direction is perpendicular to the transport path D1, and the upper blade 101a moves downward with respect to the fixed lower blade 101b, so that the upper blade 101a and the lower blade 101a are lowered. The paper is cut at the cutting position sandwiched between the blades of the blade 101b.
As shown in FIG. 3B, a plate body 102, which is an auxiliary member for preventing sticking of cutting debris generated by cutting, is provided at the central portion of the lower blade 101b in the longitudinal direction.
As shown in FIG. 3C, the plate body 102 is provided at the upper end portion of the lower blade 101b so that the upper end portion 102a of the plate body 102 floats from the tip slope (rake surface) 101c of the lower blade 101b. is set up. As a result, a gap is formed between the lower blade 101b and the generated cutting waste, and the cutting waste is prevented from sticking to the lower blade 101b.

FIG. 4 is a perspective view of the upstream guide unit 103.
As shown in FIG. 4, the upstream guide section 103 is a long member including a transport guide section 103a and a drop path forming section 103b, and either the transport guide section 103a or the drop path forming section 103b functions. A variable mechanism 103c (see FIG. 2) that moves (swings) the upstream guide portion 103 is provided so as to be in a position where the upstream guide portion 103 is moved.
The upstream guide portion 103 is installed below the transport path D1 on the upstream side in the FD direction with respect to the lower blade 101b so that its longitudinal direction is along the CD direction.
The upstream guide unit 103 is swingable around the rotation shaft R1 (see FIG. 2), and forms a "transport guide position" for functioning as a paper transport guide and a transport path (fall path) for cutting waste. Can be either a "path formation position" for.

The “transport guide position” is a position in which the transport guide portion 103a of the upstream guide portion 103 is arranged in parallel along the transport path D1. The “path forming position” means that the upstream guide portion 103 rotates counterclockwise by a predetermined angle from the “conveying guide position”, so that a space serving as a transport path for cutting waste is provided in the transport path D1 on the upstream side of the lower blade 101b. It is the position to be formed.
Further, as shown in FIG. 4, ribs 103d extending in the vertical direction are provided on the upstream guide portion 103 at predetermined intervals in the longitudinal direction to prevent cutting debris falling from the transport path from sticking to the upstream guide portion 103. It has become so.
Further, the variable mechanism 103c includes, for example, a rotation shaft R1 that pivotally supports the upstream guide portion 103, a motor that rotates the rotation shaft R1, and the like, and swings the upstream guide portion 103 as described above under the control of the CPU 21. Let me.

Returning to FIG. 2, the downstream guide portion 104 is a long member including the transport guide portion 104a and the drop path forming portion 104b, and either the transport guide portion 104a or the drop path forming portion 104b functions. A variable mechanism 104c that moves (swings) the downstream guide portion 104 so as to be in a position is provided.
The downstream guide portion 104 is installed below the transport path D1 on the downstream side in the FD direction with respect to the lower blade 101b so that its longitudinal direction is along the CD direction.
The downstream guide unit 104 is configured to swing around the rotation shaft R2, and has a "transport guide position" for functioning as a paper transport guide and a "path" for forming a transport path (fall path) for cutting waste. It can be either a "forming position" or a "retracted position" for avoiding the operation of the upper blade 101a.

The “transport guide position” is a position in which the transport guide portion 104a of the downstream guide portion 104 is arranged in parallel along the transport path D1. The “path forming position” means that the downstream guide portion 104 rotates clockwise from the “conveying guide position” by a predetermined angle, so that a space serving as a transport path for cutting waste is formed in the transport path D1 on the downstream side of the lower blade 101b. Position. The “retracted position” is a position in which the rotation angle of the downstream guide portion 104 is smaller than that of the “path forming position” and the transport guide portion 104a is retracted from the transport path D1.
Further, the variable mechanism 104c includes, for example, a rotation shaft R2 that pivotally supports the downstream guide portion 104, a motor that rotates the rotation shaft R2, and the like, and swings the downstream guide portion 104 as described above under the control of the CPU 21. Let me.

