JP5554861B1 - Rotary punching machine - Google Patents

Abstract

The present invention provides a rotary punching machine equipped with a simple and low-cost control mechanism for correcting a shift in feeding timing between a processing roller and a receiving roller.
A first driving mechanism for rotating a processing roller and a receiving roller and a second driving mechanism for rotating a pair of conveying rollers are arranged independently of each other. A sensor 28 is arranged on the downstream side of the pair of conveying rollers, and when processing the first sheet S, the time until the sheet passes the sensor after the sheet supply operation by the sheet feeding unit 1 is started is measured. Based on the deviation of the measured value from the set value, the sheet supply timing by the sheet feeding unit is corrected. The second and subsequent sheets are fed by the paper feed unit at the corrected timing, and the rotation of the conveying roller pair is controlled in accordance with the peripheral speed and rotational position of the blade mold using the detection signal from the sensor as a trigger. Then, the front end of the punching range of the sheet is made to coincide with the front end of the blade die at the lowest point of the processing roller.
[Selection] Figure 1

Description

  The present invention includes a sheet feeding unit that supplies sheets one by one from a sheet stack, a punching unit that has a pair of a processing roller and a receiving roller, and punches a sheet supplied from the sheet feeding unit, and a sheet feeding unit And a conveyance unit that is arranged between the punching processing unit and conveys the sheet received from the paper feeding unit to the punching processing unit, and is punched while the sheet is conveyed through the gap between the processing roller and the receiving roller. The present invention relates to a rotary punching machine.

As this type of rotary punching machine, those incorporated in a sheet-fed rotary printing press are known in the prior art (see, for example, Patent Documents 1 and 2).
This sheet-fed rotary printing press includes a paper feeding unit that supplies sheets one by one, a printing unit that prints on the fed sheets, and a varnish coating unit that varnishes the printed sheets. And a drying unit for drying the sheet, and a finishing unit for performing a predetermined punching process on the sheet in accordance with the printing pattern on the sheet.

  The finishing unit includes a processing roller, a receiving roller that forms a pair with the processing roller, and a blade mold attached to the peripheral surface of the processing roller, and a single wafer supplied from the preceding apparatus (drying unit). While the paper is conveyed by the processing roller and the receiving roller, the paper is punched (including embossing, creasing, and perforation) by the blade die.

  By the way, in order to accurately punch a predetermined portion of the sheet, the front end of the punching range of the sheet introduced between the processing roller and the receiving roller at the lowest point of the processing roller, and the blade type It is necessary to align the front ends in the rotational direction with each other. For this purpose, paper must be fed between the processing roller and the receiving roller at an accurate timing corresponding to the peripheral speed and rotational position of the blade mold.

However, in the sheet-fed rotary printing press as described above, a plurality of devices are arranged in the front stage of the finishing unit, and each device has an independent drive mechanism. For this reason, even if paper is fed to the finishing unit at a preset timing, a timing shift is likely to occur while passing through each apparatus. There was a problem that non-defective products were produced and productivity was lowered.
In the prior art, a complicated and high-cost control mechanism is required to correct the deviation in the timing of feeding paper to the finishing unit.

Japanese Patent Laying-Open No. 2003-237018 (paragraphs [0019] to [0020], FIG. 2) JP 2012-161859 A

  An object of the present invention is to provide a rotary punching machine equipped with a simple and low-cost control mechanism that corrects a deviation in timing of paper feeding between a processing roller and a receiving roller.

