CN215360467U - Flat-pressing flat-stamping die-cutting machine - Google Patents

Abstract

The utility model relates to the technical field of die cutting equipment, in particular to a flat pressing and hot stamping die cutting machine, which comprises: a sprocket drive assembly; a sliding frame arranged on a non-working part of the chain wheel type driving component; the folding linkage assembly and the pressing linkage assembly are symmetrically arranged on the sliding frame; the output end of the double-station driving component is in transmission connection with the folding linkage component and the pressing linkage component respectively; the bottom supporting plate is arranged at the non-working part of the chain wheel type driving assembly; the flat ironing machine is arranged at the output end of the pressing linkage assembly; cutting die and die-cutting rule set up respectively in two outputs of foling the interlock subassembly, and this technical scheme can go on cross cutting and gilt simultaneously, has improved production efficiency to the practicality of equipment has been improved.

Description

Flat-pressing flat-stamping die-cutting machine

Technical Field

The utility model relates to the technical field of die cutting equipment, in particular to a flat pressing and hot stamping die cutting machine.

Background

The die cutting machine has the working principle that a die cutting knife, a steel knife, a hardware die and a steel wire (or a template carved by a steel plate) are utilized, a certain pressure is applied through a stamping plate, a printed product or a paperboard is rolled and cut into a certain shape, if the whole printed product is pressed and cut into a single pattern product, the product is called die cutting, if the steel wire is utilized to press traces on the printed product or leave bent groove traces, the product is called indentation, if a male template and a female template are utilized, the die is heated to a certain temperature, patterns or characters with a three-dimensional effect are stamped on the surface of the printed product, the product is called gold stamping, if one base material is overlaid on another base material, the other parts except a genuine product are called waste discharge, and the waste discharge technology can be called die cutting technology.

In the prior art, when a plastic product is cut or gilded, the plastic product is often divided into two parts to be completed, the process is complicated, the operation is difficult, and meanwhile, the plastic product can be gilded only by manually heating a die, so that the efficiency is low, and meanwhile, certain danger can be caused to an operator due to overhigh temperature.

Therefore, a flat-pressing and flat-stamping die-cutting machine needs to be provided, die cutting and stamping can be carried out simultaneously, production efficiency is improved, and practicability of equipment is improved.

SUMMERY OF THE UTILITY MODEL

For solving the technical problem, the flat-pressing and flat-stamping die-cutting machine is provided, the technical scheme can simultaneously carry out die cutting and stamping, the production efficiency is improved, and the practicability of the equipment is improved.

In order to achieve the above purposes, the technical scheme adopted by the utility model is as follows:

a platen gold stamping die cutting machine comprising:

a sprocket drive assembly;

a sliding frame arranged on a non-working part of the chain wheel type driving component;

the folding linkage assembly and the pressing linkage assembly are symmetrically arranged on the sliding frame;

the output end of the double-station driving component is in transmission connection with the folding linkage component and the pressing linkage component respectively;

the bottom supporting plate is arranged at the non-working part of the chain wheel type driving assembly;

the flat ironing machine is arranged at the output end of the pressing linkage assembly;

the cutting die and the die-cutting rule are respectively arranged at two output ends of the folding linkage component.

Preferably, the sprocket drive assembly comprises:

a sprocket frame;

the first wheel set and the second wheel set are respectively arranged at two ends of the chain wheel frame, are rotatably connected with the chain wheel frame and are in transmission connection through a chain;

the second wheel set is arranged on the chain wheel frame, and the output end of the second wheel set is connected with the first wheel set.

Preferably, the dual station drive assembly comprises:

the driving rod is arranged on the sliding frame and is rotatably connected with the sliding frame;

the first bevel gear and the second bevel gear are respectively arranged at two ends of the driving rod;

and the rotating driving assembly is arranged on the sliding frame, and the output end of the rotating driving assembly is in transmission connection with the driving rod.

Preferably, the rotary drive assembly comprises:

the second servo motor is arranged on the sliding frame;

the first belt pulley is arranged at the output end of the second servo motor;

the second belt pulley is sleeved on the driving rod and fixedly connected with the driving rod, and the first belt pulley and the second belt pulley are in transmission connection through a belt.

