JP4043553B2 - Stencil printing machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a stencil printing apparatus that includes a plurality of plate cylinders and can perform multicolor printing.
[0002]
[Prior art]
Conventionally, a digital thermal stencil printing apparatus is known as a simpler printing method. In a stencil printing machine, a thermal head in which fine heating elements are arranged in a row is brought into contact with the thermal stencil master, and the master is melt-drilled by conveying the master while energizing the heating elements in a pulsed manner according to image information. Then, the plate-making master is wound around the outer peripheral surface of a porous cylindrical plate cylinder, and the ink is passed through the perforated portion to transfer to the paper to form a printed image. Printing by this type of stencil printing apparatus is performed by the pressure of a press roller that is arranged in the vicinity of the outer peripheral surface of the plate cylinder so as to face the roller, and is pressed against the outer peripheral surface at appropriate times. The ink on the ink roller is transferred from the perforation of the pre-made master wound around the outer peripheral surface of the plate cylinder to the outer peripheral surface side of the master and transferred to the paper.
[0003]
Since the paper to be printed adheres to the plate cylinder due to the viscosity of the ink, etc., in the invention described in JP-A-62-242677, the separation claw is disposed close to the outer peripheral surface of the plate cylinder, and the plate cylinder The air is blown by a blow source between the outer peripheral surface of the sheet and the separation claw, and a suction device is disposed below the press roller to separate and peel the adhered paper from the plate cylinder. In the device described in Japanese Utility Model Publication No. 2-35717, a separation claw is disposed close to the outer peripheral surface of the plate cylinder, and a suction conveyance device is provided between the plate cylinder and a printed paper discharge unit, and the separation claw The sheet peeled from the drum is sucked by the suction conveyance device and conveyed to the paper discharge unit.
[0004]
Japanese Laid-Open Patent Publication No. 6-32038 discloses a plurality of plate cylinders each having a plate-making master that has been made in correspondence with a color image and wound around the outer peripheral surface, with a space in the sheet transport direction. In between, a suction conveyance device that sucks and conveys paper printed on the plate cylinder located upstream in the conveyance direction toward the plate cylinder located downstream in the conveyance direction is provided, and contacts the upper surface (print image surface) of the paper There has been proposed a stencil printing apparatus capable of simultaneous multicolor printing in which a sheet is conveyed between plate cylinders without being transferred and sent to the next plate cylinder and a corresponding press roller. In this way, in a stencil printing machine having a plurality of plate cylinders, the conveyance speed of the paper by the suction conveyance apparatus is constant, and each plate cylinder is rotationally driven at a constant speed in synchronization with the paper feed timing for feeding the paper. The paper and the image front end on each plate cylinder coincide with each other at the printing position of each plate cylinder.
[0005]
[Problems to be solved by the invention]
The problem with stencil printing machines capable of simultaneous multicolor printing is that the ink on the paper printed on the upstream plate cylinder adheres to the master on the downstream plate cylinder, and the attached ink is transported next. In other words, so-called image double printing, which is transferred when printing on a sheet of paper, occurs.
[0006]
In the case of stencil printing, the paper is pressed against the plate cylinder with a press roller and ink is attached to the paper to print the ink image for the stencil image, so the image area varies depending on the size of the ink image and the size of the paper. There is a change in the amount of ink transferred to the paper. For this reason, the timing at which the paper adhering to the plate cylinder peels off from the plate cylinder during printing varies depending on the amount of ink transferred, and a conveyance delay to the plate cylinder located downstream in the conveyance direction occurs. If the paper is thick and stiff, even if it adheres to the plate cylinder due to the viscosity of the ink, it will separate well from the plate cylinder, but if the paper is thin and weak, it will adhere to the plate cylinder due to the viscosity of the ink and roll up. Separation of paper from the cylinder is delayed.
[0007]
In addition, since various types of paper are used for printing, the suction and conveyance device cannot perform suction and suction well due to the difference in the type of paper, causing fluttering and the like, resulting in insufficient conveyance performance.
[0008]
Since the leading edge of the paper is separated from the suction conveyance device when entering the downstream plate cylinder, its position is not stable, and printing is performed when the press roller moves and is pressed against the downstream plate cylinder. As a result, the paper entering property between the downstream plate cylinder and the press roller is lowered, and the leading edge of the paper is displaced.
[0009]
This is mainly due to the delay in separation of the paper from the plate cylinder, insufficient paper conveyance performance, and poor paper entry into the printing position of the downstream plate cylinder. The transport time varies and image double printing is incurred.
[0010]
The present invention eliminates misalignment of the leading edge of the sheet due to the winding of the sheet in the upstream plate cylinder, and also allows the leading edge of the sheet to enter the downstream plate cylinder and transport of the sheet between the upstream and downstream plate cylinders. An object of the present invention is to provide a stencil printing apparatus capable of improving the performance and stabilizing the conveyance timing of the sheet to the downstream plate cylinder and reducing the image double printing.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, the invention described in claim 1 is characterized in that a plurality of plate cylinders that are rotated and driven by a master made on the outer peripheral surface thereof are arranged in parallel at intervals in the paper conveyance direction, In the stencil printing apparatus, in which a suction conveyance device for sucking and conveying a sheet printed by a plate cylinder located upstream in the conveyance direction toward a plate cylinder located downstream in the conveyance direction is disposed above the suction conveyance device And a wind guide member that forms a flow path for blowing the air flow from the blow source to the sheet conveyance path formed between the upstream and downstream plate cylinders. Intermediate air blowing means is provided.
[0012]
According to a second aspect of the present invention, in the stencil printing apparatus according to the first aspect, a separation claw provided on the upstream plate cylinder so as to be able to approach and separate is provided between the two plate cylinders, and the flow path is formed by an air guide member. Is provided so that an air flow from an air source can be blown in a tangential direction at a point where a line connecting the tip of the separation claw and the rotation center of the upstream plate cylinder intersects with an outer peripheral surface of the plate cylinder. .
[0013]
Claim 1 In the described invention, the air guide member includes an upstream end of a paper transport path positioned in the vicinity of the upstream plate cylinder, and a downstream end of the paper transport path positioned in the vicinity of the downstream plate cylinder. of The flow path which blows the airflow from a ventilation source is formed in the at least 2 site | part.
[0014]
Claim 3 The invention described in claim 1 Or 2 The stencil printing apparatus described above includes sheet information input means for inputting sheet information, and control means for controlling the operation of the air source in accordance with input information from the sheet information input means.
[0015]
Claim 4 The described invention is claimed. 3 The stencil printing apparatus described above has an air volume setting means connected to the control means, and the control means individually determines the operation of the air source as input information from the paper information input means in response to a signal from the air volume setting means. Control.
[0016]
Claim 5 The described invention is claimed. 1 or 2 In the stencil printing apparatus described above, a plurality of the air guide members are provided, and a variable mechanism capable of translating the plurality of air guide members in a direction orthogonal to the tangential direction is provided.
[0017]
Claim 6 The described invention is claimed. 5 In the stencil printing apparatus described above, paper information input means for inputting the information on the paper, and control means for controlling the operation of the variable mechanism or the variable mechanism and the air source according to the input information from the paper information input means. I have.
[0018]
Claim 7 The described invention is claimed. 6 In the stencil printing apparatus described above, there is an air volume setting means connected to the control means, and the operation of the air source or the variable mechanism or the operation of the air source and the variable mechanism according to the signal from the air volume setting means Input information from the input means is configured to be controlled by the control means separately.
[0019]
Claim 8 The described invention is claimed. 3 Or 6 In the stencil printing apparatus described above, the paper information input means includes paper identification means for outputting a signal corresponding to the type of paper to the control means, and paper size setting means for outputting a signal corresponding to the paper size to the control means. Has been.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
In the stencil printing apparatus according to the present invention, a plurality of plate cylinders, in which a master-making master is wound around an outer peripheral surface and rotationally driven, are arranged in parallel at intervals in the paper conveyance direction, and a suction conveyance device is provided between the two plate cylinders. The sheet to be printed is sucked and conveyed toward the plate cylinder located on the downstream side in the conveyance direction, and the intermediate blower is disposed above the suction conveyance device. Is the basic configuration. The intermediate air blowing means includes an air blowing source and an air guide member, and an air flow generated by the air source is blown to the sheet conveyance path formed between the upstream plate cylinder and the downstream plate cylinder using the air guide member. A guiding channel is formed.
[0021]
If the part to be blown is in the vicinity of the separation position of the paper that becomes the upstream end of the paper transport path in the upstream plate cylinder, the paper printed on the upstream plate cylinder is caused by the air flow and the stiffness of the paper. Separated from. If the part to be blown is the conveyance surface of the suction conveyance device, the sheet peeled from the upstream plate cylinder is pressed against the conveyance surface of the suction conveyance device by the air flow, and the decrease in conveyance force is reduced. So good. If the part to be blown is the downstream end of the paper conveyance path in the vicinity of the downstream plate cylinder, an air flow is blown near the downstream plate cylinder, and the air flow hits the paper that has been removed from the suction conveyance device, The position is stabilized, and the paper penetration into the downstream plate cylinder is improved.
[0022]
In order to further improve the separation performance of the sheet from the upstream plate cylinder, a separation claw is provided in the vicinity of the upstream plate cylinder so as to be able to approach and separate, and the leading end of the separation claw and the rotation center of the upstream plate cylinder The air outlet from the air source is arranged in a tangential direction at the point where the line connecting the plate cylinder and the outer peripheral surface of the plate cylinder intersects, and a blowout port for the flow path formed by the air guide member is provided. It is preferable that an air flow from the air source is blown between the front end and the outer peripheral surface of the plate cylinder.
[0023]
If a flow passage for blowing the air flow from the blower source is formed in the air guide member in at least two portions that cause the paper conveyance delay to the downstream plate cylinder, the air from a plurality of positions at a time with respect to the paper A stream is sprayed. For example, when the flow path is formed by the air guide member so as to blow the air flow from the air source to the upstream end of the suction conveyance device located in the vicinity of the upstream plate cylinder and the conveyance surface of the suction conveyance device, This is effective in suppressing paper fluttering on the conveying surface while preventing the paper from rolling up to the upstream plate cylinder.
[0024]
An air guide member so as to blow an air flow from a blow source to an upstream end of a suction conveyance device located in the vicinity of an upstream plate cylinder and a downstream end of a suction conveyance device located in the vicinity of a downstream plate cylinder When the flow path is formed, the paper tip is stabilized even when the paper leading edge deviates from the conveyance surface while preventing the paper from rolling up to the upstream cylinder, and the paper is fed to the downstream cylinder. It is preferable for improving the penetrability of the tip.
[0025]
The flow path formed by the air guide member includes an upstream end of the suction conveyance device located in the vicinity of the upstream plate cylinder, a conveyance surface of the suction conveyance device, and a suction conveyance device located in the vicinity of the downstream plate cylinder. Providing air flow from the air source at three locations at the downstream end at a time so that air can be blown at once improves separation and separation between the upstream plate cylinder and the paper, suppresses paper flutter on the transport surface, and reduces the transport force. It is possible to improve and improve the paper penetration into the downstream plate cylinder, which is more preferable.
[0026]
The amount of air blown to the paper in the intermediate blower is controlled in accordance with input information from a paper information input unit comprising a paper identification unit that identifies the type of paper and a paper size detection unit that outputs a signal corresponding to the size of the paper. If adjusted by means, the air volume is increased or decreased according to the type and size of the paper and supplied to each flow path, and the separation and isolation from the upstream plate cylinder in consideration of the type and size of the paper, It is possible to suppress the paper fluttering in the suction conveyance means and improve the conveyance performance, and to improve the paper penetration into the downstream plate cylinder. Examples of the paper identification means include an optical sensor that detects the thickness of the paper, a manual operation selection switch that activates the control operation of each unit in accordance with the type of the paper, and the like. Examples of the paper size detection means include an optical sensor for detecting the paper size, a manual operation selection switch that activates the control operation of each unit in accordance with the paper size, and the like. When a selection switch (key switch) is used for the paper identification means and the paper size detection means, if only the type and size of the paper are selected, the setting of the amount of air blown onto the paper can be automatically controlled according to the type and size of the paper. Become. If an optical sensor is used for the paper identification means and the paper size detection means, it is possible to automatically control everything from the setting of the type and size of the paper to the setting of the air volume blown onto the paper.