In order to solve the above problems, according to the present invention, a sheet feeding unit that supplies sheets one by one from a sheet stack at a predetermined timing, a punching unit that punches sheets supplied from the sheet feeding unit, A conveying unit that extends between the sheet feeding unit and the punching unit and conveys the sheet received from the sheet feeding unit to the punching unit while correcting skew; and the sheet feeding unit, the punching unit, and the conveyance A control unit that controls the operation of the unit, and the sheet feeding unit is disposed above the sheet stack, and sequentially adsorbs the uppermost sheet of the sheet stack at the timing, and the conveyance unit from the sheet outlet The punching section includes a processing roller extending perpendicular to the sheet transport direction, parallel to the processing roller, and a peripheral surface extending from the peripheral surface of the processing roller. The receiving roller disposed opposite to the fixed roller, the blade mold mounted on the peripheral surface of the processing roller, and the processing roller and the receiving roller are synchronized with each other at a constant peripheral speed equal to each other. A first driving mechanism that rotates, a pair of conveying rollers that are disposed upstream of the pair of the processing roller and the receiving roller at a distance from the first driving mechanism and extend in parallel to the pair of the processing roller and the receiving roller; A second drive mechanism for rotating the roller pair, and the processing roller and the receiving roller always rotate in a direction in which a sheet is introduced from the conveyance roller pair, and a gap between the conveyance roller pair and the conveyance roller pair. The sheet introduced into the sheet is conveyed through the gap between the processing roller and the receiving roller by the pair of conveying rollers, and punched by the blade mold in the meantime. The punching processing unit is further provided with a sensor that is disposed between the processing roller and the pair of conveying rollers, and that detects passage of a front end of the sheet, and the sheet feeding unit controls the sheet. When the first sheet is supplied from the stack, the control unit measures the time from the start of operation of the suction conveyance unit until the front end of the first sheet passes the sensor, and from the set value of the measurement value Based on the deviation, the timing of sheet supply by the sheet feeding unit is corrected, and the second and subsequent sheets are fed by the sheet feeding unit at the corrected timing, and from the sensor. Using the detection signal as a trigger, the rotation of the conveying roller pair is controlled in accordance with the peripheral speed and the rotational position of the blade mold, and the processing roller is rotated to the maximum. A rotary punching machine is provided in which the front end of the punching range of the sheet is made to coincide with the front end of the blade mold at the lower point.
Here, the “punching” includes embossing, creasing, perforation, and the like. The same applies hereinafter.

  According to a preferred embodiment of the present invention, there is further provided another sensor that is disposed between the sheet outlet of the paper feeding unit and the inlet of the conveying unit, and detects the passage of the front end of the sheet. Each time the subsequent sheets are supplied, the time from the start of operation of the suction conveyance unit until the front edge of the related sheet passes the other sensor is measured, and the deviation of the measured value from the set value is detected in advance. When the determined range is exceeded, the next sheet feeding by the sheet feeding unit is skipped, and during this time, the operation of the pair of conveying rollers is temporarily performed when the related sheet is detected by the sensor. After stopping, at the timing when the sensor detects the sheet when it is determined that the sheet supply has not been skipped, the conveyance roller pair starts to operate again. The rotation of the pair of conveying rollers is controlled corresponding to the peripheral speed and rotational position of the blade die, and the front end of the sheet punching range coincides with the front end of the blade die at the lowest point of the processing roller. It is supposed to be.

  According to another preferred embodiment of the present invention, the sheet feeding unit is disposed so as to be movable up and down, and is disposed in front of the sheet stacking shelf on which the sheet stack is mounted, and the sheet stacking shelf. A vertical sheet aligning plate, a lifting unit for moving up and down the sheet stacking shelf, and a height detection sensor for detecting the height of the sheet stack on the sheet stacking shelf, and detecting from the height detection sensor Based on the signal, each time the height of the sheet stack decreases by a certain amount, the sheet stacking shelf rises by a corresponding amount, and the suction conveyance unit of the sheet feeding unit A horizontal suction conveyor belt extending forwardly from the front end of the sheet stack over the sheet aligning plate above the sheet stack on the shelf, Down belt conveyor is operated at the timing of the supply of the sheet, the uppermost sheet of the sheet stack, so that the feeding forward beyond the sheet aligning plate while adsorbing the upper surface.