Preferably, the folding linkage assembly includes:

the first threaded rod is arranged on the sliding frame and is rotatably connected with the sliding frame, two sections of threads are arranged on the first threaded rod, a third bevel gear is arranged at the end part of the first threaded rod, and the third bevel gear is meshed with the first bevel gear;

first sliding block and second sliding block set up respectively in the both ends of first threaded rod and rather than threaded connection, first sliding block and second sliding block all with carriage sliding connection, cutting die and die-cutting rule set up respectively on first sliding block and second sliding block.

Preferably, the push-down interlock assembly includes:

the second threaded rod is arranged on the sliding frame and is rotatably connected with the sliding frame, and a fourth bevel gear is arranged at the end part of the second threaded rod;

the working block is sleeved on the second threaded rod and is in threaded connection with the second threaded rod, the working block is in sliding connection with the sliding frame, and the flat ironing machine is arranged on the working block.

Compared with the prior art, the utility model has the beneficial effects that: firstly, a worker places a paper board at the output end of a chain wheel type driving component, the chain wheel type driving component starts to work, the output end of the chain wheel type driving component drives the paper board to move to the top of a bottom support plate, a double-station driving component starts to work, the output end of the double-station driving component drives a folding linkage component and a pressing linkage component to work, the output end of the pressing linkage component drives a flat ironing machine to descend, the flat ironing machine carries out gold stamping on the paper board, then the chain wheel type driving component works again, the output end of the chain wheel type driving component drives the paper board to move to a position between a cutting mold and a mold cutter after the gold stamping, the paper board placed later moves to the top of the bottom support plate again, the double-station driving component starts to work, the output end of the double-station driving component drives the folding linkage component and the pressing linkage component to work, and the output end of the pressing linkage component drives the flat ironing machine to descend, the flat ironing machine gilts the paper board, two output ends of the folding linkage assembly drive the cutting die and the die-cutting rule to approach each other, the bottom of the gilded paper board is supported by the cutting die, and the paper board is cut by the die-cutting rule;

1. through the arrangement of the chain wheel type driving assembly, the material can be moved and processed at the same time;

2. through the arrangement of the equipment, the die cutting and the gold stamping can be simultaneously carried out, the production efficiency is improved, and the practicability of the equipment is improved.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a perspective view of the sprocket drive assembly of the present invention;

FIG. 3 is a front view of the carriage, the dual-station drive assembly, the folding linkage assembly, the pressing linkage assembly, the flat ironing machine, the cutting die and the die cutter of the present invention;

FIG. 4 is an enlarged view taken at A of FIG. 3 in accordance with the present invention;

FIG. 5 is a schematic view showing a first three-dimensional structure of the sliding frame, the double-station driving assembly, the folding linkage assembly, the pressing linkage assembly, the flat ironing machine, the cutting mold and the die-cutting rule according to the present invention;

fig. 6 is a schematic diagram of a three-dimensional structure of the sliding frame, the double-station driving component, the folding linkage component, the pressing linkage component, the flat ironing machine, the cutting die and the die-cutting rule.

The reference numbers in the figures are:

1-a sprocket drive assembly; 1 a-sprocket carrier; 1 b-a first wheel set; 1 c-a second wheel set; 1 d-a first servo motor;

2-sliding rack;

3-a double-station driving component; 3 a-a drive rod; 3 b-a first bevel gear; 3 c-a second bevel gear; 3 d-a rotary drive assembly; 3d1 — second servomotor; 3d2 — first pulley; 3d3 — second pulley;

4-folding linkage component; 4 a-a first threaded rod; 4a 1-third bevel gear; 4 b-a first slider; 4 c-second slider;

5-pressing the linkage component; 5 a-a second threaded rod; 5a 1-fourth bevel gear; 5 b-a work block;

6-bottom supporting plate;

7-flat ironing machine;

8-cutting the mould;

9-die cutting rule.

Detailed Description

The following description is presented to disclose the utility model so as to enable any person skilled in the art to practice the utility model. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

