JPH0764110B2 - Automatic stamping device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an automatic stamping device that automatically stamps paper and other objects, and more particularly to an automatic stamping device for sheet-like objects such as copy paper.

[Conventional technology]

For example, in an automatic stamping device of a copy making machine, a backup roller is opposed to a cylindrical stamp drum to which a printing rubber is attached.

[Problems to be Solved by the Invention]

Characters that do not need to be changed are formed on the printing rubber (print surface), and numbers that need to be changed, such as date, must be stamped by hand with a date stamper. Some of the stamps are removable, but when you change the stamp, your hands get dirty and the parts of the automatic stamper get dirty when you remove the stamp. Therefore, currently, even removable
It is used as a special machine fixed on almost one stamp face.

A first object of the present invention is to provide an automatic stamping device for automatically changing a stamp surface, and a second object thereof is to provide an automatic stamping device having a simple mechanism for automatically changing the stamp surface. A third object of the present invention is to provide an automatic stamping device that can be easily attached and changed without causing ink stains on hands and the like, and an automatic stamping device that automatically sends stamped paper in combination with a paper processing machine such as a copying machine. A fourth object is to provide a device.

[Means for Solving the Problems]

In order to achieve the above object, in the present invention, a stamp mechanism is provided with at least a motor (520); a rotary member (512, 526) that is rotationally driven by the motor (520); Is a printing cylinder (540, 541) that is eccentrically and pivotally attached and has a plurality of printing surfaces; Latch shafts (542, 543) that are connected to the printing cylinder; Latch members that engage with the latch wheel and restrain the latch wheel at a fixed angle rotation. (548,549,
551); stopper (552,553) that engages with the latch wheel; stopper drive means (554,55) that drives the stopper to the engagement position
5); and stopper drive means (55
4,555) to move the stopper (552,553) to a position that obstructs the movement of the latch wheel (542,543), drive the motor (520), and rotate the rotating member (512,526) in the direction opposite to the conveying direction of the stamp object. Control means (10, 50) for moving the printing cylinder (540, 541) to update the printing surface.

[Action]

When the control means (10, 50) urges the stopper drive means (554, 555), the latch wheels (542, 543) move to the stopper (552, 553).
Will be stopped and restrained by. Since the latch wheels (542, 543) are fixed to the printing cylinder (540, 541) and the printing cylinder (540, 541) is pivotally attached to the rotating member (512, 526) which is rotationally driven by the motor (520), the control means (10, 50) ) Is the motor (52
When the print cylinder (540, 541) is stopped, the rotary member (512, 526) is rotated, and when the motor (520) is stopped, the latch member (548, 549, 551) is rotated by the rotary member (512, 526) with respect to the latch wheel (542, 543). ) Is statically restrained at a rotation position of a predetermined angle unit.

As described above, the printing surface occupying the position (printing position) most protruding outward from the rotation center of the rotating member (512, 526) due to the eccentricity of the printing cylinder (540, 541) is changed. In this way, by energizing the stopper driving means (554, 555) and rotationally energizing the motor (520), the printing surface at the printing position is updated. This update is for latch members (548,549,55
Since the presence of 1) causes a step of a predetermined angle unit, by aligning the printing surface with this, each printing surface is in the form of a step rotation and the printing position (the position most protruding outward from the rotation center of the rotating member 526). ) Is accurately positioned.

In a preferred embodiment of the invention, the stamping mechanism comprises at least a pulse motor (520), a first rotating member (512) rotationally driven by the pulse motor, and a second rotating member (526) coupled to the first rotating member. ), A first printing cylinder (540) pivotally attached to the first rotating member so as to be eccentric to the center of rotation of the first rotating member, and a first latch member (6) for statically latching the first printing cylinder every rotation of a predetermined angle. 548), a first latch wheel (542) coupled to the first printing cylinder, a first stopper (552) that engages with the first latch wheel when the first latch wheel is in a predetermined position,
A second printing cylinder (541) pivotally attached to a first stopper driving means (554) for driving the first stopper to an engagement position and a second rotating member (526) eccentrically with respect to a rotation center of the second rotating member. , A second latch member (549, 551) that latches the second printing cylinder stationary at every rotation of a predetermined angle, a second latch wheel (543) connected to the second printing cylinder, and a second latch wheel when in a predetermined position. A second stopper (552) that engages with the second latch wheel, and a second stopper drive means (55) that drives the second stopper to the engagement position.
4) and a date stamper (556) disposed between the first printing cylinder and the second printing cylinder and connected to at least one of the first rotating member and the second rotating member, and the control means (10). ,Five
In 0), the first and second stoppers are urged to the engagement position to rotate the pulse motor to rotate the first and second printing cylinders to update the printing surface.

According to this, the first printing cylinder (540) and the second printing cylinder (541)
A plurality of stamp surfaces can be arranged on each of the stamps and the stamp surfaces can be automatically selected and set, and the date is stamped at the same time as these stamp surfaces.

Other objects and features of the present invention will become apparent from the following description of preferred embodiments with reference to the drawings.

〔Example〕

FIG. 1 shows a state in which a front cover that can be freely opened and closed is removed from a sheet processing machine 900 equipped with a stamp device according to an embodiment of the present invention. Note that this sheet processing machine 900 has the appearance shown in FIG. 2 when the front cover is closed, and in the most preferable embodiment, as shown in FIG. 2, it is inserted between the copying machine 800 and the sorter 1000. The control signal line of the sheet processing machine 900 is connected to the copying machine 800. The control signal line of the sorter 1000 is also connected to the copying machine 800.

If the copier 800 is designed to be the most suitable for this combination mode, the copy size (recording paper size), the number of sheets,
Copy supply attitude (vertical, horizontal), stamp data (stamp necessity, stamp position, publisher, drawing type), punch data (punch necessity), paper discharge data (paper discharge to tray ET or sorter 1000) Paper discharge), start signal, end signal, etc. are given to the sheet processing machine 900.

The sheet processing machine 900 is equipped with an operation board 11,
With this operation board, input size, input attitude (vertical, horizontal),
Set stamp data (stamp necessity, stamp position, issuer, drawing type), punch data (punch necessity), paper ejection data (paper ejection to tray ET or paper ejection to sorter 1000), start signal, etc. It can be input and can operate independently of the copying machine 800 even in response to the setting of the operation board 11 and the operation of the board 11.
When receiving a certain signal from the copying machine 800, the sheet processing machine 900 takes up the data and signals received from the copying machine 800 prior to the setting and operation of the operation board 11. When the copying machine 800 does not provide the required data, the sheet processing machine 900 operates according to the setting and / or operation of the operation board 11.

Referring back to FIG. Copy paper from copier 800 is arrow 8
It is given to the sheet processing machine 900 from the 01 direction. When the copying machine 800 is not connected, the paper is fed to the sheet processing machine 900 from the direction of the arrow 801 by an auto feeder or by hand.

The paper that has entered the sheet processing machine 900 is the vertical folding mechanism unit 100-
90 ° Turn Mechanism Unit 200-Blade Folding Mechanism Unit 300-
The punch mechanism unit 400, the stamp mechanism unit 500, the vertical transport mechanism unit 600, the sheet discharge mechanism unit 700 are transported in this order, and are discharged from the sheet discharge mechanism unit 700 in the direction 701 toward the tray ET or the direction 703 toward the sorter 1000. To be done.

The vertical folding mechanism unit 100, the 90 ° turn mechanism unit 200, the blade folding mechanism unit 300, the punch mechanism unit 400, the stamp mechanism unit 500, and the vertical transport mechanism unit 600 are housed in a drawer type case, and a paper discharge mechanism unit. The 700 is mounted on the main body of the sheet processing machine 900, and is protected by a unit cover that can be freely opened and closed.

A drawer handshake is fixed to the case wall on the front side of the drawer type case that houses each unit, and a grip for manually feeding jam paper 180, 215, 38 is attached to the outside of the case wall.
6,472 and 634 are exposed. Each of these grips is connected to the paper feed roller of the mechanical unit.
237, 390 and 476 are switches for instructing the cutting of jammed paper.

Engagements that are spring-engaged with the latch members of the main body of the sheet processing machine 900 are fixed to the case wall on the back side of the drawer type case that houses each unit. When it is pushed in with a relatively strong force, it engages with the latch member.

In the engaged state, the engagement element cannot be disengaged from the latch member even if a weak force is applied in the case withdrawing direction. When the case is pulled out with a strong force, the engaging element is disengaged from the latch member, and the pull-out type case is pulled out from the main body of the sheet processing machine 900 to the front side.

Also, a power line male connector and a signal line male connector that are coupled to the power line female connector and the signal line female connector of the sheet processing machine 900 are fixed to the case wall on the back side of the drawer type case that houses each unit. These male connectors engage the female connectors when the aforementioned engagers engage the latch members.