  According to the present invention, the first drive mechanism for rotating the processing roller and the receiving roller and the second drive mechanism for rotating the conveyance roller pair are arranged independently of each other, and a sensor is provided on the downstream side of the conveyance roller pair. When the first sheet is processed, the time until the sheet passes the sensor after the sheet feeding operation is started by the sheet feeding unit is measured, and the measured value deviates from the set value. Based on the above, the sheet supply timing of the sheet feeding unit is corrected, and the second and subsequent sheets are supplied by the sheet feeding unit at the corrected timing, and the detection signal from the sensor is used as a trigger to carry the sheet. The rotation of the roller pair was controlled according to the peripheral speed and rotational position of the blade mold, and the front end of the sheet punching range coincided with the front edge of the blade mold at the lowest point of the processing roller. , It is possible to accurately punched into a predetermined position of the sheet. In this case, the feeding timing to the pair of processing roller and receiving roller can be controlled only by providing a pair of conveying roller and a sensor that are driven independently of the pair of processing roller and receiving roller. Therefore, the control mechanism can be simplified and reduced in cost.

It is a side view which shows schematic structure of the rotary punching machine by one Example of this invention. It is a side view which shows the principal part of the punching process part of the rotary punching machine of FIG. It is a figure explaining the method of determining the paper feed timing with respect to a pair of a process roller and a receiving roller.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. FIG. 1 is a side view showing a schematic configuration of a rotary punching machine according to one embodiment of the present invention, and FIG. 2 is a side view showing a main part of the rotary punching machine of FIG.
1 and 2, the rotary punching machine of the present invention is arranged at a sheet feed unit 1 that supplies sheets S from a sheet stack P one by one at a predetermined timing, and at a subsequent stage of the sheet feed unit 1. , A conveying unit 2 that conveys the sheet S received from the sheet feeding unit 1 while correcting the skew, a punching unit 3 disposed at a subsequent stage of the conveying unit 2, and a subsequent stage of the punching unit 3. A discharge unit 4 that discharges the sheet S, and a control unit 5 that controls operations of the sheet feeding unit 1, the conveyance unit 2, the punching unit 3, and the discharge unit 4.

The sheet feeding unit 1 is disposed so as to be movable up and down, a horizontal sheet stacking shelf 1a on which the sheet stack P is placed, a lifting unit (not shown) that lifts and lowers the sheet stacking shelf 1a, and a sheet stacking shelf 1a And a vertical sheet aligning plate 1b that is arranged in front and aligns the front ends of the sheets S of the sheet stack P. The upper end of the sheet aligning plate 1b is bent forward at a right angle and extends horizontally.
Above the front end portion of the sheet stack P on the sheet stacking shelf 1a, a suction conveyance unit 6 that sucks the uppermost sheet S of the sheet stack P and sends it forward beyond the upper end of the sheet aligning plate 1b is disposed. Yes.
Although not shown, a height detection sensor for detecting the height of the sheet stack P on the sheet stacking shelf 1a is disposed, and the height of the sheet stack P is reduced by a certain amount based on a detection signal from the sensor. Each time, the sheet stacking shelf 1a is raised by an amount corresponding thereto.

In this embodiment, the suction conveyance unit 6 includes horizontal suction belt conveyors 6a to 6d that extend forward from the front end portion of the sheet stack P beyond the sheet alignment plate 1b.
The suction belt conveyors 6a to 6d include a pair of rollers 6a and 6b that are spaced apart from each other and extend at right angles to the conveying direction of the sheet S. One roller 6a of the pair of rollers 6a and 6b is positioned above the front end of the sheet stack P, and the other roller 6b is positioned above the horizontal portion of the sheet aligning plate 1b. An endless belt 6c is stretched between the pair of rollers 6a and 6b. Vent holes are uniformly formed on the belt surface of the endless belt 6c.

  Although not shown, one of the pair of rollers 6a and 6b, for example, the rotation shaft of the roller 6b, is connected to the drive shaft of the motor via an electromagnetic clutch. During the operation of the rotary punching machine, the drive shaft of this motor always rotates in a constant direction, while the rotation and stop of the roller 6b are switched by the electromagnetic clutch, whereby the endless belt 6c moves the sheet S forward. It is designed to make a turning motion intermittently in the direction of feeding to the.