[0027]
As the air guide member, it is preferable that a plurality of air guide members are integrally formed to make the area of the flow path constant, or the air guide member is provided so as to be movable by a variable mechanism so that the area of the flow path can be increased or decreased. . In this case, when the plurality of wind guide members are provided so as to be able to translate in a direction orthogonal to the tangential direction of the upstream plate cylinder, the area of the blowing port with respect to the upstream plate cylinder and the tip of the separation claw is particularly efficient. Therefore, the separation / peeling performance of the printed paper in the upstream plate cylinder can be adjusted according to the type of paper, which is preferable.
[0028]
In order to increase or decrease the amount of airflow sprayed on the paper, the airflow generated from the air source may be adjusted instead of adjusting the area of the flow path. If the air source is electrically driven, the amount of air flow applied to the paper can be adjusted according to the type and size of the paper by controlling the voltage and current amount according to the type and size of the paper. It becomes possible to adjust the separation / peelability of the sheet from the plate cylinder, the conveying force on the conveying surface, and the sheet invasion property to the downstream plate cylinder.
[0029]
In order to increase or decrease the amount of airflow blown onto the paper, air volume setting means may be provided, and the variable mechanism or the air source may be controlled using the control means by a signal from the air volume setting means. The control of the amount of airflow blown onto the paper may be performed independently by connecting the air volume setting means to the control means alone, based on the signal from the air volume setting means, or the air volume setting means and the paper identification means or the paper The size setting means may be connected to the control means and may be performed according to signals from these means. In this case, if the control means is configured to give priority to the signal from the air volume setting means over the signal from the paper identification means or the paper size setting means, the air volume control by the paper identification means or the paper size setting means could not be corrected. This is preferable because it is possible to manually correct the deviation of the sheet conveyance timing with respect to the downstream plate cylinder.
[0030]
【Example】
Hereinafter, embodiments of the present invention will be sequentially described in detail with reference to the drawings.
(First embodiment)
The overall configuration and basic stencil printing operation of a multi-cylinder stencil printing apparatus to which the present invention is applied will be described. The double cylinder type stencil printing apparatus shown in FIG. 1 includes two plate cylinders arranged in parallel from the upstream side to the downstream side in the conveyance direction X of the paper 22 (hereinafter referred to as “plate cylinder 1A”, “plate cylinder 1B”). And simultaneous multicolor printing (in this embodiment, simultaneous two-color printing) is possible. The plate cylinder 1A and the plate cylinder 1B have substantially the same function and configuration. In the same manner, ink supply means, plate making apparatus, plate discharging apparatus and the like, which will be described later, disposed around the inside and outside of the plate cylinder 1A, and ink supply means, plate making apparatus, which will be described later, disposed around the inside and outside of the plate cylinder 1B. And the plate removal device have substantially the same function and configuration, they are distinguished by adding the symbol a or b to the end of the same symbol, and when one of them is described in detail, it is duplicated The description of the other is omitted as much as possible to avoid the description. In addition, another function and configuration may be simply represented by adding a or b to the end of the same symbol.
[0031]
The double cylinder type stencil printing apparatus has a structure of a well-known thermosensitive digital plate making integrated stencil printing apparatus. That is, the multi-cylinder type stencil printing apparatus includes a plate cylinder 1A that winds the master 33a around the outer peripheral surface 1Aa, a plate making apparatus 41a that is disposed on the upper right side of the plate cylinder 1A and makes the master 33a, and is disposed below the plate making apparatus 41a. A sheet feeding device 20 that feeds the sheets 22 loaded on the sheet feeding tray 21, a plate discharging device 42a that peels off the used master 33a disposed at the upper left of the plate cylinder 1A from the plate cylinder 1A, and A printing pressure device 32a that performs printing by pressing a sheet 22 disposed below the printing drum 1A and fed to the master 33a on the printing drum 1A, and between the printing pressure device 32a and the printing drum 1A. A first unit U1 including a separation claw 7a for peeling the printed paper 22 printed at the printing position E1 to be formed from the plate cylinder 1A, a plate cylinder 1B for winding the master 33b around the outer peripheral surface 1Ba, and a plate A plate making apparatus 41b arranged on the upper left side of 1B for making the master 33b, a plate discharging apparatus 42b for peeling off the used master 33b arranged on the left side of the plate cylinder 1B from the plate cylinder 1B, and a lower side of the plate cylinder 1B A printing pressure device 32b that performs printing by pressing the paper 22 disposed and fed to the master 33b on the plate cylinder 1B, and a printing position formed between the printing pressure device 32b and the plate cylinder 1B. A second unit U2 having a separation claw 7b for separating and peeling the printed paper 22 printed at E2 from the plate cylinder 1B, and the printed paper 22 printed at the printing position E1 toward the printing position E2. A sheet discharge device that is disposed below the sheet conveying device 17a and the plate discharging device 42b and discharges the printed paper 22 that has been printed in multiple colors at the printing position E1 and the printing position E2 onto the paper discharge tray 37. 5, is mainly composed of the intermediate blowing means 45 provided the plate cylinder 1A above the suction transporting device 17a, during 1B.
[0032]
Above the plate making apparatuses 41a and 41b and the plate discharging apparatus 42a of the stencil printing apparatus, an original reading apparatus (not shown) for reading an image of the original and an operation panel 70 shown in FIG. 3 for operating the stencil printing apparatus are provided. Are arranged.
[0033]
Next, the operation of the double cylinder type stencil printing apparatus will be described including the detailed configuration of each of the above apparatuses.
The plate cylinder 1A has a well-known porous cylindrical shape and is rotatably supported around the drum shaft 2a. The plate cylinder 1A is rotated in the direction of the arrow in synchronization with the plate cylinder 1B via a plate cylinder drive motor 61 shown in FIG. 2 and a known power transmission mechanism including a gear train, a belt and a pulley (not shown). An openable and closable clamper 5a that clamps the tip of the master 33a is provided on one bus bar of the outer peripheral surface 1Aa of the plate cylinder 1A. The clamper 5a is pivotally mounted on the plate cylinder 1A by a clamper shaft 6a, and is opened and closed at a predetermined position by an opening / closing means (not shown) disposed at an appropriate position around the outer periphery of the plate cylinder 1A. Inside the plate cylinder 1A, ink supply means for supplying ink from the inner peripheral surface 1Ab of the plate cylinder 1A toward the outer peripheral surface 1Aa is disposed. The ink supply means in the plate cylinder 1A supplies, for example, magenta ink as the first color ink, and the ink supply means in the plate cylinder 1B supplies, for example, black ink as the second color ink.
[0034]
As the master 33a, a master in which Japanese paper or the like is bonded as a porous support to a thermoplastic resin film such as polyester is used. The master 33a is not limited to the above, and it is also possible to use a very thin material that is substantially made of only a thermoplastic resin film.
[0035]
When an operator sets a document to be printed on a document tray of a document reading device (not shown) and presses a plate making start key 73 shown in FIG. 3 for starting plate making, the plate discharging process is the same in both plate cylinders 1A and 1B. To be executed. That is, the plate cylinder 1A rotates in the direction opposite to the arrow direction (counterclockwise direction) in the figure, and the used master 33a wound around the outer peripheral surface of the plate cylinder 1A gradually starts from the outer peripheral surface 1Aa of the plate cylinder 1A. While being peeled off and transported, it is discharged into each discharging box (not shown), and so-called discharging is completed.
[0036]
In parallel with the plate discharging process, the document reading device operates to read the document. The detailed configuration and operation relating to this document reading is performed by, for example, a known “reduction type document reading method”, and the image read from the document is finally a photoelectrical device such as a CCD (charge coupled device). Photoelectric conversion is performed by an image sensor including a conversion element. The electrical signal photoelectrically converted by the image sensor is converted to a digital image signal by being transmitted to an analog / digital (A / D) conversion board (not shown).
[0037]
The document reading apparatus has a structure having various functions for color separation necessary for multi-color overprint printing, for example, a filter capable of switching a plurality of color filters described in JP-A No. 64-18682. A unit having the same function and configuration as that of the unit is disposed on the optical path between the mirror group and the lens (both not shown), and performs operations such as automatic plate making and plate feeding as described in the publication. Detailed explanation is omitted.
[0038]
On the other hand, in parallel with the original reading operation, the same plate making / plate feeding process is performed in both plate making apparatuses 41a and 41b based on the digital image signal. The master 33a is rotated by a platen roller (both not shown) and a delivery roller pair (not shown) pressed against a planar thermal head disposed in the plate making apparatus 41a, so that the master 33a becomes a master transport path. To the downstream side. A large number of minute heating elements arranged in a line in the main scanning direction of the thermal head are arranged on the A / D conversion board and the subsequent plate-making control board (not shown) with respect to the master 33a thus conveyed. The thermoplastic resin film of the master 33a that is selectively heated according to the digital image signal sent after being subjected to various processes and is in contact with the generated heating element is melt-pierced. In this way, image information is written as a drilling pattern by position-selective melt drilling of the master 33a according to the image information.
[0039]
The front end of the master 33a that has been subjected to image making and plate making is sent out toward the outer peripheral side of the plate cylinder 1A by the rotation of the sending roller pair, and the direction of travel by a plate feeding guide plate (not shown). Is changed and hangs down toward the expanded clamper 5a of the plate cylinder 1A in the illustrated plate feeding position state. At this time, the used master 33a has already been removed from the plate cylinder 1A by the plate removing process. On the other hand, the front end of the master 33b after the plate making on the plate cylinder 1B side is sent out toward the outer peripheral side of the plate cylinder 1B by the rotation of the sending roller pair, and is guided in a substantially horizontal direction by a plate feed guide plate (not shown). The clamper 5b is inserted toward the expanded clamper 5b of the plate cylinder 1B in the plate feeding position located almost immediately above in FIG.
[0040]
When the tip of the master 33a that has been made is clamped by the clamper 5a at a certain timing, the plate cylinder 1A gradually rotates the master 33a that has been made on the outer peripheral surface 1Aa while rotating in the direction of the arrow in the figure (clockwise direction). Wrap around. After the completion of the plate making, the rear end of the plate making master 33a is cut to a certain length by the operation of a cutting means including a movable blade and a fixed blade (not shown) disposed in the plate making apparatus 41a. When the master 33a is completely wound around the outer peripheral surface 1Aa of the plate cylinder 1A, the so-called plate feeding process is completed.
[0041]
When the masters 33a and 33b of one plate are wound around the outer peripheral surfaces 1Aa and 1Ba of the plate cylinders 1A and 1B, the plate making / plate feeding process is finished, and the plate making process and the printing process are started. . First, the uppermost sheet 22 loaded on the sheet feeding tray 21 is raised and the sheet feeding tray 21 is raised until it contacts the calling roller 23. The uppermost sheet 22 in contact with the calling roller 23 is conveyed by the rotation operation of the calling roller 23 and is separated into one sheet by the cooperative action of the separation roller pairs 24 and 25 and the separation plate 26, so While being guided by the upper guide plate 28 and the lower guide plate 27, the paper is fed in the transport direction X toward the registration roller pairs 29 and 30. At this time, the front end of the conveyed paper 22 is in contact with the portion immediately before the nip portion of the registration roller pair 29, 30 and is stopped in a state of being bent along the upper guide plate 28.
[0042]
The plate cylinder 1A located on the upstream side in the transport direction X starts to rotate in the direction of the arrow at the rotation speed during printing when the printing operation starts. On the inner peripheral side of the plate cylinder 1A, magenta ink is supplied from an ink supply distributor (not shown) to an ink reservoir Ia formed between the ink roller 3a and the doctor roller 4a. As the roller 3a and the doctor roller 4a rotate, they are kneaded and stretched, and are uniformly attached to the outer peripheral surface of the ink roller 3a. The remaining amount of ink is detected by an ink detection means (not shown), and is supplied from the ink supply distributor when the ink is low. Thus, ink is supplied to the inner peripheral side of the plate cylinder 1A by the ink roller 3a that is in contact with the inner peripheral surface 1Ab while rotating in the same direction as the rotation direction of the plate cylinder 1A and in synchronization with the rotation speed of the plate cylinder 1A. Is done.
