JP2006103809A - Continuous paper post-processing device and continuous paper post-processing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a continuous paper post-processing device and a continuous paper post-processing method for giving proper tension to a continuous paper by setting the optimum feed rate corresponding to each of issuing speeds of the continuous paper from each printer even when connecting the device with a printer having different issuing speeds for use and preventing improper printing, printing elongation, and running-out of paper. <P>SOLUTION: A rotation speed setting part 13 sets rotation speed based on the inputted travel time between sensors when inputting the travel time between the sensors from an arm position recognizing part 11 and a rotation speed table stored in a rotation speed storing part 12 to inform a motor driving part 14 of the set rotation speed. The motor driving part 14 drives a winding motor 15 at the rotation speed informed by the rotation speed setting part 13 when inputting the lowermost part detection signal from the arm position recognizing part 11 and informing the rotation speed from the arm position recognizing part 11. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention provides post-processing of continuous paper issued from a printer (a label continuous body in which labels are temporarily attached to a belt-like backing sheet at intervals, a label continuous body in which labels are connected at perforations, a belt-like paper, etc.) In particular, the present invention relates to a continuous paper post-processing apparatus and a continuous paper post-processing method having tension applying means for applying tension to continuous paper issued from a printer.

  As a continuous paper post-processing device that processes continuous paper issued from a printer, a winding device that winds continuous paper issued from a printer, a stacker device that stacks continuous paper issued from a printer (stacker, auto stacker, And a peeling device that peels a label issued from a printer from a belt-like mount.

  In such a continuous paper post-processing apparatus, continuous paper feeding means such as a winding means for winding the continuous paper issued from the printer and a conveying means for conveying the continuous paper to the stacking position or the peeling position are provided. If the tension applied to the continuous paper by the feeding means is small, the continuous paper may float at the printer's issuing port and print defects such as misalignment or overlap may occur, and if the tension is large, the tension arm is positioned at the top. Even if it stops, it does not stop immediately due to inertia, and there is a possibility that the printing will be extended or the paper may run out. Therefore, it is necessary to apply an appropriate tension to the continuous paper issued from the printer.

  Therefore, a tension arm (buffer arm) is provided upstream of the continuous paper feeding means. One end is swingably attached to the arm shaft and a tension roller that abuts the continuous paper from above is attached to the other end. The tension arm raises and lowers in proportion to the difference between the issuance speed and the feeding speed from the printer, thereby giving an appropriate tension to the continuous paper issued from the printer.

  The continuous paper feeding means is controlled by the position of the tension arm. For example, ON / OFF control that starts feeding when the tension arm reaches the bottom and stops feeding when the tension arm reaches the top, or the tension arm reaches the target position. The feed speed control for changing the feed speed for each position of the tension arm is performed (see, for example, Patent Document 1).

  However, in the prior art in which ON / OFF control is performed according to the position of the tension arm, the continuous paper feed speed by the continuous paper feed means is fixed, or the feed speed is set by a human switch using a manual switch. Therefore, when connected to a printer with a different issue speed, the optimum feed speed corresponding to the issue speed of the continuous paper is not necessarily set from the printer, and appropriate tension can be applied to the continuous paper. There is a risk that printing failure will occur due to the tension applied to the continuous paper being too small, and there is a risk that print extension and paper cutting will occur due to the tension applied to the continuous paper being too large. There was a problem.

Also, in the conventional technology that controls the feed speed that changes the feed speed for each tension arm position, the feed speed for each tension arm position is fixed. However, it is not always possible to set the optimum feed speed corresponding to the continuous paper issuance speed from the printer, it becomes impossible to apply an appropriate tension to the continuous paper, and the printing failure due to the tension applied to the continuous paper being too small. And there is a problem that print extension and out of paper may occur due to excessive tension applied to the continuous paper.
JP 2003-261121 A

  The present invention has been made in view of such problems, and the object of the present invention is to respond to the continuous paper issue speeds from each printer even when connected to printers with different issue speeds. By setting the optimum feeding speed, it is possible to apply an appropriate tension to continuous paper, printing defects caused by too little tension applied to continuous paper, and too much tension applied to continuous paper. Accordingly, the present invention is to provide a continuous paper post-processing apparatus and a continuous paper post-processing method capable of preventing the printing extension and the paper shortage caused by the above.