Generally speaking, the gear for obtaining the main power of the mechanism unit is exposed on the inner side of the case wall on the inner side of the drawer type case accommodating each unit, and the aforementioned engaging element engages with the latch member. At this time, this gear engages with the gear of the power transmission system of the main body of the sheet processing machine 900 driven by the main motor.
The gear for obtaining the main power of the mechanism unit is pivotally attached to the drawer type case, and its gear shaft is provided with another gear through
Further, a power transmission means such as a chain or a belt and, if necessary, a clutch are connected to a paper transport roller of a mechanical unit. Depending on the mechanism unit, a roller driving motor is independently provided. In this embodiment, in the mechanism unit whose paper feed control is simple, the main power system of the sheet processing machine 900 main body is connected to the roller of the mechanism unit via a gear. However, in a mechanical unit whose paper feed control is rather complicated, a drawer type case is provided with an independent motor, and the paper feed rollers in the mechanism are independently driven by the motor.

The vertical folding mechanism unit 100, 90 ° turn mechanism unit 200, blade folding mechanism unit 300, punch mechanism unit 400, stamp mechanism unit 500, and vertical transport mechanism unit 600 are drawer-type unit units. In mechanism inspection, repair, etc., each unit can be simply removed from the processor 900 and placed on a workbench. It is also easy to reattach.

When the jammed paper straddles the vertical folding mechanism unit 100 and the 90 ° turn mechanism unit 200, the switch 237 is pressed, and then the vertical folding mechanism unit 100 and the 90 ° turn mechanism unit 200 are pulled out in order to remove the jammed paper. When the switch 237 is pressed, a cutter (223: FIG. 4) provided in the unit 200, which will be described later, automatically cuts the paper between the units 100 and 200 between them.

Similarly, when the jammed paper straddles the 90 ° turn mechanism unit 200 and the blade folding mechanism unit 300, the switch 390 is pressed, and then the 90 ° turn mechanism unit 200 and the blade folding mechanism unit 300 are pulled out in order to remove the jammed paper. To do. When the switch 390 is pressed, the cutter (376: Fig. 4) provided in the unit 300, which will be described later, will automatically
-Cut between 300 sheets of paper between them.

Similarly, when the jammed paper straddles the blade folding mechanism unit 300 and the punching mechanism unit 400, the switch 476 is pressed, and then the blade folding mechanism unit 300 and the punching mechanism unit 400 are pulled out in order to remove the jammed paper. When the switch 476 is pressed, the cutter (452: Fig. 4) provided in the unit 400, which will be described later, automatically becomes the unit 300-400.
Cut the paper in between between them.

An outline of the paper processing operation of the sheet processing machine 900 of this embodiment is shown in FIGS. 3a and 3b.

The sheet processing machine 900 sets the maximum size of the processable paper to A2 (indicates the size; hereinafter, the size and the plate are omitted and only the size symbol is shown).
Only the vertical orientation shown in the figure can be processed. The relationship between paper size and possible processing of sheet processor 900 is summarized below.

As shown in the left column of FIGS. 3a and 3b, the copying machine 800 makes copies of various sizes, magnifications and postures from originals of various sizes and postures, and gives them to the sheet processing machine 900.

FIG. 4 shows a schematic configuration of each mechanical unit of the sheet processing machine 900. This FIG. 4 shows the sheet processing machine 90 shown in FIG.
This corresponds to an enlarged view of the drawer type case of 0 with the front side wall surface removed. The outline of the paper processing of each mechanism unit corresponding to the paper size and the posture with reference to FIG. 4 is as follows.

Longitudinal folding mechanism unit 100 (1) A2, vertical, plain-through ... The paper that has arrived with the gate claw 112 as the solid line position in the figure is sent to the unit 200.

(2) A2 / vertical / four-folding ... With the gate claw 112 at the position of the two-dot chain line, the incoming paper is guided between the vertical folding rollers 116-120,
It is folded in half by the vertical folding roller and sent to the unit 200 through the paper feed port directly below the vertical folding roller.

(3) A2 / JIS fold ... The incoming paper is guided between the vertical folding rollers 116-120 with the gate claw 112 at the position indicated by the chain double-dashed line, and the vertical folding roller descends vertically by two at the length of the A4 long side. As a result, the sheet is sent to the unit 200 through the paper feed port directly below the vertical folding rollers 116, 118, 120.

(4) B3 is processed in the same manner as (1) to (3) above. However, A2 in (1) to (3) is read as B3.

(5) For paper of sizes other than A2 and B3, the incoming paper is guided (passed) to the unit 200 with the gate claw 112 as the solid line position in the drawing.

90 ° turn unit 200 (1) A2 sends one side of the paper to the unit 300 as it is along the register.

(2) A3, sideways, plain ..... 1 side of the paper is sent to the unit 300 as it is along the register.

(3) A3, sideways, JIS fold or double fold ... Turn the paper 90 degrees, put one side of the paper along the register and send it to the unit 300.

(4) A3 lengthwise ... One side of the paper is placed along the register and sent to the unit 300 as it is.

(5) A4 / Horizontal ... Send one side of the paper as it is to the unit 300 along the register.

(6) A4 length: Turn the paper 90 °, put one side of the paper along the register, and send it to the unit 300.

(7) For the processing of the B plate paper, the processing of the A plate paper (1) to
It is similar to (6). However, A2 is B3, A3 is B4,
Read A4 as B5.

Blade folding mechanism unit 300 (1) A2, vertical, four-fold ...... Paper (vertically folded in two)
Is sent to the register 342, and is horizontally folded in two by the horizontal folding rollers 320 and 322 and sent to the unit 400.

(2) A2, portrait, JIS fold ... Paper (folded in two portraits)
To the register 340 and folded in half horizontally with the horizontal folding rollers 320 and 322, and further sent to the register 362 and the horizontal folding rollers 322 and 132.
Send it to the unit 400 by folding it horizontally in three.

(3) A3 / horizontal / JIS fold ... Paper is sent to the register 336 and folded horizontally by the horizontal folding rollers 320 and 322, and further sent to the register 358 and folded horizontally by the horizontal folding rollers 322 and 1324 to make a unit.
Send to 400.

(4) A3 / horizontal / double-folding ... The paper is sent to the register 342 and horizontally-folded by the horizontal folding rollers 320 and 322 and sent to the unit 400.

(5) For other A-size paper, use the unit 40 as it is.
Send to 0.

(6) The processing of B-size paper is also the same as in (1) to (5) above. However, A2 should be read as B3, A3 as B4, and A4 as B5.

However, in the register layout of this example, B3 JIS fold (file fold)
Only possible, then use 338 and 360 registers.
The register arrangement is such that the B-row cannot be folded in two.

Punch mechanism unit 400 (1) If punch is not specified, the unit will be used as it is.
Pass through the 500.

(2) If punching is specified on the A plate, punch on the left long side with the center of the long side of A4 as the symmetry point.

(3) If punching is specified on the B plate, punching is performed on the left long side with the center of the long side of B5 as the symmetry point.

Stamping mechanism unit 500 (1) If the stamping is not designated, the stamping unit is directly passed through the unit 600.

(2) If the stamp is designated, the mechanical unit 500
The stamp is performed at the position in the paper longitudinal direction (direction orthogonal to the paper feeding direction) set manually in (1) and the position in the paper short side direction (paper feeding direction) specified by the data.

Vertical transport mechanism unit 600 Sends all paper that is fed to unit 700.

Paper ejection mechanism unit 700 (1) When the paper ejection to the tray ET is instructed, the paper ejection gate claw 712 is set to the solid line position in the drawing to deliver the incoming paper to the tray ET.

(2) When it is instructed to discharge the paper to the sorter 1000,
The incoming paper is sent to the sorter 1000 with the discharge gate claw 712 at the position indicated by the chain double-dashed line.

Next, the structure of the stamp mechanism unit will be described with reference to FIGS. 5a to 5c.

The paper sent from the punch mechanism unit 400 passes below the sensor 598, between the stamp roller 572 and the free rotating wheels 532 and 514, and between the rollers 580 and 582 for feeding, and is sent to the vertical feed mechanism unit 600. To be

A pulse motor 520 is fixed to the base frame 502. A belt pulley 518 having two grooves is fixed to the output shaft of the pulse motor 520, and a belt stretched in one groove is attached to a manual rotating wheel.
522 pulley groove is connected. The manual rotating wheel 522 is for the purpose of manually driving the output shaft (and a mechanism connected thereto) of the pulse motor 520 with the unit 500 pulled out from the main body of the sheet processing machine 900. Belt pulley
A belt stretched in another groove of 518 is connected to a pulley 516 fixed to a rotary shaft 510. The rotating shaft 510 is pivotally attached to the base frame 502 by a bearing 508. The rotating shaft 510 is
The free rotation wheel 514 penetrates the center hole, and the printing tool first support plate 512, which is a rotating member, is fixed to the tip of the hole.
When the pulse motor 520 is rotated by electric bias or the rotary wheel 522 is rotated, the rotary shaft 510 rotates and the printing tool first support plate 512 rotates. However, since the free rotation wheel 514 is not fixed to the rotation shaft 510, it does not rotate particularly.

