KR200365652Y1 - Automatic register lontroller of prints equipment - Google Patents

Abstract

The present invention is a method for automatically adjusting registers and touches for correcting and correcting errors by automatically detecting errors in registers generated by printing a pattern on a printing film by overlapping colors and colors performed in a multicolor gravure printing process. An apparatus is disclosed that allows the use of a screen to quickly adjust the register of a printout. It is possible to observe the waveform for one period, so that anyone can easily set the gate address so that the register error can be adjusted automatically, and the graphic user interface is introduced in the touch monitor for easy understanding. The dual monitors enable the use of two systems with one system. In addition, it is possible to maintain cleanliness in the organic solvent by using an ultrasonic touch monitor, and there is no electrical contact.

Description

Automatic register lontroller of prints equipment

The present invention relates to a method for automatically adjusting a register of a printed matter and a device thereof, and more particularly, to automatically correct an error of a register generated in the process of printing a pattern on a printing film by overlapping a color and a color performed in a multicolor gravure printing process. The present invention relates to a method for automatically adjusting a register of a printed matter to be corrected by detecting the error and to correct an error, and a device for quickly adjusting a register of a printed matter using a touch screen.

In general, the tubular film used for various printed materials such as confectionery bags and wrapping papers is printed in a gravure printing process using various colors with various patterns and symbols. However, even if the film fabric supplied to the printing apparatus is normally supplied in the printing process, the position of the film fabric is separated from the set position in the printing process, thereby causing a problem in that print quality is deteriorated.

That is, in the case of printing 8 degrees on the film fabric while the film fabric of one roller is supplied for the gravure printing process, one unit (printer) per 1 degree is required so that 8 units operate. At this time, the film fabric supplied to each unit for printing is printed with the color set in the unit. Therefore, the film fabric automatically supplied to each unit must be exactly matched to the set position to complete printing of 8 degree color normally in each unit. However, since the material of the film fabric supplied and printed in the printing process is a kind of synthetic resin, mainly composed of PVC, PP, and PE, the film fabric is soft and causes stress such as stress applied from the supply roller in the process of being supplied to each unit. As a result, the film fabric is partially stretched, causing a register error. That is, since a plurality of guide rolls and dryers pass through, shrinkage and expansion of the printed matter occur, and a slight change in the length of the printed matter occurs due to slips generated in the guide roll and the pressure and tension changes between the respective pulsating plates. However, if these small changes are constant and driven by the same prime mover and the copper plates operate in perfect synchronization, the error of the register is not a problem, but if the length of the printed material changes until reaching the unit after printing in one unit, Since an error occurs, the error of the register must be detected and corrected.

1 is a diagram illustrating an example for explaining a method of detecting an error of a conventional register.

Referring to FIG. 1, when a user detects a register error, a register mark called ordinary registration (1) (2), which is difficult to identify in printing, is put in various colors and compared and examined to identify the error. . The dome beam 1 is a dome beam displayed at 1 degree in the printing process, and the dome beam 2 is determined when the dome beam is displayed at 2 degrees. When the dome beam 1 and the dome beam 2 fit together, printing is performed. Is said to be a perfect match. Therefore, as shown in the figure, an error occurs when the dome 1 and the dome 2 do not coincide with each other. That is, it is confirmed that the amount of error in the horizontal line is the error amount in the longitudinal direction, and the amount of error in the vertical line is the error amount in the horizontal direction. When such a register error occurs, the user corrects the amount of error immediately generated.

To correct such a register error, the user makes a correction while watching the pulse displayed on the oscilloscope. However, since the pulses appearing on the oscilloscope are displayed as they move continuously, it is difficult to set the gate address of the system while viewing the pulses that move continuously. In addition, when operating fewer units based on eight units in a limited space, the front part of the empty unit should be blocked, and in case of more than eight units, a main body needs to be added, which makes it difficult to add or subtract units. In addition, when correcting a resistor error while looking at the pulse displayed on the oscilloscope, the electrical contact of the switches causes contact failure due to contamination of dust, etc., resulting in inconvenient operation of the system. .

The present invention was devised to solve the above problems, and the object of the present invention is to quickly detect and correct an error of a register generated in the process of printing a picture by overlapping color and color in a multicolor gravure printing process. It is to provide the fixing according to the register automatic adjustment method of the printed matter.

Another object of the present invention is to provide an automatic register regulating apparatus for adjusting a register of a printed matter using a touch screen suitable for realizing the above method.

In order to achieve the above object, the present invention is a printing system having a unit consisting of a top and bottom motor, a left and right motor, a dryer, a scanning head, a pulse generator and a copper plate for performing multi-color gravure printing, which is applied from a scanning head and a pulse generator. A microcomputer for receiving data through a primary comparator, an amplifier and a secondary comparator, an oscilloscope for comparing the data applied from the scanning head and the pulse controller with the oscilloscope for transmitting the data to the fish, and the data applied from the microcomputer. A register comprising a controller for comparatively analyzing and applying the fish, a fish for storing and comparing the data applied from the fish, applying the displayed data to the touch monitor, and a touch monitor displaying the data applied from the fish. Provide automatic adjustment device.