In order to solve the above problems, the present invention has the following configurations.
The gist of the invention described in claim 1 is a continuous paper post-processing device in which tension applying means for applying tension to the continuous paper is provided upstream of the continuous paper feeding means for feeding continuous paper issued from a printer. A position detection sensor that detects the tension applying means at a plurality of detection positions within a movement range of the tension applying means, and an arm position recognition that measures the time required to move between the plurality of detection positions as a movement time between the sensors. And a feed speed setting means for setting the feed speed of the continuous paper by the continuous paper feed means based on the movement time between the sensors measured by the arm position recognition means. It exists in an aftertreatment device.
According to a second aspect of the present invention, the arm position recognizing unit measures the movement time between the sensors while the continuous paper feeding operation by the continuous paper feeding unit is stopped. It exists in the continuous paper post-processing apparatus of Claim 1.
According to a third aspect of the present invention, there is provided a rotational speed storage means for storing a rotational speed table in which the inter-sensor movement time and the feed speed are associated with each other, and the speed setting means includes the sensor The continuous paper post-processing apparatus according to claim 1, wherein the feed speed is set based on an intermediate movement time and the rotation speed table.
According to a fourth aspect of the present invention, the continuous paper feeding means is a take-up shaft for winding the continuous paper, and the tension applying means is attached to an arm shaft so that one end thereof is swingable. 4. The continuous paper post-processing apparatus according to claim 1, wherein the tension roller that contacts the continuous paper is a tension arm attached to the other end.
According to a fifth aspect of the present invention, there is provided a continuous paper post-processing method for feeding a continuous paper issued from a printer while applying tension to the continuous paper by a tension applying unit, wherein a plurality of detection positions within a moving range of the tension applying unit. The tension applying means is detected, and the time required for movement between the plurality of detection positions is measured as the movement time between sensors, and the feed speed of the continuous paper is set based on the measured movement time between the sensors. The present invention resides in a continuous paper post-processing method.

  The continuous paper post-processing apparatus and continuous paper post-processing method of the present invention detects the tension applying means at a plurality of detection positions within the movement range of the tension applying means, and determines the time required for movement between the plurality of detection positions between the sensors. By measuring the movement time and setting the continuous paper feed speed based on the measured movement time between sensors, even when connected to a printer with a different issue speed, the movement time between sensors is reduced. Based on this, the printer issuance speed is estimated, and by setting the feed speed according to the continuous paper issuance speed from the printer, an appropriate tension can be applied to the continuous paper, and the tension applied to the continuous paper is small. It is possible to prevent printing failure due to being too large, printing extension and paper cutting due to excessive tension applied to continuous paper. To.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

(This embodiment)
FIG. 1 is a schematic perspective view showing a configuration of an embodiment of a continuous paper post-processing apparatus according to the present invention, and FIG. 2 is a schematic diagram for explaining an operation of a tension arm shown in FIG. 3 is a schematic diagram showing a sensor mechanism attached to the arm shown in FIG. 1, and FIG. 4 is a block diagram showing a configuration of a control unit in the embodiment of the continuous paper post-processing apparatus according to the present invention.
It is.

  The continuous paper post-processing apparatus of the present embodiment is a continuous label such as a label continuous body in which labels are temporarily attached to a belt-like mount, and continuous labels such as a label continuous body, a belt-like paper, etc. A take-up device connected to a printer that performs printing and takes up the continuous paper 1 issued from the printer. Referring to FIGS. 1 and 2, a take-up shaft 2 that takes up the continuous paper 1 issued from the printer; The first guide roller 3 and the second guide roller 4 that are arranged on the upstream side of the take-up shaft 2 and guide the conveyance of the continuous paper 1, and the first guide roller 3 that is arranged on the upstream side of the take-up shaft 2 The tension arm 5 is a tension arm 5 that is a tension applying means for applying tension to the continuous paper 1 in contact with the continuous paper 1 spanned between the second guide roller 4. With swingably attached to, the tension roller 52 abuts from above the paper web is attached to the other end.

  In the present embodiment, as shown in FIG. 2, the tension arm 5 abuts the continuous paper 1 spanned between the first guide roller 3 and the second guide roller 4 from above, and The tension arm 5 (tension roller 52) is configured to be tensioned by an urging means such as its own weight or a spring that urges the tension arm 5 downward (clockwise in FIG. 2). Is increased and decreased in proportion to the difference between the issue speed of the continuous paper 1 from the printer and the take-up speed of the take-up shaft 2. Reference numeral 6 shown in FIG. 2 is a paper tube for winding the continuous paper 1.