FIG. 5 is a perspective view of the waste guide portion 105.
As shown in FIG. 5, the scrap guide portion 105 is a long member having a transport guide surface 105a and a scrap guide surface 105b, and a position where either one of the transport guide surface 105a and the scrap guide surface 105b functions. A variable mechanism 105c for moving (swinging) the waste guide portion 105 is provided so as to be.
The waste guide portion 105 is installed above the transport path D1 on the upstream side in the FD direction with respect to the upper blade 101a so that its longitudinal direction is along the CD direction. The waste guide portion 105 is arranged at a position substantially facing the upstream guide portion 103.
The waste guide portion 105 is swung around the rotation shaft R3 (see FIG. 2) and has a "conveyance guide position" for functioning as a paper transport guide and a "dust guide position" for suppressing the soaring of cutting waste. , "Jam processing position" to enable jam processing when jam occurs.

The “transport guide position” is a position in which the transport guide surface 105a of the waste guide portion 105 is arranged in parallel along the transport path D1. The “dust guide position” is a position in which a guard covering the lower blade 101b is formed above the lower blade 101b by rotating the waste guide portion 105 counterclockwise by a predetermined angle from the “conveying guide position”. The “jam processing position” is a position that forms a space for jam processing on the upstream side of the lower blade 101b by rotating clockwise from the “conveying guide position” of the waste guide unit 105 by a predetermined angle.

Further, as shown in FIG. 5, ribs 105d extending in the vertical direction are provided on the scrap guide surface 105b at predetermined intervals in the longitudinal direction to prevent cutting scraps from sticking. There is.
Further, an opening 105e is formed in the waste guide surface 105b so that the wind from above can escape through the opening 105e, and it is possible to prevent the cutting waste from being vertically oriented by blowing the wind. ing.
Further, the variable mechanism 105c includes, for example, a rotating shaft R3 that pivotally supports the scrap guide portion 105, a motor that rotates the rotating shaft R3, and the like, and swings the scrap guide portion 105 as described above under the control of the CPU 21. Let me.

FIG. 6 is a diagram for explaining the blower unit 106 and the auxiliary blower unit 108.
The blower portion 106 is a mechanism for blowing air toward the cutting position sandwiched between the blades of the upper blade 101a and the lower blade 101b from diagonally above the downstream side of the cutting position.
The blower unit 106 includes, for example, a fan 106a that generates wind, a blower passage 106b that is a distribution path for the generated wind, and a shutter member 106c as an adjustment mechanism provided in the blower passage 106b.

The fan 106a may have any configuration as long as it can generate a predetermined amount of air. That is, it may be one fan, or a plurality of fans may be combined.

The air passage 106b is set so that the wind is blown from diagonally above on the downstream side toward the cutting position sandwiched between the upper blade 101a and the lower blade 101b. Specifically, the wind blowing direction is set so that the wind flows from diagonally above the downstream side of the upper blade 101a along the tip slope (rake surface) 101c of the lower blade 101b through the cutting position. .. By controlling the flow of wind in this way, it is possible to make it easier for the cutting debris to fall.

The shutter member 106c is configured to swing around the fulcrum R4 by a drive unit (not shown), and has an open position where the wind flows out from the air passage 106b and a closed position where the wind from the air passage 106b is blocked from flowing out. Can work between. FIG. 6 shows a state in which the shutter member 106c is in the open position. The state in which the shutter member 106c is in the closed position is shown in FIG. 2, for example.
By opening and closing the shutter member 106c in this way, it is possible to start and stop blowing the wind toward the cutting position.

The auxiliary blower unit 108 includes, for example, an auxiliary fan 108a that generates wind.
The auxiliary fan 108a has a smaller air volume than the fan 106a, and blows air from above to the position where the lower blade 101b is installed through a ventilation path different from the ventilation path 106b of the fan 106a.
The wind sent from the auxiliary fan 108a collides with the waste guide portion 105 and passes through the opening 105e of the waste guide portion 105. Therefore, it is possible to easily drop the cutting waste. The air passage of the auxiliary fan 108a is also provided with an adjustment mechanism (shutter member) similar to that of the shutter member 106c, so that the blowing of wind toward the cutting position can be started and stopped.

In the above configuration, the upstream guide unit 103, the downstream guide unit 104, and the waste guide unit 105 are independently movable (swinging), and are in predetermined positions according to the cutting mode.
Blowers from the blower unit 106 and the auxiliary fan 108a are also started and stopped according to the cutting mode.
Further, a fixedly installed transport guide 107 (see FIG. 2) is provided at a position substantially facing the downstream guide portion 104 across the transport path D1.