  Further, a suction duct 6d is disposed between the pair of rollers 6a and 6b and above the lower straight portion of the endless belt 6c. The suction duct 6d has an intake port on the lower surface, and is connected to an intake pump (not shown) via an electromagnetic valve (not shown). During the operation of the rotary punching machine, the intake pump always operates, while the operation of the suction duct 6d is switched by switching the electromagnetic valve.

Then, the endless belt 6c revolves and suction by the suction duct 6d is started, whereby the uppermost sheet S of the sheet stack P is attracted to the lower surface of the endless belt 6c and conveyed forward, and the feed roller It is sent out to the transport unit 2 through the pair 6e.
In this embodiment, the gap between the horizontal portions of the suction belt conveyors 6a to 6d and the sheet aligning plate 1b forms the sheet outlet.

A pair of paper feed rollers 6e is disposed adjacent to the downstream ends of the suction belt conveyors 6a to 6d. The pair of paper feed rollers 6e extends across the conveying direction of the sheet S at a right angle, and the gap is disposed so as to face the gap between the suction belt conveyors 6a to 6d and the horizontal portion of the sheet aligning plate 1b. ing.
The sheet feed roller pair 6e is always rotated in the direction to take in the sheet S from the suction belt conveyors 6a to 6d, and the suction belt conveyors 6a to 6 operate when the sheet S is introduced into the sheet feed roller pair 6e. Is supposed to stop.

  Further, a flat support plate 6f that supports the lower surface of the conveyed sheet S is disposed between the paper feed roller pair 6e and the conveyance unit 2, and the passage of the front end of the sheet S is detected above the support plate 6f. A sensor 29 is disposed. A detection signal of the sensor 29 is transmitted to the control unit 5. The support plate 6f is provided as necessary.

In this embodiment, the transport unit 2 is composed of a suction belt conveyor. The suction belt conveyor 2 is stretched between a pair of rollers 7a and 7b and a pair of rollers 7a and 7b extending horizontally across the sheet conveying path at right angles on the sheet feeding unit 1 side and the punching processing unit 3 side, respectively. An endless belt 10 is provided. The belt surface of the endless belt 10 is uniformly provided with air holes.
A first pulley 8 is fixed to the rotation shaft of one of the pair of rollers 7a and 7b, and a motor 11 is disposed below the roller 7a. The drive shaft of the motor 11 extends parallel to the roller 6 and includes a second pulley 12. Further, another endless belt 13 is stretched between the first and second pulleys 8 and 12. The endless belt 10 rotates by driving the motor 11.

Further, a suction duct 14 is disposed between the pair of rollers 7 a and 7 b and below the upper straight portion that forms the conveying surface of the endless belt 10. The suction duct 14 has an intake port on the upper surface and is connected to the intake pump 15.
Although not shown, a known skew correction unit that corrects the skew of the conveyed sheet S is disposed above the transport surface of the endless belt 10.

  Then, as the endless belt 10 rotates and the intake pump 15 is operated, the sheet S supplied from the sheet feeding unit 1 is skew-corrected while the lower surface of the sheet S is adsorbed by the endless belt 10. It is conveyed to the punching unit 3.

  The punching unit 3 includes a processing roller 16 disposed in parallel to the pair of rollers 7 a and 7 b of the suction belt conveyor 2, a parallel surface to the processing roller 16, and a peripheral surface spaced apart from the peripheral surface of the processing roller 16. A receiving roller 17 is provided so as to be opened and opposed thereto. As shown in FIG. 2, a sheet-like blade die 29 is attached to the peripheral surface of the processing roller 16.

Referring to FIG. 1 again, a third pulley 18 is fixed to the rotating shaft of the receiving roller 17, and a motor 19 is disposed below the receiving roller 17. The drive shaft of the motor 19 extends parallel to the receiving roller 17 and includes a fourth pulley 19a. The first timing belt 20 is stretched between the third and fourth pulleys 18 and 19a. The receiving roller 17 is rotated by driving the motor 19.
In addition, the rotating shaft of the processing roller 16 is connected to the rotating shaft of the receiving roller 17 by an interlocking connecting mechanism (not shown), whereby the processing roller 16 and the receiving roller 17 rotate synchronously at the same peripheral speed. .

