CN114919012A

CN114919012A - High-precision die cutting machine and die cutting method

Info

Publication number: CN114919012A
Application number: CN202210671567.6A
Authority: CN
Inventors: 陈敏; 叶蓉华; 陈明建
Original assignee: Fuqing Chengye Electronics Co ltd
Current assignee: Fuqing Chengye Electronics Co ltd
Priority date: 2022-06-14
Filing date: 2022-06-14
Publication date: 2022-08-19
Anticipated expiration: 2042-06-14
Also published as: CN114919012B

Abstract

The invention provides a high-precision die-cutting machine and a die-cutting method. Let remaining leftover bits simultaneously by the pressure on guide mechanism to separate the material after the cross cutting from two upper and lower directions respectively, the better accuracy of separation effect is higher.

Description

High-precision die cutting machine and die cutting method

Technical Field

The invention relates to the technical field of die cutting, in particular to a high-precision die cutting machine and a die cutting method.

Background

The die cutting machine is called a beer machine, a cutting machine and a numerical control punching machine, and is mainly used for die cutting (full breaking and half breaking), indentation and gold stamping operation, fitting and automatic waste discharge of corresponding nonmetal materials, non-setting adhesive, EVA (ethylene vinyl acetate), double-sided adhesive, electrons, mobile phone rubber mats and the like.

Disclosure of Invention

In view of the above problems, the present invention is directed to solving the above-described problems. An object of the present invention is to provide a high-precision die cutting machine and a die cutting method which solve the above problems and can better separate the stamped objects.

In order to achieve the purpose, the invention adopts the following technical scheme:

a high-precision die-cutting machine comprises a die-cutting machine body, wherein the die-cutting machine body is provided with an embossing device and a material guide mechanism, and the material guide mechanism penetrates through the lower part of the output end of the embossing device; the stamping device is characterized by further comprising a separating mechanism, a discharging mechanism and a recovering mechanism, wherein the recovering mechanism and the discharging mechanism are located on one side of the output end of the material guiding mechanism, the separating mechanism is located between the stamping device and the discharging mechanism, the separating mechanism is arranged below the material guiding mechanism, and the discharging mechanism is located above the separating mechanism; the separating mechanism comprises an inner shell, a driving module, a circulating belt and an ejector rod; the inner shell transversely comprises a base part, a convex part and a magnetic absorption layer, the cross section of the base part is in a straight notch shape, the convex part is arranged at the upper end of the base part, the height of the convex part is gradually increased from one end close to the imprinting device to the other end and then gradually reduced, and the magnetic absorption layer surrounds the outer periphery of the inner shell; the circulating belt is arranged on the outer side of the inner shell in a surrounding manner, and the output end of the driving module is connected with the circulating belt and used for driving the circulating belt to rotate circularly along the periphery of the inner shell in the material conveying direction; a plurality of sliding grooves are arranged on the circulating belt in a penetrating manner, the ejector rod is connected with the sliding grooves in a sliding manner, and the lower end of the ejector rod is in sliding abutment with the outer side of the magnetic absorption layer; when the circulating belt drives the ejector rod to move to the top end of the protruding portion, the upper end of the ejector rod moves upwards from the port of the sliding groove, and an imprinting object passing through the upper material guide mechanism is ejected into the input end of the discharging mechanism. The rotating circulating belt drives the ejector rod to move along the surface of the inner shell, and when the ejector rod passes through the convex part, the ejector rod ejects and separates the stamped objects upwards along the fluctuation, and simultaneously transfers the ejected stamped objects.

The stamping device comprises a main frame, wherein the upper end of the main frame is provided with a telescopic cylinder group, and the output end of the telescopic cylinder group is vertically downward and fixedly connected with a stamping block; the material guide mechanism comprises a bottom plate and guide assemblies, the bottom plate is arranged below the stamping block, and the guide assemblies are symmetrically arranged on two sides of the bottom plate; the guide assembly comprises a material guide conveying belt and a driving wheel set, and the driving wheel set is connected with the material guide conveying belt and used for driving the material guide conveying belt to operate. So as to stamp the material to obtain the stamped object.

The invention has the preferable technical scheme that a baffle is arranged on one side of the material guide conveying belt, which is far away from the bottom plate, a pressing roller is arranged above the material guide conveying belt, and the pressing roller is arranged on the baffle. Therefore, the redundant part of the material is kept in a flat state, so that the presswork can be better separated when being ejected.