FIG. 7 is a block diagram showing a functional configuration of the image forming system 1.
The image forming apparatus 10 includes a CPU 11, a ROM (Read Only Memory) 12, a RAM (Random Access Unit) 13, a storage unit 14, a paper feeding unit 15, an image reading unit 16, an image forming unit 17, an operation display unit 18, and a communication I. / F (InterFace) 19 and the like are provided. The functional parts already described will be omitted.

The CPU 11 reads the program stored in the ROM 12 and expands it in the RAM 13, and controls the operation of each part of the image forming apparatus 10 in cooperation with the expanded program.
The ROM 12 is composed of a non-volatile semiconductor memory or the like, and stores a system program, various processing programs that can be executed on the system program, various data, and the like.
The RAM 13 is composed of a volatile semiconductor memory or the like, and forms a work area for temporarily storing a program, input or output data, parameters, etc. read from the ROM 12 in various processes executed by the CPU 11. ..

The storage unit 14 is composed of an HDD (Hard Disk Drive), a non-volatile semiconductor memory, or the like, and stores various data.
The communication I / F 19 is composed of a NIC (Network Interface Card), a modem, or the like, and transmits / receives data to / from the post-processing device 20 or a PC.

The post-processing device 20 includes a CPU 21, a ROM 22, a RAM 23, a storage unit 24, a paper transport unit 25, a cutting unit 26, a sensor 27, a communication I / F 28, and the like.

The CPU 21, ROM 22 and RAM 23 are the same as the CPU 11, ROM 12 and RAM 13 except that the control target of the CPU 21 is the post-processing device 20.

The storage unit 24 is composed of an HDD, a non-volatile semiconductor memory, or the like, and stores various data.

The paper transport unit 25 transports the paper carried in from the image forming apparatus 10 until it is discharged to the output trays T11, T12 or the card tray T13.
The communication I / F 28 is composed of a NIC, a modem, or the like, and transmits / receives data to / from the image forming apparatus 10.

<Operation>
Next, the cutting process executed by the cutting unit 26 will be described.
Here, the cutting mode will be described with reference to FIGS. 8A to 8D.
FIG. 8A is an example of cutting in the four-way cutting mode. The four-way cutting mode is a mode in which the four edges of the paper are cut to create one product from one sheet of paper. Specifically, both ends (back end, front end) of the paper in the CD direction are cut by the FD cutting portion 26a. Further, the front end side end portion and the rear end side end portion in the FD direction of the paper are cut by the CD cutting portion 100.

8 (b) to 8 (d) are cutting examples in the multiple cutting mode. The multiple cutting mode is a mode in which, in addition to the four edges of the paper, the paper is cut at one or more places along the FD direction or the CD direction to create a plurality of deliverables from one sheet.
In the multiple cutting mode in which the A4 size paper shown in FIG. 8B is divided into two in the FD direction, both ends (back end and front end) of the paper in the CD direction are cut by the FD cutting portion 26a. To. Further, the margins between the front end side end portion and the rear end side end portion in the FD direction of the paper and the deliverables adjacent to each other in the FD direction are cut by the CD cutting portion 100.

In the card-making multiple cutting mode shown in FIG. 8C, both ends (back end and front end) of the paper in the CD direction are cut by the FD cutting portion 26a. Further, the margin between the deliverables adjacent to each other in the CD direction of the paper is cut by the FD cutting unit 26b. Further, the margins between the front end side end portion and the rear end side end portion in the FD direction of the paper and the deliverables adjacent to each other in the FD direction are cut by the CD cutting portion 100.

In the multiple cutting mode for creating a business card shown in FIG. 8D, both ends (back end and front end) of the paper in the CD direction are cut by the FD cutting portion 26a. Further, the margin between the deliverables adjacent to each other in the CD direction of the paper is cut by the FD cutting unit 26b. Further, the margins between the front end side end portion and the rear end side end portion in the FD direction of the paper and the deliverables adjacent to each other in the FD direction are cut by the CD cutting portion 100.

Of course, with respect to the above-mentioned cutting mode, details such as the size of the deliverable and the size of the margin can be set as appropriate. In addition, although the four edges of the paper are cut in all of the examples given here, it is possible to set the edges of the paper not to be cut, and to provide a margin between adjacent deliverables. It can also be set to cut without cutting.