1 is a diagram illustrating an example for explaining a method of detecting an error of a conventional register.

2 is a view showing an example for explaining a method for detecting an error of a register according to the present invention.

3 is a view schematically showing an apparatus for detecting an error of a register according to the present invention.

4A and 4B illustrate an embodiment of detecting an error of a register from a register mark according to the present invention.

5 is a view schematically showing an apparatus for detecting and correcting a register error of the present invention.

6 is a flowchart illustrating an embodiment of detecting and correcting a register error according to the present invention.

7 to 9 are views showing a state displayed on the touch monitor according to the present invention.

FIG. 10 is a view illustrating a state in which a tool for setting various data is displayed on a touch monitor in the case of printing at 9 degrees according to the present invention.

<Brief description of symbols for the main parts of the drawings>

M: Up / down motor P / G: Pulse generator S / H: Scanning head

SM: Left and Right Motor 10: Central Control 20: Touch Monitor

Hereinafter, the present invention with reference to the accompanying drawings as follows.

2 is a diagram illustrating an example for explaining a method of detecting an error of a register according to the present invention.

Referring to Fig. 2, the register marks are arranged in the longitudinal direction, and 1 degree, 2 degrees in the vertical direction with respect to the advancing direction of the printed matter (fabric). The n-degree register mark is printed at 20mm intervals. At this time, if the register mark has a gap of 20 mm, if there is no error, the register mark is changed to 19.5 mm or 20.5 mm, and a register error of ± 0.5 mm is detected. In addition, if an error occurs to the left or right from the vertical line of the register mark being printed in the left and right direction, the interval between the inclined portions of the register mark is changed, so that this change is detected and becomes a register error in the left and right direction. Scanning heads and pulse generators are responsible for detecting register errors from these register marks.

3 is a view schematically showing an apparatus for detecting an error of a register according to the present invention.

Referring to FIG. 3, the scanning head S / H performs a function of detecting a register mark and is installed near the bottom of the dryer so as to be detected immediately after printing of each unit. Only one pulse generator (P / G) is installed in one printing press, and performs a function of distinguishing a printed register mark from another printing, and the scanning head (S / H) and the pulse generator (P / G) In combination, the register error is detected and only the register mark is applied to the central control control 10.

The scanning head S / H includes two lenses and a photodiode (not shown) with respect to one light source lamp (not shown), and a reflecting plate R / installed at a position opposite to the scanning head S / H. It is configured to focus two points on P) and receive them on each of the two photodiodes. When each register mark passes through the two focal planes, a change of light appears in each photodiode, and the change of light is converted into a current pulse and applied to the controller 11. When the current pulse is generated in two photodiodes at the same time, the register error in the vertical direction and the left and right directions becomes zero. On the contrary, if there is a time difference between the up edges of the current pulses, an error in the up and down directions occurs. When a time difference occurs in the down edges, a resistor error occurs in the left and right directions.

4A and 4B illustrate an embodiment of detecting an error of a register from a register mark according to the present invention, and FIG. 5 schematically illustrates an apparatus for detecting and correcting a register error of the present invention.

Referring to FIGS. 4A, 4B, and 5, if a pulse of the next register mark occurs before the reference pulse of the register mark for detecting the register error, it corresponds to an error of forward (up and down) and right (left and right) directions. If the pulse of the next register mark occurs later than the reference pulse of the reference register mark, it corresponds to the error of retreat (up-down direction) and left (left-right direction). In this case, when the amount and direction of the upper and lower registers are Ev, and the amount and direction of the left and right registers are Eh, the left and right error amounts can be calculated from the equation Eh = (Ed-Ev) tan.

However, if there is another mark other than the above-mentioned register mark, the same shape pulse appears depending on the shape of the printing, and it is impossible to distinguish between the register mark pulse and the printing pulse. Thus, by operating the selection unit, the pulse generator can distinguish between printing and mark pulses.

That is, the pulse generator is rotated like a printed copper plate to generate 1000 pulses during one rotation, and the position of this pulse is synchronized with the position of the register mark by touching the gate shift key in the selection unit. The other part is turned off, and the part of this on can be set freely. In addition, when the copper plate rotates to print a register mark and exit to the position of the scanning head S / H, the switch can be switched on, and can be switched off when other printing pulses.

In addition, the controller 11 receives a pulse signal of a register mark from the scanning head S / H and the pulse generator P / G, and displays the presence or absence of a register error and the error amount and direction according to the pulse. The data is analyzed and the correct data on the generated register error is transmitted to the touch monitor 20 through a PC and displayed. In addition, when the data is stored, and a change amount of the error is detected each time to instruct a correction amount, the change is added and calculated, a proper correction amount is selected to quickly eliminate hunting, and the error is always zero. It sends a correction signal to the outside so that it can be kept in the) state.