  The motor 19, the third and fourth pulleys 18, 19a, the first timing belt 20, and the interlocking coupling mechanism (not shown) constitute a first drive mechanism for rotating the magnet roller 16 and the receiving roller 17. Yes.

Further, a rotary encoder 22 is disposed between the receiving roller 17 and the motor 19. A rotary shaft of the rotary encoder 22 extends in parallel to the rotary shaft of the receiving roller 17 and includes a fifth pulley 21. The fifth pulley 21 is in contact with the first timing belt 20 from the outside, and rotates with the turning motion of the first timing belt 20.
Based on the output pulse of the rotary encoder 22, the rotational position of the receiving roller 17, and hence the processing roller 16 (that is, the blade die 26) is detected.

  The punching processing unit 3 also includes a pair of conveying rollers 23a and 23b arranged at a predetermined interval on the upstream side of the pair of processing roller 16 and receiving roller 17 and adjacent to the downstream end of the suction belt conveyor 2. I have. The conveyance roller pairs 23a and 23b are arranged side by side in the vertical direction, and are composed of a pair of rollers extending in parallel with the processing roller 16 and the receiving roller 17, respectively.

A sixth pulley 24 is fixed to the rotation shaft of the lower roller 23b of the conveying roller pair 23a, 23b. A servo motor 25 is disposed below the lower roller 23b, and a seventh pulley 25a is fixed to a drive shaft of the servo motor 25 parallel to the lower roller 23b.
A second timing belt 27 is stretched between the sixth and seventh pulleys 24 and 25a, and the drive roller pair 23a and 23b is rotated by driving the servo motor 25.
The servo motor 25, the sixth and seventh pulleys 24 and 25a, and the second timing belt 27 constitute a second drive mechanism that rotates the conveyance roller pair 23a and 23b.

  Then, the processing roller 16 and the receiving roller 17 are always rotated in the direction in which the sheet S is introduced from the conveying roller pair 23a, 23b, and introduced into the gap between the conveying roller pair 23a, 23b from the suction belt conveyor (conveying unit) 2. The sheet S is conveyed through the gap between the processing roller 16 and the receiving roller 17 by the conveying roller pair 23a and 23b, and is punched by the blade die 26 therebetween.

Further, a sensor 28 that detects the passage of the front end of the sheet S is disposed on the downstream side of the pair of conveyance rollers 23a and 23b. A detection signal of the sensor 28 is transmitted to the control unit 5.
Further, a flat support plate 32 that supports the lower surface of the sheet that is conveyed by each roller pair is disposed between the conveying roller pair 23a, 23b and the pair of the processing roller 16 and the receiving roller 17. The support plate 32 is provided as necessary.

The control unit 5 includes an input unit for receiving data relating to the punching processing of the sheet S, such as the vertical and horizontal sizes of the sheet S, the distance from the front end of the sheet S to the front end of the punching processing range, and the like.
In this embodiment, the input unit comprises a touch panel display 9 and a numeric keypad (not shown).

  Thus, when the operation of the rotary punching machine is started and the first sheet S is supplied from the sheet stack P by the sheet feeding unit 1, the control unit 5 starts the operation of the suction conveyance unit 6 of the sheet feeding unit 1 after starting the operation. The time until the front end of S passes the sensor 28 is measured. Then, based on the deviation of the measured value from the set value, the sheet supply timing by the sheet feeding unit 1, that is, the operation timing of the suction conveyance unit 6 is corrected.