The position of the tension arm 5, as shown in FIG. 2, are detected at a plurality of positions (n) from the detection position A ₁ is a top to a bottom detection position A _{n (n} = 2 or more) It is configured as follows. In the present embodiment, is configured to detect the position of the tension arm 5 at four points from the detection position A ₁ is a top detector to the position A ₄ is a bottom, adjacent the detection position (A ₁ , A ₂ , A ₃ , A ₄ ) (the movement distances L ₁ , L ₂ , L ₃ ) of the tension roller 52 are set to the same distance. The uppermost part and the lowermost part do not mean the upper limit and the lower limit of the swing range of the tension arm 5, but mean the uppermost part and the lowermost part in the position detection of the tension arm 5, respectively.

  For example, referring to FIG. 3, the detection of the position of the tension arm 5 is a disc-shaped sensor plate 53 that is assembled to the arm shaft 51 and rotates as the tension arm 5 swings, and a peripheral portion of the sensor plate 53. This is performed by the first position detection sensor 7 and the second position detection sensor 8 which are arranged at different positions in the movement path of the first groove portion 54 and the second groove portion 55 formed in the above. In addition, as the first position detection sensor 7 and the second position detection sensor 8, an optical sensor such as a light reflection sensor or a light transmission sensor may be used, or other sensors such as a magnetic sensor may be used. In the present embodiment, when the first groove portion 54 and the second groove portion 55 come to the positions of the first position detection sensor 7 and the second position detection sensor 8, respectively, the first position detection sensor 7 and the second position detection sensor are detected. Assume that the sensor 8 is turned on.

In FIG. 3 (a), in which to position the tension arm 5 at the detection position A ₁ is a top, the second position detecting sensor 8 is in the OFF state, the first position detection sensor 7 is ON by the first groove 54 the / OFF is the fact, the tension arm 5 can be detected that has reached the detection position a ₁ is a top.

In FIG. 3B, the tension arm 5 is located at the detection position A ₂ below the uppermost part, the first position detection sensor 7 is ON, and the second position detection sensor 8 is the second position. by being turned oN / OFF by the groove 55, it is possible to detect that the tension arm 5 has reached the detection position a _2.

Further, in FIG. 3 (c), the detection position A ₃ in the lower A ₂ is located tension arm 5, the second position detecting sensor 8 is in the state ON, the first position detection sensor 7 is first by being turned oN / OFF by the groove 54, it is possible to detect that the tension arm 5 has reached the detection position a _3.

Further, in FIG. 3 (d), the tension arm 5 at the detection position A ₄ at the bottom is located at a first position detecting sensor 7 is in OFF state, the second position detecting sensor 8 and the second groove part 55 by being turned oN / OFF, it is possible to detect that the tension arm 5 has reached the detection position a ₄ at the bottom.

  Referring to FIG. 4, the control unit that controls the rotation speed of the winding shaft 2, that is, the winding speed, is based on the ON / OFF state of the first position detection sensor 7 and the second position detection sensor 8. An arm position recognition unit 11 for recognizing the position, a rotation speed storage unit 12 in which a rotation speed corresponding to the movement time between sensors, which is the movement time between the detection positions of the tension arm 5, and the rotation of the winding shaft 2 are stored. The rotation speed setting unit 13 sets the speed, and the motor drive unit 14 drives the winding motor 15 that rotates the winding shaft 2 at the rotation speed set by the rotation speed setting unit 13.

Arm position recognizing section 11 recognizes that it has reached the detection position A ₁ is a top, outputs a top detection signal to the motor driver 14, that has reached the detection position A ₄ is a bottom When recognized, the lowermost detection signal is output to the motor drive unit 14. The arm position recognition section 11, until recognizing that it has reached after recognizing that it has reached the detection position A ₄ is a bottom at the detection position A ₁ is a top, i.e. the take-up motor 15 During the stop, the detection positions (A ₁ , A ₂ , A ₃ , A ₄ ) of the tension arm 5 that swings based on the ON / OFF state of the first position detection sensor 7 and the second position detection sensor 8 are recognized. Then, the inter-sensor movement time required for moving to the adjacent detection position is measured and output to the rotation speed setting unit 13.

The rotation speed storage unit 12 stores a rotation speed table in which the movement time between sensors and the rotation speed of the winding shaft 2 are associated with each other. The rotational speed of the take-up shaft 2 depends on the distance between adjacent detection positions (A ₁ , A ₂ , A ₃ , A ₄ ) (movement distances L ₁ , L ₂ , L ₃ ) of the tension roller 52 and the sensor. The printer is set based on the printer issuance speed estimated from the travel time, and the estimated printer issuance speed and winding speed are set to be substantially the same.

