CN114193551A - Table type plane digital die-cutting machine capable of realizing die-cutting force detection and calibration - Google Patents

Abstract

The invention discloses a table type plane digital die-cutting machine capable of realizing die-cutting force detection calibration, which comprises two oppositely arranged side wall plates, wherein a paper feeding transmission mechanism is arranged between the two side wall plates; and a working wallboard is also arranged between the two side wallboards, and a die cutting mechanism is arranged on the working wallboard. The invention can realize die cutting force calibration and facilitate die cutting in offices.

Description

Table type plane digital die-cutting machine capable of realizing die-cutting force detection and calibration

Technical Field

The invention belongs to the technical field of digital post-printing machinery, and relates to a table type plane digital die-cutting machine capable of realizing die-cutting force detection and calibration.

Background

Currently in the field of printed packaging, post-printing is essential. For the label manufacturing process, die cutting is a key process for ensuring the quality of labels. With the improvement of people's life, people have more and more requirements on personalized label packaging. Resulting in digital printing gradually replacing traditional printing in many printing companies. With the rapid advance of the digital printing scale, the corresponding post-printing process has to be digitalized in advance to meet the market demand. Currently, digital die-cutting equipment has been developed by many companies, and the digital die-cutting equipment is mainly developed for the subsequent process of digital printing, and can perform digital die-cutting in advance without plate making. The key of the digital die cutting is the die cutting force, if the die cutting force is not adjusted, the label is not cut due to the fact that the die cutting force is small, or the bottom layer material is cut due to the fact that the die cutting force is large. In addition, the general digital die cutting machine is mainly a wheel-rolling type digital die cutting machine, and the number of single sheets is very small. If office needs, die cutting is rarely performed on a single sheet of two sheets.

Disclosure of Invention

The invention aims to provide a table type plane digital die-cutting machine capable of realizing die-cutting force detection and calibration.

The technical scheme adopted by the invention is that the table type plane digital die-cutting machine capable of realizing die-cutting force detection calibration comprises two oppositely arranged side wall plates, and a paper feeding transmission mechanism is arranged between the two side wall plates; and a working wallboard is also arranged between the two side wallboards, and a die cutting mechanism is arranged on the working wallboard.

The invention is also characterized in that:

the paper feeding transmission mechanism comprises a driving paper feeding roller and a driven paper feeding roller which are arranged in parallel along the horizontal direction; the active paper feeding roller is connected with the side wall plate through a bearing I, a bearing seat and a bearing gland. The extension end of the driving paper feeding roller is provided with a duplex-tooth-shaped belt wheel, the duplex-tooth-shaped belt wheel is connected with a paper feeding driving tooth-shaped belt wheel on a paper feeding driving motor arranged on the side wall plate through a paper feeding driving tooth-shaped belt, and the duplex-tooth-shaped belt wheel is also connected with a paper feeding driven tooth-shaped belt wheel on a driven paper feeding roller through a paper feeding driven tooth-shaped belt.

Paper pressing wheel assemblies are arranged on the driving paper feeding roller and the driven paper feeding roller, and the paper pressing wheel assemblies are arranged on the side wall plate through paper pressing wheel supporting rods.

The die cutting mechanism comprises two transverse moving guide rails which are arranged on a working wallboard in parallel, the transverse moving guide rails are matched with a transverse moving sliding block, the transverse moving sliding block is connected with a transverse moving platform, an up-and-down moving motor base is arranged on the transverse moving platform, an up-and-down moving driving motor is arranged on the up-and-down moving motor base, a motor shaft of the up-and-down moving driving motor is connected with an up-and-down moving lead screw through a coupling, an up-and-down moving screw nut is arranged on the up-and-down moving lead screw in a matched mode, the up-and-down moving screw nut is arranged on a pressure sensor base, a pressure sensor is simultaneously arranged on the pressure sensor base, a die cutting tool assembly is arranged below the pressure sensor, and the die cutting tool assembly is connected with a die cutting tool clamping base through screws and is arranged on the transverse moving platform; the pressure sensor seat is installed on the up-and-down motion workbench, the back of the up-and-down motion workbench is provided with an up-and-down motion guide rail sliding block, and the up-and-down motion guide rail sliding block is matched with an up-and-down motion guide rail installed on the transverse motion platform.