In any of these cutting modes, first, the paper is cut along the FD direction by the FD cutting section 26a and / or the FD cutting section 26b, and reaches the CD cutting section 100. In the CD cutting section 100, when the portion of the paper to be cut reaches the cutting position sandwiched between the blades of the upper blade 101a and the lower blade 101b, the paper transport is temporarily stopped in the middle of the transport path D1 and the guillotine cutter 101 Cuts the paper along the CD direction.

The CD cutting unit 100 cuts the CD cutting unit 100 according to the cutting mode being executed under the control of the CPU 11 and the CPU 21 (position control unit, air volume control unit), that is, depending on which position of the paper is cut. Each of the constituent parts performs a predetermined operation.
Hereinafter, the operation of each part of the CD cutting part 100 according to the cutting position of the paper will be described.

FIG. 9 is a diagram for explaining the movement when cutting the tip end portion of the paper in the FD direction.
As shown in FIG. 9, when cutting the tip of the paper, the downstream guide 104 at the “transport guide position” shown in FIG. 2 rotates clockwise (full rotation) at the same time as the paper is cut by the guillotinecutter 101. , "Path formation position".
As a result, a transport path for cutting waste is formed downstream of the lower blade 101b, and the cutting waste generated by cutting the tip of the paper falls downward without being blocked.
After that, the downstream guide portion 104 returns to the "transport guide position" after the upper blade 101a returns to the initial position until the tip of the deliverable in the FD direction reaches the nip portion of the transport roller downstream of the downstream guide portion 104. Return to.
At the time of cutting the tip of the paper, the upstream guide portion 103 and the waste guide portion 105 do not operate.

When cutting the tip of the paper as described above, the shutter member 106c of the blower portion 106 rotates to the closed position, and the wind from the blower passage 106b is blocked. Alternatively, the rotation angle of the shutter member 106c may be controlled so that the air volume can be reduced. The same applies to the auxiliary blower unit 108.
This is to prevent the lower blade 101b from being caught, broken or jammed by the wind being blown to the tip of the product in the FD direction after cutting and the tip being urged downward. Is the control of.
The blocked or reduced wind may be returned to the original state after the tip of the product in the FD direction reaches the nip portion of the transport roller downstream of the downstream guide portion 104.

Further, the air volume from the air passage 106b may be controlled by the length of the product in the CD direction, the paper basis weight, the paper type, the image information, the presence or absence of curl of the paper, the surrounding environment of the device, and the like. For example, in the case of paper having a basis weight of a predetermined value or more and being judged to be stiff, control such as reducing the amount of reduction in the air volume can be performed because the influence of the air volume is small.
The auxiliary blower 108 can be controlled in the same manner.

FIG. 10 is a diagram for explaining the movement when cutting the rear end portion of the paper in the FD direction.
As shown in FIG. 10, when cutting the rear end of the paper, the downstream guide portion 104 at the “transport guide position” shown in FIG. 2 rotates clockwise (half a turn) at the same time as the paper is cut by the guillotine cutter 101. Then, it becomes the "retract position".
As a result, even when the guillotinecutter 101 and the downstream guide portion 104 are arranged close to each other, it is possible to prevent the operation of the upper blade 101a from being hindered by the minimum operation of the downstream guide portion 104. The “close arrangement” is an arrangement in which the downstream guide portion 104 in the “conveyance guide position” is located below the upper blade 101a, as shown in FIG. 2, for example.
Further, the upstream guide unit 103 and the waste guide unit 105 rotate counterclockwise at the same time as the paper is cut by the guillotine cutter 101, and become the “path forming position” and the “dust guide position”.
As a result, a transport path for cutting waste is formed upstream of the lower blade 101b, and the cutting waste generated by cutting the rear end portion of the paper falls diagonally downward without being blocked. In addition, a guide is formed above the lower blade 101b to suppress the scattering of cutting debris.
After that, after the upper blade 101a returns to the initial position, the downstream guide portion 104 returns the “conveying guide” until the rear end in the FD direction of the deliverable reaches the nip portion of the transport roller downstream of the downstream guide portion 104. Return to "Position". Further, after the upper blade 101a returns to the initial position, the upstream guide portion 103 and the waste guide portion 105 return to the returning "conveying guide position" by the time the tip of the subsequent paper in the FD direction reaches.