[0043]
The printing pressure device 32a mainly includes an ink roller 3a, a press roller 9a, a press roller bracket 11a supported by a shaft 10a in a swingable manner, a press roller tension 13a, and a press roller cam 12a. The press roller 9 a has a function as a pressing unit that presses the fed paper 22 against the plate cylinder 1 </ b> A to form a print image on the paper 22. The press roller 9a is rotatably supported at one oscillating end of the press roller bracket 11a, and is provided so as to be able to contact and separate from the outer peripheral surface 1Aa of the plate cylinder 1A. The printing pressure of the press roller 9a against the plate cylinder 1A is applied by a press roller tension 13a (tensile spring) stretched on the other swing end side of the press roller bracket 11a, and by the urging force of the press roller tension 13a. The other oscillating end of the press roller bracket 11a is in pressure contact with the contour peripheral surface of the fan-shaped press roller cam 12a. The press roller cam 12a is rotated by the plate cylinder driving motor 61 in synchronization with the sheet 22 feeding timing from the sheet feeding device 20 and the rotation of the plate cylinder 1A. When the paper 22 is not fed, the large diameter portion is opposed to the other swinging end of the press roller bracket 11a. The press roller cam 12a rotates when the paper 22 is fed from the paper feeding device 20, the small diameter portion thereof faces the other swinging end of the press roller bracket 11a, and the press roller 9a is rotated clockwise in the figure. It swings in the direction.
[0044]
When the sheet 22 is fed between the plate cylinder 1A and the press roller 9a in the printing pressure device 32a at a predetermined timing synchronized with the rotation of the plate cylinder 1A by the registration roller pair 29, 30, it synchronizes with this. The press roller 9a that has been separated below the outer peripheral surface of the plate cylinder 1A is swung and lifted to be pressed against the master 33a that has been pre-rolled around the outer peripheral surface 1Aa of the plate cylinder 1A. As a result, the master 33a that has been subjected to plate making comes into close contact with the outer peripheral surface of the plate cylinder 1A by the adhesive force due to the viscosity of the ink that has oozed out of the opening portion of the plate cylinder 1A, and at the same time, the perforation pattern portion of the master 33a that has already been made Then, the ink oozes out, and the oozed ink is transferred to the surface of the paper 22 so that a desired image of the first color is formed on the paper 22.
[0045]
When the leading end 22a of the paper 22 on which the first color image is printed reaches a position near the leading end of the separation claw 7a, the separation claw 7a rotates around the separation claw shaft 8a in synchronization with the rotation operation of the plate cylinder 1A. It approaches the outer peripheral surface 1Aa of the plate cylinder 1A. Separation / peeling of the paper 22 from the plate cylinder 1A is mainly performed by the intermediate air blowing means 45, the separation claw 7a, and the suction conveyance device 17a. This separation / peeling operation will be described later. The separated and peeled paper 22 is further transported downstream in the transport direction X by the suction transport device 17a.
[0046]
The suction conveyance device 17a is mainly composed of a porous conveyance belt 16a stretched between a driven roller 14a and a driving roller 15a driven counterclockwise by a conveyance motor 60, and a suction fan 18a. ing. The suction conveyance device 17a is under the control of the control means 34 shown in FIG. 2, and the conveyance speed of the paper 22 by the conveyance belt 16a is controlled to be constant by the control means 34. The separated and peeled printed paper 22 is attracted to the upper surface 16b of the conveying belt 16a, which becomes the conveying surface, by the operation of the suction fan 18a, and the next printing position E2 is rotated by rotating the conveying belt 16a counterclockwise. It is conveyed toward.
[0047]
The plate cylinder 1B located downstream in the transport direction X and corresponding to the second color starts a printing operation in synchronization with the plate cylinder 1A, and starts to rotate at the rotation speed at the time of printing in the arrow direction (clockwise direction) in the figure. . On the inner peripheral side of the plate cylinder 1B, black ink is supplied to an ink reservoir Ib formed between the ink roller 3b and the doctor roller 4b. The black ink is kneaded and stretched by the rotation of the ink roller 3b and the doctor roller 4b, and is uniformly adhered to the outer peripheral surface of the ink roller 3b, and the second color ink is supplied to the inner peripheral side of the plate cylinder 1B. The
[0048]
When the paper 22 is fed to the printing position E2 between the plate cylinder 1B and the press roller 9b in the printing pressure device 32b at a predetermined timing by the conveyance belt 16a of the suction conveyance device 17a, the plate is synchronized with this. When the press roller 9b that has been separated below the outer peripheral surface of the cylinder 1B is swung and raised, the press roller 9b is pressed against the master 33b that has been made around the outer peripheral surface 1Ba of the plate cylinder 1B. As a result, the master 33b that has been subjected to the plate making comes into close contact with the outer peripheral surface of the plate cylinder 1B due to the adhesive force due to the viscosity of the ink that has oozed out of the opening portion of the plate cylinder 1B, and at the same time, the perforation pattern portion of the master 33b that has already been made Then, the ink oozes out, and the oozed ink is transferred to the surface of the paper 22 so that the image of the second color ink is printed on the paper 22 on which the image of the first color ink has already been formed.
[0049]
When the leading edge 22a of the paper 22 on which the second color image is formed reaches the vicinity of the leading edge of the separation claw 7b, the separation claw 7b is centered on the separation claw shaft 8b in synchronization with the rotation of the plate cylinder 1B. At the same time as rotating and approaching the outer peripheral surface 1Ba of the plate cylinder 1B, a compressed air flow generated by a pneumatic generator (not shown) is blown from the tip of the separation claw 7b, and the tip 22a of the paper 22 is separated from the plate cylinder 1B.・ Peel off. The printed paper 22 separated and peeled off by the separation claw 7b is further transported by the paper discharge device 35 to the paper discharge tray 37 located downstream in the transport direction X.
[0050]
The paper discharge device 35 is mainly composed of a porous conveyance belt 40 that is stretched between a driven roller 39 and a driving roller 38, and a suction fan 36. The conveyance belt 40 of the paper discharge device 35 is driven in synchronization with the plate cylinder 1B at a conveyance speed substantially the same as the rotation speed of the plate cylinder 1B. The printed paper 22 separated and peeled off by the separation claw 7b is sucked by the suction fan 36 and sucked by the transport belt 40. By the rotation of the transport belt 40 in the counterclockwise direction, the paper discharge tray 37 are sequentially discharged and loaded. In this way, so-called “printing” or “trial printing” is completed.
[0051]
When the number of prints is set with the numeric keypad 71 of the operation panel 70 shown in FIG. 3 and the print start key 72 is pressed, the steps of paper feeding, printing and paper discharge are repeated for the set number of prints in the same process as the trial printing. This is the end of the entire stencil printing process.
[0052]
The configuration of each of the above-mentioned devices constituting such a stencil printing device and the arrangement state thereof are merely examples, and it may be configured with other well-known devices and various arrangement states. Not too long. The multi-cylinder type stencil printing apparatus is not limited to the one constituting the heat sensitive digital plate-making integrated stencil printing apparatus as described above. For example, each plate cylinder 1A, 1B constitutes a drum unit and is detachable from the apparatus main body. The master is made by a plate making apparatus or a plate removing apparatus (both not shown) arranged separately from the main body of the apparatus, or used masters are placed in each plate cylinder. The plates may be peeled off from the outer peripheral surfaces 1Aa and 1Ba of 1A and 1B, and the plate making apparatuses 41a and 41b and the plate discharging apparatuses 42a and 42b may not necessarily be provided in the apparatus main body. Further, the data for plate making may be data read by a document reading apparatus as described above, or data created by a computer or the like. As a multicolor stencil printing apparatus, printing pressure is applied to the plate cylinders 1A and 1B by the press rollers 9a and 9b in the printing unit, but a pressure cylinder known in a printing machine may be used instead of the press roller.
[0053]
The intermediate blower 45 that is a main part of the present embodiment will be described. The intermediate blower 45 forms a plurality of flow paths for guiding a blower fan 46 serving as a blower source and a blown air generated by the blower fan 46 to a sheet conveyance path 47 formed between the plate cylinder 1A and the plate cylinder 1B. And a wind guide member 48. The paper transport path 47 is a transport belt 16a disposed between the printing positions E1 and E2, and its transport surface is mainly configured. The blower fan 46 is rotationally driven by a blower motor 49 so as to generate a strong air flow toward the suction conveyance device 17a. As shown in FIG. 2, the blower motor 49 is electrically connected to the control means 34 via the drive circuit 50, and when the print start key 72 is pressed and a print signal is input to the control means 34, It operates as a start signal.
[0054]
As shown in FIG. 4, the air guide member 48 is formed by integrally forming the air guide plate outer 51 and 52 and the air guide plate 53 and 54, and is a device (not shown) in the space between the plate cylinders 1A and 1B. It is fixed and provided at the base portion. The outside of the air guide plates 51 and 52 and the inside of the air guide plates 53 and 54 are formed to have a width that is somewhat longer than the length of the plate cylinders 1A and 1B with respect to the generatrix direction. The outer air guide plates 51 and 52 are curved so as to follow the outer peripheral surfaces 1Aa and 1Ba of the plate cylinders 1A and 1B, respectively, and are installed at positions that do not contact the clampers 5a and 5b when the plate cylinders 1A and 1B rotate. Has been. The upper ends 51 a and 52 a of the outside air guide plates 51 and 52 are extended to the case 46 a that houses the air blowing fan 46, and the air blowing fan 46 is positioned in the main channel 55 formed by the outside air guide plates 51 and 52. I am letting.
[0055]
The air guide plates 53 and 54 are curved so as to extend along the outer peripheral surfaces 1Aa and 1Ba of the plate cylinders 1A and 1B, respectively, and have a letter C shape so as to spread toward the sheet transport path 47. It is arranged below the outer 51 and 52. The upper ends 53a and 54a of the air guide plates 53 and 54 are disposed inside the outlet 56 of the main flow channel 55 formed between the lower ends 51b and 52b of the air guide plates 51 and 52. As a result, the main channel 55 is divided in the vicinity of the outlet 56, and three branch channels 57, 58, 59 are formed between the plate cylinders 1A, 1B. The lower end 53b of the air guide plate 53 extends to the vicinity of the separation claw 7a.
[0056]
The branch flow path 57 is formed between the outer peripheral surface 1Aa of the plate cylinder 1A and the outer surface of the air guide plate 53, and a paper conveyance path in which the blowing port 57a is located between the driven roller 14a and the plate cylinder 1A. 47 at the upstream end 47a. The branch flow path 59 is formed between the outer peripheral surface 1Ba of the plate cylinder 1B and the outer surface of the air guide plate 54, and a paper conveyance path in which the blowing port 59a is located between the drive roller 15a and the plate cylinder 1B. 47 at the downstream end 47b. The branch flow path 58 is formed between the air guide plates 53 and 54, and the outlet 58 a is disposed on the upper surface 16 b of the transport belt 16 a serving as the transport surface of the paper transport path 47. Also, an entry guide plate 64 serving as an entry guide means between the drive roller 15a and the printing position E2 linearly connects the upper surface of the transport belt 16a and the printing position E2 so as not to contact the press roller 9b. Is provided.