The invention has the preferable technical scheme that the driving module comprises rotating wheels, rotating shafts and belt driving groups, the rotating shafts are rotatably arranged at the front end and the rear end of the inner shell, the rotating wheels are symmetrically arranged at the two ends of the rotating shafts, the output ends of the belt driving groups are connected with the rotating shafts at one side, and the circulating belts are rotatably connected with the rotating wheels. Therefore, the rotating shaft and the rotating wheel are driven to rotate through the belt driving set so as to drive the circulating belt to rotate.

The invention has the preferable technical scheme that the lower end of the ejector rod is provided with a groove, a magnetic ball is rotationally connected in the groove, and the magnetic ball is in rolling connection with the magnetic attraction layer. Therefore, the top rod is easier to move, and the bottom of the top rod is always kept close to the magnetic layer.

The preferable technical scheme of the invention is that the discharging mechanism comprises a connecting plate and a discharging conveying belt group, one end of the connecting plate is arranged at one side of the input end of the discharging conveying belt group, and the other end of the connecting plate extends to the upper part of the separating mechanism; the connection plate is arranged in an inclined way. Thereby receiving and transporting the ejected stamps.

The invention has the preferable technical scheme that the recovery mechanism comprises a traction roller group and a recovery box, and the recovery box is arranged below the traction roller group. For recovering the residual material.

A use method of a high-precision die-cutting machine comprises the following steps:

step S00: after the materials are put in from the input end of the material guide mechanism, the body is started to be debugged, and a mandril is arranged at a proper position on the circulating belt;

step S10: when the material passes through the lower part of the stamping device, the stamping block is driven by the telescopic cylinder group to stamp a stamped object on the material, and the stamped object moves forwards continuously;

step S20: the driving module drives the circulating belt to rotate circularly, drives the ejector rod to move on the surface of the magnetic attraction layer, presses two sides of the material through the pressing roller, pushes the imprinting object onto the connecting plate along with the upward movement of the protruding part, and simultaneously gradually separates the imprinting object from the material integrally, so that the imprinting object enters the discharging conveying belt group to be transported away;

step S30: meanwhile, the residual materials separated out of the presswork are guided to a recovery box along with the drawing roller group and collected.

The invention has the beneficial effects that:

the invention provides a high-precision die-cutting machine and a die-cutting method.A rotating circulating belt drives an ejector rod to move along the surface of an inner shell, and when the ejector rod passes through a convex part, an embossed object is ejected upwards and separated along fluctuation, and the ejected embossed object is transferred. Let remaining leftover bits simultaneously by the pressure on guide mechanism to separate the material after the cross cutting from two upper and lower directions respectively, the better accuracy of separation effect is higher.

Other characteristic features and advantages of the invention will become apparent from the following description of exemplary embodiments, which is to be read in connection with the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and together with the description, serve to explain the principles of the invention. In the drawings, like reference numerals are used to indicate like elements. The drawings in the following description are directed to some, but not all embodiments of the invention. For a person skilled in the art, other figures can be derived from these figures without inventive effort.

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

FIG. 2 is an enlarged schematic view taken at A of FIG. 1 in accordance with the present invention;

FIG. 3 is a schematic view of a portion of the upper portion of the endless belt of the present invention;

FIG. 4 is a schematic diagram of the die cutting operation of the present invention.

In the figure: 1. a body; 2. an imprint device; 3. a material guiding mechanism; 4. a separating mechanism; 5. a discharging mechanism; 6. a recovery mechanism; 7. an inner shell; 8. a driving module; 9. a circulating belt; 10. a top rod; 11. a base; 12. a boss portion; 13. a magnetic absorption layer; 14. a chute; 15. a main frame; 16. a telescopic cylinder; 17. a stamping block; 18. a base plate; 19. a guide assembly; 20. a material guiding and conveying belt; 21. a driving wheel set; 22. a baffle plate; 23. pressing the roller; 24. a rotating wheel; 25. a rotating shaft; 26. a belt drive group; 27. a groove; 28. a magnetic ball; 29. a connection plate; 30. a discharge conveyor belt group; 31. drawing the roller set; 32. and (6) a recycling bin.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention. It should be noted that the embodiments and features of the embodiments in the present application may be arbitrarily combined with each other without conflict.