A second printing tool support plate 526 (shown by a chain double-dashed line), which is a rotary member, is fixed to the first printing tool support plate 512 by rods 524 (four pieces). Therefore, the printing tool first support plate 512 and the printing tool second support plate 526 are integrated, and the printing tool first support plate 512 is integrated.
When the printer rotates, the second printing tool support plate also rotates in the same direction.

One pin 538 is rotatably supported on the printing tool first support plate 512, a latch ring 542 is fixed in the middle of this pin 538, and a first printing cylinder 540 is fixed to the tip of the pin 38. ing. In other words, the printing cylinder 540 is pivotally attached to the printing tool first support plate 512, which is a rotating member, via the pin 538 so as to be eccentric from the rotation center thereof. Further, another pin is erected on the printing tool first support plate 512, and one end of the latch arm 548 is pivotally attached to the tip of this pin. Latch arm 548
A latch pin that engages with the base of the claw of the first latch ring 542 is fixed to the other end of the. One end of a tension spring (corresponding to 551: not shown) is engaged with the latch arm 548, and the other end of the tension spring is the first support plate for the printing tool.
It is engaged with another pin that is set up on 512.

One pin 539 is rotatably supported on the printing tool second support plate 526, a latch ring 543 is fixed in the middle of this pin 539, and a second printing cylinder 541 is fixed to the tip of the pin 539. ing. That is, the printing cylinder 541 is pivotally attached to the printing tool second support plate 526, which is a rotating member, via the pin 539, while being eccentric to the rotation center thereof. Further, another pin is erected on the printing tool second support plate 526, and one end of the latch arm 549 is pivotally attached to the tip of this pin. Latch arm 549
A latch pin that engages with the base of the claw of the second latch ring 543 is fixed to the other end of the. One end of a tension spring 551 is engaged with the latch arm 549, and the other end of the tension spring 551 is engaged with another pin that is erected on the second printing tool support plate 526.

Light-reflecting plates 544 and 545 are fixed to the latch wheels 542 and 543, respectively, and photosensors 546 and 547 fixed to supporting means (not shown) (fixed to side plates 504 and 506 of the base frame 502). , The light reflectors 544 and 545 are detected when the latch wheels 542 and 543 are in the home position, respectively.

The latch claw at the tip of the first stopper arm 552 is located above the latch wheel 542, and the latch claw at the tip of the second stopper arm 553 is located above the latch wheel 543. The other end of the first stopper arm 552 penetrates the back side plate 504 of the base frame 502 and is connected to the plunger of the first solenoid 554 via a spring. The other end of the second stopper arm 553 penetrates the front side plate 506 of the base frame 502 and is connected to the plunger of the second solenoid 555 via a spring.

Latch wheel 543, latch arm 549 and tension spring 551
The combination allows the counterclockwise rotation of the latch wheel 543, but blocks the clockwise rotation. Another set of latch wheel 542, latch arm 548 and tension spring (equivalent to 551: not shown)
The latch wheel 542 is allowed to rotate counterclockwise but is prevented from rotating clockwise. In this example,
Latch arm 548,549, spring 551, latch wheel 542,5
It is a latch member that holds 43 stationary. During the stamping operation, the printing tool first support plate 512 and the printing tool second support plate 526 rotate counterclockwise, and the first printing cylinder 540 and the second printing cylinder 541.
To the first printing cylinder 540 and the second printing cylinder 5 by pressing them against the paper.
41 does not rotate with respect to the first support plate 512 and the second support plate 526.

When the printing tool first support plate 512 (and hence the printing tool second support plate 526) is in the home position (the state in which the sensor 536 is shielded from light by the shutter 534), the first solenoid
When the 554 (555) is energized, the first stopper arm 552 (5
53) rotates clockwise, and the tip of the arm 552 (553) enters between the claws of the latch wheel 542 (543). In this state, when the printing tool first and second support plates 512 and 526 rotate in the clockwise direction (the rotation direction opposite to the rotation direction during the stamp operation), the first stopper arm 552 (553) latches the latch wheel 542 (543). Since the movement of the claw is hindered, a counterclockwise rotational force acts on the printing cylinder 540 (541) and the printing cylinder 540 (541) rotates together with the pin 538 (539). In this embodiment, the stopper arms 552 and 553 are stoppers that engage with the latch wheel. Also, the solenoid 55
4,555 is a stopper drive means for driving the stopper to the engagement position. Since the printing cylinder 540 (541) is a pentagon in this embodiment, when the printing cylinder 540 (541) rotates 360 ° / 5 = 72 °, the printing tool first and second support plates 512 and 526 rotate clockwise. Stop, or when the solenoid 554 (555) is turned off and the stopper arm 552 (553) is returned to the illustrated state,
The printing cylinder 540 (541) has the same posture as the illustrated state. However,
This means that the print surface of the print cylinder 540 (541) facing the ink roller 560 has been updated to the next print surface by rotating 72 ° from the previous state. In the description of the printing surface updating operation, the symbols in parentheses indicate the elements of the second printing cylinder 541 during the printing surface updating operation.

The tip of the second rotating shaft 528 is fixed to the second printing tool support plate 526. The second rotating shaft 528 is pivotally attached to the base frame 502 via a bearing 530. A shutter 534 is fixed to the rear end of the rotary shaft 528. The shutter 534 shields the sensor 636 from light when the printing tool first and second support plates 512 and 526 are in the home position (as shown). When in the home position, the print cylinders 540, 541 are above the ink rollers 560, and the latch wheels 542 and 543 are directly below the latch pawls at the tips of the stopper arms 552 and 553, respectively.

On each of the five sides of the pentagonal first printing cylinder 540, a rubber plate formed with stamp characters (inside-out characters) indicating the drawing type such as official drawing, provisional drawing, approval drawing, etc. is attached. Stamp letters (inside-out letters) indicating the origin of the drawing such as the first design, the second design, the equipment, etc. are formed on each of the five sides of the pentagonal second printing cylinder 541. A rubber plate is attached.

A date stamper 556 having a structure similar to that of a commercially available date stamper is arranged between the first printing cylinder 540 and the second printing cylinder 541, and this has four rods 558 and a printing tool second support plate 526. Is stuck to. The date stamper 556 has an inside-out number for the stamp on the print side (on the side facing the ink roller 560), but on the rotating wheel for changing the date, the number shown on the print side. The same numbers as those that appear upright (usually visible). The base frame 502 is supported by guide bars 562 and 564 fixed to a case frame (not shown) of the stamp mechanism unit 500 so as to be movable in a direction orthogonal to the paper feeding directions 403 and 501. In the case frame,
A stamp roller 572 is mounted so as to be located immediately below the free rotating wheels 514 and 532. The bearing (not shown) at the rear end of the roller 572 is tiltably engaged with the case frame of the unit 500, and the bearing 574 at the front end of the roller 572 is a vertical slit (not shown) in the case frame. Through
It is supported on the lower side by an arm 576. The arm 576 is pivotally attached to the case frame. A solenoid 578 has a plunger connected to the arm 576 via a spring. When the solenoid 578 is energized, the arm 576 rotates clockwise and its left end moves up to lift the bearing 574,
As a result, the front end of the roller 572 is lifted, and the roller 572 is pressed against the free rotating wheels 514 and 532. When the solenoid 578 is de-energized, the arm 576 rotates counterclockwise, its left end moves downward, and the roller 572 moves downward. In this embodiment, the arm 576 is a vertical drive arm that supports the roller 572, and the solenoid 578 is an arm drive means. When the printing surfaces of the printing cylinders 540 and 541 and the printing surface of the date stamper 556 face the roller 572, these printing surfaces slightly project from the free rotating wheels 514 and 532 to the roller 572 side. A stopper 566 is attached to the base frame 502. This stopper 566 can move up and down, and the tension spring 568
Is being urged downwards. A positioning arm 570 fixed to a case frame (not shown) is located immediately below the stopper 566. The arm 570 has a large number of rectangular cutouts for receiving the lower end of the stopper 566. Stopper 56
By pushing 6 upward and pushing the base frame to the back side, the stamp position on the paper moves to the back side in the direction orthogonal to the paper feeding direction. The stamp position moves to the front by pulling it toward you. As described above, the stamp position in the direction orthogonal to the paper feeding direction can be manually adjusted. The adjustment of the stamp position in the paper feed direction is performed by the pulse motor 520 with the arrival of the leading edge of the paper as the base point.
The adjustment is performed by adjusting the drive start timing of the (support plates 512, 526). As will be described later, this timing is set by an electric signal and is automatically performed.