Referring to fig. 1, a flat-pressing flat-stamping die-cutting machine includes:

a sprocket drive assembly 1;

a carriage 2 provided in a non-operating part of the sprocket drive assembly 1;

the folding linkage assembly 4 and the pressing linkage assembly 5 are symmetrically arranged on the sliding frame 2;

the double-station driving component 3 is arranged on the sliding frame 2, and the output end of the double-station driving component 3 is in transmission connection with the folding linkage component 4 and the pressing linkage component 5 respectively;

a bottom support plate 6 arranged at a non-working part of the sprocket wheel type driving component 1;

the flat ironing machine 7 is arranged at the output end of the lower pressing linkage component 5;

the cutting die 8 and the die-cutting rule 9 are respectively arranged at two output ends of the folding linkage component 4;

firstly, a worker places a paper board at the output end of a chain wheel type driving component 1, the chain wheel type driving component 1 starts to work, the output end of the chain wheel type driving component 1 drives the paper board to move to the top of a bottom support plate 6, a double-station driving component 3 starts to work, the output end of a double-station driving component 3 drives a folding linkage component 4 and a pressing linkage component 5 to work, the output end of the pressing linkage component 5 drives a flat ironing machine 7 to descend, the flat ironing machine 7 carries out gold stamping on the paper board, then the chain wheel type driving component 1 works again, the output end of the chain wheel type driving component 1 drives the paper board to move to a position between a cutting mold 8 and a mold cutter 9 after the gold stamping, the subsequently placed paper board also moves to the top of the bottom support plate 6 again, the double-station driving component 3 starts to work, the output end of the double-station driving component 3 drives the folding linkage component 4 and the pressing linkage component 5 to work, the output end of the downward pressing linkage component 5 drives the flat ironing machine 7 to descend, the flat ironing machine 7 gilts the paper board, the two output ends of the folding linkage component 4 drive the cutting die 8 and the die cutting knife 9 to be close to each other, the bottom of the gilt paper board is supported through the cutting die 8, and the paper board is cut through the die cutting knife 9.

The sprocket drive assembly 1 shown in fig. 2 comprises:

a sprocket frame 1 a;

the first wheel set 1b and the second wheel set 1c are respectively arranged at two ends of the chain wheel frame 1a, the first wheel set 1b and the second wheel set 1c are both rotatably connected with the chain wheel frame 1a, and the first wheel set 1b and the second wheel set 1c are in transmission connection through a chain;

the second wheel set 1c is arranged on the chain wheel frame 1a, and the output end of the second wheel set 1c is connected with the first wheel set 1 b;

the staff places the cardboard on the chain, and the output of first servo motor 1d drives first wheelset 1b and rotates, and first wheelset 1b drives the cardboard through the chain and removes, and second wheelset 1c supports the chain and the cooperation rotates, and sprocket carrier 1a is used for the fixed stay.

As shown in fig. 3, the double-station driving assembly 3 comprises:

a drive rod 3a which is arranged on the sliding frame 2 and is rotatably connected with the sliding frame;

a first bevel gear 3b and a second bevel gear 3c, which are respectively provided at both ends of the driving lever 3 a;

the rotating driving component 3d is arranged on the sliding frame 2, and the output end of the rotating driving component 3d is in transmission connection with the driving rod 3 a;

the double-station driving component 3 starts to work, the output end of the rotary driving component 3d drives the driving rod 3a to rotate, the driving rod 3a drives the first bevel gear 3b and the second bevel gear 3c to rotate in the same direction, and the first bevel gear 3b and the second bevel gear 3c respectively drive the force bearing ends of the folding linkage component 4 and the pressing linkage component 5 to rotate.

The rotary drive assembly 3d shown in fig. 4 includes:

a second servo motor 3d1 provided on the carriage 2;

a first belt pulley 3d2 arranged at the output end of the second servo motor 3d 1;

the second belt pulley 3d3 is sleeved on the driving rod 3a and fixedly connected with the driving rod 3a, and the first belt pulley 3d2 is in transmission connection with the second belt pulley 3d3 through a belt;

the rotary driving assembly 3d starts to work, the output end of the second servo motor 3d1 drives the first belt pulley 3d2 to rotate, the first belt pulley 3d2 drives the second belt pulley 3d3 to rotate through the belt, and the second belt pulley 3d3 drives the driving rod 3a to rotate.

As shown in fig. 5, the folding linkage assembly 4 includes:

the first threaded rod 4a is arranged on the sliding frame 2 and is rotatably connected with the sliding frame, two sections of threads are arranged on the first threaded rod 4a, a third bevel gear 4a1 is arranged at the end part of the first threaded rod 4a, and the third bevel gear 4a1 is meshed with the first bevel gear 3 b;

the first sliding block 4b and the second sliding block 4c are respectively arranged at two ends of the first threaded rod 4a and are in threaded connection with the first threaded rod 4a, the first sliding block 4b and the second sliding block 4c are both in sliding connection with the sliding frame 2, and the cutting die 8 and the die-cutting knife 9 are respectively arranged on the first sliding block 4b and the second sliding block 4 c;

the first bevel gear 3b drives the first threaded rod 4a to rotate through the third bevel gear 4a1, the first threaded rod 4a drives the cutting die 8 and the die-cutting rule 9 to be close to each other through the first sliding block 4b and the second sliding block 4c, the bottom of the gilded paperboard is supported through the cutting die 8, and the paperboard is cut through the die-cutting rule 9.