The transverse motion platform is connected with a transverse motion connecting block, the transverse motion connecting block is connected to a transverse line motion toothed belt, and a transverse motor transmission toothed belt wheel is connected with a transverse motion medium belt wheel arranged on a transverse motion medium belt wheel shaft through a transverse motion toothed belt; the transverse motor transmission tooth belt wheel is arranged on a motor shaft of the transverse motion driving motor.

The side of the transverse motion platform is provided with a reflective photoelectric sensor, and one side of the working wallboard is provided with an array photoelectric sensor.

The invention has the beneficial effects that: the pressure sensor is arranged above the die-cutting rule, and the pressure sensor is pressed down to a die-cutting tool bit by a screw transmission mechanism driven by a servo motor. Therefore, the die cutting pressure of the die cutting tool bit after contacting the paper can be directly obtained by the pressure sensor, and the reliable die cutting pressure of different material specifications can be conveniently calibrated, so that the reliable die cutting effect is ensured. Meanwhile, the array photoelectric sensor is adopted to detect the deviation of the paper, and corresponding coordinate correction is carried out on die cutting through detecting the deviation degree, so that the die cutting quality is ensured.

Drawings

FIG. 1 is a left side view of the overall structure of a table-top digital die-cutting machine capable of detecting and calibrating die-cutting force according to the present invention;

FIG. 2 is a front view of the overall structure of a table-type digital die-cutting machine capable of detecting and calibrating die-cutting force according to the present invention;

FIG. 3 is a diagram of a paper feeding driving mechanism of a desktop digital flat die-cutting machine capable of detecting and calibrating die-cutting force according to the present invention;

FIG. 4 is a top view of the overall structure of a table-top digital die-cutting machine capable of detecting and calibrating die-cutting force according to the present invention;

fig. 5 is a die cutting mechanism diagram of the table-top digital die cutting machine capable of detecting and calibrating die cutting force according to the invention.

In the figure, 1-side wall plate, 2-platen supporting rod, 3-driving feed roller, 4-platen assembly, 5-coupling, 6-up-down motion driving motor, 7-up-down motion lead screw, 8-up-down motion motor base, 9-up-down motion screw, 10-up-down motion guide rail, 11-transverse motion slide block, 12-transverse motion guide rail, 13-transverse motion platform, 14-transverse motion motor base, 15-transverse motion toothed belt pressing sheet, 16-transverse motion connecting block, 17-transverse motor transmission toothed belt wheel, 18-transverse motion driving motor, 19-upper cover plate, 20-rear cover plate, 21-servo unit, 22-transverse motion toothed belt, 23-driven feed roller, 24-PLC controller, 25-die cutting table, 26-paper feeding driving motor, 27-up-down moving guide slider, 28-DC power supply, 29-front cover plate, 30-dual-tooth type belt wheel, 31-paper feeding driving tooth belt, 32-shaft sleeve, 33-bearing gland, 34-bearing seat, 35-working wall plate, 36-pressure sensor, 37-die cutting tool holder, 38-bearing I, 39-array type photoelectric sensor, 40-reflection type photoelectric sensor, 41-up-down moving table, 42-die cutting tool assembly, 43-pressure sensor seat, 44-paper feeding driving tooth type belt wheel, 45-paper feeding driven tooth belt, 46-paper feeding driven tooth type belt wheel, 47-paper guiding baffle, 48-transverse moving medium belt wheel, 49-transverse movement belt wheel shaft, 50-bearing II.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