[0057]
As shown in FIG. 3, the operation panel 70 includes a ten key 71 for setting the number of prints, a print start key 72 for outputting a print start signal for setting activation of each operation up to the printing process, and a document. A plate making start key 73 for starting each operation from image reading to plate making, plate feeding, and plate making as a trial print, a stop key 74 for stopping each operation leading to a printing process, and the numeric keypad 71, a display device 75 comprising LEDs for displaying the number of printed sheets set in 71, and a monitor display device 76 for displaying failure locations such as jams of the masters 33a, 33b and paper 22 in the stencil printing device and the details of the failure. A clear key 77 for canceling the number of printed sheets set by the ten key 71, and an adjustment key 7 comprising a down key 78a and an up key 78b. An air volume selection key 44 as an air volume setting means, a paper type selection key 43 as a paper identification means for identifying the type of the paper 22, and a paper size selection key as a paper size setting means for setting the size of the paper 22 79 are arranged respectively. The paper type selection key 43 and the paper size selection key 79 each constitute a paper information input unit. The paper type selection key 43, the air volume selection key 44, the adjustment key 78, and the paper size selection key 79 are not used in this embodiment.
[0058]
As shown in FIG. 2, the control means 34 includes a CPU (central processing unit) 80, an I / O (input / output) port (not shown), a ROM (read only storage device) 81, and a RAM (read / write storage device) 82. And the like, and a known microcomputer having a configuration in which they are connected by a signal bus (not shown). Various keys of the operation panel 70 and a display device 75 are electrically connected to the control means 34, and command signals and / or on / off signals and data signals are transmitted and received between them.
[0059]
The CPU 80 includes a plate making apparatus 41a and 41b and a plate making and feeding system driving section 83 for driving a plate feeding section (not shown), a plate discharging system driving section 84 for driving the plate discharging apparatuses 42a and 42b, and a paper feeding system for driving the paper feeding apparatus 20. A driving unit 85, a printing pressure system driving unit 86 for driving the printing pressure devices 32a and 32b, a paper discharging system driving unit 87 for driving the paper discharging device 35 and an air pressure generator (not shown), and a fan driving unit for driving the suction fan 18a. 88 are electrically connected to each other, and a command signal and / or an on / off signal and a data signal are transmitted and received between them, and start, stop, and timing of the devices and drive mechanisms of the respective parts of the stencil printing apparatus The entire system is controlled.
[0060]
A conveyance motor 60 that rotationally drives the drive roller 15a and a plate cylinder drive motor 61 that rotationally drives the plate cylinder 1A are electrically connected to the CPU 80 via drive circuits 62 and 63, respectively. In the control means 34, input information from sensors (not shown) and calculation results in the CPU 80 are temporarily stored in the RAM 82, and the information is read out in a timely manner.
[0061]
The ROM 81 stores in advance a program and necessary data relating to operations such as activation, stop and timing of the stencil printing apparatus and each drive unit. In particular, in this embodiment, data is stored that drives the blower motor 49, the conveyance motor 60, and the fan drive unit 88 when a print start signal is input, and stops the drive when the set number of prints is completed. .
[0062]
The separation / peeling operation of the paper 22 in the stencil printing apparatus having such a configuration will be described.
When the print start key 72 is pressed and a print start signal is input to the control means 34, the blower motor 49, the transport motor 60, and the fan drive unit 88 are driven, and the blower fan 46 rotates to rotate the entire sheet transport path 47. On the other hand, the air flow is started, the conveying belt 16a rotates counterclockwise, the suction fan 18a rotates, and a suction action is generated on the upper surface 16b of the conveying belt 16a and its peripheral portion. That is, an air flow is blown against the paper transport path 47 and a suction force acts on the transport surface on which the paper transport path 47 moves and its vicinity.
[0063]
When the leading end 22a of the paper 22 on which the first color image is printed at the printing position E1 reaches the upstream end 47a of the paper transport path 47, the air flow blown from the blower fan 46 and blown out from the outlet 57a of the branch flow path 57 is The top 22a of the paper 22 is sprayed from the upper side to the front end 22a of the paper 22 and the front end 22a of the paper 22 adhering to the outer peripheral surface 1Aa of the plate cylinder 1A is separated and separated from the front of the separation claw 7a. Rising is reduced. The leading end 22a of the separated paper 22 is guided toward the conveyor belt 16a by the air flow blown from the blowout port 57a. Therefore, the leading end 22a of the paper 22 reaches the transport belt 16a in the vicinity of the driven roller 14a and there is no transport delay of the paper 22, and image double printing is reduced.
[0064]
If the paper 22 is not stiff or if a large amount of ink adheres and the adhesive force between the paper 22 and the plate cylinder 1A is large, the adhesion period between the paper 22 and the plate cylinder 1A becomes long, as shown by the broken line in FIG. The leading end 22a of the paper 22 is separated from the outer peripheral surface 1Aa of the plate cylinder 1A by the separation claw 7a. When the leading end 22a is separated, an air flow is blown from the blowing port 57a to the separated portion, and the paper 22 is guided by the air flow toward the conveying belt 16a. As a result, even if the paper 22 moves in the transport direction X, contact between the separation claw 7a and the upper surface (print image surface) of the paper 22 is avoided, image rubbing by the separation claw 7a is eliminated, and the printing state of the paper 22 is good. It can be conveyed while being held in
[0065]
When the paper 22 adsorbed by the transport belt 16a and transported in the transport direction X reaches the range of the blowout port 58a of the branch flow path 58, an air flow blown from the blowout port 58a blows on the upper surface of the paper 22. Then, the paper 22 is pressed against the conveyor belt 16a. For this reason, the fluttering of the paper 22 on the transport belt 16a is extremely reduced, and the suction force by the suction fan 18a is transmitted to the paper 22 to obtain a sufficient transport force. Therefore, the conveyance delay to the printing position E2 of the paper 22 due to insufficient conveyance force is reduced, and image double printing is further reduced.
[0066]
When the conveyance of the sheet 22 further proceeds and the leading end 22a reaches the downstream end 47b of the sheet conveyance path 47, an air flow blown from the blowing port 59a of the branch flow path 59 is blown from above the sheet 22, and the driving roller The sheet 22 near 15a is pressed against the conveying belt 16a, and the leading end 22a of the sheet 22 that has passed over the driving roller 15a is pressed against the entry guide plate 64. For this reason, the fluttering of the leading end 22a of the paper 22 is extremely reduced, the position is stabilized, and the entry performance with respect to the printing position E2 is improved. Since the conveyance delay of the leading end 22a of the paper 22 reaching the downstream end 47b has already been reduced by the blowing of airflow from the branch flow paths 57 and 58, the conveyance delay to the printing position E2 can be further reduced. . As a result, image double printing can be further reduced.
[0067]
In this embodiment, the branch flow paths 57, 58, 59 are formed over the entire sheet conveyance path 47, but the present invention is not limited to this. When the conveyance delay with respect to the printing position E2 occurs due to the winding of the sheet 22 to the plate cylinder 1A, a flow path for blowing the air flow from the blower fan 46 is formed only at the upstream end 47a, and the sheet to the printing position E2 is formed. When there is a problem with the approachability of the belt 22, a flow path for blowing the air flow from the blower fan 46 is formed only at the downstream end 47b, and when there is a problem with the conveyance force by the conveyance belt 16a, the conveyance belt 16a. A flow path for blowing the air flow from the blower fan 46 may be formed only above. Since the main cause of the conveyance delay of the paper 22 with respect to the printing position E2 is often caused by the roll-up of the paper 22, a branch flow path 57 that blows an air flow at least at the upstream end 47a is provided. Two branch channels such as the channel 57 and the branch channel 58 or the branch channel 57 and the branch channel 59 may be formed. Ideally, the air flow is generated in the entire sheet conveyance path 47 as in the present embodiment. Blow out. When the conveyance delay of the sheet 22 with respect to the printing position E2 causes problems such as insufficient conveyance force by the conveyance belt 16a and the entry of the sheet 22 into the printing position E2, the blower fan 46 is inserted into the branch flow path 58 and the branch flow path 59. It is sufficient to blow an air flow from the air.
[0068]
Without providing the air guide plates 53 and 54, the lower ends 51b and 52b of the air guide plates 51 and 52 extend to the vicinity of the separation claw 7a and the conveyor belt 16a, respectively, and extend from the main channel 55 to the entire sheet transport path 47. If the air flow is blown, the configuration of the air guide member 48 can be simplified and the workability is improved.
[0069]
If the outlet 56 of the main channel 55 is divided to form the branch channels 57, 58, 59 as in this embodiment, the air flow inlets to the branch channels 57, 58, 59 are narrowed. The flow velocity of the air flow can be increased, and the blowing force against the paper 22 can be made stronger than when the air flow is blown out only from the outlet 56 of the main channel 55.
[0070]
In this embodiment, the entry guide plate 64 is provided. However, when the distance between the drive roller 15a and the printing position E2 is short, it is not always necessary to provide the entry guide plate 64. This is because the sheet 22 positioned before and after the driving roller 15a is pressed by the air flow from the branch flow path 59 and the suction force by the suction fan 18a, so that the leading end 22a of the sheet 22 pushes the driving roller 15a. This is because even if it passes, the stiffness is given to the tip 22a.
[0071]
(Second embodiment)
In this embodiment, as shown in FIGS. 5 and 6, the position of the outlet 57a of the branch flow path 57 in the first embodiment is set to the optimum airflow blowing angle. The blowout port 57a extends from the blower fan 46 in the tangential direction of the tangent line 66 at the point P where the line 65 connecting the tip 7b of the separation claw 7a and the rotation center of the plate cylinder 1A intersects the outer peripheral surface 1Aa of the plate cylinder 1A. It is provided so that an air flow can be blown.
[0072]
The outside of the air guide plate 51 and the inside of the air guide plate 53, and the outside of the air guide plate 52 and the inside of the air guide plate 54 are line targets based on a center line O that bisects the space between the plate cylinders 1A and 1B in the left-right direction. Placed in position.
[0073]
With such a configuration, the air flow blown from the blower fan 46 through the branch flow path 57 is blown between the tip 7b of the separation claw 7a and the outer peripheral surface 1Aa of the plate cylinder 1A. The air flow is blown toward the front end 22a of the paper 22 along the outer peripheral surface 1Aa. That is, the air flow blowing range to the front end 22a of the paper 22 is narrower than that in the first embodiment, and the front end 22a of the paper 22 adhered to the outer peripheral surface 1Aa of the plate cylinder 1A and the outer peripheral surface 1Aa of the plate cylinder 1A. By blowing an airflow in a pinpoint manner in between, the separation between the tip 22a and the outer peripheral surface 1Aa and the peelability from the outer peripheral surface 1Aa of the paper 22 are enhanced. Thereby, the roll-up of the paper 22 is further reduced, the conveyance delay of the paper 22 with respect to the printing position E2 is reduced, and image double printing can be further reduced.
[0074]
(Third embodiment)
The third embodiment is characterized in that the airflow generated by the blower fan 46 in the first and second embodiments is controlled so as to change according to the type of the paper 22. Specifically, the rotation of the blower motor 49 of the blower fan 46 is controlled using the control means 90 shown in FIG.
[0075]
The control means 90 includes a CPU (central processing unit) 91, an unillustrated I / O (input / output) port, ROM (read only storage device) 92, RAM (read / write storage device) 93, and the like. It consists of a known microcomputer having a configuration connected by a non-signal bus. Various keys of the operation panel 70, the display device 75, and the paper type selection key 43 are electrically connected to the control means 90, and command signals and / or on / off signals and data signals are transmitted and received between them. is doing. The paper type selection key 43 includes a key switch 43a that is selected when the paper is thick, a key switch 43b that is selected when the paper is a standard thickness, and a key switch 43c that is selected when the paper is thin. ing.
[0076]
The CPU 91 includes plate making apparatuses 41a and 41b and a plate making and feeding system driving section 83 for driving a plate feeding section (not shown), a plate making system driving section 84 for driving the plate discharging apparatuses 42a and 42b, and a paper feeding system for driving the paper feeding apparatus 20. A driving unit 85, a printing pressure system driving unit 86 for driving the printing pressure devices 32a and 32b, a paper discharging system driving unit 87 for driving the paper discharging device 35 and an air pressure generator (not shown), and a fan driving unit for driving the suction fan 18a. 88 are electrically connected to each other, and a command signal and / or an on / off signal and a data signal are transmitted and received between them, and start, stop, and timing of the devices and drive mechanisms of the respective parts of the stencil printing apparatus The entire system is controlled. A blower motor 49 is electrically connected to the CPU 91 via a voltage variable device 94.