The ink roller 560 is pivotally attached to the support frame 584, as shown in FIG. 5b. Sliders 586 (two) are mounted on the support frame 584 so as to be movable in the direction of arrow 593 and in the opposite direction. A compression coil spring 589 is interposed between the two sliders 586, and gives a force to pull them apart. A notch 590 for pin engagement is formed in the support frame 560, and a pin guide hole 587 and a pin guide groove 588 continuous with the pin guide hole 587 are formed in the slider 586. The ink roller unit shown in FIG.
Pins fixed to support arms (not shown) fixed to the side plates 504 and 506 of the base frame 502 in a state where they are brought close to each other.
Align 592 and 591 with notch 590 and pin guide hole 587.
In FIG. 5b, the support frame 584 is pushed to the right, then the hands are released from the sliders 586, and the sliders 586 are spread by the force of the spring 589, so that the sliders 586 are mounted on the base frame 502. The mounted position is shown in Figure 5a. Ink roller 560 like this
Is supported by a support frame 584, and the support frame 584 is detachable from the base frame 502. In this embodiment, the support frame 584 is a removable frame body.

After the paper is detected by the sensor 598, the pulse motor 520 is biased in the forward direction at a speed synchronized with the moving speed of the paper to rotate the printing tool first and second support plates 512 and 526 counterclockwise so that the printing surface is Immediately before facing the roller 572, the solenoid 578 is energized to pull up the roller 572, and when one side of the printing surface passes the roller 572, the solenoid 578 is de-energized and the roller 572 is lowered to perform one printing. Be done. Note that the printing surface is rolled from the standby position (home position) shown in Fig. 5a.
While moving over 572, the print surface contacts the surface of ink roller 560, compressing the surface of roller 560 slightly. As a result, the ink of the roller 560 is transferred to the print surface. An example of the stamp image is shown in FIG. 8c.

An upper cover 594 is attached to the base frame 502. Top cover 59
Fig. 5c shows the state where 4 is attached. Note that FIG. 5c shows a state in which the date changing wheel portion of the date stamper 556 is moved right below the opening 594 of the cover 594 by rotating the manual rotating wheel 522. The date can be changed in this state. In addition,
Although the date is adjusted manually like this,
A roller for changing the date is provided at a position on the base frame 502 that can face the date changing wheel of the date stamper 556 so that the roller can be moved forward and backward by a solenoid or the like, and the motor 520 is used when changing the date. Alternatively, the date stamper may be driven to set at a position facing the changing roller, and the roller may be pushed out and pressed against the date changing wheel to rotate the roller. In this way, the date can be changed automatically. Further, a drive mechanism may be coupled to the base frame 502 to automatically drive the base frame 502 in a direction orthogonal to the paper feeding direction.

The structure of the stamp mechanism unit has been described above.
Next, an electric control system for controlling the operation of the mechanical unit will be described.

Figure 6a shows an outline of the configuration of the electric control system. The electrical control system is
Operation board control unit 10 which is the main control means, vertical folding & 90
A turn control unit 20, a blade folding control unit 30, a punch control unit 40, a stamper control unit 50 as a subordinate control means, a vertical conveyance & discharge control unit 60, and a sheet processing machine main power source energizing circuit 80. ing.

As shown in FIG. 2, the operation board 11 is a sheet processing machine 900.
It is mounted on the top surface of the key board of this operation board 12a (for paper size indication), 12b (for paper posture indication), 12c
(For specifying folding type), 12d (for specifying whether punching is required), 12e (for specifying stamp type of drawing), 12f (for specifying stamp issuer stamp), 12g (position for stamping stamp: paper feed direction) position:
Key interface 15a of control unit 10 for 12h (for specifying the paper ejection direction) and 12i (for specifying the start direction)
Is connected, and the indicator light on the operation board 12 (light emitting diode: 2
The display interface of the control unit 10 is connected to (shown by a double circle). There are a total of 38 indicator lights, which are assigned as follows.

For paper size indication: 1 for each of A2, A3, A4, B3, B4, B5, all 6 pieces For processing operation availability display: 1 each for ready (ready) display and standby (not available) display
1 piece, 2 pieces in total For indication of type: 1 for each of JIS fold, 4 fold, 2 fold, and no fold
Number of pieces, all 4 pieces For paper orientation display: 1 piece each for vertical orientation display and horizontal orientation display, 2 pieces each For stamp indication presence / absence: 1 piece each for indication with and without stamp indication, 2 pieces stamp position display For: For displaying the position where the right edge of the stamp is 0mm from the right edge of the paper, 20m
m Inside position display, 35 mm inside position display, 50 mm inside position display, 65 mm inside position display, 80 mm inside position display, 95 mm inside position display, 110 mm inside position display 1 stamp, all 8 stamps For displaying the drawing issuer: 1 stamp for each of 5 printing surfaces, 5 stamps for displaying stamp type: 1 stamp for each of 5 printing surfaces, 5 punches For display: 1 for display with punch designation, 1 for display without punch designation, 2 in total Discharging direction display: 1 for discharging display to sorter, 1 for discharging display to tray A sheet transfer path in the sheet processing machine 900 is drawn on the display panel 13 of the operation board 11, and an indicator lamp (issued diode: 2 in FIG. 6a is shown at the position of paper jam detection on the sheet transfer path. Shigemaru) is arranged. These indicator lights are connected to the display interface 15c. The signal line of the copying machine 800 is connected to the host interface 15e of the control unit 10 via a connector (not shown). The sheet processing machine main power source energizing circuit 80 is connected to the interface 16e of the control unit 10.

As shown in FIG. 6a, the operation board control unit 10 is composed of various interfaces, an input / output port (I / O), a common bus line 17, a microprocessor 14, a ROM 19 and a RAM 18, and is a copy machine 800. To exchange signals with the control unit 20, 30, 40, 50 and 60, and to set ON / OFF signals to the main power system energizing circuit 80. Further, it reads the state of the key switch of the operation board 11 and controls the on / off of the indicator lamp.

The other control units 20, 30, 40, 50 and 60 have the same configuration as that of the operation board control unit 10, and include an interface, I / O, a microprocessor and, if necessary, ROM, RAM.
And so on.

The control units 10, 20, 30, 40, 50 and 60 are sheet processing machines 90
It is stored at the bottom of the 0 output tray ET.

The interfaces of the vertical folding & 90 ° turn control unit 20 include electric elements such as sensors, solenoids, clutches, motors and encoders of the vertical folding mechanism unit 100 shown in FIG. 4 and the 90 ° turn mechanism unit 200 shown in FIG. Are connected via a female connector on the back side of the processor 900 main body and a male connector on the mechanism unit side.

The interface of the blade folding control unit 30 has a fourth
Electrical elements such as sensors, solenoids, and motors of the blade folding mechanism unit 300 shown in the figure are connected via a female connector on the back side of the processor 900 main body and a male connector on the mechanism unit side.

Electrical elements such as sensors, solenoids, and motors of the punch mechanism unit shown in FIG. 4 are connected to the interface of the punch control unit 40 via a female connector on the back side of the processor 900 main body and a male connector on the mechanism unit side. Has been done.

Electrical elements such as sensors, solenoids, and motors of the stamp mechanism unit 500 are connected to the interface of the stamper control unit 50 via a female connector on the back side of the processor 900 main body and a male connector on the mechanism unit side.

For the interface of the vertical conveyance & discharge control unit 60,
Electrical elements such as sensors, solenoids, and encoders of the vertical transport mechanism unit 600 and the paper discharge mechanism unit 700 are used as the processor.
900 Connected via the female connector on the back side of the main body and the male connector on the mechanism unit side.

7a to 7d show the control operation of the microprocessor 14 of the operation board control unit 10. The control operation of the operation board control unit 10, that is, the control operation of the microprocessor 14 will be described with reference to these drawings.

First, refer to FIG. 7a. When the power is turned on, the microprocessor (hereinafter simply referred to as CPU) 14 initializes the input / output port, registers for temporary data storage, status register (flag), counter (program counter), timer (program timer), etc. Is cleared (step 1). In the following, in parentheses, the word "step" is omitted and only the step mechanism is displayed.