The invention discloses a table type plane digital die-cutting machine capable of realizing die-cutting force detection and calibration, which comprises two side wall plates 1 forming a die-cutting machine support, wherein the two side wall plates 1 are oppositely arranged, two paper pressing wheel support rods 2 are arranged on the side wall plates 1, three sets of paper pressing wheel assemblies 4 are uniformly arranged on each paper pressing wheel support rod 2, and the paper pressing wheel assemblies 4 are pressed at the upper ends of a driving paper feeding roller 3 and a driven paper feeding roller 23. The active paper feeding roller 3 is connected with the side wall plate 1 through a bearing I38, a bearing seat 34 and a bearing gland 33. The extended end of the driving paper feeding roller 3 is provided with a double-tooth type belt wheel 30, the double-tooth type belt wheel 30 is connected with a paper feeding driving tooth type belt wheel 44 on a paper feeding driving motor 26 arranged on the side wall plate 1 through a paper feeding driving tooth type belt 31, and the double-tooth type belt wheel 30 is also connected with a paper feeding driven tooth type belt wheel 46 on a driven paper feeding roller 23 through a paper feeding driven tooth type belt 45. A shaft sleeve 32 is coaxially sleeved at one end of the core shaft of the active paper feeding roller 3.

As shown in fig. 4 and 5, a working wall plate 35 is further arranged between the two side wall plates 1, two parallel transverse movement guide rails 12 are mounted on the working wall plate 35, a transverse movement platform 13 is mounted on a transverse movement sliding block 11 matched with the transverse movement guide rails 12, an up-down movement motor base 8 is mounted on the transverse movement platform 13, an up-down movement driving motor 6 is mounted on the up-down movement motor base 8, a motor shaft of the up-down movement driving motor 6 is connected with an up-down movement screw 7 through a coupling 5, and an up-down movement screw 9 is arranged on the up-down movement screw 7 in a matching manner. The up-and-down movement screw 9 is installed on the pressure sensor holder 43, and the pressure sensor 36 is installed on the pressure sensor holder 43 at the same time.

A die cutting tool assembly 42 is arranged below the pressure sensor 36, and the die cutting tool assembly 42 and the die cutting tool clamping seat 37 are fixedly connected through screws and are arranged on the transverse moving platform 13; the pressure sensor seat 43 is installed on the up-and-down movement workbench 41, the up-and-down movement guide rail slide block 27 is installed on the back of the up-and-down movement workbench 41, and the up-and-down movement guide rail slide block 27 is matched with the up-and-down movement guide rail 10 installed on the transverse movement platform 13.

The lateral movement of the lateral movement platform 13 is driven by a lateral movement drive motor 18 mounted on the lateral movement motor base 14. The transverse motor transmission gear type belt wheel 17 is arranged at the front end of the transverse movement driving motor 18, and the transverse motor transmission gear type belt wheel 17 is connected with a transverse movement medium belt wheel 48 which is arranged on a transverse movement medium belt wheel shaft 49 through a bearing II50 by a transverse movement gear type belt 22.

The both ends of the transverse moving toothed belt 22 are disconnected and fixed to the transverse moving connecting block 16 by screws and the transverse moving toothed belt pressing plate 15, respectively, and the transverse moving connecting block 16 is fixed to the transverse moving platform 13 so that the transverse moving platform 13 moves when the motor rotates.

The lateral side of the lateral motion platform 13 is provided with a reflective photoelectric sensor 40, and one side of the working wallboard 35 is also provided with an array type photoelectric sensor 39 for detecting the deviation of the paper edge. A die cutting table 25 is mounted below the die cutting blade assembly 42. The front and rear of the machine are enclosed by a top panel 19, a rear panel 20 and a front panel 29, respectively. The back cover plate 20 and the front cover plate 29 also have the function of a paper feeding workbench, strip blanks are processed on the back cover plate 20 and the front cover plate 29, paper guide baffles 47 are installed, and the paper guide baffles 47 can be adjusted according to the specifications of die-cut products. Some electrical components are mounted on the side wall panel 1 to ensure the aesthetics and integrity of the machine. These electrical devices include a servo unit 21 of 3 drive motors, a PLC controller 24 and a dc power supply 28.