[0077]
A conveyance motor 60 that rotationally drives the drive roller 15a and a plate cylinder drive motor 61 that rotationally drives the plate cylinder 1A are connected to the CPU 91 via drive circuits 62 and 63, respectively. In the control means 90, input information from sensors (not shown) and calculation results in the CPU 91 are temporarily stored in the RAM 93, and the information is read out in a timely manner.
[0078]
The ROM 92 stores in advance a program and necessary data regarding operations such as activation, stop, and timing of the stencil printing apparatus and each drive unit. In particular, in this embodiment, when a print start signal is input, the blower motor 49, the transport motor 60, and the fan drive unit 88 are driven, and when the set number of prints is completed, the driving data is stopped and the paper type is selected. Voltage control data for switching the voltage to the blower motor 49 by electrically operating the voltage variable device 94 in accordance with input information from the key 43 is stored.
[0079]
When the signal from the key switch 43a is input to the CPU 91, the voltage control data controls the voltage variable device 94 so that the voltage supplied to the blower motor 49 is lower than the reference voltage, and the signal from the key switch 43c is When input to the CPU 91, the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 becomes higher than the reference voltage. When a signal from the key switch 43 b is input to the CPU 91, it is supplied to the blower motor 49. The voltage variable device 94 is controlled so that the voltage to be used becomes the reference voltage.
[0080]
According to the stencil printing apparatus having the control means 90 having such a configuration, when the paper 22 loaded on the paper feed tray 21 is thick, the key switch 43a is pressed. Then, since the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 is lower than the reference voltage, the rotation of the blower fan 46 per unit time is reduced, and the per unit time generated by this fan is reduced. The air volume is reduced. For this reason, the air flow rate blown to the paper 22 through the branch flow paths 57, 58 and 59 shown in FIGS. 4 and 6 is reduced.
[0081]
When the paper 22 loaded on the paper feed tray 21 is thin, when the key switch 43c is pressed, the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 becomes higher than the reference voltage. The rotation per unit time increases, and the air volume per unit time generated by this fan increases. For this reason, the air flow rate blown to the paper 22 through the branch flow paths 57, 58 and 59 shown in FIGS. 4 and 6 increases.
[0082]
When the paper 22 is thick, the paper 22 is stiff and has good separation / peelability from the plate cylinder 1A, and even if the rotation of the blower motor 49 is suppressed, there is no problem. By reducing the heating of the motor 49, the durability of the motor can be increased and the energy of the apparatus can be saved. When the paper 22 is thin, the paper 22 is not stiff and sticks to the plate cylinder 1A, so that the separation / peelability is not good. In such a case, the rotation of the blower motor 49 is increased to increase the leading edge of the paper 22 Increasing the flow rate of air blown onto 22a can improve the entering property with respect to the printing position E2 as well as the separation / peelability. As described above, when the paper type selection key 43 is operated to control the blower motor 49 and the amount of airflow sprayed onto the paper 22 is automatically adjusted, image double printing can be reduced while shortening the adjustment time. Can do.
[0083]
(Fourth embodiment)
In the fourth embodiment, as shown in FIG. 8, between the plate cylinders 1A and 1B, a blower fan 46 rotated by a blower motor 49 and an air flow generated by the blower fan 46 are guided to a sheet conveying path 47. Intermediate air blowing means 99 having movable air guide plate outer portions 95 and 96 and movable air guide plate inner portions 97 and 98 as air guide members for forming a plurality of flow paths are provided. The inside of the movable air guide plates 97 and 98 is moved in accordance with the type of the paper 22 to change the flow path area and automatically adjust the flow rate of air blown onto the paper 22.
[0084]
The movable air guide plate outer portions 95 and 96 and the movable air guide plate inner portions 97 and 98 are formed to have widths somewhat longer than the lengths (widths) of the plate cylinders 1A and 1BA in the generatrix direction, respectively. The movable wind guide plate outer 95 and the movable wind guide plate inner 97 are tangent lines 66 at a point P where the line 65 connecting the tip 7b of the separation claw 7a and the rotation center of the plate cylinder 1A intersects the outer peripheral surface 1Aa of the plate cylinder 1A. 9 can be translated by a variable mechanism 100 shown in FIG. The movable air guide plate outside 95 and the movable air guide plate inside 97, and the movable air guide plate outside 96 and the movable wind guide plate inside 98 are based on a center line O that bisects the space between the plate cylinders 1A and 1B in the left-right direction. It is arranged at the position of the line object.
[0085]
The movable air guide plate outer portions 95 and 96 are curved so as to follow the outer peripheral surfaces 1Aa and 1Ba of the plate cylinders 1A and 1B, respectively, and are installed at positions that do not contact the clampers 5a and 5b when the plate cylinders 1A and 1B rotate. Has been. As shown in FIG. 9, the upper ends 95 a and 96 a of the movable air guide plate outer portions 95 and 96 extend to the case 46 a of the blower fan 46 and are formed between the movable air guide plate outer portions 95 and 96. The blower fan 46 is positioned at the center in the main flow path 105. Pins 101 and 102 extending in the generatrix direction of the plate cylinder 1A are rotatably provided at upper ends 95a and 96a of the movable air guide plate outer portions 95 and 96, respectively. The pins 101 and 102 are loosely fitted into arcuate guide holes 103 and 104 provided on the side plates of the device (not shown), respectively, and the upper ends 95a and 96a can freely swing when the movable air guide plate outer portions 95 and 96 move. In addition, the movement amount of the movable air guide plate outer portions 95, 96 to the outer peripheral surfaces 1Aa, 1Ba of the plate cylinders 1A, 1B is limited so as not to contact the clampers 5a, 5b. Lower ends 95 b and 96 b of the movable air guide plate outer portions 95 and 96 are respectively pin-coupled to racks 106 and 107 constituting one configuration of the variable mechanism 100.
[0086]
The movable air guide plates 97 and 98 are curvedly formed along the outer peripheral surfaces 1Aa and 1Ba of the plate cylinders 1A and 1B, respectively, and spread toward the paper transport path 47 below the air guide plates 95 and 96. Are arranged in a square shape. Upper ends 97 a and 98 a of the movable air guide plates 97 and 98 are respectively pin-coupled to racks 108 and 109 constituting one structure of the variable mechanism 100, and are arranged inside the outlet 110 of the main flow path 105. The air outlet 110 is divided into three parts by the movable air guide plates 97 and 98, and three branch passages 111, 112, and 113 are formed between the plate cylinders 1A and 1B. A lower end 97b of the movable air guide plate 97 extends to the vicinity of the separation claw 7a as shown in FIG. The lower end 98 b of the movable air guide plate 98 extends to the vicinity of the downstream end 47 b of the paper transport path 47.
[0087]
The branch flow path 111 is formed between the outer peripheral surface 1Aa of the plate cylinder 1A and the outer surface of the movable air guide plate 97, and the blowout port 111a is located between the driven roller 14a and the plate cylinder 1A. It is arranged at the upstream end 47 a of the paper transport path 47. The branch channel 113 is formed between the outer peripheral surface 1Ba of the plate cylinder 1B and the outer surface of the movable air guide plate 98, and the blowout port 113a is located between the drive roller 15a and the plate cylinder 1B. It is arranged at the downstream end 47 b of the paper transport path 47. The branch channel 112 is formed between the movable air guide plates 97 and 98, and the outlet 112 a is disposed on the transport belt 16 a serving as a transport unit of the paper transport path 47.
[0088]
The variable mechanism 100 includes a pair of racks 106 and 108 that connect the movable air guide plate outer 95 and the movable air guide plate 97 so as to be relatively movable, a small gear 114 that meshes with the racks 106 and 108, the movable air guide plate outer 96, and the movable guide. A pair of racks 107 and 109 that connect the inside of the wind plate 97 to be relatively movable and a small gear 115 meshing with the pair of racks 107 and 109, a wind guide plate drive motor 116 that serves as a drive source, and outputs of the wind guide plate drive motor 116 are output. It is mainly composed of a power transmission mechanism 117 that transmits to the movable air guide plates 97 and 98. The racks 106 and 108 and the racks 107 and 109 are arranged to face each other in parallel with the small gears 114 and 115 interposed therebetween. When one of the racks 108 and 109 moves, the racks 106 and 107 are moved in the opposite directions. It has a configuration. The air guide plate drive motor 116 is a stepping motor that can rotate in both directions, and an output gear 128 is fixed to an output shaft 116a thereof.
[0089]
As shown in FIGS. 9 and 11, the power transmission mechanism 117 includes a movable belt 120 wound around pulleys 118 and 119 and a movable belt 123 wound around pulleys 121 and 122, respectively. The center parts of 97 and 98 are fixed via holders 124 and 125. The pulleys 119 and 122 are provided on the rotary shafts 126 and 127 with the electromagnetic clutches 119a and 122a incorporated therein, respectively, and rotate integrally with the rotary shafts 126 and 127 when the electromagnetic clutches 119a and 122a are turned on. Yes. Driving gears 130 and 131 connected to the output gear 128 via the connecting gear 129 are fixed to the rotating shafts 126 and 127. The moving belt 120 is provided in parallel with the racks 106 and 108, and the moving belt 123 is provided in parallel with the racks 107 and 109. The holders 124 and 125 are fixed to the belt surfaces that move in the same direction in the moving belts 120 and 123.
[0090]
When the air guide plate moving belts 120 and 123 move in the clockwise direction, the movable air guide plates 97 and 98 move together with the racks 108 and 109 in the direction of narrowing the branch flow path 112, and the moving belts 120 and 123 are counterclockwise. When it moves in the turning direction, it moves together with the racks 108 and 109 in the direction of expanding the branch flow path 112.
[0091]
When the movable air guide plates 97 and 98 move in the direction of narrowing the branch flow path 112, the racks 106 and 107 move in the opposite direction to the racks 108 and 109, and the movable air guide plates outside 95 and 96 are moved to the plate cylinder 1A, respectively. When the movable air guide plates 97 and 98 move in the direction of expanding the branch flow path 112, the racks 106 and 107 move in the opposite direction to the racks 108 and 109. The movable air guide plate outer portions 95 and 96 are moved in directions away from the outer peripheral surfaces 1Aa and 1Ba of the plate cylinders 1A and 1B, respectively.
[0092]
That is, when the moving belts 120 and 123 are moved in the counterclockwise direction, the movable air guide plates 97 and 98 and the movable air guide plates in which the main flow path 105 and the branch flow paths 111 and 113 shown in FIG. The outer portions 95 and 96 move as shown in FIG. 10 to narrow the width of the main flow path 105, and at the same time, are branched by the lower end 95b of the movable air guide plate 95 and the upper end 97a of the movable air guide plate 97. The inlet 113b of the branch channel 113 constituted by the inlet 111b of the channel 111, the lower end 96b of the movable air guide plate 96 and the upper end 98a of the movable air guide plate 98 is narrowed.
[0093]
When the moving belts 120 and 123 are moved in the clockwise direction, the movable air guide plate inside 97 and 98 and the movable air guide plate outside 95 and the main flow channel 105 and the branch flow channels 111 and 113 shown in FIG. 96 moves as shown in FIG. 9 to widen the main channel 105, and the inlet 111b and the inlet 113b are also enlarged.
[0094]
The electromagnetic clutches 119a and 122a and the air guide plate drive motor 116 are under the control of the control means 132 shown in FIG. The control means 132 includes a CPU (central processing unit) 133, an I / O (input / output) port (not shown), a ROM (read only storage device) 134, a RAM (read / write storage device) 135, and the like. It consists of a known microcomputer having a configuration connected by a non-signal bus. The control means 132 is electrically provided with a numeric keypad 71, a printing start key 72, a plate making start key 73, various operation keys 74 and 77, display devices 75 and 76, and a paper type selection key 43 of the operation panel 70 shown in FIG. They are connected to transmit / receive command signals and / or on / off signals and data signals to / from them. The paper type selection key 43 includes a key switch 43a, a key switch 43b, and a key switch 43c as in the third embodiment.