In addition, the fish 12 processes and manages and stores various data and calculations based on the parameter values of the system, and may be implemented in the touch monitor 20, and the data may be stored through a controller and a dual port memory. Always send and receive

In addition, the touch monitor 20 can be easily operated / operated by implementing an ultrasonic touch monitor and a graphic user interface, and inputs the size of a cylinder, parameter values of a printer and a system, and displays an error and an operation state. To check.

Hereinafter, the present invention will be described in more detail with reference to the following examples.

6 is a flowchart illustrating an embodiment of detecting and correcting a register error according to the present invention.

Referring to FIG. 6, in the tenth step S10, the interrupt and input / output ports are initialized. After the tenth step S10, reference data is input in a twelfth step S12. That is, data such as cylinder size, amplification degree (T1, T2), mark type, fine adjustment data (up, down, left and right), and minimum speed are stored in the controller 10 in advance. After the twelfth step S12, it is determined whether the channel is used in the fourteenth step S14. If the channel is used, the A system or the B system in the sixteenth step S16 to the twentieth step S20. To operate. The A system or B system represents a large unit system for performing a printing process, and there are units in the A system or B system, respectively, and typically only two systems are installed.

After the sixteenth step (S16) to the twentieth step (S20), in the twenty-second step (S22) it is determined whether the remote controller that the user adjusts remotely is used. If the remote controller is used in the twenty-second step S22, interrupt enable is performed (S24). If the remote controller is not used, interrupt disable is performed (S26). The remote control may directly transmit and receive data with the fish remotely.

After the twenty-sixth step (S26), it is determined whether or not the minimum speed or more (S28), and if the printing speed is more than the minimum speed or not (S29). If an error occurs in the twenty-ninth step S29, the photodiode is controlled to perform an operation (S30), and then data is displayed on the fish 12 (S32).

In addition, if all autos are performed in the thirty-fourth step S34, the register error is corrected in the thirty-sixth steps S36 to 44, and then the fourteenth step S14 is repeatedly executed.

7 to 9 are views showing a state displayed on the touch monitor according to the present invention.

7 to 9, the initial setting icon 70 selects this icon before printing and sets the separation, mark method, mark type, and copper plate size. The preset operation icon 72 selects this icon when the initial setting is completed and starts presetting. The oscillator indicator icon 74 selects this icon after completion of the above setting and starts printing. The waveform of the register mark appears. If you touch the full auto on / off icon 76, the background color changes from red to green and all the motors will operate. Touching the alarm on / off icon 78 changes the background color from red to green and a buzzer sounds when an error occurs.

FIG. 10 is a view illustrating a state in which a tool for setting various data is displayed on a touch monitor in the case of printing at 9 degrees according to the present invention. Referring to FIG. 10, ① and ② are icons used for setting separate printing methods. Touch 6 to start printing the B system from 6 units. Touch 2 to print only the A system. Touch No. 9 to print only with B system. Also, ③ is an icon used for setting the register mark type, and is selected by touching the shape of the register mark shown on the scanning head.

④ is an icon used to set the mark progression method. It is selected by touching the FOR (forward) and reverse (REV) directions. When the register mark array is vertical, the upper mark is the forward mark and the lower mark is the reverse mark. If the array of register marks is horizontal, the left side is the forward mark and the right side is the reverse mark. And to control only one register mark, it can be selected by touching the original mark. (5) is a copper plate size input icon. After inputting the copper plate size with 10 numeric keys, the diameter and the circumference of the copper plate can be input by touching the enter icon.

As can be seen from the above description, the present invention can observe the waveform for one period, and anyone can easily set the gate address so that the register error can be automatically adjusted, and the graphic user interface on the touch monitor can be used. It can be easily understood by introducing a dual touch system using a fish-based serial gun, so the effect of two systems can be achieved with one system. In addition, it is possible to maintain cleanliness in the organic solvent by using an ultrasonic touch monitor, and there is no electrical contact.

Claims (3)

In the register automatic control of the printed matter for performing multicolor gravure printing, A microcomputer that receives data transmitted from the scanning head and the pulse generator to detect a register error; A controller for analyzing the presence or absence of a register error, the amount of error and the direction thereof, using the data transmitted from the microcomputer; A PC for receiving accurate information on the register error received from the controller, processing and managing and storing various data and operations by the parameter values of each component; An oscilloscope configured to compare the data transmitted from the scanning head and the pulse generator to transmit the waveform generated to the fish; And And a touch monitor for displaying the data received from the fish. The method of claim 1, wherein the touch monitor comprises a separate printing method setting icon for setting various data, an icon used for setting register mark type, an icon used for setting mark progress method, and an icon for inputting copper plate size. And an icon operable by the user when a register error occurs. The touch monitor of claim 1, wherein the register error detected by the scanning head and the pulse generator detects up, down, left, and right directions of a register mark, and the oscilloscope compares and analyzes the detected register error. Automatic registration device of the printed material, characterized in that displayed on.