  The rotation speed setting unit 13 sets the rotation speed based on the inter-sensor movement time input from the arm position recognition unit 11 and the rotation speed table stored in the rotation speed storage unit 12, and sets the set rotation speed to the motor. Notify the drive unit 14. When a plurality of inter-sensor movement times are input, an average time of the input inter-sensor movement times is calculated, and the average time and the rotation speed table stored in the rotation speed storage unit 12 are calculated. Set the rotation speed based on this.

  When the lowermost detection signal is input from the arm position recognition unit 11, the motor drive unit 14 drives the winding motor 15 at the rotation speed set by the rotation speed setting unit 13 and from the arm position recognition unit 11 to the lowest position. When the lower detection signal is input, the driving of the winding motor 15 is stopped.

Next, the operation of the present embodiment will be described in detail with reference to FIG.
FIG. 5 is a flowchart for explaining the operation of the embodiment of the continuous paper post-processing apparatus according to the present invention.

When a winding start is instructed by a power button or an input switch (not shown), the motor driving unit 14 stands by in a state where the winding motor 15 is stopped (step A1), and the arm position recognizing unit 11 includes the tension arm 5. Is detected (step A2), and issuance of the continuous paper 1 from the printer is started, the tension arm 5 is lowered, and it is recognized that the tension arm 5 has reached the detection position. it is equal to or a detection position a ₄ of the bottom (step A3).

When recognized detected position is not detected position A ₄ of the lowermost arm position recognition unit 11 further monitors the arrival of the next detected position of the tension arm 5 (step A4), the tension arm 5 is the following with measuring the sensor between time to reach the detection position (step A5), it recognized the next detection position it is determined whether or not the detection position a ₄ of the bottom (step A6), recognized the following position detection repeats step A4 and step A5 until the detection position a ₄ at the bottom.

When recognized next detection position is a detection position A ₄ of the bottom in step A6, the arm position recognition unit 11 outputs the bottom detection signal to the motor driver 14, travel time between the measured sensor Is output to the rotation speed setting unit 13.

  When the inter-sensor movement time is input from the arm position recognition unit 11, the rotation speed setting unit 13 rotates based on the input inter-sensor movement time and the rotation speed table stored in the rotation speed storage unit 12. Is set, and the set rotation speed is notified to the motor drive unit 14 (step A7).

When the lowermost detection signal is input from the arm position recognizing unit 11 and the rotation speed is notified from the arm position recognizing unit 11, the motor driving unit 14 is wound at the rotation speed notified by the rotation speed setting unit 13. The motor 15 is driven (step A8), the arm position recognition unit 11 monitors the arrival of the tension arm 5 to the detection position (step A9), and the tension arm 5 is wound by the winding of the continuous paper 1 by the winding shaft 2. is increased, the tension arm 5 recognizes that reaches the detection position, recognized position detection it is determined whether the detected position a ₁ of the top (step A10), the detection recognized position detection of the uppermost repeating step A9 and step A10 until the position _{a 1.}

When recognized detected position is the detection position A ₁ of the top in step A10, the arm position recognition unit 11 outputs a top portion detection signal to the motor driver 14, motor driver 14, the arm position recognition When the uppermost detection signal is input from the unit 11, the driving of the winding motor 15 is stopped (step A1), and the processing of step A1 to step A10 is repeated thereafter.

Incidentally, it detects the position recognized in step A3 is the detection position A ₄ at the bottom, the addition time of the winding start, can not be envisaged, the detection position recognized in step A3 at the winding start outermost If the detection position a ₄ of the bottom, it is not possible to measure the travel time between the sensor, the motor driver 14, the bottom detection signal is input from the arm position recognizing section 11, are set in advance The rotation speed is set to the initial setting speed (step A11), and the process proceeds to step A8.

As described above, according to the present embodiment, the tension arm 5 is detected at a plurality of detection positions (A _{1 to} A _n ) within the movement range of the tension arm 5 and is necessary for movement between the plurality of detection positions. By measuring the measured time as the inter-sensor movement time and setting the continuous paper feed speed based on the measured inter-sensor movement time, even when connected to a printer with a different issue speed, Estimating the issuance speed of the printer based on the movement time between sensors without obtaining information on the issuance speed from the printer, and setting the rotation speed (winding speed) according to the issuance speed of the continuous paper 1 from the printer. Thus, it is possible to apply an appropriate tension to the continuous paper 1, print defects caused by the tension applied to the continuous paper 1 being too small, and tension applied to the continuous paper 1. There is an effect that it is possible to prevent the print extension and the paper shortage due to the excessively large amount of ink.

  In this embodiment, while the winding operation is continued, the sensor moving time is always measured to set the rotation speed, but the sensor moving time is measured only at the initial setting. The rotational speed may be set.