[0095]
The CPU 133 includes plate making apparatuses 41a and 41b and a plate making and feeding system driving section 83 for driving a plate feeding section (not shown), a plate making system driving section 84 for driving the plate discharging apparatuses 42a and 42b, and a paper feeding system for driving the paper feeding apparatus 20. A driving unit 85, a printing pressure system driving unit 86 for driving the printing pressure devices 32a and 32b, a paper discharging system driving unit 87 for driving the paper discharging device 35 and an air pressure generator (not shown), and a fan driving unit for driving the suction fan 18a. 88 are electrically connected to each other, and a command signal and / or an on / off signal and a data signal are transmitted and received between them, and start, stop, and timing of the devices and drive mechanisms of the respective parts of the stencil printing apparatus The entire system is controlled.
[0096]
The air guide plate drive motor 116 is electrically connected to the CPU 133 via the drive circuit 136. A conveyance motor 60 that rotationally drives the driving roller 15a, a plate cylinder driving motor 61 that rotationally drives the plate cylinder 1A, and a blower motor 49 are connected to the CPU 133 via drive circuits 62, 63, and 50, respectively. In the control means 132, the input information from each sensor and the calculation result in the CPU 133 are temporarily stored in the RAM 135, and the information is read out in a timely manner.
[0097]
The ROM 134 stores in advance programs related to operations such as activation, stop, and timing of the stencil printing apparatus and each drive unit, and necessary data. Particularly in this embodiment, when a print start signal is input from the print start key 72, the blower motor 49, the transport motor 60, and the fan drive unit 88 are driven, and when the set number of prints is completed, these drives are stopped. Data for switching the rotation direction of the air guide plate drive motor 116 in accordance with data and input information from the paper type selection key 43 and for controlling on / off of the electromagnetic clutches 119a and 122a are stored.
[0098]
The control data for the air guide plate drive motor 116 and the electromagnetic clutches 119a and 122a is such that when the signal from the key switch 43a is input to the CPU 133, the electromagnetic clutches 119a and 122a are turned on to drive the drive force from the air guide plate drive motor 116. Can be transmitted to the moving belts 120 and 123, and the direction of rotation of the air guide plate drive motor 116 to move the movable air guide plates 97 and 98 in the direction of narrowing the main flow path 105 and the inlets 111b and 113b, respectively. To control.
[0099]
When a signal from the key switch 43c is input to the CPU 133, the electromagnetic clutches 119a and 122a are turned on so that the driving force from the wind guide plate driving motor 116 can be transmitted to the moving belts 120 and 123, and the main flow path 105 and The rotational direction of the air guide plate drive motor 116 is controlled so as to move the movable air guide plates 97 and 98 in the direction in which the inlets 111b and 113b become wider, respectively.
[0100]
In this embodiment, when the output shaft 116a of the air guide plate drive motor 116 is rotationally driven in the clockwise direction, the moving belts 120 and 123 are rotated in the clockwise direction, respectively, and the output shaft 116a is rotationally driven in the counterclockwise direction. Then, each of the moving belts 120 and 123 rotates and moves in the counterclockwise direction.
[0101]
According to the stencil printing apparatus having such a configuration, when the paper 22 stacked on the paper feed tray 21 shown in FIG. 8 is thick, the key switch 43a is pressed. Then, the output shaft 116a of the air guide plate drive motor 116 is rotationally driven in the counterclockwise direction, and the moving belts 120 and 123 are rotated in the counterclockwise direction, so that the main flow path 105 and the inlets 111b and 113b Becomes narrower as shown in FIG. As a result, the areas of the inlets 111b and 113b and the branch channels 111 and 113 are reduced along with the area of the main channel 105, and the air flow rate per unit time introduced into the branch channels 111 and 113 from the inlets 111b and 113b is reduced. Less.
[0102]
For this reason, the flow rate of air blown to the upstream end 47a and the downstream end 47b of the paper transport path 47 is reduced, and the air flow blown to the paper 22 is reduced. Further, when the inflow ports 111b and 113b are narrowed, the branch flow path 112 is widened. However, since the main flow path 105 is narrowed, the flow rate of air flowing through the branch flow path 112 is relatively reduced and blown to the entire conveying belt 16a.
[0103]
When the paper 22 loaded on the paper feed tray 21 is thin, the key switch 43c is pressed. Then, the output shaft 116a of the air guide plate driving motor 116 is rotationally driven in the clockwise direction, and the moving belts 120 and 123 are rotated in the clockwise direction, so that the main flow path 105 and the inlets 111b and 113b are illustrated. As shown in FIG. This increases the area of the inlets 111b and 113b and the branch channels 111 and 113 together with the area of the main channel 105, and the air flow rate per unit time introduced into the branch channels 111 and 113 from the inlets 111b and 113b is large. Become. For this reason, the flow rate of air blown to the upstream end 47 a and the downstream end 47 b of the paper transport path 47 increases, and the flow rate of air blown to the paper 22 on the paper transport path 47 increases. Further, when the inflow ports 111b and 113b are widened, the branch flow path 112 is narrowed, but the main flow path 105 is widened. Therefore, the air flow rate flowing through the branch flow path 112 is relatively increased, and the entire upper surface 16b of the conveyor belt 16a is formed. Be sprayed.
[0104]
When the paper 22 is thick, the paper 22 is firm and has good separation / peelability from the plate cylinder 1A, and there is no problem even if the amount of airflow to the paper 22 is suppressed. 22 is not stiff and sticks to the plate cylinder 1A, so that the separation / peelability and the penetration of the plate cylinder 1B with respect to the printing position E2 are not good. In such a case, the main channel 105 and the branch channel 111, By widening 113 and increasing the flow rate of air blown onto the paper 22, the separation / peelability of the plate cylinder 1 </ b> A and the paper 22 and the performance of entering the printing position E <b> 2 can be improved. As described above, by operating the paper type selection key 43 to control the flow area of the air flow with respect to the paper 22 and automatically adjust the amount of air flow sprayed onto the paper 22, the adjustment time can be shortened. Image double printing can be reduced.
[0105]
In this embodiment, the movable air guide plate outer portions 95 and 96 are configured to move in conjunction with the movable air guide plate inner portions 97 and 98. However, the racks 106, 107, 108, and 109 and the gears 114 and 115 are not provided. Further, only the movable air guide plates 97 and 98 are moved by the moving belts 120 and 123 to move only the branch flow paths 111, 112, and 113, and the flow rate of air blown onto the paper 22 is adjusted. Also good. Alternatively, only one of the electromagnetic clutches 119a and 122a is turned on so that the driving force is not transmitted, and the movable air guide plate 97 and the movable air guide plate outside 95 side or the movable air guide plate 98 is movable. Even if only one side of the air guide plate outside 96 is moved and the air flow rate blown onto the paper 22 is automatically adjusted, image double printing can be reduced while shortening the adjustment time.
[0106]
(5th Example)
In the fifth embodiment, the flow volume selection key serving as the air volume setting means is performed together with the variable control of the flow path area performed in the fourth embodiment and the rotation control of the blower motor 49 that drives the blower fan 46 performed in the third embodiment. 44 and the adjustment key 78, the blower fan 46 is individually controlled. Specifically, the stencil printing apparatus is controlled using the control means 140 shown in FIG. Hereinafter, the configuration of the control unit 140 and the control operation by the control unit 140 will be described. The description of the stencil printing apparatus shown in FIG.
[0107]
The control means 140 includes a CPU (central processing unit) 141, an I / O (input / output) port (not shown), a ROM (read only storage device) 142, a RAM (read / write storage device) 143, and the like. It consists of a known microcomputer having a configuration connected by a non-signal bus. The control means 140 is electrically provided with various keys on the operation panel 70 and the display device 75 shown in FIG. And transmit / receive command signals and / or on / off signals and data signals to / from them.
[0108]
The CPU 141 includes plate making apparatuses 41a and 41b and a plate making / feeding system driving section 83 for driving a plate feeding section (not shown), a plate making system driving section 84 for driving the plate discharging apparatuses 42a and 42b, and a paper feeding system for driving the paper feeding apparatus 20. A driving unit 85, a printing pressure system driving unit 86 for driving the printing pressure devices 32a and 32b, a paper discharging system driving unit 87 for driving the paper discharging device 35 and an air pressure generator (not shown), and a fan driving unit for driving the suction fan 18a. 88 are electrically connected to each other, and a command signal and / or an on / off signal and a data signal are transmitted and received between them, and start, stop, and timing of the devices and drive mechanisms of the respective parts of the stencil printing apparatus The entire system is controlled.
[0109]
The blower motor 49 is connected to the CPU 141 via the voltage variable device 94. A conveyance motor 60 that rotationally drives the drive roller 15a and a plate cylinder drive motor 61 that rotationally drives the plate cylinder 1A are connected to the CPU 141 via drive circuits 62 and 63, respectively. The CPU 141 is connected to the air guide plate drive motor 116 via the drive circuit 136 and is also connected to the electromagnetic clutches 119a and 122a.
[0110]
In the control means 140, input information from sensors (not shown) and calculation results in the CPU 141 are temporarily stored in the RAM 143, and the information is read out in a timely manner.
[0111]
The ROM 142 stores in advance a program and necessary data regarding operations such as activation, stop, and timing of the stencil printing apparatus and each drive unit. In particular, in this embodiment, when a print start signal is input, the blower motor 49, the transport motor 60, and the fan drive unit 88 are driven, and when the set number of prints is completed, the driving data is stopped and the paper type is selected. According to the input information from the key 43, the voltage variable device 94 is electrically operated to switch the rotation direction of the air guide plate drive motor 116, to switch the voltage to the blower motor 49, and to switch the electromagnetic clutches 119a, 122a. Data for on / off control is stored.
[0112]
Here, when a signal from the key switch 43a is input to the CPU 141, the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 is lower than the reference voltage, and the electromagnetic clutches 119a and 122a are turned on. Thus, the driving force from the air guide plate drive motor 116 can be transmitted to the moving belts 120 and 123, and the insides of the movable air guide plates 97 and 98 are moved in the direction of narrowing the main flow path 105 and the inlets 111b and 113b, respectively. Therefore, the rotation direction of the air guide plate drive motor 116 is controlled.
[0113]
When a signal from the key switch 43c is input to the CPU 141, the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 becomes higher than the reference voltage, and the electromagnetic clutches 119a and 122a are turned on to guide the air. It is possible to transmit the driving force from the plate driving motor 116 to the moving belts 120 and 123, and to guide the moving air guide plates 97 and 98 in such a direction that the main flow path 105 and the inlets 111b and 113b become wider, respectively. The direction of rotation of the plate drive motor 116 is controlled. Further, when a signal from the key switch 43b is input to the CPU 141, the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 becomes the reference voltage.
[0114]
In the control means 140, when a selection signal from the air volume selection key 44 is input to the CPU 141, the signal from the adjustment key 78 is preferentially received, and the voltage variable device 94 is electrically operated based on this signal to drive the blower motor. The voltage for 49 is switched stepwise.
[0115]
According to the stencil printing apparatus having such a configuration, when the paper 22 stacked on the paper feed tray 21 shown in FIG. 8 is thick, the key switch 43a is pressed. Then, the output shaft 116a of the air guide plate drive motor 116 is rotationally driven in the counterclockwise direction, and the moving belts 120 and 123 are rotated in the counterclockwise direction, so that the main flow path 105 and the inlets 111b and 113b Becomes narrower as shown in FIG. For this reason, the area of the inflow ports 111b and 113b and the branch flow paths 111 and 113 is reduced together with the area of the main flow path 105. Further, since the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 is lower than the reference voltage, the rotation of the blower fan 46 per unit time is reduced, and the unit per unit time generated by this fan is reduced. The air volume is reduced.
[0116]
Therefore, the air flow rate per unit time introduced from the inlets 111b and 113b into the branch flow paths 111 and 113 is reduced, and the air flow rate blown to the upstream end 47a and the downstream end 47b of the paper transport path 47 is reduced. Thus, the air flow blown to 22 is lowered. When the inlets 111b and 113b are narrowed, the branch passage 112 is widened, but the main flow path 105 is narrowed and the air volume per unit time generated by the blower fan 46 is also reduced. Decreases and is sprayed on the entire conveyor belt 16a.