When the initialization is completed, the CPU 14 reads the status. In this, first, it is referred to whether or not there is a reading flag (2).
At this point, since the initialization has just finished, there is no read flag, so the routine proceeds to step 3, where the standard data is set in the operation board register. Standard data: Paper size: A4 Fold selection: No fold Vertical / horizontal posture: Horizontal Stamp position: 0mm Publisher: 1st design (1st publisher stamp) Drawing type: Provisional drawing (1st drawing type) Punch selection: No punch Paper output selection: Tray. When this data set is completed, the data-corresponding indicator lamp is turned on correspondingly. In this state, on the operation board 12, stand by (this is set by initialization), A
4, Indicator lights showing No Folding, Horizontal, 0mm, No Punch, 1st Design, Tray, Preliminary Drawing.

FIG. 7b shows the write position of the data to be temporarily written in the 3-byte memory area (one area of the internal RAM of the CPU 14) allocated to the operation board register OBR.

When the standard data is written in the operation board register OBR, the read flag is set (4). Next, it is determined whether or not a signal is transmitted from the copying machine 800 by referring to the state of the port that receives the input signal from the copying machine 800 (5). When the signal is transmitted, the signal and data are read in and it is determined whether the signal is a start signal (6). If it is not a start signal, it is judged whether it is an end signal (7). If it is not an end signal, it is data. Therefore, of the input data, the data whose memory bit is allocated to the operation board register OBR is stored in the operation board register. Write OBR update. When such update writing is performed, 1 is written in the bit indicated as the copier input bit of the operation board register OBR. This one
Indicates that the copying machine 800 has instructed the sheet processing machine 900 about a sheet processing method regarding sheet processing. Although not shown, the CPU 14 retains in memory the data received from the copying machine and indicating the data written in the operation board register OBR (indicating what the write data is). When data is received from the copying machine 800 and writing to the operation board register OBR is completed and the process proceeds to step 9, or there is no input from the copying machine 800, step 5
From step 9 to step 9, in this step the operation board 12
Read the key in. If the key-in is due to the key switches 12a-12e (10), refer to the copier input bit,
If it is not 1 (data has not yet been received from the copying machine) (11), the contents of the operation register are updated according to the key-in, and the on / off of the indicator light on the operation board is updated according to this update. For example, when the switch 12a is closed, the size specification bit of the operation board register OBR is updated to the data indicating B3 next to A4 at the moment when the switch 12a is closed, and the indicator light of A4 is turned off and the indicator light of B3 is turned on. To do. When the key switch 12a is closed once when the size designation bit of the operation board register OBR is B5, the data indicating the size designation bit A2 is updated, and the indicator light of B5 is turned off and the indicator light of A2 is turned on. . In this way, the size instruction key switch 12a
Each time it is closed, the indicator light turns on from the upper side to the lower side in Fig. 6a, and at the same time, the data of the size designation bit of the operation board register OBR is updated to the data showing the size indicated by the indicator light. To be done. However, this operation is
This is performed only when size data has not been received from 800, and if size data has already been received, step 11
Proceed to -12- and do not update the data or display according to the key-in. The CPU 14 also operates in the same manner for key-in by the key switches 12c to 12h.

The reason why the input data from the copying machine 800 is prioritized in this way is that the data from the copying machine 800 is more reliable than the setting by the operation board 12. When no data comes from the copying machine (for example, when the copying machine is not connected) or when only a part of the required data comes, the insufficient data is updated and set according to the key-in from the operation board 12. When no data is given from the copying machine and there is no key-in on the operation board 12, the setting data becomes the above-mentioned standard data. The start signal for starting the operation of the mechanism of the sheet processing machine is also changed by the copying machine 80, although it goes back and forth from the step development of the illustrated flow chart.
It is designed to be received from 0 and to be keyed in with the start key switch 12i of the operation board 12, but when data is partially received from the copying machine 800 (OBR copying machine input bit = 1), The key-in of the start signal due to the closing of the switch 12i is not accepted in step 38. In this way, the start signal from the copying machine is prioritized even when the processing mechanism starts. As described above, in this embodiment, the copying machine 800 is the host of the sheet processing machine, and supplies data to the stamp control unit 50 of the stamp mechanism unit 500, with respect to the operation board control unit 10 which is the main control means, The copier 800 is the host.

The operation board 12 and its key-in reading / data set have meaning when the copier is not connected and when it is connected to the copier that does not transmit all required data. ) Is not connected, or if the host function is not sufficient, it is supplemented with key-in.

By setting the data in step 8 (setting the data received from the copying machine) or setting the data in step 13 (setting the key-in data), or no data is sent from the copying machine (5). If there is no key-in (9), proceed to step 14 in FIG. 7b, refer to the signal level of the signal receiving port from the unit 20,
Refer to whether it is ready (paper acceptance is possible) or not (standby: paper acceptance is not possible).

Vertical folding & 90 ° turn control unit 20 in step 14 of Fig. 7b
Is Lady, then in step 16 it is checked whether the unit 30 is Lady. When the blade folding control unit 30 is ready,
In step 18, see if unit 40 is ready.
If the punch control unit 40 is ready, then in step 20 it is determined whether the unit 50 is ready. If the stamper control unit 50 is ready, it is checked in step 22 whether the unit 60 is ready. Vertical transport & discharge control unit
If 60 is ready, all units are ready and sheet processing can be executed, so 1 is set in the ready standby bit of the operation board register OBR to indicate that processing is possible (24) and the data of the operation board register OBR is set. Pre-operation board register P
Compare with OBR data (25). Since the previous operation board register OBR has been cleared by the initialization of step 1, the contents of both do not match when the process proceeds to step 25 for the first time. This means that the processing mode data transfer to each of the units 20 to 60, which will be described later, is not executed. Therefore, first, in step 26, the data of the operation board register OBR is updated and stored in the previous operation board register POBR, and the unit 20 in the A version processing mode of FIG.
Proceed to setting (27).

Setting of unit A in processing mode A in Fig. 7c (27)
Then, first, the size is judged from the data of the size designation bit of the operation board register OBR (271).

If the size is A2, then the folding selection bits of the OBR are referenced (272 to 276). If there is no fold, the unit 20 will be A2
Data indicating the transit mode is transmitted (273). When the sheet is folded in four, the data indicating the A2 / vertical folding mode is transmitted to the unit 20 (275). When folded in two, put it in unit 20, A
2. Send data indicating vertical / passing mode (277). If it is JIS folding, data indicating A2, end face folding, JIS vertical folding mode is transmitted to the unit 20 (278).

If the size is not A2, proceed to step 279 to see if it is A3.

If the size is A3, the vertical / horizontal designation bit of the OBR is referred to, which indicates the vertical (280) and the unit 20.
Send A3, portrait, pass mode to (281). When it indicates the side, refer to the OBR fold selection bit (28
2) If it is unbroken, it sends A20, A3, Transverse mode to unit 20 (283). If something is wrong, the unit 20 is sent an A3 90 ° turn mode.

When the size is A4 (285), the vertical / horizontal designation bit is referred to (286), and if it indicates the horizontal direction (286), A4 / horizontal / pass mode is transmitted to the unit 20 (287). .
If it does not indicate the side, the A4 / 90 ° turn mode is transmitted to the unit 288 (288).

If the size is B, step 28, and step 27 above.
Similarly, the mode is transmitted to the unit 20 according to the size and the like. Step 27: A2 to B3, A3 to B4, A4 to B5
The contents of step 28 can be read as

As described above, when the unit 20 is ready, the unit 10 gives the control operation mode instruction to the unit 20,
It will be set in 20 microprocessors.

The CPU 14 of the unit 10 then proceeds to the blade folding mode setting (29) in FIG. 7d. In this step 29, first, the folding selection bit of the operation board register OBR is referred to (291,292,29).
Four). Then, when there is no folding, size data is attached and the passage is transmitted to the unit 30 (295). 4 folds, 2 folds,
In the case of JIS folding, the data of the size designation bit of the operation board register OBR and the data of the folding selection bit are transmitted to the unit 30 (293,296). This completes units 10 to 3
The control operation mode instruction is given to 0 and is set in the microprocessor of the unit 30.

When you finish setting the blade folding mode (29), CPU1 of unit 10
At 4, the punch mode is set (30).

In this, referring to the data of the size designation bit, the data of the folding selection bit and the data of the punch selection bit of the operation board register OBR (301 to 306, 308, 309),
Unit 40 when the final size is A4 and there is punch
Send A4 / punch mode to (307) and final size is B5
Moreover, when punching is present, the B5 / punch mode is transmitted to the unit 40 (310), and in other cases, the non-punch mode is transmitted to the unit 40.

When punch mode setting (30) is completed, CPU 10 of unit 10
At 4, the stamp mode is set (31).