At the time of cutting the rear end portion of the paper as described above, the wind is blown from the blower portion 106 so as to flow along the rake face 101c of the lower blade 101b, so that the cutting debris falls smoothly. There is.
Here, since the lower blade 101b is provided with the plate body 102, even if the generated cutting debris is electrostatically adsorbed on the lower blade 101b, it can be peeled off.

Further, even if the cutting debris is blown up by the blowing of wind, the cutting debris is suppressed by the debris guide surface 105b of the debris guide portion 105, and the cutting debris can be stably dropped.
Further, since the wind is blown from the auxiliary blower portion 108 toward the lower blade 101b and the wind escapes through the opening 105e of the waste guide portion 105, it is assumed that the cutting waste is electrostatically adsorbed on the waste guide portion 105. Can also be dropped by this wind.
Further, at this time, since the rib 105d is provided on the waste guide portion 105, the contact area between the waste guide portion 105 and the cutting waste can be reduced, and the adsorption force of electrostatic adsorption can be reduced.
Further, the rib 105d prevents the posture of the cutting debris from being parallel to the direction in which the wind is blown, so that the cutting debris can be stably blown with the wind.

FIG. 11 is a diagram for explaining the movement when cutting the central portion of the paper in the FD direction.
This operation is performed when cutting the margins between the deliverables adjacent to each other in the FD direction in the multiple cutting modes for card creation or business card creation shown in FIGS. 8 (c) and 8 (d). It is an operation. Even in the cutting mode for creating a business card or the like, the cutting of the front end portion and the rear end portion of the paper in the FD direction is the same as the above-described operation (see FIGS. 9 and 10).

For cutting the center of the paper (that is, the margin), cutting is performed twice for each margin.
As shown in FIG. 11, in the cutting of the central portion of the paper, the downstream guide portion 104, which was in the “transport guide position” shown in FIG. 2 at the time of the first cutting, rotates clockwise at the same time as the paper is cut by the guillotine cutter 101. (Full rotation), and it becomes the "path formation position". Then, the downstream guide portion 104 maintains the "path forming position" until all the margins in the FD direction are cut.
As a result, during cutting of one or more margins, a transport path for cutting waste is formed downstream of the lower blade 101b, and the cutting waste of the margin generated by cutting the central portion of the paper falls downward without being blocked.
After that, the downstream guide portion 104 returns to the "transport guide position" after the upper blade 101a returns to the initial position until the tip of the deliverable in the FD direction reaches the nip portion of the transport roller downstream of the downstream guide portion 104. Return to.
At the time of cutting the central portion for this purpose, the upstream guide portion 103 and the waste guide portion 105 do not operate.

At the time of cutting the central portion of the paper as described above, the shutter member 106c of the blower portion 106 is controlled to block the air from the air passage 106b or reduce the air volume in the same manner as when cutting the front end portion of the paper.

Further, although not shown, when cutting the central portion of the paper in the FD direction without leaving a margin, the downstream guide portion 104 in the "transport guide position" is used to cut the paper by the guillotine cutter 101. At the same time, it rotates clockwise (half a turn) to the "retracted position", and after the upper blade 101a returns to the initial position, the downstream guide unit 104 returns "transport" until the tip of the deliverable in the FD direction comes. It suffices if the control to return to the "guide position" is performed.
That is, since cutting dust is not generated, the downstream guide portion 104 may perform the minimum operation so as not to hinder the movement of the upper blade 101a.
At this time, the upstream guide unit 103 and the waste guide unit 105 do not operate.
Further, at the time of cutting without such a margin, the shutter member 106c of the blower portion 106 rotates to the closed position, and the wind from the blower passage 106b is blocked. The same applies to the auxiliary blower unit 108.

In this way, by operating each part of the CD cutting unit 100 according to the cutting mode (according to the cutting position of the paper), it is possible to secure a fall path for the cutting waste without impairing the paper transport stability. It will be possible. Further, by controlling the direction and the amount of the blown wind, it is possible to smoothly drop the generated cutting debris without causing poor transportation of the created product.

When a jam occurs in the CD cutting unit 100, as shown in FIG. 12, the waste guide unit 105 can be rotated clockwise to set the “jam processing position”. Further, at this time, the upstream guide portion 103 can be rotated counterclockwise to obtain the “path formation position”. As a result, a space for jam processing is formed on the upstream side of the lower blade 101b.
At the time of jam processing, the upstream guide unit 103 and the waste guide unit 105 may be manually moved while the operation of the CD cutting unit 100 is stopped.