The working process of the table type plane digital die-cutting machine capable of realizing die-cutting force detection and calibration comprises the following steps:

in operation, when the paper feed driving motor 26 rotates, the paper feed driving toothed belt wheel 44 at the front end thereof rotates, and the double-toothed belt wheel 30 is rotated by the paper feed driving toothed belt 31. The rotation of the dual-toothed belt wheel 30 drives the driving paper feeding roller 3 fixed thereto to rotate, and the paper feeding driven toothed belt 45 drives the paper feeding driven toothed belt wheel 46 to rotate, thereby rotating the driven paper feeding roller 23. At this time, the driving feed roller 3 and the driven feed roller 23 are rotated in one direction. The tape-cut sheet is now placed on the back plate 20 between the two paper guide fences 47 and between the driven paper feed roller 23 and the platen roller assembly 4 thereon. Under pressure, the sheet will be moved in the sheet feeding direction by the driven sheet-feeding roller 23 rotating by friction. When the front edge of the Mark point is detected by the emitting photoelectric sensor 40 placed at the side edge of the transverse moving platform 13 at the initial position, the data of the original point is calculated according to the position data of the side edge of the Mark point sensed by the array type photoelectric sensor 39. At which time die cutting is initiated according to die cutting instructions in the controller. The die cutting is mainly the difference compensation movement of two servo motors and is carried out according to the die cutting instruction produced by the requirement of the knife line. One is that the transverse moving drive motor 18 drives the transverse moving toothed belt 22 to rotate, thereby driving the transverse moving connecting block 16 fixed to the transverse moving toothed belt 22 to move transversely. Because the laterally moving connecting block 16 is attached to the laterally moving platform 13, the laterally moving platform 13 moves laterally and the die cutting cutter assembly 42 thereon moves laterally.

The other is the movement in the paper feeding direction in which the driving paper feeding roller 3 and the driven paper feeding roller 23 are rotated together by the paper feeding driving motor 16 through belt drive. Under the pressure action of the paper pressing wheel assembly 4 at the upper end of the paper pressing wheel assembly, the generated friction force drives the paper to be die-cut to move. If the die cutting is required, the other servo motor, namely the up-and-down movement driving motor 6 drives the up-and-down movement lead screw 7 to rotate. The pressure sensor holder 43 is moved downward by the up-and-down movement of the screw 9 engaged therewith, which is installed in the pressure sensor holder 43. The pressure sensor 36 mounted on the other end of the pressure sensing base 43 presses down the cutter bar on the upper end of the die cutter assembly 42 when moving downward, and the cutter head of the die cutter assembly 42 is extended to contact the surface of the paper tape to be die-cut. At this time, since the pressure is generated, the pressure sensor 36 transmits data to the controller so that the die cutting can be performed if the pressure reaches a desired value.

And calibrating the die cutting pressure. The die cutting pressure is a key parameter of digital die cutting, and reliable die cutting quality can be guaranteed only if the die cutting pressure is proper. The invention can realize the table type plane digital die cutting machine structure for detecting and calibrating die cutting force, can provide the calibration of reliable die cutting pressure, and comprises the following steps: the sheet to be die-cut is placed on the rear housing plate 20 and fed to the lower end of the die-cutting cutter assembly 42 by the driven paper feed roller 23. The up-and-down motion driving motor 6 is adjusted to move so that the protruding cutter head of the die cutting cutter assembly 42 contacts the sheet to be die cut. The effect of die cutting is seen by performing test die cutting, if the die cutting is not complete, the descending displacement of the pressure sensor seat 43 is continuously increased, and the pressure is increased due to resistance. And then die cutting is carried out until an ideal die cutting effect is achieved. When the ideal die cutting effect is achieved, the current die cutting pressure and the type and the material of the paper are recorded, so that the calibrated die cutting pressure is adopted when the paper made of the same material is die-cut next time.