In this case, referring to the stamp selection bit of the operation board register OBR (312), if it is 1 indicating the stamp, the unit 50 informs the unit 50 of the stamp selection bit, stamp position bit, issuer selection bit and The data of the drawing type selection bit is transmitted (313). If the stamp select bit is 0, it sends a non-stamp signal to unit 50.

When the stamp mode setting (31) is completed, the CP of unit 10
U14 sets the discharge mode (32).

In this case, referring to the paper discharge selection bit of the operation board register OBR (321), if it is 1, the unit 60 is instructed to discharge paper to the sorter, and when the discharge mode setting (32) is completed, This means that all the control operation modes have been instructed to 20 to 60, and the CPUs of these units hold the received instructions (mode data) respectively.

The CPU 14 of the unit 10 then returns to step 24 of FIG. 7b and goes through step 24 to step 25. Here, since the data in the previous operation board register POBR matches the data in the operation board register OBR due to the execution of the preceding step 26, the process proceeds from step 25 to 33. In step 33, all the indicator lamps of the abnormality display panel 33 are turned off, the standby indicator lamps of the operation board 12 are turned off, and the ready indicator lamps are turned on. Next, the ready signal is output and set to the copying machine 800 (34). Then, returning to step 5 in FIG. 7a, the arrival of a signal from the copying machine 800 and the key-in of the operation board 12 are waited for.

When the start signal arrives from the copier 800 (6), the ready / standby bit of the operation board register OBR is referred to (3
5) If it is 1, normal operation is possible, so start signals are sequentially transmitted to the units 20 to 60 at a predetermined timing (37). Then, again, the process proceeds to the state reading below the step. Upon receiving the start signal, each of the units 20 to 60 starts driving the transport roller and waits for the arrival of the paper at the sensor. When the paper arrives, a predetermined control operation is started.

Before or after the control unit 10 gives a start signal to the units 20 to 60, if the unit 20 is in standby (cannot process) or is in standby, the CP of the unit 10
U14 reads this in step 14 of FIG. 7b, and proceeds to the abnormality processing (15) of the unit 20. In this abnormality processing, first, the copier input bit of the operation board register OBR is referred to (151). If it is 1, data is received from the copying machine 800 and an abnormality (standby) is transmitted to the copying machine 800 because the sheet processing has started or has already started (152).
Then, the ready / standby bit of the OBR is set to 0 indicating that the operation is not possible, the ready indicator light of the operation board 12 is turned off, and the standby indicator light is turned on (153). Next, the abnormal data is received from the unit 20 (154), and if the abnormal data indicates a paper jam, the abnormal display panel corresponding to the position data is displayed.
13 Turn on the upper indicator lamp (156). When the abnormal data indicates that it is not a page jam, all the indicator lights of the display panel 13 associated with the abnormal mechanism unit are turned on (15
7). Then, the process returns to the state reading after step 5 in FIG. 7a.

Before or after the control unit 10 gives a start signal to the units 20 to 60, if the unit 30 is in a standby state (not processable) or in a standby state, the CP of the unit 10
U14 reads this in step 16 of FIG. 7b, and proceeds to the abnormality processing (17) of the unit 30. This abnormality processing (17) is similar to the above-mentioned abnormality processing (15). However, unit 20 of (15)
Should be read as unit 30.

Before or after the control unit 10 gives a start signal to the units 20 to 60, if the unit 40 is in standby (not processable) or is in standby, the CP of the unit 10
U14 reads this in step 18 of FIG. 7b, and proceeds to the abnormality processing (19) of the unit 40. This abnormality processing (19) is the same as the above-mentioned abnormality processing (15). However, unit 20 of (15)
Should be read as unit 40.

Before or after the control unit 10 gives a start signal to the units 20 to 60, if the unit 50 is in standby (cannot process) or is in standby, the CP of the unit 10
The U14 reads this in step 20 of FIG. 7b, and proceeds to the abnormality processing (31) of the unit 50. This abnormality processing (21) is the same as the above-mentioned abnormality processing (15). However, unit 20 of (15)
Should be read as unit 50.

Before or after the control unit 10 gives a start signal to the units 20 to 60, if the unit 60 is in standby (cannot process) or is in standby, the CP of the unit 10
U14 reads this in step 22 of FIG. 7b, and proceeds to the abnormality processing (23) of the unit 60. This abnormality processing (23) is the same as the above-mentioned abnormality processing (15). However, unit 20 of (15)
Should be read as unit 60.

The operation of the vertical folding mechanism unit 100 and the operation of the 90 ° turn mechanism unit 200 provided by the vertical folding & 90 ° turn control unit 20 have been described in the respective mechanism description sections. Therefore, the description of the control operation of the unit 20 will be omitted here because it is redundant.

Further, the operation of the blade folding mechanism unit 300 provided by the blade folding control unit 30 has been described in the mechanism description section of the unit 300. Therefore, the description of the control operation of this unit 30 will be omitted here because it is redundant.

The control operation of the punch control unit 40 and the control operation of the stamper control unit 50 will be described later.

The control operation of the vertical conveyance & discharge control unit 60 is to drive the paper conveyance roller, detect paper jam, and gate claw 712.
The positioning control is simple and can be easily understood by those skilled in the art from the mechanical description of the units 600 and 700, and therefore the description thereof is omitted here.

Next, the control operation of the microprocessor of the stamp control unit 50 will be described with reference to FIGS. 8a and 8b.
See also Figure 5a.

First, refer to FIG. 8a. The microprocessor (hereinafter simply referred to as CPU) of the unit 50 to which the power is turned on executes initialization (91) and status reading (92). When the sensor 598 detects the paper (93), the paper jam is transmitted to the unit 10 (94). And read status (92)
While waiting for the sensor 598 to wait for the paper non-detection state.

If the sensor 598 does not detect the paper in the status reading (92), the detection status of the sensor 536 is referred to (95). Sensor 5
If 36 is a photodetector, since the stamper's printing tool is not in the home position, the forward rotation bias of the pulse motor 520 is started and the rotation amount counting is started (96). And sensor 53
6 status reading and rotation amount reading are performed (97a, 98), and when the sensor 536 is in the light-shielded state, the printing tool reaches the home position and the motor 520 is stopped. Yes (97b). Since the sensor 536 is not in the light-shielded state, it is abnormal when the rotation amount reaches one rotation, so the motor 520 is stopped (99), a mechanism abnormality is transmitted to the unit 10 (100), and the system waits until the power is cut off. (101).

If the sensor 536 is shielded from light, then the state of the sensor 547 is referred to (102). When the sensor 547 detects light (reflector 545), the second printing cylinder 541 (printing surface of the publisher) is at the home position.

If the sensor 547 does not detect light, the second printing cylinder 541 is set to 1
Step forward (103). This is done as follows. First, the solenoid 555 is energized so that the latch claw at the tip of the arm 553 advances to the base of the latch wheel 543, and then the pulse motor 5
20 is reversely rotated by a predetermined angle, then the energization of the solenoid 555 is cut off, then the pulse motor 520 is forwardly biased by the predetermined angle, and a stop constraint current is supplied to the motor 520. As a result, the second printing cylinder 541 rotates 360 ° / 5 = 72 °, and the printing surface is fed by one step. Sensor 536
Has returned to the shading state.

When such one-step printing surface feeding is completed, the feeding step counter is incremented by 1 and the count value (feeding step amount) is compared with 4 (104). If it is not 4, the state of the sensor 547 is referred to again, and if it is light-shielded, the printing surface is fed once again. In this way, the printing surface is fed step by step until the sensor 547 is shielded from light. When the sensor 547 is shielded from light, the second printing cylinder 5
41 is set to the home position (printing position is the first issuer).

If the sensor 547 does not block the light even after performing the step feeding four times, it is determined that there is a mechanical abnormality, the mechanical abnormality is transmitted to the unit 10 (100), and the process proceeds to the abnormality standby (101).

When the second printing cylinder 541 is in the home position,
The home position set of the printing cylinder (printing surface of the drawing type) 540 is determined and when there is no home position, the home position set is set to the second printing cylinder.
Do the same as the home position setting of 541 (105,106,1
07).

If the first printing cylinder 540 is also in the home position, the unit 1
It sends ready to 0 (108), waits for the arrival of a signal from the unit 10 (109), and receives the signal from the unit 10 (110).