As shown in fig. 6, the push-down interlock assembly 5 includes:

a second threaded rod 5a which is arranged on the sliding frame 2 and is rotatably connected with the sliding frame, and a fourth bevel gear 5a1 is arranged at the end part of the second threaded rod 5 a;

the working block 5b is sleeved on the second threaded rod 5a and is in threaded connection with the second threaded rod, the working block 5b is in sliding connection with the sliding frame 2, and the flat ironing machine 7 is arranged on the working block 5 b;

the second bevel gear 3c drives the second threaded rod 5a to rotate through a fourth bevel gear 5a1, and the second threaded rod 5a drives the flat ironing machine 7 to descend through a working block 5 b.

The working principle of the utility model is as follows: firstly, a worker places a paper board on a chain, the output end of a first servo motor 1d drives a first wheel set 1b to rotate, the first wheel set 1b drives the paper board to move through the chain, the paper board moves to the top of a bottom support plate 6, a double-station driving component 3 starts to work, a rotary driving component 3d starts to work, the output end of a second servo motor 3d1 drives a first belt pulley 3d2 to rotate, the first belt pulley 3d2 drives a second belt pulley 3d3 to rotate through a belt, the second belt pulley 3d3 drives a driving rod 3a to rotate, the driving rod 3a drives a first bevel gear 3b and a second bevel gear 3c to rotate in the same direction, the first bevel gear 3b and the second bevel gear 3c respectively drive a third bevel gear 4a1 and a fourth bevel gear 5a1 to rotate, the fourth bevel gear 5a1 drives a second threaded rod 5a to rotate, the second threaded rod 5a drives a flatting machine 7 to descend through a working block 5b, the flat stamping machine 7 carries out gold stamping on the paper board, then the chain wheel type driving component 1 works again, the output end of the chain wheel type driving component 1 drives the paper board to move to a position between the cutting die 8 and the die-cutting knife 9, the paper board placed later also moves to the top of the bottom supporting plate 6 again, the double-station driving component 3 starts to work, the rotary driving component 3d starts to work, the output end of the second servo motor 3d1 drives the first belt pulley 3d2 to rotate, the first belt pulley 3d2 drives the second belt pulley 3d3 to rotate through a belt, the second belt pulley 3d3 drives the driving rod 3a to rotate, the driving rod 3a drives the first bevel gear 3b and the second bevel gear 3c to rotate in the same direction, the first bevel gear 3b and the second bevel gear 3c respectively drive the third bevel gear 4a1 and the fourth bevel gear 5a1 to rotate, the fourth bevel gear 5a1 drives the second threaded rod 5a to rotate, the second threaded rod 5a drives the flat ironing machine 7 to descend through the working block 5b, the flat ironing machine 7 gilts the paperboard, the third bevel gear 4a1 drives the first threaded rod 4a to rotate, the first threaded rod 4a drives the cutting die 8 and the die-cutting rule 9 to mutually approach through the first sliding block 4b and the second sliding block 4c, the bottom of the gilded paperboard is supported through the cutting die 8, the paperboard is cut through the die-cutting rule 9,

the device realizes the functions of the utility model through the following steps, thereby solving the technical problems provided by the utility model:

firstly, a worker places a paper board at the output end of a chain wheel type driving component 1;

step two, the chain wheel type driving component 1 starts to work, and the output end of the chain wheel type driving component 1 drives the paper board to move to the top of the bottom supporting plate 6;

step three, the double-station driving component 3 starts to work, and the output end of the double-station driving component 3 drives the folding linkage component 4 and the pressing linkage component 5 to work;

fourthly, the output end of the linkage assembly 5 is pressed down to drive the flat ironing machine 7 to descend, and the flat ironing machine 7 gilts the paper board;

fifthly, the chain wheel type driving assembly 1 works again, the output end of the chain wheel type driving assembly 1 drives the paper board to move to a position between the cutting die 8 and the die-cutting rule 9 after gold stamping, and the paper board placed later also moves to the top of the bottom supporting plate 6 again;

sixthly, the double-station driving component 3 starts to work, the output end of the double-station driving component 3 drives the folding linkage component 4 and the pressing linkage component 5 to work, the output end of the pressing linkage component 5 drives the flat ironing machine 7 to descend, and the flat ironing machine 7 gilts the paper board;

seventhly, two output ends of the folding linkage assembly 4 drive the cutting die 8 and the die-cutting rule 9 to be close to each other, the bottom of the gilded paper board is supported through the cutting die 8, and the paper board is cut through the die-cutting rule 9.