Claims (6)

1. Can realize that cross cutting force detects desk-top plane digital cross cutting machine of demarcation, its characterized in that: the paper feeding mechanism comprises two side wall plates which are oppositely arranged, and a paper feeding transmission mechanism is arranged between the two side wall plates; and a working wallboard is also arranged between the two side wallboards, and a die cutting mechanism is arranged on the working wallboard.

2. The table-type plane digital die-cutting machine capable of realizing die-cutting force detection and calibration according to claim 1, characterized in that: the paper feeding transmission mechanism comprises a driving paper feeding roller and a driven paper feeding roller which are arranged in parallel along the horizontal direction; the active paper feeding roller is connected with the side wall plate through a bearing I, a bearing seat and a bearing gland; the extension end of the driving paper feeding roller is provided with a duplex-tooth-shaped belt wheel, the duplex-tooth-shaped belt wheel is connected with a paper feeding driving tooth-shaped belt wheel on a paper feeding driving motor arranged on the side wall plate through a paper feeding driving tooth-shaped belt, and the duplex-tooth-shaped belt wheel is also connected with a paper feeding driven tooth-shaped belt wheel on a driven paper feeding roller through a paper feeding driven tooth-shaped belt.

3. The table-type plane digital die-cutting machine capable of realizing die-cutting force detection and calibration according to claim 2, characterized in that: paper pressing wheel assemblies are arranged on the driving paper feeding roller and the driven paper feeding roller, and the paper pressing wheel assemblies are installed on the side wall plate through paper pressing wheel supporting rods.

4. The table-type plane digital die-cutting machine capable of realizing die-cutting force detection and calibration according to claim 2, characterized in that: the die cutting mechanism comprises two transverse moving guide rails which are arranged on a working wallboard in parallel, the transverse moving guide rails are matched with a transverse moving sliding block, the transverse moving sliding block is connected with a transverse moving platform, an up-and-down moving motor base is arranged on the transverse moving platform, an up-and-down moving driving motor is arranged on the up-and-down moving motor base, a motor shaft of the up-and-down moving driving motor is connected with an up-and-down moving lead screw through a coupling, an up-and-down moving screw nut is arranged on the up-and-down moving lead screw in a matched mode, the up-and-down moving screw nut is arranged on a pressure sensor base, a pressure sensor is simultaneously arranged on the pressure sensor base, a die cutting tool assembly is arranged below the pressure sensor, and the die cutting tool assembly is connected with a die cutting tool clamping base through screws and is arranged on the transverse moving platform; the pressure sensor seat is installed on the up-and-down motion workbench, the back of the up-and-down motion workbench is provided with an up-and-down motion guide rail sliding block, and the up-and-down motion guide rail sliding block is matched with an up-and-down motion guide rail installed on the transverse motion platform.

5. The table-type plane digital die-cutting machine capable of realizing die-cutting force detection and calibration according to claim 4, characterized in that: the transverse motion platform is connected with a transverse motion connecting block, the transverse motion connecting block is connected to a transverse line motion toothed belt, and a transverse motor transmission toothed belt wheel is connected with a transverse motion medium belt wheel arranged on a transverse motion medium belt wheel shaft through a transverse motion toothed belt; the transverse motor transmission tooth belt wheel is arranged on a motor shaft of the transverse motion driving motor.

6. The table-type plane digital die-cutting machine capable of realizing die-cutting force detection and calibration according to claim 4, characterized in that: reflective photoelectric sensors are installed on the side face of the transverse motion platform, and array photoelectric sensors are installed on one side of the working wallboard.

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