Next, proceeding to steps 111 and 112 in FIG. 8b, if the received signal is data, the data is stored in the mode register (11
3) Referring to the contents of this data (114), if a stamp is designated, the stamp-issued stamp data (first to fifth stamp numbers) and the current position (first stamp) The original mark number = 1) is compared (115), and if they do not match, the second printing cylinder 541 is step-driven (116).
The step driving operation of this step driving is step 103.
Is the same as For example, if the data specifies the third printing surface, 3-1 = 2 and 2 steps are driven, and 3 is stored in the position register. When the current position is the third print surface (position register = 3) and the first print surface is specified,
Three steps are driven with 1-3 = -2 and 5-2 = 3. Next, the drawing seed mark data (the numbers of the first to fifth drawing seed marks) and the current position (the number of the first drawing seed mark = 1) are compared (115),
If they do not match, the first printing unit 540 is step-driven (118). This print side setting is also similar to the setting operation in step 116.

When the setting of the printing surface is completed, the ready is transmitted to the unit 10 (108) and the start signal from the unit 10 is waited for (109, 110, 111).

When the start signal is received from the unit 10, the roller 582
Is set to the driving state, the timer Ts is set (119),
Wait for the sensor 598 to detect the paper or for the timer Ts to expire (120, 121). Paper does not come T
If s timed out, was there any trouble in the mechanical units up to the stamp mechanical unit 500?
If it is considered that the copying machine 800 has changed its status such that copying is not started, or that the feeding has ended (end), the roller drive is stopped (122), and standby is sent to the unit 10 (123). Proceed to read 92. After this process, the unit 500 is in the ready state,
Immediately after that, in step 108, send ready to unit 10,
It will wait for the start signal to arrive again from the unit 10.

When the start signal arrives and the sensor 598 detects the paper before the timer Ts times out (120), the contents of the mode register are referenced (124). The timing pulse number corresponding to is set and the pulse down count of the encoder 730 is started (125). It also waits for the count value to reach 0 (126). When the count value becomes 0, the pulse motor 520 is forwardly biased in synchronization with the pulse of the encoder 730 to start counting the rotation amount of the motor (12
7).

The contents of this pulse motor rotation energizing subroutine 127 are
A detailed description will be given here.

First, the forward rotation of the pulse motor is started with a predetermined acceleration pattern, the forward rotation amount count is started, and the paper discharge mechanism unit
Measure the time for one rotation of 700 rotary encoder.
The paper feed speed of the paper discharge mechanism unit 700 is set to the same speed. This time is measured by setting a 0.6msec timer until the number of pulses (slits) generated by one rotation of the rotary encoder is counted up,
When it times out, the time counter is counted by 1 and the 0.6 msec timer is reset. The content of the time counter when the value of the rotary encoder generated pulse counter reaches the value for one rotation indicates the feed speed (more precisely, its reciprocal). When the feed rate data is obtained, the timer value associated with the feed rate is read from the ROM,
Set in register. When the acceleration is completed, the timer value is set in the timer register, and when the time is over, the energizing phase signal of the pulse motor is switched to the next one and set in the timer register. This operation is repeated until the content of the forward rotation amount counter becomes PV.

When the normal rotation driving amount becomes PV, this subroutine 127 is exited.

Now, when the drive amount reaches the specified value PV, the printing surface is
Since it has arrived just before, the solenoid 578 is energized to pull up the roller 572 (129). This starts the stamp. After that, the forward rotation of the motor 520 is continued, and when the sensor 536 is shielded from light (130), the printing tool returns to the home position, so the motor 520 is stopped and the solenoid 5
The energization of 78 is cut off, and a stop constraint current is applied to the motor 520 (131). As a result, the rotary member is stopped and locked at the home position, and the positional displacement does not occur. When the stamp is not instructed, neither the motor 520 nor the solenoid 578 is energized.

Figure 8c shows the stamped image. Of the printing positions on the paper, the position from the front end of the paper in the feeding direction is determined by the value set in the counter in step 125. The printing position in the direction orthogonal to the paper feeding direction is determined by the position of the base frame 520 in the orthogonal direction.

Next, the excellent transfer of the above-described embodiment will be summarized and described.

(1) The processing mechanism is a unit section, and the jammed paper can be removed, inspected, and repaired for each unit section. Since each unit has a grip for manual paper ejection,
You can remove jammed paper in units.

(2) The stamp mechanism unit 500 has a polygonal printing cylinder 54.
Since 0, 541 are provided, and these are rotated by the solenoids 554, 555 and the printing tool drive motor 520, the number of mechanical elements for updating the printing surface is small and the apparatus is compact.

(3) The printing cylinders 540 and 541 are polygonal, and the printing tool rotary shaft 5
Since it is installed eccentrically from 10,528, only one printing surface set at the printing position is stamped during one rotation of the printing tool (one rotation of 510). The paper is clean. The printing cylinder 54
The printing rubber carrying side of 0,541 may not be a flat surface, but may be a curved surface curved in an arc shape.

(4) The stamp roller 572 can move back and forth, and the solenoid 578
In the advanced position, the paper is slightly pushed up from the transport surface toward the free rotating wheel, and in the retracted position, it does not contact the printing surface. Therefore, even if the printing tool rotates, if the stamp roller 572 is in the retracted position, the roller 572
Does not get stained with ink.

(5) Since the printing tool drive motor 520 is a pulse motor and a stop constraint current is applied during stop, the stop constraint (positioning) of the printing tool is reliable.

(6) Since the printing tool drive motor 520 is a pulse motor and is driven in synchronization with the paper feed synchronization pulse (encoder pulse) at the time of stamping, the paper synchronous drive of the printing tool is accurate and simple.

(7) The position of the base frame can be manually adjusted in the direction orthogonal to the paper feed direction, and the stamp position in this direction can be adjusted and set. The stamp position in the paper feed direction is automatically determined according to an electric signal and can be set by a switch.

(8) Since the ink roller 560 is detachable from the base frame and the stamp mechanism unit 500 can be pulled out from the main body of the sheet processing machine 900, it is possible to remove dust from the ink roller 560 and supply new ink to the roller 560. It's easy.

(9) Date The date of the printing position of the printing device is set in unit 50.
With 0 pulled out, the manual rotary wheel 522 can be turned to change the mode as shown in FIG. 5c. Since the mechanism unit 500 can be pulled out freely, this date change is relatively easy.

(10) A control unit is provided, and an operation board control unit is provided, and the operation board control unit serves as a main control unit and the other control units serve as slave control units, and the paper size, posture, folding type, punch necessity, stamp, and stamp. Data indicating the necessity, stamp contents, etc. is given to the operation board control unit from the operation board and / or the host such as a copying machine, the operation board control unit determines the stamp processing mode, and the slave control is performed based on the determined processing mode. Determine the processing mode of the unit and send it to the slave control unit. Therefore,
The control operation of the slave control unit is relatively simple. The slave control unit controls the sheet processing control of the mechanical unit, the paper jam judgment and the abnormality judgment, and the jam and the protection stop at the time of the abnormality and the transmission of this to the main control unit. You can do it. The entire movement of the sheet processing machine 900 and the movement of the mechanical unit are matched, the response at the time of trouble is quick, and further, the superposition of trouble is prevented.

(11) When the signal and data obtained in the setting state of the host such as the copying machine 800 and the signal and data obtained in the setting response of the operation board are duplicated, the operation board control unit extracts the former with priority over the latter. However, the signals and data that cannot be obtained from the host are obtained in the setting state of the operation board, and the data that is the basis of the processing mode determination is prepared.

When the sheet processing machine 900 is connected to a host such as the copying machine 800, the data given by the host is more reliable, and the processing should be started according to the start signal from the host. Therefore, the signal and data processing described above is rational, and there are few errors in judgment and processing. Also, the operation of the host and the operation of the stamp device are motivated or matched.

If the host is not connected, it operates according to the input of the operation board, so that the stamp device can be used alone.

〔The invention's effect〕

By energizing the stopper driving means and energizing the motor in rotation, a plurality of marking surfaces can be automatically set to the imprinting position.
This automatic setting is stepwise in units of a predetermined angle due to the presence of the latch member, so by aligning the stamp surface with this, each stamp surface is in the form of step rotation, and the printing position (outward from the rotation center of the rotating member is the most. Accurately positioned in the protruding position).