[0117]
When the paper 22 loaded on the paper feed tray 21 is thin, the key switch 43c is pressed. Then, since the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 becomes higher than the reference voltage, the rotation of the blower fan 46 per unit time increases, and the per unit time generated by this fan increases. The air volume increases. In addition, since the output shaft 116a of the air guide plate drive motor 116 is driven to rotate in the clockwise direction, and the moving belts 120 and 123 rotate in the clockwise direction, the main flow path 105 and the inlets 111b and 113b are wide. Become. This increases the area of the inlets 111b and 113b and the branch channels 111 and 113 together with the area of the main channel 105, and the air flow rate per unit time introduced into the branch channels 111 and 113 from the inlets 111b and 113b is large. Become.
[0118]
For this reason, the flow rate of air blown to the upstream end 47a and the downstream end 47b of the sheet transport path 47 increases, and the flow rate of air blown to the sheet 22 located near the plate cylinders 1A and 1B increases. In addition, when the inflow ports 111b and 113b are widened, the branch flow path 112 is narrowed, but the main flow path 105 is widened and the air volume per unit time generated by the blower fan 46 is increased. The air flow rate is relatively increased, and a sufficient air flow is blown over the entire upper surface 16b of the conveyor belt 16a.
[0119]
When the paper 22 is thick, the paper 22 is stiff and has good separation / peelability from the plate cylinder 1A, and even if the rotation of the blower motor 49 is suppressed, there is no problem. By reducing the heating of the motor 49, the durability of the motor can be increased and the energy of the apparatus can be saved. When the paper 22 is thin, the paper 22 is not stiff and sticks to the plate cylinder 1A, so that the separation / peeling property and the entrance to the printing position E2 of the plate cylinder 1B are not good. By increasing the rotation of the blower motor 49 and widening the main flow path 105 and the branch flow paths 111 and 113 to increase the flow rate of air blown to the paper 22, separation / peelability and entry performance can be improved.
[0120]
As described above, the control unit 140 automatically determines the air volume per unit time generated by the blower fan 46 according to the type of the paper 22 and the area of the flow path for blowing this air flow toward the paper 22. By variably controlling, the amount of air flow sprayed onto the paper 22 can be finely adjusted, and the conveyance performance of the paper 22 can be improved along with the separation / peelability of the paper 22 from the plate cylinder 1A and the approachability to the printing position E2. Can be improved. As described above, when the paper type selection key 43 is operated to control the blower motor 49 and the air guide plate driving motor 116 to automatically adjust the amount of airflow sprayed onto the paper 22, image double printing is performed while shortening the adjustment time. Can be reduced.
[0121]
On the other hand, even if such a type of paper 22 is selected and each part is controlled, it is conceivable that image double printing of the paper 22 occurs due to a failure or the like. In such a case, when the air volume selection key 44 is pressed, a manual mode is given in which the signal from the adjustment key 78 is prioritized over the control based on the type of the paper 22. When the up key 78b is pressed, the voltage from the voltage varying device 94 to the blower motor 49 increases stepwise based on this signal, the air volume of the air flow generated by the blower fan 46 per unit time increases, and the down key 78a is pressed. When pressed, the voltage from the voltage varying device 94 to the blower motor 49 is reduced stepwise based on this signal, and the airflow per unit time generated by the blower fan 46 is reduced.
[0122]
Therefore, even if a trouble occurs in the control system corresponding to the type of the paper 22, the amount of airflow sprayed on the paper 22 is manually adjusted by operating the adjustment key 78 while viewing the state of the image printed on the paper 22. In addition to the separation / peelability of the paper 22 from the plate cylinder 1A and the penetration into the printing position E2, the paper conveyance performance can be improved, and the occurrence of image double printing can be stably reduced.
[0123]
(Sixth embodiment)
In the sixth embodiment, the intermediate air blowing means 99 shown in FIG. 8 is controlled according to the input information from the paper size selection key 79 serving as the paper size setting means shown in FIG. Is to adjust. Specifically, the control means 150 shown in FIG. 14 is used to perform rotation control of the blower motor 49 and variable control of the flow passage area by the wind guide plate drive motor 116. Hereinafter, the configuration of the control unit 150 and the control operation by the control unit 150 will be described. The description of the stencil printing apparatus shown in FIG. 8 will be continued as an example of the mechanical configuration of the stencil printing apparatus.
[0124]
The control means 150 includes a CPU (central processing unit) 151, an I / O (input / output) port (not shown), a ROM (read only storage device) 152, a RAM (read / write storage device) 153, and the like. It consists of a known microcomputer having a configuration connected by a non-signal bus. 3 are electrically connected to various keys of the operation panel 70 shown in FIG. 3, a display device 75, and a paper size selection key 79 for outputting a signal corresponding to the size of the paper 22. A command signal and / or an on / off signal and a data signal are transmitted and received between them. The paper size selection key 79 is a key switch 79a that is selected when the paper 22 is a relatively small size such as B6 or A5, and the key switch that is selected when the paper is a standard size such as B5 or A4. 79b and a key switch 79c that is selected in the case of relatively large paper such as B4 and A3.
[0125]
The CPU 151 includes a plate making apparatus 41a and 41b and a plate making and feeding system driving section 83 for driving a plate feeding section (not shown), a plate making system driving section 84 for driving the plate discharging apparatuses 42a and 42b, and a paper feeding system for driving the paper feeding apparatus 20. A driving unit 85, a printing pressure system driving unit 86 for driving the printing pressure devices 32a and 32b, a paper discharging system driving unit 87 for driving the paper discharging device 35 and an air pressure generator (not shown), and a fan driving unit for driving the suction fan 18a. 88 are electrically connected to each other, and a command signal and / or an on / off signal and a data signal are transmitted and received between them, and start, stop, and timing of the devices and drive mechanisms of the respective parts of the stencil printing apparatus The entire system is controlled.
[0126]
The blower motor 49 is connected to the CPU 151 via the voltage variable device 94. A conveyance motor 60 that rotationally drives the drive roller 15a and a plate cylinder drive motor 61 that rotationally drives the plate cylinder 1A are connected to the CPU 151 via drive circuits 62 and 63, respectively. The CPU 151 is connected to a wind guide plate drive motor 116 via a drive circuit 136 and is also connected to electromagnetic clutches 119a and 122a.
[0127]
In the control means 150, input information from sensors (not shown) and calculation results in the CPU 151 are temporarily stored in the RAM 153, and the information is read out in a timely manner.
[0128]
The ROM 152 stores programs and necessary data relating to operations such as activation, stop, and timing of the stencil printing apparatus and each drive unit in advance. In particular, in this embodiment, when a print start signal is input, the blower motor 49, the transport motor 60, and the fan drive unit 88 are driven, and when the set number of prints is finished, data for stopping these drives and a paper size selection are selected. The direction of rotation of the air guide plate drive motor 116 is switched according to the input information from the key 79, the voltage variable device 94 is electrically operated to switch the voltage to the blower motor 49, and the electromagnetic clutches 119a and 122a are switched. Data for on / off control is stored.
[0129]
Here, when a signal from the key switch 79a is input to the CPU 151, the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 is lower than the reference voltage, and the electromagnetic clutches 119a and 122a are turned on. Thus, the driving force from the air guide plate drive motor 116 can be transmitted to the moving belts 120 and 123, and the insides of the movable air guide plates 97 and 98 are moved in the direction of narrowing the main flow path 105 and the inlets 111b and 113b, respectively. Therefore, the rotation direction of the air guide plate drive motor 116 is controlled.
[0130]
When a signal from the key switch 79c is input to the CPU 151, the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 becomes higher than the reference voltage, and the electromagnetic clutches 119a and 122a are turned on to guide the air. It is possible to transmit the driving force from the plate driving motor 116 to the moving belts 120 and 123, and to guide the moving air guide plates 97 and 98 in such a direction that the main flow path 105 and the inlets 111b and 113b become wider, respectively. The direction of rotation of the plate drive motor 116 is controlled. When the signal from the key switch 79b is input to the CPU 151, the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 becomes the reference voltage.
[0131]
According to the stencil printing apparatus provided with such control means 150, when the paper 22 stacked on the paper feed tray 21 shown in FIG. 8 is a relatively small size such as B6 or A5 size, the key switch 79a is pressed. To do. Then, the output shaft 116a of the air guide plate drive motor 116 is rotationally driven in the counterclockwise direction, and the moving belts 120 and 123 are rotated in the counterclockwise direction, so that the main flow path 105 and the inlets 111b and 113b Becomes narrower as shown in FIG. For this reason, the area of the inflow ports 111b and 113b and the branch flow paths 111 and 113 is reduced together with the area of the main flow path 105. Further, since the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 is lower than the reference voltage, the rotation of the blower fan 46 per unit time is reduced, and the unit per unit time generated by this fan is reduced. The air volume is reduced.
[0132]
Accordingly, the air flow rate per unit time introduced into the branch flow paths 111 and 113 from the inlets 111b and 113b is reduced, and the air flow rate blown to the upstream end 47a and the downstream end 47b of the paper transport path 47 is reduced and small. The air flow blown to the size paper 22 is reduced. At this time, if the inflow ports 111b and 113b are narrowed, the branch passage 112 is widened, but the main flow path 105 is narrowed and the air volume per unit time generated by the blower fan 46 is reduced. The flow rate is relatively reduced and sprayed on the entire conveyor belt 16a.
[0133]
When the paper 22 loaded on the paper feed tray 21 is a relatively large size such as B4 or A3, the key switch 79c is pressed. Then, since the voltage variable device 94 is controlled so that the voltage supplied to the blower motor 49 becomes higher than the reference voltage, the rotation of the blower fan 46 per unit time increases, and the per unit time generated by this fan increases. The air volume increases. In addition, since the output shaft 116a of the air guide plate drive motor 116 is driven to rotate in the clockwise direction, and the moving belts 120 and 123 rotate in the clockwise direction, the main flow path 105 and the inlets 111b and 113b are wide. Become. This increases the area of the inlets 111b and 113b and the branch channels 111 and 113 together with the area of the main channel 105, and the air flow rate per unit time introduced into the branch channels 111 and 113 from the inlets 111b and 113b is large. Become.
[0134]
For this reason, the air flow rate blown to the upstream end 47a and the downstream end 47b of the paper transport path 47 is increased, and the air flow rate blown to the large size paper 22 located in the vicinity of the plate cylinders 1A and 1B is increased. In addition, when the inflow ports 111b and 113b are widened, the branch flow path 112 is narrowed, but the main flow path 105 is widened and the air volume per unit time generated by the blower fan 46 is increased. The air flow rate is relatively increased, and a sufficient air flow is blown over the entire upper surface 16b of the conveyor belt 16a.
[0135]
When the paper 22 is small, the contact surface between the paper 22 and the plate cylinder 1A is small and the length in the transport direction X is short, so that the separation and release from the plate cylinder 1A is good and the rotation of the blower motor 49 is suppressed. Therefore, by suppressing the rotation of the blower motor 49, it is possible to reduce the heating of the blower motor 49, increase the durability of the motor, and save energy in the apparatus. When the paper 22 is large, the contact surface between the paper 22 and the plate cylinder 1A is large, and the length in the transport direction X is also long. Therefore, the separation / peelability from the plate cylinder 1A and the printing position E2 of the plate cylinder 1B are increased. Since the approachability is not good, in such a case, the rotation of the blower motor 49 is increased, and the main flow path 105 and the branch flow paths 111 and 113 are widened to increase the air flow rate blown to the paper 22. Even the size of the paper 22 can improve the penetration into the printing position E2 as well as the separation / peelability from the plate cylinder 1A.
[0136]
By changing the amount of airflow per unit time generated by the blower fan 46 according to the size of the paper 22 and the area of the flow path for blowing this airflow toward the paper 22, the airflow with respect to the paper 22 is changed. The spraying amount can be adjusted more finely and automatically, and the conveyance performance of the paper 22 can be improved together with the separation / peeling property of the paper 22 from the plate cylinder 1A and the entry property to the printing position E2. As described above, by operating the paper size selection key 79 to control the blower motor 49 and the air guide plate driving motor 116 to automatically adjust the amount of airflow sprayed onto the paper 22, the image is reduced while reducing the adjustment time. Double printing can be reduced.