The technical solution of the present invention will be further described with reference to the accompanying drawings and examples.

As shown in fig. 1 to 4, the present embodiment provides a high precision die cutting machine, which includes a die cutting machine body 1, the die cutting machine body 1 is provided with a stamping device 2 and a material guiding mechanism 3, and the material guiding mechanism 3 passes through a lower portion of an output end of the stamping device 2; the stamping device is characterized by further comprising a separating mechanism 4, a discharging mechanism 5 and a recovering mechanism 6, wherein the recovering mechanism 6 and the discharging mechanism 5 are positioned on one side of the output end of the material guiding mechanism 3, the separating mechanism 4 is positioned between the stamping device 2 and the discharging mechanism 5, the separating mechanism 4 is arranged below the material guiding mechanism 3, and the discharging mechanism 5 is positioned above the separating mechanism 4; the material is impressed by impression device 2 after the input of guide mechanism 3 gets into, and the impression is followed closely with remaining material separation through separating mechanism 4 to the impression thing. The separating mechanism 4 comprises an inner shell 7, a driving module 8, a circulating belt 9 and a mandril 10; the inner shell 7 transversely comprises a base 11, a bulge part 12 and a magnetic absorption layer 13, the cross section of the base 11 is in a straight slot shape, the bulge part 12 is arranged at the upper end of the base 11, the height of the bulge part 12 is gradually increased from one end close to the imprinting device 2 to the other end and then gradually reduced, and the magnetic absorption layer 13 surrounds the outer periphery of the inner shell 7; the endless belt 9 is arranged around the outside of the inner casing 7, wherein the endless belt 9 is arranged at an equal distance from the base 11. The output end of the driving module 8 is connected with the circulating belt 9 and used for driving the circulating belt 9 to rotate circularly along the periphery of the inner shell 7 in the material conveying direction; a plurality of sliding grooves 14 are arranged on the circulating belt 9 in a penetrating manner, wherein the sliding grooves 14 are arranged in a horizontal-vertical manner, the ejector rod 10 is connected with the sliding grooves 14 in a sliding manner, and the lower end of the ejector rod 10 is in sliding contact with the outer side of the magnetic absorption layer 13; when the circulating belt 9 runs and rotates, the ejector rod 10 arranged in the sliding groove 14 moves along with the circulating belt, when the ejector rod 10 moves above the convex part 12, due to the fluctuation of the convex part 12, the ejector rod moves upwards, and when the circulating belt 9 drives the ejector rod 10 to move to the top end of the convex part 12, the upper end of the ejector rod 10 moves upwards from the port of the sliding groove 14, and the imprinting materials passing through the upper material guide mechanism 3 are ejected into the input end of the material discharge mechanism 5. Wherein, the top rod 10 can be arranged in the sliding groove 14 at different positions according to different patterns.

Preferably, the embossing device 2 comprises a main frame 15, the upper end of the main frame 15 is provided with a telescopic cylinder group 16, and the output end of the telescopic cylinder group 16 is vertically downward and fixedly connected with an embossing block 17; the material guide mechanism 3 comprises a bottom plate 18 and guide components 19, the bottom plate 18 is arranged below the stamping block 17, and the guide components 19 are symmetrically arranged on two sides of the bottom plate 18; the guiding assembly 19 includes a material guiding conveyor 20 and a driving wheel set 21, wherein the driving wheel set 21 is connected to the material guiding conveyor 20 for driving the material guiding conveyor 20 to move. The driving wheel set 21 drives the material guiding conveyor 20 to run, and when materials on the material guiding conveyor 20 pass through, the telescopic cylinder set 16 pushes the stamping block 17 to stamp the materials, wherein the bottom plate 18 plays a supporting role during stamping.

Preferably, a baffle plate 22 is arranged on one side of the material guiding and conveying belt 20 far away from the bottom plate 18, a pressing roller 23 is arranged above the material guiding and conveying belt 20, and the pressing roller 23 is arranged on the baffle plate 22. The material moves between guide transmission band 20 and pressing roller 23, can play the effect of location to the material through pressing roller 23 to when ejector pin 10 upwards ejecting pressing object, through pressing roller 23 downwards pressing leftover bits, can be higher with both separation.