[Brief description of drawings]

FIG. 1 is a front view of a sheet processing machine 900 equipped with a stamp device according to an embodiment of the present invention, in which a front cover is removed and a front cover plate of a paper discharge mechanism unit 700 is removed. . FIG. 2 is an external perspective view showing a most recommended use state in which the sheet processing machine 900 is connected to the copying machine 800 and the sorter 1000 is connected to the sheet processing machine 900. FIGS. 3a and 3b are plan views of paper and show the paper processing state in the sheet processing machine 900 and the copying machine 800. FIG. 4 is a front view showing a main part of the mechanism of the sheet processing machine, and corresponds to an enlarged view in which the unit cover is removed in the state of FIG. FIG. 5a shows the stamp mechanism unit 500 of the sheet processing machine 900.
It is an expansion perspective view which shows the main mechanism element of. FIG. 5b shows the ink roller 560 of the stamp mechanism unit 500.
It is an enlarged perspective view showing. FIG. 5c is a perspective view of the cover 594 attached to the base frame 502 of the stamp mechanism unit 500. FIG. 6a is a block diagram showing the upper surface of the operation board 11 of the sheet processing machine 900 in an enlarged manner and showing the configuration of the electric control system in blocks. FIG. 6b is a plan view showing the memory contents of a register in which the operation board control unit 10 shown in FIG. 6a stores state data, sheet processing instruction data and the like. 7a, 7b, 7c and 7d are flow charts showing the control operation of the operation board control unit 10 shown in FIG. 6a. 8a and 8b are a flow chart showing the control operation of the stamp control unit 50 shown in FIG. 6a. FIG. 8c is a plan view showing an example of a stamp. Figures 1, 2 and 4 800: Copying machine, 900: Sheet processing machine, 1000: Sorter ET: Paper ejection tray, 11: Operation board 100: Vertical folding mechanism unit, 190, 192: Handshake for drawer 180: Grip for driving jam paper discharge, 801: Arrival direction of paper to be processed 200: 90 ° turn mechanism unit 239: Handshake for pulling out paper, 21: Grip for driving jam paper discharge 237: Switch for jam paper cutting 300: Feather folding mechanism unit, 388: Handshake for pulling out drawer 386: Grip for driving jam paper ejection 390: Switch for instructing to cut jam paper 400: Punch mechanism unit, 474: Handshake for pulling out jam paper 472: Grip for driving jam paper ejection 476: Switch for jam paper cut instruction 500: Stamp mechanism unit, 398: Handshake for drawer 600: Vertical transport mechanism unit, 636: Handshake for drawer 634: Handgrip for driving jam paper 700: Paper discharge mechanism unit, 701: Tray ejection direction 703: Sorter ejection direction Figures 5a and 5b And Fig. 5c 572,580,582: Roller, 502: Base frame 504,506: Side plate, 508,530: Bearing 510,528: Rotating shaft, 512,526: Printing tool support plate 514,532: Free rotating wheel, 516,518: Pulley 520: Pulse motor, 522: Manual rotating wheel 524,558 : Connecting rod, 534: Shutter 536: Optical sensor, 538,539: Pin 540,541: Printing cylinder, 542,545: Latch ring 544,545: Reflector, 546,547: Reflector sensor 548,549: Latch arm, 551: Tension spring 552,553: Feed arm, 554,555: Solenoid 556: Date stamper, 560: Ink roller 562,564: Guide bar, 566: Stopper 568: Extension spring, 570: Positioning arm 574: Bearing, 578: Solenoid 594: Cover, 598: Paper sensor

Claims (19)

[Claims] 1. A motor (520); a rotary member (512, 526) rotatably driven by the motor (520);
A printing cylinder (540, 541) that is eccentrically pivoted about the center of rotation of the rotating member and has a plurality of printing surfaces; a latch shaft (542, 543) connected to the printing cylinder; Latch member for static restraint (548,549,55
1); stoppers (552,553) for engaging the latch wheels; stopper driving means (554,55) for driving the stoppers to the engaging position
5); and a stamp mechanism; and a stopper ring (554,555) for urging the latch wheel (542,5).
The stopper (552,553) is moved to a position that obstructs the movement of (43), the motor (520) is driven, and the rotary member (512,526) is rotated in the direction opposite to the conveying direction of the stamp target, and the printing cylinder (540,541) rotates. An automatic stamping device provided with a control means (10, 50) for updating the stamp surface by doing so. 2. The automatic stamping device according to claim 1, wherein the latch member (548,549,551) allows rotation of the latch wheel (542,543) in one direction and prevents rotation in the other direction. 3. The movable stamp device according to claim 1, wherein the stopper driving means (554, 555) is a solenoid. 4. The motor (520) is a pulse motor, and the control means (10, 50) places the stoppers (552, 553) in the retracted position and sets the pulse motor (520) to the sheet feed timing pulse of the stamp object. The automatic stamping device according to claim (1), which rotates in synchronization. 5. A stamp mechanism includes a roller (572) and a vertically moving arm (576), one end of which is fixedly supported and the other end of which is supported by an up-and-down drive arm (576) and which is located below a stamp object carrying surface. Arm drive means for lifting upwards (578)
The control means (10, 50) places the stopper (552, 553) in the retracted position to rotate the pulse motor (520) in synchronization with the paper feed timing pulse, and the arm drive means (57).
The automatic stamping device according to claim (4), wherein the roller (572) is driven upward by energizing 8). 6. The automatic stamping device according to claim 5, wherein the arm driving means (578) is a solenoid. 7. The stamp mechanism comprises a pulse motor (520),
The first rotating member (51
2), a second rotating member (526) coupled to the first rotating member,
A first printing cylinder (540) pivotally attached to the first rotating member so as to be eccentric to the rotation center of the first rotating member, and a first latch member (548) for statically latching the first printing cylinder at every rotation of a predetermined angle. A first latch wheel (542) coupled to the first printing cylinder, a first stopper (552) that engages the first latch wheel when the first latch wheel is in a predetermined position, and a first stopper engaging position Stopper driving means (554) and second rotating member (526) driven to
A second printing cylinder (541) pivotally mounted eccentrically to the center of rotation of the second rotating member, a second latch member (549,551) for latching the second printing cylinder stationary at every rotation of a predetermined angle, second printing A second latch wheel (543) coupled to the body, a second stopper (553) that engages with the second latch wheel when the second latch wheel is in a predetermined position, and a second stopper that drives the second stopper to the engagement position. Two stopper driving means (555), and a date stamper (556) disposed between the first and second printing cylinders and coupled to at least one of the first rotating member and the second rotating member. The control means (10, 50) urges the first and second stoppers to the engagement position to rotate the pulse motor to rotate the first and second printing cylinders to update the printing surface. The automatic stamping device according to item (1). 8. The automatic stamping device according to claim 7, wherein the first and second stopper driving means (554, 555) are solenoids. 9. The control means (10, 50) according to claim 1, wherein the pulse motor is rotated in synchronization with the feed timing pulse of the stamp object by placing the first and second stoppers at the retracted position. An automatic stamping device according to the item 7). 10. The stamp mechanism has one end fixedly supported,
The control means (10, 50) includes a roller (572) whose other end is supported by a vertical drive arm (576) and which is located below the paper transport surface, and an arm drive means (578) for lifting the vertical movement arm upward. The first and second stoppers are placed in the retracted position, the pulse motor is rotated in synchronization with the feed timing pulse of the stamp object, and the arm drive means is urged to drive the roller upward. The automatic stamping device according to item (7). 11. The automatic stamping device according to claim 10, wherein the arm driving means (578) is a solenoid. 12. The control means (10, 50) synchronizes with a feed timing pulse of the stamp object after a predetermined delay designated by an electric signal from the arrival of the stamp object at a predetermined point. The automatic stamping device according to claim (4), (5), (9) or (10), which starts driving. 13. The stamp mechanism comprises a first rotating member (512).
Manual rotating wheel (522) for manually rotating the rotating shaft (510)
The automatic stamping device according to claim (7), further comprising: 14. The automatic stamp according to claim 13, wherein the date stamper (556) has a normally visible numeral shape of the numeral appearing on the printing surface, which appears on the date changing wheel portion. apparatus. 15. The stamp mechanism according to claim 1, further comprising: a printing surface of the printing cylinder (540, 541) in a standby position, and an ink roller (560) arranged between the printing surface and a position where the printing surface contacts a stamp object. The automatic stamping device according to item (1). 16. An ink roller (560) is a removable frame (584).
The detachable frame (584) is pivotally attached to the rotating member (512,526).
The automatic stamping device according to claim (15), wherein said shaft body (510, 528) is connected to a beam fixed to a base frame (502) pivotally attached. 17. The automatic stamping apparatus according to claim 1, wherein the control means (10, 50) sets the stamping operation mode according to the necessity of stamping and the stamping position. 18. A control means (10, 50) comprises a main judgment means (10) for judging an operation mode of the stamp mechanism by reading a signal inputted from the outside, and an operation of the stamp mechanism according to the judged operation mode. The automatic stamping device according to claim (17), which comprises sub-controlling means (50) for controlling the. 19. The main control means (10) is an operation board (11).
The key-in and the signal from the host (800) are read, and when both are duplicated, the signal from the host is read first to determine the operation mode of the stamp mechanism, and the operation mode is given to the slave control means (50). The sub-control means (50) gives the state of the stamp mechanism to the main control means (10), and the main control means (10) displays a pulse (13) indicating the state of the stamp mechanism. ) The automatic stamping device described in the paragraph.