<Effect>
As described above, according to the present embodiment, there are a pair of cutting blades 101a and 101b arranged vertically with the transport path D1 in between, and a part of the sheet transported along the transport path D1 is cut. At the cutting position where the CD cutting portion 100 that can be cut off as waste and the pair of cutting blades 101a and 101b cut the sheet, the wind is sent in the direction along the slope of the tip of the lower cutting blade (lower blade 101b). A blower unit 106 is provided.
Therefore, it is possible to prevent the occurrence of a drop defect of the cutting waste generated by the cutting process and the occurrence of a transport defect of the created product.

Further, according to the present embodiment, a waste guide portion 105 having a waste guide surface 105b for suppressing the scattering of generated cutting waste is provided above the transport path D1.
Therefore, even if the cutting debris is blown up by the air blown from the air blowing unit 106, it can be suppressed.

Further, according to the present embodiment, the waste guide surface 105b is provided with a rib 105d.
Therefore, it is possible to prevent the cutting waste from sticking to the waste guide surface 105b.

Further, according to the present embodiment, the dust guide portion 105 is provided with an auxiliary blower portion 108 that blows air from above, and the scrap guide surface 105b allows the wind sent from the auxiliary blower portion 108 to escape downward. An opening 105e is formed.
Therefore, it is possible to prevent the cutting waste from sticking to the waste guide surface 105b.

Further, according to the present embodiment, the air volume of the auxiliary air blowing unit 108 is smaller than the air volume of the air blowing unit 106.
If the air volume of the auxiliary air blowing unit 108 is larger, the cutting debris may not fall and stay there. However, by doing so, it is possible to prevent the cutting debris from staying.

Further, according to the present embodiment, the waste guide portion 105 is at a position where either the transport guide surface 105a for guiding the sheet to be transported, the transport guide surface 105a, or the scrap guide surface 105b functions. It has a variable mechanism 105c that moves (swings) the waste guide portion 105 as described above, and the CPU 21 controls the variable mechanism 105c.
Therefore, the waste guide portion 105 becomes a member in which the transport guide surface 105a and the waste guide surface 105b are integrated, and the device configuration can be simplified.

Further, according to the present embodiment, the waste guide portion 105 is arranged on the upstream side of the CD cutting portion 100 in the paper transport direction of the sheet, and the CD cutting portion 100 is a lower cutting blade (lower blade 101b). ) Is installed so as to be upstream of the upper cutting blade (upper blade 101a) in the sheet conveying direction, and the CPU 21 is scrapped when the rear end portion of the sheet in the conveying direction is cut off by the CD cutting portion 100. The waste guide portion 105 is controlled so that the guide surface 105b is in a functioning position. Further, the CPU 21 controls the waste guide portion 105 so that the transport guide surface 105a functions when the tip portion of the sheet in the transport direction is cut off by the CD cutting section 100.
Therefore, the scrap guide portion 105 can be operated in response to the difference in the transport path (falling path) of the generated cutting waste between the front end portion and the rear end portion in the sheet transport direction.

Further, according to the present embodiment, the blower unit 106 includes a shutter member 106c capable of opening and closing the air flow path as an adjustment mechanism for adjusting the amount of wind sent to the cutting position, and the CPU 21 conveys the sheet. The shutter member 106c is controlled according to the cutting portion in the direction to adjust the air volume of the wind sent to the cutting position.
Therefore, fine control according to the cutting portion in the sheet transport direction becomes possible.

Specifically, when the tip portion of the sheet in the transport direction is cut off by the CD cutting portion 100, the CPU 21 controls the adjusting mechanism to reduce the air volume of the wind sent to the cutting position to a set value.
Therefore, after cutting, it is possible to prevent the tip of the deliverable from bending downward and causing problems such as poor transportation.
Further, according to the present embodiment, the lower blade 101b is provided with a plate body 102 arranged so that the upper end portion thereof floats from the tip end portion of the lower blade 101b.
Therefore, a gap is formed between the lower blade 101b and the cutting waste, and it is possible to prevent the cutting waste from sticking to the lower blade 101b.

<Others>
Although the preferred embodiment to which the present invention is applied has been described above, the description content in the above embodiment is a preferable example of the present invention and is not limited thereto.