A method for obtaining the set value and correcting the timing of sheet supply by the sheet feeding unit 1 will be described with reference to FIG.
In FIG. 3, the same components as those shown in FIG. Also, in FIG. 3, the correspondence between each symbol and what it indicates is as follows.
d: Distance from the front end of the sheet S to the front end of the punching range G: Punching range of the sheet S L ₁ : Distance from the front end of the sheet S (sheet alignment plate 1b) on the sheet stacking shelf 1a to the sensor L ₂ : Distance between sensor 29 and sensor L ₃ : Distance from sensor 28 to point Q Q: Bottom point of processing roller v ₁ : Peripheral speed of blade 26 v ₂ : Conveying speed of sheet S x: Processing roller 16 The distance from point Q to the front edge of blade 26 along the circumference of

Referring to FIG. 3, after the start operation of the suction conveyance unit 6 (after the start conveyance of the sheet S), the time t until the front end of the punching range G of the sheet S reaches the point Q, with v ₂ is constant if there is,
t = (L ₁ + L ₂ + L ₃ + d) / v ₂
It is. Therefore, the front end of the blade mold 26 is
x = v ₁ × t
If the supply of the sheet S by the sheet feeding unit 1 is started at the rotational position, the front end of the punching range G of the sheet S coincides with the front end of the blade die 26 at the point Q, and punching can be performed accurately. become.
In this way, the timing is set so that the supply of the sheet S by the paper feeding unit 1 is started (the suction conveyance unit 6 is activated) every time the front end of the blade die 26 comes to the rotational position where x = v ₁ × t. The

However, in practice, the feeding speed of the sheet S by the suction conveyance unit and the conveyance speed of the sheet S by the suction belt conveyor (conveying unit) 2 fluctuate up and down v ₂ (particularly, the size of the sheet S has been changed). And when the rotary punching machine operates at a high speed, the time at which the front end of the punching range G of the sheet S reaches the point Q deviates from the set value (= t).

  Therefore, in the rotary punching machine of the present invention, first, during the processing of the first sheet S, the time from the start of the operation of the suction conveyance unit 6 until the front end of the sheet S passes the sensor 28 is measured, and the set value ( = T) is detected, and based on this deviation, the sheet supply timing by the sheet feeding unit 1 and the operation timing of the suction conveyance unit 6 are corrected.

  In this way, the second and subsequent sheets S are supplied by the paper supply unit 1 at the corrected timing, and the sheets S supplied one by one from the paper supply unit 1 are conveyed by the suction belt conveyor 2, and are supplied to the suction belt. It is introduced from the conveyor 2 into the gap between the conveying roller pair 23a, 23b. In this case, the suction belt conveyor 2 is always in an operating state.

The sheet S introduced into the gap between the conveyance roller pair 23a and 23b is conveyed on the support plate 32 toward the gap between the processing roller 16 and the receiving roller 17 by the conveyance roller pair 23a and 23b.
When the front end of the sheet S passes the sensor 28, the detection signal from the sensor 28 is used as a trigger to control the rotation of the conveying roller pair 23a, 23b according to the peripheral speed and the rotational position of the blade die 26. At the lowest point of the processing roller 16, the front end of the punching range G of the sheet S is aligned with the front end of the blade die 26.

This will be described again with reference to FIG. 3. When the front end of the sheet S is detected by the sensor 28, it is assumed that the front end of the blade mold 26 is at a rotational position away from the point Q by a distance x. The time t to reach point Q is
t = x / v ₁
Therefore, during this time, in order for the front end of the punching range G of the sheet S to reach the point Q, the sheet S is
v = (L ₃ + d) / t
Must be transported at a speed of The rotational speeds of the transport roller pairs 23a and 23b are controlled so that the transport speed v is obtained.

  Then, after the front end of the punching range G of the sheet S coincides with the front end of the blade mold 26 at the point Q, the conveyance speed of the sheet S is maintained until the rear end of the blade mold 26 is separated from the sheet s. The rotation of the pair of transport rollers 23a and 23b is controlled so as to coincide with the peripheral speed.

  Thus, in addition to correcting the sheet feeding timing by the sheet feeding unit 1, the rotation of the conveying roller pair 23a and 23b is controlled by using the detection signal from the second sensor 29 as a trigger, thereby processing at an accurate timing. Paper can be fed to the pair of roller 16 and punching roller 17.