The foregoing shows and describes the general principles, essential features, and advantages of the utility model. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the utility model, but that various changes and modifications may be made without departing from the spirit and scope of the utility model, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a flat-pressing gilt cross cutting machine which characterized in that includes:

a sprocket drive assembly (1);

a sliding frame (2) arranged at a non-working part of the chain wheel type driving assembly (1);

the folding linkage component (4) and the pressing linkage component (5) are symmetrically arranged on the sliding frame (2);

the double-station driving component (3) is arranged on the sliding frame (2), and the output end of the double-station driving component (3) is in transmission connection with the folding linkage component (4) and the pressing linkage component (5) respectively;

the bottom supporting plate (6) is arranged at the non-working part of the chain wheel type driving component (1);

the flat ironing machine (7) is arranged at the output end of the downward pressing linkage component (5);

the cutting die (8) and the die-cutting rule (9) are respectively arranged at two output ends of the folding linkage component (4).

2. The platen die cutting machine according to claim 1, wherein the sprocket drive assembly (1) comprises:

a sprocket carrier (1 a);

the first wheel set (1b) and the second wheel set (1c) are respectively arranged at two ends of the chain wheel frame (1a), the first wheel set (1b) and the second wheel set (1c) are both rotatably connected with the chain wheel frame (1a), and the first wheel set (1b) and the second wheel set (1c) are in transmission connection through a chain;

the second wheel set (1c) is arranged on the chain wheel frame (1a), and the output end of the second wheel set (1c) is connected with the first wheel set (1 b).

3. The platen die cutting machine according to claim 1, wherein the double station drive assembly (3) comprises:

a drive rod (3a) which is arranged on the sliding frame (2) and is rotatably connected with the sliding frame;

a first bevel gear (3b) and a second bevel gear (3c) which are respectively arranged at two ends of the driving rod (3 a);

the rotary driving assembly (3d) is arranged on the sliding frame (2), and the output end of the rotary driving assembly (3d) is in transmission connection with the driving rod (3 a).

4. Flat-pressing and flat-stamping die-cutting machine according to claim 3, characterized in that the rotary drive assembly (3d) comprises:

a second servo motor (3d1) provided on the carriage (2);

the first belt pulley (3d2) is arranged at the output end of the second servo motor (3d 1);

the second belt pulley (3d3) is sleeved on the driving rod (3a) and fixedly connected with the driving rod, and the first belt pulley (3d2) is in transmission connection with the second belt pulley (3d3) through a belt.

5. The platen stamping die-cutting machine according to claim 3, wherein the folding linkage assembly (4) comprises:

the first threaded rod (4a) is arranged on the sliding frame (2) and is rotatably connected with the sliding frame, two sections of threads are arranged on the first threaded rod (4a), a third bevel gear (4a1) is arranged at the end part of the first threaded rod (4a), and the third bevel gear (4a1) is meshed with the first bevel gear (3 b);

first sliding block (4b) and second sliding block (4c), set up respectively in the both ends of first threaded rod (4a) and rather than threaded connection, first sliding block (4b) and second sliding block (4c) all with carriage (2) sliding connection, cutting die (8) and die-cutting rule (9) set up respectively on first sliding block (4b) and second sliding block (4 c).

6. The platen stamping die-cutting machine according to claim 3, wherein the pressing linkage assembly (5) comprises:

the second threaded rod (5a) is arranged on the sliding frame (2) and is rotatably connected with the sliding frame, and a fourth bevel gear (5a1) is arranged at the end part of the second threaded rod (5 a);

the working block (5b) is sleeved on the second threaded rod (5a) and is in threaded connection with the second threaded rod, the working block (5b) is in sliding connection with the sliding frame (2), and the flat ironing machine (7) is arranged on the working block (5 b).

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