For example, in the above-described embodiment, the configuration in which the upstream guide unit 103, the downstream guide unit 104, and the waste guide unit 105 are oscillated has been described as an example. It doesn't have to be moving.
Further, the blower portion 106 may be configured to blow wind in a direction along the slope of the tip portion of the lower blade 101b, and the detailed configuration is not limited to the above.

Further, in the above embodiment, the case where paper is used as the sheet has been described, but the material of the sheet is not limited to paper, and may be a sheet-shaped resin or the like.

1 Image forming system 10 Image forming device 11 CPU
20 Post-processing device 21 CPU (position control unit, air volume control unit)
26 Cutting section 26a, 26b FD cutting section 100 CD cutting section 101 Guillotine cutter 101a Upper blade (cutting blade)
101b Lower blade (cutting blade)
101c (scooping surface)
102 Plate 102a Upper end 103 Upstream guide 103a Transport guide 103b Drop path forming section 103c Variable mechanism 103d Rib 104 Downstream guide section 104a Transport guide section 104b Drop path forming section 104c Variable mechanism 105 Waste guide section 105a Transport guide surface 105b Waste Guide surface 105c Variable mechanism 105d Rib 105e Opening 106 Blower 106a Fan 106b Blower 106c Shutter member (adjustment mechanism)
107 Conveyance guide 108 Auxiliary blower 108a Auxiliary fan

Claims (13)

A cutting portion having a pair of cutting blades arranged one above the other across a transport path and capable of cutting off a part of a sheet transported along the transport path as cutting scraps.
At the cutting position where the pair of cutting blades cut the sheet, a blower portion that sends air in a direction along the slope of the tip of the lower cutting blade, and a blower portion.
An aftertreatment device comprising. The blower portion has an adjusting mechanism for adjusting the air volume of the wind sent to the cutting position.
The post-processing apparatus according to claim 1, further comprising an air volume control unit that controls the adjusting mechanism according to the cutting portion in the sheet conveying direction to adjust the air volume of the air sent to the cutting position. .. When the cutting portion cuts off the tip of the sheet in the transport direction, the air volume control unit controls the adjusting mechanism to stop the air sent to the cutting position or reduce the air volume of the wind to a set value. 2. The post-processing apparatus according to claim 2. The post-processing device according to claim 2 or 3, wherein the adjusting mechanism includes a shutter member capable of opening and closing an air flow path. The post-treatment apparatus according to any one of claims 1 to 4, wherein a guide portion having a waste guide surface for suppressing scattering of generated cutting waste is provided above the cutting position. The post-treatment apparatus according to claim 5, wherein the waste guide surface is provided with ribs. The guide unit
A transport guide surface for guiding the sheet transported along the transport path, and
It has a variable mechanism for moving the guide portion so that either one of the transport guide surface and the waste guide surface functions.
The post-processing apparatus according to claim 5 or 6, further comprising a position control unit that controls the variable mechanism. The guide portion is arranged on the upstream side in the sheet transport direction with respect to the cutting portion.
The cutting portion is installed so that the lower cutting blade is on the upstream side in the sheet transport direction with respect to the upper cutting blade.
The seventh aspect of claim 7, wherein the position control unit controls the variable mechanism so that the scrap guide surface functions when the rear end portion of the sheet in the transport direction is cut off by the cutting portion. Post-processing device. The guide portion is arranged on the upstream side in the sheet transport direction with respect to the cutting portion.
The cutting portion is installed so that the lower cutting blade is on the upstream side in the sheet transport direction with respect to the upper cutting blade.
7. The position control unit according to claim 7 or 8, wherein the position control unit controls the variable mechanism so that the transfer guide surface functions when the tip portion of the sheet in the transport direction is cut off by the cutting section. Post-processing device. An auxiliary air blower that sends air from above to the guide part is provided.
The post-treatment apparatus according to any one of claims 5 to 9, wherein the waste guide surface is formed with an opening for allowing air sent from the auxiliary air blowing portion to escape downward. The post-treatment apparatus according to claim 10, wherein the air volume of the auxiliary air blowing unit is smaller than the air volume of the air blowing unit. The invention according to any one of claims 1 to 11, wherein the lower cutting blade is provided with a plate body arranged so that the upper end thereof floats from the tip end portion of the lower cutting blade. Post-processing device. An image forming device that forms an image on a sheet,
The post-processing apparatus according to any one of claims 1 to 12,
An image forming system characterized by comprising.

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