By the way, when the suction belt conveyor is employed in the suction conveyance unit 6 as in this embodiment, the sheet S is sucked when the size of the sheet S is increased or the operation speed of the rotary punching machine is increased. There is a possibility that the supply of the sheet S by the suction conveyance unit 6 may be greatly delayed as a result of being conveyed while slipping on the conveyance surface without being reliably attracted to the belt conveyor.
In this case, the timing from the start of the operation of the suction conveyance unit 6 to the passage of the sensor 28 at the front end of the sheet S is greatly deviated. Alignment with the front end of 26 becomes impossible.

For this reason, in the rotary punching machine of the present invention, every time the second and subsequent sheets S are supplied by the sheet feeding unit 1 until the front end of the related sheet passes through the sensor 29 from the start of the operation of the suction conveyance unit 6. When the deviation of the measured value from the set value (t ′ = L ₁ / v ₂ ) exceeds a predetermined range, the next sheet supply by the sheet feeding unit 1 is performed. Skipped. Then, while skipping, when the relevant sheet is detected by the sensor 28, after the operation of the pair of conveying rollers 23a and 23b is temporarily stopped, the sheet when the sheet supply is not skipped is assumed. Is detected by the sensor 28, the conveying roller pair 23a, 23b starts to operate again, and the rotation of the conveying roller pair 23a, 23b is controlled corresponding to the peripheral speed and rotational position of the blade die 26. The front end of the punching range of the sheet S is made to coincide with the front end of the blade die 26 at the lowest point of the processing roller 16.

  The discharge section 4 is perpendicular to the conveyor belt 30 in the vicinity of the conveyor belt 30 extending from the outlet of the pair of the magnet roller 16 and the receiving roller 17 toward the discharge port of the rotary punching machine, and in the vicinity of the downstream end of the conveyor belt 30. And a conveying roller 31 disposed so that its peripheral surface is in contact with the conveying surface of the conveyor belt. And the sheet | seat S punched by the punching process part 3 is conveyed by the conveyor belt 30 and the conveyance roller 31, and is discharged | emitted from the discharge port of a rotary punching machine.

As mentioned above, although the structure of this invention was demonstrated based on the preferable Example, the structure of this invention is not limited to the said Example, Various within the range of the structure described in the claim of this application It goes without saying that variations can be devised.
For example, in the said Example, although the adsorption conveyance unit 6 was comprised from the suction belt conveyors 6a-6d, a well-known suction rotor, a suction cup type conveyance unit, etc. are employ | adopted instead of the suction belt conveyors 6a-6d. You can also.

  In the above embodiment, a servo motor is employed as the first drive mechanism for rotating the conveying roller pair 23a, 23b, and a normal motor 19 is employed as the second drive mechanism for rotating the pair of the processing roller 16 and the receiving roller 17. Although the rotary encoder 22 is used together to detect the rotational position of the roller, a servo motor or a stepping motor can also be used for both the first and second drive mechanisms.

DESCRIPTION OF SYMBOLS 1 Paper feed part 1a Sheet stacking shelf 1b Sheet alignment board 2 Conveyance part (suction belt conveyor)
3 punching unit 4 discharge unit 5 control unit 6 suction conveyance unit 6a, 6b roller 6c endless belt 6d suction duct 6e paper feed roller pair 7a, 7b roller 8 first pulley 9 touch panel display 10 endless belt 11 motor 12 second Pulley 13 endless belt 14 suction duct 15 intake pump 16 processing roller 17 receiving roller 18 third pulley 19 motor 19a fourth pulley 20 first timing belt 21 fifth pulley 22 rotary encoders 23a and 23b conveying roller pair 24 Sixth pulley 25 Servo motor 25a Seventh pulley 26 Blade type 27 Second timing belt 28, 29 Sensor 30 Conveyor belt 31 Conveying roller 32 Support plate P Sheet stack S Sheet G Punching range Q Processing The lowest point of over La

Claims (3)