Preferably, wherein, the driving module 8 includes runner 24, pivot 25 and belt drive group 26, and pivot 25 rotates and sets up in the front and back both ends of inner shell 7, and runner 24 symmetry sets up in the both ends of pivot 25, and the output of belt drive group 26 is connected with the pivot 25 of one side, and the circulatory system 9 rotates with runner 24 to be connected, drives the pivot 25 through belt drive group 26 and rotates, lets runner 24 rotate simultaneously to let the circulatory system 9 move.

Preferably, the lower end of the top rod 10 is provided with a groove 27, a magnetic ball 28 is rotatably connected in the groove 27, and the magnetic ball 28 is in rolling connection with the magnetic attraction layer 13. The push rod 10 can move more smoothly by arranging the magnetic ball 28 at the bottom end of the push rod 10, and meanwhile, the bottom end of the push rod 10 always moves on the surface of the magnetic attraction layer 13 through the magnetic connection between the magnetic attraction layer 13 and the magnetic ball 28.

Preferably, the discharging mechanism 5 comprises a connecting plate 29 and a discharging conveyor belt group 30, one end of the connecting plate 29 is arranged on one side of the input end of the discharging conveyor belt group 30, and the other end of the connecting plate extends to the upper part of the separating mechanism 4; the connector tiles 29 are arranged in an inclined manner. When the ejector pins 10 are separated against the stamp, the portion of the stamp from which the leading end has been separated will be higher than the lower end of the connector tile 29, and when the stamp is not completely separated, the stamp will still advance and eventually be completely separated and carried away in contact with the outfeed conveyor set 30.

Preferably, the recovery mechanism 6 includes a pull roll group 31 and a recovery tank 32, and the recovery tank 32 is provided below the pull roll group 31. The residual materials separated from the presswork are drawn and guided to the recovery box 32 through the drawing roller group 31, so that the materials are kept stable in the moving process.

A use method of a high-precision die cutting machine comprises the following steps:

step S00: after materials are put in from the input end of the material guide mechanism 3, the body 1 is started to be debugged, and a mandril 10 is arranged at a proper position on the circulating belt 9;

step S10: when the material passes below the imprinting device 2, the imprinting block 17 is driven by the telescopic cylinder group 16 to imprint an imprinting object on the material, and the imprinting object continues to move forwards;

step S20: the driving module 8 drives the circulating belt 9 to rotate circularly, drives the ejector rod 10 to move on the surface of the magnetic absorption layer 13 at the same time, presses two sides of the material through the pressing roller, meanwhile, the ejector rod 10 moves upwards along with the convex part 12 to push the imprinting object onto the connecting plate 29, and meanwhile, the imprinting object enters the discharging conveying belt group 30 to be transported away along with the gradual separation of the imprinting object and the material;

step S30: while the residual material separated from the imprints is guided with the pull roll group 31 to the recovery bin 32 for collection.

The above embodiments are merely to illustrate the technical solutions of the present invention and not to limit the present invention, and the present invention has been described in detail with reference to the preferred embodiments. It will be understood by those skilled in the art that various modifications and equivalent arrangements may be made without departing from the spirit and scope of the present invention and it should be understood that the present invention is to be covered by the appended claims.

Claims

1. The utility model provides a high accuracy cross cutting machine which characterized in that:

the die cutting machine comprises a die cutting machine body (1), wherein the die cutting machine body (1) is provided with an embossing device (2) and a material guiding mechanism (3), and the material guiding mechanism (3) penetrates through the lower part of the output end of the embossing device (2); the stamping device is characterized by further comprising a separating mechanism (4), a discharging mechanism (5) and a recovering mechanism (6), wherein the recovering mechanism (6) and the discharging mechanism (5) are located on one side of the output end of the material guiding mechanism (3), the separating mechanism (4) is located between the stamping device (2) and the discharging mechanism (5), the separating mechanism (4) is arranged below the material guiding mechanism (3), and the discharging mechanism (5) is located above the separating mechanism (4);