In the present embodiment, the rotation speed is set based on the movement time between sensors measured by the arm position recognition unit 11 and the rotation speed table stored in the rotation speed storage unit 12. The rotational speed is calculated based on the inter-sensor movement time measured by the arm position recognition unit 11, that is, the inter-sensor movement time S _m (m = n−1) between the adjacent detection positions (A _{1 to An} ). The winding motor 15 may be driven at the calculated rotation speed. That is, since the distance between the detection positions (A _{1 to An} ) adjacent to each other (the movement distance L _m of the tension roller 52) is known, the outline of the printer between the adjacent detection positions (A _{1 to An} ) is determined. The issuance speed can be calculated at 2L _m / S _m and the diameter of the take-up shaft 2 is also known, so the rotation speed is calculated so that the take-up speed is the approximate issuance speed of the calculated printer. can do.

  Further, in the present embodiment, the take-up device for winding the continuous paper 1 issued from the printer has been described. However, a stacker device (stacker, auto stacker, cutter stacker, etc.) for stacking the continuous paper 1 issued from the printer. The present invention can also be applied to other continuous paper post-processing devices such as a peeling device for peeling a label issued from a printer from a strip mount. In the stacker device and the peeling device, instead of the winding means (winding shaft 2) for winding the continuous paper 1 in the winding device, a transporting means for transporting to the stack position or the peeling position is provided. Then, the winding means and the conveying means are collectively referred to as a continuous paper feeding means, and the winding speed by the winding means and the conveying speed by the conveying means are collectively referred to as a feeding speed.

  Note that the present invention is not limited to the above-described embodiments, and it is obvious that the embodiments can be appropriately changed within the scope of the technical idea of the present invention. In addition, the number, position, shape, and the like of the constituent members are not limited to the above-described embodiment, and can be set to a suitable number, position, shape, and the like in practicing the present invention. In each figure, the same numerals are given to the same component.

It is a schematic perspective view which shows the structure of embodiment of the continuous paper post-processing apparatus which concerns on this invention. It is a schematic diagram for demonstrating operation | movement of the tension arm shown in FIG. It is a schematic diagram which shows the sensor mechanism attached to the arm shown in FIG. It is a block diagram which shows the structure of the control part in embodiment of the continuous paper post-processing apparatus which concerns on this invention. It is a flowchart for demonstrating operation | movement of embodiment of the continuous paper post-processing apparatus based on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Continuous paper 2 Winding shaft 3 1st guide roller 4 2nd guide roller 5 Tension arm 6 Paper tube 7 1st position detection sensor 8 2nd position detection sensor 11 Arm position recognition part 12 Rotation speed memory | storage part 13 Rotation speed setting part DESCRIPTION OF SYMBOLS 14 Motor drive part 15 Winding motor 51 Arm axis | shaft 52 Tension roller 53 Sensor board 54 1st groove part 55 2nd groove part

Claims (5)

A continuous paper post-processing device provided with tension applying means for applying tension to the continuous paper upstream of continuous paper feeding means for feeding continuous paper issued from a printer,
A position detection sensor for detecting the tension applying means at a plurality of detection positions within a movement range of the tension applying means;
Arm position recognition means for measuring the time required for movement between the plurality of detection positions as movement time between sensors;
A continuous paper post-processing device, comprising: a feed speed setting means for setting a feed speed of the continuous paper by the continuous paper feed means based on the movement time between the sensors measured by the arm position recognizing means. .   2. The continuous paper post-processing apparatus according to claim 1, wherein the arm position recognizing unit measures the movement time between the sensors while the continuous paper feeding operation by the continuous paper feeding unit is stopped. A rotation speed storage means for storing a rotation speed table in which the movement time between the sensors and the feed speed are associated with each other;
The continuous paper post-processing apparatus according to claim 1, wherein the speed setting unit sets the feed speed based on the movement time between sensors and the rotation speed table. The continuous paper feeding means is a take-up shaft that winds the continuous paper,
2. The tension applying means according to claim 1, wherein the tension applying means is a tension arm having one end swingably attached to an arm shaft and a tension roller that contacts the continuous paper attached to the other end. 4. The continuous paper post-processing apparatus according to any one of 3 above. A continuous paper post-processing method for feeding a continuous paper issued from a printer while applying tension by a tension applying means,
Detecting the tension applying means at a plurality of detection positions within a movement range of the tension applying means;
Measure the time required for movement between the plurality of detection positions as the movement time between sensors,
A continuous paper post-processing method, wherein a feed speed of the continuous paper is set based on the measured movement time between the sensors.

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