A sheet feeding unit that supplies sheets one by one from the sheet stack at a predetermined timing;
A punching unit for punching a sheet supplied from the paper feeding unit;
A conveying unit that extends between the paper feeding unit and the punching processing unit and conveys the sheet received from the paper feeding unit to the punching processing unit while correcting skew feeding; and
A control unit that controls operations of the sheet feeding unit, the punching unit, and the transport unit,
The paper feeder is
A suction conveyance unit that is disposed above the sheet stack and sequentially sucks the uppermost sheet of the sheet stack at the timing and sends the sheet from the sheet outlet to the conveyance unit;
The punched portion is
A processing roller extending perpendicular to the sheet conveying direction;
A receiving roller arranged in parallel to the processing roller and facing the peripheral surface of the processing roller at a certain distance from the peripheral surface;
A blade mold mounted on the peripheral surface of the processing roller;
A first drive mechanism for synchronously rotating the processing roller and the receiving roller at a constant peripheral speed equal to each other;
A pair of conveying rollers disposed upstream of the pair of processing rollers and the receiving roller and spaced from the pair, and extending parallel to the pair of processing rollers and the receiving roller;
A second drive mechanism for rotating the pair of transport rollers,
The processing roller and the receiving roller always rotate in a direction in which the sheet is introduced from the conveyance roller pair, and the sheet introduced into the gap between the conveyance roller pair from the conveyance unit is moved by the conveyance roller pair. And is conveyed through the gap between the receiving rollers, and is punched by the blade mold in the meantime,
The punching section further includes:
A sensor that is disposed between the processing roller and the pair of conveyance rollers and that detects passage of a front end of the sheet;
When the first sheet is supplied from the sheet stack by the sheet feeding unit, the control unit measures the time from the start of operation of the suction conveyance unit until the front end of the first sheet passes the sensor, Based on the deviation of the measured value from the set value, the timing of sheet supply by the sheet feeding unit is corrected,
The second and subsequent sheets are supplied by the sheet feeding unit at the timing after the correction, and the rotation of the pair of conveying rollers is triggered by the detection signal from the sensor as a peripheral speed and rotation of the blade type. A rotary punching machine controlled according to a position, wherein a front end of a punching range of a sheet is made to coincide with a front end of the blade die at the lowest point of the processing roller. Another sensor disposed between the sheet outlet of the sheet feeding unit and the entrance of the conveying unit, and further detecting the passage of the front end of the sheet;
Each time the second and subsequent sheets are supplied by the sheet feeding unit, the time from the start of operation of the suction conveyance unit until the front edge of the related sheet passes the other sensor is measured, and the setting of the measurement value is performed. When the deviation from the value exceeds a predetermined range, the next sheet feeding by the sheet feeding unit is skipped, and during that time, when the related sheet is detected by the sensor, the conveyance is performed. After the operation of the roller pair is temporarily stopped, at the timing when the sheet is detected by the sensor when the sheet supply is not skipped, the conveyance roller pair starts the operation again, and the conveyance roller pair Is controlled in accordance with the peripheral speed and rotational position of the blade die, and the front end of the sheet punching range is the front end of the blade die at the lowest point of the processing roller. Rotary punching machine according to claim 1, characterized in that it is matched allowed. The paper feeder is
A sheet stacking shelf that is arranged to be movable up and down and on which a sheet stack is placed;
A vertical sheet alignment plate disposed in front of the sheet stacking shelf;
A lifting unit for lifting and lowering the sheet stacking shelf;
A height detection sensor for detecting the height of the sheet stack on the sheet stacking shelf, and based on a detection signal from the height detection sensor, each time the height of the sheet stack decreases by a certain amount, The sheet stacking shelf rises by a corresponding amount,
The suction conveyance unit of the paper feed unit is
Above the sheet stack on the sheet stacking shelf, it is composed of a horizontal suction conveyor belt that extends forward from the front end portion of the sheet stack beyond the sheet aligning plate, and the suction belt conveyor is configured to supply the sheet at a timing. 3. The rotary punching machine according to claim 1, wherein the uppermost sheet of the sheet stack is fed forward through the sheet aligning plate while adsorbing an upper surface thereof. .

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