[0137]
In the present embodiment, the paper size selection key 79 that is operated by manual operation is used as the paper size setting means. However, the present invention is not limited to this. As an example, a well-known photointerrupter type optical sensor having a light projecting element and a light receiving element and a shielding member that is slidable according to the size of the paper 22 and shields the optical sensor according to the paper size are fed. A paper size setting unit may be provided on the tray 21 so that the paper size is automatically detected when the paper 22 is set on the paper feed tray 21.
[0138]
In the sixth embodiment, as in the fifth embodiment, the air volume selection key 44 is provided. When the air volume selection key 44 is pressed, the signal from the adjustment key 78 is prioritized over the control based on the size of the paper 22. By pressing the up key 78b or the down key 78a, the voltage to the blower motor 49 from the voltage variable device 94 is stepped up or down stepwise, and the air per unit time generated by the blower fan 46 is set. The flow volume of the flow may be increased or decreased. In this way, even when a trouble occurs in the control system corresponding to the size of the paper 22, the air flow is blown onto the paper 22 by operating the adjustment key 78 while viewing the state of the image printed on the paper 22. The amount can be manually adjusted, the separation / peeling property of the paper 22 from the plate cylinder 1A and the entry property to the printing position E2, and the paper conveyance performance can be improved, and the occurrence of image double printing can be stably reduced. Can do.
[0139]
When the air volume selection key 44 and the adjustment key 78 used in the fifth embodiment are connected to the control means 90 of the third embodiment, and the air volume selection key 44 is pressed, the adjustment key is more effective than the signal from the paper type selection key 43. A manual mode in which the signal from 78 is prioritized may be set. In this way, even if a trouble occurs in the control system corresponding to the type of the paper 22, the amount of airflow sprayed on the paper 22 by operating the adjustment key 78 while viewing the state of the image printed on the paper 22. Can be adjusted manually, and the paper conveyance performance can be improved along with the separation / peelability of the paper 22 from the plate cylinder 1A and the penetration into the printing position E2, and the occurrence of image double printing can be stably reduced. become able to.
[0140]
In the third embodiment, the amount of air generated by the blower fan 46 is controlled according to the paper type (thickness) using the paper type selection key 43, but the sixth embodiment does not use the paper type selection key 43. As described above, the air volume generated by the blower fan 46 may be controlled in accordance with the size of the paper 22 by using the paper size setting key 79. In this case, when the size of the paper 22 is large, the amount of air generated by the blower fan 46 is increased. When the size of the paper 22 is small, the amount of air generated by the blower fan 46 is controlled to be reduced. As a result, the paper 22 having a large size can be separated and peeled off from the plate cylinder 1A, and can enter the printing position E2 to reduce image double printing.
[0141]
In the fifth embodiment, the blower motor 49 is controlled using the adjustment key 78 to manually adjust the amount of air generated by the blower fan 46. However, the rotation of the air guide plate drive motor 116 is controlled together with the blower motor 49 to flow the air. The amount of airflow sprayed onto the paper 22 may be manually adjusted by increasing or decreasing the road area, or the airflow sprayed amount onto the paper 22 may be manually adjusted by controlling only the air guide plate driving motor 116 alone. You may do it.
[0142]
【The invention's effect】
According to the first aspect of the present invention, the air flow generated by the air source is efficiently guided and blown to the sheet conveyance path formed between the upstream plate cylinder and the downstream plate cylinder by the air guide member. Therefore, the separation performance between the upstream plate cylinder and the paper is improved, the paper is pressed against the suction conveyance device to improve the conveyance performance, and at the leading edge of the paper when the paper enters the downstream plate cylinder. When the air is blown, the paper entrance performance with respect to the downstream plate cylinder is improved, and image double printing can be reduced.
[0143]
According to the second aspect of the present invention, since the air flow from the air source is efficiently blown between the tip of the separation claw and the outer peripheral surface of the plate cylinder, the separation / separation of the sheet from the upstream plate cylinder is performed. The performance becomes more reliable and image double printing can be further reduced.
[0144]
Claim 1 According to the described invention, the air flow is simultaneously blown to at least two positions of the upstream end and the downstream end of the sheet transport path by the air source and the air guide member of the intermediate air blowing means. Separation performance from paper And At least two of the paper entrance performances with respect to the downstream plate cylinder can be improved at the same time, and image double printing can be further reduced.
[0145]
Claim 3 According to the described invention, the amount of air generated at the air source is controlled by the control means in accordance with the input information from the paper information input means, so that the amount of airflow blown onto the paper on the paper transport path can be adjusted in a short time. As a result, the separation performance between the upstream plate cylinder and the paper and the paper conveyance performance in the suction conveyance device are improved, and the paper entry performance into the downstream plate cylinder is improved and image double printing is performed. Can be further reduced.
[0146]
Claim 4 According to the described invention, since the air volume setting means adjusts the air volume generated by the air source separately from the paper information input means and variably controls the amount of airflow blown to the paper conveyed through the paper conveyance path, the paper information Even if there is a problem with the control system using the input means, it is possible to improve the separation performance between the upstream plate cylinder and the paper, the paper conveyance performance in the suction conveyance device, and the paper entry performance into the downstream plate cylinder. Thus, it is possible to stably reduce image double printing while shortening the adjustment time.
[0147]
Claim 5 According to the described invention, the air flow rate blown onto the paper on the paper conveyance path is adjusted by changing the flow area of the air flow, so that the separation performance between the upstream plate cylinder and the paper and the suction conveyance device The paper transport performance and the paper entrance performance to the downstream plate cylinder are improved, and image double printing can be further reduced.
[0148]
Claim 6 According to the described invention, since the air volume generated by the air source and the flow area of the air flow or both the generated air volume and the flow area are controlled by the control means, the separation performance between the plate cylinder and the paper on the further upstream side is controlled. In addition, the sheet conveyance performance in the suction conveyance apparatus and the sheet entry performance with respect to the downstream plate cylinder are improved, and image double printing can be more reliably reduced while shortening the adjustment time.
[0149]
Claim 7 According to the described invention, the flow rate of the generated air flow, the flow area of the air flow, or the generated air volume and the flow path area are variably controlled separately from the paper information input means by the air volume setting means. Even if there is a problem with the control system, the separation performance between the upstream plate cylinder and the paper, the paper conveyance performance with the suction conveyance device, and the paper entry performance into the downstream plate cylinder are improved, resulting in a stable image. Double printing can be reduced.
[0150]
Claim 8 According to the described invention, the paper conveyed through the paper conveyance path by controlling the generated air volume of the air source and the area of the flow path, or both the generated air volume and the area of the flow path according to the type and size of the paper. It is possible to adjust the amount of air flow to the air automatically or semi-automatically, and to further increase or decrease the separation performance between the upstream plate cylinder and the paper, the conveyance performance by the suction conveyance device, and the entrance of the paper into the downstream plate cylinder The performance is improved, and image double printing can be more reliably reduced.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of a stencil printing apparatus showing a first embodiment of the present invention.
FIG. 2 is a block diagram showing the configuration of the control means of the first embodiment.
FIG. 3 is a partially broken plan view showing a configuration of an operation panel of the stencil printing apparatus.
FIG. 4 is an enlarged view showing the configuration and operation of the intermediate air blowing means in the first embodiment.
FIG. 5 is an overall configuration diagram of a stencil printing apparatus showing a second embodiment of the present invention.
FIG. 6 is an enlarged view showing the configuration and operation of the intermediate air blowing means in the second embodiment.
FIG. 7 is a block diagram showing a configuration of a control means constituting a main part of a third embodiment of the present invention.
FIG. 8 is an overall configuration diagram of a stencil printing apparatus showing a fourth embodiment of the present invention.
FIG. 9 is an enlarged view showing the configuration and operation of the intermediate blower and variable mechanism in the fourth embodiment.
FIG. 10 is an enlarged view showing the operation of the intermediate blower and the variable mechanism in the fourth embodiment.
FIG. 11 is a side view showing the configuration of the variable mechanism.
FIG. 12 is a block diagram showing a configuration of a control means in the fourth embodiment.
FIG. 13 is a block diagram showing a configuration of a control means constituting a main part of a fifth embodiment of the present invention.
FIG. 14 is a block diagram showing a configuration of a control means constituting a main part of a sixth embodiment of the present invention.
[Explanation of symbols]
1A, 1B plate cylinder
1Aa, 1Ba Outer peripheral surface
7a Separation claw
16b Conveying surface of suction conveying device
17a Suction transfer device
22 paper
33a, 33b Master
43 Paper information input means (paper identification means)
44, 78 Air volume setting means
45,99 Intermediate ventilation means
46 Air source
47 Paper transport path
47a Upstream end of paper transport path
47b Downstream end of paper transport path
48 Air guide member
55, 57, 58, 59 flow path
57a Outlet
65 Line connecting the tip of the separation claw and the rotation center of the plate cylinder
66 Tangent
79 Paper information input means (paper size setting means)
90, 132, 140, 150 Control means
95, 96, 97, 98 Multiple air guide members
100 Variable mechanism
105,111,112,113 flow path
X Transport direction

Claims (8)

A plate cylinder in which a pre-printed master is wound around an outer peripheral surface and rotated and arranged in parallel with a gap in the paper conveyance direction, and a plate cylinder located upstream of the conveyance direction between the two plate cylinders. In the stencil printing apparatus in which the suction conveyance device that sucks and conveys the paper to be printed toward the plate cylinder located on the downstream side in the conveyance direction is arranged,
An air source that generates an air flow above the suction conveyance device, and an air flow from the air source is blown to a paper conveyance path formed between the upstream plate cylinder and the downstream plate cylinder. An intermediate air blowing means having an air guide member that forms a flow path is provided ,
The wind guide member includes at least two parts, an upstream end of the paper conveyance path located in the vicinity of the upstream plate cylinder and a downstream end of the paper conveyance path located in the vicinity of the downstream plate cylinder. A stencil printing apparatus characterized in that a flow path for blowing an air flow from the blowing source is formed . In the stencil printing apparatus according to claim 1,
A separation claw provided on the upstream plate cylinder so as to be close to and away from the plate cylinder is provided between the two plate cylinders. A stencil printing apparatus, wherein an air flow from the air source is provided in a tangential direction at a point where a line connecting the rotation center of the plate cylinder and an outer peripheral surface of the plate cylinder intersect. In the stencil printing apparatus according to claim 1 or 2,
A stencil printing apparatus comprising: paper information input means for inputting information on the paper; and control means for controlling the operation of the air source in accordance with input information from the paper information input means . In the stencil printing apparatus according to claim 3 ,
Air flow setting means connected to the control means, and the control means controls the operation of the air source separately from the input information from the paper information input means in response to a signal from the air flow setting means. A stencil printing apparatus characterized by that. In the stencil printing apparatus according to claim 1 or 2 ,
The air duct member is provided with a plurality of stencil printing machine, characterized in that have a variable mechanism that can move parallel to the plurality of air guide members in a direction orthogonal to the tangential direction. In the stencil printing apparatus according to claim 5 ,
A sheet information input means for inputting information on the sheet; and a control means for controlling the operation of the variable mechanism or the variable mechanism and the air source in accordance with input information from the sheet information input means. Stencil printing device. In the stencil printing apparatus according to claim 6 ,
An air volume setting unit connected to the control unit, and the control unit controls the operation of the air source or the variable mechanism, or the air source and the variable mechanism in accordance with a signal from the air volume setting unit. A stencil printing apparatus that is controlled separately from input information from an input means . The stencil printing apparatus according to claim 3 or 6 ,
The paper information input means includes a paper identification means for outputting a signal corresponding to the type of the paper to the control means, and a paper size setting means for outputting a signal corresponding to the paper size to the control means. stencil printing apparatus characterized in that it is.

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