the separating mechanism (4) comprises an inner shell (7), a driving module (8), a circulating belt (9) and a push rod (10); the inner shell (7) transversely comprises a base (11), a protruding portion (12) and a magnetic absorption layer (13), the cross section of the base (11) is in a straight notch shape, the protruding portion (12) is arranged at the upper end of the base (11), the height of the protruding portion (12) is gradually increased from one end close to the imprinting device (2) to the other end and then gradually reduced, and the magnetic absorption layer (13) surrounds the outer periphery of the inner shell (7); the circulating belt (9) is arranged on the outer side of the inner shell (7) in a surrounding mode, and the output end of the driving module (8) is connected with the circulating belt (9) and used for driving the circulating belt (9) to rotate circularly along the periphery of the inner shell (7) in the material conveying direction; a plurality of sliding grooves (14) are arranged on the circulating belt (9) in a penetrating mode, the ejector rod (10) is connected with the sliding grooves (14) in a sliding mode, and the lower end of the ejector rod (10) is in sliding abutting contact with the outer side of the magnetic absorption layer (13);

when the circulating belt (9) drives the ejector rod (10) to move to the top end of the protruding portion (12), the upper end of the ejector rod (10) moves upwards from the port of the sliding groove (14), and the imprinting materials passing through the upper material guide mechanism (3) are ejected into the input end of the discharging mechanism (5).

2. The high accuracy die cutting machine of claim 1, wherein:

the embossing device (2) comprises a main frame (15), a telescopic cylinder group (16) is arranged at the upper end of the main frame (15), and an output end of the telescopic cylinder group (16) is vertically downward and fixedly connected with an embossing block (17); the material guide mechanism (3) comprises a bottom plate (18) and guide assemblies (19), the bottom plate (18) is arranged below the stamping block (17), and the guide assemblies (19) are symmetrically arranged on two sides of the bottom plate (18); the guide assembly (19) comprises a material guide conveying belt (20) and a driving wheel set (21), and the driving wheel set (21) is connected with the material guide conveying belt (20) to drive the material guide conveying belt (20) to operate.

3. The high accuracy die cutting machine of claim 2, characterized in that:

one side of the material guide conveying belt (20) far away from the bottom plate (18) is provided with a baffle (22), a pressing roller (23) is arranged above the material guide conveying belt (20), and the pressing roller (23) is arranged on the baffle (22).

4. The high accuracy die cutting machine of claim 1, characterized in that:

drive module (8) include runner (24), pivot (25) and belt drive group (26), pivot (25) rotate set up in both ends around inner shell (7), runner (24) symmetry set up in the both ends of pivot (25), the output of belt drive group (26) is connected with pivot (25) of one side, endless belt (9) with runner (24) rotate to be connected.

5. The high accuracy die cutting machine of claim 1, characterized in that:

the lower end of the ejector rod (10) is provided with a groove (27), a magnetic ball (28) is rotationally connected in the groove (27), and the magnetic ball (28) is in rolling connection with the magnetic absorption layer (13).

6. The high accuracy die cutting machine of claim 1, characterized in that:

the discharging mechanism (5) comprises a connecting plate (29) and a discharging conveying belt group (30), one end of the connecting plate (29) is arranged on one side of the input end of the discharging conveying belt group (30), and the other end of the connecting plate extends to the upper part of the separating mechanism (4); the connection plate (29) is arranged in an inclined mode.

7. The high accuracy die cutting machine of claim 1, characterized in that:

the recovery mechanism (6) comprises a drawing roller group (31) and a recovery box (32), and the recovery box (32) is arranged below the drawing roller group (31).

8. The use method of the high-precision die-cutting machine is characterized by comprising the following steps: the method comprises the following steps:

step S00: after materials are put into the material guide mechanism (3) from the input end, the body (1) is started to be debugged, and a mandril (10) is arranged at a proper position on the circulating belt (9);

step S10: when the material passes below the imprinting device (2), the imprinting block (17) is driven by the telescopic cylinder group (16) to imprint an imprinting object on the material, and the imprinting object moves forwards continuously;

step S20: the driving module (8) drives the circulating belt (9) to rotate circularly, meanwhile, the ejector rod (10) is driven to move on the surface of the magnetic attraction layer (13), two sides of a material are pressed by pressing the roller, meanwhile, the ejector rod (10) moves upwards along with the bulge (12) to push an imprinting object onto the connecting plate (29), and meanwhile, the imprinting object enters the discharging conveying belt group (30) to be transported away along with the gradual separation of the imprinting object and the material;

step S30: meanwhile, the residual materials separated out of the presswork are guided to a recovery box (32) along with the drawing roller group (31) to be collected.